®
Universe IID/IIBTM User Manual
May 12, 2010
6024 Silver Creek Valley Road, San Jose, California 95138
Telephone: (800) 345-7015 • (408) 284-8200 • FAX: (408) 284-2775
Printed in U.S.A.
©2009 Integrated Device Technology, Inc.
�GENERAL DISCLAIMER
Integrated Device Technology, Inc. reserves the right to make changes to its products or specifications at any time, without notice, in order to improve design or performance
and to supply the best possible product. IDT does not assume any responsibility for use of any circuitry described other than the circuitry embodied in an IDT product. The
Company makes no representations that circuitry described herein is free from patent infringement or other rights of third parties which may result from its use. No license is
granted by implication or otherwise under any patent, patent rights or other rights, of Integrated Device Technology, Inc.
CODE DISCLAIMER
Code examples provided by IDT are for illustrative purposes only and should not be relied upon for developing applications. Any use of the code examples below is completely
at your own risk. IDT MAKES NO REPRESENTATIONS OR WARRANTIES OF ANY KIND CONCERNING THE NONINFRINGEMENT, QUALITY, SAFETY OR SUITABILITY
OF THE CODE, EITHER EXPRESS OR IMPLIED, INCLUDING WITHOUT LIMITATION ANY IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR NON-INFRINGEMENT. FURTHER, IDT MAKES NO REPRESENTATIONS OR WARRANTIES AS TO THE TRUTH, ACCURACY OR COMPLETENESS
OF ANY STATEMENTS, INFORMATION OR MATERIALS CONCERNING CODE EXAMPLES CONTAINED IN ANY IDT PUBLICATION OR PUBLIC DISCLOSURE OR
THAT IS CONTAINED ON ANY IDT INTERNET SITE. IN NO EVENT WILL IDT BE LIABLE FOR ANY DIRECT, CONSEQUENTIAL, INCIDENTAL, INDIRECT, PUNITIVE OR
SPECIAL DAMAGES, HOWEVER THEY MAY ARISE, AND EVEN IF IDT HAS BEEN PREVIOUSLY ADVISED ABOUT THE POSSIBILITY OF SUCH DAMAGES. The code
examples also may be subject to United States export control laws and may be subject to the export or import laws of other countries and it is your responsibility to comply with
any applicable laws or regulations.
LIFE SUPPORT POLICY
Integrated Device Technology's products are not authorized for use as critical components in life support devices or systems unless a specific written agreement pertaining to
such intended use is executed between the manufacturer and an officer of IDT.
1. Life support devices or systems are devices or systems which (a) are intended for surgical implant into the body or (b) support or sustain life and whose failure to perform,
when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user.
2. A critical component is any components of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device
or system, or to affect its safety or effectiveness.
IDT, the IDT logo, and Integrated Device Technology are trademarks or registered trademarks of Integrated Device Technology, Inc.
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Contents
1.
Functional Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
1.1
1.2
2.
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1.1.1
Universe II Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1.1.2
Universe II Benefits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1.1.3
Universe II Typical Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Main Interfaces. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1.2.1
VMEbus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1.2.2
PCI Bus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1.2.3
Interrupter and Interrupt Handler . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1.2.4
DMA Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
17
18
19
19
20
22
22
23
24
VMEbus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
2.1
2.2
2.3
2.4
2.5
2.6
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VMEbus Requester . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.2.1
Internal Arbitration for VMEbus Requests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.2.2
Request Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.2.3
VMEbus Release . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Universe II as VMEbus Master . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.3.1
Addressing Capabilities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.3.2
Data Transfer Capabilities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.3.3
Cycle Terminations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Universe II as VMEbus Slave . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.4.1
Coupled Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.4.2
Posted Writes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.4.3
Prefetched Block Reads . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.4.4
VMEbus Lock Commands (ADOH Cycles) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.4.5
VMEbus Read-Modify-Write Cycles (RMW Cycles) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.4.6
Register Accesses. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.4.7
Location Monitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.4.8
Generating PCI Configuration Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VMEbus Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.5.1
First Slot Detector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.5.2
VMEbus Register Access at Power-up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Automatic Slot Identification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.6.1
Auto Slot ID: VME64 Specified . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.6.2
Auto-ID: A Proprietary IDT Method . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.6.3
System Controller Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.6.4
IACK Daisy-Chain Driver Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.6.5
VMEbus Time-out . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2.6.6
Bus Isolation Mode (BI-Mode) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Integrated Device Technology
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25
25
26
27
28
28
30
31
32
32
33
34
36
37
37
38
38
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Universe II User Manual
May 12, 2010
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3.
Contents
PCI Interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
3.1
3.2
3.3
3.4
4.
49
49
49
50
50
52
52
53
53
54
55
55
56
57
57
57
58
60
61
64
65
Slave Image Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
4.1
4.2
4.3
4.4
5.
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PCI Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.2.1
32-Bit Versus 64-Bit PCI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.2.2
PCI Bus Request and Parking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.2.3
Address Phase . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.2.4
Data Transfer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.2.5
Termination Phase . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.2.6
Parity Checking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Universe II as PCI Master . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.3.1
Command Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.3.2
PCI Burst Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.3.3
Termination . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.3.4
Parity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Universe II as PCI Target. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.4.1
Command Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.4.2
Data Transfer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.4.3
Coupled Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.4.4
Posted Writes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.4.5
Special Cycle Generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.4.6
Using the VOWN bit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.4.7
Terminations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VME Slave Image Programming. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.2.1
VMEbus Fields . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.2.2
PCI Bus Fields . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.2.3
Control Fields . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PCI Bus Target Images . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.3.1
PCI Bus Fields . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.3.2
VMEbus Fields . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4.3.3
Control Fields . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Special PCI Target Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
67
67
68
69
69
70
71
71
73
73
Registers Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
5.1
5.2
5.3
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Register Access from the PCI Bus. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.2.1
PCI Configuration Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.2.2
Memory or I/O Access. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.2.3
Locking the Register Block from the PCI bus. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Register Access from the VMEbus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.3.1
VMEbus Register Access Image (VRAI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.3.2
CR/CSR Accesses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.3.3
RMW and ADOH Register Access Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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5
5.4
5.5
Mailbox Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83
Semaphores . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83
6.
DMA Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
6.1
6.2
6.3
6.4
6.5
6.6
6.7
6.8
7.
Interrupt Generation and Handling. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
7.1
7.2
7.3
8.
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
DMA Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
6.2.1
Source and Destination Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
6.2.2
Non-incrementing DMA Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
6.2.3
Transfer Size. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
6.2.4
Transfer Data Width . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
6.2.5
DMA Command Packet Pointer. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90
6.2.6
DMA Control and Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90
Direct Mode Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
Linked-list Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96
6.4.1
Linked-list Updating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100
FIFO Operation and Bus Ownership . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101
6.5.1
PCI-to-VMEbus Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101
6.5.2
VMEbus-to-PCI Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103
DMA Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104
DMA Channel Interactions with Other Channels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105
DMA Error Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105
6.8.1
DMA Software Response to Error . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105
6.8.2
DMA Hardware Response to Error . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106
6.8.3
Resuming DMA Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Interrupt Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7.2.1
PCI Interrupt Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7.2.2
VMEbus Interrupt Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Interrupt Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7.3.1
PCI Interrupt Handling. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7.3.2
VMEbus Interrupt Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7.3.3
Internal Interrupt Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
7.3.4
VME64 Auto-ID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
109
111
111
113
116
116
116
118
123
Error Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 125
8.1
8.2
8.3
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Errors on Coupled Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Errors on Decoupled Transactions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8.3.1
Posted Writes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8.3.2
Prefetched Reads . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8.3.3
DMA Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8.3.4
Parity Errors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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125
125
126
127
127
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Contents
Resets, Clocks and Power-up Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .129
9.1
9.2
9.3
9.4
9.5
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Resets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9.2.1
Universe II Reset Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9.2.2
Reset Implementation Cautions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Power-Up Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9.3.1
Power-up Option Descriptions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9.3.2
Power-up Option Implementation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9.3.3
Hardware Initialization (Normal Operating Mode) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Test Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9.4.1
Auxiliary Test Modes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
9.4.2
JTAG support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Clocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
129
129
132
133
135
136
139
140
141
141
141
142
10. Signals and Pinout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .143
10.1
10.2
10.3
10.4
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VMEbus Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PCI Bus Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Pin-out . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
10.4.1
313-pin Plastic BGA Package (PBGA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
143
144
147
151
151
11. Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .153
11.1
11.2
11.3
11.4
DC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11.1.1
Non-PCI Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11.1.2
PCI Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11.1.3
Pin List and DC Characteristics for all Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Operating Conditions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11.2.1
Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Power Sequencing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
153
153
154
155
160
161
161
162
12. Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .163
12.1
12.2
12.3
A.
163
164
171
171
Packaging Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .333
A.1
B.
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Register Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
12.3.1
PCI Configuration Space ID Register (PCI_ID) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
313 Pin PBGA Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 333
Performance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .335
B.1
B.2
B.3
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PCI Slave Channel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
B.2.1
Coupled Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
B.2.2
Decoupled Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VME Slave Channel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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336
336
338
340
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B.4
B.5
B.6
C.
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Physical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Thermal Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Universe II Ambient Operating Calculations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Thermal Vias . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
355
355
356
357
358
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 359
Little-endian Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 359
Typical Applications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 363
E.1
E.2
E.3
E.4
E.5
F.
340
342
347
347
347
348
350
350
350
352
Endian Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 359
D.1
D.2
E.
B.3.1
Coupled Cycles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
B.3.2
Decoupled Cycles. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
DMA Channel and Relative FIFO Sizes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
B.4.1
VMEbus Ownership Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
B.4.2
VME Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
B.4.3
PCI Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Universe II Specific Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
B.5.1
Overview of the U2SPEC Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
B.5.2
Adjustable VME Timing Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Performance Summary. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Reliability Prediction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 355
C.1
C.2
C.3
C.4
C.5
D.
7
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VME Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
E.2.1
Transceivers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
E.2.2
Direction control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
E.2.3
Power-up Options. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PCI Bus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
E.3.1
Resets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
E.3.2
Local Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Manufacturing Test Pins. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Decoupling VDD and VSS on the Universe II . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
363
363
363
367
367
368
369
370
370
371
Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 373
F.1
Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 373
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Universe II Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Universe II In Single Board Computer Application . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Universe II Data Flow Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
VMEbus Slave Channel Dataflow. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Timing for Auto-ID Cycle. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
PCI Bus Target Channel Dataflow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
Register Fields for the Special Cycle Generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
Address Translation Mechanism for VMEbus to PCI Bus Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
Address Translation Mechanism for PCI Bus to VMEbus Transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
Memory Mapping in the Special PCI Target Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
Universe II Control and Status Register Space . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76
PCI Bus Access to UCSR as Memory or I/O Space . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77
UCSR Access from the VMEbus Register Access Image. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
UCSR Access in VMEbus CR/CSR Space . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
Direct Mode DMA transfers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
Command Packet Structure and Linked List Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97
DMA Linked List Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98
Universe Interrupt Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110
STATUS/ID Provided by Universe II . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115
Sources of Internal Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119
Reset Circuitry. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 133
Resistor-Capacitor Circuit Ensuring Power-Up Reset Duration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 134
Power-up Options Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 139
UCSR Access Mechanisms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 163
313 PBGA - Bottom View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 333
313 PBGA - Top and Side View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 334
Coupled Read Cycle - Universe II as VME Master . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 337
Several Coupled Read Cycles - Universe II as VME Master . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 337
Coupled Write Cycle - Universe II as VME Master . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 338
Several Non-Block Decoupled Writes - Universe II as VME Master. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 340
BLT Decoupled Write - Universe II as VME Master . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 340
Coupled Read Cycle - Universe II as VME Slave . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 341
Coupled Write Cycle - Universe II as VME Slave (bus parked at Universe II) . . . . . . . . . . . . . . . . . . . . . . . . . . 342
Non-Block Decoupled Write Cycle - Universe II as VME Slave . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 343
BLT Decoupled Write Cycle - Universe II as VME Slave . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 344
MBLT Decoupled Write Cycle - Universe II as VME Slave . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 344
BLT Pre-fetched Read Cycle - Universe II as VME Slave . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 346
PCI Read Transactions During DMA Operation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 349
Multiple PCI Read Transactions During DMA Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 349
Universe II Connections to the VMEbus Through TTL Buffers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 364
Universe II Connections to the VMEbus Through TTL Buffers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 365
Power-up Configuration Using Passive Pull-ups . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 368
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Figures
Power-up Configuration Using Active Circuitry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 368
Analog Isolation Scheme . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 371
Noise Filter Scheme . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 371
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VMEbus Address Modifier Codes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
PCI Address Line Asserted as a Function of VA[15:11] . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39
Command Type Encoding for Transfer Type . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
VMEbus Fields for VMEbus Slave Image. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67
PCI Bus Fields for VMEbus Slave Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
Control Fields for VMEbus Slave Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68
PCI Bus Fields for the PCI Bus Target Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
VMEbus Fields for the PCI Bus Target Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
Control Fields for PCI Bus Target Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
PCI Bus Fields for the Special PCI Target Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
VMEbus Fields for the Special PCI Bus Target Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
Control Fields for the Special PCI Bus Target Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
Programming the VMEbus Register Access Image . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
VON Settings for Non-Inc Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
DMA Interrupt Sources and Enable Bits . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104
Source, Enabling, Mapping, and Status of PCI Interrupt Output. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
Source, Enabling, Mapping, and Status of VMEbus Interrupt Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 114
Internal Interrupt Routing. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118
Hardware Reset Mechanisms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 129
Software Reset Mechanism . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 130
Functions Affected by Reset Initiators. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
Power-Up Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135
VRAI Base Address Power-up Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
Manufacturing Pin Requirements for Normal Operating Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 140
Test Mode Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
VMEbus Signals. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 144
PCI Bus Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 147
Non-PCI Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 153
AC/DC PCI Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 154
Pin List and DC Characteristics for Universe II Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155
Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160
Absolute Maximum Ratings. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161
Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161
Universe II Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 164
Power-up Option Behavior of the VAS field in VRAI_CTL. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 304
PCI Slave Channel Performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 352
VME Slave Channel Performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 352
DMA Channel Performance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 353
Ambient to Junction Thermal Impedance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 357
Maximum Universe II Junction Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 357
Thermal Characteristics of Universe II . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 358
Mapping of 32-bit Little-Endian PCI Bus to 32-bit VMEbus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 360
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Table 43:
Table 44:
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Table 46:
Table 47:
Tables
Mapping of 32-bit Little-Endian PCI Bus to 64-bit VMEbus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VMEbus Signal Drive Strength Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
VMEbus Transceiver Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Reset Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Standard Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
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About this Document
This section discusses the following topics:
•
“Scope” on page 13
•
“Document Conventions” on page 13
•
“Revision History” on page 15
Scope
The Universe IID/IIB User Manual discusses the features, capabilities, and configuration requirements
for the Universe II. It is intended for hardware and software engineers who are designing system
interconnect applications with the device.
Document Conventions
This document uses the following conventions.
Signal Notation
Signals are either active high or active low. Active low signals are defined as true (asserted) when they
are at a logic low. Similarly, active high signals are defined as true at a logic high. Signals are
considered asserted when active and negated when inactive, irrespective of voltage levels. For voltage
levels, the use of 0 indicates a low voltage while a 1 indicates a high voltage.
For voltage levels, the use of 0 indicates a low voltage while a 1 indicates a high voltage. For voltage
levels, the use of 0 indicates a low voltage while a 1 indicates a high voltage.
Each signal that assumes a logic low state when asserted is followed by an underscore sign, “_”. For
example, SIGNAL_ is asserted low to indicate an active low signal. Signals that are not followed by an
underscore are asserted when they assume the logic high state. For example, SIGNAL is asserted high
to indicate an active high signal.
The asterisk sign “*” is used in this manual to show that a signal is asserted low and that is used on the
on the VMEbus backplane. For example, SIGNAL* is asserted to low to indicate an active low signal
on the VMEbus backplane.
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About this Document
Object Size Notation
•
A byte is an 8-bit object.
•
A word is a 16-bit object.
•
A doubleword (Dword) is a 32-bit object.
•
A quadword is a 64-bit (8 byte) object.
•
A Kword is 1024 16-bit words.
Numeric Notation
•
Hexadecimal numbers are denoted by the prefix 0x (for example, 0x04).
•
Binary numbers are denoted by the prefix 0b (for example, 0b010).
•
Registers that have multiple iterations are denoted by {x..y} in their names; where x is first register
and address, and y is the last register and address. For example, REG{0..1} indicates there are two
versions of the register at different addresses: REG0 and REG1.
Symbols
Ti
This symbol indicates a basic design concept or information considered helpful.
p
This symbol indicates important configuration information or suggestions.
This symbol indicates procedures or operating levels that may result in misuse or damage to
the device.
Document Status Information
•
Advance – Contains information that is subject to change, and is available once prototypes are
released to customers.
•
Preliminary – Contains information about a product that is near production-ready, and is revised as
required.
•
Formal – Contains information about a final, customer-ready product, and is available once the
product is released to production.
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15
Revision History
May 12, 2010, Formal
This document fixed a number of minor typographical errors. No technical changes were made.
October 2009, Formal
This document was rebranded as IDT. No technical changes were made.
June 2009, Formal
There have been changes throughout the manual.
August 2007, Formal
There have been numerous edits throughout the manual. The formatting of the document has also been
updated.
November 2002, Formal
This document information applies to both the Universe IIB and the Universe IID devices. The
Universe IID is recommended for all new designs. For more information about the two devices, see the
Universe IID/IIB Differences Summary.
The following chapter was updated for the release of this manual:
•
“Reliability Prediction” on page 355
October 2002, Formal
This document information applies to both the Universe IIB and the Universe IID devices. The
Universe IID is recommended for all new designs. For more information about the two devices, see the
Universe IID/IIB Differences Summary.
There was an erratum found in the 361 DBGA package drawing.
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Universe II User Manual
May 12, 2010
About this Document
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�17
1.
Functional Overview
This chapter outlines the functionality of the Universe II. This chapter discusses the following topics:
1.1
•
“Overview” on page 17
•
“VMEbus Interface” on page 22
•
“PCI Bus Interface” on page 22
•
“Interrupter and Interrupt Handler” on page 23
•
“DMA Controller” on page 24
Overview
The IDT Universe II is the industry's leading high performance PCI-to-VMEbus interconnect.
Universe II is fully compliant with the VME64 bus standard, and tailored for the next-generation of
advanced PCI processors and peripherals. With a zero-wait state implementation, multi-beat
transactions, and support for bus-parking, Universe II provides high performance on the PCI bus.
The Universe II eases development of multi-master, multi-processor architectures on VMEbus and PCI
bus systems. The device is ideally suited for CPU boards functioning as both master and slave in the
VMEbus system, and that require access to PCI systems. Bridging is accomplished through a
decoupled architecture with independent FIFOs for inbound, outbound, and DMA traffic. With this
architecture, throughput is maximized without sacrificing bandwidth on either bus.
With the Universe II, you know that as your system becomes more complex, you have proven silicon
that continues to provide everything you need in a PCI-to-VME bridge.
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1. Functional Overview > Overview
Figure 1: Universe II Block Diagram
Four Location Monitors
To Support VMEbus
Broadcast Capability
Location
Monitor
Fixed Priority,
Round Robin,
Single Level Modes
VMEbus
Arbiter
32-bit Address / 64-bit Data
33 MHz PCI Bus
DMA Channel
Bidirectional FIFO
Direct/Linked List Mode
VMEbus Interface
PCI Interface
32-bit Address / 64-bit Data
33 MHz PCI Bus
VMEbus Slave Channel
Posted Writes, Prefetched Reads,
Coupled Reads
Register Channel
Configuraion Registers,
Mailbox Registers, Semaphores
Interrupt Channel
Interrupt Handler,
Interrupter
PCI Target Channel
Posted Writes, Coupled Read
JTAG
8091142_BK001_05
IEEE1149.1 Boundary Scan
1.1.1
Universe II Features
The Universe II has the following features:
•
Industry-proven, high performance 64-bit VMEbus interconnect
•
Fully compliant, 32-bit or 64-bit, 33 MHz PCI bus interconnect
•
Integral FIFOs for write posting to maximize bandwidth utilization
•
Programmable DMA controller with Linked-List mode (Scatter/Gather) support
•
Flexible interrupt logic
•
Sustained transfer rates up to 60-70 Mbytes/s
•
Extensive suite of VMEbus address and data transfer modes
•
Automatic initialization for slave-only applications
•
Flexible register set, programmable from both the PCI bus and VMEbus ports
•
Full VMEbus system controller
•
Support for RMWs, ADOH, PCI LOCK_ cycles, and semaphores
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•
Commercial, industrial, and extended temperature variants
•
IEEE 1149.1 JTAG
•
Available packaging:
19
— 35mm x 35mm, 313-contact plastic BGA (PBGA) package
1.1.2
Universe II Benefits
The Universe II offers the following benefits to designers:
1.1.3
•
Industry proven device
•
Reliable customer support with experience in hundreds of customer designs
Universe II Typical Applications
The Universe II is targeted at today’s technology demands, such as the following:
1.1.3.1
•
Single-board computers
•
Telecommunications equipment
•
Test equipment
•
Command and control systems
•
Factory automation equipment
•
Medical equipment
•
Military
•
Aerospace
Typical Application Example: Single Board Computers
The Universe II is widely used on VME-based Single Board Computers (SBC) that employ PCI as
their local bus and VME as the backplane bus, as shown in the accompanying diagram. These SBC
cards support a variety of applications including telecom, datacom, medical, industrial, and military
equipment.
The Universe II high performance architecture seamlessly bridges the PCI and VME busses, and is the
VME industry's standard for single board computer interconnect device.
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1. Functional Overview > Main Interfaces
Figure 2: Universe II In Single Board Computer Application
PMC
Connection
Memory
Processor
Processor Bus
Processorto-PCI Bridge
PCI Bus
32-bit/64-bit Data
33 MHz
I/O
Controller
Universe II
64-bit Data
VMEbus
1.2
8091142_TA001_02
Main Interfaces
The Universe II has two main interfaces: the PCI Bus Interface and the VMEbus Interface. Each of the
interfaces, VMEbus and PCI bus, there are three functionally distinct modules: master module, slave
module, and interrupt module. These modules are connected to the different functional channels
operating in the
Universe II. The device had the following channels:
•
VMEbus Slave Channel
•
PCI Bus Target Channel
•
DMA Channel
•
Interrupt Channel
•
Register Channel
Figure 3 shows the Universe II in terms of the different modules and channels.
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�1. Functional Overview > Main Interfaces
21
Figure 3: Universe II Data Flow Diagram
DMA Channel
PCI Bus
Interface
DMA bidirectional FIFO
VMEbus
Interface
VMEbus Slave Channel
PCI
Master
posted writes FIFO
prefetch read FIFO
coupled read
VME
Slave
PCI Bus Slave Channel
PCI
BUS
PCI
Slave
posted writes FIFO
coupled read logic
VME
Master
VMEbus
Interrupt Channel
PCI
Interrupts
Interrupt Handler
Interrupter
VME
Interrupts
8091142_BK001_01
Register Channel
Mailbox Registers
Semaphores
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1.2.1
1. Functional Overview > Main Interfaces
VMEbus Interface
The VME Interface is a VME64 Specification compliant interface.
1.2.1.1
Universe II as VMEbus Slave
The Universe II VMEbus Slave Channel accepts all of the addressing and data transfer modes
documented in the VME64 Specification - except A64 and those intended to augment 3U applications.
Incoming write transactions from the VMEbus can be treated as either coupled or posted, depending
upon the programming of the VMEbus slave image (see “VME Slave Image Programming” on
page 67). With posted write transactions, data is written to a Posted Write Receive FIFO (RXFIFO),
and the VMEbus master receives data acknowledgment from the Universe II. Write data is transferred
to the PCI resource from the RXFIFO without the involvement of the initiating VMEbus master (see
“Posted Writes” on page 33 for a full explanation of this operation). With a coupled cycle, the VMEbus
master only receives data acknowledgment when the transaction is complete on the PCI bus. This
means that the VMEbus is unavailable to other masters while the PCI bus transaction is executed.
Read transactions may be either prefetched or coupled. A prefetched read is initiated when a VMEbus
master requests a block read transaction (BLT or MBLT) and this mode is enabled. When the Universe
II receives the block read request, it begins to fill its Read Data FIFO (RDFIFO) using burst
transactions from the PCI resource. The initiating VMEbus master then acquires its block read data
from the RDFIFO instead of directly from the PCI resources.
As VMEbus slave, the Universe II does not assert RETRY* as a termination of the
transaction.
1.2.1.2
Universe II as VMEbus Master
The Universe II becomes VMEbus master when the VMEbus Master Interface is internally requested
by the PCI Bus Target Channel, the DMA Channel, or the Interrupt Channel. The Interrupt Channel
always has priority over the other two channels. Several mechanisms are available to configure the
relative priority that the PCI Bus Target Channel and DMA Channel have over ownership of the
VMEbus Master Interface.
The Universe II’s VMEbus Master Interface generates all of the addressing and data transfer modes
documented in the VME64 Specification - except A64 and those intended to augment 3U applications.
The Universe II is also compatible with all VMEbus modules conforming to pre-VME64
specifications.
As VMEbus master, the Universe II supports Read-Modify-Write (RMW), and
Address-Only-with-Handshake (ADOH) but does not accept RETRY* as a termination from the
VMEbus slave. The ADOH cycle is used to implement the VMEbus Lock command allowing a PCI
master to lock VMEbus resources.
1.2.2
PCI Bus Interface
The PCI Interface is a PCI 2.1 Specification compliant interface
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1.2.2.1
23
Universe II as PCI Target
Read transactions from the PCI bus are always processed as coupled transactions. Write transactions
can be either coupled or posted, depending upon the setting of the PCI bus target image (see “PCI Bus
Target Images” on page 70). With a posted write transaction, write data is written to a Posted Write
Transmit FIFO (TXFIFO) and the PCI bus master receives data acknowledgment from the Universe II
with zero wait-states. Meanwhile, the Universe II obtains the VMEbus and writes the data to the
VMEbus resource independent of the initiating PCI master (see “Posted Writes” on page 60 for a full
description of this operation).
The Universe II has a Special Cycle Generator that enables PCI masters to perform RMW and ADOH
cycles. The Special Cycle Generator must be used in combination with a VMEbus ownership function
to guarantee PCI masters exclusive access to VMEbus resources over several VMEbus transactions
(see “Special Cycle Generator” on page 61 and “Using the VOWN bit” on page 64 for a full
description of this functionality).
1.2.2.2
Universe II as PCI Master
The Universe II becomes PCI master when the PCI Master Interface is internally requested by the
VMEbus Slave Channel or the DMA Channel. There are mechanisms provided which allow the user to
configure the relative priority of the VMEbus Slave Channel and the DMA Channel.
1.2.3
Interrupter and Interrupt Handler
The Universe II has both interrupt generation and interrupt handling capability.
1.2.3.1
Interrupter
The Universe II Interrupt Channel provides a flexible scheme to map interrupts to the PCI bus or
VMEbus Interface. Interrupts are generated from hardware or software sources (see “Interrupt
Generation” on page 111 and “Interrupt Handling” on page 116 for a full description of hardware and
software sources). Interrupt sources can be mapped to any of the PCI bus or VMEbus interrupt output
pins. Interrupt sources mapped to VMEbus interrupts are generated on the VMEbus interrupt output
pins VIRQ_ [7:1]. When a software and hardware source are assigned to the same VIRQ_ pin, the
software source always has higher priority.
Interrupt sources mapped to PCI bus interrupts are generated on one of the INT_ [7:0] pins. To be fully
PCI compliant, all interrupt sources must be routed to a single INT_ pin.
For VMEbus interrupt outputs, the Universe II interrupter supplies an 8-bit STATUS/ID to a VMEbus
interrupt handler during the IACK cycle. The interrupter also generates an internal interrupt in this
situation if the SW_IACK bit, in the PCI Interrupt Status (LINT_STAT) register, is set to 1 (see
“VMEbus Interrupt Generation” on page 113).
Interrupts mapped to PCI bus outputs are serviced by the PCI interrupt controller. The CPU determines
which interrupt sources are active by reading an interrupt status register in the Universe II. The source
negates its interrupt when it has been serviced by the CPU (see “PCI Interrupt Generation” on
page 111).
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1.2.3.2
1. Functional Overview > Main Interfaces
VMEbus Interrupt Handling
A VMEbus interrupt triggers the Universe II to generate a normal VMEbus IACK cycle and generate
the specified interrupt output. When the IACK cycle is complete, the Universe II releases the VMEbus
and the interrupt vector is read by the PCI resource servicing the interrupt output. Software interrupts
are ROAK, while hardware, and internal interrupts are RORA.
1.2.4
DMA Controller
The Universe II has an internal DMA controller for high performance data transfer between the PCI
and VMEbus. DMA operations between the source and destination bus are decoupled through the use
of a single bidirectional FIFO (DMAFIFO). Parameters for the DMA transfer are software
configurable in the Universe II registers (see “DMA Controller” on page 85).
The principal mechanism for DMA transfers is the same for operations in either direction
(PCI-to-VMEbus, or VMEbus-to-PCI), only the relative identity of the source and destination bus
changes. In a DMA transfer, the Universe II gains control of the source bus and reads data into its
DMAFIFO. Following specific rules of DMAFIFO operation (see “FIFO Operation and Bus
Ownership” on page 101), it then acquires the destination bus and writes data from its DMAFIFO.
The DMA controller can be programmed to perform multiple blocks of transfers using linked-list
mode. The DMA works through the transfers in the linked-list following pointers at the end of each
linked-list entry. Linked-list operation is initiated through a pointer in an internal Universe II register,
but the linked-list itself resides in PCI bus memory.
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2.
VMEbus Interface
This chapter explains the operation of the VMEbus Interface.This chapter discusses the following
topics:
2.1
•
“VMEbus Requester” on page 25
•
“Universe II as VMEbus Master” on page 28
•
“Universe II as VMEbus Slave” on page 32
•
“VMEbus Configuration” on page 41
•
“Automatic Slot Identification” on page 42
•
“System Clock Driver” on page 44
Overview
The VMEbus Interface incorporates all operations associated with the VMEbus. This includes master
and slave functions, VMEbus configuration and system controller functions.
2.2
VMEbus Requester
There are different channels in the Universe II which require the use of the VMEbus. They are referred
to as VMEbus requesters and are described in the following sections.
2.2.1
Internal Arbitration for VMEbus Requests
Different internal channels within the Universe II require use of the VMEbus: the Interrupt Channel,
the PCI Target Channel, and the DMA Channel. These three channels do not directly request the
VMEbus, instead they compete internally for ownership of the VMEbus Master Interface.
2.2.1.1
Interrupt Channel
The Interrupt Channel always has the highest priority for access to the VMEbus Master Interface (see
Figure 3 on page 21). The DMA and PCI Target Channel requests are handled in a fair manner. The
channel awarded VMEbus mastership maintains ownership of the VMEbus until it is has completed the
transaction. The definition of a complete transaction for each channel is in “VMEbus Release” on
page 27.
The Interrupt Channel requests the VMEbus master when it detects an enabled VMEbus interrupt line
asserted and must run an interrupt acknowledge cycle to acquire the STATUS/ID.
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2.2.1.2
2. VMEbus Interface > VMEbus Requester
PCI Target Channel
The PCI Target Channel requests the VMEbus Master Interface to service the following conditions:
2.2.1.3
•
TXFIFO contains a complete transaction
•
A coupled cycle request
DMA Channel
The DMA Channel requests the VMEbus Master Interface in the following instances:
•
The DMAFIFO has 64 bytes available (if it is reading from the VMEbus) or 64 bytes in its FIFO (if
it is writing to the VMEbus)
•
The DMA block is complete (see “DMA Controller” on page 85).
In the case of the DMA Channel, the DMA Channel VMEbus-off-timer can be used to further qualify
requests from this channel. The VMEbus-off-timer controls how long the DMA remains off the
VMEbus before making another request (see “PCI-to-VMEbus Transfers” on page 101).
The Universe II provides a software mechanism for VMEbus acquisition through the VMEbus
ownership bit (VOWN in the “Master Control Register (MAST_CTL)” on page 271). When the
VMEbus ownership bit is set, the Universe II acquires the VMEbus and sets an acknowledgment bit
(VOWN_ACK in the MAST_CTL register) and optionally generates an interrupt to the PCI bus (see
“VME Lock Cycles—Exclusive Access to VMEbus Resources” on page 63). The Universe II
maintains VMEbus ownership until the ownership bit is cleared. During the VMEbus tenure initiated
by setting the ownership bit, only the PCI Target Channel and Interrupt Channel can access the
VMEbus Master Interface.
2.2.2
Request Modes
The Universe II has configurable request modes of operation.
2.2.2.1
Request Levels
The Universe II is software configurable to request on any one of the four VMEbus request levels:
BR3*, BR2*, BR1*, and BR0*. The default setting is for level 3 VMEbus request. The request level is
a global programming option set through the VMEbus Release Mode (VRL) field in the “Master
Control Register (MAST_CTL)” on page 271. The programmed request level is used by the VMEbus
Master Interface regardless of the channel (Interrupt Channel, DMA Channel, or PCI Target Channel)
currently accessing the VMEbus Master Interface.
2.2.2.2
Fair and Demand Modes
The Universe II requester can be programmed for either Fair or Demand mode. The request mode is a
global programming option set through the VMEbus Request Mode (VRM) bits in the “Master Control
Register (MAST_CTL)” on page 271.
In Fair mode, the Universe II does not request the VMEbus until there are no other VMEbus requests
pending at its programmed level. This mode ensures that every requester on an equal level has access
to the bus.
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27
In the default setting of Demand mode, the requester asserts its bus request regardless of the state of the
BRn* line. By requesting the bus frequently, requesters far down the daisy chain may be prevented
from ever obtaining bus ownership. This is referred to as starving those requesters. Note that in order to
achieve fairness, all bus requesters in a VMEbus system must be set to fair mode.
2.2.3
VMEbus Release
The Universe II VMEbus requester can be configured as either RWD (release when done) or ROR
(release on request) using the VREL bit in the “Master Control Register (MAST_CTL)” on page 271.
The default setting is for RWD. ROR means the Universe II releases BBSY* only if a bus request is
pending from another VMEbus master and once the channel that is the current owner of the VMEbus
Master Interface is done. Ownership of the bus can be assumed by another channel without
re-arbitration on the bus if there are no pending requests on any level on the VMEbus. When set for
RWD, the VMEbus Master Interface releases BBSY* when the channel accessing the VMEbus Master
Interface is done (see below). Note that the MYBBSY status bit in the “Miscellaneous Status Register
(MISC_STAT)” on page 275 is 0 when the Universe II asserts BBSY*.
In RWD mode, the VMEbus is released when the channel (for example, the DMA Channel) is done,
even if another channel has a request pending (for example, the PCI Target Channel). A re-arbitration
of the VMEbus is required for any pending channel requests. Each channel has a set of rules that
determine when it is ‘done’ with its VMEbus transaction.
2.2.3.1
Transaction Complete
The interrupt is complete when a single interrupt acknowledge cycle is complete.
The PCI Target Channel is complete under the following conditions:
•
when the TXFIFO is empty, the TXFE bit is clear (the TXFE bit is set by the Universe II in the
MISC_STAT register,
•
when the maximum number of bytes per PCI Target Channel tenure has been reached (as
programmed with the PWON field in the “Master Control Register (MAST_CTL)” on page 2711,
•
after each posted write, if the PWON is equal to 0b1111, as programmed in the MAST_CTL
register
•
when the coupled cycle is complete and the Coupled Window Timer has expired,
•
if the Coupled Request Timer (page 58) expires before a coupled cycle is retried by a PCI master,
or
•
when VMEbus ownership is acquired with the VOWN bit in the MAST_CTL register and then the
VOWN bit is cleared (in other words, if the VMEbus is acquired through the use of the VOWN bit,
the Universe II does not release BBSY* until the VOWN bit is cleared—see “VME Lock
Cycles—Exclusive Access to VMEbus Resources” on page 63).
The DMA Channel is complete under the following conditions:
•
DMAFIFO full during VMEbus to PCI bus transfers,
•
DMAFIFO empty during PCI bus to VMEbus transfers,
1. This setting is overridden if the VOWN mechanism is used.
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2. VMEbus Interface > Universe II as VMEbus Master
•
if an error is encountered during the DMA operation,
•
the DMA VMEbus Tenure Byte Counter has expired, or
•
DMA block is complete.
Refer to “FIFO Operation and Bus Ownership” on page 101 and “DMA Error Handling” on page 105
for more information.
Universe II ownership of the VMEbus is not affected by the assertion of BCLR* because it does not
monitor BCLR*.
2.3
Universe II as VMEbus Master
The Universe II becomes VMEbus master under the following circumstances:
1. PCI master accesses a Universe II PCI target image (leading to VMEbus access) or the DMA
Channel initiates a transaction,
2. Either the Universe II PCI Target Channel or the DMA Channel wins access to the VMEbus
Master Interface through internal arbitration
3. Universe II Master Interface requests and obtains ownership of the VMEbus
The Universe II also becomes VMEbus master if the VMEbus ownership bit is set (see “VME Lock
Cycles—Exclusive Access to VMEbus Resources” on page 63) and in its role in VMEbus interrupt
handling (see “VMEbus Interrupt Handling” on page 116).
The following sections describe the function of the Universe II as a VMEbus master in terms of the
different phases of a VMEbus transaction: addressing, data transfer, cycle termination, and bus release.
2.3.1
Addressing Capabilities
Depending upon the programming of the PCI target image (see “PCI Bus Target Images” on page 70),
the Universe II generates A16, A24, A32, and CR/CSR address phases on the VMEbus. The address
mode and type (supervisor/non-privileged and program/data) are also programmed through the PCI
target image. Address pipelining is provided, except during MBLT cycles. The VMEbus Specification
does not permit pipelining during MBLT cycles.
The address and Address Modifier (AM) codes that are generated by the Universe II are functions of
the PCI address and PCI target image programming (see “PCI Bus Target Images” on page 70) or
through DMA programming. Table 1 shows the AM codes used for the VMEbus.
Table 1: VMEbus Address Modifier Codes
Address Modifier
Address Bits
0x3F
24
A24 supervisory block transfer (BLT)
0x3E
24
A24 supervisory program access
0x3D
24
A24 supervisory data access
0x3C
24
A24 supervisory 64-bit block transfer (MBLT)
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29
Table 1: VMEbus Address Modifier Codes
Address Modifier
Address Bits
0x3B
24
A24 non-privileged block transfer (BLT)
0x3A
24
A24 non-privileged program access
0x39
24
A24 non-privileged data access
0x38
24
A24 non-privileged 64-bit block transfer (MBLT)
0x37
40
A40BLT [MD32]
0x35
40
A40 lock command (LCK)
0x34
40
A40 access
0x32
24
A24 lock command
0x2F
24
CR/CSR
0x2D
16
A16 supervisory access
0x2C
16
A16 lock command
0x29
16
A16 non-privileged access
0x21
32 or 40
2eVME for 3U bus modules (address size in XAM code)
0x20
32 or 40
2eVME for 6U bus modules (address size in XAM code)
0x10 - 0x1F
Undefined
0xF
32
A32 supervisory block transfer (BLT)
0xE
32
A32 supervisory program access
0xD
32
A32 supervisory data access
0xC
32
A32 supervisory 64-bit block transfer (MBLT)
0xB
32
A32 non-privileged block transfer (BLT)
0xA
32
A32 non-privileged program access
0x9
32
A32 non-privileged data access
0x8
32
A32 non-privileged 64-bit block transfer (MBLT)
0x5
32
A32 lock command
0x4
64
A64 lock command
0x3
64
A64 block transfer (BLT)
0x1
64
A64 single transfer access
0x0
64
A64 64-bit block transfer (MBLT)
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2. VMEbus Interface > Universe II as VMEbus Master
The Universe II generates Address-Only-with-Handshake (ADOH) cycles in support of lock
commands for A16, A24, and A32 spaces. ADOH cycles can only be generated through the Special
Cycle Generator (see “Special Cycle Generator” on page 61).
There are two User Defined AM codes that can be programmed through the “User AM Codes Register
(USER_AM)” on page 276. The USER_AM register can only be used to generate and accept AM
codes 0x10 through 0x1F. The default USER_AM code is 0x10. These AM codes are designated as
USERAM codes in the VMEbus Specification. After power-up, the two values in the USER_AM
register default to the same VME64 User-defined AM code.
If USER_AM code is used with the VMEbus Slave Interface, the cycles must use 32-bit
addressing, and only single cycle accesses are used. BLTs and MBLTs with USER_AM codes
will lead to unpredictable behavior.
2.3.2
Data Transfer Capabilities
PCI and VMEbus protocols have different data transfer capabilities. The maximum data width for a
VMEbus data transfer is programmed with the VMEbus Maximum Datawidth (VDW) field in the “PCI
Target Image 0 Control (LSI0_CTL)” on page 181. For example, consider a 32-bit PCI transaction
accessing a PCI target image with VDW set to 16 bits. A data beat with all byte lanes enabled will be
broken into two 16-bit cycles on the VMEbus. If the PCI target image is also programmed with block
transfers enabled, the 32-bit PCI data beat will result in a D16 block transfer on the VMEbus. Write
data is unpacked to the VMEbus and read data is packed to the PCI bus data width.
If the data width of the PCI data beat is the same as the maximum data width of the PCI target image,
then the Universe II maps the data beat to an equivalent VMEbus cycle. For example, consider a 32-bit
PCI transaction accessing a PCI target image with VDW set to 32 bits. A data beat with all byte lanes
enabled is translated to a single 32-bit cycle on the VMEbus.
As the general rule, if the PCI bus data width is less than the VMEbus data width then there is no
packing or unpacking between the two buses. The only exception to this is during 32-bit PCI multi-data
beat transactions to a PCI target image programmed with maximum VMEbus data width of 64 bits. In
this case, packing/unpacking occurs to make maximum use of the full bandwidth on both buses.
Only aligned VMEbus transactions are generated, so if the requested PCI data beat has unaligned, or
non-, byte enables, then it is broken into multiple aligned VMEbus transactions no wider than the
programmed VMEbus data width. For example, consider a three-byte PCI data beat (on a 32-bit PCI
bus) accessing a PCI target image with VDW set to 16 bits. The three-byte PCI data beat is broken into
three aligned VMEbus cycles: three single-byte cycle (the ordering of the cycles depends on the
arrangement of the byte enables in the PCI data beat). If in the above example the PCI target image has
a VDW set to 8-bit, then the three-byte PCI data beat is broken into three single-byte VMEbus cycles.
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31
BLT/MBLT cycles are initiated on the VMEbus if the PCI target image has been programmed with this
capacity (see “PCI Bus Target Images” on page 70). The length of the BLT/MBLT transactions on the
VMEbus is determined by the initiating PCI transaction. For example, a single data beat PCI
transaction queued in the TXFIFO results in a single data beat block transfer on the VMEbus. With the
PWON field, the user can specify a transfer byte count that is queued from the TXFIFO before the
VMEbus Master Interface relinquishes the VMEbus. The PWON field specifies the minimum tenure of
the Universe II on the VMEbus. However, tenure is extended if the VOWN bit in the MAST_CTL
register is set (see “Using the VOWN bit” on page 64).
During DMA operations, the Universe II attempts block transfers to the maximum length permitted by
the VMEbus specification (256 bytes for BLT, 2 Kbytes for MBLT) and is limited by the VON counter
(see “DMA VMEbus Ownership” on page 91).
The Universe II provides indivisible transactions with the VMEbus lock commands and the VMEbus
ownership bit (see “VME Lock Cycles—Exclusive Access to VMEbus Resources” on page 63).
2.3.3
Cycle Terminations
The Universe II accepts BERR* or DTACK* as cycle terminations from the VMEbus slave. It does not
support RETRY*. The assertion of BERR* indicates that some type of system error occurred and the
transaction did not complete properly. The assertion of BERR* during an IACK also causes the error to
be logged.
A VMEbus BERR* received by the Universe II during a coupled transaction is communicated to the
PCI master as a Target-Abort. No information is logged if the Universe II receives BERR* in a coupled
transaction. If an error occurs during a posted write to the VMEbus or during an IACK cycle, the
Universe II uses the “VMEbus AM Code Error Log (V_AMERR)” on page 307 to log the AM code of
the transaction (AMERR [5:0]), and the state of the IACK* signal (IACK bit, to indicate whether the
error occurred during an IACK cycle). The current transaction in the FIFO is purged. The V_AMERR
register also records if multiple errors have occurred (with the M_ERR bit), although the actual number
of errors is not given. The error log is qualified by the value of the V_STAT bit. The address of the
errored transaction is latched in the “VMEbus Address Error Log (VAERR)” on page 308. When the
Universe II receives a VMEbus error during a posted write, it generates an interrupt on the VMEbus
and/or PCI bus depending upon whether the VERR and LERR interrupts are enabled (see “Interrupt
Handling” on page 116).
DTACK* signals the successful completion of the transaction.
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2.4
2. VMEbus Interface > Universe II as VMEbus Slave
Universe II as VMEbus Slave
This section describes the VMEbus Slave Channel and other aspects of the
Universe II as VMEbus slave.
The Universe II becomes VMEbus slave when one of its eight programmed slave images or register
images are accessed by a VMEbus master. Depending upon the programming of the slave image,
different possible transaction types can result (see “VME Slave Image Programming” on page 67).
The Universe II cannot reflect a cycle on the VMEbus and access itself.
For reads, the transaction can be coupled or prefetched. Write transactions can be coupled or posted.
The type of read or write transaction allowed by the slave image depends on the programming of that
particular VMEbus slave image (see Figure 4 and “VME Slave Image Programming” on page 67). To
ensure sequential consistency, prefetched reads, coupled reads, and coupled write operations are only
processed once all previously posted write operations have completed (the RXFIFO is empty).
Figure 4: VMEbus Slave Channel Dataflow
PREFETCHED READ DATA
RDFIFO
PCI BUS
MASTER
INTERFACE
COUPLED READ DATA
COUPLED WRITE DATA
VMEbus
SLAVE
INTERFACE
POSTED WRITE DATA
RXFIFO
Incoming cycles from the VMEbus can have data widths of 8-bit, 16-bit, 32-bit, and 64-bit. Although
the PCI bus supports only two port sizes (32-bit and 64-bit), the byte lanes on the PCI bus can be
individually enabled, which allows each type of VMEbus transaction to be directly mapped to the PCI
data bus.
In order for a VMEbus slave image to respond to an incoming cycle, the PCI Master Interface
must be enabled by setting the bit BM in the “PCI Configuration Space Control and Status
Register (PCI_CSR)” on page 172. If data is queued in the VMEbus Slave Channel FIFO and
the BM bit is cleared, the FIFO empties but no additional transfers are received.
2.4.1
Coupled Transfers
A coupled transfer means that no FIFO is involved in the transaction and handshakes are relayed
directly through the Universe II. Coupled mode is the default setting for the VMEbus slave images.
Coupled transfers only proceed once all posted write entries in the RXFIFO have completed
(see “Posted Writes” on page 33).
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A coupled cycle with multiple data beats (such as block transfers) on the VMEbus side is always
mapped to single data beat transactions on the PCI bus, where each data beat on the VMEbus is
mapped to a single data beat transaction on the PCI bus regardless of data beat size. No packing or
unpacking is performed. The only exception to this is when a D64 VMEbus transaction is mapped to
D32 on the PCI bus. The data width of the PCI bus depends on the programming of the VMEbus slave
image (32-bit or 64-bit, see “VME Slave Image Programming” on page 67). The Universe II enables
the appropriate byte lanes on the PCI bus as required by the VMEbus transaction. For example, a
VMEbus slave image programmed to generate 32-bit transactions on the PCI bus is accessed by a
VMEbus D08 BLT read transaction (prefetching is not enabled in this slave image). The transaction is
mapped to single data beat 32-bit transfers on the PCI bus with only one byte lane enabled.
Target-Retry from a PCI target is not communicated to the VMEbus master. PCI transactions
terminated with Target-Abort or Master-Abort are terminated on the VMEbus with BERR*. The
Universe II sets the R_TA or R_MA bits in the “PCI Configuration Space Control and Status Register
(PCI_CSR)” on page 172 when it receives a Target-Abort or Master-Abort.
2.4.2
Posted Writes
A posted write involves the VMEbus master writing data into the Universe II’s RXFIFO, instead of
directly to the PCI address. Write transactions from the VMEbus are processed as posted if the PWEN
bit is set in the VMEbus slave image control register (see “VME Slave Image Programming” on
page 67). If the bit is cleared (default setting) the transaction bypasses the FIFO and is performed as a
coupled transfer. Incoming posted writes from the VMEbus are queued in the 64-entry deep RXFIFO.
Each entry in the RXFIFO can contain 32 address bits, or 64 data bits. Each incoming VMEbus address
phase, whether it is 16-bit, 24-bit, or 32-bit, constitutes a single entry in the RXFIFO and is followed
by subsequent data entries. The address entry contains the translated PCI address space and command
information mapping relevant to the particular VMEbus slave image that has been accessed (see “VME
Slave Image Programming” on page 67). For this reason, any reprogramming of VMEbus slave image
attributes are only reflected in RXFIFO entries queued after the reprogramming. Transactions queued
before the re-programming are delivered to the PCI bus with the VMEbus slave image attributes that
were in use before the reprogramming.
The RXFIFO is the same structure as the RDFIFO. The different names are used for the
FIFO’s two roles. In each FIFO, only one role, either the RXFIFO or the RDFIFO, can used
at one time.
2.4.2.1
FIFO Entries
Incoming non-block write transactions from the VMEbus require two entries in the RXFIFO: one
address entry (with accompanying command information) and one data entry. The size of the data entry
corresponds to the data width of the VMEbus transfer. Block transfers require at least two entries: one
entry for address and command information, and one or more data entries. The VMEbus Slave Channel
packs data received during block transfers to the full 64-bit width of the RXFIFO. For example, a ten
data phase D16 BLT transfer (20 bytes in total) does not require ten data entries in the RXFIFO.
Instead, eight of the ten data phases (16 bits per data phase for a total of 128 bits) are packed into two
64-bit data entries in the RXFIFO. The final two data phases (32 bits combined) are queued in the next
RXFIFO entry. When the address entry is added to the three data entries, this VMEbus block write has
been stored in a total of five RXFIFO entries.
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2. VMEbus Interface > Universe II as VMEbus Slave
Unlike the PCI Target Channel (see “Universe II as PCI Target”), the VMEbus Slave Channel does not
retry the VMEbus if the RXFIFO does not have enough space to hold an incoming VMEbus write
transaction. Instead, the DTACK* response from the VMEbus Slave Interface is delayed until space
becomes available in the RXFIFO. Since single transfers require two entries in the RXFIFO, two
entries must be available before the VMEbus Slave Interface asserts DTACK*. Similarly, the VMEbus
Slave Channel requires two available RXFIFO entries before it can acknowledge the first data phase of
a BLT or MBLT transfer (one entry for the address phase and one for the first data phase). If the
RXFIFO has no available space for subsequent data phases in the block transfer, then the VMEbus
Slave Interface delays assertion of DTACK* until a single entry is available for the next data phase in
the block transfer.
The PCI Master Interface uses transactions queued in the RXFIFO to generate transactions on the PCI
bus. No address phase deletion is performed, so the length of a transaction on the PCI bus corresponds
to the length of the queued VMEbus transaction. Non-block transfers are generated on the PCI bus as
single data beat transactions. Block transfers are generated as one or more burst transactions, where the
length of the burst transaction is programmed by the PABS field in the “Master Control Register
(MAST_CTL)” on page 271.
The Universe II always packs or unpacks data from the VMEbus transaction to the PCI bus data width
programmed into the VMEbus slave image (with all PCI bus byte lanes enabled). The data width for a
VMEbus transaction to the PCI bus is programmed in the LD64EN bit in the “VMEbus Slave Image 1
Control (VSI1_CTL)” on page 285. The LD64EN bit enables 64-bit PCI bus transactions For example,
consider a VMEbus slave image programmed for posted writes and a D32 PCI bus that is accessed with
a VMEbus D16 block write transaction. VMEbus D16 write transactions are mapped to D32 write
transactions on the PCI bus with all byte lanes enabled. (However, a single D16 transaction from the
VMEbus is mapped to the PCI bus as D32 with only two byte lanes enabled).
During block transfers, the Universe II packs data to the full negotiated width of the PCI bus. This may
imply that for block transfers that begin or end on addresses not aligned to the PCI bus width different
byte lanes may be enabled during each data beat.
2.4.2.2
Errors
If an error occurs during a posted write to the PCI bus, the Universe II uses the “PCI Command Error
Log Register (L_CMDERR)” on page 210 to log the command information for the transaction
(CMDERR [3:0]). The L_CMDERR register also records if multiple errors have occurred (with the
M_ERR bit) although the actual number of errors is not given. The error log is qualified with the
L_STAT bit. The address of the errored transaction is latched in the “PCI Address Error Log
(LAERR)” on page 211. An interrupt is generated on the VMEbus and/or PCI bus depending upon
whether the VERR and LERR interrupts are enabled (see “Error Handling” on page 125 and “Interrupt
Generation and Handling” on page 109).
2.4.3
Prefetched Block Reads
Prefetching of read data occurs for VMEbus block transfers (BLT, MBLT) in those slave images that
have the Prefetch Enable (PREN) bit set (see “VME Slave Image Programming” on page 67). In the
VMEbus Slave Channel, prefetching is not supported for
non- BLT/MBLT transfers.
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35
Without prefetching, block read transactions from a VMEbus master are handled by the VMEbus Slave
Channel as coupled reads. This means that each data phase of the block transfer is translated to a single
data beat transaction on the PCI bus. In addition, only the amount of data requested during the relevant
data phase is fetched from the PCI bus. For example, a D16 block read transaction with 32 data phases
on the VMEbus maps to 32 PCI bus transactions, where each PCI bus transaction has only two byte
lanes enabled.
The VMEbus lies idle during the arbitration time required for each PCI bus transaction,
resulting in a performance degradation.
With prefetching enabled, the VMEbus Slave Channel uses a 64-entry deep RDFIFO to provide read
data to the VMEbus with minimum latency. The RDFIFO is 64-bit, with additional bits for control
information. If a VMEbus slave image is programmed for prefetching (see “VME Slave Image
Programming” on page 67), then a block read access to that image causes the VMEbus Slave Channel
to generate aligned burst read transactions on the PCI bus (the size of the burst read transactions is
determined by the setting of the aligned burst size, PABS in the MAST_CTL register). These PCI burst
read transaction are queued in the RDFIFO and the data is then delivered to the VMEbus. The first data
phase provided to the VMEbus master is essentially a coupled read, but subsequent data phases in the
VMEbus block read are delivered from the RDFIFO and are decoupled (see “Prefetched Reads” on
page 127 for the impact on bus error handling).
The RXFIFO is the same structure as the RDFIFO. The different names are used for the
FIFO’s two roles. In each FIFO, only one role, either the RXFIFO or the RDFIFO, can used
at one time.
2.4.3.1
FIFO Entries
When there is a transactions from the Universe PCI Slave to the Universe VME Master, the data width
of the transaction on the PCI bus (32-bit or 64-bit) depends on the setting of the LD64EN bit in the
“VMEbus Slave Image 1 Control (VSI1_CTL)” on page 285 and the capabilities of the accessed PCI
target.
Internally, the prefetched read data is packed to 64-bit, regardless of the width of the PCI bus or the
data width of the original VMEbus block read (no address information is stored with the data). Once
one entry is queued in the RDFIFO, the VMEbus Slave Interface delivers the data to the VMEbus,
unpacking the data as necessary to fit with the data width of the original VMEbus block read (D16, or
D32).
The VMEbus Slave Interface continuously delivers data from the RDFIFO to the VMEbus master
performing the block read transaction. Because PCI bus data transfer rates exceed those of the
VMEbus, it is unlikely that the RDFIFO will be unable to deliver data to the VMEbus master. For this
reason, block read performance on the VMEbus is similar to that observed with block writes. However,
if the RDFIFO be unable to deliver data to the VMEbus master (which can happen if there is
considerable traffic on the PCI bus or the PCI bus target has a slow response) the VMEbus Slave
Interface delays DTACK* assertion until an entry is queued and is available for the VMEbus block
read.
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2. VMEbus Interface > Universe II as VMEbus Slave
On the PCI bus, prefetching continues as long as there is room for another transaction in the RDFIFO
and the initiating VMEbus block read is still active. The space required in the RDFIFO for another PCI
burst read transaction is determined by the setting of the PCI aligned burst size (PABS in the “Master
Control Register (MAST_CTL)” on page 271). If PABS is set for 32 bytes, there must be four entries
available in the RDFIFO; for aligned burst size set to 64 bytes, eight entries must be available, for
aligned burst size set to 128 bytes, there must be 16 entries available. When there is insufficient room
in the RDFIFO to hold another PCI burst read, the read transactions on the PCI bus are terminated and
only resume if room becomes available for another aligned burst and the original VMEbus block read
is still active. When the VMEbus block transfer terminates, any remaining data in the RDFIFO is
removed.
Reading on the PCI bus does not cross a 2048-byte boundary. The PCI Master Interface releases
FRAME_ and the VMEbus Slave Channel relinquishes internal ownership of the PCI Master Interface
when it reaches this boundary. The VMEbus Slave Channel re-requests internal ownership of the PCI
Master Interface as soon as possible, in order to continue reading from the external PCI target.
The PABS setting determines how much data must be available in the RDFIFO before the
VMEbus Slave Channel continues reading.
Regardless of the read request, the data width of prefetching on the PCI side is full width with all byte
lanes enabled. If LD64EN is set in the VMEbus Slave image, the Universe II requests D64 on the PCI
bus by asserting REQ64_ during the address phase. If the PCI target does not respond with ACK64_,
subsequent data beats are D32.
2.4.3.2
Errors
If an error occurs on the PCI bus, the Universe II does not translate the error condition into a BERR*
on the VMEbus; the Universe II does not directly map the error. By doing nothing, the Universe II
forces the external VMEbus error timer to expire.
2.4.4
VMEbus Lock Commands (ADOH Cycles)
The Universe II supports VMEbus lock commands as described in the VME64 Specification. Under the
specification, ADOH cycles are used to execute the lock command with a special AM code (see
Table 1 on page 28). The purpose of the Lock command is to lock the resources on a card so a master
on the card cannot modify the resource. Any resource locked on the VMEbus cannot be accessed by
any other resource during the bus tenure of the VMEbus master.
When the Universe II receives a VMEbus lock command, it asserts LOCK_ to the addressed resource
on the PCI bus. The PCI Master Interface processes this as a 32-bit read transfer with all byte lanes
enabled (no data). All subsequent slave VMEbus transactions are coupled while the Universe II owns
PCI LOCK_. The Universe II holds the PCI bus lock until the VMEbus lock command is terminated
(by negating BBSY*).
The VMEbus Slave Channel has dedicated access to the PCI Master Interface during the
locked transaction.
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37
The Universe II accepts ADOH cycles in any of the slave images when the
Universe II PCI Master Interface is enabled (BM bit in PCI_CSR register) and the images are
programmed to map transactions into PCI Memory Space.
2.4.4.1
Errors
If an error occurs on the PCI bus, a bus error will occur on the VMEbus because they are coupled. In
the event a bus error occurs on the VMEbus once a LOCK_ has been established, the VMEbus master
which locked the VMEbus must terminate the LOCK_ by negating BBSY*.
2.4.4.2
DMA Access
Once an external VMEbus masters locks the PCI bus, the Universe II DMA does not perform transfers
on the PCI bus until the bus is unlocked.
LOCK_ is negated on the PCI bus when AS* is negated on the VMEbus. LOCK_ is not
negated when AS* is negated if LOCK_ was asserted by an ADOH/lock command
2.4.5
VMEbus Read-Modify-Write Cycles (RMW Cycles)
A read-modify-write (RMW) cycle allows a VMEbus master to read from a VMEbus slave and then
write to the same resource without relinquishing bus tenure between the two operations. Each of the
Universe II slave images can be programmed to map RMW transactions to PCI locked transactions. If
the LLRMW enable bit is set in the selected “VMEbus Slave Image 1 Control (VSI1_CTL)” on
page 285), then every non-block slave read is mapped to a coupled PCI locked read. LOCK_ is held on
the PCI bus until AS* is negated on the VMEbus. Every non-block slave read is assumed to be a RMW
since there is no possible indication from the VMEbus master that the single cycle read is just a read or
the beginning of a RMW.
RMW cycles are not supported with unaligned or D24 cycles.
If the LLRMW enable bit is not set and the Universe II receives a VMEbus RMW cycle, the read and
write portions of the cycle are treated as independent transactions on the PCI bus (a read followed by a
write). The write can be coupled or decoupled depending on the state of the PWEN bit in the accessed
slave image.
There can be an adverse performance impact for reads that are processed through a
RMW-capable slave image This can be increased if LOCK_ is currently owned by another
PCI master.
When an external VMEbus Master begins a RMW cycle, at some point a read cycle appears on the PCI
bus. During the time between when the read cycle occurs on the PCI bus and when the associated write
cycle occurs on the PCI bus, no DMA transfers occurs on the PCI bus.
2.4.6
Register Accesses
See “Registers” on page 163 for a full description of register mapping and register access.
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2.4.7
2. VMEbus Interface > Universe II as VMEbus Slave
Location Monitors
Universe II has four location monitors to support a VMEbus broadcast capability. The location
monitors’ image is a 4-Kbyte image in A16, A24 or A32 space on the VMEbus. If enabled, an access to
a location monitor causes the PCI Master Interface to generate an interrupt.
The “Location Monitor Control Register (LM_CTL)” on page 300 controls the Universe II’s location
monitoring. The EN field of the LM_CTL register enables the capability. The PGM[1:0] field sets the
Program/Data AM code. The SUPER[1:0] field of the LM_CTL register sets the Supervisor/User AM
code to which the Universe II responds. The VAS[3:0] field of the LM_CTL register specifies the
address space that is monitored. The BS[31:12] field of the “Location Monitor Base Address Register
(LM_BS)” on page 302 specifies the lowest address in the 4 Kbyte range that is decoded as a location
monitor access. While the Universe II is has four location monitors, they all share the same LM_CTL
and LM_BS registers.
In address spaces A24 and A16, the respective upper address bits are ignored.
When an access to a location monitor is detected, an interrupt is generated on the PCI bus. VMEbus
address bits [4:3] determine which Location Monitor is used, and hence which of four PCI interrupts to
generate (see “Location Monitors” on page 122).
The location monitors do not store write data. Read data from the location monitors is undefined.
Location monitors do not support BLT or MBLT transfers.
Each Universe II on the VMEbus must be programmed to monitor the same 4 Kbytes of addresses on
the VMEbus. If the Universe II accesses its own (enabled) location monitor, the same Universe II
generates DTACK* on the VMEbus and terminates its own cycle. This removes the necessity of the
system integrator ensuring that there is another card enabled to generate DTACK*. The generation of
DTACK* happens after the Universe II has decoded and responded to the cycle. If the location monitor
is accessed by a different master, the Universe II does not respond with DTACK*.
2.4.8
Generating PCI Configuration Cycles
PCI Configuration cycles can be generated by accessing a VMEbus slave image whose Local Address
Space field (LAS) is set for Configuration Space.
ADOH, BLT and MBLT cycles must not be attempted when the LAS field of an image is
programmed for PCI Configuration Space.
PCI Configuration cycles can only be generated when the VAS field in the appropriate
VSIx_CTRL register is programmed for either A32, USER1, or USER2.
Both Type 0 and Type 1 cycles are generated and handled through the same mechanism. Once a
VMEbus cycle is received and mapped to a configuration cycle, the Universe II compares bits [23:16]
of the incoming address with the value stored in the Bus Number field (BUS_NO[7:0]) in the “Master
Control Register (MAST_CTL)” on page 271. If the bits are the same as the BUS_NO field, then a
TYPE 0 access is generated. If they are not the same, a Type 1 configuration access is generated. The
PCI bus-generated address then becomes an unsigned addition of the incoming VMEbus address and
the VMEbus slave image translation offset.
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2.4.8.1
39
Generating Configuration Type 0 Cycles
The Universe II asserts one of AD[31:11] on the PCI bus to select a device during a configuration Type
0 access. To perform a configuration Type 0 cycle on the PCI bus, the following steps must be
completed:
1. Program the LAS field of VSIx_CTL for Configuration Space
2. Program the VSIx_BS, VSIx_BD registers to some suitable value
3. Program the VSIx_TO register to 0
4. Program the BUS_NO field of the MAST_CTL register to some value
Perform a VMEbus access where:
•
VA[7:2] identifies the PCI Register Number and will be mapped directly to AD[7:2]
•
VA[10:8] identifies the PCI Function Number and will be mapped directly to AD[10:8]
•
VA[15:11] selects the device on the PCI bus and will be mapped to AD[31:12] according to Table 2
•
VA[23:16] matches the BUS_NO in MAST_CTL register
•
Other address bits are not important—they are not mapped to the PCI bus
Table 2: PCI Address Line Asserted as a Function of VA[15:11]
VA[15:11]a
PCI Address Line Assertedb
00000
11
00001
12
00010
13
00011
14
00100
15
00101
16
00110
17
00111
18
01000
19
01001
20
01010
21
01011
22
01100
23
01101
24
01110
25
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2. VMEbus Interface > Universe II as VMEbus Slave
Table 2: PCI Address Line Asserted as a Function of VA[15:11]
VA[15:11]a
PCI Address Line Assertedb
01111
26
10000
27
10001
28
10010
29
10011
30
10100
31
a. The other values of VA[15:11] are not defined and must not be
used.
b. Only one of AD[31:11] is asserted; the other address lines in
AD[31:11] are negated.
ADOH, BLT and MBLT cycles must not be attempted when the LAS of an image is
programmed to PCI Configuration space.
2.4.8.2
Generating Configuration Type 1 Cycles
The following steps are used to generate a configuration Type 1 cycle on the VMEbus:
1. Program LAS field of VSIx_CTL to Configuration Space
2. Program the VSIx_BS, VSIx_BD registers to some suitable value
3. Program the VSIx_TO register to 0
4. Program the BUS_NO field of the MAST_CTL register to some value
Perform a VMEbus access where:
•
VMEbus Address[7:2] identifies the PCI Register Number,
•
VMEbus Address[10:8] identifies the PCI Function Number,
•
VMEbus Address[15:11] identifies the PCI Device Number,
•
VMEbus Address[23:16] does not match the BUS_NO in MAST_CTL register, and
•
VMEbus Address[31:24] are mapped directly through to the PCI bus.
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2.5
41
VMEbus Configuration
The Universe II provides the following functions to assist in the initial configuration of the VMEbus
system:
2.5.1
•
First Slot Detector
•
Register Access at Power-up
•
Auto Slot ID (two methods)
First Slot Detector
As specified by the VME64 Specification the First Slot Detector module on the Universe II samples
BG3IN* immediately after reset to determine whether the Universe II’s host board resides in slot 1.
The VME64 Specification requires that BG[3:0]* lines be driven high after reset. This means that if a
card is preceded by another card in the VMEbus system, it always sample BG3IN* high after reset.
BG3IN* can only be sampled low after reset by the first card in the system — there is no preceding
card to drive BG3IN* high. If BG3IN* is sampled at logic low immediately after reset (due to the
Universe II’s internal pull-down), then the Universe II’s host board is in slot 1 and the Universe II
becomes SYSCON: otherwise, the SYSCON module is disabled.
This mechanism may be overridden by software through clearing or setting the SYSCON bit
in the “Miscellaneous Control Register (MISC_CTL)” on page 273.
The Universe II monitors IACK*, instead of IACKIN*, when it is configured as SYSCON. This
permits it to operate as SYSCON in a VMEbus chassis slot other than slot 1, provided there are only
empty slots to its left. The slot with SYSCON in it becomes a virtual slot 1.
2.5.2
VMEbus Register Access at Power-up
The Universe II provides a VMEbus slave image that allows access to all Universe II registers. The
base address for the slave image is programmed through the “VMEbus Register Access Image Base
Address Register (VRAI_BS)” on page 304. At power-up, the Universe II can program the VRAI_BS
and “VMEbus Register Access Image Control Register (VRAI_CTL)” on page 303 registers with
information specifying the Universe II Control/Status (UCSR) register slave image (see “Power-Up
Options” on page 135).
Register access at power-up is used in systems where the Universe II’s card has no CPU, or
where register access for that card needs to be independent of the local CPU.
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2.6
2. VMEbus Interface > Automatic Slot Identification
Automatic Slot Identification
The Universe II supports two types of Auto ID functionality. One type uses the Auto Slot ID technique
as described in the VME64 Specification. The other type uses a proprietary method developed by DY4
Systems and implemented in the IDT SCV64 and the Universe II. Neither system identifies
geographical addressing, only the relative position amongst the boards present in the system, for
example, fourth board versus fourth slot.
Both the VME64 Auto Slot ID and the DY4 method of automatic slot identification are
activated through a power-up option. Refer “Power-Up Options” on page 135 for more
information.
Auto ID prevents the need for jumpers to uniquely identify cards in a system. The benefits of this
feature are:
2.6.1
•
Increases the speed of system level repairs in the field
•
Reduces the possibility of incorrect configurations
•
Reduces the number of unique spare cards that must be stocked
Auto Slot ID: VME64 Specified
The VME64 Auto Slot ID cycle, as described in the VME64 Specification, requires at power-up that the
Auto ID slave takes the following actions:
•
Generate IRQ2*
•
Negate SYSFAIL*
When the Auto Slot ID slave responds to the Monarch’s IACK cycle, the following actions are taken:
1. Enable accesses to its CR/CSR space
2. Provide a Status/ID to the Monarch indicating the interrupt is an Auto-ID request
3. Assert DTACK*
4. Release IRQ2*
The Universe II participates in the VME64 Auto Slot ID cycle in either an automatic or semi-automatic
mode. In its fully automatic mode, it holds SYSFAIL* asserted until SYSRST* is negated. When
SYSRST* is negated, the Universe II asserts IRQ2* and releases SYSFAIL*. In its semi-automatic
mode, the Universe II still holds SYSFAIL* asserted until SYSRST* is negated. However, when
SYSRST* is negated, the local CPU performs diagnostics and local logic sets the AUTOID bit in the
“Miscellaneous Control Register (MISC_CTL)” on page 273. This asserts IRQ2* and releases
SYSFAIL*.
After SYSFAIL* is released and the Universe II detects a level 2 IACK cycle, it responds with the
STATUS/ID stored in its STATID register. The default value is 0xFE.
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The Universe II can be programmed so that it does not release SYSFAIL* until the SYSFAIL bit in the
“VMEbus CSR Bit Clear Register (VCSR_CLR)” on page 329 is cleared by local logic.
SYSFAIL* is asserted if the SYSFAIL bit in the “VMEbus CSR Bit Set Register
(VCSR_SET)” on page 330 is set at power-up.
Since the system Monarch does not service the Auto-ID slave until after SYSFAIL* is negated, not
clearing the SYSFAIL bit allows the Auto-ID process to be delayed until the CPU completes local
diagnostics. Once local diagnostics are complete, the CPU clears the SYSFAIL bit and the Auto Slot
ID cycle proceeds.
The Monarch can perform CR/CSR reads and writes at A[23:19]= 0x00 in CR/CSR space and re-locate
the Universe II’s CR/CSR base address.
2.6.1.1
Universe II and the Auto Slot ID Monarch
At power-up an Auto Slot ID Monarch waits to run a IACK cycle until after SYSFAIL* goes high.
After the IACK cycle is performed and it has received a Status/ID indicating an Auto Slot ID request,
the monarch software does the following:
1. Masks IRQ2*
— It will not service other interrupters at that interrupt level until current Auto Slot ID cycle is
completed
2. Performs an access at 0x00 in CR/CSR space to get information about Auto Slot ID slave
3. Moves the CR/CSR base address to a new location
4. Unmasks IRQ2* (to allow it to service the next Auto-ID slave)
The Universe II supports monarch activity through its capability to be a level 2 interrupt handler. All
other activity must be handled through software residing on the board.
2.6.2
Auto-ID: A Proprietary IDT Method
The Universe II uses a proprietary Auto-ID scheme when enabled through a power-up option (see
“Auto-ID” on page 137). The IDT proprietary Auto-ID function identifies the relative position of each
board in the system, without using jumpers or on-board information. The ID number generated by
Auto-ID can then be used to determine the board’s base address.
After any system reset (assertion of SYSRST*), the Auto-ID logic responds to the first level one IACK
cycle on the VMEbus.
After the level one IACK* signal has been asserted (either through IRQ1* or with a synthesized
version), the Universe II in slot 1 counts five clocks from the start of the cycle and then asserts
IACKOUT* to the second board in the system (see Figure 5). All other boards continue counting until
they receive IACKIN*, then count four more clocks and assert IACKOUT* to the next board. Finally,
the last board asserts IACKOUT* and the bus pauses until the data transfer time-out circuit ends the
bus cycle by asserting BERR*.
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2. VMEbus Interface > Automatic Slot Identification
Figure 5: Timing for Auto-ID Cycle
A
B
C
D
SYSCLK
AS*
DS0✴
IACK✴
IACKOUT✴
(CARD 1)
ID = 5
IACKOUT✴
(CARD 2)
ID = 9
IACKOUT✴
(CARD 3)
ID COUNTER
VALUE
ID = 13
0
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
Because all boards are four clocks wide, the value in the clock counter is divided by four to identify the
slot in which the board is installed; any remainder is discarded. Note that since the start of the IACK
cycle is not synchronized to SYSCLK, a one count variation from the theoretical value of the board can
occur. However, in all cases the ID value of a board is greater than that of a board in a lower slot
number. The result is placed in the DY4AUTOID [7:0] field and the DY4DONE bit is set located in the
“Miscellaneous Status Register (MISC_STAT)” on page 275.
2.6.3
System Controller Functions
When located in Slot 1 of the VMEbus system (see “First Slot Detector” on page 41), the Universe II
assumes the role of SYSCON and sets the SYSCON status bit in the MISC_CTL register. In
accordance with the VME64 Specification, as SYSCON the Universe II has the following functions:
2.6.3.1
•
A system clock driver
•
An arbitration module
•
An IACK Daisy Chain Driver (DCD)
•
A bus timer
System Clock Driver
The Universe II provides a 16 MHz SYSCLK signal derived from CLK64 when configured as
SYSCON.
2.6.3.2
VMEbus Arbiter
When the Universe II is SYSCON, the Arbitration Module is enabled. The Arbitration Module
supports the following arbitration modes:
•
Fixed Priority Arbitration Mode (PRI)
•
Round Robin Arbitration Mode (RRS) (default setting)
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These modes are selected with the VARB bit in the “Miscellaneous Status Register (MISC_STAT)” on
page 275.
2.6.3.3
Fixed Priority Arbitration Mode (PRI)
In this mode, the order of priority is VRBR_[3], VRBR_[2], VRBR_[1], and VRBR_[0] as defined by
the VME64 Specification. The Arbitration Module issues a Bus Grant (VBGO [3:0]_) to the highest
requesting level.
If a Bus Request of higher priority than the current bus owner is asserted, the Arbitration Module
asserts VBCLR_ until the owner releases the bus (VRBBSY_ is negated).
2.6.3.4
Round Robin Arbitration Mode (RRS)
This mode arbitrates all levels in a round robin mode, by scanning from levels 3 to 0. Only one grant is
issued per level and one owner is never forced from the bus in favor of another requester (VBCLR_ is
never asserted).
Since only one grant is issued per level on each round robin cycle, several scans are required to service
a queue of requests at one level.
2.6.3.5
VMEbus Arbiter Time-out
The Universe II’s VMEbus arbiter can be programmed to time-out if the requester does not assert
BBSY* within a specified period. This allows BGOUT to be negated so that the arbiter can continue
with other requesters. The timer is programmed using the VARBTO field in the MISC_CTL register,
and can be set to 16 µs, 256 µs, or disabled. The default setting for the timer is 16 µs. The arbitration
time-out timer has a granularity of 8 µs; setting the timer for 16 µs means the timer can timeout in as
little as 8 µs.
2.6.4
IACK Daisy-Chain Driver Module
The IACK Daisy-Chain Driver module is enabled when the Universe II becomes system controller.
This module guarantees that IACKIN* stays high for at least 30 ns as specified in rule 40 of the
VME64 specification.
2.6.5
VMEbus Time-out
A programmable bus timer allows users to select a VMEbus time-out period. The time-out period is
programmed through the VBTO field in the “Miscellaneous Control Register (MISC_CTL)” on
page 273 and can be set to 16µs, 32µs, 64µs, 128 µs, 256 µs, 512 µs, 1024 µs, or disabled. The default
setting for the timer is 64 µs. The VMEbus Timer module asserts VXBERR_ if a VMEbus transaction
times out (indicated by one of the VMEbus data strobes remaining asserted beyond the time-out
period).
The VME Bus Time-out value has a 4us resolution. Therefore, the time-out may occur up to
4us earlier than the selected VME Bus Time-out period.
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2.6.6
2. VMEbus Interface > Automatic Slot Identification
Bus Isolation Mode (BI-Mode)
®
BI-Mode is a mechanism for logically isolating the Universe II from the VMEbus. This mechanism
is useful for the following purposes:
•
Implementing hot-standby systems
— A system may have two identically configured boards, one in BI-Mode. If the board that is not
in BI-Mode fails, it can be put in BI-Mode while the spare board is removed from BI-Mode.
•
System diagnostics for routine maintenance
•
Fault isolation in the event of a card failure
— The faulty board can be isolated
While in BI-Mode, the Universe II data channels cannot be used to communicate between VMEbus
and PCI (Universe II mailboxes do provide a means of communication). The only traffic permitted is to
Universe II registers either through configuration cycles, the PCI register image, the VMEbus register
image, or CR/CSR space. No IACK cycles are generated or responded to. No DMA activity occurs.
Any access to other PCI images result in a Target-Retry. Access to other VMEbus images are ignored.
Entering BI-Mode has the following effects:
•
The VMEbus Master Interface becomes inactive
— PCI Target Channel coupled accesses are retried. The PCI Target Channel Posted Writes FIFO
continues to accept transactions but eventually fills and no further posted writes are accepted.
The DMA FIFO eventually empties or fills and no further DMA activity takes place on the
PCI bus. The Universe II VMEbus Master does not service interrupts while in BI-Mode.
•
The Universe II does not respond as a VMEbus slave
— Except for accesses to the register image and CR/CSR image.
•
The Universe II does not respond to any interrupt it had outstanding.
— All VMEbus outputs from the Universe II are tri-stated, so that the Universe II are not driving
any VMEbus signals. The only exception to this is the IACK and BG daisy chains which must
remain in operation as before.
There are four ways to cause the Universe II to enter BI-Mode. The Universe II is put into BI-Mode for
the following reasons:
•
If the BI-Mode power-up option is selected (See “Power-Up Options” on page 135 and Table 22 on
page 135)
•
When SYSRST* or RST_ is asserted any time after the Universe II has been powered-up in
BI-Mode
•
When VRIRQ_ [1] is asserted, provided that the ENGBI bit in the“Miscellaneous Control Register
(MISC_CTL)” on page 273 has been set
•
When the BI bit in the MISC_CTL register is set
Either of the following actions remove the Universe II from BI-Mode:
•
Power-up the Universe II with the BI-Mode option off (see “BI-Mode” on page 137), or
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47
Clear the BI bit in the MISC_CTL register.
— This is effective only if the source of the BI-Mode is no longer active. If VRIRQ_ [1] is still
being asserted while the ENGBI bit in the MISC_CTL register is set, then attempting to clear
the BI bit in the MISC_CTL register does not work.
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3.
PCI Interface
Peripheral Component Interconnect (PCI) is a bus protocol that defines how devices communicate on a
peripheral bus and with a host processor. If a device is referred to as PCI compliant it must be
compliant with the PCI Local Bus Specification (Revision 2.1). The Universe II PCI bus supports
frequencies up to 33 MHz, and 32-bit or 64-bit transfers.
This chapter describes the Universe II’s PCI Interface. This chapter discusses the following topics:
3.1
•
“PCI Cycles” on page 49
•
“Universe II as PCI Master” on page 53
•
“Universe II as PCI Target” on page 57
Overview
The Universe II PCI Bus Interface is a directly connected to the PCI bus. For information concerning
the different types of PCI accesses available, see “PCI Bus Target Images” on page 70.
3.2
PCI Cycles
The PCI Bus Interface of the Universe II operates as a PCI compliant port with a 64-bit multiplexed
address/data bus. The Universe II PCI Bus Interface is configured as little-endian using address
invariant translation when mapping between the VMEbus and the PCI bus. Address invariant
translation preserves the byte ordering of a data structure in a little-endian memory map and a
big-endian memory map (see “Endian Mapping” on page 359 and the PCI 2.1 Specification).
The Universe II has all the PCI signals described in the PCI 2.1 Specification) with the
exception of SBO_ and SDONE. These pins are exception because the Universe II does not
provide cache support.
Universe II PCI cycles are synchronous, meaning that bus and control input signals are externally
synchronized to the PCI clock (CLK). PCI cycles are divided into the following phases:
1. Request
2. Address
3. Data transfer
4. Cycle termination
3.2.1
32-Bit Versus 64-Bit PCI
The Universe II is configured with a 32-bit or 64-bit PCI data bus at power-up (see “PCI Bus Width”
on page 138).
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3. PCI Interface > PCI Cycles
Each of the Universe II’s VMEbus slave images can be programmed so that VMEbus transactions are
mapped to a 64-bit data bus on the PCI Interface through the LD64EN bit, in the “DMA Transfer
Control Register (DCTL)” on page 232. If the VMEbus slave image is programmed with a 64-bit PCI
bus data width and Universe II is powered-up in a 64-bit PCI environment, the Universe II asserts
REQ64_ during the address phase of the PCI transaction.
REQ64_ is asserted if LD64EN is set in a 64-bit PCI system independent of whether the
Universe II has a full 64-bit transfer. This can result in a performance degradation because of
the extra clocks required to assert REQ64_ and to sample ACK64_. Also, there can be some
performance degradation when accessing 32-bit targets with LD64EN set.
Do not set the LD64EN bit unless there are 64-bit targets in the slave image window.
If the VMEbus slave images are not programmed for a 64-bit wide PCI data bus, then the Universe
operates transparently in a 32-bit PCI environment.
Independent of the setting of the LD64EN bit, the Universe II never attempts a 64-bit cycle on the PCI
bus if it is powered-up as a 32-bit device.
3.2.2
PCI Bus Request and Parking
The Universe II supports bus parking. If the Universe II requires the PCI bus it asserts REQ_ only if its
GNT_ is not currently asserted. When the PCI Master Module is ready to begin a transaction and its
GNT_ is asserted, the transfer begins immediately. This eliminates a possible one clock cycle delay
before beginning a transaction on the PCI bus which would exist if the Universe II did not implement
bus parking.
Refer to the PCI 2.1 Specification for more information
3.2.3
Address Phase
PCI transactions are initiated by asserting FRAME_ and driving address and command information
onto the bus. In the VMEbus Slave Channel, the Universe II calculates the address for the PCI
transaction by adding a translation offset to the VMEbus address (see “Universe II as VMEbus Slave”
on page 32).
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The command signals (on the C/BE_ lines) contain information about Memory space, cycle type and
whether the transaction is read or write. Table 3 shows the PCI command type encoding implemented
with the Universe II.
Table 3: Command Type Encoding for Transfer Type
3.2.3.1
C/BE_ [3:0] for PCI,
C/BE_ [7:4] for
non-multiplexed
Command Type
Universe II Capability
0000
Interrupt Acknowledge
N/A
0001
Special Cycle
N/A
0010
I/O Read
Target/Master
0011
I/O Write
Target/Master
0100
Reserved
N/A
0101
Reserved
N/A
0110
Memory Read
Target/Master
0111
Memory Write
Target/Master
1000
Reserved
N/A
1001
Reserved
N/A
1010
Configuration Read
Target/Master
1011
Configuration Write
Target/Master
1100
Memory Read Multiple
See “Memory Read Types” on
page 51
1101
Dual Address Cycle
N/A
1110
Memory Read Line
See “Memory Read Types” on
page 51
1111
Memory Write and Invalidate
See “Memory Read Types” on
page 51
Memory Read Types
Memory Read Multiple and Memory Read Line transactions are aliased to Memory Read transactions
when the Universe II is accessed as a PCI target with these commands. Likewise, Memory Write and
Invalidate is aliased to Memory Write. As a PCI master, the Universe II can generate Memory Read
Multiple but not Memory Read Line.
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3. PCI Interface > PCI Cycles
PCI targets must assert DEVSEL_ if they have decoded the access. During a Configuration cycle, the
target is selected by its particular ID Select (IDSEL). If a target does not respond with DEVSEL_
within six clocks, a Master-abort is generated. The role of configuration cycles is described in the PCI
2.1 Specification.
3.2.4
Data Transfer
Acknowledgment of a data phase occurs on the first rising clock edge after both IRDY_ and TRDY_
are asserted by the master and target, respectively. REQ64_ can be driven during the address phase to
indicate that the master wishes to initiate a 64-bit transaction. The PCI target asserts ACK64_ if it is
able to respond to the 64-bit transaction.
Wait cycles are introduced by either the master or the target by de-asserting IRDY_ or TRDY_. For
write cycles, data is valid on the first rising edge after IRDY_ is asserted. Data is acknowledged by the
target on the first rising edge with TRDY_ asserted. For read cycles, data is transferred and
acknowledged on first rising edge with both IRDY_ and TRDY_ asserted.
A single data transfer cycle is repeated every time IRDY_ and TRDY_ are both asserted. The
transaction only enters the termination phase when FRAME_ is de-asserted (master-initiated
termination) or if STOP_ is asserted (target-initiated). When both FRAME_ and IRDY_ are
de-asserted (final data phase is complete), the bus is defined as idle.
3.2.5
Termination Phase
The PCI Bus Interface permits the following types of PCI terminations:
1. Master-abort: The PCI bus master negates FRAME_ when no target responds (DEVSEL_ not
asserted) after six clock cycles.
2. Target-disconnect: A termination is requested by the target (STOP_ is asserted) because it is unable
to respond within the latency requirements of the PCI specification or it requires a new address
phase.
•
Target-disconnect with data: The transaction is terminated after data is transferred. The
Universe II de-asserts REQ_ for at least two clock cycles if it receives STOP_ from the PCI
target.
•
Target-disconnect without data: The transaction is terminated before data is transferred. The
Universe II de-asserts REQ_ for at least two clock cycles if it receives STOP_ from the PCI
target.
3. Target-retry: Termination is requested (STOP_ is asserted) by the target because it cannot currently
process the transaction. Retry means that the transaction is terminated after the address phase
without any data transfer.
4. Target-abort: Is a modified version of target-disconnect where the target requests a termination
(asserts STOP_) of a transaction which it will never be able to respond to, or during which a fatal
error occurred. Although there may be a fatal error for the initiating application, the transaction
completes gracefully, ensuring normal PCI operation for other PCI resources.
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3.2.6
53
Parity Checking
The Universe II both monitors and generates parity information using the PAR signal. The Universe II
monitors PAR when it accepts data as a master during a read or a target during a write. The Universe II
drives PAR when it provides data as a target during a read or a master during a write. The Universe II
also drives PAR during the address phase of a transaction when it is a master and monitors PAR during
an address phase when it is the PCI target. In both address and data phases, the PAR signal provides
even parity for C/BE_[3:0] and AD[31:0]. The Universe II continues with a transaction independent of
any parity error reported during the transaction.
The Universe II can also be programmed to report address parity errors. It does this by asserting the
SERR_ signal and setting a status bit in its registers. No interrupt is generated, and regardless of
whether assertion of SERR_ is enabled, the Universe II does not respond to the errored access.
When the Universe II is powered-up in a 64-bit PCI environment, it uses PAR64 in the same
way as PAR, except for AD[63:32] and C/BE[7:4].
Universe II reports parity errors during all transactions with the PERR_ signal. The Universe II drives
PERR_ high within two clocks of receiving a parity error on incoming data, and holds PERR_ for at
least one clock for each errored data phase.
3.3
Universe II as PCI Master
The Universe II requests PCI bus mastership through its PCI Master Interface. The PCI Master
Interface is available to either the VMEbus Slave Channel (access from a remote VMEbus master) or
the DMA Channel.
The VMEbus Slave Channel makes an internal request for the PCI Master Interface when the following
conditions are met:
•
RXFIFO contains a complete transaction,
•
Sufficient data exists in the RXFIFO to generate a transaction of length defined by the
programmable aligned burst size (PABS)
•
There is a coupled cycle request
The DMA Channel makes an internal request for the PCI Master Interface when the following
conditions are met:
•
DMAFIFO has room for 128 bytes to be read from PCI
•
DMAFIFO has queued 128 bytes to be written to PCI
•
DMA block is completely queued during a write to the PCI bus
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3. PCI Interface > Universe II as PCI Master
Arbitration between the two channels for the PCI Master Interface follows a round robin protocol. Each
channel is given access to the PCI bus for a single transaction. Once that transaction completes,
ownership of the PCI Master Interface is granted to the other channel if it requires the bus. The
VMEbus Slave Channel and the DMA Channel each have a set of rules that determine when the
transaction is complete and the channels no longer need the PCI Master Interface. The VMEbus Slave
Channel no longer needs the PCI Master Interface under the following conditions:
•
An entire transaction (no greater in length than the programmed aligned burst size) is emptied from
the RXFIFO
•
The coupled cycle is complete
The DMA Channel no longer needs the PCI Master Interface when the following conditions are met:
•
The boundary programmed into the PCI aligned burst size is emptied from the DMAFIFO during
writes to the PCI bus
•
The boundary programmed into the PCI aligned burst size is queued to the DMAFIFO during reads
from the PCI bus
Access from the VMEbus can be either coupled or decoupled. For a full description of the operation of
these data paths, see “Universe II as VMEbus Slave” on page 32.
3.3.1
Command Types
The PCI Master Interface can generate the following command types:
•
I/O Read
•
I/O Write
•
Memory Read
•
Memory Read Multiple
•
Memory Write
•
Configuration Read (Type 0 and 1)
•
Configuration Write (Type 0 and 1)
The type of cycle the Universe II generates on the PCI bus depends on which VMEbus slave image is
accessed and how it is programmed. For example, one slave image might be programmed as an I/O
space, another as Memory space and another for Configuration space (see “VME Slave Image
Programming” on page 67). When generating a memory transaction, the addressing is either 32-bit or
64-bit aligned, depending upon the PCI target. When generating an I/O transaction, the addressing is
32-bit aligned and all incoming transactions are coupled.
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3.3.2
55
PCI Burst Transfers
The Universe II generates aligned burst transfers of some maximum alignment, according to the
programmed PCI aligned burst size (PABS field in the “Master Control Register (MAST_CTL)” on
page 271). The PCI aligned burst size can be programmed at 32, 64 or 128 bytes. Burst transfers do not
cross the programmed boundaries. For example, when programmed for 32-byte boundaries, a new
burst begins at XXXX_XX20, XXXX_XX40, etc. If necessary, a new burst begins at an address with
the programmed alignment. To optimize PCI bus usage, the Universe II always attempts to transfer
data in aligned bursts at the full width of the PCI bus.
The Universe II can perform a 64-bit data transfer over the AD [63:0] lines, if operated in a 64-bit PCI
environment or against a 64-bit capable target or master. The LD64EN bit must be set if the access is
being made through a VMEbus slave image; the LD64EN bit must be set if the access is being
performed with the DMA.
The Universe II generates burst cycles on the PCI bus if it is performing the following tasks:
•
Emptying the RXFIFO
— The TXFE bit in the “Miscellaneous Status Register (MISC_STAT)” on page 275 is clear
•
Filling the RDFIFO receives a block read request from a VMEbus master to an appropriately
programmed VMEbus slave image
•
Performing DMA transfers
All other accesses are treated as single data beat transactions on the PCI bus.
During PCI burst transactions, the Universe II dynamically enables byte lanes on the PCI bus by
changing the BE_ signals during each data phase.
3.3.3
Termination
The Universe II performs a Master-Abort if the target does not respond within six clock cycles.
Coupled PCI transactions terminated with Target-Abort or Master-Abort are terminated on the
VMEbus with BERR*. The R_TA or R_MA bits in the PCI_CS register are set when the Universe II
receives a Target-Abort or generates a Master-Abort independent of whether the transaction was
coupled, decoupled, prefetched, or initiated by the DMA.
If the Universe II receives a retry from the PCI target, then it relinquishes the PCI bus and re-requests
within three PCI clock cycles. No other transactions are processed by the PCI Master Interface until the
retry condition is cleared. The Universe II can be programmed to perform a maximum number of
retries using the MAXRTRY field in the “Master Control Register (MAST_CTL)” on page 271. When
this number of retries has been reached, the Universe II responds in the same way as it does to a
Target-Abort on the PCI bus. The Universe II can issue a BERR* signal on the VMEbus. All VMEbus
slave coupled transactions and decoupled transactions encounter a delayed DTACK once the FIFO fills
until the condition clears either due to success or a retry time-out.
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If the error occurs during a posted write to the PCI bus (see also “Error Handling” on page 125), the
Universe II uses the “PCI Command Error Log Register (L_CMDERR)” on page 210 to log the
command information for the transaction (CMDERR [3:0]) and the address of the errored transaction is
latched in the “PCI Address Error Log (LAERR)” on page 211. The L_CMDERR register also records
if multiple errors occur (with the M_ERR bit) although the number of errors is not given. The error log
is qualified with the L_STAT bit. The rest of the transaction is purged from the RXFIFO if some
portion of the write encounters an error. An interrupt is generated on the VMEbus and/or PCI bus
depending upon whether the VERR and LERR interrupts are enabled (see “Interrupt Generation and
Handling” on page 109).
If an error occurs on the PCI bus, the Universe II does not translate the error condition into a BERR*
on the VMEbus; the Universe II does not directly map the error. By taking no action, the Universe II
forces the external VMEbus error timer to expire.
3.3.4
Parity
The Universe II monitors PAR when it accepts data as a master during a read and drives PAR when it
provides data as a master during a write. The Universe II also drives PAR during the address phase of a
transaction when it is a master. In both address and data phases, the PAR signal provides even parity for
C/BE_[3:0] and AD[31:0].
When the Universe II is powered-up in a 64-bit PCI environment, it uses PAR64
in the same way as PAR, except for AD[63:32] and C/BE[7:4].
The PERESP bit in the “PCI Configuration Space Control and Status Register (PCI_CSR)” on
page 172 determines whether or not the Universe II responds to parity errors as PCI master. Data parity
errors are reported through the assertion of PERR_ if the PERESP bit is set. Regardless of the setting of
these two bits, the D_PE (Detected Parity Error) bit in the PCI_CS register is set if the Universe II
encounters a parity error as a master. The DP_D (Data Parity Detected) bit in the same register is only
set if parity checking is enabled through the PERESP bit and the Universe II detects a parity error while
it is PCI master (i.e. it asserts PERR_ during a read transaction or receives PERR_ during a write).
No interrupts are generated by the Universe II in response to parity errors reported during a transaction.
Parity errors are reported by the Universe II through assertion of PERR_ and by setting the appropriate
bits in the PCI_CS register. If PERR_ is asserted to the Universe II while it is PCI master, the only
action it takes is to set the DP_D. The Universe II continues with a transaction independent of any
parity errors reported during the transaction.
As a master, the Universe II does not monitor SERR_. It is expected that a central resource on the PCI
bus monitors SERR_ and take appropriate action.
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3.4
57
Universe II as PCI Target
The Universe II becomes PCI bus target when one of its nine programmed PCI target images, or one of
its registers, is accessed by a PCI bus master. The
Universe II cannot access its own images or registers and master the PCI bus. Refer to “Registers” on
page 163 for more information on register accesses.
When one of its PCI target images is accessed, the Universe II responds with DEVSEL_ within two
clocks of FRAME_. This makes the Universe II a medium speed device, as reflected by the DEVSEL
field in the PCI_CS register).
3.4.1
Command Types
As PCI target, the Universe II responds to the following command types:
•
I/O Read
•
I/O Write
•
Memory Read
•
Memory Write
•
Configuration Read (Type 0)
•
Configuration Write (Type 0)
•
Memory Read Multiple (aliased to Memory Read)
•
Memory Line Read (aliased to Memory Read)
•
Memory Write and Invalidate (aliased to Memory Write)
Type 0 Configuration accesses can only be made to the Universe II’s PCI configuration registers. The
PCI target images do not accept Type 0 accesses.
Address parity errors are reported if both PERESP and SERR_EN are set in the “PCI Configuration
Space Control and Status Register (PCI_CSR)” on page 172. Address parity errors are reported by the
Universe II by asserting the SERR_ signal and setting the S_SERR (Signalled SERR_) bit in the
PCI_CS register. Assertion of SERR_ can be disabled by clearing the SERR_EN bit in the PCI_CS
register. No interrupt is generated, and regardless of whether assertion of SERR_ is enabled or not, the
Universe II does not respond to the access with DEVSEL_. Typically, the master of the transaction
times out with a Master-Abort.
If the Universe II is accessed with REQ64_ in Memory space as a 64-bit target, then it responds with
ACK64_ if it is powered up as a 64-bit device.
3.4.2
Data Transfer
Read transactions are always coupled, as opposed to VMEbus slave reads which can be pre-fetched
(see “Universe II as VMEbus Slave” on page 32). Write transactions can be coupled or posted (see
Figure 6 and “PCI Bus Target Images” on page 70). To ensure sequential consistency, coupled
operations (reads or writes) are only processed once all previously posted write operations have
completed (the TXFIFO is empty).
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Figure 6: PCI Bus Target Channel Dataflow
POSTED WRITE DATA
TXFIFO
PCI BUS
SLAVE
INTERFACE
COUPLED WRITE DATA
VMEbus
MASTER
INTERFACE
COUPLED READ DATA
The PCI bus and the VMEbus can have different data width capabilities. The maximum VMEbus data
width is programmed into the PCI target image through the VDW bit in the “PCI Target Image 0
Control (LSI0_CTL)” on page 181. For example, consider a 32-bit PCI transaction accessing a PCI
target image with VDW set to 16 bits. A data beat with all byte lanes enabled will be broken into two
16-bit cycles on the VMEbus. If the PCI target image is also programmed with block transfers enabled,
the 32-bit PCI data beat will result in a D16 block transfer on the VMEbus. Write data is unpacked to
the VMEbus and read data is packed to the PCI bus data width.
If the data width of the PCI data beat is the same as the maximum data width of the PCI target image,
then the Universe II maps the data beat to an equivalent VMEbus cycle. For example, consider a 32-bit
PCI transaction accessing a PCI target image with VDW set to 32 bits. A data beat with all byte lanes
enabled is translated to a single 32-bit cycle on the VMEbus.
If the PCI bus data width is less than the VMEbus data width then there is no packing or unpacking
between the two buses. The only exception to this is during 32-bit PCI multi-data beat transactions to a
PCI target image programmed with maximum VMEbus data width of 64 bits. In this case,
packing/unpacking occurs to make maximum use of the full bandwidth on both buses.
Only aligned VMEbus transactions are generated, so if the requested PCI data beat has unaligned or
non-contiguous byte enables, then it is broken into multiple aligned VMEbus transactions no wider
than the programmed VMEbus data width. For example, consider a three-byte PCI data beat (on a
32-bit PCI bus) accessing a PCI target image with VDW set to 16-bit. The three-byte PCI data beat will
be broken into three aligned VMEbus cycles: three single-byte cycles. If in the above example the PCI
target image has a VDW set to 8-bit, then the three-byte PCI data beat will be broken into three
single-byte VMEbus cycles.
3.4.3
Coupled Transfers
The PCI Target Channel supports coupled transfers. A coupled transfer through the PCI Target Channel
is a transfer between PCI and VME where the Universe II maintains ownership of the VMEbus from
the beginning to the end of the transfer on the PCI bus, and where the termination of the cycle on the
VMEbus is relayed directly to the PCI master in the normal manner (Target-Abort or Target
Completion), rather than through error-logging and interrupts.
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By default, all PCI target images are set for coupled transfers. Coupled transfers typically cause the
Universe II to go through three phases: the Coupled Data-Transfer Phase, and then the Coupled Wait
Phase. When an external PCI Master attempts a data transfer through a slave image programmed for
coupled cycles, and the Universe II currently owns the VMEbus, the PCI Target Channel moves
directly to the Coupled Data-Transfer Phase
3.4.3.1
Coupled Data-Transfer Phase
At the beginning of the Coupled Data-Transfer Phase, the Universe II latches the PCI command, byte
enable, address and (in the case of a write) data. Regardless of the state of FRAME_, the Universe II
retries1 the master, and then performs the transaction on the VMEbus. The Universe II continues to
signal Target-Retry to the external PCI master until the transfer completes on the VMEbus.
If the transfer completes normally on the VMEbus then, in the case of a read, the data is transmitted to
the PCI bus master. If a data phase of a coupled transfer requires packing or unpacking on the VMEbus,
acknowledgment of the transfer is not given to the PCI bus master until all data has been packed or
unpacked on the VMEbus. Successful termination is signalled on the PCI bus—the data beat is
acknowledged with a Target-Disconnect, forcing all multi-beat transfers into single beat. At this point,
the Universe II enters the Coupled Wait Phase.
If a bus error is signalled on the VMEbus or an error occurs during packing or unpacking, then the
transaction is terminated on the PCI bus with Target-Abort.
For more information refer to “Data Transfer” on page 57.
3.4.3.2
Coupled Wait Phase
The Coupled Wait Phase is entered after the successful completion of a Coupled Data-Transfer phase.
The Coupled Wait Phase allows consecutive coupled transactions to occur without releasing the
VMEbus. If a new coupled transaction is attempted while the Universe II is in the Coupled Wait Phase,
the Universe II moves directly to the Coupled Data-Transfer Phase.
The Coupled Window Timer determines the maximum duration of the Coupled Wait Phase. When the
Universe II enters the Coupled Wait Phase, the Coupled Window Timer starts. The period of this timer
is specified in PCI clocks and is programmable through the CWT field of the “PCI Miscellaneous
Register (LMISC)” on page 206. If this field is programmed to 0000, the Universe II does an early
release of BBSY* during the coupled transfer on the VMEbus and will not enter the Coupled Wait
Phase. In this case, VMEbus ownership is relinquished immediately by the PCI Target Channel after
each coupled cycle.
Once the timer associated with the Coupled Wait Phase expires, the Universe II releases the VMEbus if
release mode is set for RWD, or the release mode is set for ROR and there is a pending (external)
request on the VMEbus.
1. PCI latency requirements (as described in revision 2.1 of the PCI Specification) require that only 16 clock cycles can elapse between the
first and second data beat of a transaction. Since the Universe II cannot guarantee that data acknowledgment will be received from the
VMEbus in time to meet these PCI latency requirements, the Universe II performs a target-disconnect after the first data beat of every
coupled write transaction.
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3.4.4
3. PCI Interface > Universe II as PCI Target
Posted Writes
Posted writes are enabled for a PCI target image by setting the PWEN bit in the control register of the
PCI target image (see “PCI Bus Target Images” on page 70) to 1 and setting the LAS bit to 0. Write
transactions are relayed from the PCI bus to the VMEbus through a 64-entry deep TXFIFO. The
TXFIFO allows each entry to contain 32 address bits (with extra bits provided for command
information), or to a full 64-bit width. For each posted write transaction received from the PCI bus, the
PCI Target Interface queues an address entry in the FIFO. This entry contains the translated address
space and mapped VMEbus attributes information relevant to the particular PCI target image that has
been accessed (see “PCI Bus Target Images” on page 70). For this reason, any reprogramming of PCI
bus target image attributes will only be reflected in TXFIFO entries queued after the reprogramming.
Transactions queued before the re-programming are delivered to the VMEbus with the PCI bus target
image attributes that were in use before the reprogramming.
Care must be taken before reprogramming target images. To ensure the FIFO is empty use
one of the following options:
3.4.4.1
•
Perform a coupled read. The coupled read does not complete until all posted-write data
has been queued
•
Read the MISC_STAT register until the TXFE bit has a value of 0
FIFO Entries
Once the address phase is queued in one TXFIFO entry, the PCI Target Interface may pack the
subsequent data beats to a full 64-bit width before queuing the data into new entries in the TXFIFO.
For 32-bit PCI transfers in the Universe II, the TXFIFO accepts a single burst of one address phase and
59 data phases when it is empty. For 64-bit PCI, the TXFIFO accepts a single burst of one address
phase and 31 data phases when it is empty. To improve PCI bus utilization, the TXFIFO does not
accept a new address phase if it does not have room for a burst of one address phase and 128 bytes of
data. If the TXFIFO does not have enough space for an aligned burst, then the posted write transaction
is terminated with a Target-Retry immediately after the address phase.
When an external PCI Master posts writes to the PCI Target Channel of the Universe II, the Universe II
issues a disconnect if the address crosses a 256-byte boundary.
Before a transaction can be delivered to the VMEbus from the TXFIFO, the PCI Target Channel must
obtain ownership of the VMEbus Master Interface. Ownership of the VMEbus Master Interface is
granted to the different channels on a round robin basis (see “VMEbus Release” on page 27). Once the
PCI Target Channel obtains the VMEbus through the VMEbus Master Interface, the manner in which
the TXFIFO entries are delivered depends on the programming of the VMEbus attributes in the PCI
target image (see “PCI Bus Target Images” on page 70). For example, if the VMEbus data width is
programmed to 16-bit, and block transfers are disabled, then each data entry in the TXFIFO
corresponds to four transactions on the VMEbus.
If block transfers are enabled in the PCI target image, then each transaction queued in the TXFIFO,
independent of its length, is delivered to the VMEbus as a block transfer. This means that if a single
data beat transaction is queued in the TXFIFO, it appears on the VMEbus as a single data phase block
transfer.
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Any PCI master attempting coupled transactions is retried while the TXFIFO contains data. If posted
writes are continually written to the PCI Target Channel by another master, and the FIFO does not
empty, coupled transactions requested by the first PCI master in the PCI Target Channel does not
proceed and are continually retried. This presents a potential starvation scenario.
This functionality is intended to support earlier versions of PCI-to-PCI bridges.
3.4.5
Special Cycle Generator
The Special Cycle Generator in the PCI Target Channel of the Universe II can be used in conjunction
with one of the PCI Target Images to generate Read-Modify-Write (RMW) and Address Only With
Handshake (ADOH) cycles.
The address programmed into the “Special Cycle PCI Bus Address Register (SCYC_ADDR)” on
page 202, in the address space specified by the LAS field of the SCYC_CTL register (Memory or I/O),
must appear on the PCI bus during the address phase of a transfer for the Special Cycle Generator to
perform its function. Whenever this address on the PCI bus (bits [31:2]) is used to matches the address
in the SCYC_ADDR register, the Universe II does not respond with ACK64_ (since the Special Cycle
Generator only processes up to 32-bit cycles).
The cycle that is produced on the VMEbus uses attributes programmed into the Image Control Register
of the image that contains the address programmed in the SCYC_ADDR register.
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The Special Cycle Generator is configured through the register fields shown in Table 7.
Figure 7: Register Fields for the Special Cycle Generator
Field
Register Bits
Description
32-bit address
ADDR in “Special Cycle PCI
Bus Address Register
(SCYC_ADDR)” on
page 202
Specifies PCI bus target image address
PCI Address Space
LAS in “Special Cycle
Control Register
(SCYC_CTL)” on page 201
Specifies whether the address specified in the ADDR
field lies in PCI memory or I/O space
Special cycle
SCYC[1:0] in “Special Cycle
Control Register
(SCYC_CTL)” on page 201
Disabled, RMW or ADOH
32-bit enable
EN [31:0] in “Special Cycle
Swap/Compare Enable
Register (SCYC_EN)” on
page 203
A bit mask to select the bits to be modified in the
VMEbus read data during a RMW cycle
32-bit compare
CMP [31:0] in “Special Cycle
Compare Data Register
(SCYC_CMP)” on page 204
Data which is compared to the VMEbus read data
during a RMW cycle
32-bit swap
SWP [31:0] in “Special Cycle
Swap Data Register
(SCYC_SWP)” on page 205
Data which is swapped with the VMEbus read data and
written to the original address
during a RMW cycle
The following sections describe the specific properties for each of the transfer types: RMW and
ADOH.
3.4.5.1
Read-Modify-Write
When the SCYC field is set to RMW, any PCI bus read access to the specified PCI bus address
(SCYC_ADDR register) results in a RMW cycle on the VMEbus (provided the constraints listed below
are satisfied). RMW cycles on the VMEbus consist of a single read followed by a single write
operation. The data from the read portion of the RMW on the VMEbus is returned as the read data on
the PCI bus.
RMW cycles make use of three 32-bit registers (see Table 7). The bit enable field is a bit mask which
lets the user specify which bits in the read data are compared and modified in the RMW cycle. This bit
enable setting is completely independent of the RMW cycle data width, which is determined by the
data width of the initiating PCI transaction. During a RMW, the VMEbus read data is bitwise compared
with the SCYC_CMP and SCYC_EN registers. The valid compared and enabled bits are then swapped
using the SCYC_SWP register.
Each enabled bit that compares equal is swapped with the corresponding bit in the 32-bit swap field. A
false comparison results in the original bit being written back.
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Once the RMW cycle completes, the VMEbus read data is returned to the waiting PCI bus master and
the PCI cycle terminates.
RMW Constraints
Certain restrictions apply to the use of RMW cycles. If a write transaction is initiated to the VMEbus
address when the special cycle field (SCYC in “Special Cycle Control Register (SCYC_CTL)” on
page 201) is set for RMW, then a standard write occurs with the attributes programmed in the PCI
target image (in other words, the special cycle generator is not used). The Universe II performs no
packing and unpacking of data on the VMEbus during a RMW operation. The following constraints
must also be met.
1. The Special Cycle Generator only generates a RMW if it is accessed with an 8-bit, aligned 16-bit,
or aligned 32-bit read cycle.
2. The Special Cycle Generator only generates a RMW if the size of the request is less than or equal
to the programmed VMEbus Maximum Data width.
3. The destination VMEbus address space must be one of A16, A24 or A32.
In the event that the Special Cycle Generator is accessed with a read cycle that does not meet the RMW
criteria, the Universe II generates a Target-Abort. The
Universe II must be correctly programmed and accessed with correct byte-lane information.
3.4.5.2
VME Lock Cycles—Exclusive Access to VMEbus Resources
The VME Lock cycle is used, in combination with the VOWN bit in the “Master Control Register
(MAST_CTL)” on page 271, to lock resources on the VMEbus. The VME Lock cycle can be used by
the Universe II to inform the resource that a locked cycle is intended. The VOWN bit in the
MAST_CTL register can be set to ensure that when the Universe II acquires the VMEbus, it is the only
master given access to the bus (until the VOWN bit is cleared). It may also be necessary for the PCI
master to have locked the Universe II using the PCI LOCK_ signal.
When the SCYC field is set to VME Lock, any write access to the specified VMEbus address will
result in a VME Lock cycle on the VMEbus. A VME Lock cycle is coupled: the cycle does not
complete on the PCI bus until it completes on the VMEbus. Reads to the specified address translate to
VMEbus reads in the standard fashion. The data during writes is ignored. The AM code generated on
the VMEbus is determined by the PCI target image definition for the specified VMEbus address (see
Table 8 on page 70).
However, after the VME Lock cycle is complete, there is no guarantee that the Universe II remains
VMEbus master unless it has set the VOWN bit. If the Universe II loses VMEbus ownership, the
VMEbus resouce does not remain locked.
The following procedure is required to lock the VMEbus through an ADOH cycle:
1. If there is more than one master on the PCI bus, it may be necessary to use PCI LOCK_ to ensure
that the PCI master driving the ADOH cycle has sole PCI access to the Universe II registers and
the VMEbus
2. program the VOWN bit in the MAST_CTL register to a value of 1 (see “Using the VOWN bit” on
page 64)
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3. PCI Interface > Universe II as PCI Target
3. wait until the VOWN_ACK bit in the MAST_CTL register is a value of 1
4. generate an ADOH cycle with the Special Cycle Generator
5. perform transactions to be locked on the VMEbus
6. release the VMEbus by programming the VOWN bit in the MAST_CTL register to a value of 0
7. wait until the VOWN_ACK bit in the MAST_CTL register is a value of 0
In the event that BERR* is asserted on the VMEbus once the Universe II has locked and owns the
VMEbus, it is the responsibility of the user to release ownership of the VMEbus by programming the
VOWN bit in the MAST_CTL register to a value of 0.
The following restrictions apply to the use of VME Lock cycles:
3.4.6
•
All byte lane information is ignored for VME Lock cycles
•
The Universe II generates a VME Lock cycle on the VMEbus if the PCI Target Image, which
includes the special cycle, has posted writes disabled
•
The Universe II Special Cycle Generator does not generate VME Lock cycles if the address space
is not one of A16, A24 or A32 — it produces regular cycles instead
Using the VOWN bit
The Universe II provides a VMEbus ownership bit (VOWN bit in the “Master Control Register
(MAST_CTL)” on page 271) to ensure that the Universe II has access to the locked VMEbus resource
for an indeterminate period. The Universe II can be programmed to assert an interrupt on the PCI bus
when it acquires the VMEbus and the VOWN bit is set in the “PCI Interrupt Enable Register
(LINT_EN)” on page 242. While the VMEbus is held using the VOWN bit, the Universe II sets the
VOWN_ACK bit in the MAST_CTL register. The act of changing the VOWN_ACK bit from 0 to 1
generates and interrupt. The VMEbus Master Interface maintains bus tenure while the ownership bit is
set, and only releases the VMEbus when the ownership bit is cleared.
3.4.6.1
Reasons for Using the VOWN Bit
If the VMEbus Master Interface is programmed for RWD, through the VREL bit in “Master Control
Register (MAST_CTL)” on page 271, it may release the VMEbus when the PCI Target Channel has
completed a transaction. If exclusive access to the VMEbus resource is required for multiple
transactions, then the VMEbus ownership bit holds the bus until the exclusive access is no longer
required.
Alternatively, if the VMEbus Master Interface is programmed for ROR, the VMEbus ownership bit
ensures VMEbus tenure even if other VMEbus requesters require the VMEbus.
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3.4.7
65
Terminations
The Universe II performs the following terminations as PCI target:
1. Target-Disconnect
•
When registers are accessed with FRAME_ asserted (no bursts allowed to registers)
•
After the first data beat of a coupled cycle with FRAME_ asserted
A Target-disconnect with data only occurs if FRAME_ is asserted.
•
After the first data phase of a PCI Memory command (with FRAME_ asserted) if AD[1:0] is
not equal to 00 (refer to Revision 2.1 of the PCI Specification)
2. Target-Retry
•
When a new posted write is attempted and the TXFIFO does not have room for a burst of one
address phase and sixteen 64-bit data phases (for 64-bit PCI)
•
When a coupled transaction is attempted and the Universe II does not own the VMEbus
•
When a coupled transaction is attempted while the TXFIFO has entries to process
•
Register Channel is locked by the VME Slave Channel if a register access (including a RMW
access) is in progress or the registers have been locked by an ADOH access. If the registers are
locked by the VME Slave Channel, register accesses by external PCI masters are retried
3. Target-Abort
•
When the Universe II receives BERR* on the VMEbus during a coupled cycle (BERR*
translated as Target-Abort on the PCI side and the S_TA bit is set in the “PCI Configuration
Space Control and Status Register (PCI_CSR)” on page 172
Whether to terminate a transaction or for retry purposes, the Universe II keeps STOP_ asserted until
FRAME_ is de-asserted, independent of the logic levels of IRDY_ and TRDY_. If STOP_ is asserted
while TRDY_ is de-asserted, it means that the Universe II does not transfer any more data to the
master.
3.4.7.1
Error During Posted Write
If an error occurs during a posted write to the VMEbus, the Universe II uses the AMERR field in the
“VMEbus AM Code Error Log (V_AMERR)” on page 307 to log the AM code of the transaction, and
the state of the IACK* signal, through the IACK bit, to indicate whether the error occurred during an
IACK cycle. The FIFO entries for the cycle are purged. The V_AMERR register also records whether
multiple errors have occurred (with the M_ERR bit) although the number is not given. The error log is
qualified with the V_STAT bit because logs are valid if the V_STAT bit is set.
The address of the errored transaction is latched in the “VMEbus Address Error Log (VAERR)” on
page 308. When the Universe II receives a VMEbus error during a posted write, it generates an
interrupt on the VMEbus and/or PCI bus depending upon whether the VERR and VERR interrupts are
enabled (see “Interrupt Generation and Handling” on page 109).
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4.
Slave Image Programming
This chapter describes the Slave Image Programming functionality of the Universe II. This chapter
discusses the following topics:
4.1
•
“VME Slave Image Programming” on page 67
•
“PCI Bus Target Images” on page 70
•
“Special PCI Target Image” on page 73
Overview
The Universe II recognizes two types of accesses on its bus interfaces: accesses destined for the other
bus, and accesses decoded for its own register space. Address decoding for the Universe II’s register
space is described in “Registers” on page 163. This section describes the slave images used to map
transactions between the PCI bus and VMEbus.
4.2
VME Slave Image Programming
The Universe II accepts accesses from the VMEbus within specific programmed slave images. Each
VMEbus slave image opens a window to the resources of the PCI bus and, through its specific
attributes, allows the user to control the type of access to those resources. The tables below describe
programming for the VMEbus slave images by dividing them into VMEbus, PCI bus and Control
fields.
Table 4: VMEbus Fields for VMEbus Slave Image
Field
Register Bits
Description
Base
BS[31:12] or BS[31:16] in
VSIx_BS
Multiples of 4 or 64 Kbytes (base to bound:
maximum of 4 GBytes)
Bound
BD[31:12] or BD[31:16] in
VSIx_BD
Address space
VAS in VSIx_CTL
A16, A24, A32, User 1, User 2
Mode
SUPER in VSIx_CTL
Supervisor and/or non-privileged
Type
PGM in VSIx_CTL
Program and/or data
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Table 5: PCI Bus Fields for VMEbus Slave Image
Field
Register Bits
Description
Translation offset
TO[31:12] or TO[31:16] in
VSIx_TO
Offsets VMEbus slave address to a selected
PCI address
Address space
LAS in VSIx_CTL
Memory, I/O, Configuration
RMW
LLRMW in VSIx_CTL
RMW enable bit
Table 6: Control Fields for VMEbus Slave Image
Field
Register Bits
Description
Image enable
EN in VSIx_CTL
Enable bit
Posted write
PWEN in VSIx_CTL
Posted write enable bit
Prefetched read
PREN in VSIx_CTL
Prefetched read enable bit
Enable PCI D64
LD64EN in VSIx_CTL
Enables 64-bit PCI bus transactions
The Bus Master Enable (BM) bit of the PCI_CS register must be set in order for the image to accept
posted writes from an external VMEbus master. If this bit is cleared while there is data in the VMEbus
Slave Posted Write FIFO, the data is written to the PCI bus but no further data is accepted into this
FIFO until the bit is set.
IDT recommends that the attributes in a slave image not be changed while data is enqueued in
the Posted Writes FIFO. To ensure data is queued from the FIFO, check the RXFE status bit
in the “Miscellaneous Status Register (MISC_STAT)” on page 275 or perform a read from
that image. If the programming for an image is changed after the transaction is queued in the
FIFO, the transaction’s attributes are not changed. Only subsequent transactions are affected
by the change in attributes.
4.2.1
VMEbus Fields
Decoding for VMEbus accesses is based on the address, and address modifiers produced by the
VMEbus master. Before responding to an external VMEbus master, the address must lie in the window
defined by the base and bound addresses, and the Address Modifier must match one of those specified
by the address space, mode, and type fields.
The Universe II’s eight VMEbus slave images (images 0 to 7) are bounded by A32 space. The first and
fourth of these images (VMEbus slave image 0 and 4) have a 4-Kbyte resolution while VMEbus slave
images 1 to 3 and 5 to 7 have 64-Kbyte resolution (maximum image size of 4 Gbytes).
The address space of a VMEbus slave image must not overlap with the address space for the
Universe II’s control and status registers.
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4.2.2
69
PCI Bus Fields
The PCI bus fields specify how the VMEbus transaction is mapped to the appropriate PCI bus
transaction. The translation offset field allows the user to translate the VMEbus address to a different
address on the PCI bus. The translation of VMEbus transactions beyond 4 Gbytes results in
wrap-around to the low portion of the address range.
The LAS field controls generation of the PCI transaction command. The LLRMW bit allows
indivisible mapping of incoming VMEbus RMW cycles to the PCI bus via the PCI LOCK_ mechanism
(see “VMEbus Read-Modify-Write Cycles (RMW Cycles)” on page 37). When the LLRMW bit is set,
single cycle reads are always be mapped to single data beat locked PCI transactions. Setting this bit has
no effect on non-block writes: they can be coupled or decoupled.
Only accesses to PCI Memory Space are decoupled, accesses to I/O or Configuration Space
are always coupled.
Figure 8: Address Translation Mechanism for VMEbus to PCI Bus Transfers
A32 Image
Offset [31..12]
PCI [31..12]
VME [31..12]
4.2.3
PCI [11..0]
VME [11..0]
Control Fields
The control fields enable a VMEbus slave image (using the EN bit), as well as specify how reads and
writes are processed. At power-up, all images are disabled and are configured for coupled reads and
writes.
If the PREN bit is set, the Universe II prefetches for incoming VMEbus block read cycles. It is the
user's responsibility to ensure that prefetched reads are not destructive and that the entire image
contains prefetchable resources.
Prefetching is only possible in PCI Memory Space.
If the PWEN bit is set, incoming write data from the VMEbus is loaded into the RXFIFO (see “Posted
Writes” on page 33). Note that posted write transactions can only be mapped to Memory space on the
PCI bus. Setting the LAS bit in the PCI fields to I/O or Configuration Space will force all incoming
cycles to be coupled independent of this bit.
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4. Slave Image Programming > PCI Bus Target Images
If the LD64EN bit is set, the Universe II generates 64-bit transactions on the PCI bus by asserting
REQ64_. The REQ64_ line is asserted during the address phase in a 64-bit PCI system, and is the
means of determining whether the PCI target is a 64-bit port. If the target asserts ACK64_ with
DEVSEL_, then the Universe II uses the 64-bit data bus. If the target does not assert ACK64_ with
DEVSEL_, then the Universe II uses a 32-bit data bus. However, note that use of REQ64_ requires
extra clocks internally. If no 64-bit targets are expected on the PCI bus then performance can be
improved by disabling LD64EN on the VMEbus slave images.
Universe II only performs 64-bit PCI transactions if the power-up option LCLSIZE bit in the
“Miscellaneous Status Register (MISC_STAT)” on page 275 is set to 1. If the Universe II is
set for a 32-bit PCI transaction (LCLSIZE bit set to 0) it does not perform 64-bit PCI
transactions.
4.3
PCI Bus Target Images
The Universe II accepts accesses from the PCI bus with programmed PCI target images. Each image
opens a window to the resources of the VMEbus and allows the user to control the type of access to
those resources. The Table 7, Table 8 and Table 9 describe programming for the eight standard PCI bus
target images (numbered 0 to 7) by dividing them into VMEbus, PCI bus and Control fields. One
special PCI target image is described in “Special PCI Target Image” on page 73.
Table 7: PCI Bus Fields for the PCI Bus Target Image
Field
Register Bits
Description
Base
BS[31:12] or BS[31:16] in
LSIx_BS
Multiples of 4 or 64 Kbytes (base to bound:
maximum of 4 GBytes)
Bound
BD[31:12] or BD[31:16] in
LSIx_BD
Address space
LAS in LSIx_CTL
Memory or I/O
Table 8: VMEbus Fields for the PCI Bus Target Image
Field
Register Bits
Description
Translation offset
TO[31:12] or TO[31:16] in
LSIx_TO
Translates address supplied by PCI master
to a specified VMEbus address
Maximum data width
VDW in LSIx_CTL
8, 16, 32, or 64 bits
Address space
VAS in LSIx_CTL
A16, A24, A32, CR/CSR, User1, User2
Mode
SUPER in LSIx_CTL
Supervisor or non-privileged
Type
PGM in LSIx_CTL
Program or data
Cycle
VCT in LSIx_CTL
single or block
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Table 9: Control Fields for PCI Bus Target Image
Field
Register Bits
Description
Image enable
EN in LSIx_CTL
Enable bit
Posted write
PWEN in LSIx_CTL
enable bit
IDT recommends that the attributes in a target image not be changed while data is enqueued
in the Posted Writes FIFO. To ensure data is queued from the FIFO, check the TXFE status
bit in the “Miscellaneous Status Register (MISC_STAT)” on page 275 or perform a read from
that image. If the programming for an image is changed after the transaction is queued in the
FIFO, the transaction’s attributes are not changed. Only subsequent transactions are affected
by the change in attributes.
4.3.1
PCI Bus Fields
All decoding for VMEbus accesses are based on the address and command information produced by a
PCI bus master. The PCI Target Interface claims a cycle if there is an address match and if the
command matches certain criteria.
All of the Universe II’s eight PCI target images are A32-capable only. The first and fifth of them (PCI
target images 0 and 4) have a 4 Kbyte resolution while PCI target images 1 to 3 and 5 to 7 have 64
Kbyte resolution. Typically, image 0 or image 4 would be used for an A16 image since they have the
finest granularity.
The address space of a VMEbus slave image must not overlap with the address space for the
Universe II’s registers.
4.3.2
VMEbus Fields
The VMEbus fields map PCI transactions to a VMEbus transaction, causing the Universe II to generate
the appropriate VMEbus address, AM code, and cycle type. Some invalid combinations exist within
the PCI target image definition fields. For example, A16 and CR/CSR spaces do not support block
transfers, and A16 space does not support 64-bit transactions. Note that the Universe II does not
attempt to detect or prevent these invalid programmed combinations, and that use of these
combinations may cause illegal activity on the VMEbus.
The 21-bit translation offset allows the user to translate the PCI address to a different address on the
VMEbus. Figure 9 illustrates the translation process.
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4. Slave Image Programming > PCI Bus Target Images
Figure 9: Address Translation Mechanism for PCI Bus to VMEbus Transfers
A32 Image
Offset [31..12]
PCI [31..12]
VME [31..12]
PCI [11..0]
VME [11..0]
Translations beyond the 4 Gbyte limit will wrap around to the low address range.
The Universe II provides support for user defined AM codes. The “User AM Codes Register
(USER_AM)” on page 276 contains AM codes identified as User1 and User2. The USER_AM register
can only be used to generate and accept AM codes 0x10 through 0x1F. These AM codes are designated
as USERAM codes in the VMEbus Specification. If the user selects one of these two, then the
corresponding AM code from the global register is generated on the VMEbus. This approach results in
standard single cycle transfers to A32 VMEbus address space independent of other settings in the
VMEbus fields.
The VCT bits in the “PCI Target Image 0 Control (LSI0_CTL)” on page 181 determine whether or not
the VMEbus Master Interface will generate BLT transfers. The VCT bit will only be used if the VAS
field is programmed for A24 or A32 space and the VDW bits are programmed for 8, 16, or 32 bits. If
VAS bits of the control register are programmed to A24 or A32 and the VDW bits are programmed for
64-bit, the Universe II may perform MBLT transfers independent of the state of the VCT bit.
4.3.2.1
Transfers
Transfers appear on the VMEbus as 16-bit transfers when the Universe II is programmed in the
following manner:
•
PWEN= 1
•
VDW=16-bit, 32-bit or 64-bit
•
VCT= 0
External PCI master begins a burst 32-bit write with A2=0 and BE_=0011, followed by a transfer with
BE_=1100.
These criteria optimize performance of 32-bit PCI systems which regularly perform 16-bit transfers. A
series of 16-bit transfers is also performed if 64-bit posted write is received with BE_=11000011.
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4.3.3
73
Control Fields
The control fields enable a PCI target image (the EN bit), as well as specify how writes are processed.
If the PWEN bit is set, then the Universe II performs posted writes when that particular PCI target
image is accessed. Posted write transactions are only decoded within PCI Memory space. Accesses
from I/O spaces results in coupled cycles independent of the setting of the PWEN bit.
4.4
Special PCI Target Image
The Universe II provides a special PCI target image located in Memory or I/O space. Its base address is
aligned to 64-Mbyte boundaries and its size is fixed at 64 Mbytes (decoded using PCI address lines
[31:26]). The “Special PCI Target Image (SLSI)” on page 208 is divided into four 16 Mbyte regions
numbered 0 to 3 (see Figure 10 on page 74). These separate regions are selected with PCI address bits
AD [25:24]. For example, if AD[25:24] = 01, then region 1 is decoded. Within each region, the upper
64Kbytes map to VMEbus A16 space, while the remaining portion of the 16 Mbytes maps to VMEbus
A24 space. Note that no offsets are provided, so address information from the PCI transaction is
mapped directly to the VMEbus.
The general attributes of each region are programmed according to the tables below.
Table 10: PCI Bus Fields for the Special PCI Target Image
Field
Register Bits
Description
Base
BS[5:0]
64 Mbyte aligned base address for the
image
Address space
LAS
Places image in Memory or I/O
Table 11: VMEbus Fields for the Special PCI Bus Target Image
Field
Register Bits
Description
Maximum data width
VDW
Separately sets each region for 16 or 32 bits
Mode
SUPER
Separately sets each region as supervisor or
non-privileged
Type
PGM
Separately sets each region as program or
data
Table 12: Control Fields for the Special PCI Bus Target Image
Field
Register Bits
Description
Image enable
EN
Enable bit for the image
Posted write
PWEN
Enable bit for posted writes for the image
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4. Slave Image Programming > Special PCI Target Image
The special PCI target image provides access to all of A16 and most of A24 space (all except the upper
64 Kbytes). By using the special PCI target image for A16 and A24 transactions, it is possible to free
the eight standard PCI target images (see “PCI Bus Target Images” on page 70), which are typically
programmed to access A32 space.
Address space redundancy is provided in A16 space. The VMEbus specification requires only two A16
spaces, while the special PCI target image allows for four A16 address spaces.
Figure 10: Memory Mapping in the Special PCI Target Image
BASE+400 0000
64 Kbytes
A16
BASE+3FF 0000
3
A24
16 Mbytes
BASE+300 0000
BASE+2FF 0000
2
BASE+200 0000
A16
A24
A16
BASE+1FF 0000
1
BASE+100 0000
A24
A16
BASE+0FF 0000
0
A24
BASE+000 0000
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5.
Registers Overview
The Universe II Control and Status Registers (UCSR) occupy 4 Kbytes of internal memory. This
chapter discusses the following topics:
5.1
•
“Register Access from the PCI Bus” on page 76
•
“Register Access from the VMEbus” on page 79
•
“Mailbox Registers” on page 83
•
“Semaphores” on page 83
Overview
The Universe II Control and Status Registers (UCSR) occupy 4 Kbytes of internal memory. This 4
Kbytes is logically divided into the following three groups (see Figure 11):
•
PCI Configuration Space (PCICS)
•
Universe II Device Specific Registers (UDSR)
•
VMEbus Control and Status Registers (VCSR)
The Universe II registers are little-endian.
The access mechanisms for the UCSR are different depending upon whether the register space is
accessed from the PCI bus or VMEbus. Register access from the PCI bus and VMEbus is discussed in
the following sections.
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5. Registers Overview > Register Access from the PCI Bus
Figure 11: Universe II Control and Status Register Space
VMEbus Configuration
and Status Registers
(VCSR)
UNIVERSE DEVICE
SPECIFIC REGISTERS
(UDSR)
4 Kbytes
UCSR Space
PCI CONFIGURATION
SPACE
(PCICS)
5.2
Register Access from the PCI Bus
There are different mechanisms to access the UCSR space from the PCI bus: Configuration space, PCI
Memory or I/O space.
5.2.1
PCI Configuration Access
When the UCSR space is accessed as Configuration space, it means that the access is externally
decoded and the Universe II is notified through IDSEL (much like a standard chip select signal). Since
the register location is encoded by a 6-bit register number (a value used to index a 32-bit area of
Configuration space), only the lower 256 bytes of the UCSR can be accessed as Configuration space
(this corresponds to the PCICS in the UCSR space, see Figure 12 on page 77). Only the PCI
configuration registers are accessible through PCI Configuration cycles.
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77
Figure 12: PCI Bus Access to UCSR as Memory or I/O Space
VMEbus Configuration
and Status Registers
(VCSR)
4 Gbytes
of Memory
or I/O Space
UNIVERSE DEVICE
SPECIFIC REGISTERS
(UDSR)
Accessible
through PCI
Configuration
Cycle
5.2.2
All 4 Kbytes
Accessible as
Memory or I/O
Space
PCI CONFIGURATION
SPACE
(PCICS)
PCI_BS
Memory or I/O Access
Two 4-Kbyte ranges of addresses in PCI Memory space and/or PCI I/O space can be dedicated to the
Universe II registers. There is one 4-Kbyte range in PCI Memory space and one 4-Kbyte range in PCI
I/O space.
The Universe II has the following two programmable registers: “PCI Configuration Base Address
Register (PCI_BS0)” on page 178 and “PCI Configuration Base Address 1 Register (PCI_BS1)” on
page 179. These register each specify the base address and address space for PCI access to the
Universe II’s registers. The PCI_BSx registers can be programmed through PCI Configuration space or
through a VMEbus access, to make the Universe II registers available anywhere in the 32-bit Memory
space and in I/O space (as offsets of the BS[31:12] field in PCIBSx).
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5. Registers Overview > Register Access from the PCI Bus
The SPACE bit of the PCI_BSx registers specifies whether the address lies in Memory space or I/O
space. The SPACE bit of these two registers are read-only. There is a power-up option that determines
the value of the SPACE bit of the PCI_BSx registers. At power-up the SPACE bit of the PCI_BS1
register is the negation of the SPACE bit of the PCI_BS0 register.
•
When the VA[1] pin is sampled low at power-up, the PCI_BS0 register’s SPACE bit is set to 1,
which signifies I/O space, and the PCI_BS1 register’s SPACE bit is set to 0, which signifies
Memory space.
•
When VA[1] is sampled high at power-up, the PCI_BS0 register’s SPACE register’s bit is set to 0,
which signifies Memory space, and the PCI_BS1 register’s SPACE bit is set to 1, which signifies
I/O space.
Universe II registers are not prefetchable and do not accept burst writes.
5.2.2.1
Conditions of Target-Retry
Attempts to access UCSR space from the PCI bus can be retried by the Universe II under the following
conditions:
5.2.3
•
While UCSR space is being accessed by a VMEbus master, PCI masters are retried.
•
If a VMEbus master is performing a RMW access to the UCSRs then PCI attempts to access the
USCR space results in a Target-Retry until AS* is negated.
•
If the Universe II registers are accessed through an ADOH cycle from the VMEbus, any PCI
attempt to access the UCSRs is retried until BBSY* is negated.
Locking the Register Block from the PCI bus
The Universe II registers can be locked by a PCI master by using a PCI locked transaction. When an
external PCI master locks the register block of the Universe II, an access to the register block from the
VMEbus does not terminate with the assertion of DTACK* until the register block is unlocked. Hence
a prolonged lock of the register block by a PCI resource may cause the VMEbus to timeout with a
BERR*.
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5.3
79
Register Access from the VMEbus
There are two mechanisms to access the UCSR space from the VMEbus. One method uses a VMEbus
Register Access Image (VRAI) which can put the UCSR in an A16, A24 or A32 address space. The
VRAI approach is useful in systems not implementing CR/CSR space as defined in the VME64
Specification. The other way to access the UCSR is as CR/CSR space, where each slot in the VMEbus
system is assigned 512 Kbytes of CR/CSR space.
5.3.1
VMEbus Register Access Image (VRAI)
The VMEbus Register Access Image occupies 4 Kbytes in A16, A24 or A32 space (depending upon
the programming of the address space described in Table 13, and Figure 13). All registers are accessed
as address offsets from the VRAI base address programmed in the “VMEbus Register Access Image
Base Address Register (VRAI_BS)” on page 304. The image can be enabled or disabled using the EN
bit in the“VMEbus Register Access Image Control Register (VRAI_CTL)” on page 303.
The VMEbus register access image is defined by Table 13.
Table 13: Programming the VMEbus Register Access Image
Field
Register Bits
Description
Address space
VAS in the VRAI_CTL
One of A16, A24, A32
Base address
BS[31:12] in the VRAI_BSi
Lowest address in the 4Kbyte slave image
Slave image
enable
EN in the VRAI_CTL
Enables VMEbus register access image
Mode
SUPER in the VRAI_CTL
Supervisor and/or Non-Privileged
Type
PGM in the VRAI_CTL
Program and/or Data
Note that the VRAI base address can be configured as a power-up option (see “Resets, Clocks and
Power-up Options” on page 129).
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5. Registers Overview > Register Access from the VMEbus
Figure 13: UCSR Access from the VMEbus Register Access Image
VMEbus Configuration
and Status Registers
(VCSR)
Total Memory
in A16, A24 or A32
Address Space
UNIVERSE DEVICE
SPECIFIC REGISTERS
(UDSR)
4 Kbytes
of UCSR
PCI CONFIGURATION
SPACE
(PCICS)
VRAI_BS
5.3.2
CR/CSR Accesses
The VME64 Specification assigns a total of 16 Mbytes of CR/CSR space for the VMEbus system. The
CR/CSR image is enabled with the EN bit in the “VMEbus CSR Control Register (VCSR_CTL)” on
page 305. This 16 Mbytes is broken up into 512 Kbytes per slot for a total of 32 slots. The first 512
Kbyte block is reserved for use by the Auto-ID mechanism. The UCSR space occupies the upper 4
Kbytes of the 512 Kbytes available for its slot position (see Figure 14). The base address of the
CR/CSR space allocated to the Universe II’s slot is programmed in the “VMEbus CSR Base Address
Register (VCSR_BS)” on page 331.
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81
For CSRs not supported in the Universe II and for CR accesses, the LAS field in the VCSR_CTL
register specifies the PCI bus command that is generated when the cycle is mapped to the PCI bus.
There is also a translation offset added to the 24-bit VMEbus address to produce a 32-bit PCI bus
address which is programmed in the “VMEbus CSR Translation Offset (VCSR_TO)” on page 306.
The registers in the UCSR space are located as address offsets from VCSR_BS.
These offsets are different from those used in the VRAI mechanisms, where the
first register in the UCSR has address offset of zero (see Table 34 on page 164).
When accessing the UCSR in CR/CSR space, the first register has an address
offset of 508 Kbytes (512 Kbytes minus 4 Kbytes). A simple approach for
determining the register offset when accessing the UCSR in CR/CSR space is to
add 508 Kbytes (0x7F000) to the address offsets given in Table 34 on page 164.
5.3.3
RMW and ADOH Register Access Cycles
The Universe II supports RMW and ADOH accesses to its registers.
A read-modify-write (RMW) cycle allows a VMEbus master to read from a VMEbus slave and then
write to the same resource without relinquishing VMEbus tenure between the two operations. The
Universe II accepts RMW cycles to any of its registers. This prevents an external PCI Master from
accessing the registers of the Universe II until VMEbus AS* is asserted. This is useful if a single RMW
access to the ADOH is required.
If a sequence of accesses to the Universe registers must be performed without intervening PCI access
to UCSR is required, then the VMEbus master should lock the Universe II through the use of ADOH.
This prevents an external PCI Master from accessing the registers of the Universe II until VMEbus
BBSY* is negated. It also prevents other VMEbus masters from accessing the Universe II registers.
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5. Registers Overview > Register Access from the VMEbus
Figure 14: UCSR Access in VMEbus CR/CSR Space
VMEbus Configuration
and Status Registers
(VCSR)
UNIVERSE DEVICE
SPECIFIC REGISTERS
(UDSR)
4 Kbytes
of UCSR
PCI CONFIGURATION
SPACE
(PCICS)
512 Kbytes
of VMEbus
CR/CSR Space
(Portion of 16 Mbyte
Total for Entire
VMEbus System)
Mapped
to
PCI
VCSR_BS
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5.4
83
Mailbox Registers
The Universe II has four 32-bit mailbox registers which provide an additional communication path
between the VMEbus and the PCI bus (see “Mailbox 0 Register (MBOX0)” on page 265 to “Mailbox 3
Register (MBOX3)” on page 268). The mailboxes support read and write accesses from either bus, and
may be enabled to generate interrupts on either bus when they are written to. The mailboxes are
accessible from the same address spaces and in the same manner as the other Universe II registers, as
described above.
Mailbox registers are useful for the communication of concise command, status, and parameter data.
The specific uses of mailboxes depend on the application. For example, they can be used when a
master on one bus needs to pass information (a message) on the other bus, without knowing where the
information should be stored in the other bus’s address space. Or they can be used to store the address
of a longer message written by the processor on one bus to the address space on the other bus, through
the Universe II. They can also be used to initiate larger transfers through the FIFO, in a user-defined
manner.
Often users will enable and map mailbox interrupts, so that when the processor writes to a mailbox
from one bus, the Universe II will interrupt the opposite bus. The interrupt service routine on the
opposite bus would then cause a read from this same mailbox.
Reading a mailbox cannot automatically trigger an interrupt. However, a similar effect can be achieved
by reading the mailbox and then triggering an interrupt through hardware or software. Or one may use
a “polling” approach, where one designates a bit in a mailbox register to indicate whether one has read
from the mailbox.
For details on how the mailbox interrupts are enabled and mapped, see “Interrupt Generation and
Handling” on page 109 and “Mailbox Register Access Interrupts” on page 122.
Applications will sometimes designate two mailboxes on one interface as being read/write from the
PCI bus, and read-only from the VMEbus, and the two other mailboxes as read/write from the VMEbus
and read-only from the PCI bus. This eliminates the need to implement locking. The Universe II
provides semaphores which can be also be used to synchronize access to the mailboxes. Semaphores
are described in the next section.
5.5
Semaphores
The Universe II has two general-purpose semaphore registers each containing four semaphores (
“Semaphore 0 Register (SEMA0)” on page 269 and “Semaphore 1 Register (SEMA1)” on page 270).
To gain ownership of a semaphore, a process writes a logic 1 to the semaphore bit and a unique pattern
to the associated tag field. If a subsequent read of the tag field returns the same pattern, the process can
consider itself the owner of the semaphore. A process writes a value of 0 to the semaphore to release it.
When a semaphore bit is a value of 1, the associated tag field cannot be updated. Only when a
semaphore is a value of 0 can the associated tag field be updated.
These semaphores shares resources in the system. While the Universe II provides the semaphores, it is
up to the user to determine access to which part of the system will be controlled by semaphores, and to
design the system to enforce these rules.
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5. Registers Overview > Semaphores
An example of a use of the semaphore involves gating access to the Special Cycle Generator (“Special
Cycle Generator” on page 61). It may be necessary to ensure that while one process uses the Special
Cycle Generator on an address, no other process accesses this address. Before performing a Special
Cycle, a process would be required to obtain the semaphore. This process would hold the semaphore
until the Special Cycle completes. A separate process that intends to modify the same address would
need to obtain the semaphore before proceeding (it need not verify the state of the SCYC[1:0] bit). This
mechanism requires that processes know which addresses might be accessed through the Special Cycle
Generator.
Each of the four semaphores in a semaphore register are intended to be accessed with 8-bit
transfers.
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6.
DMA Controller
Direct memory access (DMA) allows a transaction to occur between two devices without involving the
host processor (for example, a read transaction between a peripheral device and host processor
memory). Because less time is required to complete transactions, applications that contain one or more
DMA channels support faster read and write transfers than applications that support only host-assisted
transactions.
This chapter discusses the following topics:
6.1
•
“DMA Registers” on page 85
•
“Direct Mode Operation” on page 93
•
“Linked-list Mode” on page 96
•
“FIFO Operation and Bus Ownership” on page 101
•
“DMA Interrupts” on page 104
•
“DMA Channel Interactions with Other Channels” on page 105
•
“DMA Error Handling” on page 105
Overview
The Universe II has a DMA controller for high performance data transfer between the PCI bus and
VMEbus. It is operated through a series of registers that control the source and destination for the data,
length of the transfer and the transfer protocol to be used.
There are two modes of operation for the DMA: Direct Mode, and Linked List Mode. In direct mode,
the DMA registers are programmed directly by the external PCI master. In linked list mode, the
registers are loaded from PCI memory by the Universe II, and the transfer described by these registers
is executed. A block of DMA registers stored in PCI memory is called a command packet. A command
packet can be linked to another command packet, so that when the DMA has completed the operations
described by one command packet, it automatically moves on to the next command packed in the
linked-list of command packets.
6.2
DMA Registers
The DMA registers reside in a register block starting at offset 0x200. The registers describe the
following information for a single DMA transfer:
•
Source: where to transfer data from
•
Destination: where to transfer data to
•
Size: how much data to transfer
•
Attributes: the transfer attributes to use on the PCI bus and VMEbus.
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6. DMA Controller > DMA Registers
A final register contains status and control information for the transfer. While the DMA is active, the
registers are locked against any changes so that any writes to the registers will have no impact.
In direct-mode operation, these registers are programmed directly. In linked-list operation, they are
repeatedly loaded by the Universe II from command packets residing in PCI memory until the end of
the linked-list is reached (see “Linked-list Mode” on page 96).
6.2.1
Source and Destination Addresses
The source and destination addresses for the DMA reside in two registers: the “DMA PCI Bus Address
Register (DLA)” on page 235), and the “DMA VMEbus Address Register (DVA)” on page 236. The
determination of which is the source address, and which is the destination is made by the L2V bit in the
“DMA Transfer Control Register (DCTL)” on page 232. When set, the DMA transfers data from the
PCI to the VMEbus. The DLA becomes the PCI source register and DVA becomes the VMEbus
destination register. When cleared, the DMA transfers data from the VMEbus to PCI bus and DLA
becomes the PCI destination register; DVA becomes the VMEbus source register.
The PCI address may be programmed to any byte address in PCI Memory space. It cannot transfer to or
from PCI I/O or Configuration spaces.
The VMEbus address can also be programmed to any byte address, and can access any VMEbus
address space from A16 to A32 in supervisory or non-privileged space, and data or program space. The
setting of address space, A16, A24 or A32, is programmed in the VAS field of the “DMA Transfer
Control Register (DCTL)” on page 232. The sub-spaces are programmed in the PGM and SUPER
fields of the same register.
Although the PCI and VMEbus addresses may be programmed to any byte aligned address,
they must be 8-byte aligned to each other (the low three bits of each must be identical). If not
programmed with aligned source and destination addresses and an attempt to start the DMA
is made, the DMA does not start. It sets the protocol error bit (P_ERR) in the “DMA General
Control/Status Register (DGCS)” on page 238 and,if enabled to, generates an interrupt. When
this occurs linked-list operations cease.
In direct mode the user must reprogram the source and destination address registers (DMA, DLA)
before each transfer. These registers are not updated in direct mode. In linked-list mode, these registers
are updated by the DMA when the DMA is stopped, halted, or at the completion of processing a
command packet. If read during DMA activity, they return the number of bytes remaining to transfer
on the PCI side. All of the DMA registers are locked against any changes by the user while the DMA is
active.
When stopped due to an error situation, the DLA and DVA registers must not be used, but the DTBC is
valid (see “DMA Error Handling” on page 105 for details). At the end of a successful linked-list
transfer, the DVA and DLA registers point to the next address at the end of the transfer block, and the
DTBC register is 0.
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6.2.2
87
Non-incrementing DMA Mode
The VMEbus Non-Incrementing Mode (Non-Inc Mode) enables the DMA Controller to perform
transfers to or from a fixed VMEbus address. This means that the specified VMEbus address is not
incremented during DMA reads or writes. This applies to both Direct and Linked List modes of DMA
operation. For more information on these two types of DMA operation, refer to “Direct Mode
Operation” on page 93 and “Linked-list Mode” on page 96.
Unlike incrementing DMA operation, in Non-Inc Mode the DMA Controller can only perform 8-,16or 32-bit single cycle transfers on the VMEbus. This means that BLT and MBLT transfers cannot be
performed when operating in Non-Inc Mode.
6.2.2.1
Using Non-Inc Mode
The VMEbus Non-Inc Mode is enabled by writing a 1 to the NO_VINC bit in the “DMA Transfer
Control Register (DCTL)” on page 232.
In order to set-up and initiate DMA operation, the same steps which are described in the DMA
Controller Section in the Universe II User Manual must be followed for Non-Inc Mode.
The steps in setting-up and initiating DMA operation are as follows:
1. Program the tenure and interrupt requirements in the DGCS register (offset 0x220).
2. Program the source and destination addresses in the DLA and DVA registers.
3. Set the GO bit in the DGCS register.
6.2.2.2
Issues with Non-Inc Mode
The VMEbus Address
In Non-Inc Mode, the DVA register (offset 0x210) does not necessarily contain the fixed VMEbus
address. This register must not be read during a DMA Non-Inc Mode transfer. Once a DMA transfer
has been stopped — by setting the STOP bit of the DGCS register — the Non-Inc Mode transfer cannot
be restarted by simply writing a 1 to the GO bit of the DGCS register. The DVA register must be
reprogrammed with the required address before setting the DGCS GO bit.
The VON Counter
When the VON counter in the DGCS register reaches its programmed limit, the VMEbus Master
Interface of the Universe II stops transferring data until the VOFF timer expires. If the device is
operating in Non-Inc Mode, the VON counter has different limits than those indicated in the DMA
Controller section.
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The different settings are detailed in Table 14.
Table 14: VON Settings for Non-Inc Mode
VON
VMEbus Aligned DMA Transfer Count
001
128 bytes
010
256 bytes
011
512 bytes
100
1024 bytes
101
2048 bytes
110
4096 bytes
111
8192 bytes
P_ERR Flag Behavior
When the GO bit is set in Non-Inc Mode, the P_ERR flag of the “DMA General Control/Status
Register (DGCS)” on page 238 is 1 when the following conditions are true:
•
VCT bit of the “DMA Transfer Control Register (DCTL)” on page 232 has a value of 1
•
VDW field of the DCTL register has a value of 01 and bit 0 of the DVA register is a value of 0
•
VDW field of the DCTL register has a value of 10 and bits 1 and 0 of the DVA register are
non-zero
•
VDW field of the DCTL register has a value of 11.
Single Cycle Transfers
The Universe II performs 8-,16- or 32-bit single cycle transfers on the VMEbus. BLT and MBLT
transfers cannot be performed when operating in Non-Inc Mode.
6.2.2.3
Non-Inc Mode Performance
The transfer performance of DMA in Non-Inc Mode has been simulated at 14 MB/s for 32-bit writes
and at 8 MB/s for 32-bit reads. This performance was determined using ideal slave responses; lower
performance can be expected in actual systems.
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6.2.3
89
Transfer Size
The DMA can be programmed through the “DMA Transfer Byte Count Register (DTBC)” on page 234
to transfer any number of bytes from 1 byte to 16 MBytes. There are no alignment requirements to the
source or destination addresses. If the width of the data turnovers (8- through 64-bit on VMEbus and
32- or 64-bit on PCI) do not align to the length of the transfer or the source/destination addresses, the
DMA inserts transfers of smaller width on the appropriate bus. For example, if a 15-byte transfer is
programmed to start at address 0x1000 on the VMEbus, and the width is set for D32, the DMA will
perform three D32 transfers, followed by a D08 transfer. The Universe II does not generate unaligned
transfers. On a 32-bit PCI bus, if the start address was 0x2000, the DMA would generate three data
beats with all byte lanes enabled, and a fourth with three byte lanes enabled.
The DTBC register is not updated while the DMA is active (DMA is indicated as active by the ACT bit
in the DGCS register). At the end of a transfer it contains 0. However, if stopped by the user (through
the STOP bit in the DGCS register) or the DMA encounters an error, the DTBC register contains the
number of bytes remaining to transfer on the source side (see “DMA Error Handling” on page 105).
Starting the DMA while DTBC is 0 results in one of two situations. If the CHAIN bit in the “DMA
General Control/Status Register (DGCS)” on page 238 is not set, the DMA does not start; it performs
no action. If the CHAIN bit is set, then the DMA loads the DMA registers with the contents of the
command packet pointed to by the“DMA Command Packet Pointer (DCPP)” on page 237, and starts
the transfers described by that packet. Note that the DCPP[31:5] field of the DCPP register implies that
the command packets be 32-byte aligned (bits 4:0 of this register must be 0).
6.2.4
Transfer Data Width
The VMEbus and PCI bus data widths are determined by three fields in the “DMA Transfer Control
Register (DCTL)” on page 232. These fields affect the speed of the transfer. They should be set for the
maximum allowable width that the destination device is capable of accepting.
On the VMEbus, the DMA supports the following data widths:
•
D08(EO)
•
D8BLT
•
D16
•
D16BLT
•
D32
•
D64
•
D32BLT
•
D64BLT (MBLT)
The width of the transfer is set with the VDW field in the DCTL register. The VCT bit determines
whether or not the Universe II VMEbus Master will generate BLT transfers. The value of this bit only
has meaning if the address space is A24 or A32 and the data width is not 64 bits. If the data width is 64
bits the Universe II may perform MBLT transfers independent of the state of the VCT bit.
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The Universe II can perform data transfers smaller than that programmed in the VDW field in order to
bring itself into alignment with the programmed width. For example if the width is set for D32 and the
starting VMEbus address is 0x101, the DMA performs a D08 cycle. Only once it has achieved the
alignment set in the VDW field does it start D32 transfers. At the end of the transfer, the DMA also
performs more low-width transfers if the last address is not aligned to VDW. Similarly, if the VCT bit
is set to enable block transfers, the DMA can perform non-block transfers to bring itself into alignment.
On the PCI bus, the DMA provides the option of performing 32- or 64-bit PCI transactions through the
LD64EN bit in the “DMA Transfer Control Register (DCTL)” on page 232 If the Universe II has
powered-up on a 32-bit bus (see “Power-Up Options” on page 135), this bit has have no effect. If
powered-up on a 64-bit bus, this bit can provide some performance improvements when accessing
32-bit targets on that bus. Following the PCI 2.1 Specification, before a 64-bit PCI initiator starts a
64-bit transaction, it engages in a protocol with the intended target to determine if it is 64-bit capable.
This protocol typically consumes one clock period. To save bandwidth, the LD64EN bit can be cleared
to bypass this protocol when it is known that the target is only 32-bit capable.
6.2.5
DMA Command Packet Pointer
The “DMA Command Packet Pointer (DCPP)” on page 237 points to a 32-byte aligned address
location in PCI Memory space that contains the next command packet to be loaded once the transfer
currently programmed into the DMA registers has been successfully completed. When it has been
completed (or the DTBC register is 0 when the GO bit is set) the DMA reads the 32-byte command
packet from PCI memory and executes the transfer it describes.
6.2.6
DMA Control and Status
“DMA General Control/Status Register (DGCS)” on page 238 contains a number of fields that control
initiation and operation of the DMA as well as actions to be taken on completion.
6.2.6.1
DMA Initiation
Once all the parameters associated with the transfer have been programmed (source/destination
addresses, transfer length and data widths, and if desired, linked lists enabled), the DMA transfer is
started by setting the GO bit in the DGCS register. This causes the DMA first to examine the DTBC
register. If it is non-zero, it latches the values programmed into the DCTL, DTBC, DLA, and DVA
registers and initiates the transfer programmed into those registers. If DTBC=0, it checks the CHAIN
bit in the DGCS register and if that bit is cleared it assumes the transfer to have completed and stops.
Otherwise, if the CHAIN bit is set, it loads into the DMA registers the command packet pointed to by
the DCPP register and initiates the transfer describe there.
If the GO bit is set, but the Universe II has not been enabled as a PCI master with the BM (bus master
enable) bit in the “PCI Configuration Space Control and Status Register (PCI_CSR)” on page 172, or if
the DVA and DLA contents are not 64-bit aligned to each other, the transfer does not start, a protocol
error is indicated by the P_ERR bit in the “DMA General Control/Status Register (DGCS)” on
page 238 and, if enabled, an interrupt is generated.
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If the DMA has been terminated (stopped, halted, or error), all DMA registers contain values indicating
where the DMA terminated. Once all status bits have been cleared, the DMA may be restarted from
where it left off by simply setting the GO bit. The GO bit only has an effect if all status bits have been
cleared. These bits include STOP, HALT, DONE, LERR, VERR, and P_ERR and are located in the
“DMA General Control/Status Register (DGCS)” on page 238. These bits are all cleared by writing 1
to them, either before or while setting the GO bit.
The GO bit always returns a 0 when read independent of the DMA’s current state. Clearing the bit has
no impact at any time. The ACT bit in the DGCS register indicates whether the DMA is currently
active. It is set by the DMA once the GO bit is set, and cleared when the DMA is idle. Generally, when
the ACT bit is cleared, one of the other status bits in the DGCS register is set (DONE, STOP, HALT,
LERR, VERR, or P_ERR), indicating why the DMA is no longer active.
6.2.6.2
DMA VMEbus Ownership
Two fields in the DGCS register determine how the DMA shares the VMEbus with the other two
potential masters in the Universe II (PCI Target Channel, and Interrupt Channel), and with other
VMEbus masters on the bus. These fields are: VON and VOFF.
VON
VON affects how much data the DMA transfers before giving the opportunity to another master (either
the Universe II or an external master) to assume ownership of the bus. The VON counter is used to
temporarily stop the DMA from transferring data once a programmed number of bytes have been
transferred (256 bytes, 512 bytes, 1K, 2K, 4K, 8K, or 16K). When performing MBLT transfers on the
VMEbus, the DMA stops performing transfers within 2048 bytes after the programmed VON limit has
been reached. When not performing MBLT transfers, the DMA will stop performing transfers within
256 bytes once the programmed limit has been reached. When programmed for Release-When-Done
operation, the Universe II performs an early release of BBSY* when the VON counter reaches its
programmed limit. VON may be disabled by setting the field to zero. When the VON bit is set to 0, the
DMA continues transferring data as long as it is able.
There are other conditions under which the DMA may relinquish bus ownership. See“FIFO Operation
and Bus Ownership” on page 101 for details on the VMEbus request and release conditions for the
DMA.
VOFF
VOFF affects how long the DMA waits before re-requesting the bus after the VON limit has been
reached. By setting VOFF to 0, the DMA immediately re-requests the bus once the VON boundary has
been reached. Since the DMA operates in a round-robin fashion with the PCI Target Channel, and in a
priority fashion with the Interrupt Channel, if either of these channels require ownership of the
VMEbus, they receive it at this time.
VOFF is only invoked when VMEbus tenure is relinquished due to encountering the VON boundary.
When the VMEbus is released due to other conditions (for example, the DMAFIFO has become full
while reading from the VMEbus), it will be re-requested as soon as that condition is cleared. The
VOFF timer can be programmed to various time intervals from 0µs to 1024µs. See “FIFO Operation
and Bus Ownership” on page 101 for details on the VMEbus request and release conditions for the
DMA.
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See “DMA Channel Interactions with Other Channels” on page 105 for information on other
mechanisms which can delay the DMA Channel from acquiring the VMEbus or the PCI bus.
6.2.6.3
DMA Completion and Termination
Normally, the DMA continues processing its transfers and command packets until either it completes
all requests, or it encounters an error. There are also two methods for the user to interrupt this process
and cause the DMA to terminate prematurely: STOP and HALT. STOP causes the DMA to terminate
immediately, while HALT causes the DMA to terminate when it has completed processing the current
command packet in a linked list.
STOP
When the STOP_REQ bit in the DGCS register is set, it tells the DMA to cease its operations on the
source bus immediately. Remaining data in the FIFO continues to be written to the destination bus until
the FIFO is empty. Once the FIFO is empty, the STOP bit in the same register is set and, if enabled, an
interrupt generated. The DMA registers contain the values that the DMA stopped at: the DTBC register
contains the number of bytes remaining in the transfer, the source and destination address registers
contain the next address to be read/written, the DCPP register contains the next command packet in the
linked-list, and the DCTL register contains the transfer attributes.
If read transactions are occurring on the VMEbus, then setting a stop request can be affected by the
VOFF timer. If the STOP_REQ bit is set while the DMA is lying idle waiting for VOFF to expire
before re-starting reads, then the request remains pending until the VOFF timer has expired and the bus
has been granted.
HALT
HALT provides a mechanism to interrupt the DMA at command packet boundaries during a linked-list
mode transfer. In contrast, a STOP requests the DMA to be interrupted immediately, while halt takes
effect only when the current command packet is complete. A halt is requested of the DMA by setting
the HALT_REQ bit in the DGCS register. This causes the DMA to complete the transfers defined by
the current contents of the DMA registers and, if the CHAIN bit is set, load in the next command
packet. The DMA then terminates, the HALT bit in the DGCS register is set, and, if enabled, an
interrupt generated.
After a stop or halt, the DMA can be restarted from the point it left off by setting the GO bit; but before
it can be re-started, the STOP and HALT bits must be cleared.
Regardless of how the DMA stops—whether normal, bus error or user interrupted—the DMA indicates
in the DGCS register why it stopped. The STOP and HALT bits are set in response to a stop or halt
request. The DONE bit gets set when the DMA has successfully completed the DMA transfer,
including all entries in the linked-list (if operating in that mode). There are also three bits that are set in
response to error conditions: LERR in the case of Target-Abort encountered on the PCI bus; VERR in
the case of a bus error encountered on the VMEbus; and P_ERR in the case that the DMA has not been
properly programmed (the DMA was started with the BM bit in the PCI_CSR register not enabled, or
the DLA and DVA registers were not 64-bit aligned, (see “Source and Destination Addresses” on
page 86). Before the DMA can be restarted, each of these status bits must be cleared.
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93
When the DMA terminates, an interrupt may be generated to VMEbus or PCI bus. The user has control
over which DMA termination conditions cause the interrupt through the INT_STOP, INT_HALT,
INT_DONE, INT_LERR, INT_VERR, and INT_P_ERR bits in the DGCS register.
6.3
Direct Mode Operation
When operated in direct mode, the Universe II DMA is set through manual register programming.
Once the transfer described by the DVA, DLA, DTBC and DCTL registers has been completed, the
DMA sits idle awaiting the next manual programming of the registers.
Figure 15 describes the steps involved in operating the DMA in direct mode.
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6. DMA Controller > Direct Mode Operation
Figure 15: Direct Mode DMA transfers
Step 1: Program DGCS
with tenure and interrupt
requirements
Step 2: Program
source/destination
addresses, & transfer
size/attributes
Step 3: Ensure status bits are clear
Step 4: Set GO bit
Step 5: Await termination
of DMA
Normal
Termination?
No
Handle error
Yes
Yes
More
transfers
required?
No
Done
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In Step 1, the “DMA General Control/Status Register (DGCS)” on page 238is set up
— The CHAIN bit is cleared, VON and VOFF are programmed with the appropriate values for
controlling DMA VMEbus tenure, and the interrupt bits (INT_STOP, INT_HALT,
INT_DONE, INT_LERR, INT_VERR, and INT_P_ERR) are programmed to enable
generation of interrupts based on DMA termination events. DMA interrupt enable bits in the
LINT_EN or VINT_EN bits should also be enabled as necessary (see “PCI Interrupt
Generation” on page 111 and “VMEbus Interrupt Generation” on page 113 for details on
generating interrupts).
In Step 2, the actual transfer is programmed into the DMA
— Source and destination start addresses into the DLA and DVA registers, transfer count into the
DTBC register, and transfer width, direction and VMEbus address space into the DCTL
register. These should be reprogrammed after each transfer.
In Step 3, ensure that if any status bits (DONE, STOP, HALT, LERR, VERR, or P_ERR) remain set
from a previous transfer they are cleared.
— P_ERR must not be updated at the same time as Step 4, otherwise the P_ERR that may be
generated by setting GO may be missed (see Step 4). These bits can be cleared as part of Step
1.
In Step 4, with the transfer programmed, the GO bit in DGCS must be set.
— If the DMA has been improperly programmed, either because the BM bit in the PCI_CSR has
not been set to enable PCI bus mastership, or the source and destination start addresses are not
aligned, then P_ERR will be asserted. Otherwise, the ACT bit will be set, and the DMA will
then start transferring data, sharing ownership of the VMEbus with the PCI Target and
Interrupt channels and the PCI bus with the VMEbus Slave Channel.
In Step 5, the DMA waits for termination of the DMA transfers.
— The DMA continues with the transfers until it:
–
Completes all transfers
–
Terminates early with the STOP_REQ bit
–
Encounters an error on the PCI bus or VMEbus
Each of these conditions cause the ACT bit to clear, and a corresponding status bit to be set in the
DGCS register. If enabled in Step 1, an interrupt is generated. Once the software has set the GO bit, the
software can monitor for DMA completion by either waiting for generation of an interrupt, or by
polling the status bits. It is recommended that a background timer also be initiated to time-out the
transfer. This ensures the DMA has not been hung up by a busy VMEbus, or other such system issues.
If an early termination is desired (perhaps because a higher priority operation is required) the
STOP_REQ bit in the DGCS register can be set. This stops all DMA operations on the source bus
immediately, and set the STOP bit in the same register when the last piece of queued data in the DMA
FIFO has been written to the destination bus. Attempting to terminate the transfer with the HALT_REQ
bit has no effect in direct mode operation since this bit only requests the DMA to stop between
command packets in linked-list mode operation.
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6. DMA Controller > Linked-list Mode
When the software has detected completion, it must verify the status bits in the DGCS register to see
the reason for completion. If one of the error bits have been set it proceeds into an error handling
routine (see “DMA Error Handling” on page 105). If the STOP bit was set, the software must take
whatever actions were programmed when it set the STOP_REQ bit. For example, if it was stopped for
a higher priority transfer, it might record the DLA, DVA and DTBC registers, and then reprogram them
with the higher priority transfer. When that has completed it can restore the DVA, DLA and DTBC
registers to complete the remaining transfers.
If the DONE bit was set, it indicates that the DMA completed its requested transfer successfully, and if
more transfers are required, the software can proceed to Step 2 to start a new transfer.
6.4
Linked-list Mode
Unlike direct mode, in which the DMA performs a single block of data at a time, linked-list mode
allows the DMA to transfer a series of non-contiguous blocks of data without software intervention.
Each entry in the linked-list is described by a command packet which parallels the DMA register
layout. The data structure for each command packet is the same (see Figure 16 below), and contains all
the necessary information to program the DMA address and control registers. It could be described in
software as a record of eight 32-bit data elements. Four of the elements represent the four core registers
required to define a DMA transfer: DCTL, DTBC, DVA, and DLA. A fifth element represents the
DCPP register which points to the next command packet in the list. The least two significant bits of the
DCPP element (the PROCESSED and NULL bits) provide status and control information for linked
list processing.
The PROCESSED bit indicates whether a command packet has been processed or not. When the DMA
processes the command packet and has successfully completed all transfers described by this packet, it
sets the PROCESSED bit to 1 before reading in the next command packet in the list. The PROCESSED
bit must be initially set for 0. This bit, when set to 1, indicates that this command packet has been
disposed of by the DMA and its memory can be de-allocated or reused for another transfer description.
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97
Figure 16: Command Packet Structure and Linked List Operation
First Command Packet
in Linked-List
DCTL Register
Linked-List Start
Address in
Command Packet
Pointer Register
DTBC Register
Register information
copied to DMA Control
and Address Registers
DLA Register
reserved
DVA Register
reserved
DCPP Register
r PN
reserved
DCPP points
to next command
packet
in Linked-List
Second Command Packet
in Linked-List
r = reserved
P = processed bit
(after command packet is processed
the bit is set to 1)
N = null bit
DCTL Register
DTBC Register
DLA Register
reserved
DVA Register
reserved
DCPP Register
r PN
reserved
N = 0 for another command packet
Last Command Packet
in Linked-List
DCTL Register
DTBC Register
DLA Register
reserved
DVA Register
reserved
DCPP Register
reserved
r PN
N = 1 for last command packet
The NULL bit indicates the termination of the entire linked list. If the NULL bit is set to 0, the DMA
processes the next command packet pointed to by the command packet pointer. If the NULL bit is set
to 1 then the address in the command packet pointer is considered invalid and the DMA stops at the
completion of the transfer described by the current command packet.
Figure 17 outlines the steps in programming the DMA for linked-list operation.
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6. DMA Controller > Linked-list Mode
Figure 17: DMA Linked List Operation
Step 1: Program DGCS
with tenure and interrupt
requirements
Step 2 : Set up linked-list
in PCI memory space
Step 3 : Clear DTBC
register, program DCPP
Step 4 : Set GO bit
Step 5 : Await termination
of DMA
Normal
Termination?
No
handle error
Yes
Done
In Step 1, the DGCS register is set up
— The CHAIN bit is set, VON and VOFF are programmed with the appropriate values for
controlling DMA VMEbus tenure, and the interrupt bits (INT_STOP, INT_HALT,
INT_DONE, INT_LERR, INT_VERR, and INT_P_ERR) are programmed to enable
generation of interrupts based on DMA termination events. DMA interrupt enable bits in the
LINT_EN or VINT_EN bits should also be enabled as necessary (“PCI Interrupt Generation”
on page 111 and “VMEbus Interrupt Generation” on page 113).
In Step 2, the linked-list structure is programmed with the required transfers.
— The actual structure may be set up at any time with command packet pointers pre-programmed
and then only the remaining DMA transfer elements need be programmed later. One common
way is to set up the command packets as a circular queue: each packet points to the next in the
list, and the last points to the first. This allows continuous programming of the packets without
having to set-up or tear down packets later.
Once the structure for the linked-list is established, the individual packets are programmed with the
appropriate source and destination addresses, transfer sizes and attributes.
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In Step 3, Clear the DTBC register and program the DCPP register to point to the first command packet
in the list.
When using the DMA to perform linked-list transfers, it is important to ensure that the DTBC
register contains a value of zero before setting the GO bit of the DGCS register. Otherwise,
the DMA cannot read the first command packet but instead performs a direct mode transfer
based on the contents of the DCTL, DTBC, DLA, DVA and DGCS registers. After this direct
mode transfer is completed, the PROCESSED bit of the first command packet is programmed
with a value of 1 even though the packet was not actually processed. The DMA continues as
expected with the next command packet.
In Step 4, to start the linked-list transfer, set the GO bit in the DGCS register.
— The DMA first performs the transfers defined by the current contents of the DCTL, DTBC,
DVA and DLA registers. Once that is complete it then starts the transfers defined by the
linked-list pointed to in the DCPP register.
In Step 5, await and deal with termination of the DMA.
— Once the DMA channel is enabled, it processes the first command packet as specified by the
DCPP register. The DMA transfer registers are programmed by information in the command
packets and the DMA transfer steps along each command packet in sequence (see Figure 16).
The DMA terminate when one of the following conditions are met:
–
Processes a command packet with the NULL bit set indicating the last packet of the list
–
Stops with the STOP_REQ bit in the DGCS register
–
Halts with the HALT_REQ bit in the DGCS register
–
Encounters an error on either the PCI bus or VMEbus
Each of these conditions cause the ACT bit to clear, and a corresponding status bit to be set in the
DGCS register. If enabled in step 1, an interrupt is generated. Once the software has set the GO bit, the
software can monitor for DMA completion by either waiting for generation of an interrupt, by polling
the status bits in the DGCS register, or by polling the PROCESSED bits of the command packets. It is
recommended that a background timer also be initiated to time-out the transfer. This ensures that the
DMA has not been hung up by a busy VMEbus, or other such system issues.
Linked-list mode can be halted by setting the HALT_REQ bit in the “DMA Transfer Control Register
(DCTL)” on page 232. When the HALT_REQ bit is set, the DMA terminates when all transfers defined
by the current command packet is complete. It then loads the next command packet into its registers.
The HALT bit in the DGCS register is asserted, and the ACT bit in the DGCS register is cleared. The
PROCESSED bit in the linked-list is set to 1 approximately 1 s after the HALT bit is set: therefore
after a DMA halt the user should wait at least 1 s before checking the status of the PROCESSED bit.
The DMA can be restarted by clearing the HALT status bit and setting the GO bit during the same
register write. If the DMA is restarted, the ACT bit is set by the Universe II and execution continues as
if no HALT had occurred (that is, the Universe II processes the current command packet (see
Figure 16)).
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In contrast to a halt, the DMA can also be immediately terminated through the STOP_REQ bit. This
stops all DMA operations on the source bus immediately, and set the STOP bit in the same register
when the last piece of queued data in the DMA FIFO has been written to the destination bus.
Once stopped, the DVA, DLA and DTBC registers contain values indicating the next addresses to
read/write and the number of bytes remaining in the transfer. Clearing the STOP bit and setting the GO
bit causes the DMA to start-up again from where it left off, including continuing with subsequent
command packets in the list.
If the DMA is being stopped to insert a high priority DMA transfer, the remaining portion of the DMA
transfer can be stored as a new command packet inserted at the top of the linked list. A new command
packet with the attributes of the high priority transfer is then placed before that one in the list. Now the
linked list is set up with the high priority packet first, followed be the remainder of the interrupted
packet, followed in turn by the rest of the linked list. Finally, the DTBC register is cleared and the
DCPP programmed with a pointer to the top of the list where the high priority command packet has
been placed. When the GO bit is set (after clearing the STOP status bit in the DGCS register), the DMA
performs the transfers in the order set in the linked list. For more details on updating the linked list see
“Linked-list Updating” on page 100.
DMA transfers continue until the DMA encounters a command packet with the NULL bit set to 1,
indicating that the last packet has been reached. At this point, the DMA stops, the DONE bit is set, and
the ACT flag is cleared. As it completes the transfers indicated by each command packet, the DMA
sets the PROCESSED bit in that command packet before reading in the next command packet and
processing its contents.
6.4.1
Linked-list Updating
The Universe II provides a mechanism which enables the linked-list to be updated with additional
linked list entries without halting or stopping the DMA. This takes place through the use of a
semaphore in the device: the UPDATE bit in the “DMA Linked List Update Enable Register
(D_LLUE)” on page 241. This bit is meant to ensure that the DMA does not read a command packet
into the DMA registers while the command packet (outside the Universe II) is being updated. This
semaphore does not prevent external masters from updating the DMA registers.
Adding to a linked list begins by writing a 1 to the UPDATE bit. The DMA checks this bit before
proceeding to the next command packet. If the UPDATE bit is 0, then the DMA locks the UPDATE bit
against writes and proceeds to the next command packet. If the UPDATE bit is 1, then the DMA waits
until the bit is cleared before proceeding to the next command packet. Setting the UPDATE bit is a
means of stalling the DMA at command packet boundaries while local logic updates the linked-list.
In order to ensure that the DMA is not currently reading a command packet during updates, the update
logic must write a 1 to the UPDATE bit and read a value back. If a 0 is read back from the UPDATE bit,
then the DMA is currently reading a command packet and has locked the UPDATE bit against writes.
If a 1 is read back from the UPDATE bit, then the DMA is idle or processing a transaction and
command packets can be updated. If the DMA attempts to proceed to the next command packet during
the update, it encounters the set UPDATE bit and wait until the bit is cleared.
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If a set of linked command packets has already been created with empty packets at the end of new
transfers, adding to the end of the current linked list is accomplished by the following steps:
1. Get UPDATE valid (write 1, read back 1)
2. Program attributes for new transfer in next available packet in list
3. Change null pointer (on previous tail of linked list)
4. Release update (clear the UPDATE bit)
After updating the linked list, the DMA controller is in one of the following conditions:
1. It can be active and working its way through the linked list. In this case, no further steps are
required.
2. The DMA can be idle (done) because it reached the final command packet. If a full set of linked
command packets had already been created ahead of time, then the DCPP register points to the
most recently programmed command packet, and the DTBC register would be zero. The DMA can
be started on the new packet by simply clearing the DONE bit and setting the GO bit in the DGCS
register. If a set of command packets have not been created ahead of time, the DCPP register can
not be programmed to any valid packet, and needs programming to the newly programmed packet.
3. The DMA has encountered an error. In this circumstance, see “DMA Error Handling” on page 105
for how to handle DMA errors.
Operation can be considerably simplified by ensuring that sufficient command packets have been
created during system initialization, probably in a circular queue. In this fashion, when a new entry is
added to the list, it is simply a matter of programming the next available entry in the list with the new
transfer attributes and changing the previously last packet's NULL bit to zero. The DCPP register is
guaranteed to point to a valid command packet, so upon updating the list, both cases 1 and 2 above can
be covered by clearing the DONE bit and setting the GO bit. This has no effect for case 1 since the
DMA is still active, and restarts the DMA for case 2.
If an error has been encountered by the DMA (case 3), setting the GO bit and clearing the DONE bit is
not be sufficient to restart the DMA—the error bits in the DGCS register also has to be cleared before
operation can continue.
6.5
FIFO Operation and Bus Ownership
The DMA uses a 256-byte, 64-bit FIFO (DMAFIFO). This supports high performance DMA transfers.
In general, the DMA reads data from the source, and stores it as transactions in the FIFO. On the
destination side, the DMA requests ownership of the master and once granted begins transfers.
Transfers stop on the source side when the FIFO fills, and on the destination side when the FIFO
empties.
6.5.1
PCI-to-VMEbus Transfers
PCI-to-VMEbus transfers involve the Universe II reading from the PCI bus and writing to the
VMEbus.
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The PCI bus is requested for the current read once 128 bytes are available in the DMAFIFO. The DMA
Channel fills the DMAFIFO using PCI read transactions with each transaction broken at address
boundaries determined by the programmed PCI aligned burst size (PABS field in the “Master Control
Register (MAST_CTL)” on page 271). This ensures that the DMA makes optimal use of the PCI bus
by always generating bursts of 32, 64 or 128 bytes with zero wait states.
The DMA packs read data into the DMAFIFO to the full 64-bit width of the FIFO, independent of the
width of the PCI bus, or the data width of the ensuing VMEbus transaction. The PCI read transactions
continue until either the DMA has completed the full programmed transfer, or there is insufficient room
available in the DMAFIFO for a full transaction. The available space required for another burst read
transaction is again 128 bytes.
Since the VMEbus is typically much slower than the PCI bus, the DMAFIFO can fill
frequently during PCI to VMEbus transfers, though the depth of the FIFO helps to minimize
this situation.
When the DMAFIFO fills, the PCI bus is free for other transactions (for example, between other
devices on the bus or possibly for use by the Universe II’s VMEbus Slave Channel). The DMA only
resumes read transactions on the PCI bus when the DMAFIFO has space for another aligned burst size
transaction.
The DMA can prefetch extra read data from the external PCI target. This means that the
DMA must only be used with memory on the PCI bus which has no adverse side-effects when
prefetched. The Universe II prefetches up to the aligned address boundary defined in the
PABS field of the MASC_CTL register.
On the VMEbus, the actual programmed number of bytes in the “DMA Transfer Byte Count
Register (DTBC)” on page 234 are written. Prefetching can be avoided by programming the
DMA for transfers that terminate at the PABS boundary. If further data is required beyond the
boundary, but before the next boundary, the DTBC register may be programmed to eight byte
transfers. The DMA fetches the full eight bytes, and nothing more. Programming the DTBC
to less than eight bytes still results in eight bytes fetched from PCI.
The DMA requests ownership of the Universe II's VMEbus Master Interface once 64 bytes of data
have been queued in the DMAFIFO (see “VMEbus Requester” on page 25 on how the VMEbus Master
Interface is shared between the DMA, the PCI Target Channel, and the Interrupt Channel). The
Universe II maintains ownership of the Master Interface until one of the following conditions are met:
•
DMAFIFO is empty
•
DMA block is complete
•
DMA is stopped
•
a linked list is halted
•
DMA encounters an error
•
DMA VMEbus tenure limit (VON in the DGCS register)
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The DMA can be programmed to limit its VMEbus tenure to fixed block sizes using the VON field in
the “DMA General Control/Status Register (DGCS)” on page 238. With VON enabled, the DMA
relinquishes ownership of the Master Interface at defined address boundaries. See “DMA VMEbus
Ownership” on page 91.
To further control the DMA’s VMEbus ownership, the VOFF timer in the DGCS register can be used to
program the DMA to remain off the VMEbus for a specified period when VMEbus tenure is
relinquished. See “DMA VMEbus Ownership” on page 91.
The DMA Channel unpacks the 64-bit data queued in the DMAFIFO to whatever the programmed
transfer width is on the VMEbus (D16, D32, or D64). The VMEbus Master Interface delivers the data
in the DMAFIFO according to the VMEbus cycle type programmed into the “DMA Transfer Control
Register (DCTL)” on page 232. The DMA provides data to the VMEbus until one of the following
conditions are met:
•
DMA FIFO empties
•
DMA VMEbus Tenure Byte Count expires.
— Set in the VON in the “DMA General Control/Status Register (DGCS)” on page 238
If the DMAFIFO empties transfers on the VMEbus stop and, if the cycle being generated is a block
transfer, then the block is terminated (AS* negated). The VMEbus ownership is relinquished by the
DMA. The DMA does not re-request VMEbus ownership until another eight entries are queued in the
DMAFIFO, or the DMA Channel has completed the current Transfer Block on the PCI bus (see
“VMEbus Release” on page 27).
PCI bus transactions are the full width of the PCI data bus with appropriate byte lanes enabled. The
maximum VMEbus data width is programmable to 8, 16, 32, or 64-bit. Byte transfers can be only of
type DO8 (EO). Because the PCI bus has a more flexible byte lane enabling scheme than the VMEbus,
the Universe II can be required to generate a variety of VMEbus transaction types to handle the byte
resolution of the starting and ending addresses (see “Data Transfer” on page 52).
6.5.2
VMEbus-to-PCI Transfers
VMEbus-to-PCI transfers involve the Universe II reading from the VMEbus and writing to the PCI
bus.
With DMA transfers in this direction, the DMA Channel begins to queue data in the DMAFIFO as
soon as there is room for 64 bytes in the DMAFIFO. When this watermark is reached, the DMA
requests the VMEbus (through the VMEbus Master Interface) and begins reading data from the
VMEbus. The Universe II maintains VMEbus ownership until one of the following conditions are met:
•
DMAFIFO is full
•
DMA block is complete
•
DMA is stopped
•
a linked list is halted
•
DMA encounters an error
•
VMEbus tenure limit is reached (VON in the DGCS register)
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The DMA can be programmed to limit its VMEbus tenure to fixed block sizes using the VON field in
the “DMA General Control/Status Register (DGCS)” on page 238. With VON enabled, the DMA will
relinquish ownership of the Master Interface at defined address boundaries (see “DMA VMEbus
Ownership” on page 91).
To further control the DMA’s VMEbus ownership, the VOFF timer in the DGCS register can be used to
program the DMA to remain off the VMEbus for a specified period when VMEbus tenure is
relinquished. See “DMA VMEbus Ownership” on page 91.
Entries in the DMAFIFO are delivered to the PCI bus as PCI write transactions as soon as there are 128
bytes available in the DMAFIFO. If the PCI bus responds too slowly, the DMAFIFO runs the risk of
filling before write transactions can begin at the PCI Master Interface. Once the DMAFIFO reaches a
nearly full state (three entries remaining) the DMA requests that the VMEbus Master Interface
complete its pending operations and stop. The pending read operations fill the DMAFIFO. Once the
pending VMEbus reads are completed (or the VON timer expires), the DMA relinquishes VMEbus
ownership and only re-requests the VMEbus Master Interface once 64 bytes again become available in
the DMAFIFO. If the bus was released due to encountering a VON boundary, the bus is not
re-requested until the VOFF timer expires.
PCI bus transactions are the full width of the PCI data bus with appropriate byte lanes enabled. The
maximum VMEbus data width is programmable to 8, 16, 32, or 64 bits. Byte transfers can be only of
type DO8 (EO). Because the PCI bus has a more flexible byte lane enabling scheme than the VMEbus,
the Universe II can be required to generate a variety of VMEbus transaction types to handle the byte
resolution of the starting and ending addresses (see “Universe II as PCI Target” on page 57).
6.6
DMA Interrupts
The Interrupt Channel in the Universe II handles a single interrupt sourced from the DMA Channel
which it routes to either the VMEbus or PCI bus through the DMA bits in the LINT_EN and VINT_EN
registers. There are six internal DMA sources of interrupts and these are all routed to this single
interrupt. Each of these six sources can be individually enabled, and are listed in Table 15. Setting the
enable bit enables the corresponding interrupt source.
Table 15: DMA Interrupt Sources and Enable Bits
Interrupt Source
Enable Bit
Stop Request
INT_STOP
Halt Request
INT_HALT
DMA Completion
INT_DONE
PCI Target-Abort or Master-Abort
INT_LERR
VMEbus Error
INT_VERR
Protocol Error
INT_M_ERR
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Once an enabled DMA interrupt has occurred the corresponding DMA bit in the “PCI
Interrupt Status Register (LINT_STAT)” on page 244 and “VMEbus Interrupt Status Register
(VINT_STAT)” on page 251 are set — regardless of whether the LINT_EN or VINT_EN
enable bits have been set. Each one must be cleared independently. Clearing either the
LINT_STAT or VINT_STAT registers does not clear the other. See “Interrupt Generation and
Handling” on page 109.
6.7
DMA Channel Interactions with Other Channels
This section describes the impact that the PCI Bus Target Channel and the VMEbus Slave Channel can
have on the DMA Channel.
The Universe II does not apply PCI 2.1 Specification transaction ordering requirements to the
DMA Controller. Reads and writes through the DMA Controller can occur independently of
the other channels.
ADOH cycles and RMW cycles through the VMEbus Slave Channel do impact on the DMA Channel.
Once an external VMEbus master locks the PCI bus, the DMA Controller does not perform transfers
on the PCI bus until the Universe II is unlocked (see “VMEbus Lock Commands (ADOH Cycles)” on
page 36). When an external VMEbus Master begins a RMW cycle, at some point a read cycle appears
on the PCI bus. During the time between when the read cycle occurs on the PCI bus and when the
associated write cycle occurs on the PCI bus, no DMA transfers occurs on the PCI bus (see “VMEbus
Read-Modify-Write Cycles (RMW Cycles)” on page 37).
If the PCI Target Channel locks the VMEbus using VOWN, no DMA transfers takes place on the
VMEbus (see “Using the VOWN bit” on page 64).
6.8
DMA Error Handling
This section describes how the Universe II responds to errors involving the DMA, and how the user
can recover from them. The software source of a DMA error is a protocol, and the hardware source of a
DMA error is a VMEbus error, or PCI bus Target-Abort or Master-Abort.
6.8.1
DMA Software Response to Error
While the DMA is operating normally, the ACT bit in the “DMA General Control/Status Register
(DGCS)” on page 238. Once the DMA has terminated, it clears this bit, and sets one of six status bits in
the same register. The DONE bit will be set if the DMA completed all its programmed operations
normally. If the DMA is interrupted, either the STOP or HALT bits are set. If an error has occurred, one
of the remaining three bits, LERR, VERR, or P_ERR, is set. All six forms of DMA terminations can be
optionally set to generate a DMA interrupt by setting the appropriate enable bit in the DGCS register
(see “DMA Interrupts” on page 104).
•
LERR is set if the DMA encounters an error on the PCI bus (either a Master-Abort or
Target-Abort)
— Bits in the “PCI Configuration Space Control and Status Register (PCI_CSR)” on page 172
indicate which of these conditions caused the error.
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6. DMA Controller > DMA Error Handling
•
VERR is set if the DMA encounters a bus error on the VMEbus. This is through a detected
assertion of BERR* during a DMA cycle.
•
P_ERR is set if the GO bit in the DGCS register is set to start the DMA, and the DMA has been
improperly programmed either because the BM bit in the PCI_CSR disables PCI bus mastership,
or the source and destination start addresses are not aligned (see “Source and Destination
Addresses” on page 86).
Whether the error occurs on the destination or source bus, the DMA_CTL register contains the
attributes relevant to the particular DMA transaction. The DTBC register provides the number of bytes
remaining to transfer on the PCI side. The DTBC register contains valid values after an error. The DLA
and DVA registers should not be used for error recovery.
6.8.2
DMA Hardware Response to Error
When the error condition (VMEbus Error, Target-Abort, or Master-Abort) occurs on the source bus
while the DMA is reading from the source bus, the DMA stops reading from the source bus. Any data
previously queued within the DMAFIFO is written to the destination bus. Once the DMAFIFO
empties, the error status bit is set and the DMA generates an interrupt (if enabled by INT_LERR or
INT_VERR in the DGCS register—see “DMA Interrupts” on page 104).
When the error condition (VMEbus Error, Target-Abort, or Master-Abort) occurs on the destination
bus while the DMA is writing data to the destination bus, the DMA stops writing to the destination bus,
and it also stops reading from the source bus. The error bit in the DGCS register is set and an interrupt
asserted (if enabled).
6.8.2.1
Interrupt Generation During Bus Errors
To generate an interrupt from a DMA error, there are two bits in the DGCS register, and one bit each in
the VINT_EN and LINT_EN registers. In the DGCS register the INT_LERR bit enables the DMA to
generate an interrupt to the Interrupt Channel after encountering an error on the PCI bus. The
INT_VERR enables the DMA to generate an interrupt to the Interrupt Channel upon encountering an
error on the VMEbus. Upon reaching the Interrupt Channel, all DMA interrupts can be routed to either
the PCI bus or VMEbus by setting the appropriate bit in the enable registers. All DMA sources of
interrupts (Done, Stopped, Halted, VMEbus Error, and PCI Error) constitute a single interrupt into the
Interrupt Channel.
6.8.3
Resuming DMA Transfers
When a DMA error occurs (on the source or destination bus), the status bits must be read in order to
determine the source of the error. If it is possible to resume the transfer, the transfer should be resumed
at the address that was in place up to 256 bytes from the current byte count. The original addresses
(DLA and DVA) are required in order to resume the transfer at the appropriate location. However, the
values in the DLA and the DVA registers should not be used to reprogram the DMA, because they are
not valid once the DMA begins. In direct mode, it is the user’s responsibility to record the original state
of the DVA and DLA registers for error recovery. In Linked-List mode, the user can refer to the current
Command Packet stored on the PCI bus (whose location is specified by the DCPP register) for the
location of the DVA and DLA information.
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The DTBC register contains the number of bytes remaining to transfer on the source side. The
Universe II does not store a count of bytes to transfer on the destination side. If the error occurred on
the source side, then the location of the error is simply the latest source address plus the byte count. If
the error occurred on the destination side, then one cannot infer specifically where the error occurred,
because the byte count only refers to the number of data queued from the source, not what has been
written to the destination. In this case, the error will have occurred up to 256 bytes before: the original
address plus the byte count.
Given this background, the following procedure can be implemented to recover from errors.
1. Read the value contained in the DTBC register.
2. Read the record of the DVA and DLA that is stored on the PCI bus or elsewhere (not the value
stored in the Universe II registers of the same name).
3. If the difference between the value contained in the DTBC register and the original value is less
than 512 bytes (the FIFO depth of the Universe II), reprogram all the DMA registers with their
original values.
4. If the difference between the value contained in the DTBC register and the original value is greater
than 512 bytes (the FIFO depth of the Universe II), add 512 bytes to the value contained in the
DTBC register.
5. Add the difference between the original value in the DTBC and the new value in the DTBC
register to the original value in the DLA register.
6. Add the difference between the original value in the DTBC and the new value in the DTBC
register to the original value in the DVA register.
7. Clear the status flags.
8. Restart the DMA (see “DMA Initiation” on page 90).
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7.
Interrupt Generation and Handling
An interrupt is a signal informing a program that an event (for example, an error) has occurred. When a
program receives an interrupt signal, it temporarily suspends normal processing and diverts the
execution of instructions to a sub-routine handled by an interrupt controller. The controller
communicates with the host processor and the device that initiated the interrupt to determine how to
handle the interrupt.
Interrupt signals can come from a variety of sources. Interrupt signals generated by devices (for
example, a printer) indicate an event has occurred and are called hardware interrupts. Interrupt signals
generated by programs are called software interrupts.
This chapter discussed the interrupt generation and handling functionality of the Universe II. This
chapter discusses the following topics:
7.1
•
“Interrupt Generation” on page 111
•
“Interrupt Handling” on page 116
Overview
The Universe II has two types of interrupt capability: it is a generator of interrupts and an interrupt
handler.
The Interrupt Channel handles the prioritization and routing of interrupt sources to interrupt outputs on
the PCI bus and VMEbus. The interrupt sources are:
•
PCI LINT_[7:0]
•
VMEbus IRQ*[7:1]
•
ACFAIL* and SYSFAIL*
•
Various internal events
These sources can be routed to either the PCI LINT_ [7:0] lines or the VMEbus IRQ* [7:1] lines. Each
interrupt source is individually maskable and can be mapped to various interrupt outputs. Most
interrupt sources can be mapped to one particular destination bus. The PCI sources, LINT_[7:0], can
only be mapped to the VMEbus interrupt outputs. The VMEbus sources, VIRQ[7:1], are not mapped to
the PCI bus interrupts. However, the VIRQ[7:1] bits are status bits which indicate whether or not a
STATUS/ID vector has been acquired. This indication can be used to generate an interrupt on the PCI
bus. Some internal sources (for example, error conditions or DMA activity) can be mapped to either
bus.
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7. Interrupt Generation and Handling > Overview
Figure 18: Universe Interrupt Circuitry
VRACFAIL_
VRSYSFAIL_
Mapping
and Enabling
LINT [7:0]
Internal
Interrupt
Handler
VRIQ[7:1]_
Internal
Sources
Mapping
VXIRQ[7:1]_
and Enabling
Figure 18 illustrates the circuitry inside the Universe II Interrupt Channel. The PCI hardware interrupts
are listed on the left, and the VMEbus interrupt inputs and outputs are on the right. Internal interrupts
are also illustrated. The figure shows that the interrupt sources may be mapped and enabled. The
Internal Interrupt Handler is a block within the Universe II that detects assertion of the VRIRQ_[7:1]
pins and generates the VME IACK through the VME Master. Upon completion of the IACK cycle, the
Internal Interrupt Handler notifies the Mapping Block which in turn asserts the local LINT_, if enabled.
(Whereas the Internal Interrupt Handler implies a delay between assertion of an interrupt condition to
the Universe II and the Universe’s mapping of the interrupt, all other interrupt sources get mapped
immediately to their destination—assertion of LINT_ immediately causes an IRQ, assertion of
ACFAIL immediately causes an LINT_, etc.)
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7.2
111
Interrupt Generation
The Universe II has the ability to generate interrupts on both the PCI bus and VMEbus.
7.2.1
PCI Interrupt Generation
The Universe II expands on the basic PCI specification which permits “single function” devices to
assert only a single interrupt line. Eight PCI interrupt outputs provide maximum flexibility, although if
full PCI compliancy is required, all interrupt sources can be routed to a single PCI interrupt output.
PCI interrupts may be generated from multiple sources:
•
VMEbus sources of PCI interrupts
— IRQ*[7:1]
— SYSFAIL*
— ACFAIL*
–
internal sources of PCI interrupts
— DMA
— VMEbus bus error encountered
— PCI Target-Abort or Master-Abort encountered
— VMEbus ownership has been granted while the VOWN bit is set (see “VME Lock
Cycles—Exclusive Access to VMEbus Resources” on page 63)
— Software interrupt
— Mailbox access
— Location monitor access
— VMEbus IACK cycle performed in response to a software interrupt
Each source can be individually enabled in the “PCI Interrupt Enable Register (LINT_EN)” on
page 242 and mapped to a single LINT_ signal through the “PCI Interrupt Map 0 Register
(LINT_MAP0)” on page 246, “PCI Interrupt Map 1 Register (LINT_MAP1)” on page 247, and “PCI
Interrupt Map 2 Register (LINT_MAP2)” on page 263. When an interrupt is received on any of the
enabled sources, the Universe II asserts the appropriate LINT_ pin and sets a matching bit in the “PCI
Interrupt Status Register (LINT_STAT)” on page 244. See Table 17 on page 114 for a list of the enable,
mapping and status bits for PCI interrupt sources.
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7. Interrupt Generation and Handling > Interrupt Generation
Table 16: Source, Enabling, Mapping, and Status of PCI Interrupt Output
Enable Bit in LINT_EN
Interrupt Source
Register
Mapping Field in
LINT_MAPx Register
Status Bit in
LINT_STAT Register
ACFAIL*
ACFAIL
ACFAIL
ACFAIL
SYSFAIL*
SYSFAIL
SYSFAIL
SYSFAIL
PCI Software
Interrupt
SW_INT
SW_INT
SW_INT
VMEbus Software
IACK
SW_IACK
SW_IACK
SW_IACK
VMEbus Error
occurred during a
posted write
VERR
VERR
VERR
PCI Target-Abort or
Master-Abort
occurred during a
posted write
LERR
LERR
LERR
DMA Event
DMA
DMA
DMA
VMEbus Interrupt
Input
VIRQ7-1
VIRQ7-1
VIRQ7-1
Location Monitor
LM3-0
LM3-0
LM3-0
Mailbox Access
MBOX3-0
MBOX3-0
MBOX3-0
VMEbus Ownership
VOWN
VOWN
VOWN
The “PCI Interrupt Status Register (LINT_STAT)” on page 244 shows the status of all sources of PCI
interrupts, independent of whether that source has been enabled. This implies that an interrupt handling
routine must mask out those bits in the register that do not correspond to enabled sources on the active
LINT_ pin.
Except for SYSFAIL* and ACFAIL*, all sources of PCI interrupts are edge-sensitive. Enabling of the
ACFAIL* or SYSFAIL* sources (ACFAIL and SYSFAIL bits in the LINT_EN register) causes the
status bit and mapped PCI interrupt pin to assert synchronously with the assertion of the ACFAIL* or
SYSFAIL* source. The PCI interrupt is negated once the ACFAIL or SYSFAIL status bit is cleared.
The status bit cannot be cleared if the source is still active. Therefore, if SYSFAIL* or ACFAIL* is still
asserted while the interrupt is enabled the interrupt will continue to be asserted. Both of these sources
are synchronized and filtered with multiple edges of the PCI clock at their inputs.
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All other sources of PCI interrupts are edge-sensitive. The VMEbus source for PCI interrupts actually
comes out of the VMEbus Interrupt Handler block and reflects acquisition of a VMEbus STATUS/ID.
Therefore, even though VMEbus interrupts externally are level-sensitive as required by the VMEbus
Specification, they are internally mapped to edge-sensitive interrupts (see “VMEbus Interrupt
Handling” on page 116).
The interrupt source status bit (in the LINT_STAT register) and the mapped LINT_ pin remain asserted
with all interrupts. The status bit and the PCI interrupt output pin are only released when the interrupt is
cleared by writing a 1 to the appropriate status bit.
7.2.2
VMEbus Interrupt Generation
This section details the conditions under which the Universe II generates interrupts to the VMEbus.
Interrupts may be generated on any combination of VMEbus interrupt lines (IRQ*[7:1]) from multiple
sources:
•
PCI sources of VMEbus interrupts
— LINT_[7:0]
•
Internal sources of VMEbus interrupts
— DMA
— VMEbus bus error encountered
— PCI Target-Abort or Master-Abort encountered
— Mailbox register access
— Software interrupt
Each of these sources may be individually enabled through the “VMEbus Interrupt Enable Register
(VINT_EN)” on page 248 and mapped to a particular VMEbus Interrupt level using the “VME
Interrupt Map 0 Register (VINT_MAP0)” on page 253, “VME Interrupt Map 1 Register
(VINT_MAP1)” on page 254, and “VME Interrupt Map 2 Register (VINT_MAP2)” on page 264.
Multiple sources may be mapped to any VMEbus level. Mapping interrupt sources to level 0
effectively disables the interrupt.
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7. Interrupt Generation and Handling > Interrupt Generation
Once an interrupt has been received from any of the sources, the Universe II sets the corresponding
status bit in the“VMEbus Interrupt Status Register (VINT_STAT)” on page 251, and asserts the
appropriate VMEbus interrupt output signal (if enabled). When a VMEbus interrupt handler receives
the interrupt, it will perform an IACK cycle at that interrupt level. When the Universe II decodes that
IACK cycle together with IACKIN* asserted, it provides the STATUS/ID previously stored in the
“Interrupt STATUS/ID Out Register (STATID)” on page 255, unless it is configured as SYSCON in
which case it does not monitor IACKIN*. See Table 17 for a list of the enable, mapping and status bits
for VMEbus interrupt sources.
Table 17: Source, Enabling, Mapping, and Status of VMEbus Interrupt Outputs
Interrupt Source
Enable Bit in the
“VMEbus Interrupt
Enable Register
(VINT_EN)” on
page 248
VINT_MAPx
Status Bit in the
“VMEbus Interrupt
Status Register
(VINT_STAT)” on
page 251
Mapping Field in
VMEbus Software
Interrupt
SW_INT7-1
N/Aa
SW_INT7-1
VMEbus Error
VERR
VERR in the “VME Interrupt
Map 1 Register
(VINT_MAP1)” on page 254
VERR
PCI Target-Abort or
Master-Abort
LERR
LERR in the “VME Interrupt
Map 1 Register
(VINT_MAP1)” on page 254
LERR
DMA Event
DMA
DMA in the “VME Interrupt
Map 1 Register
(VINT_MAP1)” on page 254
DMA
Mailbox Register
MBOX3-0
MBOX3-0 in the “VME
Interrupt Map 2 Register
(VINT_MAP2)” on page 264
MBOX3-0
PCI bus Interrupt
Input
LINT7-0
LINT7-0 in the “VME Interrupt
Map 0 Register
(VINT_MAP0)” on page 253
LINT7-0
VMEbus Software
Interrupt
SW_INT
SW_INT in the “VME
Interrupt Map 1 Register
(VINT_MAP1)” on page 254
SW_INT
(mappable)
a. This set of software interrupts cannot be mapped. That is, setting the SW_INT1 bit triggers VXIRQ1, setting
the SW_INT2 bit triggers VXIRQ2, etc.
For all VMEbus interrupts, the Universe II interrupter supplies a pre-programmed 8-bit STATUS/ID; a
common value for all interrupt levels. The upper seven bits are programmed in the STATID register.
The lowest bit is cleared if the source of the interrupt was the software interrupt, and is set for all other
interrupt sources. If a software interrupt source and another interrupt source are active and mapped to
the same VMEbus interrupt level, the Universe II gives priority to the software source.
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Figure 19: STATUS/ID Provided by Universe II
STATUS/ID
Programmed from
VME_STATUS/ID
Registers
0 if S/W Interrupt Source
1 if Internal or LINT
Interrupt Source
Once the Universe II has provided the STATUS/ID to an interrupt handler during a software initiated
VMEbus interrupt, it generates an internal interrupt, SW_IACK. If enabled, this interrupt feeds back to
the PCI bus (through one of the LINT_ pins) to signal a process that the interrupt started through
software has been completed.
All VMEbus interrupts generated by the Universe II are RORA, except for the software interrupts
which are ROAK. This means that if the interrupt source was a software interrupt, then the VMEbus
interrupt output is automatically negated when the Universe II receives the IACK cycle. However, for
any other interrupt, the VMEbus interrupt output remains asserted until cleared by a register access.
Writing 1 to the relevant bit in the VINT_STAT register clears that interrupt source. However, since
PCI interrupts are level-sensitive, if an attempt is made to clear the VMEbus interrupt while the LINT_
pin is still asserted, the VMEbus interrupt remains asserted. For this reason, a VMEbus interrupt
handler should clear the source of the PCI interrupt before clearing the VMEbus interrupt.
Since software interrupts are ROAK, the respective bits in the VINT_STAT register are cleared
automatically on completion of the IACK cycle, simultaneously with the negation of the IRQ.
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7.3
7. Interrupt Generation and Handling > Interrupt Handling
Interrupt Handling
The Universe II can handle interrupts from both the PCI bus and the VMEbus.
7.3.1
PCI Interrupt Handling
All eight PCI interrupt lines, LINT_[7:0], can act as interrupt inputs to the Universe II. They are
level-sensitive and, if enabled in the “VMEbus Interrupt Enable Register (VINT_EN)” on page 248,
immediately generate an interrupt to the VMEbus. It is expected that when a VMEbus interrupt handler
receives the Universe II’s STATUS/ID from the Universe II, the interrupt handler clears the VMEbus
interrupt by first clearing the source of the interrupt on the PCI bus, and then clearing the VMEbus
interrupt (by writing a 1 to the appropriate bit in the “VMEbus Interrupt Status Register
(VINT_STAT)” on page 251.
Note that since PCI interrupts are level-sensitive, if an attempt is made to clear the VMEbus interrupt
while the LINT_ pin is still asserted, the VMEbus interrupt remains asserted. This causes a second
interrupt to be generated to the VMEbus. For this reason, a VMEbus interrupt handler should clear the
source of the PCI interrupt before clearing the VMEbus interrupt.
7.3.2
VMEbus Interrupt Handling
As a VMEbus interrupt handler, the Universe II can monitor any or all of the VMEbus interrupt levels.
It can also monitor SYSFAIL* and ACFAIL*, although IACK cycles are not generated for these inputs.
Each interrupt is enabled through the “PCI Interrupt Enable Register (LINT_EN)” on page 242.
Once enabled, assertion of any of the VMEbus interrupt levels, IRQ[7:1]*, causes the internal interrupt
handler circuitry to request ownership of the Universe II's VMEbus Master Interface on the level
programmed in the “Master Control Register (MAST_CTL)” on page 271 (see “VMEbus Requester”
on page 25). This interface is shared between several channels in the Universe II: the PCI Target
Channel, the DMA Channel, and the Interrupt Channel. The Interrupt Channel has the highest priority
over all other channels and, if an interrupt is pending, assumes ownership of the VMEbus Master
Interface when the previous owner has relinquished ownership.
The Universe II latches the first interrupt that appears on the VMEbus and begins to process it
immediately. If an interrupt at a higher priority is asserted on the VMEbus before BBSY* is asserted
the Universe II performs an interrupt acknowledge for the first interrupt it detected. Upon completion
of that IACK cycle, the Universe II then performs IACK cycles for the higher of any remaining active
interrupts.
There may be some latency between reception of a VMEbus interrupt and generation of the IACK
cycle. This arises because of the latency involved in the Interrupt Channel gaining control of the
VMEbus Master Interface, and because of possible latency in gaining ownership of the VMEbus if the
VMEbus Master Interface is programmed for release-when-done. In addition, the Universe II only
generates an interrupt on the PCI bus once the IACK cycle has completed on the VMEbus. Because of
these combined latencies (time to acquire VMEbus and time to run the IACK cycle), systems should be
designed to accommodate a certain worst case latency from VMEbus interrupt generation to its
translation to the PCI bus.
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When the Universe II receives a STATUS/ID in response to an IACK cycle, it stores that value in one
of seven registers. These registers, “VIRQ1 STATUS/ID Register (V1_STATID)” on page 256 through
“VIRQ7 STATUS/ID Register (V7_STATID)” on page 262, store the STATUS/ID corresponding to
each IACK level in the STATID field. Once an IACK cycle has been generated and the resulting
STATUS/ID is latched, another IACK cycle is not run on that level until the level has been cleared by
writing a 1 to the corresponding status bit in the “PCI Interrupt Status Register (LINT_STAT)” on
page 244. If other interrupts (at different levels) are pending while the interrupt is waiting to be cleared,
IACK cycles are run on those levels in order of priority and the STATUS/IDs stored in their respective
registers.
Once the IACK cycle is complete and the STATUS/ID stored, an interrupt is generated to the PCI bus
on one of LINT_[7:0] depending on the mapping for that VMEbus level in the “PCI Interrupt Map 0
Register (LINT_MAP0)” on page 246. The interrupt is cleared and the VMEbus interrupt level is
re-armed by clearing the correct bit in the “PCI Interrupt Status Register (LINT_STAT)” on page 244
register.
7.3.2.1
Bus Error During VMEbus IACK Cycle
A bus error encountered on the VMEbus while the Universe II is performing an IACK cycle is handled
by the Universe II in two ways. The first is through the error logs in the VMEbus Master Interface.
These logs store address and command information whenever the Universe II encounters a bus error on
the VMEbus (see “Error Handling” on page 125). If the error occurs during an IACK cycle, the IACK_
bit is set in the “VMEbus AM Code Error Log (V_AMERR)” on page 307. The VMEbus Master
Interface also generates an internal interrupt to the Interrupt Channel indicating a VMEbus error
occurred. This internal interrupt can be enabled and mapped to either the VMEbus or PCI bus.
As well as generating an interrupt indicating an error during the IACK cycle, the Universe II also
generates an interrupt as though the IACK cycle completed successfully. If an error occurs during the
fetching of the STATUS/ID, the Universe II sets the ERR bit in the “Interrupt STATUS/ID Out Register
(STATID)” on page 255, and generates an interrupt on the appropriate LINT_ pin (as mapped in the
“PCI Interrupt Map 0 Register (LINT_MAP0)” on page 246). The PCI resource, upon receiving the
PCI interrupt, is expected to read the“Interrupt STATUS/ID Out Register (STATID)” on page 255, and
take appropriate actions if the ERR bit is set. Note that the STATUS/ID cannot be considered valid if
the ERR bit is set in the STATUS/ID register.
It is important to recognize that the IACK cycle error can generate two PCI interrupts: one through the
VMEbus master bus error interrupt and another through the standard PCI interrupt translation. If an
error occur during acquisition of a STATUS/ID, the “PCI Interrupt Status Register (LINT_STAT)” on
page 244 shows that both VIRQx, and VERR are active.
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7.3.3
7. Interrupt Generation and Handling > Interrupt Handling
Internal Interrupt Handling
The Universe II's internal interrupts are routed from several processes in the device. There is an
interrupt from the VMEbus Master Interface to indicate a VMEbus error, another from the PCI Master
Interface to indicate an error on that bus, another from the DMA to indicate various conditions in that
channel, along with several others. Table 18 shows to which bus each interrupt source can be routed.
Some sources can be mapped to both buses, but mapping interrupts to a single bus is
recommended.
Table 18: Internal Interrupt Routing
May be Routed to:
Interrupt Source
VMEbus
PCI s/w interrupt
VMEbus s/w
interrupt
PCI Bus
IACK cycle complete
for s/w interrupt
DMA event
Mailbox access
Location monitor
PCI Target-Abort or
Master-Abort
VMEbus bus error
VMEbus bus
ownership granted
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Figure 20 shows the sources of interrupts, and the interfaces from which they originate.
Figure 20: Sources of Internal Interrupts
PCI Bus
Interface
VMEbus
Interface
VMEbus Slave Channel
PCI
Master
posted writes FIFO
VME
Slave
prefetch read FIFO
coupled path
DMA Channel
DMA bidirectional FIFO
PCI Bus Slave Channel
posted writes FIFO
PCI
Target
coupled read logic
VME
Master
Interrupt Channel
Interrupt Handler
DMA
PCI error
PCI software interrupt
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VME error
VME ownership bit
software IACK
VME software interrupt
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7. Interrupt Generation and Handling > Interrupt Handling
7.3.3.1
VMEbus and PCI Software Interrupts
It is possible to interrupt the VMEbus and the PCI bus through software. These interrupts may be
triggered by writing a 1 to the respective enable bits.
Interrupting the VMEbus Through Software
The following methods trigger software interrupts on the VMEbus:
1. The first method for interrupting the VMEbus through software involves writing 1 to one of the
SW_INT7-1 bits in the VINT_EN register while the mask bit is 0.1 This causes an interrupt to be
generated on the corresponding IRQ7-1 line. For example, setting the SW_INT1 bit triggers
VXIRQ1, setting the SW_INT2 bit triggers VXIRQ2, etc.
2. The second method for interrupting the VMEbus through software involves an extra step. Writing
a 1 to the SW_INT bit in the“VMEbus Interrupt Enable Register (VINT_EN)” on page 248 when
this bit is 0 triggers one interrupt on the VMEbus on the level programmed in the “VME Interrupt
Map 1 Register (VINT_MAP1)” on page 254.
This method requires that the user specify in the VINT_MAP1 register to which line the interrupt
is to be generated. When the SW_INT interrupt (method 2) is active at the same level as one of
SW_INT7-1 interrupts (method 1), the SW_INT interrupt (method 2) takes priority.While this
interrupt source is active, the SW_INT status bit in the VINT_STAT register is set.
This method is provided for compatibility with the original Universe device.
With both methods, the mask bit (SW_INTx or SW_INT) in the “VMEbus Interrupt Enable Register
(VINT_EN)” on page 248 must be 0 in order for writing 1 to the bit to have any effect.
Regardless of the software interrupt method used, when an IACK cycle is serviced on the VMEbus, the
Universe II can be programmed to generate an interrupt on the PCI bus by setting the SW_IACK
enable bit in the “PCI Interrupt Enable Register (LINT_EN)” on page 242 (see “Software IACK
Interrupt” on page 121).
Interrupting the PCI bus Through Software
On the PCI bus, there is only one method of directly triggering a software interrupt. This method is the
same as the second method described in “Interrupting the VMEbus Through Software” on page 120.
Causing a 0 to 1 transition in the SW_INT in the LINT_EN register generates an interrupt to the PCI
bus. While this interrupt source is active, the SW_INT status bit in LINT_STAT is set. The SW_INT
field in the “PCI Interrupt Map 1 Register (LINT_MAP1)” on page 247 determines which interrupt line
is asserted on the PCI interface.
1. The term “enable” is more meaningful with respect to the other fields in this register, i.e., excluding the software interrupts. Writing to
the software interrupt fields of this register does not enable an interrupt, it triggers an interrupt.
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Termination of Software Interrupts
Any software interrupt can be cleared by clearing the respective bit in the “VMEbus Interrupt Enable
Register (VINT_EN)” on page 248 or “PCI Interrupt Enable Register (LINT_EN)” on page 242.
However, this method is not recommend for VME bus software interrupts because it can result in a
false interrupts on that bus. These false interrupts are caused because the Universe II does not respond
to the interrupt handler’s IACK cycle, and the handler is left without a STATUS/ID for the interrupt.
Since the software interrupt is edge-sensitive, the software interrupt bit in the VINT_EN or LINT_EN
register should be cleared any time between the last interrupt finishing and the generation of another
interrupt. It is recommended that the appropriate interrupt handler clear this bit once it has completed
its operations. Alternatively, the process generating a software interrupt could clear this bit before
re-asserting it.
Software interrupts on the VMEbus have priority over other interrupts mapped internally to the same
level on the VMEbus. When a VMEbus interrupt handler generates an IACK cycle on a level mapped
to both a software interrupt and another interrupt, the Universe II always provides the STATUS/ID for
the software interrupt (bit zero of the Status/ID is cleared). If there are no other active interrupts on that
level, the interrupt is automatically cleared upon completion of the IACK cycle (since software
interrupts are ROAK).
While the software interrupt STATUS/ID has priority over other interrupt sources, the user can give
other interrupt sources priority over the software interrupt. This is done by reading the “PCI Interrupt
Status Register (LINT_STAT)” on page 244 when handling a Universe II interrupt. This register
indicates all active interrupt sources. Using this information, the interrupt handler can then handle the
interrupt sources in any system-defined order.
7.3.3.2
Software IACK Interrupt
The Universe II generates an internal interrupt when it provides the software STATUS/ID to the
VMEbus. This interrupt can only be routed to a PCI interrupt output. A PCI interrupt is generated upon
completion of an IACK cycle that had been initiated by the Universe II’s software interrupt if the
following occurs:
•
The SW_IACK bit is set in the “PCI Interrupt Status Register (LINT_STAT)” on page 244
•
The SW_IACK field in the “PCI Interrupt Map 1 Register (LINT_MAP1)” on page 247 is mapped
to a corresponding PCI interrupt line
This interrupt could be used by a PCI process to indicate that the software interrupt generated to the
VMEbus has been received by the device and acknowledged.
Like other interrupt sources, this interrupt source can be independently enabled through the “PCI
Interrupt Enable Register (LINT_EN)” on page 242 and mapped to a particular LINT_ pin using the
LINT_MAP1 register. A status bit in the LINT_STAT register indicates when the interrupt source is
active, and is used to clear the interrupt once it has been serviced.
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7.3.3.3
7. Interrupt Generation and Handling > Interrupt Handling
VMEbus Ownership Interrupt
The VMEbus ownership interrupt is generated when the Universe II acquires the VMEbus in response
to programming of the VOWN bit in the MAST_CTL register (“Master Control Register
(MAST_CTL)” on page 271). This interrupt source can be used to indicate that ownership of the
VMEbus is ensured during an exclusive access (see “VME Lock Cycles—Exclusive Access to
VMEbus Resources” on page 63). The interrupt is cleared by writing a one to the matching bit in the
“PCI Interrupt Status Register (LINT_STAT)” on page 244.
7.3.3.4
DMA Interrupt
The DMA module provides the following possible interrupt sources:
•
The DMA is stopped (INT_STOP)
•
The DMA is halted (INT_HALT)
•
The DMA is done (INT_DONE)
•
PCI Target-Abort or Master-Abort (INT_LERR)
•
VMEbus errors (INT_VERR)
•
A PCI protocol error or if the Universe II is not enabled as PCI master (INT_P_ERR)
All of these interrupt sources are ORed to a single DMA interrupt output line. When an interrupt comes
from the DMA module, software must read the DMA status bits in the “PCI Interrupt Status Register
(LINT_STAT)” on page 244 and the “VMEbus Interrupt Status Register (VINT_STAT)” on page 251
to discover the originating interrupt source. The DMA interrupt can be mapped to either the VMEbus
or one of the PCI interrupt output lines (see “DMA Interrupts” on page 104).
7.3.3.5
Mailbox Register Access Interrupts
The Universe II can be programmed to generate an interrupt on the PCI bus and/or the VMEbus when
any one of its mailbox registers is written to (see “Mailbox Registers” on page 83). The user may
enable or disable an interrupt response to the access of any mailbox register. Each register access may
be individually mapped to a specific interrupt on the PCI bus through the “PCI Interrupt Map 2
Register (LINT_MAP2)” on page 263 and/or the VMEbus through the “VME Interrupt Map 2 Register
(VINT_MAP2)” on page 264. The status of the PCI interrupt and the VMEbus are recorded in the “PCI
Interrupt Status Register (LINT_STAT)” on page 244 and “VMEbus Interrupt Status Register
(VINT_STAT)” on page 251.
7.3.3.6
Location Monitors
The Universe II can be programmed to generate an interrupt on the PCI bus when one of its four
location monitors is accessed (see “Location Monitors” on page 38).
In order for an incoming VMEbus transaction to activate the location monitor of the Universe II the
following criteria must be met:
•
Location monitor must be enabled
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•
Access must be within 4 kbytes of the location monitor base address (see “Location Monitor Base
Address Register (LM_BS)” on page 302)
•
It must be in the specified address space
When an access to a location monitor is detected, an interrupt may be generated on the PCI bus (if the
location monitor is enabled). There are four location monitors:
•
VA[4:3] = 00 selects Location Monitor 1,
•
VA[4:3] = 01 selects Location Monitor 2,
•
VA[4:3] = 10 selects Location Monitor 3, and
•
VA[4:3] = 11 selects Location Monitor 4.
An interrupt response to the access of any location monitor can be enabled or disabled with bits in the
“PCI Interrupt Enable Register (LINT_EN)” on page 242. Access to each location monitor can be
individually mapped to a specific interrupt on the PCI bus through the “PCI Interrupt Map 2 Register
(LINT_MAP2)” on page 263—not to the VMEbus bus. The status of the PCI interrupt is logged in the
LM bit of the “PCI Interrupt Status Register (LINT_STAT)” on page 244.
7.3.3.7
PCI and VMEbus Error Interrupts
Interrupts from VMEbus errors, PCI Target-Aborts or Master-Aborts are generated only when bus
errors arise during decoupled writes. The bus error interrupt (from either a PCI or VMEbus error) can
be mapped to either a VMEbus or PCI interrupt output line.
7.3.4
VME64 Auto-ID
The Universe II includes a power-up option for participation in the VME64 Auto-ID process. When
this option is enabled, the Universe II generates a level 2 interrupt on the VMEbus before release of
SYSFAIL*. When the level 2 IACK cycle is run by the system Monarch, the Universe II responds with
the Auto-ID Status/ID, 0xFE, and enables access to a CR/CSR image at base address 0x00_0000.
When the Monarch detects an Auto-ID STATUS/ID on level 2, it is expected to access the enabled
CR/CSR space of the interrupter. From there it completes identification and configuration of the card.
The Monarch functionality is typically implemented in software on one card in the VMEbus system.
See “Automatic Slot Identification” on page 42.
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8.
Error Handling
Errors occur in a system as a result of parity, bus, or internal problems. In order to handle errors so that
they have minimum effects on an application, devices have a logic module called an error handler. The
error handler logs data about the error then communicates the information to another device (for
example, a host processor) that is capable of resolving the error condition.
This chapter discusses the following topics:
8.1
•
“Errors on Coupled Cycles” on page 125
•
“Errors on Decoupled Transactions” on page 125
Overview
There are different conditions under which bus errors can occur with the
Universe II: during coupled cycles or during decoupled cycles. In a coupled transaction, the completion
status is returned to the transaction master, which can then take some action. However, in a decoupled
transaction, the master is not involved in the data acknowledgment at the destination bus and higher
level protocols are required.
The error handling provided by the Universe II is described for both coupled and decoupled
transactions.
8.2
Errors on Coupled Cycles
During coupled cycles, the Universe II provides immediate indication of an errored cycle to the
originating bus. VMEbus to PCI transactions terminated with Target-Abort or Master-Abort are
terminated on the VMEbus with BERR*. The R_TA or R_MA bits in the “PCI Configuration Space
Control and Status Register (PCI_CSR)” on page 172 are set when the Universe II receives a
Target-Abort or Master-Abort. For PCI to VMEbus transactions, a VMEbus BERR* received by the
Universe II is communicated to the PCI master as a Target-Abort and the S_TA bit is set in the
PCI_CSR register. No information is logged in either direction, nor is an interrupt generated.
8.3
Errors on Decoupled Transactions
During decoupled transactions, there is a possibility that an error in the transaction can occur. The
following sections detail the decoupled transactions supported by Universe II and the types of error
handling supported for these transactions.
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8.3.1
8. Error Handling > Errors on Decoupled Transactions
Posted Writes
The Universe II provides the option of performing posted writes in both the PCI Target Channel and
the VMEbus Slave Channel. Once data is written into the RXFIFO or TXFIFO by the initiating master
(VMEbus or PCI bus respectively), the Universe II provides immediate acknowledgment of the cycle's
termination. When the data in the FIFO is written to the destination slave or target by the Universe II,
the Universe II can receive a bus error instead of a normal termination. The Universe II handles this
situation by logging the errored transactions in one of two error logs and generating an interrupt. Each
error log (one for VMEbus errors and one for PCI bus errors) is comprised of two registers: one for
address and one for command or address space logging.
8.3.1.1
Error Logs
If the error occurs during a posted write to the VMEbus, the Universe II uses the “VMEbus AM Code
Error Log (V_AMERR)” on page 307 to log the AM code of the transaction in the AMERR field. The
state of the IACK* signal is logged in the IACK bit, to indicate whether the error occurred during an
IACK cycle. The address of the errored transaction is latched in the V_AERR register
(Table 12.3.108). An interrupt is generated on the VMEbus and/or PCI bus depending upon whether
the VERR interrupts are enabled (see “Interrupt Generation and Handling” on page 109). The
remaining entries of the transaction are removed from the FIFO.
If the error occurs during a posted write to the PCI bus, the Universe II uses the “PCI Command Error
Log Register (L_CMDERR)” on page 210 to log the command information for the transaction
(CMDERR [3:0]). The address of the errored transaction is latched in the “PCI Address Error Log
(LAERR)” on page 211. An interrupt is generated on the VMEbus and/or PCI bus depending upon
whether the VERR and LERR interrupts are enabled (see “Interrupt Generation and Handling” on
page 109).
Under either of the conditions (VMEbus-to-PCI, or PCI-to-VMEbus), the address that is stored in the
log represents the most recent address the Universe II generated before the bus error was encountered.
For single cycle transactions, the address represents the address for the actual errored transaction.
However, for multi-data beat transactions (block transfers on the VMEbus or burst transactions on the
PCI bus) the log only indicates that an error occurred somewhere after the latched address. For a
VMEbus block transfer, the logged address will represent the start of the block transfer. In the PCI
Target Channel, the Universe II generates block transfers that do not cross 256-byte boundaries, the
error will have occurred from the logged address up to the next 256-byte boundary. In the VMEbus
Slave Channel, the error will have occurred anywhere from the logged address up to the next burst
aligned address.
In the case of PCI-initiated transactions, all data from the errored address up to the end of the initiating
transaction is flushed from the TXFIFO. Since the Universe II breaks PCI transactions at 256-byte
boundaries (or earlier if the TXFIFO is full), the data is not flushed past this point. If the PCI master is
generating bursts that do not cross the 256-byte boundary, then (again) only data up to the end of that
transaction is flushed.
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127
In a posted write from the VMEbus, all data subsequent to the error in the transaction is flushed from
the RXFIFO. However, the length of a VMEbus transaction differs from the length of the errored PCI
bus transaction. For non-block transfers, the length always corresponds to one so only the errored data
beat is flushed. However, if an error occurs on the PCI bus during a transaction initiated by a VMEbus
block transfer, all data subsequent to the errored data beat in the block transfer is flushed from the
RXFIFO. In the case of BLTs, this implies that potentially all data up to the next 256-byte boundary
may be flushed. For MBLTs, all data up to the next 2-KByte boundary may be flushed.
Once an error is captured in a log, that set of registers is frozen against further errors until the error is
acknowledged. The log is acknowledged and made available to latch another error by clearing the
corresponding status bit in the VINT_STAT or LINT_STAT registers. if a second error occur before the
CPU has the opportunity to acknowledge the first error, another bit in the logs is set to indicate this
situation (M_ERR bit).
8.3.2
Prefetched Reads
In response to a block read from the VMEbus, the Universe II initiates prefetching on the PCI bus (if
the VMEbus slave image is programmed with this option, see “VME Slave Image Programming” on
page 67). The transaction generated on the PCI bus is an aligned memory read transaction with
multiple data beats extending to the aligned burst boundary (as programmed by PABS in the “Master
Control Register (MAST_CTL)” on page 271). Once an acknowledgment is given for the first data
beat, an acknowledgment is sent to the VMEbus initiator by the assertion of DTACK*. Therefore, the
first data beat of a prefetched read is coupled while all subsequent reads in the transaction are
decoupled.
If an error occurs on the PCI bus, the Universe II does not translate the error condition into a BERR*
on the VMEbus. Indeed, the Universe II does not directly map the error. By doing nothing, the
Universe II forces the external VMEbus error timer to expire.
8.3.3
DMA Errors
The Universe II’s response to a bus error during a transfer controlled by the DMA Channel is described
in “DMA Error Handling” on page 105.
8.3.4
Parity Errors
The Universe II both monitors and generates parity information using the PAR signal. The Universe II
monitors PAR when it accepts data as a master during a read or as a target during a write. The Universe
II drives PAR when it provides data as a target during a read or a master during a write. The Universe II
also drives PAR during the address phase of a transaction when it is a master and monitors PAR during
an address phase when it is the PCI target. In both address and data phases, the PAR signal provides
even parity for C/BE_[3:0] and AD[31:0].
If the Universe II is powered up in a 64-bit PCI environment, then PAR64
provides even parity for C/BE_[7:4] and AD[63:32].
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8. Error Handling > Errors on Decoupled Transactions
The PERESP and SERR_EN bits in the “PCI Configuration Space Control and Status Register
(PCI_CSR)” on page 172 determine whether or not the Universe II responds to parity errors. Data
parity errors are reported through the assertion of PERR_ if the PERESP bit is set. Address parity
errors, reported through the SERR_ signal, are reported if both PERESP and SERR_EN are set.
Regardless of the setting of these two bits, the D_PE (Detected Parity Error) bit in the PCI_CS register
is set if the Universe II encounters a parity error as a master or as a target. The DP_D (Data Parity
Detected) bit in the same register is only set if parity checking is enabled through the PERESP bit and
the Universe II detects a parity error while it is PCI master (that is, it asserts PERR_ during a read
transaction or receives PERR_ during a write).
No interrupts are generated by the Universe II either as a master or as a target in response to parity
errors reported during a transaction. Parity errors are reported by the Universe II through assertion of
PERR_ and by setting the appropriate bits in the PCI_CSR register. If PERR_ is asserted to the
Universe II while it is PCI master, the only action it takes is to set the DP_D. Regardless of whether the
Universe II is the master or target of the transaction, and regardless which agent asserted PERR_, the
Universe II does not take any action other than to set bits in the PCI_CSR register. The Universe II
continues with a transaction independent of any parity errors reported during the transaction.
Similarly, address parity errors are reported by the Universe II (if the SERR_EN bit and the PERESP
bit are set) by asserting the SERR_ signal for one clock cycle and setting the S_SERR (Signalled
SERR_) bit in the PCI_CSR register. Assertion of SERR_ can be disabled by clearing the SERR_EN
bit in the PCI_CSR register. No interrupt is generated, and regardless of whether assertion of SERR_ is
enabled or not, the Universe II does not respond to the access with DEVSEL_. Typically the master of
the transaction times-out with a Master-Abort. As a master, the
Universe II does not monitor SERR_. It is expected that a central resource on the PCI bus monitors
SERR_ and takes appropriate action.
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9.
Resets, Clocks and Power-up Options
This chapter highlights utility functions in the Universe II. This chapter discusses the following topics:
9.1
•
“Resets” on page 129
•
“Power-Up Options” on page 135
•
“Test Modes” on page 141
•
“Clocks” on page 142
Overview
The Universe II has many programmable reset options and power-up options that impact the
functionality of the device.
9.2
Resets
The Universe II provides a number of pins and registers for reset support. Pin support is summarized in
Table 19.
Table 19: Hardware Reset Mechanisms
Interface and
Direction
Pin Name
Long Name
Effectsa
VMEbus Input
VRSYSRST_
VMEbus Reset Input
Asserts LRST_ on the local bus, resets the
Universe II, and re-configures power-up options.
VMEbus Output
VXSYSRST
VMEbus System
Reset
Universe II output for SYSRST* (resets the
VMEbus)
PCI Input
PWRRST_
Power-up Reset
Resets the Universe II and re-configures
power-up options.
RST_
PCI Reset Input
Resets the Universe II from the PCI bus.
VME_
RESET_
VMEbus Reset
Initiator
Causes Universe II to assert VXSYSRST
PCI Output
LRST_
PCI Bus Reset
Output
Resets PCI resources
JTAG Input
TRST_
JTAG Test Reset
Provides asynchronous initialization of the TAP
controller in the Universe II.
a. A more detailed account of the effects of reset signals is provided in “Reset Implementation Cautions” on
page 133
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The Universe II is only reset through hardware. Software can make the Universe II assert its reset
outputs. In order to reset the Universe II through software, the Universe II reset outputs must be
connected to the Universe II reset inputs. For example, the SW_LRST bit in the MISC_CTL register,
which asserts the LRST_ output, does not reset the Universe II itself unless LRST_ is looped back to
RST_. As described in “Reset Implementation Cautions” on page 133, there are potential loopback
configurations resulting in permanent reset.
Table 20: Software Reset Mechanism
Register
Name
Type
“Master
Control
Register
(MAST_CTL)”
on page 271
SW_LRST
W
Function
Software PCI Reset
0=No effect
1=Initiate LRST_
A read always returns 0.
SW_SYSRST
W
Software VMEbus SYSRESET
0=No effect
1=Initiate SYSRST*
A read always returns 0
“VMEbus CSR
Bit Set
Register
(VCSR_SET)”
on page 330
RESET
R/W
Board Reset
Reads:
0=LRST_ not asserted
1=LRST_ asserted
Writes:
0=no effect
1=assert LRST_
SYSFAIL
R/W
VMEbus SYSFAIL
Reads:
0=VXSYSFAIL not asserted
1=VXSYSFAIL asserted
Writes:
0=no effect
1=assert VXSYSFAIL
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Table 20: Software Reset Mechanism
Register
Name
Type
“VMEbus CSR
Bit Clear
Register
(VCSR_CLR)”
on page 329
RESET
R/W
Function
Board Reset
Reads:
0=LRST_ not asserted
1=LRST_ asserted
Writes:
0=no effect
1=negate LRST_
SYSFAIL
R/W
VMEbus SYSFAIL
Reads:
0=VXSYSFAIL not asserted
1=VXSYSFAIL asserted
Writes:
0=no effect
1=negate VXSYSFAIL
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9.2.1
9. Resets, Clocks and Power-up Options > Resets
Universe II Reset Circuitry
Table 21 on page 132 and Figure 21 on page 133 shows how to reset various aspects of the Universe II.
For example, it shows that in order to reset the clock services (SYSCLK, CLK64 enables, and PLL
divider), PWRRST_ must be asserted.
PWRRST_ resets all aspects of Universe II listed in column 1 of Table 21. Table 21 also indicates the
reset effects that are extended in time. For example, VXSYSRST_ remains asserted for 256 ms after all
initiators are removed—this satisfies VMEbus Specification (minimum of 200 ms SYSRST*). The
external 64 MHz clock controls this assertion time. LRST_ is asserted for 5 ms or more from all
sources except VRSYSRST_.
Table 21: Functions Affected by Reset Initiators
Effect of Reseta
Clock Services
Reset Source
PWRRST_
SYSCLK
CLK64 enables
PLL Divider
VMEbus Services
PWRRST_, or
VRSYSRST_
VMEbus Arbiter
VMEbus Timer
VCSR Registers
General Services
PWRRST_,
RST_ or
Most registers
VRSYSRST_
Power-Up and Reset State Machine
Power-up the device
PWRRST_, or
VRSYSRST_
Reset Registers
PWRRST_, or
VMEbus Reset Output
VXSYSRST_ (asserted for more than 200 ms)
VME_RESET_, or
SW_SYSRST bit in MISC_CTL register
PWRRST_, or
VRSYSRST_, or
PCI Bus Reset Output
LRST_ (asserted for at least 5 ms)
SW_LRST bit in MISC_CTL register, or
RESET bit in VCSR_SET registerb
a. On PWRRST_, options are loaded from pins. On SYSRST and RST_, options are loaded from values that
were latched at the previous PWRRST_.
b. LRST_ can be cleared by writing 1 to the RESET bit in the CSR_CLR register.
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Figure 21: Reset Circuitry
PWRRST_
VME Services
(VME Arbiter, VMEbus timer, VCSR registers)
VRSYSRST_
Clock Services
(SYSCLK, CLK64 enables, PLL divider)
General Services
(Most Registers)
RST_
Power-Up and Reset
(Power-up, reset registers, assert VOE_)
VOE_
VME_RESET_
hold for
> 200ms
VXSYSRST_
MISC_CTL Register
SW_SYSRST
SW_LRST
VCSR_CLR and
VCSR_SET Registers
RESET
hold for
>= 5ms
LRST_
Notes:
1. On PWRRST_, options are loaded from pins. On SYSRST and RST_, options
are loaded from values that were latched at the previous PWRRST_.
2. Refer to “Registers” on page 163 to find the effects of various reset events.
9.2.2
Reset Implementation Cautions
To prevent the Universe II from resetting the PCI bus, the LRST_ output can be left unconnected.
Otherwise, LRST_ must be grouped with other PCI reset generators to assert the RST_ signal so that
the following conditions are met:
RST_ = LRST_ & reset_source1 & reset_source2 &...
If the Universe II is the only initiator of PCI reset, LRST_ can be directly connected to RST_.
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9. Resets, Clocks and Power-up Options > Resets
Assertion of VME_RESET_ causes the Universe II to assert VXSYSRST_.
Since VME_RESET_ causes assertion of SYSRST*, and since SYSRST* causes
assertion of LRST_, tying both VME_RESET_ and LRST_ to RST_ will put the
Universe II into permanent reset. If VME_RESET_ is driven by PCI reset logic,
ensure that the logic is designed to break this feedback path.
The PWRRST_ input keeps the Universe II in reset until the power supply has reached a stable level
(see Table 21). It must be held asserted for over 100 milliseconds after power is stable. Typically this
can be achieved through a resistor/capacitor combination (see Figure 22)or under voltage sensing
circuits.
Figure 22: Resistor-Capacitor Circuit Ensuring Power-Up Reset Duration
47 K
PWRRST_
10μF
The Universe II supports the VMEbus CSR Bit Clear and Bit Set registers. The “VMEbus CSR Bit Set
Register (VCSR_SET)” on page 330 register allows the user to assert LRST_ or SYSFAIL by writing
to the RESET or SYSFAIL bits. LRST_ or SYSFAIL remains asserted until the corresponding bit is
cleared in the“VMEbus CSR Bit Clear Register (VCSR_CLR)” on page 329. The FAIL bit in each of
these registers is a status bit and is set by the software to indicate board failure.
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9.3
135
Power-Up Options
The Universe II can be automatically configured at power-up to operate in different functional modes.
These power-up options allow the Universe II to be set in a particular mode independent of any local
intelligence.
Table 22: Power-Up Optionsa
Option
Register
Field
Default
Pins
VMEbus Register Access Slave
Image
VRAI_CTL
EN
Disabled
VA[31]
VAS
A16
VA[30:29]
VRAI_BS
BS
0x00
VA[28:21]
VCSR_CTL
LAS
Memory
VA[20]
VCSR_TO
TO
0x00
VA[19:15]
MISC_STAT
DY4AUTO
Disabled
VD[30]
MISC_CTL
V64AUTO
Disabled
VD[29]
VINT_EN
SW_INT
0
VINT_STAT
SW_INT
0
VINT_MAP1
SW_INT
000
BI-Mode
MISC_CTL
BI
Disabled
VD[28]
Auto-Syscon Detect
MISC_CTL
SYSCON
Enabled
VBGIN[3]*
SYSFAIL* Assertion
VCSR_SET
SYSFAIL
Asserted
VD[27]
VCSR_CLR
SYSFAIL
LSI0_CTL
EN
Disabled
VA[13]
LAS
Memory
VA[12]
VAS
A16
VA[11:10]
LSI0_BS
BS
0x0
VA[9:6]
LSI0_BD
BD
0x0
VA[5:2]
PCI Register Access
PCI_BS0,
PCI_BS1
SPACE
See “Registers”
on page 163
VA[1]
PCI Bus Sizeb
MISC_STAT
LCLSIZE
32-bit
REQ64_
PCI CSR Master Enable
PCI_CSR
BM
Disabled
VA[14]
VMEbus CR/CSR Slave Image
Auto-ID
PCI Target Image
a. All power-up options are latched only at the rising-edge of PWRRST_. They are loaded when PWRRST_,
SYSRST* and RST_ are negated.
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9. Resets, Clocks and Power-up Options > Power-Up Options
b. The PCI Bus Size is loaded on any RST_ event (PCI 2.1 Specification).
The majority of the Universe II power-up options are loaded from the VMEbus address and data lines
after any PWRRST_ (see Table 22 on page 135). The PCI bus width (a power-up option required by
the PCI 2.1 Specification) is loaded on any RST_ event from the REQ64_ pin.
The second special power-up option is VMEbus SYSCON enabling, required by the VMEbus
specification. The SYSCON option is loaded during a SYSRST* event from the BG3IN* signal.
All power-up options are latched from the state of a particular pin or group of pins on the rising edge of
PWRST_. Each of these pins, except REQ64_, has a weak internal pull-down to put the Universe II
into a default configuration. (REQ64_ has an internal pull-up). If a non-default configuration is
required, a pull-up of approximately 10k is required on the signal. See “PCI Bus Width” on page 138
and the VMEbus Specification.
The Universe II may be restored to the state it was in immediately following the previous power-up
without re-asserting PWRRST_. After SYSRST* or RST_ (with PWRRST_ negated), the values that
were originally latched at the rising edge of PWRRST_ are reloaded into the Universe II (except for
PCI bus width and VMEbus SYSCON enabling, which are loaded from their pins).
Table 22 lists the power-up options of the Universe II, the pins which determine the options, and the
register settings that are set by this option. Each option is described in more detail in “Power-up Option
Descriptions” on page 136.
9.3.1
Power-up Option Descriptions
This section describes each of the groups of power-up options that were listed in Table 22.
9.3.1.1
VMEbus Register Access Image
The Universe II has several VMEbus slave images, each of which can provide a different mapping of
VMEbus cycles to PCI cycles. All VMEbus slave images are configurable through a set of VMEbus
slave image registers: VSIx_CTL, VSIx_BS, VSIx_BD, and VSIx_TO.
No VMEbus to PCI transaction is possible until these registers are programmed.
The VMEbus Register Access Image (VRAI) power-up option permits access from the VMEbus to the
Universe II internal registers at power-up. The power-up option allows programming of the VMEbus
register access image address space and the upper five bits of its base address; all other bits are 0 (see
Table 23). Once access is provided to the registers, then all other Universe II features (such as further
VMEbus slave images) can be configured from the VMEbus.
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Table 23 shows how the upper bits in the VRAI base address are programmed for A16, A24, and A32
VMEbus register access images.
Table 23: VRAI Base Address Power-up Options
VRAI_CTL: VAS
BS [31:24]
BS [23:16]
BS [15:12]
A16
0
0
Power-up Option
VA [28:25]
A24
0
Power-up Option
0
VA [28:21]
A32
Power-up Option
0
0
VA [28:21]
9.3.1.2
VMEbus CR/CSR Slave Image
CR/CSR space is an address space introduced in the VME64 Specification. The CR/CSR space on any
VMEbus device is 512 Kbytes in size; the upper region of the 512 Kbytes dedicated to register space,
and the lower region is dedicated to configuration ROM. The Universe II maps its internal registers to
the upper region of the CR/CSR space, and passes all other accesses through to the PCI bus (see
“Registers” on page 163).
The VMEbus CR/CSR Slave Image power-up option maps CR/CSR accesses to the PCI bus. CR/CSR
space can be mapped to memory or I/O space with a 5-bit offset. This allows mapping to any 128
Mbyte page on the PCI bus. As part of this implementation, ensure that the PCI Master Interface is
enabled through the MAST_EN bit power-up option or configured through a register access before
accessing configuration ROM.
9.3.1.3
Auto-ID
There are two Auto-ID mechanisms provided by the Universe II. One is the VME64 Specification
version which relies upon use of the CR/CSR space for configuration of the VMEbus system, and a
IDT proprietary system which uses the IACK daisy chain for identifying cards in a system. Either of
these mechanisms can be enabled at power-up (see “Automatic Slot Identification” on page 42).
Because VME64 Auto-ID relies upon SYSFAIL to operate correctly, this power-up option overrides
the SYSFAIL power-up option described in “SYSFAIL* Assertion” on page 138.
9.3.1.4
BI-Mode
BI-Mode (Bus Isolation Mode) is a mechanism for logically isolating the
Universe II from the VMEbus for diagnostic, maintenance and failure recovery purposes. BI-Mode can
be enabled as a power-up option (see “Bus Isolation Mode (BI-Mode)” on page 46). When the
Universe II has been powered-up in BI-Mode, then any subsequent SYSRST* or RST_ restores the
Universe II to BI-Mode,
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9.3.1.5
9. Resets, Clocks and Power-up Options > Power-Up Options
Auto-Syscon Detect
The VMEbus SYSCON enabling, required by the VMEbus Specification, is a special power-up option
in that it does not return to its after-power-up state following RST_ or SYSRST_. The SYSCON option
is loaded during a SYSRST* event from the VBG3IN* signal.
9.3.1.6
SYSFAIL* Assertion
This power-up option causes the Universe II to assert SYSFAIL* immediately upon entry into reset.
The SYSFAIL* pin is released through a register access. Note that this power-up option is over-ridden
if VME64 Auto-ID has been enabled. This option is used when extensive on-board diagnostics need to
be performed before release of SYSFAIL*. After completion of diagnostics, SYSFAIL* can be
released through software or through initiation of the VME64 Auto-ID sequence (if enabled, see “Auto
Slot ID: VME64 Specified” on page 42).
9.3.1.7
PCI Target Image
The PCI Target Image power-up option provides for default enabling of a PCI target image
(automatically mapping PCI cycles to the VMEbus). The default target image can be mapped with base
and bounds at 256MB resolution in Memory or I/O space, and map PCI transactions to different
VMEbus address spaces. Beyond the settings provided for in this power-up option, the target image
possesses its other default conditions: the translation offset is 0, posted writes are disabled, and only
32-bit (maximum) non-block VMEbus cycles in the non-privileged data space are generated.
This option is typically used to access permits the use of Boot ROM on another card in the VMEbus
system.
9.3.1.8
PCI Register Access
A power-up option determines if the registers are mapped into Memory or I/O space.
9.3.1.9
PCI Bus Width
The PCI Interface can be used as a 32-bit bus or 64-bit bus. The PCI bus width is determined during a
PCI reset (see the PCI 2.1 Specification). The Universe II is configured as 32-bit PCI if REQ64_ is
high on RST_; it is configured as 64-bit if REQ64_ is low. The Universe II has an internal pull-up on
REQ64_, so the
Universe II defaults to 32-bit PCI. On a 32-bit PCI bus, the Universe II drives all its 64-bit extension
bi-direct signals at all times; these signals include: C/BE[7:4]_, AD[63:32], REQ64_, PAR64 and
ACK64_ to unknown values. If used as a 32-bit interface, the 64-bit pins, AD[63:32], C/BE[7:4],
PAR64 and ACK64_ can be left un-terminated.
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9.3.1.10
139
PCI CSR Image Space
There is a power-up option (using the VA[1] pin) that determines the value of the SPACE bit of the
PCI_BSx registers. At power-up the SPACE bit of the PCI_BS1 register is the negation of the SPACE
bit of the PCI_BS0 register.
•
When the VA pin is sampled low at power-up, the PCI_BS0 register’s SPACE bit is set to 1, which
signifies I/O space, and the PCI_BS1 register’s SPACE bit is set to 0, which signifies Memory
space.
•
When VA is sampled high at power-up, the PCI_BS0 register’s SPACE register’s bit is set to 0,
which signifies Memory space, and the PCI_BS1 register’s SPACE bit is set to 1, which signifies
I/O space.
Once set, this mapping is constant until the next power-up sequence. See “Memory or I/O Access” on
page 77.
9.3.2
Power-up Option Implementation
In order to implement power-up requirements for the Universe II weak pull-up resistors are required.
9.3.2.1
Pull-up Requirements
The pull-ups for the general power-up options (if other than default values are required) must be placed
on the VA[31:1] and VD[31:27] lines. During reset, the Universe II negates VOE_, putting these
signals into a high-impedance state. While VOE_ is negated the pull-ups (or internal pull-downs) bring
the option pins (on A[31:1] and D[31:27]) to their appropriate state.
The internal pull-downs are very weak. The leakage current on many transceivers
can be sufficient to override these pull-downs. To ensure proper operation
designers must ensure power-up option pins go to the correct state.
Within two CLK64 periods after PWRRST_ is negated, the Universe II latches the levels on the option
pins, and then negates VOE_ one clock later. This enables the VMEbus transceivers inwards.
Figure 23: Power-up Options Timing
minimum 100ms
CLK64
PWRRST_
VOE_
VA, VD
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9. Resets, Clocks and Power-up Options > Power-Up Options
The power-up options are subsequently loaded into their respective registers several PCI clock periods
after PWRRST_, SYSRST* and RST_ have all been negated.
Because of the power-up configuration, the VMEbus buffers are not enabled
until several CLK64 periods after release of SYSRST* (approximately 45 ns).
Allowing for worst case backplane skew of 25 ns, the Universe II is not prepared
to receive a slave access until 70 ns after release of SYSRST*.
9.3.3
Hardware Initialization (Normal Operating Mode)
The Universe II has I/O capabilities that are specific to manufacturing test functions. These pins are not
required in a non-manufacturing test setting. Table 24 shows how these pins must be terminated.
Table 24: Manufacturing Pin Requirements for Normal Operating Mode
Pin Name
Pin Value
tmode[2]
VSS (or pulled-down if board tests are performed, see “Auxiliary Test Modes” on
page 141)
tmode[1]
tmode[0]
pll_testsel
VSS
enid
VSS
pll_testout
No connect
VCOCTL
VSS
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9.4
141
Test Modes
The Universe II provides two types of test modes: auxiliary modes (NAND tree simulation and High
Impedance) and JTAG (IEEE 1149.1).
9.4.1
Auxiliary Test Modes
Two auxiliary test modes are supported: NAND tree and high impedance. The Universe II has three
test mode input pins (TMODE[2:0]). For normal operations these inputs should be tied to ground (or
pulled to ground through resistors). Table 25 below indicates the 3 operating modes of the Universe II.
At reset the TMODE[2:0] inputs are latched by the Universe II to determine the mode of operation.
The Universe II remains in this mode until the TMODE[2:0] inputs have changed and a reset event has
occurred. PLL_TESTSEL must be high for any test mode.
Table 25: Test Mode Operation
Operation Mode
TMODE[2:0]
PLL_TESTSEL
Normal Mode
000
0
Accelerate
001
0
PLL Test
010
1
Scan Mode
011
1
NAND Tree Simulation
100
1
RAM Test
101
1
High Impedance
110
0/1
Reserved
111
1
For NAND Tree Simulation, the values of the TMODE pins are latched during the active part of
PWRRST_. These pins can change state during the NAND Tree tests. The timers are always
accelerated in this mode. All outputs are tristated in this mode, except for the VXSYSFAIL output pin.
For High Impedance mode, the values of the TMODE pins are also latched during the active part of
PWRRST_. All outputs are tristated in this mode, except for the VXSYSFAIL output pin.
9.4.2
JTAG support
The Universe II includes dedicated user-accessible test logic that is fully compatible with the IEEE
1149.1 Standard Test Access Port (TAP) and Boundary Scan Architecture. This standard was
developed by the Test Technology Technical Committee of IEEE Computer Society and the Joint Test
Action Group (JTAG). The Universe II’s JTAG support includes:
•
five-pin JTAG interface (TCK, TDI, TDO, TMS, and TRST_)
•
JTAG TAP controller
•
three-bit instruction register
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9. Resets, Clocks and Power-up Options > Clocks
•
boundary scan register
•
bypass register
•
an IDCODE register
The following required public instructions are supported: BYPASS (3'b111), SAMPLE(3'b100), and
EXTEST(3'b000). The optional public instruction IDCODE(3'b011) selects the IDCODE register
which returns 32'b01e201d. The following external pins are not part of the boundary scan register:
LCLK, PLL_TESTOUT, PLL_TESTSEL, TMODE[3:0], and VCOCTL.
9.5
Clocks
CLK64 is a 64 MHz clock that is required by the Universe II in order to synchronize internal Universe
II state machines and to produce the VMEbus system clock (VSYSCLK) when the Universe II is
system controller (SYSCON). This clock is specified to have a minimum 50-50 duty cycle with a
maximum rise time of 5 ns.
Using a different clock frequency is not recommended. It will alter various
internal timers and change VME timing.
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10.
Signals and Pinout
This chapter discusses the following topics:
10.1
•
“VMEbus Signals” on page 144
•
“PCI Bus Signals” on page 147
•
“Pin-out” on page 151
Overview
The following detailed description of the Universe II signals is organized according to these functional
groups:
•
VMEbus Signals
•
PCI Signals
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10. Signals and Pinout > VMEbus Signals
10.2
VMEbus Signals
Table 26: VMEbus Signals
CLK64
Input
Reference Clock – this 64MHz clock is used to generate fixed timing parameters. It requires a 50-50 duty cycle (±20%)
with a 5ns maximum rise time. CLK64 is required to synchronize the internal state machines of the VME side of the
Universe II.
VA [31:1]
Bidirectional
VMEbus Address Lines 31 to 01 – during MBLT transfers, VA 31-01 serve as data bits D63-D33.
VA03-01 are used to indicate interrupt level on the VMEbus.
VA_DIR
Output
VMEbus Address Transceiver Direction Control – the Universe II controls the direction of the address (VA31-01,
VLWORD_) transceivers as required for master, slave and bus isolation modes. When the Universe II is driving lines
on the VMEbus, this signal is driven high; when the VMEbus is driving the Universe II, this signal is driven low.
VAM [5:0]
Bidirectional
VMEbus Address Modifier Codes – these codes indicate the address space being accessed (A16, A24, A32), the
privilege level (user, supervisor), the cycle type (standard, BLT, MBLT) and the data type (program, data).
VAM_DIR
Output
VMEbus AM Code Direction Control – controls the direction of the AM code transceivers as required for master, slave
and bus isolation modes. When the Universe II is driving lines on the VMEbus, this signal is driven high; when the
VMEbus is driving the Universe II, this signal is driven low.
VAS_
Bidirectional
VMEbus Address Strobe – the falling edge of VAS_ indicates a valid address on the bus. By continuing to assert
VAS_, ownership of the bus is maintained during a RMW cycle.
VAS_DIR
Output
VMEbus Address Strobe Direction Control – controls the direction of the address strobe transceiver as required for
master, slave and bus isolation modes. When the Universe II is driving lines on the VMEbus, this signal is driven high;
when the VMEbus is driving the Universe II, this signal is driven low.
VBCLR_
Output
VMEbus Bus Clear – requests that the current owner release the bus.
Asserted by the Universe II when configured as SYSCON and the arbiter detects a higher level pending request.
VBGI[3:0]_
Input
VMEbus Bus Grant Inputs – The VME arbiter awards use of the data transfer bus by driving these bus grant lines low.
The signal propagates down the bus grant daisy chain and is either accepted by a requester if it requesting at the
appropriate level, or passed on as a VBGO [3:0]_ to the next board in the bus grant daisy chain.
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145
Table 26: VMEbus Signals (Continued)
VBGO[3:0]_
Output
VMEbus Bus Grant Outputs – Only one output is asserted at any time, according to the level at which the VMEbus is
being granted.
VD[31:0]_
Bidirectional
VMEbus Data Lines – 31 through 0
VD_DIR
Output
VMEbus Data Transceiver Direction Control – the Universe II controls the direction of the data (VD [31:0]) transceivers
as required for master, slave and bus isolation modes. When the Universe II is driving lines on the VMEbus, this signal
is driven high; when the VMEbus is driving the Universe II, this signal is driven low.
VDS[1:0]_
Bidirectional
VMEbus Data Strobes – the level of these signals are used to indicate active byte lanes During write cycles, the falling
edge indicates valid data on the bus. During read cycles, assertion indicates a request to a slave to provide data.
VDS_DIR
Output
VMEbus Data Strobe Direction Control – controls the direction of the data strobe transceivers as required for master,
slave and bus isolation modes. When the Universe II is driving lines on the VMEbus, this signal is driven high; when
the VMEbus is driving the Universe II, this signal is driven low.
VDTACK_
Bidirectional
VMEbus Data Transfer Acknowledge – VDTACK_ driven low indicates that the addressed slave has responded to the
transfer. The Universe II always rescinds DTACK*. It is tristated once the initiating master negates AS*.
VIACK_
Bidirectional
VMEbus Interrupt Acknowledge – Indicates that the cycle just beginning is an interrupt acknowledge cycle.
VIACKI_
Input
VMEbus Interrupt Acknowledge In – Input for IACK daisy chain driver. If interrupt acknowledge is at same level as
interrupt currently generated by the Universe II, then the cycle is accepted. If interrupt acknowledge is not at same
level as current interrupt or Universe II is not generating an interrupt, then the Universe II propagates VIACKO_.
VIACKO_
Output
VMEbus Interrupt Acknowledge Out– Generated by the Universe II if it receives VIACKI_ and is not currently
generating an interrupt at the level being acknowledged.
VLWORD_
Bidirectional
VMEbus Longword Data Transfer Size Indicator – This signal is used in conjunction with the two data strobes
VDS [1:0]_ and VA 01 to indicate the number of bytes (1 – 4) in the current transfer. During MBLT transfers VLWORD_
serves as data bit D32.
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10. Signals and Pinout > VMEbus Signals
Table 26: VMEbus Signals (Continued)
VOE_
Output
VMEbus Transceiver Output Enable – Used to control transceivers to isolate the Universe II from the VMEbus during a
reset or BI-mode. On power-up, VOE_ is high (to disable the buffers). VOE_ is negated during some VMEbus Slave
Channel read operations.
VRACFAIL_
Input
VMEbus ACFAIL Input signal – Warns the VMEbus system of imminent power failure. This gives the modules in the
system time to shut down in an orderly fashion before power-down. ACFAIL is mapped to a PCI interrupt.
VRBBSY_
Input
VMEbus Receive Bus Busy – Allows the Universe II to monitor whether the VMEbus is owned by another VMEbus
master
VRBERR_
Input
VMEbus Receive Bus Error – A low level signal indicates that the addressed slave has not responded, or is signalling
an error.
VRBR[3:0]_
Input
VMEbus Receive Bus Request Lines – If the Universe II is the Syscon, the arbiter logic monitors these signals and
generates the appropriate Bus Grant signals. Also monitored by requester in ROR mode.
VRIRQ[7:1]_
Input
VMEbus Receive Interrupts 7 through 1 – These interrupts can be mapped to any of the Universe II’s PCI interrupt
outputs. VRIRQ7-1_ are individually maskable, but cannot be read.
VRSYSFAIL_
Input
VMEbus Receive SYSFAIL – Asserted by a VMEbus system to indicate some system failure. VRSYSFAIL_ is mapped
to a PCI interrupt.
VRSYSRST_
Input
VMEbus Receive System Reset – Causes assertion of LRST_ on the local bus and resets the Universe II.
VSLAVE_DIR
Output
VMEbus Slave Direction Control – Transceiver control that allows the Universe II to drive DTACK* on the VMEbus.
When the Universe II is driving lines on the VMEbus, this signal is driven high; when the VMEbus is driving the
Universe II, this signal is driven low.
VSYSCLK
Bidirectional
VMEbus System Clock – Generated by the Universe II when it is the Syscon and monitored during DY4 Auto ID
sequence
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147
Table 26: VMEbus Signals (Continued)
VSCON_DIR
Output
Syscon Direction Control – Transceiver control that allows the Universe II to drive VBCLR_ and SYSCLK. When the
Universe II is driving lines on the VMEbus, this signal is driven high; when the VMEbus is driving the Universe II, this
signal is driven low.
VWRITE_
Bidirectional
VMEbus Write signal – Indicates the direction of data transfer.
VXBBSY
Output
VMEbus Transmit Bus Busy Signal – Generated by the Universe II when it is VMEbus master
VXBERR
Output
VMEbus Transmit Bus Error Signal – Generated by the Universe II when PCI target generates Target-Abort on
coupled PCI access from VMEbus.
VXBR [3:0]
Output
VMEbus Transmit Bus Request – The Universe II requests the VMEbus when it needs to become VMEbus master.
VXIRQ [7:1]
Output
VMEbus Transmit Interrupts – The VMEbus interrupt outputs are individually maskable.
VXSYSFAIL
Output
VMEbus System Failure – Asserted by the Universe II during reset and plays a role in VME64 Auto ID.
VXSYSRST
Output
VMEbus System Reset – The Universe II output for SYSRST*.
10.3
PCI Bus Signals
Table 27: PCI Bus Signals
ACK64_
Bidirectional
Acknowledge 64-bit Transfer – It indicates slave can perform a 64-bit transfer when driven by the PCI slave (target).
AD [31:0]
Bidirectional
PCI Address/Data Bus – Address and data are multiplexed over these pins providing a 32-bit address and 32-bit data
bus.
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10. Signals and Pinout > PCI Bus Signals
Table 27: PCI Bus Signals
AD [63:32]
Bidirectional
PCI Address/Data Bus – Address and data are multiplexed over these pins providing 64-bit address and data
capability.
C/BE_ [7:0]
Bidirectional
PCI Bus Command and Byte Enable Lines – Command and byte enable information is multiplexed over all eight C/BE
lines. C/BE [7:4]_ are only used in a 64-bit PCI bus
DEVSEL_
Bidirectional
PCI Device Select – This signal is driven by the Universe II when it is accessed as PCI slave.
ENID
Input
Enable IDD Tests – Required for ASIC manufacturing test, tie to ground for normal operation.
FRAME_
Bidirectional
Cycle Frame – This signal is driven by the Universe II when it is PCI initiator, and is monitored by the Universe II when
it is PCI target
GNT_
Input
PCI Grant – indicates to the Universe II that it has been granted ownership of the PCI bus.
IDSEL
Input
PCI Initialization Device Select – This signal is used as a chip select during configuration read and write transactions
LINT[7:0]_
Bidirectional (Open Drain)
PCI Interrupt Inputs – These PCI interrupt inputs can be mapped to any PCI bus or VMEbus interrupt output.
IRDY_
Bidirectional
Initiator Ready – Is used by the Universe II as PCI master to indicate that is ready to complete a current data phase.
LCLK
Input
PCI Clock – Provides timing for all transactions on the PCI bus. PCI signals are sampled on the rising edge of CLK,
and all timing parameters are defined relative to this signal. The PCI clock frequency of the Universe II must be
between 25 and 33MHz. Lower frequencies result in invalid VME timing.
LOCK_
Bidirectional
Lock – Used by the Universe II to indicate an exclusive operation with a PCI device. While the Universe II drives
LOCK_, other PCI masters are excluded from accessing that particular PCI device. When the Universe II samples
LOCK_, it can be excluded from a particular PCI device.
LRST_
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149
Table 27: PCI Bus Signals
PCI Reset Output – Used to reset PCI resources.
PAR
Bidirectional
Parity – Parity is even across AD [31:0] and C/BE [3:0] (the number of 1s summed across these lines and PAR equal
an even number).
PAR64
Bidirectional
Parity Upper DWORD – Parity is even across AD [63:32] and C/BE [7:4] (the number of 1s summed across these lines
and PAR equal an even number).
PERR_
Bidirectional
Parity Error – Reports parity errors during all transactions. The Universe II drives PERR_ high within two clocks of
receiving a parity error on incoming data, and holds PERR_ for at least one clock for each errored data phase.
PLL_TESTOUT
Output
Manufacturing Test Output—No connect
PLL_TESTSEL
Input
Manufacturing Test Select—Tie to ground for normal operation
PWRRST_
Input
Power-up Reset – All Universe II circuitry is reset by this input.
REQ_
Output
Bus Request – Used by the Universe II to indicate that it requires the use of the PCI bus.
REQ64_
Bidirectional
64-Bit Bus Request— Used to request a 64-bit PCI transaction. If the target does not respond with ACK64_, 32-bit
operation is assumed.
RST_
Input
PCI Reset Input— Resets the Universe II from the PCI bus.
SERR_
Output
System Error – Reports address parity errors or any other system error.
STOP_
Bidirectional
Stop – Used by the Universe II as PCI slave when it wishes to signal the PCI master to stop the current transaction. As
PCI master, the Universe II terminates the transaction if it receives STOP_ from the PCI slave.
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10. Signals and Pinout > PCI Bus Signals
Table 27: PCI Bus Signals
TCK
Input
JTAG Test Clock Input – Used to clock the Universe II’s TAP controller. Tie to any logic level if JTAG is not used in the
system.
TDI
Input
JTAG Test Data Input – Used to serially shift test data and test instructions into the Universe II. Tie to any logic level if
JTAG is not used in the system.
TDO
Output
JTAG Test Data Output – Used to serially shift test data and test instructions out of the Universe II
TMODE [2:0]
Input
Test Mode Enable – Used for chip testing, tie to ground for normal operation.
TMS
Input
JTAG Test Mode Select – Controls the state of the Test Access Port (TAP) controller in the Universe II. Tie to any logic
level if JTAG is not used in the system.
TRDY_
Bidirectional
Target Ready – Used by the Universe II as PCI slave to indicate that it is ready to complete the current data phase.
During a read with Universe II as PCI master, the slave asserts TRDY_ to indicate to the Universe II that valid data is
present on the data bus.
TRST_
Input
JTAG Test Reset – Provides asynchronous initialization of the TAP controller in the Universe II. Tie to ground if JTAG
is not used in the system.
VCOCTL
Input
Manufacturing testing – Tie to ground for normal operation
VME_RESET_
Input
VMEbus Reset Input — Generates a VME bus system reset.
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10.4
Pin-out
10.4.1
313-pin Plastic BGA Package (PBGA)
A
1
vd[22]
2
3
vrberr_
9
vam[5]
10
11
vam[3]
15
vas_
18
19
va[12]
22
23
vxsysrst
clk64
va[25]
vrirq_[2]
vxbr[3]
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vxbr[0]
vbgo_[2]
int_[0]
VDD
vxirq[4]
vracfail_
vbgo_[0]
vxirq[5]
vbgo_[1]
ad[3]
vrirq_[6]
vbgi_[3]
vbgi_[2]
VDD
ad[5]
ad[34]
ad[36]
ad[40]
tmode[2]
VDD
lock_
ad[44]
VDD
ad[6]
21
22
viacki_
VDD
VSS
19
20
enid
ad[42]
ad[7]
17
18
ad[46]
ad[10]
ad[8]
VDD
ad[37]
req64_
ad[11]
tmode[1]
15
16
gnt_
ad[12]
ad[43]
VSS
ad[47]
stop_
13
14
cbe[4]
VDD
rst_
ad[41]
vme_res
et_
VSS
vxirq[7]
ad[45]
ad[39]
cbe[5]
idsel
ad[13]
VDD
ad[38]
ad[4]
vxbr[2]
VSS
11
12
VSS
irdy_
9
10
ad[16]
cbe[7]
VSS
ad[14]
frame_
ad[35]
VDD
ad[1]
vbgo_[3]
vrirq_[5]
VDD
vrsysfail_
7
8
ad[19]
ad[17]
cbe[0]
ad[20]
ad[50]
tmode[0]
VDD
VDD
ad[2]
vbgi_[0]
vxirq[6]
vxirq[2]
VSS
ad[52]
5
6
trdy_
VSS
VDD
ad[49]
cbe[1]
ad[15]
vrirq_[7]
ad[33]
viacko_
req_
vxbr[1]
ad[0]
ad[53]
cbe[3]
par64
devsel_
3
4
VSS
ad[54]
VSS
ad[48]
cbe[2]
serr_
ack64_
VSS
VSS
VSS
VDD
vrirq_[4]
vrirq_[1]
va[31]
vrirq_[3]
vxirq[3]
cbe[6]
VSS
vbgi_[1]
ad[51]
vcoctl
AVDD
1
2
ad[22]
ad[55]
ad[21]
ad[18]
VSS
VSS
VSS
ad[32]
vxirq[1]
va[27]
va[29]
va[30]
va[26]
VDD
va[22]
VSS
VSS
VDD
VSS
VDD
AVSS
VDD
int_[1]
AE
VDD
perr_
ad[23]
VDD
VDD
VSS
VSS
VSS
VDD
VDD
va[28]
VDD
VDD
va[24]
va[16]
va[21]
vlword_
va[7]
ad[31]
VSS
ad[28]
AD
PLL_
testsel
lclk
vrbr_[0]
AC
PLL_
testout
ad[56]
int_[3]
ad[29]
ad[62]
VSS
VSS
va[4]
va[6]
va[23]
vrsysrst_
va[20]
24
25
va[17]
va[19]
va[1]
va[13]
vxsysfail
vas_DIR
VDD
par
VSS
VSS
VSS
vdtack_
va[14]
va[18]
va[15]
va[3]
va[10]
VSS
tck
vsysclk
int_[6]
int_[2]
vds_DIR
va_DIR
VDD
va[9]
va[11]
20
21
va[5]
va[8]
vam[4]
vds_[0]
vrbr_[3]
vd[1]
VDD
VDD
trst_
vslave_D
IR
VDD
vd_DIR
vxberr
vd[0]
VDD
vam[2]
vam[0]
tdo
va[2]
16
17
vam[1]
voe_
VDD
vd[29]
vd[31]
tms
tdi
14
viack_
vwrite_
VDD
vds_[1]
12
13
vd[28]
vam_DIR
AB
ad[58]
ad[57]
ad[26]
AA
ad[24]
ad[25]
VSS
Y
ad[27]
VDD
ad[60]
W
ad[59]
pwrrst_
ad[30]
V
vrbr_[1]
vrbr_[2]
ad[63]
U
ad[61]
VSS
vrbbsy_
T
lrst_
vbclr_
VDD
R
vxbbsy
int_[4]
vd[7]
P
VSS
int_[5]
vd[8]
N
vscon_
DIR
vd[4]
vd[10]
M
int_[7]
vd[3]
vd[17]
L
vd[2]
vd[11]
vd[16]
K
VDD
vd[12]
VDD
J
vd[6]
vd[15]
vd[25]
H
vd[5]
vd[20]
vd[24]
G
vd[13]
VDD
vd[27]
F
vd[9]
vd[21]
vd[30]
E
vd[14]
vd[26]
8
D
vd[19]
vd[23]
6
7
C
vd[18]
4
5
B
23
24
ad[9]
25
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11.
Electrical Characteristics
This chapter discusses the following topics:
•
“DC Characteristics” on page 153
•
“Operating Conditions” on page 160
•
“Power Dissipation” on page 161
11.1
DC Characteristics
11.1.1
Non-PCI Characteristics
Table 28 specifies the required DC characteristics of all non-PCI signals pins.
Table 28: Non-PCI Electrical Characteristics
Tested at
0°C to 70°C
Symbols
Parameters
Test conditions
Min
Max
VIH_TTL
Voltage Input high
VOUT = 0.1V or VDD – 0.1V;
[IOUT] = 20 µA
2.2 V
VDD + 0.3V
VIH_CMOS
Voltage Input high
VOUT = 0.1V or VDD – 0.1V;
[IOUT] = 20 µA
0.7 Vdd
VDD + 0.3V
VIL_TTL
Voltage Input low
VOUT = 0.1V or VDD – 0.1V;
[IOUT] = 20 µA
–0.3 V
0.8V
VIL_CMOS
Voltage Input low
VOUT = 0.1V or VDD – 0.1V;
[IOUT] = 20 µA
–0.3 V
0.3VDD
VT+_TTL
Voltage Input high
(Schmitt trigger)
VOUT = 0.1V or VDD – 0.1V;
[IOUT] = 20 µA
-
2.4 V
VT+_CMOS
Voltage Input high
(Schmitt trigger)
VOUT = 0.1V or VDD – 0.1V;
[IOUT] = 20 µA
-
0.7VDD
VT -_ttl
Voltage Input low
(Schmitt trigger)
VOUT = 0.1V or VDD – 0.1V;
[IOUT] = 20 µA
0.8V
-
VT -_CMOS
Voltage Input low
(Schmitt trigger)
VOUT = 0.1V or VDD – 0.1V;
[IOUT] = 20 µA
0.25VDD
-
IIN
Input leakage current
With no pull-up or pull-down
resistance (Vin = Vss or VDD )
-5.0A
5.0A
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11. Electrical Characteristics > DC Characteristics
Table 28: Non-PCI Electrical Characteristics
Tested at
0°C to 70°C
Symbols
Parameters
Test conditions
Min
Max
IIH
Input leakage current
high
Inputs with pull-down resistance
(Vin = Vdd)
10A
180A
IIL
Input leakage current
low
Inputs with pull-up resistance
-180A
-10A
Tristate output leakage
Vout = Vdd or Vss
-10.0A
10.0A
IOZ
11.1.2
(Vin = Vss)
PCI Characteristics
Table 29 specifies the required AC and DC characteristics of all PCI Universe II signal pins.
Table 29: AC/DC PCI Electrical Characteristics
Symbols
Parameters
VIL
Condition
Min
Max
Units
Voltage Input low
-0.5
0.8
V
VIH
Voltage Input high
2.0
Vdd + 0.5
V
IIN
Input leakage current
Vin = 2.7V or
0.5V
-10
10
A
IIL
Input leakage current low
Vin = 0.5V
-70
-10
A
(Pin with pull-up)
VOL
Voltage output low
Iout = 3mA, 6mA
-
0.4
V
VOH
Voltage output high
Iout = -2mA
2.4
-
V
IOH (AC)a
Switching current high
0 < Vout21.4
-44
-
mA
1.4 < Vout < 2.4
-44 + (Vout -1.4) /
0.024
-
mA
3.1 < Vout < Vdd
-
Equation A
mA
(Test point)
Vout = 3.1V
-
-142
mA
Switching current high
0 < Vout31.4
95
-
mA
0.6Vdd < Vout <
0.1Vdd
Vout / 0.023
-
mA
0.71 < Vout < 0
-
Equation B
mA
Vout = 0.71V
-
206
mA
IOL (AC)b
(Test point)
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Table 29: AC/DC PCI Electrical Characteristics
Symbols
Parameters
Condition
Min
Max
Units
ICL
Low clamp current
-5 Vin2-1
-25 + (Vin +10) /
0.015
-
mA
SLEWR
Output rise slew rate
0.4V to 2.4V
load
1
5
V/ns
SLEWR
Output fall slew rate
2.4V to 0.4V
load
1
5
V/ns
a. Equation A: Ioh = 11.9 * (Vout - 5.25) * (Vout + 2.45) for Vdd > Vout > 3.1V
b. Equation B: Iol = 78.5 * Vout * (4.4 - Vout) for 0V < Vout < 0.71V
11.1.3
Pin List and DC Characteristics for all Signals
Table 30 specifies the required DC characteristics of all Universe II signal pins
Table 30: Pin List and DC Characteristics for Universe II Signals
Pin Name
Pin Number
Type
Input Type
Output
Type
IOL
(mA)
IOH
(mA)
ack64#
W11
I/O
TTL
3S
6
–2
PCI Acknowledge 64 Bit
Transfer
AD [63:0]
Listed in: “313 Pin
PBGA Package”
on page 333
I/O
TTL
3S
6
–2
PCI Address/Data Pins
C/BE# [0]
Y14
I/O
TTL
3S
6
–2
PCI Command and Byte
Enables
C/BE# [1]
V14
C/BE# [2]
T14
C/BE# [3]
W13
C/BE# [4]
AE15
C/BE# [5]
AD14
C/BE# [6]
T12
C/BE# [7]
AD12
clk64
C23
I
TTL
–
–
–
VME Clock 64
MHz—60-40 duty, 5 ns
rise time
devsel#
AC7
I/O
–
3S
6
–2
PCI Device Select
enid
AE21
I
CMOS
–
–
–
Enable IDD Tests
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11. Electrical Characteristics > DC Characteristics
Table 30: Pin List and DC Characteristics for Universe II Signals (Continued)
Pin Name
Pin Number
Type
Input Type
Output
Type
IOL
(mA)
IOH
(mA)
frame#
W17
I/O
TTL
3S
6
–2
PCI Cycle Frame
gnt#
AE17
I
TTL
–
–
–
PCI Grant
idsel
AB16
I
TTL
–
–
–
PCI Initialization Device
Select
lint# [0]
K20
I/O
TTL
OD
12
–12
lint# [1]
AA5
I/O
TTL
OD
4
–4
lint# [2]
L9
lint# [3]
V6
lint# [4]
M4
lint# [5]
L3
lint# [6]
M8
lint# [7]
L1
irdy#
AC15
I/O
TTL
3S
6
–2
PCI Initiator Ready
lclk
AA3
I
TTL
–
–
–
PCI Clock Signal
lock#
AA23
I/O
TTL
3S
6
–2
PCI Lock
lrst#
R1
O
–
3S
6
–2
PCI Reset Output
par
P8
I/O
TTL
3S
6
–2
PCI parity
par64
AE5
I/O
TTL
3S
6
–2
PCI Parity Upper DWORD
perr#
AB4
I/O
TTL
3S
6
–2
PCI Parity Error
pll_testout
AB2
For factory testing
pll_testsel
AC1
For factory testing
pwrrst#
T4
I
TTL/Schm
–
–
–
Power–up Reset
req#
K22
O
–
3S
6
–2
PCI Request
req64#
AD18
I/O
TTL
3S
6
–2
PCI Request 64 Bit
Transfer
rst#
AA19
I
TTL
–
–
–
PCI Reset
serr#
AA7
O
TTL
OD
12
–12
PCI System Error
stop#
AB18
I/O
TTL
3S
6
–2
PCI Stop
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157
Table 30: Pin List and DC Characteristics for Universe II Signals (Continued)
Pin Name
Pin Number
Type
Input Type
Output
Type
IOL
(mA)
IOH
(mA)
tck
H12
I
TTL
–
–
–
JTAG Test Clock Input
tdi
A13
I
TTL
–
–
–
JTAG Test Data Input
Signal Description
(PU)
tdo
C13
O
–
3S
–
–
JTAG Test Data OUTput
tmode [0]
AA13
I
TTL
–
–
–
Test Mode Enable
tmode [1]
AA21
tmode [2]
W23
tms
C11
TTL
–
–
–
JTAG Test Mode Select
TTL
3S
6
–2
PCI Target Ready
TTL
–
–
–
JTAG Test Reset
3S
3
–3
VMEbus Address Pins
I
(PU)
trdy#
AD8
I/O
trst#
E13
I
(PU)
Listed in: “313 Pin
PBGA Package”
on page 333
I/O
vam [0]
E11
I/O
TTL
3S
3
–3
VMEbus Address Modifier
Signals
vam [1]
D10
vam [2]
G9
vam [3]
B10
vam [4]
H10
vam [5]
A9
vam_dir
B8
O
–
3S
6
–6
VMEbus AM Signal
Direction Control
vas#
B14
I/O
TTL/Schm
3S
3
–3
VMEbus Address Strobe
VA [31:1]
TTL
(PD)
(PU)
vas_dir
K12
O
–
3S
6
–6
VMEbus AS Direction
Control
va_dir
G13
O
–
3S
12
–12
VMEbus Address
Direction Control
vbclr#
N3
O
–
3S
3
–3
VMEbus BCLR* Signal
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11. Electrical Characteristics > DC Characteristics
Table 30: Pin List and DC Characteristics for Universe II Signals (Continued)
Pin Name
Pin Number
Type
Input Type
Output
Type
IOL
(mA)
IOH
(mA)
vbgi# [0]
N21
I
TT
–
–
–
vbgi# [1]
M16
vbgi# [2]
N25
vbgi# [3]
N23
vbgo# [0]
M20
vbgo# [1]
L25
vbgo# [2]
M18
vbgo# [3]
M24
vcoctl
Signal Description
VMEbus Bus Grant In
TT (PD)
O
–
3S
12
–12
VMEbus Bus Grant Out
AE3
I
–
–
–
–
Factory testing
VD [31:0]
Listed in: “313 Pin
PBGA Package”
on page 333
I/O
TTL
3S
3
–3
VMEbus Data Pins
vd_dir
F10
O
–
3S
12
–12
VMEbus Data Direction
Control
vds# [0]
F12
I/O
TTL
3S
3
–3
VMEbus Data Strobes
vds# [1]
A11
vds_dir
J11
O
–
3S
6
–6
VMEbus Data Strobe
Direction Control
vdtack#
G15
I/O
TTL/Schm
3S
3
–3
VMEbus DTACK* Signal
(PU)
(PU)
viack#
E7
I/O
TTL
3S
3
–3
VMEbus IACK* Signal
viacki#
AE23
I
TTL
–
–
–
VMEbus IACKIN* Signal
viacko#
L21
O
–
3S
12
–12
VMEbus IACKOUT*
Signal
vlword#
K14
I/O
TTL
3S
3
–3
VMEbus LWORD* Signal
(PD)
VME_RESET#
V22
I
TTL
voe#
B12
O
–
3S
24
–24
vracfail#
P18
I
TTL/Schm
–
–
–
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VMEbus Reset Input
VMEbus Transceiver
Output Enable
VMEbus ACFAIL* Signal
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159
Table 30: Pin List and DC Characteristics for Universe II Signals (Continued)
Pin Name
Pin Number
Type
Input Type
Output
Type
IOL
(mA)
IOH
(mA)
vrbbsy#
M6
I
TTL/Schm
–
–
–
VMEbus Received BBSY*
Signal
vrberr#
A7
I
TTL/Schm
–
–
–
VMEbus Receive Bus
Error
vrbr# [0]
W5
I
TTL/Schm
–
–
–
VMEbus Receive Bus
Request
vrbr# [1]
U1
vrbr# [2]
R3
vrbr# [3]
L7
vrirq# [1]
H22
I
TTL/Schm
–
–
–
VMEbus Receive
Interrupts
vrirq# [2]
H20
vrirq# [3]
E25
vrirq# [4]
J21
vrirq# [5]
V16
vrirq# [6]
P20
vrirq# [7]
R17
vrsysfail#
AC13
I
TTL
–
–
–
VMEbus Receive
SYSFAIL Signal
vrsysrst#
C21
I
TTL/Schm
–
–
–
VMEbus Receive
SYSRESET* Signal
vscon_dir
M2
O
–
3S
6
–6
SYSCON signals direction
control
vslave_dir
C15
O
–
3S
6
–6
DTACK/BERR direction
control
vsysclk
N7
I/O
TTL
3S
3
–3
VMEbus SYSCLK Signal
vwrite#
D8
I/O
TTL
3S
3
–3
VMEbus Write
vxbbsy
P2
O
–
3S
3
–3
VMEbus Transmit BBSY*
Signal
vxberr
D12
O
–
3S
3
–3
VMEbus Transmit Bus
Error (BERR*)
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11. Electrical Characteristics > Operating Conditions
Table 30: Pin List and DC Characteristics for Universe II Signals (Continued)
Pin Name
Pin Number
Type
Input Type
Output
Type
IOL
(mA)
IOH
(mA)
vxbr [0]
G25
O
–
3S
3
–3
VMEbus Transmit Bus
Request
vxbr [1]
H24
vxbr [2]
P24
vxbr [3]
G23
vxirq [1]
J19
O
–
3S
3
–3
VMEbus Transmit
Interrupts
vxirq [2]
K24
vxirq [3]
K18
vxirq [4]
J25
vxirq [5]
L23
vxirq [6]
M22
vxirq [7]
R25
vxsysfail
M10
O
–
3S
3
–3
VMEbus Transmit
SYSFAIL Signal
vxsysrst
A23
O
–
3S
3
–3
VMEbus Transmit
SYSRESET* Signal
11.2
Signal Description
Operating Conditions
The following table specifies recommended operating condition for the Universe II.
Table 31: Operating Conditions
Frequency
Operation (Mhz)
Symbols
Parameters
Min
Max
Vdd
DC Supply Voltage (5V ± 10%)
4.5V
5.5V
Ta (Commercial)
Ambient Temperature
0ºC
+70ºC
25 - 33
Ta (Industrial)
Ambient Temperature
-40ºC
+85ºC
25 - 33
Ta (Extended)
Ambient Temperature
-55ºC
+125ºC
25
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11.2.1
161
Absolute Maximum Ratings
Table 32: Absolute Maximum Ratings
Parameter
Range
DC Supply Voltage (VSS to VDD)
-0.3 to 7.0 V
DC Input Voltage (VIN)
-0.5 to vdd + 0.5V
DC Current Drain per Pin, Any Single Input or Output
± 50ma
DC Current Drain per Pin, Any Paralleled Outputs
± 100ma
DC Current Drain VDD and VSS Pins
± 75ma
Storage Temperature, (TSTG)
-40 ºC to 125 ºC
Stresses beyond those listed above may cause permanent damage to the devices.
These are stress ratings only, and functional operation of the devices at these or
any other conditions beyond those indicated in the operational sections of this
document is not implied. Exposure to maximum rating conditions for extended
periods may affect device reliability.
11.3
Power Dissipation
Table 33: Power Dissipation
Parameter
Rating
IDLE
Power Dissipation
1.50 W
Typical
Power Dissipation (32-bit PCI)
2.00 W
Power Dissipation (64-bit PCI)
2.20 W
Maximum
Power Dissipation (32-bit PCI)
2.70W
Power Dissipation (64-bit PCI)
3.20W
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11.4
11. Electrical Characteristics > Power Sequencing
Power Sequencing
When designing with the Universe II device, care must be taken when powering the device to ensure
proper operation. During power-up, no signals must be applied to any Universe II signal pins prior to
stable power being applied to the device.
In a mixed 3.3V and 5V design, IDT recommends that 5V power be stable prior to other
devices coming out reset. If other devices come out of reset before the 5V power is stable,
make certain that no signals are driven to the Universe II signal pins - including possible
signals from the VME backplane.
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12.
Registers
This appendix discusses the following topics:
12.1
•
“Overview” on page 163
•
“Register Map” on page 164
•
“Register Description” on page 171
Overview
The Universe II Control and Status Registers facilitate host system configuration and allow the user to
control Universe II operational characteristics. The registers are divided into three groups:
•
PCI Configuration Space
•
VMEbus Configuration and Status Registers
•
Universe II Device Specific Status Registers
Universe II registers have little-endian byte-ordering.
Figure 24 below summarizes the supported register access mechanisms.
Figure 24: UCSR Access Mechanisms
VMEbus Configuration
and Status Registers
(VCSR)
UNIVERSE DEVICE
SPECIFIC REGISTERS
(UDSR)
4 Kbytes
UCSR Space
PCI CONFIGURATION
SPACE
(PCICS)
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12. Registers > Register Map
Bits listed as reserved must be programmed with a value of 0. Reserved bits always read a value of
zero.
12.2
Register Map
Table 34 lists the Universe II registers by address offset.
Table 34: Universe II Register Map
Offset
Register
Name
0x000
“PCI Configuration Space ID Register (PCI_ID)” on page 171
0x004
“PCI Configuration Space Control and Status Register (PCI_CSR)” on
page 172
0x008
“PCI Configuration Class Register (PCI_CLASS)” on page 176
PCI_CLASS
0x00C
“PCI Configuration Miscellaneous 0 Register (PCI_MISC0)” on page 177
PCI_MISC0
0x010
“PCI Configuration Base Address Register (PCI_BS0)” on page 178
PCI_BS0
0x014
“PCI Configuration Base Address 1 Register (PCI_BS1)” on page 179
PCI_BS1
0x018-0x024
PCI_ID
PCI Unimplemented
0x028
PCI Reserved
0x02C
PCI Reserved
0x030
PCI Unimplemented
0x034
PCI Reserved
0x038
PCI Reserved
0x03C
“PCI Configuration Miscellaneous 1 Register (PCI_MISC1)” on page 180
0x040-0x0FF
PCI_CSR
PCI_MISC1
PCI Unimplemented
0x100
“PCI Target Image 0 Control (LSI0_CTL)” on page 181
LSI0_CTL
0x104
“PCI Target Image 0 Base Address Register (LSI0_BS)” on page 183
LSI0_BS
0x108
“PCI Target Image 0 Bound Address Register (LSI0_BD)” on page 184
LSI0_BD
0x10C
“PCI Target Image 0 Translation Offset (LSI0_TO)” on page 185
LSI0_TO
0x110
Reserved
0x114
“PCI Target Image 1 Control (LSI1_CTL)” on page 186
LSI1_CTL
0x118
“PCI Target Image 1 Base Address Register (LSI1_BS)” on page 188
LSI1_BS
0x11C
“PCI Target Image 1 Bound Address Register (LSI1_BD)” on page 189
LSI1_BD
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165
Table 34: Universe II Register Map (Continued)
Offset
Register
Name
0x120
“PCI Target Image 1 Translation Offset (LSI1_TO)” on page 190
0x124
Reserved
0x128
“PCI Target Image 2 Control (LSI2_CTL)” on page 191
LSI2_CTL
0x12C
“PCI Target Image 2 Base Address Register (LSI2_BS)” on page 193
LSI2_BS
0x130
“PCI Target Image 2 Bound Address Register (LSI2_BD)” on page 194
LSI2_BD
0x134
“PCI Target Image 2 Translation Offset (LSI2_TO)” on page 195
LSI2_TO
0x138
Reserved
0x13C
“PCI Target Image 3 Control (LSI3_CTL)” on page 196
LSI3_CTL
0x140
“PCI Target Image 3 Base Address Register (LSI3_BS)” on page 198
LSI3_BS
0x144
“PCI Target Image 3 Bound Address Register (LSI3_BD)” on page 199
LSI3_BD
0x148
“PCI Target Image 3 Translation Offset (LSI3_TO)” on page 200
LSI3_TO
0x14C-0x16C
LSI1_TO
Reserved
0x170
“Special Cycle Control Register (SCYC_CTL)” on page 201
0x174
“Special Cycle PCI Bus Address Register (SCYC_ADDR)” on page 202
0x178
“Special Cycle Swap/Compare Enable Register (SCYC_EN)” on
page 203
0x17C
“Special Cycle Compare Data Register (SCYC_CMP)” on page 204
SCYC_CMP
0x180
“Special Cycle Swap Data Register (SCYC_SWP)” on page 205
SCYC_SWP
0x184
“PCI Miscellaneous Register (LMISC)” on page 206
0x188
“Special PCI Target Image (SLSI)” on page 208
0x18C
“PCI Command Error Log Register (L_CMDERR)” on page 210
0x190
“PCI Address Error Log (LAERR)” on page 211
0x194-0x19C
SCYC_CTL
SCYC_ADDR
SCYC_EN
LMISC
SLSI
L_CMDERR
LAERR
Reserved
0x1A0
“PCI Target Image 4 Control Register (LSI4_CTL)” on page 212
LSI4_CTL
0x1A4
“PCI Target Image 4 Base Address Register (LSI4_BS)” on page 214
LSI4_BS
0x1A8
“PCI Target Image 4 Bound Address Register (LSI4_BD)” on page 215
LSI4_BD
0x1AC
“PCI Target Image 4 Translation Offset (LSI4_TO)” on page 216
LSI4_TO
0x1B0
Reserved
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12. Registers > Register Map
Table 34: Universe II Register Map (Continued)
Offset
Register
Name
0x1B4
“PCI Target Image 5 Control Register (LSI5_CTL)” on page 217
LSI5_CTL
0x1B8
“PCI Target Image 5 Base Address Register (LSI5_BS)” on page 219
LSI5_BS
0x1BC
“PCI Target Image 5 Bound Address Register (LSI5_BD)” on page 220
LSI5_BD
0x1C0
“PCI Target Image 5 Translation Offset (LSI5_TO)” on page 221
LSI5_TO
0x1C4
Reserved
0x1C8
“PCI Target Image 6 Control Register (LSI6_CTL)” on page 222
LSI6_CTL
0x1CC
“PCI Target Image 6 Base Address Register (LSI6_BS)” on page 224
LSI6_BS
0x1D0
“PCI Target Image 6 Bound Address Register (LSI6_BD)” on page 225
LSI6_BD
0x1D4
“PCI Target Image 6 Translation Offset (LSI6_TO)” on page 226
LSI6_TO
0x1D8
Reserved
0x1DC
“PCI Target Image 7 Control Register (LSI7_CTL)” on page 227
LSI7_CTL
0x1E0
“PCI Target Image 7 Base Address Register (LSI7_BS)” on page 229
LSI7_BS
0x1E4
“PCI Target Image 7 Bound Address Register (LSI7_BD)” on page 230
LSI7_BD
0x1E8
“PCI Target Image 7 Translation Offset (LSI7_TO)” on page 231
LSI7_TO
0x1EC-0x1FC
Reserved
0x200
“DMA Transfer Control Register (DCTL)” on page 232
DCTL
0x204
“DMA Transfer Byte Count Register (DTBC)” on page 234
DTBC
0x208
“DMA PCI Bus Address Register (DLA)” on page 235
0x20C
Reserved
0x210
“DMA VMEbus Address Register (DVA)” on page 236
0x214
Reserved
0x218
“DMA Command Packet Pointer (DCPP)” on page 237
0x21C
Reserved
0x220
“DMA General Control/Status Register (DGCS)” on page 238
0x224
“DMA Linked List Update Enable Register (D_LLUE)” on page 241
0x2280x-2FC
0x300
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DLA
DVA
DCPP
DGCS
D_LLUE
Reserved
“PCI Interrupt Enable Register (LINT_EN)” on page 242
LINT_EN
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167
Table 34: Universe II Register Map (Continued)
Offset
Register
Name
0x304
“PCI Interrupt Status Register (LINT_STAT)” on page 244
LINT_STAT
0x308
“PCI Interrupt Map 0 Register (LINT_MAP0)” on page 246
LINT_MAP0
0x30C
“PCI Interrupt Map 1 Register (LINT_MAP1)” on page 247
LINT_MAP1
0x310
“VMEbus Interrupt Enable Register (VINT_EN)” on page 248
0x314
“VMEbus Interrupt Status Register (VINT_STAT)” on page 251
VINT_STAT
0x318
“VME Interrupt Map 0 Register (VINT_MAP0)” on page 253
VINT_MAP0
0x31C
“VME Interrupt Map 1 Register (VINT_MAP1)” on page 254
VINT_MAP1
0x320
“Interrupt STATUS/ID Out Register (STATID)” on page 255
STATID
0x324
“VIRQ1 STATUS/ID Register (V1_STATID)” on page 256
V1_STATID
0x328
“VIRQ2 STATUS/ID Register (V2_STATID)” on page 257
V2_STATID
0x32C
“VIRQ3 STATUS/ID Register (V3_STATID)” on page 258
V3_STATID
0x330
“VIRQ4 STATUS/ID Register (V4_STATID)” on page 259
V4_STATID
0x334
“VIRQ5 STATUS/ID Register (V5_STATID)” on page 260
V5_STATID
0x338
“VIRQ6 STATUS/ID Register (V6_STATID)” on page 261
V6_STATID
0x33C
“VIRQ7 STATUS/ID Register (V7_STATID)” on page 262
V7_STATID
0x340
“PCI Interrupt Map 2 Register (LINT_MAP2)” on page 263
LINT_MAP2
0x344
“VME Interrupt Map 2 Register (VINT_MAP2)” on page 264
VINT_MAP2
0x348
“Mailbox 0 Register (MBOX0)” on page 265
MBOX0
0x34C
“Mailbox 1 Register (MBOX1)” on page 266
MBOX1
0x350
“Mailbox 2 Register (MBOX2)” on page 267
MBOX2
0x354
“Mailbox 3 Register (MBOX3)” on page 268
MBOX3
0x358
“Semaphore 0 Register (SEMA0)” on page 269
SEMA0
0x35C
“Semaphore 1 Register (SEMA1)” on page 270
SEMA1
0x360-0x3FC
VINT_EN
Reserved
0x400
“Master Control Register (MAST_CTL)” on page 271
MAST_CTL
0x404
“Miscellaneous Control Register (MISC_CTL)” on page 273
MISC_CTL
0x408
“Miscellaneous Status Register (MISC_STAT)” on page 275
MISC_STAT
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12. Registers > Register Map
Table 34: Universe II Register Map (Continued)
Offset
0x40C
0x410-0x4F8
0x4FC
0x500-0xEFC
Register
“User AM Codes Register (USER_AM)” on page 276
Name
USER_AM
Reserved
“Universe II Specific Register (U2SPEC)” on page 277
U2SPEC
Reserved
0xF00
“VMEbus Slave Image 0 Control Register (VSI0_CTL)” on page 279
VSI0_CTL
0xF04
“VMEbus Slave Image 0 Base Address Register (VSI0_BS)” on
page 282
VSI0_BS
0xF08
“VMEbus Slave Image 0 Bound Address Register (VSI0_BD)” on
page 283
VSI0_BD
0xF0C
“VMEbus Slave Image 0 Translation Offset (VSI0_TO)” on page 284
VSI0_TO
0xF10
Reserved
0xF14
“VMEbus Slave Image 1 Control (VSI1_CTL)” on page 285
VSI1_CTL
0xF18
“VMEbus Slave Image 1 Base Address Register (VSI1_BS)” on
page 287
VSI1_BS
0xF1C
“VMEbus Slave Image 1 Bound Address Register (VSI1_BD)” on
page 288
VSI1_BD
0xF20
“VMEbus Slave Image 1 Translation Offset (VSI1_TO)” on page 289
VSI1_TO
0xF24
Reserved
0xF28
“VMEbus Slave Image 2 Control (VSI2_CTL)” on page 290
VSI2_CTL
0xF2C
“VMEbus Slave Image 2 Base Address Register (VSI2_BS)” on
page 292
VSI2_BS
0xF30
“VMEbus Slave Image 2 Bound Address Register (VSI2_BD)” on
page 293
VSI2_BD
0xF34
“VMEbus Slave Image 2 Translation Offset (VSI2_TO)” on page 294
VSI2_TO
0xF38
Reserved
0xF3C
“VMEbus Slave Image 3 Control (VSI3_CTL)” on page 295
VSI3_CTL
0xF40
“VMEbus Slave Image 3 Base Address Register (VSI3_BS)” on
page 297
VSI3_BS
0xF44
“VMEbus Slave Image 3 Bound Address Register (VSI3_BD)” on
page 298
VSI3_BD
0xF48
“VMEbus Slave Image 3 Translation Offset (VSI3_TO)” on page 299
VSI3_TO
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169
Table 34: Universe II Register Map (Continued)
Offset
0xF4C-0xF60
Register
Name
Reserved
0xF64
“Location Monitor Control Register (LM_CTL)” on page 300
LM_CTL
0xF68
“Location Monitor Base Address Register (LM_BS)” on page 302
LM_BS
0xF6C
Reserved
0xF70
“VMEbus Register Access Image Control Register (VRAI_CTL)” on
page 303
VRAI_CTL
0xF74
“VMEbus Register Access Image Base Address Register (VRAI_BS)” on
page 304
VRAI_BS
0xF78-0xF7C
Reserved
0xF80
“VMEbus CSR Control Register (VCSR_CTL)” on page 305
VCSR_CTL
0xF84
“VMEbus CSR Translation Offset (VCSR_TO)” on page 306
VCSR_TO
0xF88
“VMEbus AM Code Error Log (V_AMERR)” on page 307
V_AMERR
0xF8C
“VMEbus Address Error Log (VAERR)” on page 308
0xF90
“VMEbus Slave Image 4 Control (VSI4_CTL)” on page 309r
VSI4_CTL
0xF94
“VMEbus Slave Image 4 Base Address Register (VSI4_BS)” on page 311
VSI4_BS
0xF98
“VMEbus Slave Image 4 Bound Address Register (VSI4_BD)” on
page 312
VSI4_BD
0xF9C
“VMEbus Slave Image 4 Translation Offset (VSI4_TO)” on page 313
VSI4_TO
0xFA0
Reserved
0xFA4
“VMEbus Slave Image 5 Control (VSI5_CTL)” on page 314
VSI5_CTL
0xFA8
“VMEbus Slave Image 5 Base Address Register (VSI5_BS)” on
page 316
VSI5_BS
0xFAC
“VMEbus Slave Image 5 Bound Address Register (VSI5_BD)” on
page 317
VSI5_BD
0xFB0
“VMEbus Slave Image 5 Translation Offset (VSI5_TO)” on page 318
VSI5_TO
0xFB4
Reserved
0xFB8
“VMEbus Slave Image 6 Control (VSI6_CTL)” on page 319
VSI6_CTL
0xFBC
“VMEbus Slave Image 6 Base Address Register (VSI6_BS)” on
page 321
VSI6_BS
0xFC0
“VMEbus Slave Image 6 Bound Address Register (VSI6_BD)” on
page 322
VSI6_BD
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�170
12. Registers > Register Map
Table 34: Universe II Register Map (Continued)
Offset
Register
Name
0xFC4
“VMEbus Slave Image 6 Translation Offset (VSI6_TO)” on page 323
0xFC8
Reserved
0xFCC
“VMEbus Slave Image 7 Control (VSI7_CTL)” on page 324
VSI7_CTL
0xFD0
“VMEbus Slave Image 7 Base Address Register (VSI7_BS)” on
page 326
VSI7_BS
0xFD4
“VMEbus Slave Image 7 Bound Address Register (VSI7_BD)” on
page 327
VSI7_BD
0xFD8
“VMEbus Slave Image 7 Translation Offset (VSI7_TO)” on page 328
VSI7_TO
0xFDC-0xFEC
VSI6_TO
Reserved
0xFF0
VME CR/CSR Reserved
0xFF4
“VMEbus CSR Bit Clear Register (VCSR_CLR)” on page 329
VCSR_CLR
0xFF8
“VMEbus CSR Bit Set Register (VCSR_SET)” on page 330
VCSR_SET
0xFFC
“VMEbus CSR Base Address Register (VCSR_BS)” on page 331
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�12. Registers > Register Description
12.3
171
Register Description
The following tables describe the Universe II registers.
12.3.1
PCI Configuration Space ID Register (PCI_ID)
Register name: PCI_VID
Bits
7
Register offset: 0x00
6
5
4
3
31:24
DID
23:16
DID
15:08
VID
07:00
VID
Bits
Name
31:16
DID[15:0]
Description
Device ID
2
1
0
Type
Reset by
Reset
value
R
all
0x10E3
R
all
0x10E3
IDT allocated device identifier
15:00
VID[15:0]
Vendor ID
PCI SIG allocated vendor identifier
Note: IDT acquired Tundra Semiconductor.
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12.3.2
12. Registers > Register Description
PCI Configuration Space Control and Status Register (PCI_CSR)
Register offset: 0x004
Register name: PCI_CSR
Bits
7
6
5
4
3
31:24
D_PE
S_SERR
R_MA
R_TA
S_TA
23:16
TFBBC
1
DEVSEL
PCI Reserved
WAIT
Bits
Name
31
D_PE
0
DP_D
PCI Reserved
15:08
07:00
2
PERESP
VGAPS
MWI_EN
SC
Description
Detected Parity Error
This bit is always set by the Universe II when the PCI
master interface detects a data parity error or the PCI
target interface detects address or data parity errors.
BM
MFBBC
SERR_EN
MS
IOS
Type
Reset by
Reset
value
R/Write 1
to Clear
All
0x0
R/Write 1
to Clear
All
0x0
R/Write 1
to Clear
All
0x0
R/Write 1
to Clear
All
0x0
R/Write 1
to Clear
All
0x0
0=No parity error
1=Parity error
30
S_SERR
Signalled SERR_
The Universe II PCI target interface sets this bit when
it asserts SERR_ to signal an address parity error.
SERR_EN must be set before SERR_ can be
asserted.
0=SERR_ not asserted
1=SERR_ asserted.
29
R_MA
Received Master-Abort
The Universe II PCI master interface sets this bit
when a transaction it initiated had to be terminated
with a Master-Abort.
0=Master did not generate Master-Abort
1=Master generated Master-Abort
28
R_TA
Received Target-Abort
The Universe II PCI master interface sets this bit
when a transaction it initiated was terminated with a
Target-Abort.
0=Master did not detect Target-Abort
1=Master detected Target-Abort.
27
S_TA
Signalled Target-Abort
0=Target did not terminate transaction with
Target-Abort
1=Target terminated transaction with Target-Abort.
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�12. Registers > Register Description
Bits
Name
26:25
DEVSEL
173
Type
Reset by
Reset
value
R
All
0x1
R/Write 1
to Clear
All
0x0
R
All
0x0
Reserved
R
All
0x0
Master Fast Back-to-Back Enable
R
All
0x0
R/W
All
0x0
R
All
0x0
R/W
All
0x0
Description
Device Select Timing
The Universe II is a medium speed device
24
DP_D
Master Data Parity Error
The Universe II PCI master interface sets this bit if
the Parity Error Response bit is set, if it is the master
of transaction in which it asserts PERR_, or the
addressed target asserts PERR_.
0=Master did not detect/generate data parity error,
1=Master detected/generated data parity error.
23
TFBBC
Target Fast Back to Back Capable
Universe II cannot accept Back to Back cycles from a
different agent.
22:10
Reserved
09
MFBBC
The Universe II master never generates fast back to
back transactions.
0=No fast back-to-back transactions
08
SERR_EN
SERR_ Enable
Setting this and PERESP allows the Universe II PCI
target interface to report address parity errors with
SERR_.
0=Disable SERR_ driver
1=Enable SERR_ driver
Note: The Universe II only refuses PCI addresses
with parity errors when both the PERESP and
SERR_EN bits are programmed to a value of 1.
07
WAIT
Wait Cycle Control
0=No address/data stepping
06
PERESP
Parity Error Response
Controls the Universe II response to data and
address parity errors. When enabled, it allows the
assertion of PERR_ to report data parity errors. When
this bit and SERR_EN are asserted, the Universe II
can report address parity errors on SERR_. Universe
II parity generation is unaffected by this bit.
0=Disable
1=Enable
Note: The Universe II only refuses PCI addresses
with parity errors when both the PERESP and
SERR_EN bits are programmed to a value of 1.
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12. Registers > Register Description
Bits
Name
05
VGAPS
Description
VGA Palette Snoop
Type
Reset by
Reset
value
R
All
0x0
R
All
0x0
R
All
0x0
R/W
PWR VME
This bit is 1
after reset
if the
VMEbus
Address
[14] equals
1 during
power-on
reset.
The Universe II treats palette accesses like all other
accesses.
0=Disable
04
MWI_EN
Memory Write and Invalidate Enable
The Universe II PCI master interface never generates
a Memory Write and Invalidate command.
0=Disable
03
SC
Special Cycles
0=Disable
The Universe II PCI target interface never responds
to special cycles.
02
BM
Master Enable
0=Disable
1=Enable
For a VMEbus slave image to respond to an incoming
cycle, this bit must be set. If this bit is cleared while
there is data in the VMEbus Slave Posted Write
FIFO, the data will be written to the PCI bus but no
further data will be accepted into this FIFO until the
bit is set.
01
MS
Target Memory Enable
0=Disable
1=Enable
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This bit is
reloaded
by “all”.
R/W
PWR VME
This bit is 1
after reset
if the
VMEbus
Address
[13:12]
equals 10
during
power-on
reset. This
bit is
reloaded
by “all”
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�12. Registers > Register Description
Bits
Name
00
IOS
Description
Target IO Enable
0=Disable
1=Enable
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Type
Reset by
R/W
PWR VME
Reset
value
This bit is 1
after reset
if the
VMEbus
Address
[13:12]
equals 10
during
power-on
reset. This
bit is
reloaded
by “all”
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�176
12.3.3
12. Registers > Register Description
PCI Configuration Class Register (PCI_CLASS)
Register name: PCI_CLASS
Bits
7
Register offset: 0x08
6
5
4
3
31:24
BASE
23:16
SUB
15:08
PROG
07:00
RID
Bits
Name
31:24
BASE [7:0]
Description
Base Class Code
2
1
0
Type
Reset by
Reset
value
R
All
0x06
R
All
0x80
R
All
0x00
R
All
0x02
The Universe II is defined as a PCI bridge device
23:16
SUB [7:0]
Sub Class Code
The Universe II sub-class is “other bridge device”
15:08
PROG [7:0]
Programming Interface
The Universe II does not have a standardized
register-level programming interface
07:00
RID [7:0]
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12.3.4
177
PCI Configuration Miscellaneous 0 Register (PCI_MISC0)
The Universe II is not a multi-function device.
Register name: PCI_MISC0
Register offset: 0x0C
Bits
7
6
31:24
BISTC
SBIST
23:16
MFUNCT
5
4
3
2
1
Reserved
0
CCODE
LAYOUT
15:08
LTIMER
Reserved
07:00
Reserved
Bits
Name
31
BISTC
30
SBIST
Type
Reset by
Reset
value
The Universe II is not BIST Capable
R
All
0x0
Start BIST
R
All
0x0
Reserved
R
All
0x0
Completion Code
R
All
0x0
R
All
0x0
R
All
0x0
R/W
All
0x0
R
All
0x0
Description
The Universe II is not BIST capable
29:28
Reserved
27:24
CCODE
The Universe II is not BIST capable
23
MFUNCT
Multifunction Device
The Universe II is not a multi-function device.
0=No
1=Yes
22:16
LAYOUT
Configuration Space Layout
15:11
LTIMER
Latency Timer
The latency timer has a resolution of eight clocks.
When the Universe II latency timer is programmed for
eight clock periods and FRAME_, IRDY_ and TRDY_
are asserted while GNT_ is not asserted, FRAME_ is
negated on the next clock edge.
10:00
Reserved
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Reserved
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12.3.5
12. Registers > Register Description
PCI Configuration Base Address Register (PCI_BS0)
This register specifies the 4 Kbyte aligned base address of the 4 Kbyte Universe II register space on
PCI.
Register name: PCI_BS0
Bits
7
Register offset: 0x10
6
5
4
3
31:24
BS
23:16
BS
15:08
2
1
BS
0
Reserved
07:00
Reserved
SPACE
Type
Reset by
Reset
value
R/W
All
0x00
Reserved
R
All
0x00
PCI Bus Address Space
R
All
Undefined
Bits
Name
Description
31:12
BS[31:12]
Base Address
11:02
Reserved
00
SPACE
0=Memory
1=I/O
A power-up option determines if the registers are mapped into Memory or I/O space in relation to this
base address (see “Power-Up Options” on page 135). If mapped into Memory space, the user is free to
locate the registers anywhere in the 32-bit address space. If PCI_BS0 is mapped to Memory space,
PCI_BS1 is mapped to I/O space; if PCI_BS0 is mapped to I/O space, then PCI_BS1 is mapped to
Memory space.
•
When the VA[1] pin is sampled low at power-up, the PCI_BS0 register’s SPACE bit is set to 1,
which signifies I/O space, and the PCI_BS1 register’s SPACE bit is set to 0, which signifies
memory space.
•
When VA[1] is sampled high at power-up, the PCI_BS0 register’s SPACE register’s bit is set to 0,
which signifies Memory space, and the PCI_BS1 register’s SPACE bit is set to 1, which signifies
I/O space.
A write must occur to this register before the Universe II Device Specific Registers can be accessed.
This write can be performed with a PCI configuration transaction or a VMEbus register access.
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�12. Registers > Register Description
12.3.6
179
PCI Configuration Base Address 1 Register (PCI_BS1)
This register specifies the 4 KByte aligned base address of the 4 KByte Universe II register space in
PCI
Register name: PCI_BS1
Bits
7
Register offset: 0x14
6
5
4
3
31:24
BS
23:16
BS
15:08
2
1
BS
0
Reserved
07:00
Reserved
SPACE
Type
Reset by
Reset
value
R/W
All
0x00
Reserved
R
All
0x00
PCI Bus Address Space
R
All
Undefined
Bits
Name
Description
31:12
BS[31:12]
Base Address
11:02
Reserved
00
SPACE
0=Memory
1=I/O
A power-up option determines the value of the SPACE bit. This determines whether the registers are
mapped into Memory or I/O space in relation to this base address (see “Power-Up Options” on
page 135). If mapped into Memory space, the user is free to locate the Universe registers anywhere in
the 32-bit address space. If PCI_BS0 is mapped to Memory space, PCI_BS1 is mapped to I/O space; if
PCI_BS0 is mapped to I/O space, then PCI_BS1 is mapped to Memory space.
•
When the VA[1] pin is sampled low at power-up, the PCI_BS0 register’s SPACE bit is set to “1”,
which signifies I/O space, and the PCI_BS1 register’s SPACE bit is set to “0”, which signifies
memory space.
•
When VA[1] is sampled high at power-up, the PCI_BS0 register’s SPACE register’s bit is set to
“0”, which signifies Memory space, and the PCI_BS1 register’s SPACE bit is set to “1”, which
signifies I/O space.
A write must occur to this register before the Universe II Device Specific Registers can be accessed.
This write can be performed with a PCI configuration transaction or a VMEbus register access.
The SPACE bit in this register is an inversion of the SPACE field in PCI_BS0.
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12.3.7
12. Registers > Register Description
PCI Configuration Miscellaneous 1 Register (PCI_MISC1)
Register name: PCI_MISC1
Bits
7
Register offset: 0x3C
6
5
4
3
31:24
MAX_LAT [7:0]
23:16
MIN_GNT [7:0]
15:08
INT_PIN [7:0]
07:00
INT_LINE [7:0]
Bits
Name
31:24
MAX_LAT [7:0]
23:16
MIN_GNT [7:0]
2
1
0
Type
Reset by
Reset
value
Maximum Latency: This device has no special
latency requirements
R
All
0x00
Minimum Grant
R
All
0b11
R
All
0b01
R/W
All
0x00
Description
250 ns increments
The MIN_GNT parameter assumes the Universe II
master is transferring an aligned burst size of 64
bytes to a 32-bit target with no wait states. This would
require roughly 20 clocks (at a clock frequency of 33
MHz, this is about 600 ns). MIN_GNT is set to three,
or 750 ns.
15:08
INT_PIN [7:0]
Interrupt Pin
Universe II pin INT_ [0] has a PCI compliant I/O
buffer
07:00
INT_LINE [7:0]
Interrupt Line
Used by some PCI systems to record interrupt
routing information
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�12. Registers > Register Description
12.3.8
181
PCI Target Image 0 Control (LSI0_CTL)
In the PCI Target Image Control register, setting the VCT bit will only have effect if the VAS bits are
programmed for A24 or A32 space and the VDW bits are programmed for 8-bit, 16-bit, or 32-bit.
If VAS bits are programmed to A24 or A32 and the VDW bits are programmed for 64-bit, the Universe
II may perform MBLT transfers independent of the state of the VCT bit.
The setting of the PWEN bit is ignored if the LAS bit is programmed for PCI Bus I/O Space, forcing all
transactions through this image to be coupled.
Register name: LSI0_CTL
Register offset: 0x100
Bits
7
6
31:24
EN
PWEN
23:16
15:08
5
4
2
1
Reserved
PGM
Reserved
07:00
SUPER
VAS
Reserved
VCT
Reserved
Bits
Name
31
EN
0
Reserved
VDW
Reserved
3
Description
Image Enable
LAS
Type
Reset by
Reset
value
R/W
All
Undefined
R/W
All
0x00
R
All
0x00
R/W
All
0b10
R
All
0x00
0=Disable
1=Enable
30
PWEN
Posted Write Enable
0=Disable
1=Enable
29:24
Reserved
23:22
VDW
Reserved
VMEbus Maximum Data width
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
21:19
Reserved
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�182
12. Registers > Register Description
Bits
Name
18:16
VAS
Description
VMEbus Address Space
Type
Reset by
Reset
value
R/W
All
Undefined
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
Undefined
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=CR/CSR
110=User1
111=User2
15
Reserved
14
PGM
Reserved
Program/Data AM Code
0=Data
1=Program
13
Reserved
12
SUPER
Reserved
Supervisor/User AM Code
0=Non-Privileged
1=Supervisor
11:09
Reserved
08
VCT
Reserved
VMEbus Cycle Type
0=No BLTs on VMEbus
1=Single BLTs on VMEbus
07:01
Reserved
00
LAS
Reserved
PCI Bus Memory Space
0=PCI Bus Memory Space
1=PCI Bus I/O Space
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12.3.9
183
PCI Target Image 0 Base Address Register (LSI0_BS)
The base address specifies the lowest address in the address range that will be decoded.
The base address for PCI Target Image 0 and PCI Target Image 4 have a 4 Kbyte resolution. PCI Target
Images 1, 2, 3, 5, 6, and 7 have a 64 Kbyte resolution.
Register name: LSI0_BS
Bits
7
Register offset: 0x104
6
5
4
3
31:24
BS
23:16
BS
15:08
2
1
BS
0
Reserved
07:00
Reserved
Type
Reset by
Reset
value
Base Address
R/W
All
Undefined
BS[27:12]
Base Address
R/W
All
0x00
Reserved
Reserved
R
All
0x00
Bits
Name
31:28
BS[31:28]
27:12
11:00
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12.3.10
12. Registers > Register Description
PCI Target Image 0 Bound Address Register (LSI0_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound address is 0, then the addresses decoded are those greater
than or equal to the base address.
The bound address for PCI Target Image 0 and PCI Target Image 4 have a 4Kbyte resolution. PCI
Target Images 1, 2, 3, 5, 6, and 7 have a 64Kbyte resolution.
Register name: LSI0_BD
Bits
7
Register offset: 0x108
6
5
4
3
31:24
BD
23:16
BD
15:08
2
1
BD
0
Reserved
07:00
Reserved
Type
Reset by
Reset
value
Bound Address
R/W
All
Undefined
BD[27:12]
Bound Address
R/W
All
0x00
Reserved
Reserved
R
All
0x00
Bits
Name
31:28
BD[31:28]
27:12
11:00
Universe II User Manual
May 12, 2010
Description
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
12.3.11
185
PCI Target Image 0 Translation Offset (LSI0_TO)
The translation offset for PCI Target Image 0 and PCI Target Image 4 have a 4Kbyte resolution. PCI
Target Images 1, 2, 3, 5, 6, and 7 have a 64Kbyte resolution.
Address bits [31:12] generated on the VMEbus in response to an image decode are a two’s complement
addition of address bits [31:12] on the PCI Bus and bits [31:12] of the image’s translation offset.
Register name: LSI0_TO
Bits
7
Register offset: 0x10C
6
5
4
3
31:24
TO
23:16
TO
15:08
2
1
TO
0
Reserved
07:00
Reserved
Bits
Name
31:12
TO[31:12]
Translation Offset
11:00
Reserved
Reserved
Integrated Device Technology
www.idt.com
Description
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Universe II User Manual
May 12, 2010
�186
12.3.12
12. Registers > Register Description
PCI Target Image 1 Control (LSI1_CTL)
In the PCI Target Image Control register, setting the VCT bit will only have effect if the VAS bits are
programmed for A24 or A32 space and the VDW bits are programmed for 8-bit, 16-bit, or 32-bit.
If VAS bits are programmed to A24 or A32 and the VDW bits are programmed for 64-bit, the Universe
II may perform MBLT transfers independent of the state of the VCT bit.
The setting of the PWEN bit is ignored if the LAS bit is programmed for PCI Bus I/O Space, forcing all
transactions through this image to be coupled.
Register name: LSI1_CTL
Register offset: 0x114
Bits
7
6
31:24
EN
PWEN
23:16
15:08
5
4
2
1
Reserved
PGM
Reserved
07:00
SUPER
VAS
Reserved
VCT
Reserved
Bits
Name
31
EN
0
Reserved
VDW
Reserved
3
Description
Image Enable
LAS
Type
Reset by
Reset
value
R/W
All
Undefined
R/W
All
0x00
R
All
0x00
R/W
All
0b10
R
All
0x00
0=Disable
1=Enable
30
PWEN
Posted Write Enable
0=Disable
1=Enable
29:24
Reserved
23:22
VDW
Reserved
VMEbus Maximum Data width
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
21:19
Reserved
Universe II User Manual
May 12, 2010
Reserved
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
Bits
Name
18:16
VAS
187
Description
VMEbus Address Space
Type
Reset by
Reset
value
R/W
All
Undefined
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
Undefined
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=CR/CSR
110=User1
111=User2
15
Reserved
14
PGM
Reserved
Program/Data AM Code
0=Data
1=Program
13
Reserved
12
SUPER
Reserved
Supervisor/User AM Code
0=Non-Privileged
1=Supervisor
11:09
Reserved
08
VCT
Reserved
VMEbus Cycle Type
0=No BLTs on VMEbus
1=Single BLTs on VMEbus
07:01
Reserved
00
LAS
Reserved
PCI Bus Memory Space
0=PCI Bus Memory Space
1=PCI Bus I/O Space
Integrated Device Technology
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Universe II User Manual
May 12, 2010
�188
12.3.13
12. Registers > Register Description
PCI Target Image 1 Base Address Register (LSI1_BS)
The base address specifies the lowest address in the address range that will be decoded.
Register name: LSI1_BS
Bits
7
Register offset: 0x118
6
5
4
3
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
BS[31:16]
Base Address
15:00
Reserved
Reserved
Universe II User Manual
May 12, 2010
Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Integrated Device Technology
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�12. Registers > Register Description
12.3.14
189
PCI Target Image 1 Bound Address Register (LSI1_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound address is 0, then the addresses decoded are those greater
than or equal to the base address.
The bound address for PCI Target Image 0 and PCI Target Image 4 have a 4Kbyte resolution. PCI
Target Images 1, 2, 3, 5, 6, and 7 have a 64Kbyte resolution.
Register name: LSI1_BD
Bits
7
Register offset: 0x11C
6
5
4
3
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
BD[31:16]
Bound Address
15:00
Reserved
Reserved
Integrated Device Technology
www.idt.com
Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Universe II User Manual
May 12, 2010
�190
12.3.15
12. Registers > Register Description
PCI Target Image 1 Translation Offset (LSI1_TO)
Address bits [31:16] generated on the VMEbus in response to an image decode are a two’s complement
addition of address bits [31:16] on the PCI Bus and bits [31:16] of the image’s translation offset.
Register name: LSI1_TO
Bits
7
Register offset: 0x120
6
5
4
3
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
TO[31:16]
Translation Offset
15:00
Reserved
Reserved
Universe II User Manual
May 12, 2010
Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
12.3.16
191
PCI Target Image 2 Control (LSI2_CTL)
In the PCI Target Image Control register, setting the VCT bit will only have effect if the VAS bits are
programmed for A24 or A32 space and the VDW bits are programmed for 8-bit, 16-bit, or 32-bit.
If VAS bits are programmed to A24 or A32 and the VDW bits are programmed for 64-bit, the Universe
II may perform MBLT transfers independent of the state of the VCT bit.
The setting of the PWEN bit is ignored if the LAS bit is programmed for PCI Bus I/O Space, forcing all
transactions through this image to be coupled.
Register name: LSI2_CTL
Register offset: 0x13C
Bits
7
6
31:24
EN
PWEN
23:16
15:08
5
4
2
1
Reserved
PGM
Reserved
07:00
SUPER
VAS
Reserved
VCT
Reserved
Bits
Name
31
EN
0
Reserved
VDW
Reserved
3
Description
Image Enable
LAS
Type
Reset by
Reset
value
R/W
All
Undefined
R/W
All
0x00
R
All
0x00
R/W
All
0b10
R
All
0x00
0=Disable
1=Enable
30
PWEN
Posted Write Enable
0=Disable
1=Enable
29:24
Reserved
23:22
VDW
Reserved
VMEbus Maximum Data width
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
21:19
Reserved
Integrated Device Technology
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Reserved
Universe II User Manual
May 12, 2010
�192
12. Registers > Register Description
Bits
Name
18:16
VAS
Description
VMEbus Address Space
Type
Reset by
Reset
value
R/W
All
Undefined
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
Undefined
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=CR/CSR
110=User1
111=User2
15
Reserved
14
PGM
Reserved
Program/Data AM Code
0=Data
1=Program
13
Reserved
12
SUPER
Reserved
Supervisor/User AM Code
0=Non-Privileged
1=Supervisor
11:09
Reserved
08
VCT
Reserved
VMEbus Cycle Type
0=No BLTs on VMEbus
1=Single BLTs on VMEbus
07:01
Reserved
00
LAS
Reserved
PCI Bus Memory Space
0=PCI Bus Memory Space
1=PCI Bus I/O Space
Universe II User Manual
May 12, 2010
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
12.3.17
193
PCI Target Image 2 Base Address Register (LSI2_BS)
The base address specifies the lowest address in the address range that will be decoded.
Register name: LSI12_BS
Bits
7
Register offset: 0x12C
6
5
4
3
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
BS[31:16]
Base Address
15:00
Reserved
Reserved
Integrated Device Technology
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Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Universe II User Manual
May 12, 2010
�194
12.3.18
12. Registers > Register Description
PCI Target Image 2 Bound Address Register (LSI2_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound address is 0, then the addresses decoded are those greater
than or equal to the base address.
Register name: LSI2_BD
Bits
7
Register offset: 0x130
6
5
4
3
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
BD[31:16]
Bound Address
15:00
Reserved
Reserved
Universe II User Manual
May 12, 2010
Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
12.3.19
195
PCI Target Image 2 Translation Offset (LSI2_TO)
Address bits [31:16] generated on the VMEbus in response to an image decode are a two’s complement
addition of address bits [31:16] on the PCI Bus and bits [31:16] of the image’s translation offset.
Register name: LSI2_TO
Bits
7
Register offset: 0x134
6
5
4
3
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
TO[31:16]
Translation Offset
15:00
Reserved
Reserved
Integrated Device Technology
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Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Universe II User Manual
May 12, 2010
�196
12.3.20
12. Registers > Register Description
PCI Target Image 3 Control (LSI3_CTL)
In the PCI Target Image Control register, setting the VCT bit will only have effect if the VAS bits are
programmed for A24 or A32 space and the VDW bits are programmed for 8-bit, 16-bit, or 32-bit.
If VAS bits are programmed to A24 or A32 and the VDW bits are programmed for 64-bit, the Universe
II may perform MBLT transfers independent of the state of the VCT bit.
The setting of the PWEN bit is ignored if the LAS bit is programmed for PCI Bus I/O Space, forcing all
transactions through this image to be coupled.
Register name: LSI3_CTL
Register offset: 0x13C
Bits
7
6
31:24
EN
PWEN
23:16
15:08
5
4
2
1
Reserved
PGM
Reserved
07:00
SUPER
VAS
Reserved
VCT
Reserved
Bits
Name
31
EN
0
Reserved
VDW
Reserved
3
Description
Image Enable
LAS
Type
Reset by
Reset
value
R/W
All
Undefined
R/W
All
0x00
R
All
0x00
R/W
All
10
R
All
0x00
0=Disable
1=Enable
30
PWEN
Posted Write Enable
0=Disable
1=Enable
29:24
Reserved
23:22
VDW
Reserved
VMEbus Maximum Data width
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
21:19
Reserved
Universe II User Manual
May 12, 2010
Reserved
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
Bits
Name
18:16
VAS
197
Description
VMEbus Address Space
Type
Reset by
Reset
value
R/W
All
Undefined
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
0x00
R
All
0x00
R/W
All
Undefined
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=CR/CSR
110=User1
111=User2
15
Reserved
14
PGM
Reserved
Program/Data AM Code
0=Data
1=Program
13
Reserved
12
SUPER
Reserved
Supervisor/User AM Code
0=Non-Privileged
1=Supervisor
11:09
Reserved
08
VCT
Reserved
VMEbus Cycle Type
0=No BLTs on VMEbus
1=Single BLTs on VMEbus
07:01
Reserved
00
LAS
Reserved
PCI Bus Memory Space
0=PCI Bus Memory Space
1=PCI Bus I/O Space
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Universe II User Manual
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�198
12.3.21
12. Registers > Register Description
PCI Target Image 3 Base Address Register (LSI3_BS)
The base address specifies the lowest address in the address range that will be decoded.
Register name: LSI3_BS
Bits
7
Register offset: 0x140
6
5
4
3
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
BS[31:16]
Base Address
15:00
Reserved
Reserved
Universe II User Manual
May 12, 2010
Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
12.3.22
199
PCI Target Image 3 Bound Address Register (LSI3_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound address is 0, then the addresses decoded are those greater
than or equal to the base address.
Register name: LSI3_BD
Bits
7
Register offset: 0x144
6
5
4
3
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
BD[31:16]
Bound Address
15:00
Reserved
Reserved
Integrated Device Technology
www.idt.com
Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Universe II User Manual
May 12, 2010
�200
12.3.23
12. Registers > Register Description
PCI Target Image 3 Translation Offset (LSI3_TO)
Address bits [31:16] generated on the VMEbus in response to an image decode are a two’s complement
addition of address bits [31:16] on the PCI Bus and bits [31:16] of the image’s translation offset.
Register name: LSI3_TO
Bits
7
Register offset: 0x148
6
5
4
3
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Bits
Name
31:16
TO[31:16]
Translation Offset
15:00
Reserved
Reserved
Universe II User Manual
May 12, 2010
Description
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
12.3.24
201
Special Cycle Control Register (SCYC_CTL)
The special cycle generator generates an ADOH or RMW cycle for the 32-bit PCI Bus address which
matches the programmed address in SCYC_ADDR, in the address space specified in the LAS field of
the SCYC_CTL register. A Read-Modify-Write command is initiated by a read to the specified
address. Address-Only cycles are initiated by either read or write cycles.
Register Name: SCYC_CTL
Bits
7
Register offset: 0x170
6
5
4
3
31:24
Reserved
23:16
Reserved
15:08
Reserved
07:00
Reserved
Bits
Name
31:03
Reserved
02
LAS
Description
Reserved
PCI Bus Address Space
2
1
LAS
0
SCYC
Type
Reset by
Reset
value
R
All
0x00
R/W
All
0x00
R/W
All
0x00
0=PCI Bus Memory Space
1=PCI Bus I/O Space
For a RMW cycle only
01:00
SCYC
Special Cycle
00=Disable
01=RMW
10=ADOH
11=Reserved
Integrated Device Technology
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Universe II User Manual
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�202
12.3.25
12. Registers > Register Description
Special Cycle PCI Bus Address Register (SCYC_ADDR)
This register designates the special cycle address. This address must appear on the PCI Bus during the
address phase of a transfer for the Special Cycle Generator to perform its function. Whenever the
addresses match, the Universe II does not respond with ACK64_.
Register name: SCYC_ADDR
Bits
7
6
Register offset: 0x174
5
4
3
31:24
ADDR
23:16
ADDR
15:08
ADDR
07:00
2
1
ADDR
Bits
Name
31:02
ADDR
01:00
Reserved
Universe II User Manual
May 12, 2010
0
Reserved
Type
Reset by
Reset
value
Address
R/W
All
0x00
Reserved
R/W
All
0x00
Description
Integrated Device Technology
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�12. Registers > Register Description
12.3.26
203
Special Cycle Swap/Compare Enable Register (SCYC_EN)
The bits enabled in this register determine the bits that are involved in the compare and swap
operations for VME RMW cycles.
Register name: SCYC_EN
Bits
7
Register offset: 0x178
6
5
4
3
31:24
EN
23:16
EN
15:08
EN
07:00
EN
Bits
Name
31:00
EN
Description
Bit Enable
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
0=Disable
1=Enable
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Universe II User Manual
May 12, 2010
�204
12.3.27
12. Registers > Register Description
Special Cycle Compare Data Register (SCYC_CMP)
The data returned from the read portion of a VMEbus RMW is compared with the contents of this
register. SCYC_EN is used to control which bits are compared.
Register name: SCYC_CMP
Bits
7
Register offset: 0x17C
6
5
4
3
31:24
CMP
23:16
CMP
15:08
CMP
07:00
CMP
2
1
0
Bits
Name
Description
Type
Reset by
Reset
value
31:00
CMP
The data returned from the VMEbus is compared with
the contents of this register.
R/W
All
0x00
Universe II User Manual
May 12, 2010
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�12. Registers > Register Description
12.3.28
205
Special Cycle Swap Data Register (SCYC_SWP)
If enabled bits matched with the value in the compare register, then the contents of the swap data
register is written back to VME. SCYC_EN is used to control which bits are written back to VME.
Register name: SCYC_SWP
Bits
7
Register offset: 0x180
6
5
4
3
31:24
SWP
23:16
SWP
15:08
SWP
07:00
SWP
Bits
Name
31:00
SWP
Integrated Device Technology
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Description
Swap data
2
1
0
Type
Reset by
Reset
value
R/W
All
0x00
Universe II User Manual
May 12, 2010
�206
12. Registers > Register Description
12.3.29
PCI Miscellaneous Register (LMISC)
This register can only be set at configuration or after disabling all PCI Target Images.
Register name: LMISC
Bits
7
Register offset: 0x184
6
31:24
5
4
3
CRT[3:0]
Reserved
15:08
Reserved
07:00
Reserved
CRT[3:0]
1
Reserved
23:16
Name
2
Description
CRT
0
CWT
Type
Reset By
Reset State
R/W
all
000
R/W
all
000
This field is provided for backward compatibility with the
Universe I. It has no effect on the operation of the Universe II.
CWT [2:0]
Coupled Window Timer
000=Disable - release after first coupled transaction
001=16 PCI Clocks
010=32 PCI Clocks
011=64 PCI Clocks
100=128 PCI Clocks
101=256 PCI Clocks
110=512 PCI Clocks
others= Reserved
Bits
Name
Description
Type
Reset by
Reset
value
31:28
CRT
This field is provided for backward compatibility with
the Universe I. It has no effect on the operation of the
Universe II.
R/W
All
0x00
27
Reserved
R
All
0x00
Universe II User Manual
May 12, 2010
Reserved
Integrated Device Technology
www.idt.com
�12. Registers > Register Description
Bits
Name
26:24
CWT
207
Description
Coupled Window Timer
Type
Reset by
Reset
value
R/W
All
0x00
R
All
0x00
000=Disable - release after first coupled transaction
001=16 PCI Clocks
010=32 PCI Clocks
011=64 PCI Clocks
100=128 PCI Clocks
101=256 PCI Clocks
110=512 PCI Clocks
others= Reserved
23:00
Reserved
Reserved
The Universe II uses CWT to determine how long to hold ownership of the VMEbus after processing a
coupled transaction. The timer is restarted each time the Universe II processes a coupled transaction. If
this timer expires, the PCI Slave Channel releases the VMEbus.
Device behavior is unpredictable if CWT is changed during coupled cycle
activity.
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Universe II User Manual
May 12, 2010
�208
12. Registers > Register Description
12.3.30
Special PCI Target Image (SLSI)
This register fully specifies an A32 capable special PCI Target Image. The base is programmable to a
64 Mbyte alignment, and the size is fixed at 64 Mbytes. Incoming address lines [31:26] (in Memory or
I/O) must match this field for the Universe II to decode the access. This special PCI Target Image has
lower priority than any other PCI Target Image.
The 64 Mbytes of the SLSI is partitioned into four 16 Mbyte regions, numbered 0 to 3 (0 is at the
lowest address). PCI address bits [25:24] are used to select regions. The top 64 Kbyte of each region is
mapped to VMEbus A16 space, and the rest of each 16 Mbyte region is mapped to A24 space.
The user can use the PGM, SUPER, and VDW fields to specify the AM code and the maximum port
size for each region. The PGM field is ignored for the portion of each region mapped to A16 space.
No block transfer AM codes are generated.
Register name: SLSI
Register offset: 0x188
Bits
7
6
31:24
EN
PWN
5
4
3
2
1
0
Reserved
LAS
Reserved
23:16
VDW
Reserved
15:08
PGM
SUPER
07:00
BS
Name
EN
Description
Image Enable
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
VDW
VMEbus Maximum Datawidth
Each of the four bits specifies a data width for the
corresponding 16 MByte region. Low order bits correspond to
the lower address regions.
0=16-bit
1=32-bit
Universe II User Manual
May 12, 2010
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�12. Registers > Register Description
Name
PGM
209
Description
Program/Data AM Code
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
Each of the four bits specifies Program/Data AM code for the
corresponding 16 MByte region. Low order bits correspond to
the lower address regions.
0=Data
1=Program
SUPER
Supervisor/User AM Code
Each of the four bits specifies Supervisor/User AM code for
the corresponding 16 MByte region. Low order bits
correspond to the lower address regions.
0=Non-Privileged
1=Supervisor
BS
Base Address
Specifies a 64 MByte aligned base address for this 64 MByte
image.
LAS
PCI Bus Address Space
0=PCI Bus Memory Space
1=PCI Bus I/O Space
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12. Registers > Register Description
12.3.31
PCI Command Error Log Register (L_CMDERR)
The Universe II PCI Master Interface is responsible for logging errors under the following conditions:
•
Posted write transaction results in a target abort,
•
Posted write transaction results in a master abort, or
•
Maximum retry counter expires during retry of posted write transaction.
This register logs the command information.
Register name: L_CMDERR
Bits
7
Register offset: 0x18C
6
31:24
23:16
5
4
CMDERR
L_STAT
3
M_ERR
Reserved
07:00
Reserved
CMDERR
M_ERR
1
0
Reserved
Reserved
15:08
Name
2
Description
Type
Reset by
Reset value
PCI Command Error Log
R
All
0111
Multiple Error Occurred
R
All
0
R/W
All
0
0=Single error
1=At least one error has occurred since the logs were frozen.
L_STAT
PCI Error Log Status
Reads:
0=logs invalid
1=logs are valid and error logging halted
Writes:
0=no effect
1=clears L_STAT and enables error logging
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�12. Registers > Register Description
12.3.32
211
PCI Address Error Log (LAERR)
The starting address of an errored PCI transaction is logged in this register under the following
conditions:
•
a posted write transaction results in a target abort,
•
a posted write transaction results in a master abort, or
•
a maximum retry counter expires during retry of posted write transaction.
Contents are qualified by bit L_STAT of the L_CMDERR register.
Register name: LAERR
Bits
7
Register offset: 0x190
6
5
4
3
31:24
LAERR
23:16
LAERR
15:08
LAERR
07:00
1
LAERR
Name
LAERR
2
Description
PCI Address Error Log
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0
Reserved
Type
Reset by
Reset value
R
All
0
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�212
12. Registers > Register Description
12.3.33
PCI Target Image 4 Control Register (LSI4_CTL)
In the PCI Target Image Control register, setting the VCT bit will only have effect if the VAS bits are
programmed for A24 or A32 space and the VDW bits are programmed for 8-bit, 16-bit, or 32-bit.
If VAS bits are programmed to A24 or A32 and the VDW bits are programmed for 64-bit, the Universe
II may perform MBLT transfers independent of the state of the VCT bit.
The setting of the PWEN bit is ignored if the LAS bit is programmed for PCI Bus I/O Space, forcing all
transactions through this image to be coupled.
Register name: LSI4_CTL
Register offset: 0x1A0
Bits
7
6
31:24
EN
PWEN
23:16
15:08
5
2
Reserved
PGM
Reserved
07:00
1
0
SUPER
VAS
Reserved
VCT
Reserved
Name
EN
3
Reserved
VDW
Reserved
4
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
10
R/W
All
0
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
VDW
VMEbus Maximum Datawidth
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
VAS
VMEbus Address Space
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=CR/CSR
110=User1
111=User2
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�12. Registers > Register Description
Name
PGM
213
Description
Program/Data AM Code
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
0=Data
1=Program
SUPER
Supervisor/User AM Code
0=Non-Privileged
1=Supervisor
VCT
VMEbus Cycle Type
0=no BLTs on VMEbus
1=BLTs on VMEbus
LAS
PCI Bus Memory Space
0=PCI Bus Memory Space
1=PCI Bus I/O Space
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12. Registers > Register Description
12.3.34
PCI Target Image 4 Base Address Register (LSI4_BS)
The base address specifies the lowest address in the address range that will be decoded.
Register name: LSI4_BS
Bits
7
Register offset: 0x1A4
6
5
4
3
31:24
BS
23:16
BS
15:08
BS
1
0
Reserved
07:00
Reserved
Name
BS
2
Description
Base Address
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Type
Reset by
Reset value
R/W
All
0
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�12. Registers > Register Description
12.3.35
215
PCI Target Image 4 Bound Address Register (LSI4_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound address is 0, then the addresses decoded are those greater
than or equal to the base address.
The bound address for PCI Target Image 0 and PCI Target Image 4 have a 4Kbyte resolution. PCI
Target Images 1, 2, 3, 5, 6, and 7 have a 64Kbyte resolution.
Register name: LSI4_BD
Bits
7
Register offset: 0x1A8
6
5
4
3
31:24
BD
23:16
BD
15:08
BD
1
0
Reserved
07:00
Reserved
Name
BD
2
Description
Bound Address
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Type
Reset by
Reset value
R/W
All
0
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12. Registers > Register Description
12.3.36
PCI Target Image 4 Translation Offset (LSI4_TO)
Address bits [31:12] generated on the VMEbus in response to an image decode are a two’s complement
addition of address bits [31:12] on the PCI Bus and bits [31:12] of the image’s translation offset.
Register name: LSI4_TO
Bits
7
Register offset: 0x1AC
6
5
4
3
31:24
TO
23:16
TO
15:08
TO
1
0
Reserved
07:00
Reserved
Name
TO
2
Description
Translation offset
Universe II User Manual
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Type
Reset by
Reset value
R/W
All
0
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�12. Registers > Register Description
12.3.37
217
PCI Target Image 5 Control Register (LSI5_CTL)
In the PCI Target Image Control register, setting the VCT bit will only have effect if the VAS bits are
programmed for A24 or A32 space and the VDW bits are programmed for 8-bit, 16-bit, or 32-bit.
If VAS bits are programmed to A24 or A32 and the VDW bits are programmed for 64-bit, the Universe
II may perform MBLT transfers independent of the state of the VCT bit.
The setting of the PWEN bit is ignored if the LAS bit is programmed for PCI Bus I/O Space, forcing all
transactions through this image to be coupled.
Register name: LSI5_CTL
Register offset: 0x1B4
Bits
7
6
31:24
EN
PWEN
23:16
5
Reserved
3
2
Reserved
PGM
1
0
Reserved
VDW
15:08
4
Reserved
07:00
SUPER
VAS
Reserved
VCT
Reserved
Name
EN
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
10
R/W
All
0
0=Disabl
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
VDW
VMEbus Maximum
Datawidth
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
VAS
VMEbus Address
Space
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=CR/CSR
110=User1
111=User2
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12. Registers > Register Description
Name
Description
Type
Reset by
Reset value
PGM
Program/Data AM
Code
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
0=Data
1=Program
SUPER
Supervisor/User AM
Code
0=Non-Privileged
1=Supervisor
VCT
VMEbus Cycle Type
0=no BLTs on VMEbus
1=BLTs on VMEbus
LAS
PCI Bus Memory
Space
0=PCI Bus Memory
Space
1=PCI Bus I/O Space
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�12. Registers > Register Description
12.3.38
219
PCI Target Image 5 Base Address Register (LSI5_BS)
The base address specifies the lowest address in the address range that will be decoded.
Register name: LSI5_BS
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS
Register offset: 0x1B8
Description
Base Address
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Type
Reset by
Reset value
R/W
All
0
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12. Registers > Register Description
12.3.39
PCI Target Image 5 Bound Address Register (LSI5_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base
address and less than the bound register. If the bound address is 0, then the addresses decoded are
those greater than or equal to the base address.
Register name: LSI5_BD
Register offset: 0x1BC
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD
Description
Bound Address
Type
Reset by
Reset value
R/W
All
0
The bound address for PCI Target Image 0 and PCI Target Image 4 have a 4Kbyte resolution. PCI
Target Images 1, 2, 3, 5, 6, and 7 have a 64Kbyte resolution.
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�12. Registers > Register Description
12.3.40
221
PCI Target Image 5 Translation Offset (LSI5_TO)
Address bits [31:16] generated on the VMEbus in response to an image decode are a two’s complement
addition of address bits [31:16] on the PCI Bus and bits [31:16] of the image’s translation offset.
Register name: LSI5_TO
Register offset: 0x1C0
Bits
Function
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Name
TO
Description
Translation offset
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Type
Reset by
Reset value
R/W
All
0
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�222
12. Registers > Register Description
12.3.41
PCI Target Image 6 Control Register (LSI6_CTL)
In the PCI Target Image Control register, setting the VCT bit will only have effect if the VAS bits are
programmed for A24 or A32 space and the VDW bits are programmed for 8-bit, 16-bit, or 32-bit.
If VAS bits are programmed to A24 or A32 and the VDW bits are programmed for 64-bit, the Universe
II may perform MBLT transfers independent of the state of the VCT bit.
The setting of the PWEN bit is ignored if the LAS bit is programmed for PCI Bus I/O Space, forcing all
transactions through this image to be coupled.
Register name: LSI6_CTL
Register offset: 0x1C8
Bits
7
6
31:24
EN
PWEN
23:16
15:08
5
2
1
Reserved
PGM
Reserved
07:00
0
SUPER
VAS
Reserved
VCT
Reserved
Name
EN
3
Reserved
VDW
Reserved
4
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
10
R/W
All
0
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
VDW
VMEbus Maximum Datawidth
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
VAS
VMEbus Address Space
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=CR/CSR
110=User1
111=User2
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�12. Registers > Register Description
Name
PGM
223
Description
Program/Data AM Code
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
0=Data
1=Program
SUPER
Supervisor/User AM Code
0=Non-Privileged
1=Supervisor
VCT
VMEbus Cycle Type
0=no BLTs on VMEbus
1=BLTs on VMEbus
LAS
PCI Bus Memory Space
0=PCI Bus Memory Space
1=PCI Bus I/O Space
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12. Registers > Register Description
12.3.42
PCI Target Image 6 Base Address Register (LSI6_BS)
The base address specifies the lowest address in the address range that will be decoded.
Register name: LSI6_BS
Register offset: 0x1CC
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS
Description
Base Address
Universe II User Manual
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Type
Reset by
Reset value
R/W
All
0
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�12. Registers > Register Description
12.3.43
225
PCI Target Image 6 Bound Address Register (LSI6_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound address is 0, then the addresses decoded are those greater
than or equal to the base address.
Register name: LSI6_BD
Register offset: 0x1D0
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD
Description
Bound Address
Type
Reset by
Reset value
R/W
All
0
The bound address for PCI Target Image 0 and PCI Target Image 4 have a 4Kbyte resolution. PCI
Target Images 1, 2, 3, 5, 6, and 7 have a 64Kbyte resolution.
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12. Registers > Register Description
12.3.44
PCI Target Image 6 Translation Offset (LSI6_TO)
Address bits [31:16] generated on the VMEbus in response to an image decode are a two’s complement
addition of address bits [31:16] on the PCI Bus and bits [31:16] of the image’s translation offset.
Register name: LSI6_TO
Register offset: 0x1D4
Bits
Function
31:24
TO
23:16
TO
15;08
Reserved
07:00
Reserved
Name
TO
Description
Translation offset
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Type
Reset by
Reset value
R/W
All
0
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�12. Registers > Register Description
12.3.45
227
PCI Target Image 7 Control Register (LSI7_CTL)
In the PCI Target Image Control register, setting the VCT bit will only have effect if the VAS bits are
programmed for A24 or A32 space and the VDW bits are programmed for 8-bit, 16-bit, or 32-bit.
If VAS bits are programmed to A24 or A32 and the VDW bits are programmed for 64-bit, the Universe
II may perform MBLT transfers independent of the state of the VCT bit.
The setting of the PWEN bit is ignored if the LAS bit is programmed for PCI Bus I/O Space, forcing all
transactions through this image to be coupled.
Register name: LSI7_CTL
Register offset: 0x1DC
Bits
7
6
31:24
EN
PWEN
23;16
15:08
5
2
Reserved
PGM
Reserved
07:00
1
0
SUPER
VAS
Reserved
VCT
Reserved
Name
EN
3
Reserved
VDW
Reserved
4
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
10
R/W
All
0
R/W
All
0
R/W
All
0
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
VDW
VMEbus Maximum Datawidth
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
VAS
VMEbus Address Space
000=A16, 001=A24, 010=A32, 011= Reserved,
100=Reserved, 101=CR/CSR, 110=User1, 111=User2
PGM
Program/Data AM Code
0=Data
1=Program
SUPER
Supervisor/User AM Code
0=Non-Privileged
1=Supervisor
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12. Registers > Register Description
Name
VCT
Description
VMEbus Cycle Type
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
0=no BLTs on VMEbus
1=BLTs on VMEbus
LAS
PCI Bus Memory Space
0=PCI Bus Memory Space
1=PCI Bus I/O Space
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�12. Registers > Register Description
12.3.46
229
PCI Target Image 7 Base Address Register (LSI7_BS)
The base address specifies the lowest address in the address range that is decoded.
Register name: LSI7_BS
Register offset: 0x1E0
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS
Description
Base Address
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Type
Reset by
Reset value
R/W
All
0
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12. Registers > Register Description
12.3.47
PCI Target Image 7 Bound Address Register (LSI7_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound address is 0, then the addresses decoded are those greater
than or equal to the base address.
Register name: LSI7_BD
Register offset: 0x1E4
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD
Description
Bound Address
Type
Reset by
Reset value
R/W
All
0
The bound address for PCI Target Image 0 and PCI Target Image 4 have a 4Kbyte resolution. PCI
Target Images 1, 2, 3, 5, 6, and 7 have a 64Kbyte resolution.
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�12. Registers > Register Description
12.3.48
231
PCI Target Image 7 Translation Offset (LSI7_TO)
Address bits [31:16] generated on the VMEbus in response to an image decode are a two’s complement
addition of address bits [31:16] on the PCI Bus and bits [31:16] of the image’s translation offset.
Register name: LSI7_TO
Register offset: 0x1E8
Bits
Function
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Name
TO
Description
Translation offset
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Type
Reset by
Reset value
R/W
All
0
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12. Registers > Register Description
12.3.49
DMA Transfer Control Register (DCTL)
This register is programmed from either bus or is programmed by the DMAC when it loads the
command packet. The DMA only accesses PCI Bus Memory space.
The VCT bit determines whether or not the Universe II VME Master will generate BLT transfers. The
value of this bit only has meaning if the address space is A24 or A32 and the data width is not 64 bits.
If the data width is 64 bits the Universe II may perform MBLT transfers independent of the state of the
VCT bit.
Register name: DCTL
Bits
7
31:24
L2V
Register offset: 0x200
6
5
4
3
2
1
0
Reserved
23:16
VDW
15:08
PGM
Reserved
SUPER
VAS
Reserved
NO_
VCT
VINC
07:00
LD64EN
Name
L2V
Reserved
Description
Direction
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
0=Transfer from VMEbus to PCI Bus
1=Transfer from PCI Bus to VMEbus
VDW
VMEbus Maximum Datawidth
00=8-bit data width
01=16 bit data width
10=32-bit data width
11=64-bit data width
VAS
VMEbus Address Space
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=Reserved
110=User1
111=User2
PGM
Program/Data AM Code
00=Data
01=Program
others= Reserved
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Name
SUPER
233
Description
Supervisor/User AM Code
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
1
00=Non-Privileged
01=Supervisor
others= Reserved
NO_VINC
VMEbus Non-Incrementing Mode (Non-Inc Mode)
0=disabled
1=enabled
VCT
VMEbus Cycle Type
0=no BLTs on VMEbus
1=BLTs on VMEbus
LD64EN
Enable 64-bit PCI Bus Transactions
0=Disable
1=Enable
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12. Registers > Register Description
12.3.50
DMA Transfer Byte Count Register (DTBC)
This register specifies the number of bytes to be moved by the DMA before the start of the DMA
transfer, or the number of remaining bytes in the transfer while the DMA is active. This register is
programmed from either bus or is programmed by the DMA Controller when it loads a command
packet from a linked-list.
Register name: DTBC
Register offset: 0x204
Bits
Function
31:24
Reserved
23:16
DTBC
15:08
DTBC
07:00
DTBC
Name
DTBC
Description
DMA Transfer Byte Count
Type
Reset by
Reset value
R/W
All
0
In direct mode the user must re-program the DTBC register before each transfer.
When using the DMA to perform linked-list transfers, it is essential that the DTBC register contains a
value of zero before setting the GO bit of the DGCS register or undefined behaviors may occur.
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�12. Registers > Register Description
12.3.51
235
DMA PCI Bus Address Register (DLA)
This register is programmed from either bus or by the DMA Controller when it loads a command
packet. In direct mode the user must reprogram the DLA register before each transfer. In linked-list
mode, this register is only updated when the DMA is stopped, halted, or at the completion of
processing a command packet.
Register name: DLA
Register offset: 0x208
Bits
Function
31:24
LA
23:16
LA
15:08
LA
07:00
LA
Name
Description
Type
Reset by
Reset value
LA[31:3]
PCI Bus Address
R/W
All
0
LA[2:0]
PCI Bus Address
R/W
All
0
Address bits [2:0] must be programmed the same as those in
the DVA.
After a Bus Error, a Target-Abort, or a Master-Abort, the value in the DLA register must not be used to
reprogram the DMA because it has no usable information. Some offset from its original value must be
used.
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12. Registers > Register Description
12.3.52
DMA VMEbus Address Register (DVA)
This register is programmed from either bus or is programmed by the DMA Controller when it loads a
command packet. In direct mode the user must reprogram the DVA register before each transfer. In
linked-list operation, this register is only updated when the DMA is stopped, halted, or at the
completion of processing a command packet.
Register name: DVA
Register offset: 0x210
Bits
Function
31:24
VA
23:16
VA
15:08
VA
07:00
VA
Name
VA
Description
VMEbus Address
Type
Reset by
Reset value
R/W
All
0
Address bits [2:0] must be programmed the same as those in
the DLA.
After a bus error, a Target-Abort, or a Master-Abort, the value in the DVA register must not be used to
reprogram the DMA because it has no usable information. Some offset from its original value must be
used.
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�12. Registers > Register Description
12.3.53
237
DMA Command Packet Pointer (DCPP)
This register contains the pointer into the current command packet. Initially it is programmed to the
starting packet of the linked-list, and is updated with the address to a new command packet at the
completion of a packet.
The packets must be aligned to a 32-byte address.
Register name: DCPP
Bits
7
Register offset: 0x218
6
5
4
3
31:24
DCPP
23:16
DCPP
15:08
DCPP
07:00
DCPP
Name
DCPP
[31:5]
1
0
Reserved
Description
DMA Command Packet Pointer
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2
Type
Reset by
Reset value
R/W
All
0
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�238
12. Registers > Register Description
12.3.54
DMA General Control/Status Register (DGCS)
Register name: DGCS
Register offset: 0x220
Bits
7
6
5
4
3
2
1
0
31:24
GO
STOP_
HALT_
0
CHAIN
0
0
0
REQ
REQ
VERR
P_ERR
23:16
Reserved
15:08
ACT
07:00
0
VON
STOP
HALT
0
INT_
INT_
0
STOP
HALT
Name
GO
VOFF
DONE
LERR
INT_
INT_
INT_
INT_
DONE
LERR
VERR
P_ERR
Description
DMA Go Bit
0=No effect
Type
Reset by
Reset value
W/Read 0
always
All
0
W/Read 0
always
All
0
W/Read 0
always
All
0
R/W
All
0
R/W
All
0
1=Enable DMA Transfers
STOP_ REQ
DMA Stop Request
0=No effect
1=Stop DMA transfer when all buffered data has been written
HALT_ REQ
DMA Halt Request
0=No effect
1=Halt the DMA transfer at the completion of the current
command packet
CHAIN
DMA Chaining
0=DMA Direct Mode
1=DMA Linked List mode
VON [2:0]
VMEbus “On” counter
000=Until done
001=256 bytes
010=512 bytes
011=1024 bytes
100=2048 bytes
101=4096 bytes
110=8192 bytes
111=16384 bytes
others= Reserved
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�12. Registers > Register Description
Name
VOFF [3:0]
239
Description
VMEbus “Off” Counter
Type
Reset by
Reset value
R/W
All
0
R
All
0
R/Write 1 to
Clear
All
0
R/Write 1 to
Clear
All
0
R/Write 1 to
Clear
All
0
R/Write 1 to
Clear
All
0
R/Write 1 to
Clear
All
0
R/Write 1 to
Clear
All
0
0000=0µs
0001=16µs
0010=32µs
0011=64µs
0100=128µs
0101=256µs
0110=512µs
0111=1024µs
1000=2µs
1001=4µs
1010=8µs
others= Reserved
The DMA will not re-request the VME Master until this timer
expires.
ACT
DMA Active Status Bit
0=Not Active
1=Active
STOP
DMA Stopped Status Bit
0=Not Stopped
1=Stopped
HALT
DMA Halted Status Bit
0=Not Halted
1=Halted
DONE
DMA Done Status Bit
0=Not Complete
1=Complete
LERR
DMA PCI Bus Error Status Bit
0=No Error
1=Error
VERR
DMA VMEbus Error Status Bit
0=No Error
1=Error
P_ERR
DMA Programming Protocol Error Status Bit
Asserted if PCI master interface disabled or lower three bits of
PCI and VME addresses differ
0=No Error
1=Error
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�240
12. Registers > Register Description
Name
INT_STOP
Description
Interrupt when Stopped
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
0=Disable
1=Enable
INT_HALT
Interrupt when Halted
0=Disable
1=Enable
INT_ DONE
Interrupt when Done
0=Disable
1=Enable
INT_LERR
Interrupt on LERR
0=Disable
1=Enable
INT_VERR
Interrupt on VERR
0=Disable
1=Enable
INT_P_ ERR
Interrupt on Master Enable Error
0=Disable
1=Enable
STOP, HALT, DONE, LERR, VERR, and P_ERR must be cleared before the GO bit is enabled.
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�12. Registers > Register Description
12.3.55
241
DMA Linked List Update Enable Register (D_LLUE)
The PCI Resource must read back a logic 1 in the UPDATE field before proceeding to modify the
linked list. After the Linked List has been modified the PCI Resource must clear the UPDATE field by
writing a logic 0. The Universe II does not prevent an external master, from the PCI bus or the
VMEbus, from writing to the other DMA registers (see “Linked-list Updating” on page 100).
Register name: D_LLUE
Bits
7
31:24
UPDATE
Register offset: 0x224
6
5
4
3
Reserved
15:08
Reserved
07:00
Reserved
UPDATE
1
0
Reserved
23:16
Name
2
Description
DMA Linked List Update Enable
Type
Reset by
Reset value
R/W
All
0
0=PCI Resource not Updating Linked List
1=PCI Resource Updating Linked List
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�242
12. Registers > Register Description
12.3.56
PCI Interrupt Enable Register (LINT_EN)
Bits VIRQ7-VIRQ1 enable the Universe II to respond as a VME Interrupt Handler to interrupts on the
VIRQ[x] lines. When a VIRQx interrupt is enabled, and the corresponding VIRQ[x] pin is asserted, the
Universe II requests the VMEbus and performs a VME IACK cycle for that interrupt level. When the
interrupt acknowledge cycle completes, the STATUS/ID is stored in the corresponding VINT_ID
register, the VIRQx bit of the LINT_STAT register is set, and a PCI interrupt is generated. The
Universe II does not acquire further interrupt STATUS/ID vectors at the same interrupt level until the
VIRQx bit in the LINT_STAT register is cleared.
The other bits enable the respective internal or external sources to interrupt the PCI side.
Register name: LINT_EN
Bits
7
Register offset: 0x300
6
5
4
3
2
1
0
LM0
MBOX3
MBOX2
MBOX1
MBOX0
SW_
Reserved
VERR
LERR
DMA
VIRQ3
VIRQ2
VIRQ1
VOWN
31:24
Reserved
23:16
LM3
LM2
LM1
15:08
ACFAIL
SYSFAIL
SW_INT
IACK
07:00
VIRQ7
VIRQ6
Name
LM3
VIRQ5
Description
Location Monitor 3
VIRQ4
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
0=LM3 Interrupt Disabled
1=LM3 Interrupt Enabled
LM2
Location Monitor 2
0=LM2 Interrupt Disabled
1=LM2 Interrupt Enabled
LM1
Location Monitor 1
0=LM1 Interrupt Disabled
1=LM1 Interrupt Enabled
LM0
Location Monitor 0
0=LM0 Interrupt Disabled
1=LM0 Interrupt Enabled
MBOX3
Mailbox 3
0=MBOX3 Interrupt Disabled
1=MBOX3 Interrupt Enabled
MBOX2
Mailbox 2
0=MBOX2 Interrupt Disabled
1=MBOX2 Interrupt Enabled
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�12. Registers > Register Description
Name
MBOX1
243
Description
Mailbox 1
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
0=MBOX1 Interrupt Disabled
1=MBOX1 Interrupt Enabled
MBOX0
Mailbox 0
0=MBOX0 Interrupt Disabled
1=MBOX0 Interrupt Enabled
ACFAIL
ACFAIL Interrupt
0=ACFAIL Interrupt Disabled
1=ACFAIL Interrupt Enabled
SYSFAIL
SYSFAIL Interrupt
0=SYSFAIL Interrupt Disabled
1=SYSFAIL Interrupt Enabled
SW_INT
Local Software Interrupt
0=PCI Software Interrupt Disabled
1=PCI Software Interrupt Enabled
A zero-to-one transition will cause the PCI software interrupt
to be asserted. Subsequent zeroing of this bit will cause the
interrupt to be masked, but will not clear the PCI Software
Interrupt Status bit.
SW_IACK
“VME Software IACK”
0 =“VME Software IACK” Interrupt Disabled
1 =“VME Software IACK” Interrupt Enabled
VERR
PCI VERR Interrupt
0 =PCI VERR Interrupt Disabled
1=PCI VERR Interrupt Enabled
LERR
PCI LERR Interrupt
0 =PCI LERR Interrupt Disabled
1 =PCI LERR Interrupt Enabled
DMA
PCI DMA Interrupt
0=PCI DMA Interrupt Disabled
1=PCI DMA Interrupt Enabled
VIRQ7-VIRQ1
VIRQx Interrupt
0=VIRQx Interrupt Disabled
1 =VIRQx Interrupt Enabled
VOWN
VOWN Interrupt
0=VOWN Interrupt Disabled
1=VOWN Interrupt Enabled
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�244
12. Registers > Register Description
12.3.57
PCI Interrupt Status Register (LINT_STAT)
Status bits indicated as “R/Write 1 to Clear” are edge sensitive: the status is latched when the interrupt
event occurs. These status bits can be cleared independently of the state of the interrupt source by
writing a “1” to the status register. Clearing the status bit does not imply the source of the interrupt is
cleared. However, ACFAIL and SYSFAIL are level-sensitive. Clearing ACFAIL or SYSFAIL while
their respective pins are still asserted will have no effect.
Register name: LINT_STAT
Bits
7
Register offset: 0x304
6
5
4
3
2
1
0
LM0
MBOX3
MBOX2
MBOX1
MBOX0
SW_
Reserved
VERR
LERR
DMA
VIRQ3
VIRQ2
VIRQ1
VOWN
31:24
Reserved
23:16
LM3
LM2
LM1
15:08
ACFAIL
SYSFAIL
SW_INT
IACK
07:00
VIRQ7
Name
LM3
VIRQ6
VIRQ5
Description
Location Monitor 3 Status/Clear
0=no Location Monitor 3 Interrupt,
VIRQ4
Type
Reset by
Reset value
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
1=Location Monitor 3 Interrupt active
LM2
Location Monitor 2 Status/Clear
0=no Location Monitor 2 Interrupt,
1=Location Monitor 2 Interrupt active
LM1
Location Monitor 1 Status/Clear
0=no Location Monitor 1 Interrupt,
1=Location Monitor 1 Interrupt active
LM0
Location Monitor 0 Status/Clear
0=no Location Monitor 0 Interrupt,
1=Location Monitor 0 Interrupt active
MBOX3
Mailbox 3 Status/Clear
0=no Mailbox 3 Interrupt,
1=Mailbox 3 Interrupt active
MBOX2
Mailbox 2 Status/Clear
0=no Mailbox 2 Interrupt,
1=Mailbox 2 Interrupt active
MBOX1
Mailbox 1 Status/Clear
0=no Mailbox 1 Interrupt,
1=Mailbox 1 Interrupt active
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�12. Registers > Register Description
Name
MBOX0
245
Description
Mailbox 0 Status/Clear
0=no Mailbox 0 Interrupt,
Type
Reset by
Reset value
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
1=Mailbox 0 Interrupt active
ACFAIL
ACFAIL Interrupt Status/Clear
0=no ACFAIL Interrupt,
1=ACFAIL Interrupt active
SYSFAIL
SYSFAIL Interrupt Status/Clear
0=no SYSFAIL Interrupt,
1=SYSFAIL Interrupt active
SW_INT
Local Software Interrupt Status/Clear
0=no PCI Software Interrupt,
1=PCI Software Interrupt active
SW_IACK
“VME Software IACK” Status/Clear
0=no “VME Software IACK” Interrupt,
1=“VME Software IACK” Interrupt active
VERR
Local VERR Interrupt Status/Clear
0=Local VERR Interrupt masked,
1=Local VERR Interrupt active
LERR
Local LERR Interrupt Status/Clear
0=Local LERR Interrupt masked,
1=Local LERR Interrupt active
DMA
Local DMA Interrupt Status/Clear
0=Local DMA Interrupt masked,
1=Local DMA Interrupt active
VIRQ7-VIRQ1
VIRQx Interrupt Status/Clear
0=VIRQx Interrupt masked,
1=VIRQx Interrupt active
VOWN
VOWN Interrupt Status/Clear
0=no VOWN Interrupt masked,
1=VOWN Interrupt active
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�246
12. Registers > Register Description
12.3.58
PCI Interrupt Map 0 Register (LINT_MAP0)
This register maps various interrupt sources to one of the eight PCI interrupt pins. For example, a value
of 000 maps the corresponding interrupt source to LINT_ [0].
Register name: LINT_MAP0
Register offset: 0x308
Bits
7
31:24
Reserved
VIRQ7
Reserved
VIRQ6
23:16
Reserved
VIRQ5
Reserved
VIRQ4
15:08
Reserved
VIRQ3
Reserved
VIRQ2
07:00
Reserved
VIRQ1
Reserved
VOWN
Name
VIRQ7-VIRQ1
VOWN
6
5
4
Description
3
2
1
0
Type
Reset by
Reset value
PCI interrupt destination (LINT[7:0]) for VIRQx
R/W
All
0
VMEbus ownership bit interrupt map to PCI interrupt
R/W
All
0
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12.3.59
247
PCI Interrupt Map 1 Register (LINT_MAP1)
This register maps various interrupt sources to one of the eight PCI interrupt pins. For example, a value
of 000 maps the corresponding interrupt source to LINT_ [0].
Register name: LINT_MAP1
Register offset: 0x30C
Bits
7
6
5
31:24
Reserved
ACFAIL
Reserved
SYSFAIL
23:16
Reserved
SW_INT
Reserved
SW_IACK
15:08
07:00
4
3
2
Reserved
Reserved
Name
LERR
0
VERR
Reserved
DMA
Type
Reset by
Reset value
ACFAIL interrupt destination
R/W
All
0
SYSFAIL
SYSFAIL interrupt destination
R/W
All
0
SW_INT
PCI software interrupt destination
R/W
All
0
VMEbus Software IACK interrupt destination
R/W
All
0
VERR
VMEbus Error interrupt destination
R/W
All
0
LERR
PCI Bus Error interrupt destination
R/W
All
0
DMA
DMA interrupt destination
R/W
All
0
ACFAIL
SW_IACK
Description
1
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�248
12. Registers > Register Description
12.3.60
VMEbus Interrupt Enable Register (VINT_EN)
This register enables the various sources of VMEbus interrupts.
SW_INT can be enabled with the VME64AUTO power-up option.
Register name: VINT_EN
Register offset: 0x310
Bits
7
6
5
4
3
2
1
0
31:24
SW_ INT7
SW_ INT6
SW_ INT5
SW_ INT4
SW_ INT3
SW_ INT2
SW_ INT1
Reserved
MBOX3
MBOX2
MBOX1
MBOX0
SW_INT
Reserved
VERR
LERR
DMA
LINT4
LINT3
LINT2
LINT1
LINT0
23:16
Reserved
15:08
07:00
Reserved
LINT7
Name
SW_INT7
LINT6
LINT5
Description
Type
Reset by
Reset value
VME Software 7 Interrupt Mask
0=VME Software 7 Interrupt masked,
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
1=VME Software 7 Interrupt enabled
A zero-to-one transition will cause a VME level 7 interrupt to
be generated. Subsequent zeroing of this bit will cause the
interrupt to be masked, but will not clear the VME Software 7
Interrupt Status bit.
SW_INT6
VME Software 6 Interrupt Mask
0=VME Software 6 Interrupt masked,
1=VME Software 6 Interrupt enabled
A zero-to-one transition will cause a VME level 6 interrupt to
be generated. Subsequent zeroing of this bit will cause the
interrupt to be masked, but will not clear the VME Software 6
Interrupt Status bit.
SW_INT5
VME Software 5 Interrupt Mask
0=VME Software 5 Interrupt masked,
1=VME Software 5 Interrupt enabled
A zero-to-one transition will cause a VME level 5 interrupt to
be generated. Subsequent zeroing of this bit will cause the
interrupt to be masked, but will not clear the VME Software 5
Interrupt Status bit.
SW_INT4
VME Software 4 Interrupt Mask
0=VME Software 4 Interrupt masked,
1=VME Software 4 Interrupt enabled
A zero-to-one transition will cause a VME level 4 interrupt to
be generated. Subsequent zeroing of this bit will cause the
interrupt to be masked, but will not clear the VME Software 4
Interrupt Status bit.
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Name
SW_INT3
249
Description
Type
Reset by
Reset value
VME Software 3 Interrupt Mask
0=VME Software 3 Interrupt masked,
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
Power-up
Option
1=VME Software 3 Interrupt enabled
A zero-to-one transition will cause a VME level 3 interrupt to
be generated. Subsequent zeroing of this bit will cause the
interrupt to be masked, but will not clear the VME Software 3
Interrupt Status bit.
SW_INT2
VME Software 2 Interrupt Mask
0=VME Software 2 Interrupt masked,
1=VME Software 2 Interrupt enabled
A zero-to-one transition will cause a VME level 2 interrupt to
be generated. Subsequent zeroing of this bit will cause the
interrupt to be masked, but will not clear the VME Software 2
Interrupt Status bit.
SW_INT1
VME Software 1 Interrupt Mask
0=VME Software 1 Interrupt masked,
1=VME Software 1 Interrupt enabled
A zero-to-one transition will cause a VME level 1 interrupt to
be generated. Subsequent zeroing of this bit will cause the
interrupt to be masked, but will not clear the VME Software 1
Interrupt Status bit.
MBOX3
Mailbox 3 Mask
0=MBOX3 Interrupt masked,
1=MBOX3 Interrupt enabled
MBOX2
Mailbox 2 Mask
0=MBOX2 Interrupt masked,
1=MBOX2 Interrupt enabled
MBOX1
Mailbox 1 Mask
0=MBOX1 Interrupt masked,
1=MBOX1 Interrupt enabled
MBOX0
Mailbox 0 Mask
0=MBOX0 Interrupt masked,
1=MBOX0 Interrupt enabled
SW_INT
“VME Software Interrupt” Mask
0 = VME Software Interrupt masked
1 =VME Software Interrupt enabled
A zero-to-one transition causes the VME software interrupt to
be asserted. Subsequent zeroing of this bit causes the
interrupt to be masked and the VMEbus interrupt negated, but
does not clear the VME software interrupt status bit.
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12. Registers > Register Description
Name
VERR
Description
VERR Interrupt Mask
Type
Reset by
Reset value
R/W
All
0
R/W
All
0
R/W
All
0
R/W
All
0
0 =PCI VERR Interrupt masked
1=PCI VERR Interrupt enabled
LERR
LERR Interrupt Mask
0 =PCI LERR Interrupt masked
1 =PCI LERR Interrupt enabled
DMA
DMA Interrupt Mask
0=PCI DMA Interrupt masked
1=PCI DMA Interrupt enabled
LINT7-LINT0
PCI Interrupt Mask
0=LINTx Interrupt masked
1 =LINTx Interrupt enabled
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12.3.61
251
VMEbus Interrupt Status Register (VINT_STAT)
This register maps PCI Bus interrupt sources to one of the seven VMEbus interrupt pins. A value of
001 maps the corresponding interrupt source to VIRQ*[1], a value of 002 maps to VIRQ*[2], etc. A
value of 000 effectively masks the interrupt since there is no corresponding VIRQ*[0].
Register name: VINT_STAT
Register offset: 0x314
Bits
7
6
5
4
3
2
1
0
31:24
SW_
SW_
SW_
SW_
SW_
SW_
SW_
Reserved
INT7
INT6
INT5
INT4
INT3
INT2
INT1
MBOX3
MBOX2
MBOX1
MBOX0
SW_INT
Reserved
VERR
LERR
DMA
LINT4
LINT3
LINT2
LINT1
LINT0
23:16
Reserved
15:08
07:00
Reserved
LINT7
Name
SW_INT7
LINT6
LINT5
Description
VME Software 7 Interrupt Status/Clear
0=no VME Software 7 Interrupt,
Type
Reset by
Reset value
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
1=VME Software 7 Interrupt active
SW_INT6
VME Software 6 Interrupt Status/Clear
0=no VME Software 6 Interrupt,
1=VME Software 6 Interrupt active
SW_INT5
VME Software 5 Interrupt Status/Clear
0=no VME Software 5 Interrupt,
1=VME Software 5 Interrupt active
SW_INT4
VME Software 4 Interrupt Status/Clear
0=no VME Software 4 Interrupt,
1=VME Software 4 Interrupt active
SW_INT3
VME Software 3 Interrupt Status/Clear
0=no VME Software 3 Interrupt,
1=VME Software 3 Interrupt active
SW_INT2
VME Software 2 Interrupt Status/Clear
0=no VME Software 2 Interrupt,
1=VME Software 2 Interrupt active
SW_INT1
VME Software 1 Interrupt Status/Clear
0=no VME Software 1 Interrupt,
1=VME Software 1 Interrupt active
MBOX3
Mailbox 3 Status/Clear
0=no Mailbox 3 Interrupt,
1=Mailbox 3 Interrupt active
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12. Registers > Register Description
Name
MBOX2
Description
Mailbox 2 Status/Clear
0=no Mailbox 2 Interrupt,
Type
Reset by
Reset value
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
R/Write 1
to clear
All
0
R/Write 1
to Clear
All
Power-up
Option
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
R/Write 1
to Clear
All
0
1=Mailbox 2 Interrupt active
MBOX1
Mailbox 1 Status/Clear
0=no Mailbox 1 Interrupt,
1=Mailbox 1 Interrupt active
MBOX0
Mailbox 0 Status/Clear
0=no Mailbox 0 Interrupt,
1=Mailbox 0 Interrupt active
SW_INT
VME Software Interrupt Status/Clear
0=VME Software Interrupt inactive,
1=VME Software Interrupt active
VERR
VERR Interrupt Status/Clear
0=VME VERR Interrupt masked,
1=VME VERR Interrupt enabled
LERR
LERR Interrupt Status/Clear
0=VME LERR Interrupt masked,
1=VME LERR Interrupt enabled
DMA
DMA Interrupt Status/Clear
0=VME DMA Interrupt masked,
1=VME DMA Interrupt enabled
LINT7-LINT0
LINTx Interrupt Status/Clear
0=LINTx Interrupt masked,
1=LINTx Interrupt enabled
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12.3.62
253
VME Interrupt Map 0 Register (VINT_MAP0)
Register name: VINT_MAP0
Register offset: 0x318
Bits
7
31:24
Reserved
LINT7
Reserved
LINT6
23:16
Reserved
LINT5
Reserved
LINT4
15:08
Reserved
LINT3
Reserved
LINT2
07:00
Reserved
LINT1
Reserved
LINT0
Name
LINT7-LINT0
6
5
4
Description
VMEbus destination of PCI Bus interrupt source
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2
1
0
Type
Reset by
Reset value
R/W
all
0
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12. Registers > Register Description
12.3.63
VME Interrupt Map 1 Register (VINT_MAP1)
This register maps VMEbus interrupt sources to one of the seven VMEbus interrupt pins. A value of
001 maps the corresponding interrupt source to VIRQ*[1], a value of 010 maps to VIRQ*[2], etc. A
value of 000 effectively masks the interrupt since there is no corresponding VIRQ*[0].
SW_INT is set to 010 with the VME64AUTO power-up option.
Register name: VINT_MAP1
Bits
7
Register offset: 0x31C
6
5
31:24
4
3
2
1
Reserved
23:16
Reserved
SW_INT
15:08
Reserved
VERR
07:00
0
Reserved
Name
LERR
DMA
Type
Reset by
Reset value
VMEbus Software interrupt destination
R/W
all
Power-up
Option
VERR
VMEbus Error interrupt destination
R/W
all
0
LERR
PCI Bus Error interrupt destination
R/W
all
0
DMA
DMA interrupt destination
R/W
all
0
SW_INT
Description
Reserved
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�12. Registers > Register Description
12.3.64
255
Interrupt STATUS/ID Out Register (STATID)
When the Universe II responds to an interrupt acknowledge cycle on VMEbus it returns an 8-bit
STATUS/ID. STATID [7:1] can be written by software to uniquely identify the VMEbus module within
the system. STATID [0] is a value of 0 if the Universe II is generating a software interrupt (SW_IACK)
at the same level as the interrupt acknowledge cycle, otherwise it is a value of 1.
Register name: STATID
Bits
7
Register offset: 0x320
6
5
4
3
31:24
STATID [7:0]
23:16
Reserved
15:08
Reserved
07:00
Reserved
Name
STATID [7:1]
STATID [0]
Description
Bits [7:1] of the STATUS/ID byte are returned when the
Universe II responds to a VMEbus IACK cycle.
0 = the Universe II is generating a SW_IACK at the same level
as the interrupt acknowledge cycle.
2
1
0
Type
Reset by
Reset value
R/W
all
1111111
R
all
undefined
1 = the Universe II is not generating a SW_IACK at the same
level as the interrupt acknowledge cycle.
The reset state is designed to support the VME64 Auto ID STATUS/ID value.
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12. Registers > Register Description
12.3.65
VIRQ1 STATUS/ID Register (V1_STATID)
The Vx_STATID registers are read-only registers that hold the 8-bit VMEbus STATUS/ID that is
acquired when the Universe II performs a IACK cycle for a given interrupt level.
Register name: V1_STATID
Bits
7
Register offset: 0x324
6
5
4
3
31:24
Reserved
23:16
Reserved
15:08
1
Reserved
07:00
0
ERR
STATID [7:0]
Name
ERR
2
Description
Error Status Bit
Type
Reset by
Reset value
R
all
0
R
all
0
0=STATUS/ID was acquired without bus error
1=bus error occurred during acquisition of the STATUS/ID
STATID [7:0]
STATUS/ID acquired during IACK cycle for level 1 VMEbus
interrupt
The Universe II is enabled as the interrupt handler for a given interrupt level via the VIRQx bits of the
LINT_EN register. Once a vector for a given level is acquired, the Universe II does not perform a
subsequent interrupt acknowledge cycle at that level until the corresponding VIRQx bit in the
LINT_STAT register is cleared.
The acquisition of a level x STATUS/ID by the Universe II updates the STATUS/ID field of the
corresponding Vx_STATID register and generation of a PCI interrupt. A VMEbus error during the
acquisition of the STATUS/ID vector sets the ERR bit, which means the STATUS/ID field may not
contain a valid vector.
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�12. Registers > Register Description
12.3.66
257
VIRQ2 STATUS/ID Register (V2_STATID)
The Vx_STATID registers are read-only registers that hold the 8-bit VMEbus STATUS/ID that is
acquired when the Universe II performs a IACK cycle for a given interrupt level.
Register name: V2_STATID
Bits
7
Register offset: 0x328
6
5
4
3
31:24
Reserved
23:16
Reserved
15:08
1
Reserved
07:00
0
ERR
STATID [7:0]
Name
ERR
2
Description
Error Status Bit
Type
Reset by
Reset value
R
all
0
R
all
0
0=STATUS/ID was acquired without bus error
1=bus error occurred during acquisition of the STATUS/ID
STATID [7:0]
STATUS/ID acquired during IACK cycle for level 1 VMEbus
interrupt
The Universe II is enabled as the interrupt handler for a given interrupt level via the VIRQx bits of the
LINT_EN register. Once a vector for a given level is acquired, the Universe II does not perform a
subsequent interrupt acknowledge cycle at that level until the corresponding VIRQx bit in the
LINT_STAT register is cleared.
The acquisition of a level x STATUS/ID by the Universe II updates the STATUS/ID field of the
corresponding Vx_STATID register and generation of a PCI interrupt. A VMEbus error during the
acquisition of the STATUS/ID vector sets the ERR bit, which means the STATUS/ID field may not
contain a valid vector.
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12. Registers > Register Description
12.3.67
VIRQ3 STATUS/ID Register (V3_STATID)
The Vx_STATID registers are read-only registers that hold the 8-bit VMEbus STATUS/ID that is
acquired when the Universe II performs a IACK cycle for a given interrupt level.
Register name: V3_STATID
Bits
7
Register offset: 0x32C
6
5
4
3
31:24
Reserved
23:16
Reserved
15:08
1
Reserved
07:00
0
ERR
STATID [7:0]
Name
ERR
2
Description
Error Status Bit
Type
Reset by
Reset value
R
all
0
R
all
0
0=STATUS/ID was acquired without bus error
1=bus error occurred during acquisition of the STATUS/ID
STATID [7:0]
STATUS/ID acquired during IACK cycle for level 3VMEbus
interrupt
The Universe II is enabled as the interrupt handler for a given interrupt level via the VIRQx bits of the
LINT_EN register. Once a vector for a given level is acquired, the Universe II does not perform a
subsequent interrupt acknowledge cycle at that level until the corresponding VIRQx bit in the
LINT_STAT register is cleared.
The acquisition of a level x STATUS/ID by the Universe II updates the STATUS/ID field of the
corresponding Vx_STATID register and generation of a PCI interrupt. A VMEbus error during the
acquisition of the STATUS/ID vector sets the ERR bit, which means the STATUS/ID field may not
contain a valid vector.
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�12. Registers > Register Description
12.3.68
259
VIRQ4 STATUS/ID Register (V4_STATID)
The Vx_STATID registers are read-only registers that hold the 8-bit VMEbus STATUS/ID that is
acquired when the Universe II performs a IACK cycle for a given interrupt level.
Register name: V4_STATID
Bits
7
Register offset: 0x330
6
5
4
3
31:24
Reserved
23:16
Reserved
15:08
1
Reserved
07:00
0
ERR
STATID [7:0]
Name
ERR
2
Description
Error Status Bit
Type
Reset by
Reset value
R
all
0
R
all
0
0=STATUS/ID was acquired without bus error
1=bus error occurred during acquisition of the STATUS/ID
STATID [7:0]
STATUS/ID acquired during IACK cycle for level 4 VMEbus
interrupt
The Universe II is enabled as the interrupt handler for a given interrupt level via the VIRQx bits of the
LINT_EN register. Once a vector for a given level is acquired, the Universe II does not perform a
subsequent interrupt acknowledge cycle at that level until the corresponding VIRQx bit in the
LINT_STAT register is cleared.
The acquisition of a level x STATUS/ID by the Universe II updates the STATUS/ID field of the
corresponding Vx_STATID register and generation of a PCI interrupt. A VMEbus error during the
acquisition of the STATUS/ID vector sets the ERR bit, which means the STATUS/ID field may not
contain a valid vector.
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12. Registers > Register Description
12.3.69
VIRQ5 STATUS/ID Register (V5_STATID)
The Vx_STATID registers are read-only registers that hold the 8-bit VMEbus STATUS/ID that is
acquired when the Universe II performs a IACK cycle for a given interrupt level.
Register name: V5_STATID
Bits
7
Register offset: 0x334
6
5
4
3
31:24
Reserved
23:16
Reserved
15:08
1
Reserved
07:00
0
ERR
STATID [7:0]
Name
ERR
2
Description
Error Status Bit
Type
Reset by
Reset value
R
all
0
R
all
0
0=STATUS/ID was acquired without bus error
1=bus error occurred during acquisition of the STATUS/ID
STATID [7:0]
STATUS/ID acquired during IACK cycle for level 5 VMEbus
interrupt
The Universe II is enabled as the interrupt handler for a given interrupt level via the VIRQx bits of the
LINT_EN register. Once a vector for a given level is acquired, the Universe II does not perform a
subsequent interrupt acknowledge cycle at that level until the corresponding VIRQx bit in the
LINT_STAT register is cleared.
The acquisition of a level x STATUS/ID by the Universe II updates the STATUS/ID field of the
corresponding Vx_STATID register and generation of a PCI interrupt. A VMEbus error during the
acquisition of the STATUS/ID vector sets the ERR bit, which means the STATUS/ID field may not
contain a valid vector.
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�12. Registers > Register Description
12.3.70
261
VIRQ6 STATUS/ID Register (V6_STATID)
The Vx_STATID registers are read-only registers that hold the 8-bit VMEbus STATUS/ID that is
acquired when the Universe II performs a IACK cycle for a given interrupt level.
Register name: V6_STATID
Bits
7
Register offset: 0x338
6
5
4
3
31:24
Reserved
23:16
Reserved
15:08
1
Reserved
07:00
0
ERR
STATID [7:0]
Name
ERR
2
Description
Error Status Bit
Type
Reset by
Reset value
R
all
0
R
all
0
0=STATUS/ID was acquired without bus error
1=bus error occurred during acquisition of the STATUS/ID
STATID [7:0]
STATUS/ID acquired during IACK cycle for level 6 VMEbus
interrupt
The Universe II is enabled as the interrupt handler for a given interrupt level via the VIRQx bits of the
LINT_EN register. Once a vector for a given level is acquired, the Universe II does not perform a
subsequent interrupt acknowledge cycle at that level until the corresponding VIRQx bit in the
LINT_STAT register is cleared.
The acquisition of a level x STATUS/ID by the Universe II updates the STATUS/ID field of the
corresponding Vx_STATID register and generation of a PCI interrupt. A VMEbus error during the
acquisition of the STATUS/ID vector sets the ERR bit, which means the STATUS/ID field may not
contain a valid vector.
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12. Registers > Register Description
12.3.71
VIRQ7 STATUS/ID Register (V7_STATID)
The Vx_STATID registers are read-only registers that hold the 8-bit VMEbus STATUS/ID that is
acquired when the Universe II performs a IACK cycle for a given interrupt level.
Register name: V7_STATID
Bits
7
Register offset: 0x33C
6
5
4
3
31:24
Reserved
23:16
Reserved
15:08
1
Reserved
07:00
0
ERR
STATID [7:0]
Name
ERR
2
Description
Error Status Bit
Type
Reset by
Reset value
R
all
0
R
all
0
0=STATUS/ID was acquired without bus error
1=bus error occurred during acquisition of the STATUS/ID
STATID [7:0]
STATUS/ID acquired during IACK cycle for level 7 VMEbus
interrupt
The Universe II is enabled as the interrupt handler for a given interrupt level via the VIRQx bits of the
LINT_EN register. Once a vector for a given level is acquired, the Universe II does not perform a
subsequent interrupt acknowledge cycle at that level until the corresponding VIRQx bit in the
LINT_STAT register is cleared.
The acquisition of a level x STATUS/ID by the Universe II updates the STATUS/ID field of the
corresponding Vx_STATID register and generation of a PCI interrupt. A VMEbus error during the
acquisition of the STATUS/ID vector sets the ERR bit, which means the STATUS/ID field may not
contain a valid vector.
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�12. Registers > Register Description
12.3.72
263
PCI Interrupt Map 2 Register (LINT_MAP2)
This register maps interrupt sources to one of the eight PCI interrupt pins. For example, a value of 000
maps the corresponding interrupt source to LINT_ [0].
Register name: LINT_MAP2
Register offset: 0x340
Bits
7
31:24
Reserved
LM3
Reserved
LM2
23:16
Reserved
LM1
Reserved
LM0
15:08
Reserved
MBOX3
Reserved
MBOX2
07:00
Reserved
MBOX1
Reserved
MBOX0
Name
6
5
Description
4
3
2
1
0
Type
Reset by
Reset value
LM3 [2:0]
Location Monitor 3 Interrupt destination
R/W
all
0
LM2 [2:0]
Location Monitor 2 Interrupt destination
R/W
all
0
LM1 [2:0]
Location Monitor 1 Interrupt destination
R/W
all
0
LM0 [2:0]
Location Monitor 0 Interrupt destination
R/W
all
0
MBOX3 [2:0]
Mailbox 3 Interrupt destination
R/W
all
0
MBOX2 [2:0]
Mailbox 2 Interrupt destination
R/W
all
0
MBOX1 [2:0]
Mailbox 1 Interrupt destination
R/W
all
0
MBOX0 [2:0]
Mailbox 0 Interrupt destination
R/W
all
0
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12. Registers > Register Description
12.3.73
VME Interrupt Map 2 Register (VINT_MAP2)
This register maps interrupt sources to one of the seven VMEbus interrupt pins. A value of 001 maps
the corresponding interrupt source to VIRQ*[1], a value of 002 maps to VIRQ*[2], etc. A value of 000
effectively masks the interrupt since there is no corresponding VIRQ*[0].
Register name: VINT_MAP2
Bits
7
Register offset: 0x344
6
5
4
3
31:24
Reserved
23:16
Reserved
2
1
15:08
Reserved
MBOX3
Reserved
MBOX2
07:00
Reserved
MBOX1
Reserved
MBOX0
Name
Description
0
Type
Reset by
Reset value
MBOX3 [2:0]
Mailbox 3 Interrupt destination
R/W
all
0
MBOX2 [2:0]
Mailbox 2 Interrupt destination
R/W
all
0
MBOX1 [2:0]
Mailbox 1 Interrupt destination
R/W
all
0
MBOX0 [2:0]
Mailbox 0 Interrupt destination
R/W
all
0
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�12. Registers > Register Description
12.3.74
265
Mailbox 0 Register (MBOX0)
This register is a general purpose mailbox register.
Register name: MBOX0
Register offset: 0x348
Bits
Function
31:24
MBOX0
23:16
MBOX0
15:08
MBOX0
07:00
MBOX0
Name
MBOX0
[31:0]
Description
Mailbox
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Type
Reset by
Reset value
R/W
all
0
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�266
12. Registers > Register Description
12.3.75
Mailbox 1 Register (MBOX1)
This register is a general purpose mailbox register.
Register name: MBOX1
Register offset: 0x34C
Bits
Function
31:24
MBOX1
23:16
MBOX1
15:08
MBOX1
07:00
MBOX1
Name
MBOX1
[31:0]
Description
Mailbox
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Type
Reset by
Reset value
R/W
all
0
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�12. Registers > Register Description
12.3.76
267
Mailbox 2 Register (MBOX2)
This register is a general purpose mailbox register.
Register name: MBOX2
Register offset: 0x350
Bits
Function
31:24
MBOX2
23:16
MBOX2
15:08
MBOX2
07:00
MBOX2
Name
MBOX2
[31:0]
Description
Mailbox
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Type
Reset by
Reset value
R/W
all
0
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�268
12. Registers > Register Description
12.3.77
Mailbox 3 Register (MBOX3)
This register is a general purpose mailbox register.
Register name: MBOX3
Register offset: 0x354
Bits
Function
31:24
MBOX3
23:16
MBOX3
15:08
MBOX3
07:00
MBOX3
Name
MBOX3
[31:0]
Description
Mailbox
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Type
Reset by
Reset value
R/W
all
0
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�12. Registers > Register Description
12.3.78
269
Semaphore 0 Register (SEMA0)
This register can only be accessed through byte-wide access.
Register name: SEMA0
Register offset: 0x358
Bits
7
31:24
SEM3
TAG3
23:16
SEM2
TAG2
15:08
SEM1
TAG1
07:00
SEM0
TAG0
Name
SEM3
TAG3 [6:0]
SEM2
TAG2 [6:0]
SEM1
TAG1 [6:0]
SEM0
TAG0 [6:0]
6
5
Description
4
3
2
1
0
Type
Reset by
Reset value
Semaphore 3
R/W
all
0
Tag 3
R/W
all
0
Semaphore 2
R/W
all
0
Tag2
R/W
all
0
Semaphore 1
R/W
all
0
Tag 1
R/W
all
0
Semaphore 0
R/W
all
0
Tag 0
R/W
all
0
If a semaphore bit is a value of 0, the associated tag field can be written to. If a semaphore bit is a value
of 1, the associated tag field cannot be written to (see “Semaphores” on page 83).
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12. Registers > Register Description
12.3.79
Semaphore 1 Register (SEMA1)
This register can only be accessed through byte-wide access.
Register name: SEMA1
Register offset: 0x35C
Bits
7
31:24
SEM7
TAG7
23:16
SEM6
TAG6
15:08
SEM5
TAG5
07:00
SEM4
TAG4
Name
SEM3
TAG3 [6:0]
SEM2
TAG2 [6:0]
SEM1
TAG1 [6:0]
SEM0
TAG0 [6:0]
6
5
Description
4
3
2
1
0
Type
Reset by
Reset value
Semaphore 7
R/W
all
0
Tag 7
R/W
all
0
Semaphore 6
R/W
all
0
Tag 6
R/W
all
0
Semaphore 5
R/W
all
0
Tag 5
R/W
all
0
Semaphore 4
R/W
all
0
Tag 4
R/W
all
0
If a semaphore bit is a value of 0, the associated tag field can be written to. If a semaphore bit is a value
of 1, the associated tag field cannot be written to (see “Semaphores” on page 83).
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�12. Registers > Register Description
12.3.80
271
Master Control Register (MAST_CTL)
Writing a 1 to the VOWN bit in the MAST_CTL register has the effect of asserting BBSY* until a 0 is
written to the VOWN bit. It does not affect the transactions in the PCI Target Channel. The Universe II
will not do an early release of BBSY* if the VMEbus was owned during a transaction by means of
VOWN, regardless of the value of PWON.
It is important to wait until VOWN_ACK is a value of 0 before writing a value of 1 to the VOWN bit.
In the event that BERR* is asserted on the VMEbus once the Universe II owns the VMEbus, the user
must release ownership by programming the VOWN bit to a value of 0, if the VMEbus was gained by
setting the VOWN bit. VMEbus masters must not write a value of 1 to the VOWN bit since this will
lock up the VMEbus.
Once the value programmed in the PWON field is reached during de-queuing of posted writes, the
Universe II will do an early release of BBSY*. If the PWON field is programmed to a value of 1111,
the Universe II will do an early release of BBSY* at the completion of each transaction. Note that the
VOWN setting described above overrides the POWN setting.
BUS_NO is used by the VMEbus Slave Channel when mapping VME transactions into PCI
Configuration space. If the bus number of the VMEbus address (bits [23:16]) is equal to the BUS_NO
field, then the Universe II generates a Type 0 configuration cycle, otherwise Type 1 is generated.
Register name: MAST_CTL
Bits
7
6
31:24
23:16
Register offset: 0x400
5
4
3
2
MAXRTRY
VRL
1
0
PWON
VRM
VREL
VOWN
VOWN_
Reserved
ACK
15:08
Reserved
PABS
07:00
BUS_NO
Name
MAXRTRY
[3:0]
Reserved
Description
Maximum Number of Retries
Type
Reset by
Reset value
R/W
all
1000
R/W
all
0000
0000=Retry Forever, Multiples of 64 (0001 through 1111).
Maximum Number of retries before the PCI master interface
signals error condition
PWON [3:0]
Posted Write Transfer Count
0000=128 bytes, 0001=256 bytes, 0010=512 bytes, 0011=1024
bytes, 0100=2048 bytes, 0101=4096 bytes, 0110 - 1110 =
Reserved, 1111=Early release of BBSY*.
Transfer count at which the PCI Slave Channel Posted Writes
FIFO gives up the VME Master Interface.
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12. Registers > Register Description
Name
VRL [1:0]
Description
VMEbus Request Level
Type
Reset by
Reset value
R/W
all
11
R/W
all
0
R/W
all
0
R/W
all
0
R
all
0
R/W
all
00
R/W
all
0000 0000
00=Level 0,01=Level 1,10=Level 2, 11=Level 3
VRM
VMEbus Request Mode
0=Demand,1=Fair
VREL
VMEbus Release Mode
0=Release When Done (RWD), 1=Release on Request (ROR)
VOWN
VME Ownership Bit
0=Release VMEbus, 1=Acquire and Hold VMEbus
VOWN_ACK
VME Ownership Bit Acknowledge
0=VMEbus not owned, 1=VMEbus acquired and held due to
assertion of VOWN
PABS [1:0]
PCI Aligned Burst Size
00=32 byte
01=64 byte
10=128 byte
11=256 byte
Controls the PCI address boundary at which the Universe II
breaks up a PCI transaction in the VME Slave channel (see
“VME Slave Image Programming” on page 67) and the DMA
Channel (see “FIFO Operation and Bus Ownership” on
page 101).
This field also determines when the PCI Master Module as part
of the VME Slave Channel will request the PCI bus (i.e., when
32, 64,128, or 256 bytes are available). It does not have this
effect on the DMA Channel, which has a fixed watermark of 128
bytes (see “FIFO Operation and Bus Ownership” on page 101).
BUS_NO [7:0]
PCI Bus Number
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�12. Registers > Register Description
12.3.81
273
Miscellaneous Control Register (MISC_CTL)
VMEbus masters must not write to SW_SYSRST, and PCI masters must not write to SW_LRST.
The bits VBTO, VARB and VARBTO support SYSCON functionality.
Universe II participation in the VME64 Auto ID mechanism is controlled by the VME64AUTO bit.
When this bit is detected high, the Universe II uses the SW_IACK mechanism to generate VXIRQ2 on
the VMEbus, then releases VXSYSFAIL. Access to the CR/CSR image is enabled when the level 2
interrupt acknowledge cycle completes. This sequence can be initiated with a power-up option or by
software writing a 1 to this bit.
Register name: MISC_CTL
Bits
Register offset: 0x404
7
6
31:24
23:16
15:08
5
VBTO
SW_
LRST
SW_
SYSRST
Reserved
SYSRE-SE
T
Reserved
BI
3
2
Reserved
VARB
ENGBI
RE-
1
0
VARBTO
SYSCON
SCIND
V64AUTO
Reserved
07:00
Reserved
Name
VBTO
4
Description
VME Bus Time-out
Type
Reset by
Reset value
R/W
all
0011
R/W
all
0
0000=Disable
0001=16 µsec
0010=32 µsec
0011=64 µsec
0100=128 µsec
0101=256 µsec
0110=512 µsec
0111=1024 µsec
Others= Reserved
Note: The VBTO value has a 4us resolution. The time-out may
occur up to 4us earlier than the selected VBTO period.
VARB
VMEbus Arbitration Mode
0=Round Robin
1=Priority
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12. Registers > Register Description
Name
VARBTO
Description
Type
Reset by
Reset value
R/W
all
01
R/W
all
0
R/W
all
0
R/W
all
Power-up
Option
R/W
all
0
RESCIND is unused in the Universe II.
R/W
all
1
SYSCON
R/W
all
Power-up
Option
R/W
all
Power-up
Option
R/W
all
0
VMEbus Arbitration Time-out
00=Disable Timer
01=16 µs (minimum 8µs)
10=256 µs
others= Reserved
SW_LRST
Software PCI Reset
0=No effect
1=Initiate LRST_
A read always returns 0.
SW_
SYSRST
Software VMEbus SYSRESET
0=No effect
1=Initiate SYSRST*
A read always returns 0.
BI
BI-Mode
0=Universe II is not in BI-Mode,
1=Universe II is in BI-Mode
Write to this bit to change the Universe II BI-Mode status. This
bit is also affected by the global BI-Mode initiator VRIRQ1*, if
this feature is enabled.
ENGBI
Enable Global BI-Mode Initiator
0=Assertion of VIRQ1 ignored
1=Assertion of VIRQ1 puts device in BI-Mode
RESCIND
SYSCON
0=Universe II is not VMEbus System Controller,
1=Universe II is VMEbus System Controller
V64AUTO
VME64 Auto ID
Write: 0=No effect
1=Initiate sequence
This bit initiates Universe II VME64 Auto ID Slave
participation.
SYSRESET
System Reset
0=No effect
1=Initiate SYSRST*
Universe II asserts SYSRESET without resetting itself.
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May 12, 2010
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�12. Registers > Register Description
12.3.82
275
Miscellaneous Status Register (MISC_STAT)
Register name: MISC_STAT
Register offset: 0x408
Bits
7
6
31:24
Reserved
LCLSIZE
23:16
Reserved
5
4
3
Reserved
MYBBSY
DY4AUTO
Reserved
DY4_DON
E
15:08
DY4AUTOID
07:00
Reserved
Name
LCLSIZE
2
Description
PCI Bus Size
1
0
Reserved
TXFE
RXFE
Reserved
Type
Reset by
Reset value
R
all
Power-up
Option
R
all
Power-up
Option
R
all
1
R
all
0
R
all
1
R
all
1
R
Power-up
reset and
VMEbus
SYS-
0
At the rising edge of RST_, the Universe II samples REQ64_
to determine the PCI Bus size. This bit reflects the result.
0=32-bit
1=64-bit
DY4AUTO
DY4 Auto ID Enable
0=Disable
1=Enable
MYBBSY
Universe II BBSY
0=Asserted
1=Negated
DY4DONE
DY4 Auto ID Done
0=Not done
1=Done
TXFE
PCI Target Channel Posted Writes FIFO
0=data in the FIFO
1=no data in the FIFO
RXFE
VME Slave Channel Posted Writes FIFO
0=data in the FIFO
1=no data in the FIFO
DY4
DY4 Auto ID
AUTOID
RESET*
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�276
12. Registers > Register Description
12.3.83
User AM Codes Register (USER_AM)
The USER_AM register can only be used to generate and accept AM codes 0x10 through 0x1F. These
AM codes are designated as USERAM codes in the VMEbus Specification.
Register name: USER_AM
Register offset: 0x40C
Bits
7
6
5
4
3
31:24
0
1
USER1AM
Reserved
23:16
0
1
USER2AM
Reserved
15:08
Reserved
07:00
Reserved
Name
Description
2
1
0
Type
Reset by
Reset value
USER1AM [3:0]
User AM Code 1
R/W
all
0000
USER2AM [3:0]
User AM Code 2
R/W
all
0000
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�12. Registers > Register Description
12.3.84
277
Universe II Specific Register (U2SPEC)
Register name: U2SPEC
Bits
Register offset: 0x4FC
7
6
5
4
3
31:24
Universe Reserved
23:16
Universe Reserved
15:08
Universe
Reserved
DS0/DS1
07:00
AS
Reserved
Universe Reserved
Name
DS0/DS1
DTKFLTR
Description
Data Strobe Filtering
2
1
MASt11
POSt28
0
READt27
Reserved
PREt28
Type
Reset by
Reset
value
R/W
all
0
R/W
all
0
R/W
all
0
R/W
all
0
R/W
all
00
R/W
all
0
This filter eliminates the noise on DS1* and DS0*.
0=Disable
1=Enable
AS
Address Strobe Filtering
This filter eliminates the noise on AS*.
0=Disable
1=Enable
DTKFLTR
VME DTACK* Inactive Filter
0=Slower but better filter
1=Faster but poorer filter
MASt11
VME Master Parameter t11 Control (DS* high time during BLT’s and
MBLT’s)
0=Default
1=Faster
READt27
VME Master Parameter t27 Control (Delay of DS* negation after read)
00=Default
01=Faster
10=No Delay
POSt28
VME Slave Parameter t28 Control (Time of DS* to DTACK* for
posted-write)
0=Default
1=Faster
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�278
12. Registers > Register Description
Name
Description
Type
Reset by
Reset
value
PREt28
VME Slave Parameter t28 Control (Time of DS* to DTACK* for prefetch
read)
R/W
all
0
0=Default
1=Faster
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�12. Registers > Register Description
12.3.85
279
VMEbus Slave Image 0 Control Register (VSI0_CTL)
The state of PWEN and PREN are ignored if LAS is not programmed memory space.
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12. Registers > Register Description
Register name: VSI0_CTL
Register offset: 0xF00
Bits
7
6
5
31:24
EN
PWEN
PREN
23:16
PGM
4
SUPER
1
0
Reserved
VAS
Reserved
LD64EN
LLRMW
Name
EN
2
Reserved
15:08
07:00
3
Reserved
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
11
R/W
PWR VME
11
R/W
PWR VME
0
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
PREN
Prefetch Read Enable
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
VAS
VMEbus Address Space
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=Reserved
110=User1
111=User2
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�12. Registers > Register Description
Name
LD64EN
281
Description
Enable 64-bit PCI Bus Transactions
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
0=Disable
1=Enable
LLRMW
Enable PCI Bus Lock of VMEbus RMW
0=Disable
1=Enable
LAS
PCI Bus Address Space
00=PCI Bus Memory Space
01=PCI Bus I/O Space
10=PCI Bus Configuration Space
11=Reserved
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�282
12. Registers > Register Description
12.3.86
VMEbus Slave Image 0 Base Address Register (VSI0_BS)
The base address specifies the lowest address in the address range that is decoded. This image has
4 Kbyte resolution.
Register name: VSI0_BS
Register offset: 0xF04
Bits
Function
31:24
BS
23:16
BS
15:08
BS
07:00
Reserved
Name
BS[31:12]
Reserved
Description
Base Address
Universe II User Manual
May 12, 2010
Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.87
283
VMEbus Slave Image 0 Bound Address Register (VSI0_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. This image has 4 Kbyte resolution.
Register name: VSI0_BD
Register offset: 0xF08
Bits
Function
31:24
BD
23:16
BD
15:08
BD
07:00
Reserved
Name
BD[31:12]
Reserved
Description
Bound Address
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Type
Reset by
Reset value
R/W
PWR VME
0
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�284
12. Registers > Register Description
12.3.88
VMEbus Slave Image 0 Translation Offset (VSI0_TO)
This image has 4 Kbyte resolution.
Register name: VSI0_TO
Register offset: 0xF0C
Bits
Function
31:24
TO
23:16
TO
15:08
TO
07:00
Reserved
Name
TO[31:12]
Reserved
Description
Translation Offset
Universe II User Manual
May 12, 2010
Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.89
285
VMEbus Slave Image 1 Control (VSI1_CTL)
This register provides the general, VMEbus and PCI controls for this slave image. Note that only
transactions destined for PCI Memory space are decoupled (the posted write RXFIFO generates on
Memory space transactions on the PCI Bus).
In order for a VMEbus slave image to respond to an incoming cycle, the BM bit in the PCI_CSR
register must be enabled.
The state of PWEN and PREN are ignored if LAS is not programmed memory space.
Register name: VSI1_CTL
Register offset: 0xF14
Bits
7
6
5
31:24
EN
PWEN
PREN
23:16
PGM
4
SUPER
1
0
Reserved
VAS
Reserved
LD64EN
LLRMW
Name
EN
2
Reserved
15:08
07:00
3
Reserved
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
11
R/W
PWR VME
11
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
PREN
Prefetch Read Enable
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
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�286
12. Registers > Register Description
Name
VAS
Description
VMEbus Address Space
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
1
R/W
PWR VME
1
R/W
PWR VME
0
000=Reserved
001=A24
010=A32
011= Reserved
100=Reserved
101=Reserved
110=User1
111=User2
LD64EN
Enable 64-bit PCI Bus Transactions
0=Disable
1=Enable
LLRMW
Enable PCI Bus Lock of VMEbus RMW
0=Disable
1=Enable
LAS
PCI Bus Address Space
00=PCI Bus Memory Space
01=PCI Bus I/O Space
10=PCI Bus Configuration Space
11=Reserved
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�12. Registers > Register Description
12.3.90
287
VMEbus Slave Image 1 Base Address Register (VSI1_BS)
The base address specifies the lowest address in the address range that will be decoded.
Register name: VSI1_BS
Register offset: 0xF18
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS[31:16]
Description
Base Address
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Type
Reset by
Reset value
R/W
PWR VME
0
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�288
12. Registers > Register Description
12.3.91
VMEbus Slave Image 1 Bound Address Register (VSI1_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register.
Register name: VSI1_BD
Register offset: 0xF1C
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD[31:16]
Description
Bound Address
Universe II User Manual
May 12, 2010
Type
Reset by
Reset value
R/W
PWR VME
0
Integrated Device Technology
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�12. Registers > Register Description
12.3.92
289
VMEbus Slave Image 1 Translation Offset (VSI1_TO)
Register name: VSI1_TO
Register offset: 0xF20
Bits
Function
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Name
TO[31:16]
Description
Translation Offset
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Type
Reset by
Reset value
R/W
PWR VME
0
Universe II User Manual
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�290
12. Registers > Register Description
12.3.93
VMEbus Slave Image 2 Control (VSI2_CTL)
This register provides the general, VMEbus and PCI controls for this slave image. Note that only
transactions destined for PCI Memory space are decoupled (the posted write RXFIFO generates on
Memory space transactions on the PCI Bus).
In order for a VMEbus slave image to respond to an incoming cycle, the BM bit in the PCI_CSR
register must be enabled.
The state of PWEN and PREN are ignored if LAS is not programmed memory space.
Register name: VSI2_CTL
Register offset: 0xF28
Bits
7
6
5
31:24
EN
PWEN
PREN
23:16
PGM
4
SUPER
1
0
Reserved
VAS
Reserved
LD64EN
LLRMW
Name
EN
2
Reserved
15:08
07:00
3
Reserved
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
11
R/W
PWR VME
11
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
PREN
Prefetch Read Enable
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
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�12. Registers > Register Description
Name
VAS
291
Description
VMEbus Address Space
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
000=Reserved
001=A24
010=A32
011= Reserved
100=Reserved
101=Reserved
110=User1
111=User2
LD64EN
Enable 64-bit PCI Bus Transactions
0=Disable
1=Enable
LLRMW
Enable PCI Bus Lock of VMEbus RMW
0=Disable
1=Enable
LAS
PCI Bus Address Space
00=PCI Bus Memory Space
01=PCI Bus I/O Space
10=PCI Bus Configuration Space
11=Reserved
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�292
12. Registers > Register Description
12.3.94
VMEbus Slave Image 2 Base Address Register (VSI2_BS)
Register name: VSI2_BS
Register offset: 0xF2C
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS[31:16]
Description
Base Address
Universe II User Manual
May 12, 2010
Type
Reset by
Reset value
R/W
PWR VME
0
Integrated Device Technology
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�12. Registers > Register Description
12.3.95
293
VMEbus Slave Image 2 Bound Address Register (VSI2_BD)
Register name: VSI2_BD
Register offset: 0xF30
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD[31:16]
Description
Bound Address
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Type
Reset by
Reset value
R/W
PWR VME
0
Universe II User Manual
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�294
12. Registers > Register Description
12.3.96
VMEbus Slave Image 2 Translation Offset (VSI2_TO)
Register name: VSI2_TO
Register offset: 0xF34
Bits
Function
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Name
TO[31:16]
Description
Translation Offset
Universe II User Manual
May 12, 2010
Type
Reset by
Reset value
R/W
PWR VME
0
Integrated Device Technology
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�12. Registers > Register Description
12.3.97
295
VMEbus Slave Image 3 Control (VSI3_CTL)
This register provides the general, VMEbus and PCI controls for this slave image. Note that only
transactions destined for PCI Memory space are decoupled (the posted write RXFIFO generates on
Memory space transactions on the PCI Bus).
In order for a VMEbus slave image to respond to an incoming cycle, the BM bit in the PCI_CSR
register must be enabled.
The state of PWEN and PREN are ignored if LAS is not programmed memory space.
Register name: VSI3_CTL
Register offset: 0xF3C
Bits
7
6
5
31:24
EN
PWEN
PREN
23:16
PGM
4
SUPER
1
0
Reserved
VAS
Reserved
LD64EN
LLRMW
Name
EN
2
Reserved
15:08
07:00
3
Reserved
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
11
R/W
PWR VME
11
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
PREN
Prefetch Read Enable
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
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�296
12. Registers > Register Description
Name
VAS
Description
VMEbus Address Space
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
000=Reserved
001=A24
010=A32
011= Reserved
100=Reserved,
101=Reserved
110=User1
111=User2
LD64EN
Enable 64-bit PCI Bus Transactions
0=Disable
1=Enable
LLRMW
Enable PCI Bus Lock of VMEbus RMW
0=Disable
1=Enable
LAS
PCI Bus Address Space
00=PCI Bus Memory Space
01=PCI Bus I/O Space
10=PCI Bus Configuration Space
11=Reserved
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�12. Registers > Register Description
12.3.98
297
VMEbus Slave Image 3 Base Address Register (VSI3_BS)
Register name: VSI3_BS
Register offset: 0xF40
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS[31:16]
Description
Base Address
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Type
Reset by
Reset value
R/W
PWR VME
0
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�298
12. Registers > Register Description
12.3.99
VMEbus Slave Image 3 Bound Address Register (VSI3_BD)
Register name: VSI3_BD
Register offset: 0xF44
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD[31:16]
Description
Bound Address
Universe II User Manual
May 12, 2010
Type
Reset by
Reset value
R/W
PWR VME
0
Integrated Device Technology
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�12. Registers > Register Description
12.3.100
299
VMEbus Slave Image 3 Translation Offset (VSI3_TO)
Register name: VSI3_TO
Register offset: 0xF48
Bits
Function
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Name
TO[31:16]
Description
Translation Offset
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Type
Reset by
Reset value
R/W
PWR VME
0
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�300
12. Registers > Register Description
12.3.101
Location Monitor Control Register (LM_CTL)
This register specifies the VMEbus controls for the location monitor image. This image has a 4 Kbyte
resolution and a 4 Kbyte size. The image responds to a VME read or write within the 4 Kbyte space
and matching one of the address modifier codes specified. BLTs and MBLTs are not supported.
VMEbus address bits [4:3] are used to set the status bit in LINT_STAT for one of the four location
monitor interrupts. If the Universe II VMEbus master is the owner of the VMEbus, the Universe II
VMEbus slave will generate DTACK* to terminate the transaction.
The Location Monitor does not store write data and read data is undefined.
Register name: LM_CTL
Bits
7
31:24
EN
23:16
Register offset: 0xF64
6
5
4
3
1
0
Reserved
PGM
SUPER
Reserved
15:08
Reserved
07:00
Reserved
Name
EN
2
Description
Image Enable
VAS
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
11
R/W
PWR VME
11
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
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�12. Registers > Register Description
Name
VAS
301
Description
VMEbus Address Space
Type
Reset by
Reset value
R/W
PWR VME
0
000=A16
001=A24
010=A32
011=Reserved
100=Reserved
101=Reserved
110=User1
111=User2
others= Reserved
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�302
12. Registers > Register Description
12.3.102
Location Monitor Base Address Register (LM_BS)
The base address specifies the lowest address in the 4 Kbyte range that will be decoded as a location
monitor access.
Register name: LM_BS
Bits
7
Register offset: 0xF68
6
5
4
3
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS [31:12]
Description
Base Address
Universe II User Manual
May 12, 2010
2
1
0
Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.103
303
VMEbus Register Access Image Control Register (VRAI_CTL)
The VME Register Access Image allows access to the Universe II registers with standard VMEbus
cycles. Only single cycle and lock AM codes are accepted. When a register is accessed with a RMW, it
is locked for the duration of the transaction.
Register name: VRAI_CTL
Bits
7
31:24
EN
23:16
Register offset: 0xF70
6
5
4
3
1
0
Reserved
PGM
SUPER
Reserved
15:08
Reserved
07:00
Reserved
Name
EN
2
Description
Image Enable
VAS
Type
Reset by
Reset value
R/W
PWR VME
Power-up
Option
R/W
PWR VME
11
R/W
PWR VME
11
R/W
PWR VME
Power-up
Option
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
VAS
VMEbus Address Space
00=A16
01=A24
10=A32
all others are reserved
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12. Registers > Register Description
12.3.104
VMEbus Register Access Image Base Address Register (VRAI_BS)
The base address specifies the lowest address in the 4 Kbyte VMEbus Register Access Image.
Register name: VRAI_BS
Register offset: 0xF74
Bits
Function
31:24
BS
23:16
BS
15:08
BS
Reserved
07:00
Reserved
Name
Description
Type
Reset by
Reset value
BS[31:12]
The base address specifies the lowest address in the 4 Kbyte
VMEbus Register Access Image.
R/W
PWR VME
Power-up
Option
The reset state is a function of the Power-up Option behavior of the VAS field in VRAI_CTL. Table 35
shows the behavior of the VAS field.
Table 35: Power-up Option Behavior of the VAS field in VRAI_CTL
VRAI_CTL: VAS
BS [31:24]
BS [23:16]
BS [15:12]
A16
0
0
Power-up Option
VA [28:25]
A24
0
Power-up Option
VA [28:21]
0
A32
Power-up Option
VA [28:21]
0
0
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�12. Registers > Register Description
12.3.105
305
VMEbus CSR Control Register (VCSR_CTL)
Register name: VCSR_CTL
Bits
7
31:24
EN
Register offset: 0xF80
6
5
4
3
1
Reserved
15:08
Reserved
07:00
Reserved
Name
0
Reserved
23:16
EN
2
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR,VME
0
R/W
PWR,VME
0
The EN bit is set to a value of 1 whenever a VME64 monarch
acquires the Status/ID vector for the level 2 interrupt during
VME64 Auto ID.
0=Disable
1=Enable
LAS
PCI Bus Address Space
00= PCI Bus Address Space
01= PCI Bus I/O Space
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12. Registers > Register Description
12.3.106
VMEbus CSR Translation Offset (VCSR_TO)
For CSR's not supported in the Universe II and for CR accesses, the translation offset is added to the
24-bit VMEbus address to produce a 32-bit PCI Bus address.
Register name: VCSR_TO
Bits
7
Register offset: 0xF84
6
5
31:24
4
3
2
1
0
TO
23:16
TO
Reserved
15:08
Reserved
07:00
Reserved
Name
Description
Type
Reset by
Reset value
TO [31:24]
Translation Offset
R/W
PWR VME
0
TO [23:19]
Translation Offset
R/W
PWR VME
Power-up
Option
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�12. Registers > Register Description
12.3.107
307
VMEbus AM Code Error Log (V_AMERR)
The Universe II VMEbus Master Interface is responsible for logging the parameters of a posted write
transaction that results in a bus error. This register holds the address modifier code and the state of the
IACK* signal. The register contents are qualified by the V_STAT bit.
Register name: V_AMERR
Bits
7
Register offset: 0xF88
6
5
31:24
23:16
4
3
AMERR
V_STAT
Reserved
07:00
Reserved
Name
IACK
M_ERR
1
0
IACK
M_ERR
Reserved
15:08
AMERR [5:0]
2
Description
Type
Reset by
Reset value
VMEbus AM Code Error Log
R
PWR, VME
0
VMEbus IACK Signal
R
PWR, VME
0
Multiple Error Occurred
R
PWR, VME
0
R/W
PWR, VME
0
0=Single error
1=At least one error has occurred since the logs were frozen
V_STAT
VME Error Log Status
Reads:
0=logs invalid
1=logs are valid and error logging halted
Writes:
0=no effect
1=clears V_STAT and enables error logging
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12. Registers > Register Description
12.3.108
VMEbus Address Error Log (VAERR)
The Universe II VMEbus Master Interface is responsible for logging the parameters of a posted write
transaction that results in a bus error. This register holds the address. The register contents are qualified
by the V_STAT bit of the V_AMERR register.
Register name: VAERR
Bits
7
Register offset: 0xF8C
6
5
4
3
31:24
VAERR
23:16
VAERR
15:08
VAERR
07:00
VAERR
Name
VAERR [31:1]
Description
VMEbus address error log
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2
1
0
Type
Reset by
Reset value
R
PWR, VME
0
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�12. Registers > Register Description
12.3.109
309
VMEbus Slave Image 4 Control (VSI4_CTL)
This register provides the general, VMEbus and PCI controls for this slave image. Note that only
transactions destined for PCI Memory space are decoupled (the posted write RXFIFO generates on
Memory space transactions on the PCI Bus). This image has 4 Kbyte resolution.
In order for a VMEbus slave image to respond to an incoming cycle, the BM bit in the PCI_CSR
register must be enabled.
The state of PWEN and PREN are ignored if LAS is not programmed memory space.
Register name: VSI4_CTL
Register offset: 0xF90
Bits
7
6
5
31:24
EN
PWEN
PREN
23:16
PGM
4
SUPER
1
0
Reserved
VAS
Reserved
LD64EN
LLRMW
Name
EN
2
Reserved
15:08
07:00
3
Reserved
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR, VME
0
R/W
PWR, VME
0
R/W
PWR, VME
0
R/W
PWR, VME
11
R/W
PWR, VME
11
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
PREN
Prefetch Read Enable
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
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12. Registers > Register Description
Name
VAS
Description
VMEbus Address Space
Type
Reset by
Reset value
R/W
PWR, VME
0
R/W
PWR, VME
0
R/W
PWR, VME
0
R/W
PWR, VME
0
000=A16
001=A24
010=A32
011= Reserved
100=Reserved
101=Reserved
110=User1
111=User2
LD64EN
Enable 64-bit PCI Bus Transactions
0=Disable
1=Enable
LLRMW
Enable PCI Bus Lock of VMEbus RMW
0=Disable
1=Enable
LAS
PCI Bus Address Space
00=PCI Bus Memory Space
01=PCI Bus I/O Space
10=PCI Bus Configuration Space
11=Reserved
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�12. Registers > Register Description
12.3.110
311
VMEbus Slave Image 4 Base Address Register (VSI4_BS)
The base address specifies the lowest address in the address range that is decoded.
This image has a 4 Kbyte resolution.
Register name: VSI4_BS
Register offset: 0xF94
Bits
Function
31:24
BS
23:16
BS
15:08
BS
07:00
Reserved
Reserved
Name
Description
Type
Reset by
Reset value
BS[31:12]
Base Address
R/W
PWR VME
0
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12. Registers > Register Description
12.3.111
VMEbus Slave Image 4 Bound Address Register (VSI4_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound register is 0, then the addresses decoded are those greater
than or equal to the base address.
This image has 4 Kbyte resolution.
Register name: VSI4_BD
Register offset: 0xF98
Bits
Function
31:24
BD
23:16
BD
15:08
BD
07:00
Reserved
Name
BD[31:12]
Reserved
Description
Bound Address
Universe II User Manual
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Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.112
313
VMEbus Slave Image 4 Translation Offset (VSI4_TO)
The translation offset is added to the source address that is decoded and this new address becomes the
destination address. If a negative offset is desired, the offset must be expressed as a two’s complement.
This image has 4 Kbyte resolution.
Register name: VSI4_TO
Register offset: 0xF9C
Bits
Function
31:24
TO
23:16
TO
15:08
TO
07:00
Reserved
Name
TO[31:12]
Reserved
Description
Translation Offset
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Type
Reset by
Reset value
R/W
PWR VME
0
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�314
12. Registers > Register Description
12.3.113
VMEbus Slave Image 5 Control (VSI5_CTL)
This register provides the general, VMEbus and PCI controls for this slave image. Note that only
transactions destined for PCI Memory space are decoupled (the posted write RXFIFO generates on
Memory space transactions on the PCI Bus).
In order for a VMEbus slave image to respond to an incoming cycle, the BM bit in the PCI_CSR
register must be enabled.
The state of PWEN and PREN are ignored if LAS is not programmed memory space.
Register name: VSI5_CTL
Register offset: 0xFA4
Bits
7
6
5
31:24
EN
PWEN
PREN
23:16
PGM
4
SUPER
1
0
Reserved
VAS
Reserved
LD64EN
LLRMW
Name
EN
2
Reserved
15:08
07:00
3
Reserved
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
11
R/W
PWR VME
11
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
PREN
Prefetch Read Enable
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
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�12. Registers > Register Description
Name
VAS
315
Description
VMEbus Address Space
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
000=Reserved
001=A24
010=A32
011= Reserved
100=Reserved
101=Reserved
110=User1
111=User2
LD64EN
Enable 64-bit PCI Bus Transactions
0=Disable
1=Enable
LLRMW
Enable PCI Bus Lock of VMEbus RMW
0=Disable
1=Enable
LAS
PCI Bus Address Space
00=PCI Bus Memory Space
01=PCI Bus I/O Space
10=PCI Bus Configuration Space
11=Reserved
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12. Registers > Register Description
12.3.114
VMEbus Slave Image 5 Base Address Register (VSI5_BS)
The base address specifies the lowest address in the address range that is decoded.
Register name: VSI5_BS
Register offset: 0xFA8
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS[31:16]
Description
Base Address
Universe II User Manual
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Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.115
317
VMEbus Slave Image 5 Bound Address Register (VSI5_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound register is 0, then the addresses decoded are those greater
than or equal to the base address.
Register name: VSI5_BD
Register offset: 0xFAC
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD[31:16]
Description
Bound Address
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Type
Reset by
Reset value
R/W
PWR VME
0
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�318
12. Registers > Register Description
12.3.116
VMEbus Slave Image 5 Translation Offset (VSI5_TO)
The translation offset is added to the source address that is decoded and this new address becomes the
destination address. If a negative offset is desired, the offset must be expressed as a two’s complement.
Register name: VSI5_TO
Register offset: 0xFB0
Bits
Function
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Name
TO[31:16]
Description
Translation Offset
Universe II User Manual
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Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.117
319
VMEbus Slave Image 6 Control (VSI6_CTL)
This register provides the general, VMEbus and PCI controls for this slave image. Note that only
transactions destined for PCI Memory space are decoupled (the posted write RXFIFO generates on
Memory space transactions on the PCI Bus).
In order for a VMEbus slave image to respond to an incoming cycle, the BM bit in the PCI_CSR
register must be enabled.
The state of PWEN and PREN are ignored if LAS is not programmed memory space.
Register name: VSI6_CTL
Register offset: 0xFB8
Bits
7
6
5
31:24
EN
PWEN
PREN
23:16
PGM
4
SUPER
1
0
Reserved
VAS
Reserved
LD64EN
LLRMW
Name
EN
2
Reserved
15:08
07:00
3
Reserved
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
11
R/W
PWR VME
11
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
PREN
Prefetch Read Enable
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
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�320
12. Registers > Register Description
Name
VAS
Description
VMEbus Address Space
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
000=Reserved
001=A24
010=A32
011= Reserved
100=Reserved
101=Reserved
110=User1
111=User2
LD64EN
Enable 64-bit PCI Bus Transactions
0=Disable
1=Enable
LLRMW
Enable PCI Bus Lock of VMEbus RMW
0=Disable
1=Enable
LAS
PCI Bus Address Space
00=PCI Bus Memory Space
01=PCI Bus I/O Space
10=PCI Bus Configuration Space
11=Reserved
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�12. Registers > Register Description
12.3.118
321
VMEbus Slave Image 6 Base Address Register (VSI6_BS)
The base address specifies the lowest address in the address range that is decoded.
Register name: VSI6_BS
Register offset: 0xFBC
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS[31:16]
Description
Base Address
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Type
Reset by
Reset value
R/W
PWR VME
0
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�322
12. Registers > Register Description
12.3.119
VMEbus Slave Image 6 Bound Address Register (VSI6_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound register is 0, then the addresses decoded are those greater
than or equal to the base address.
Register name: VSI6_BD
Register offset: 0xFC0
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD[31:16]
Description
Bound Address
Universe II User Manual
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Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.120
323
VMEbus Slave Image 6 Translation Offset (VSI6_TO)
The translation offset is added to the source address that is decoded and this new address becomes the
destination address. If a negative offset is desired, the offset must be expressed as a two’s complement.
Register name: VSI6_TO
Register offset: 0xFC4
Bits
Function
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Name
TO[31:16]
Description
Translation Offset
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Type
Reset by
Reset value
R/W
PWR VME
0
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�324
12. Registers > Register Description
12.3.121
VMEbus Slave Image 7 Control (VSI7_CTL)
This register provides the general, VMEbus and PCI controls for this slave image. Note that only
transactions destined for PCI Memory space are decoupled (the posted write RXFIFO generates on
Memory space transactions on the PCI Bus).
In order for a VMEbus slave image to respond to an incoming cycle, the BM bit in the PCI_CSR
register must be enabled.
The state of PWEN and PREN are ignored if LAS is not programmed memory space.
Register name: VSI7_CTL
Register offset: 0xFCC
Bits
7
6
5
31:24
EN
PWEN
PREN
23:16
PGM
4
SUPER
1
0
Reserved
VAS
Reserved
LD64EN
LLRMW
Name
EN
2
Reserved
15:08
07:00
3
Reserved
Description
Image Enable
LAS
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
11
R/W
PWR VME
11
0=Disable
1=Enable
PWEN
Posted Write Enable
0=Disable
1=Enable
PREN
Prefetch Read Enable
0=Disable
1=Enable
PGM
Program/Data AM Code
00=Reserved
01=Data
10=Program
11=Both
SUPER
Supervisor/User AM Code
00=Reserved
01=Non-Privileged
10=Supervisor
11=Both
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�12. Registers > Register Description
Name
VAS
325
Description
VMEbus Address Space
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
R/W
PWR VME
0
000=Reserved
001=A24
010=A32
011= Reserved
100=Reserved
101=Reserved
110=User1
111=User2
LD64EN
Enable 64-bit PCI Bus Transactions
0=Disable
1=Enable
LLRMW
Enable PCI Bus Lock of VMEbus RMW
0=Disable
1=Enable
LAS
PCI Bus Address Space
00=PCI Bus Memory Space
01=PCI Bus I/O Space
10=PCI Bus Configuration Space
11=Reserved
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�326
12. Registers > Register Description
12.3.122
VMEbus Slave Image 7 Base Address Register (VSI7_BS)
The base address specifies the lowest address in the address range that is decoded.
Register name: VSI7_BS
Register offset: 0xFD0
Bits
Function
31:24
BS
23:16
BS
15:08
Reserved
07:00
Reserved
Name
BS[31:16]
Description
Base Address
Universe II User Manual
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Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.123
327
VMEbus Slave Image 7 Bound Address Register (VSI7_BD)
The addresses decoded in a slave image are those which are greater than or equal to the base address
and less than the bound register. If the bound register is 0, then the addresses decoded are those greater
than or equal to the base address.
Register name: VSI7_BD
Register offset: 0xFD4
Bits
Function
31:24
BD
23:16
BD
15:08
Reserved
07:00
Reserved
Name
BD[31:16]
Description
Bound Address
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Type
Reset by
Reset value
R/W
PWR VME
0
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�328
12. Registers > Register Description
12.3.124
VMEbus Slave Image 7 Translation Offset (VSI7_TO)
Register name: VSI7_TO
Register offset: 0xFD8
Bits
Function
31:24
TO
23:16
TO
15:08
Reserved
07:00
Reserved
Name
TO[31:16]
Description
Translation Offset
Universe II User Manual
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Type
Reset by
Reset value
R/W
PWR VME
0
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�12. Registers > Register Description
12.3.125
329
VMEbus CSR Bit Clear Register (VCSR_CLR)
This register implements the Bit Clear Register as defined in the VME64 Specification. The RESET bit
must be written to only from the VMEbus.
Register name: VCSR_CLR
Register offset: 0xFF4
Bits
7
6
5
31:24
RESET
SYSFAIL
FAIL
4
3
Reserved
15:08
Reserved
07:00
Reserved
RESET
Description
Board Reset
1
0
Reserved
23:16
Name
2
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
all
Power-up
Option
R
PWR VME
0
Reads:
0=LRST_ not asserted
1=LRST_ asserted
Writes:
0=no effect
1=negate LRST_
SYSFAIL
VMEbus SYSFAIL
Reads:
0=VXSYSFAIL not asserted
1=VXSYSFAIL asserted
Writes:
0=no effect
1=negate VXSYSFAIL
FAIL
Board Fail
0=Board has not failed
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�330
12. Registers > Register Description
12.3.126
VMEbus CSR Bit Set Register (VCSR_SET)
This register implements the Bit Set Register as defined in the VME64 Specification. The RESET bit
must be written to only from the VMEbus. Writing 1 to the RESET bit asserts LRST_. The PCI reset
remains asserted until a 1 is written to the RESET bit of the VCSR_CLR register.
Register name: VCSR_SET
Register offset: 0xFF8
Bits
7
6
5
31:24
RESET
SYSFAIL
FAIL
4
3
Reserved
15:08
Reserved
07:00
Reserved
RESET
Description
Board Reset
1
0
Reserved
23:16
Name
2
Type
Reset by
Reset value
R/W
PWR VME
0
R/W
all
Power-up
Option
R
PWR VME
0
Reads:
0=LRST_ not asserted
1=LRST_ asserted
Writes:
0=no effect
1=assert LRST_
SYSFAIL
VMEbus SYSFAIL
Reads:
0=VXSYSFAIL not asserted
1=VXSYSFAIL asserted
Writes:
0=no effect
1=assert VXSYSFAIL
FAIL
Board Fail
0=Board has not failed
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�12. Registers > Register Description
12.3.127
331
VMEbus CSR Base Address Register (VCSR_BS)
The base address specifies one of 31 available CR/CSR windows as defined in the VME64
Specification. Each window consumes 512 Kbytes of CR/CSR space.
Register name: VCSR_BS
Bits
7
31:24
Register offset: 0xFFC
6
5
4
3
BS
Reserved
15:08
Reserved
07:00
Reserved
Name
1
0
Reserved
23:16
BS [23:19]
2
Description
Base Address
Type
Reset by
Reset value
R/W
PWR VME
0
VCSR_BS register is accessed with an 8-bit transfer.
Bits [31:27] of the register are compared with address lines [23:19].
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A.
Packaging Information
This appendix discusses the following topics:
•
A.1
“313 Pin PBGA Package” on page 333
313 Pin PBGA Package
Figure 25: 313 PBGA - Bottom View
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A. Packaging Information > 313 Pin PBGA Package
Figure 26: 313 PBGA - Top and Side View
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B.
Performance
This chapter discusses the following topics:
B.1
•
“PCI Slave Channel” on page 336
•
“VME Slave Channel” on page 340
•
“Decoupled Cycles” on page 342
•
“DMA Channel and Relative FIFO Sizes” on page 347
•
“Universe II Specific Register” on page 350
•
“Performance Summary” on page 352
Overview
As a VMEbus bridge, the Universe II's most important function is data transfer. This function is
performed by its three channels: the PCI Slave Channel, the VME Slave Channel, and the DMA
Channel. Since each channel operates independently of the others and because each has its own unique
characteristics, the following analysis reviews the data transfer performance for each channel:
•
“PCI Slave Channel” on page 336
•
“VME Slave Channel” on page 340
•
“DMA Channel and Relative FIFO Sizes” on page 347
•
“Performance Summary” on page 352
Where relevant, descriptions of factors affecting performance and how they might be controlled in
different environments are discussed.
The decoupled nature of the Universe II can cause some confusion in discussing performance
parameters. This is because, in a fully decoupled bus bridge each of the two opposing buses
operates at its peak performance independently of the other. The Universe II, however, because of
the finite size of its FIFOs does not represent a 100% decoupled bridge. As the FIFOs fill or empty
(depending on the direction of data movement) the two buses tend to migrate to matched
performance where the higher performing bus is forced to slow down to match the other bus. This
limits the sustained performance of the device. Some factors such as the PCI Aligned Burst Size
and VME request/release modes can limit the effect of FIFO size and enhance performance.
Another aspect in considering the performance of a device is bandwidth consumption. The greater
bandwidth consumed to transfer a given amount of data, the less is available for other bus masters.
Decoupling significantly improves the Universe II's bandwidth consumption, and on the PCI bus
allows it to use the minimum permitted by the PCI specification.
To simplify the analysis and allow comparison with other devices, Universe II performance has
been calculated using the following assumptions:
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B. Performance > PCI Slave Channel
•
As a PCI master:
— one clock bus grant latency
— zero wait state PCI target
•
As a VME master:
— ideal VME slave response (DS* to DTACK* = 30ns)
Assumed as part of any calculation on VME performance is the inclusion of VME transceivers with
propagation delay of 4 ns.
This appendix presents sustained performance values. In contrast, the original Universe User Manual
(9000000.MD303.01) provided peak performance numbers. This explains why some of the
performance numbers in this document appear to be lower than for the original Universe.
B.2
PCI Slave Channel
This channel supports both coupled and decoupled transactions. Each type of transaction, and the
performance of each, are discussed in the following sections.
B.2.1
Coupled Cycles
The Universe II has a Coupled Window Timer (CWT in the LMISC register) which permits the
coupled channel to maintain ownership of the VMEbus for an extended period beyond the completion
of a cycle. This permits subsequent coupled accesses to the VMEbus to occur back-to-back without
requirement for re-arbitration.
B.2.1.1
Request of VMEbus
The CWT should be set for the expected latency between sequential coupled accesses attempted by the
CPU. In calculating the latency expected here, the designer needs to account for latency across their
host PCI bridge as well as latency encountered in re-arbitration for the PCI bus between each coupled
access. Care must be taken not to set the CWT greater than necessary as the Universe II blocks all
decoupled write transactions with target-retry, while the coupled channel owns the VMEbus. It is only
when the CWT has expired that the PCI bus is permitted to enqueue transactions in the TXFIFO.
When a coupled access to the VMEbus is attempted, the Universe II generates a target-retry to the PCI
initiator if the coupled path does not currently own the VMEbus. This occurs if the Universe II is not
currently VMEbus master, or if the DMA is currently VMEbus master or if entries exist in the
TXFIFO.
If the Universe II does not have ownership of the VMEbus when a coupled access is attempted, the
Universe II generates a target-retry with a single wait state (See Figure 27). The request for the
VMEbus occurs shortly after the cycle is retried.
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B.2.1.2
337
Read Cycles
Once the coupled channel owns the VMEbus, the Universe II propagates the cycle out to the VMEbus.
Figure 27 shows such a coupled read cycle against an ideal VME slave. There are 10 wait states
inserted by the Universe II on the PCI bus before it responds with TRDY_. Further wait states are
inserted for each extra 30ns in slave response.
Performing 32-bit PCI reads from VME gives a sustained performance of approximately 8.5 MB/s.
Figure 28 shows several of these accesses occurring consecutively.
Figure 27: Coupled Read Cycle - Universe II as VME Master
VMEbus
A[31:1]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
PCI
CLK
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
Figure 28: Several Coupled Read Cycles - Universe II as VME Master
VMEbus
A[31:1]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
PCI
CLK
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
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B. Performance > PCI Slave Channel
B.2.1.3
Write Cycles
The performance of coupled write cycles is similar to that of coupled read cycles except that an extra
wait state is inserted. Figure 29 shows a coupled write cycle against an ideal VME slave. Ten wait
states are inserted on the PCI bus by the Universe II before it responds with TRDY_. A slower VME
slave response translates directly to more wait states on the PCI bus.
The sustained performance, when generating write cycles from a 32-bit PCI bus against an ideal VME
slave is approximately 9.3 MB/s.
Figure 29: Coupled Write Cycle - Universe II as VME Master
VMEbus
A[31:1]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
PCI
CLK
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
B.2.2
Decoupled Cycles
Only write transactions can be decoupled in the PCI Target Channel.
B.2.2.1
Effect of the PWON Counter
The Posted Write On Counter (PWON in the MAST_CTL register) controls the maximum tenure that
the PCI Slave Channel will have on the VMEbus. Once this channel has gained ownership of the
VMEbus for use by the TXFIFO, it only relinquishes it if the FIFO becomes empty or if the number of
bytes programmed in the counter expires. In most situations, the FIFO empties before the counter
expires. However, if a great deal of data is being transferred by a PCI initiator to the VMEbus, then this
counter ensures that only a fixed amount of VME bandwidth is consumed.
Limiting the size of the PWON counter imposes greater arbitration overhead on data being transferred
out from the FIFO. This is true even when programmed for ROR mode since an internal arbitration
cycle will still occur. The value for the PWON counter must be weighed from the system perspective
with the impact of imposing greater latency on other channels (the DMA and Interrupt Channels) and
other VME masters in gaining ownership of the VMEbus. On a Universe II equipped card which is
only performing system control functions, the counter would be set to minimum. On a card which is
responsible for transferring considerable amounts of performance-critical data the counter will be set
much higher at the expense of system latency.
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B.2.2.2
339
PCI Target Response
As the PCI target during decoupled write operations to the VMEbus, the Universe II responds in one of
two manners:
1. It immediately issues a target retry because the FIFO does not have sufficient room for a burst of
one address phase and 128 bytes of data. (There are no programmable watermarks in the PCI
Target Channel. The PCI Aligned Burst Size (PABS) does not affect the PCI Target Channel.)
2. It responds as a zero-wait state target receiving up to 256 bytes in a transaction. When the FIFO is
full or a 256-byte boundary has been reached, the Universe II issues a Target-Disconnect.
In either case, the Universe II will consume the minimum possible PCI bandwidth, never inserting wait
states.
B.2.2.3
VME Master Performance
As a VME master, the Universe II waits until a full transaction has been enqueued in the Tx-FIFO
before requesting the VMEbus and generating a VME cycle. If the VMEbus is already owned by the
decoupled path (see “Effect of the PWON Counter” on page -338), the Universe II still waits until a
full transaction is enqueued in the FIFO before processing it.
If configured to generate non-block transfers, the Universe II can generate back-to-back VME transfers
with cycle times of approximately 180ns (AS* to AS*) against an ideal VME slave (30-45 ns). A
greater cycle time is required between the termination of one full enqueued transaction and the start of
the next. This inter-transaction time is approximately 210ns. As such, the longer the PCI transaction,
the greater the sustained performance on the VMEbus. With 64-byte PCI transactions, the sustained
rate is 43 MB/s. With 32-byte transactions, this drops to 23 MB/s. Each of these numbers is calculated
with no initial arbitration or re-arbitration for the bus. Figure 30 shows the Universe II queueing a
transaction with multiple non-block VME transfers.
Block transfers significantly increase performance. The inter-transaction period remains at
approximately 210 ns for BLTs and MBLTs, but the data beat cycle time (DS* to DS*) drops to about
120ns against the same ideal slave. Again the length of the burst size affects the sustained performance
because of the inter-transaction time. For BLTs operating with a burst size of 64 bytes, the sustained
performance is 37 MB/s, dropping to 33 MB/s for a burst size of 32 bytes. MBLTs operating with
64-byte bursts perform at a sustained rate of 66 MB/s, dropping to 50 MB/s for 32 bytes.
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B. Performance > VME Slave Channel
Figure 30: Several Non-Block Decoupled Writes - Universe II as VME Master
VMEbus
A[31:1]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
Figure 31: BLT Decoupled Write - Universe II as VME Master
VMEbus
A[31:1]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
B.3
VME Slave Channel
This channel supports both coupled and decoupled transactions. Each type of transaction, and the
performance of each, are discussed in the following sections.
B.3.1
Coupled Cycles
The Universe II VME Slave Channel handles both block and non-block coupled accesses in similar
manners. Each data beat is translated to a single PCI transaction. Once the transaction has been
acknowledged on the PCI bus, the Universe II asserts DTACK* to terminate the VME data beat.
B.3.1.1
Block vs. non-Block Transfers
A non-block transfer and the first beat of a BLT transfer have identical timing. In each, the Universe II
decodes the access and then provides a response to the data beat. Subsequent data beats in the BLT
transfer are shorter than the first due to the fact that no address decoding need be performed in these
beats.
MBLT transfers behave somewhat differently. The first beat of an MBLT transfer is address only, and
so the response is relatively fast. Subsequent data beats require acknowledgment from the PCI bus.
With a 32-bit PCI bus, the MBLT data beat (64 bits of data) requires a two data beat PCI transaction.
Because of this extra data beat required on the PCI bus, the slave response of the Universe II during
coupled MBLT cycles is at least one PCI clock greater (depending upon the response from the PCI
target) than that during BLT cycles.
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B.3.1.2
341
Read Cycles
During coupled cycles, the Universe II does not acknowledge a VME transaction until it has been
acknowledged on the PCI bus. Because of this the VME slave response during coupled reads is directly
linked to the response time for the PCI target. Each clock of latency in the PCI target response
translates directly to an extra clock of latency in the Universe II's VME coupled slave response.
The address of an incoming VME transaction is decoded and translated to an equivalent PCI
transaction. Typically, four PCI clock periods elapse between the initial assertion of AS* on the
VMEbus and the assertion of REQ_ on the PCI bus. During the data only portion of subsequent beats
in block transfers, the time from DS* assertion to REQ_ is about 4 clocks. If the PCI bus is parked at
the Universe II, no REQ_ is asserted and FRAME_ is asserted 4 clocks after AS*.
From assertion of REQ_, the Universe II does not insert any extra wait states in its operations as an
initiator on the PCI bus. Upon receiving GNT_ asserted, the Universe II asserts FRAME_ in the next
clock and after the required turn-around phase, asserts IRDY_ to begin data transfer.
Once TRDY_ is sampled asserted, the Universe II responds back to the VMEbus by asserting
DTACK*. If the initiating VME transaction is 64-bit and the PCI bus or PCI bus target are 32 bit, then
two data transfers are required on PCI before the Universe II can respond with DTACK*. No wait
states are inserted by the
Universe II between these two data beats on PCI. The assertion of DTACK* from the assertion of
TRDY_ has a latency of 1 clock. Figure 32 shows a typical non-block coupled read cycle.
When accessing a PCI target with a zero wait state response, the Universe II VME response becomes
approximately 10 PCI clock periods (about 301ns in a 33MHz system) during single cycles, and the
first beat of a BLT. During pure data beats in both BLT and MBLTs, the slave response becomes 8
clocks.
Figure 32: Coupled Read Cycle - Universe II as VME Slave
VMEbus
A[31:1]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
PCI
CLK
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
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B. Performance > VME Slave Channel
B.3.1.3
Write Cycles
Coupled writes in the VME Slave Channel operate in a similar fashion to the coupled reads. The VME
slave response is directly linked to the response of the PCI target. In generating the request to the PCI
bus, coupled write cycles require one further clock over reads. Hence, during single cycles, or the first
beat of a BLT, the time from AS* to REQ_ asserted is 3-4 PCI clocks, while DS* to REQ_ is 3 clocks
for the data beat portion of a block transfer. If the PCI bus is parked at the
Universe II, REQ_ is not asserted and the transaction begins immediately with assertion of FRAME_.
As with reads, the response from the PCI target's assertion of TRDY_ to DTACK* assertion by the
Universe II adds one clock to the transfer. Figure 33 shows a typical non-block coupled write cycle.
Because write cycles on the PCI bus require one less clock than reads, due to the absence of the
turn-around phase between address and data phases, the overall slave response during coupled writes
works out to the same as coupled reads against an identical target. In accessing a zero-wait state PCI
target, the Universe II's coupled write slave response then is approximately 10 PCI clocks. During
subsequent data beats of a block transfer (either BLT or MBLT), the slave response (DS* to DTACK*)
is 8 clocks.
Figure 33: Coupled Write Cycle - Universe II as VME Slave (bus parked at Universe II)
VMEbus
A[31:1]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
PCI
CLK
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
B.3.2
Decoupled Cycles
B.3.2.1
Write Cycles
Effect of the PCI Aligned Burst Size
The PCI Aligned Burst Size (PABS in the MAST_CTL register) affects the maximum burst size that
the Universe II generates onto the PCI bus; either 32, 64, or 128 bytes. Note that the VME Slave
Channel only generates PCI bursts in response to incoming block transfers.
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The greater burst size means less arbitration and addressing overhead. However, incumbent in this is
the greater average latency for other devices in the PCI system. Hence, in the VME Slave Channel, the
burst size is a trade-off between performance and latency.
VME Slave Response
As a VME slave, the Universe II accepts data into its RXFIFO with minimum delay provided there is
room in the FIFO for a further data beat. Assertion of DTACK* is delayed if there is insufficient room
in the FIFO for the next data beat.
During non-block transfers, the Universe II must both decode the address and enqueue the data before
asserting DTACK* to acknowledge the transfer. Because of this, the slave response during non-block
transfers is considerably slower than block transfers. This slave response time is 127ns.
During BLT transfers, the slave response in the first data beat being both address decode and data
transfer is the same as a non-block transfer, i.e., 127ns. Subsequent data beats, however, are much
faster. Response time for these is 50 to 56ns.
During MBLT transfers, the first phase is address only and the slave response is 127ns. Subsequent
phases are data only and so the slave response is the same as with BLTs i.e., 50 to 56ns.
Note that the slave response is independent of the data size. D16 non-block transfers have a slave
response identical to D32. BLT data beats have slave responses identical to MBLT data beats.
Figure 34: Non-Block Decoupled Write Cycle - Universe II as VME Slave
VMEbus
A[31:1]
AM[5:0]
LWORD*
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
PCI
CLK
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
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B. Performance > VME Slave Channel
Figure 35: BLT Decoupled Write Cycle - Universe II as VME Slave
VMEbus
A[31:1]
AM[5:0]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
PCI
CLK
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
Figure 36: MBLT Decoupled Write Cycle - Universe II as VME Slave
VMEbus
A[31:1]
AM[5:0]
AS*
D[31:0]
WRITE*
DS0*
DS1*
DTACK*
PCI
CLK
REQ#
GNT#
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
PCI Master Performance
The Universe II supports bus parking. If the Universe II requires the PCI bus it will assert REQ_ only if
its GNT_ is not currently asserted. When the PCI Master Module is ready to begin a transaction and its
GNT_ is asserted, the transfer begins immediately. This eliminates a possible one clock cycle delay
before beginning a transaction on the PCI bus which would exist if the Universe II did not implement
bus parking. Bus parking is described in Section 3.4.3 of the PCI Specification (Rev. 2.1).
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345
On the PCI bus, the Universe II deliquesce data from the RXFIFO once a complete VME transaction
has been enqueued or once sufficient data has been enqueued to form a PCI transaction of length
defined by the PABS field.
Since the Universe II does not perform any address phase deletion, non-block transfers are decreed
from the RXFIFO as single data beat transactions. Only block transfers result in multi-data beat PCI
transactions; typically 8, 16 or 32 data beats. In either case, the Universe II does not insert any wait
states as a PCI master. The clock, after the bus has been granted to the Universe II, drives out FRAME_
to generate the address phase. The data phases begin immediately on the next clock. If there is more
than one data phase, each phase will immediately follow the acknowledgment of the previous phase.
In each case, because of the lack of any wait states as a PCI master, the Universe II is consuming the
minimum possible bandwidth on the PCI bus, and data will be written to the PCI bus at an average
sustained rate equal to the rate at which the VME master is capable of writing it.
The sustained performance on the PCI bus performing single data beat write transactions to a 32-bit
PCI bus is 15 MB/s; double this for a 64-bit bus. When performing 32-byte transactions the sustained
performance increases to 106 MB/s; 120 MB/s with 64-byte transactions. Again, these can be doubled
for a 64-bit PCI bus. Bear in mind that the PCI bus can only dequeue data as fast as it is being enqueued
on the VMEbus. Hence, as the RXFIFO empties, the sustained performance on the PCI will drop down
to match the lower performance on the VME side. However, even with the decreased sustained
performance, the consumed bandwidth will remain constant (no extra wait states are inserted while the
Universe II is master of the PCI bus.)
These numbers assume the PCI bus is granted to the Universe II immediately and that the writes are to
a zero-wait state PCI target capable of accepting the full burst length. Figure 27 through Figure 36
show the Universe II responding to non-block, BLT and MBLT write transactions to a 32-bit PCI bus.
Even better performance is obtained with PCI bus parking.
B.3.2.2
Prefetched Read Cycles
To minimize its slave response, the Universe II generates prefetched reads to the PCI bus in response to
BLT and MBLT reads coming in from the VMEbus. This option must first be enabled on a per image
basis.
When enabled, the Universe II will respond to a block read by performing burst reads on the PCI bus of
length defined by the PCI Aligned Burst Size (PABS in the MAST_CTL register). These burst reads
continue while the block transfer is still active on the VMEbus (AS* not negated) and there is room in
the RDFIFO. If there is insufficient room in the RDFIFO to continue (a common occurrence since the
Universe II is capable of fetching data from the PCI bus at a much faster rate than a VME master is
capable of receiving it), then pre-fetching stops and only continues once enough room exists in the
RDFIFO for another full burst size.
The first data beat of a block transfer must wait for the first data beat to be retrieved from the PCI
bus—this is essentially a coupled transfer. See the section on coupled transfers for details on coupled
performance. However, once the pre-fetching begins, data is provided by the Universe II in subsequent
data beats with a slave response of 57ns. This continues while there is data in the RDFIFO. If the
RDFIFO empties because data is being fetched from the PCI bus too slowly, wait states are inserted on
the VMEbus awaiting the enqueueing of more data.
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B. Performance > VME Slave Channel
On the PCI bus, the Universe II fetches data at 89 MB/s with PABS set to 32-byte transactions; 106
MB/s when set to 64-byte transactions. Even better performance is obtained if PABS is set for 128-byte
transactions. Once the RDFIFO fills, pre-fetching slows to match the rate at which it is being read by
the external VMEbus master. Bandwidth consumption, however, remains constant, only the idle time
between transactions increases.
Figure 37: BLT Pre-fetched Read Cycle - Universe II as VME Slave
Cursor1 = 16,600.88 ns
Cursor2 = 18,345.94 ns
16,600.88
17,000
17,500
18,000
18,345.94 ns
Group: A
Group: VME
Va[31:0] = 'h zzzzzzzz
vam[5:0] = 'h 3F 3F
Vas = z
Vd[31:0] = 'h zzzzzzzz
vwrite = 1
Vds0 = z
Vds1 = z
Vdtack = z
FFF41000
0B
0*
xxxxxxxx
5D1*
0B
0B
*
*
*
*
5*
*
*
*
*
*
3F
Group: PCI
pclk = 1
reqnn[0] = 1
gntnn[0] = 1
framenn = 1
ad_low[31:0] = 'h A5A5A5A5 A5A5A5A5
cxbenn_low[3:0] = 'h 5 5
irdynn = 1
trdynn = 1
stopnn = 1
devselnn = 1
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0
0004107C
C
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B.4
347
DMA Channel and Relative FIFO Sizes
Two fixed “watermarks” in the DMA Channel control the Universe’s II requisition of the PCI bus and
VMEbus. The DMAFIFO PCI Watermark is 128 bytes. This means that during reads from the PCI bus,
the Universe II will wait for 128 bytes to be free in the DMAFIFO before requesting the PCI bus. For
PCI writes, the Universe II waits for 128 bytes of data to be in the FIFO before requesting the PCI bus.
The DMAFIFO VMEbus watermark is 64 bytes. This means that during reads from the VMEbus, the
Universe II will wait for 64 bytes to be free in the DMAFIFO before requesting the Vmebus. For
VMEbus writes, the Universe II waits for 64 bytes of data to be in the FIFO before requesting the
VMEbus.
These watermarks have been tailored for the relative speeds of each bus, and provide near optimal use
of the DMA channel.
B.4.1
VMEbus Ownership Modes
The DMA has two counters that control its access to the VMEbus: the VON (VMEbus On) counter and
the VOFF (VMEbus Off) timer. The VON counter controls the number of bytes that are transferred by
the DMA during any VMEbus tenure, while the VOFF timer controls the period before the next request
after a VON time-out.
While the bus is more optimally shared between various masters in the system, and average latency
drops as the value programmed for the VON counter drops, the sustained performance of the DMA
also drops. The DMA is typically limited by its performance on the VMEbus. As this drops off with
greater re-arbitration cycles, the average VMEbus throughput will drop. Even if the Universe II is
programmed for ROR mode, and no other channels or masters are requesting the bus, there will be a
period of time during which the DMA will pause its transfers on the bus, due to the VON counter
expiring.
An important point to consider when programming these timers is the more often the DMA
relinquishes its ownership of the bus, the more frequently the PCI Slave Channel will have access to
the VMEbus. If DMA tenure is too long, the TXFIFO may fill up causing any further accesses to the
bus to be retried. In the same fashion, all coupled accesses will be retried while the DMA has tenure on
the bus. This can significantly affect transfer latency and should be considered when calculating the
overall system latency.
B.4.2
VME Transfers
On the VMEbus, the Universe II can perform D08 through D64 transactions in either block or
non-block mode. The time to perform a single beat, however, is independent of the bus width being
used. Hence, a D08 transaction will transfer data at 25% the rate of a D32, which in turn is half that for
D64.
There is a significant difference between the performance for block vs. non-block operations. Because
of the extra addressing required for each data transfer in non-block operations, the DMA performance
is about half that compared to operating in block mode. Moreover, considering that most VME slaves
respond less quickly in non-block mode, the overall performance may drop to one-quarter of that
achievable in block mode.
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B. Performance > DMA Channel and Relative FIFO Sizes
When programmed for Release-When-Done operation, the Universe II will perform an early release of
BBSY* when the VON counter reaches its programmed limit. This gives other masters a chance to use
the VMEbus (and possibly access the VME Slave Channel), but may decrease performance of the
DMA Channel; this factor may also play in favor of the DMA Channel, by pausing the PCI Target
Channel’s use of the VMEbus.
B.4.2.1
Read Transfers
When performing non-block reads on the VMEbus, the Universe II cycle time (AS* to next AS*) is
approximately 209ns, which translates to about 20 MB/s when performing D32 transfers. For block
transfers the cycle time (DS* to next DS*) falls to about 156ns, or 25 MB/s for D32 transfers. For
multiplexed block transfers (MBLTs) the cycle time remains the same, but because the data width
doubles, the transfer rate increases to about 50MB/s.
B.4.2.2
Write Transfers
Non-block writes to the VMEbus occur at 180ns cycle time (AS* to next AS*), or 23MB/s during D32
transfers. Block writes, however, are significantly faster with a 116ns cycle time (DS* to next DS*), or
36 MB/s. Multiplexed block transfers have slightly longer cycle times at about 112ns (DS* to next
DS*), or 62 MB/s with D64 MBLTs.
B.4.3
PCI Transfers
As a master on the PCI bus, the Universe II DMA follows the same general set of rules as the VME
Slave channel does: it never inserts any wait states into the transfer (i.e., it never negates IRDY_ until
the transaction is complete) and will whenever possible, generate full aligned bursts as set in the PABS
field of the MAST_CTL register.
Between transactions on the PCI bus, the Universe II DMA typically sits idle for 6 clocks. Hence,
minimizing the number of idle periods and re-arbitration times by setting PABS to its maximum value
of 128 bytes may increase the performance of the DMA on this bus. Higher PABS values imply that the
Universe II will hold on to both the PCI bus and the VMEbus for longer periods of time. The reason
that PABS also may impact on VMEbus tenure is that (in the case of PCI writes), the DMA FIFO is less
likely to fill, and (in the case of PCI reads) the DMA is less likely to go empty. However, given the
relative speeds of the buses, and the relative watermarks, the effect of PABS on VMEbus utilization is
not as significant as its effects on the PCI bus.
While higher values of PABS increase DMA throughput, they may increase system latency. That is,
there will be a longer latency for other PCI transactions, including possible transactions coming
through the VME Slave Channel (since the DMA channel will own the PCI bus for longer periods of
time). Also, accesses between other PCI peripherals will, on average, have a longer wait before being
allowed to perform their transactions. PCI latency must be traded off against possible DMA
performance.
Although both read and write transactions occur on the PCI bus with zero wait states, there is a period
of six PCI clocks during which the Universe II remains idle before re-requesting the bus for the next
transaction. PCI bus parking may be used to eliminate the need for re-arbitration.
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With PABS set for 32-byte transactions on a 32-bit PCI bus, this translates to a peak transfer rate of 97
MB/s for reads (including pre-fetching), 98 MB/s for writes, doubling to 194 and 196 for a 64-bit PCI
bus. With PABS set for 64-byte transactions, the peak transfer rate increases to 118 MB/s for reads, 125
MB/s for writes on a 32-bit PCI bus—236 MB/s and 250 MB/s respectively for 64-bit PCI buses. The
numbers for writes to PCI assume that data are read from VME using BLTs.
Figure 38: PCI Read Transactions During DMA Operation
PCI
CLK
REQ#
GNT#
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
Figure 39: Multiple PCI Read Transactions During DMA Operation
PCI
CLK
REQ#
GNT#
FRAME#
AD[31:0]
C/BE[3:0]
IRDY#
TRDY#
STOP#
DEVSEL#
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B.5
B. Performance > Universe II Specific Register
Universe II Specific Register
The Universe II Specific Register, U2SPEC, offset 0x4FC, can be used to improve the performance of
the Universe II by reducing the latency of key VMEbus timing elements. This register is present in
versions of the Universe device which have a Revision ID of 01or 02 — defined in the PCI_CLASS
register, offset 008.
B.5.1
Overview of the U2SPEC Register
Although the VMEbus is asynchronous, there are a number of maximum and minimum timing
parameters which must be followed. These requirements are detailed in the VME64 Specification.
In order to qualify as compliant the master, slave and location monitor devices must guarantee they
meet these timing parameters independent of their surroundings. They must assume zero latency
between themselves and the VMEbus. This, in practice, is never the case. Buffers, transceivers and the
backplane itself, all introduce latencies that combine to produce additional system delay. The
consequence of such delay is the degradation of overall performance.
The Universe II’s U2SPEC register enables users to compensate for the latencies which are inherent to
their VMEbus system designs. Through the use of this register, users can reduce the inherent delay
associated with five key VMEbus timing parameters.
Use of the U2SPEC register may result in violation of the VME64 Specification.
B.5.2
Adjustable VME Timing Parameters
B.5.2.1
VME DTACK* Inactive Filter (DTKFLTR)
In order to overcome the DTACK* noise typical of most VME systems, the Universe II quadruple
samples this signal with the 64 MHz clock. The extra sampling is a precaution that results in decreased
performance. Users who believe their systems to have little noise on their DTACK* lines can elect to
filter this signal less, and therefore increase their Universe II response time.
B.5.2.2
VME Master Parameter t11 Control (MASt11)
According to the VME64 Specification, a VMEbus master must not drive DS0* low until both it and
DS1* have been simultaneously high for a minimum of 40 ns. The MASt11 parameter in the U2SPEC
register, however, allows DS0* to be driven low in less than 40 ns.
B.5.2.3
VME Master Parameter t27 Control (READt27)
During read cycles, the VMEbus master must guarantee the data lines are valid within 25 ns after
DTACK* is asserted. The master must not latch the data and terminate the cycle for a minimum of
25 ns after the falling edge of DTACK*.
The READt27 parameter in the U2SPEC register supports faster cycle termination with one of two
settings. One setting allows data to be latched and the cycle terminated with an associated delay that is
less than 25 ns. The second setting results in no delay in latching and termination.
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B.5.2.4
351
VME Slave Parameter t28 Control (POSt28)
According to the VME64 Specification, VMEbus slaves must wait at least 30 ns after the assertion of
DS* before driving DTACK* low. When the Universe II is acting as a VME slave, the POSt28
parameter in the U2SPEC register enables DTACK* to be asserted in less than 30 ns when executing
posted writes.
B.5.2.5
VME Slave Parameter t28 Control (PREt28)
VMEbus slaves must wait at least 30ns after the assertion of DS* before driving DTACK* low. When
the Universe II is acting as a VME slave in the transaction, PREt28 parameter in the U2SPEC register
enables DTACK* to be asserted in less than 30 ns when executing pre-fetched reads.
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B.6
B. Performance > Performance Summary
Performance Summary
Table 36: PCI Slave Channel Performance
Cycle Type
Performance
Coupled Read
— PCI target response
8 PCI clocks
Coupled Write
— PCI target response
9 PCI clocks
Decoupled Write:
Non-block D32
— VME cycle time
180 ns
— sustained perf (32-byte PABS)
23 Mbytes/s
— sustained perf (64-byte PABS)
43 Mbytes/s
D32 BLT
— VME cycle time
— sustained perf (32-byte PABS)
119 ns
— sustained perf (64-byte PABS)
32 Mbytes/s
35 Mbytes/s
D64 MBLT
— VME cycle time
— sustained performance (32-byte PABS)
119 ns
— sustained perf (64-byte PABS)
53 Mbytes/s
59 Mbytes/s
Table 37: VME Slave Channel Performance
Performance
Cycle Type
VME Slave Response (ns)
Coupled Read
— non-block
301
— D32 BLT
293
— D64 BLT
322
Coupled Write
— non-block
278
— D32 BLT
264
— D64 BLT
292
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Table 37: VME Slave Channel Performance
Performance
Cycle Type
VME Slave Response (ns)
Pre-fetched Read
— VME slave response (1st data beat)
293
— VME slave response (other data beats)
57
Decoupled Write
— non-block slave response
127
— block slave response (1st data beat)
127
— block slave response (other data beats)
50
Table 38: DMA Channel Performance
Cycle Type
Performance Mbytes/s
PCI Reads
— 32-byte PABS
97 (194)a
— 64byte PABS
118 (236)
PCI Writes
— 32-byte PABS
98 (196)
— 64byte PABS
125 (250)
VME Reads
— non-block D32
18
— D32 BLT
22
— D64 MBLT
45
VME Writes
— non-block D32
22
— D32 BLT
32
— D64 MBLT
65
a. 64-bit PCI performance in brackets.
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C.
Reliability Prediction
This appendix discusses the following topics:
C.1
•
“Physical Characteristics” on page 355
•
“Thermal Characteristics” on page 356
•
“Universe II Ambient Operating Calculations” on page 357
•
“Thermal Vias” on page 358
Overview
This section is designed to help the user to estimate the inherent reliability of the Universe II. The
information serves as a guide only; meaningful results will be obtained only through careful
consideration of the device, its operating environment, and its application.
C.2
Physical Characteristics
•
CMOS gate array
•
120,000 two-input NAND gate equivalence
•
0.5 µm feature size
•
309 mils x 309 mils scribed die size
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C.3
C. Reliability Prediction > Thermal Characteristics
Thermal Characteristics
•
Idle power consumption: 1.50 Watts
•
Typical power consumption* (32-bit PCI): 2.00 Watts
•
Maximum power consumption (32-bit PCI): 2.70 Watts
•
Typical power consumption (64-bit PCI): 2.20 Watts
•
Maximum power consumption (64-bit PCI): 3.20 Watts
Maximum power consumption is worst case consumption when the Universe II is performing DMA
reads from the VME bus with alternating worst case data patterns ($FFFF_FFFF, $0000_0000 on
consecutive cycles), and 100pF loading on the PCI bus
In the majority of system applications, the Universe II consumes typical values or less. Typical power
consumption numbers are based on the Universe II remaining idle 30%-50% of the time, which is
significantly less than what is considered likely in most systems. For this reason, it is recommended
that typical power consumption numbers be used for power estimation and ambient temperature
calculations, as described below.
The HTOL FIT rate is 67 FITs. The HTOL test showed 67 FITs based on the calculation of 60%
Confidence Level (C.L.) and Activation Energy Ea=0.7eV for 0.5um process at stress condition 1.1 x
Vcc at 125°C ambient temperature This FIT rate is approximately equivalent to 90% C.L. 167 FITs.
Calculations were based on a 100 piece sample size for three lots. The test conditions were at
125°C/Bias, 5.5 V at 1 MHz per MIL-STD-883D.M1015.8.
Ti
p
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FIT is the basic reliability rate expressed as failures per billion (1e-9) device hours. Mean
Time Between Failures (MTBF) is the reciprocal of FIT. MTBF is the predicted number of
device hours before a failure will occur.
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C.4
357
Universe II Ambient Operating Calculations
The maximum ambient temperature of the Universe II can be calculated as follows:
Ta Tj - ja * P
Where,
Ta = Ambient temperature (°C)
Tj = Maximum Universe II Junction Temperature (°C)
ja = Ambient to Junction Thermal Impedance (°C / Watt)
P = Universe II power consumption (Watts)
The ambient to junction thermal impedance (ja) is dependent on the air flow in linear feet per minute
over the Universe II. The values for ja over different values of air flow are shown in Table 39.
Table 39: Ambient to Junction Thermal Impedance
Air Flow (m/s)
0
1
2
313 PBGA
15.10
13.10
11.70
For example, the maximum ambient temperature of the 313 PBGA, 32-bit PCI environment with
100 LFPM blowing past the Universe II is:
Ta Tj - ja * P
Ta 125 - 13.1* 2.0
Ta 98.8 °C
Therefore the maximum rated ambient temperature for the Universe II in this environment is 98.8°C.
Further improvements can be made by adding heat sinks to the PBGA package.
Tj values of Universe II are calculated as follows (Tj = ja * P + Ta)
Table 40: Maximum Universe II Junction Temperature
Extended (125 °C Ambient)a
Industrial (85 °C Ambient)
Commercial: (70 °C Ambient)
Tj=13.1*2.7+125=160.37°C
Tj=13.1*2.7+85=120.37°C
Tj=13.1*2.7+70=105.37°C
a. IDT recommends that the maximum junction temperature of the Universe II does not exceed 150 °C. This
temperature limit can be achieved by using heat dissipation techniques, such as heat sinks and forced
airflows.
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C. Reliability Prediction > Thermal Vias
Table 41 shows the simulated Psi jt and Theta jc thermal characteristics of the Universe II package.
Table 41: Thermal Characteristics of Universe II
Interface
Result
Psi jt
0.25 C/watt
Theta jc (junction to case)
4.7 C/watt
These values were obtained under the following PCB and environmental conditions:
•
PCB condtionsMaximum junction
— PCB standard: JEDEC JESD51-9
— PCB layers: 4
— PCB dimensions: 101.6 mm x 114.3 mm
— PCB thickness: 1.6 mm
•
Environmental conditions
— Maximum junction temperature: 125C
— Ambient temperature: 70C
— Power dissipation: 3 W
C.5
Thermal Vias
The 313-pin plastic BGA package contains thermal vias which directly pipe heat from the die to the
solder balls on the underside of the package. The solder balls use the capabilities of the power and
ground planes of the printed circuit board to draw heat out of the package.
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D.
Endian Mapping
Universe II has Little-endian mapping. Little-endian refers to a method of formatting data where
address 0 (or the smallest address referencing the data) points to the least significant byte of the data.
Data in a system must be consistent; that is, the system must be entirely big-endian or little-endian.
This chapter discusses the following topics:
•
D.1
“Little-endian Mode” on page 359
Overview
The Universe II always performs Address Invariant translation between the PCI and VMEbus ports.
Address Invariant mapping preserves the byte ordering of a data structure in a little-endian memory
map and a big-endian memory map.
D.2
Little-endian Mode
Table 42 shows the byte lane swapping and address translation between a 32-bit little-endian PCI bus
and the VMEbus for the address invariant translation scheme.
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D. Endian Mapping > Little-endian Mode
Table 42: Mapping of 32-bit Little-Endian PCI Bus to 32-bit VMEbus
PCI Bus
Byte Enables
Address
VMEbus
3
2
1
0
1
0
1
1
1
0
0
0
D0-D7
1
1
0
1
0
1
D8-D15
1
0
1
1
1
0
0
1
1
1
1
1
1
0
0
0
1
0
1
0
0
0
0
0
0
0
0
1
0
0
0
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1
1
0
1
0
0
1
0
0
0
DS1
DS0
A1
LW
D8-D15
0
1
0
1
D0-D7
1
0
0
1
D16-D23
D8-D15
0
1
1
1
1
D24-D31
D0-D7
1
0
1
1
0
D0-D7
D8-D15
0
0
0
1
D8-D15
D0-D7
D8-D15
D16-D23
0
0
1
0
D16-D23
D8-D15
D16-D23
D8-D15
0
0
1
1
D24-D31
D0-D7
D0-D7
D24-D31
0
1
0
0
D8-D15
D16-D23
D16-D23
D8-D15
D8-D15
D16-D23
1
0
0
0
D16-D23
D8-D15
D24-D31
D0-D7
D0-D7
D24-D31
0
0
0
0
D8-D15
D16-D23
D16-D23
D8-D15
D24-D31
D0-D7
1
0
0
1
0
Byte Lane Mapping
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The unpacking of multiplexed 64-bit data from the VMEbus into two 32-bit quantities on a
little-endian PCI bus is outlined in Table 43 below.
Table 43: Mapping of 32-bit Little-Endian PCI Bus to 64-bit VMEbus
Byte Enables
3
2
1
Address
0
2
1
0
PCI to VME Byte Lane Mapping
First Transfer (D32-D63)
0
0
0
0
0
0
0
D0-D7
A24-A31 (D56-D63)
D8-D15
A16-A23 (D48-D55)
D16-D23
A8-A15 (D40-D47)
D24-D31
LWORD, A1-A7 (D32-D39)
D0-D7
D24-D31
D8-D15
D16-D23
D16-D23
D8-D15
D24-D31
D0-D7
Second Transfer (D0-D31)
0
0
0
0
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0
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E.
Typical Applications
This chapter discusses the following topics:
E.1
•
“VME Interface” on page 363
•
“PCI Bus Interface” on page 368
•
“Manufacturing Test Pins” on page 370
•
“Decoupling VDD and VSS on the Universe II” on page 371
Overview
Being a bridge between standard interfaces, the Universe II requires minimal external logic to interface
to either the VMEbus or to the PCI bus. In most applications, only transceivers to buffer the Universe II
from the VMEbus, plus some reset logic are all that is required. The following information should be
used only as a guide in designing the Universe II into a PCI/VME application. Each application will
have its own set-up requirements.
E.2
VME Interface
E.2.1
Transceivers
The Universe II has been designed such that it requires full buffering from VMEbus signals. Necessary
drive current to the VMEbus is provided by the transceivers while at the same time isolating the
Universe II from potentially noisy VMEbus backplanes. In particular, complete isolation of the
Universe II from the VMEbus backplane allows use of ETL transceivers which provide high noise
immunity as well as use in live insertion environments. The VME community has recently
standardized “VME64 Extensions” (ANSI VITA 1.1) which among other new VME features,
facilitates live insertion environments.
If neither live insertion nor noise immunity are a concern, those buffers that provide input only (U15
and U17 in Figure 40) may be omitted. The daisy chain input signals, BGIN[3:0] and IACKIN, have
Schmitt trigger inputs, which should rectify any minor noise on these signals. If considerable noise is
expected, the designer may wish to put external filters on these signals. Bear in mind that any filtering
done on these signals will detrimentally affect the propagation of bus grants down the daisy chain.
Only extremely noisy systems or poorly designed backplanes should require these filters.
Figure 40 shows one example of how to connect the Universe II to the VMEbus. The transceivers in
this example were chosen to meet the following criteria:
•
Provide sufficient drive strength as required by the VME specification
•
Meet Universe II skew requirements, and
•
Minimize part counts.
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E. Typical Applications > VME Interface
U15 and U17 in Figure 40 are optional devices and provide better noise immunity for the system.
Figure 40: Universe II Connections to the VMEbus Through TTL Buffers
Universe
VMEbus
A[31:1],
LWORD*
VOE_
VA_DIR
U1
U2
G
DIR
G
DIR
A0
A1
B0
B1
B2
A2
A3
A4
A0
A1
A5
A6
B6
B7
A7
B0
B1
B2
B3
B4
A2
A3
A4
A5
A6
B3
B4
B5
U3
U4
G
DIR
B5
B6
B7
A7
A0
A1
A2
A3
A4
A5
A6
A7
G
DIR
B0
B1
B2
B3
B4
B5
B6
B7
B0
A0
A1
A2
A3
B1
B2
B3
B4
B5
B6
A4
A5
A6
A7
B7
VA[31:1],
LWORD*
D[31:0]
VD_DIR
U5
U6
G
DIR
U7
G
DIR
U8
G
DIR
G
DIR
A0
B0
A0
B0
A0
B0
A1
B1
B2
A1
A2
B1
B2
A1
A2
B1
B2
B3
B4
A3
A4
B3
B4
A3
A4
B3
B4
A5
A6
B5
B6
A5
A6
B5
B6
A5
A6
B5
B6
A7
B7
A7
B7
A7
B7
A2
A3
A4
A0
A1
B0
B1
A2
A3
B2
B3
A4
A5
B4
B5
A6
A7
B6
B7
VD[31:0]
G
DIR
VAM[5:0]
VWRITE_
VIACK_
U10:A
VAS_
U11:
U11:A
VAS_DIR
VDS0_
VDS1_
U11:B
A0
B0
A1
A2
B1
A3
A4
B3
A5
B5
B2
B4
B6
B7
U10:B
U10:C
WRITE*
IACK*
AS*
DS[1:0]*
U11:C
VDS_DIR
VDTACK_
AM[5:0]
U9
VAM_DIR
U10:D
DTACK*
U11:D
VSLAVE_DIR
SYSCLK_
U12:A
SYSCLK
U13:A
VBCLR_
U12:B
BCLR*
VSCON_DIR
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365
Figure 41: Universe II Connections to the VMEbus Through TTL Buffers
Universe
VMEbus
Vcc
U14:A
VXBBSY
BBSY*
U15:A
VRBBSY_
U15:B
VRACFAIL_
ACFAIL*
U14:C
VXSYSFAIL
SYSFAIL*
U15:C
VRSYSFAIL_
U14:D
VXSYSRST
SYSRST*
U15:D
VRSYSRST_
U14:E
VXBERR
BERR*
U15:E
VRBERR_
U14:F-H, U16:A-D
VXIRQ[7:1]
VRIRQ[7:1]_
7
IRQ[7:1]*
7
U15:F-H, U17:A-D
U16:E-H
VXBR[3:0]
4
VRBR[3:0]_
4
BR[3:0]*
U17:E-H
VBGIN[3:0]_
4
VBGOUT[3:0]_
4
BG[3:0]IN*
BG[3:0]OUT*
VIACKIN_
IACKIN*
VIACKOUT_
IACKOUT*
U1-U9
U10, U12
U11, U13
U15, U17
’245, SN74VMEH22501 (TI)
’126
’125
’241 (optional)
U14 and U16 were originally 642 buffers, but the 642 buffer is now obsolete.
IDT recommends any other open drain buffer as a replacement, such as a F06.
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E. Typical Applications > VME Interface
The Universe II, with the addition of external transceivers, is designed to meet the timing requirements
of the VME specification. Refer to the VME64 specification (ANSI VITA 1.0) for details on the VME
timing. In order to meet the requirements outlined in this specification, the external transceivers must
meet certain characteristics as outlined in Table 45.
Table 44: VMEbus Signal Drive Strength Requirements
VME bus Signal
Required Drive Strength
A[31:1], D[31:0], AM[5:0], IACK*, LWORD*, WRITE*, DTACK*
IOL 48mA
IOH 3mA
IOL 64mA
AS*, DS[1:0]*,
IOH 3mA
IOL 64mA
SYSCLK*
IOH 3mA
BR[3:0]*, BSY*, IRQ[7:0]*, BERR*, SYSFAIL*, SYSRESET*
IOL 48mA
Table 45: VMEbus Transceiver Requirements
Parameter
From
To
(Input)
(Output)
Timing
Min
Max
VA, VD, VAM, VIACK, VLWORD, VWRITE, VAS, VDSx, VDTACKa
skew (pkg to pkg)
A
B
8 ns
skew (pkg to pkg)
B
A
4 ns
tProp
DIR
A
1 ns
5ns
tProp
DIR
B
2 ns
10ns
Cin
A
25 pf
a. There are no limits on propagation delay or skew on the remaining buffered VME
signals: VSYSCLK, VBCLR, VXBBSY, VRBBSY, VRACFAIL, VXSYSFAIL,
VRSYSFAIL, VXSYSRST, VRSYSRST, VXBERR, VRBERR, VXIRQ, VRIRQ,
VXBR, VRBR.
F Series transceivers meet the requirements specified in Table 44 and Table 45. A faster family such as
ABT, may also be used. Care should be taken in the choice of transceivers to avoid ground bounces and
also to minimize crosstalk incurred during switching. To limit the effects of crosstalk, the amount of
routing under these transceivers must be kept to a minimum. Daisy chain signals can be especially
susceptible to crosstalk.
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367
Should the designer wish to put any further circuitry between the Universe II and the VMEbus, that
circuitry must meet the same timing requirements as the transceivers in order for the combined circuit
to remain compliant with the VME64 specification.
E.2.1.1
Pull-down resistors
The Universe II has internal pull-down resistors which are used for its default power-up option state.
(Note that REQ64_ has an internal pull-up.) These internal pull-down resistors, ranging from
25k-500k, are designed to sink between 10µA-200µA. F-series buffers, however, can source up to
650 µA of current (worst case). This sourced current has the ability to override the internal power up
resistors on the Universe II. This may cause the Universe II to incorrectly sample a logic “1” on the
pins. To counteract this potential problem, assuming a worst case scenario of a 650 µA current, IDT
recommends connecting a 1K resistor to ground, in parallel, with the internal pull-down resistor.
IDT recommends that any pins controlling the power-up options which are critical to the application at
power-up be connected to ground with a pull-down resistor as described above. If these options are not
critical and if it is possible to reprogram these options after reset, additional resistors need not be
added.
E.2.2
Direction control
When the Universe II is driving VMEbus lines, it drives the direction control signals high (i.e.,
VA_DIR, VAM_DIR, VAS_DIR, VD_DIR, VDS_DIR, VSLAVE_DIR, and VSCON_DIR). When the
VMEbus is driving the Universe II, these signals are driven low. The control signals in the Universe II
do not all have the same functionality. Since the Universe II implements early bus release, VAS_DIR
must be a separate control signal.
Contention between the Universe II and the VME buffers is handled since the Universe II tristates its
outputs one 64MHz clock period before the buffer direction control is faced inwards.
E.2.3
Power-up Options
Power-up options for the automatic configuration of slave images and other Universe II features are
provided through the state of the VME address and data pins, VA[31:1] and VD[31:27]. All of these
signals are provided with internal pull-downs to bias these signals to their default conditions. Should
values other than the defaults be required here, either pull-ups or active circuitry may be applied to
these signals to provide alternate configurations.
Power-up options are described in “Resets, Clocks and Power-up Options” on page 129.
Since the power-up configurations lie on pins that may be driven by the Universe II or by the VME
transceivers, care must be taken to ensure that there is no conflict. During any reset event, the Universe
II does not drive the VA or VD signals. As well, during any VMEbus reset (SYSRST*) and for several
CLK64 periods after, the Universe II negates VOE_ to tri-state the transceivers. During the period that
these signals are tri-stated, the power-up options are loaded with their values latched on the rising edge
of PWRRST_.
Configuration of power-up options is most easily accomplished through passive 10k pull-up resistors
on the appropriate VA and VD pins. The configurations may be made user-configurable through
jumpers or switches as shown in Figure 42
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E. Typical Applications > PCI Bus Interface
Figure 42: Power-up Configuration Using Passive Pull-ups
Universe II
VDD
Power-up Pins
Alternatively, an active circuit may be designed which drives the VA and VD pins with pre-set (or
pre-programmed) values. This sort of circuit would be of value when power-up configurations such as
the register access slave image are stored in an external programmable register. To implement this
circuit, the VOE_ output from the Universe II must be monitored. When the Universe II negates this
signal, the appropriate VA and VD signals may be driven and upon re-assertion the drive must be
removed. To avoid conflict with the transceivers, logic must be designed such that the enabling of the
transceivers does not occur until some point after the configuration options have been removed from
the VD and VA signals. Figure 43 shows one such implementation. The delay for enabling of the
VMEbus transceivers could be implemented though clocked latches.
Figure 43: Power-up Configuration Using Active Circuitry
Universe II
OE_
Tranceivers
Delay
OE_
Power-up Pins
E.2.3.1
VMEbus
VOE_
External Register
Auto-Syscon and PCI Bus Width Power-up Options
The VME64 specification provides for automatic enabling of the system controller in a VME system
through monitoring of the BGIN3* signal. If at the end of SYSRST* this pin is low, then the system
controller is enabled; otherwise it is disabled. The Universe II provides an internal pull-down resistor
for this function. If it is in slot one, this pin will be sampled low. If not in slot one, then it will be driven
high by the previous board in the system and system controller functions will be disabled. No external
logic is required to implement this feature.
E.3
PCI Bus Interface
The Universe II provides a fully standard PCI bus interface compliant for both 32-bit and 64-bit
designs. No external transceivers or glue logic is required in interfacing the Universe II to any other
PCI compliant devices. All signals may be routed directly to those devices.
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�E. Typical Applications > PCI Bus Interface
369
The Universe II’s PCI interface can be used as a 32-bit bus or 64-bit bus. If used as a 32-bit interface,
the 64-bit pins, AD[32:63] and ACK64_ are left unterminated. On a 32-bit PCI bus, the Universe II
drives all its 64-bit extension bi-direct signals (C/BE[7:4]_, AD[63:32], REQ64_, PAR64 and
ACK64_) at all times to unknown values. Independent of the setting of the LD64EN bit, the Universe
II will never attempt a 64-bit cycle on the PCI bus if it is powered up as 32-bit.
REQ64_ must be pulled-down (with a 4.7kresistor) at reset for 64-bit PCI (see “PCI Bus Width” on
page 138). There is an internal pull-up on this pin which causes the Universe II to default to 32-bit PCI.
This power-up option provides the necessary information to the Universe II so that these unused pins
may be left unterminated.
E.3.1
Resets
The Universe II provides several reset input and outputs which are asserted under various conditions.
These can be grouped into three types as shown in Table 46.
Table 46: Reset Signals
Group
Signal Name
Direction
VMEbus
VXSYSRST
output
VRSYSRST_
input
LRST_
output
RST_
input
VME_RESET_
input
PWRRST_
input
PCI bus
Power-up
E.3.1.1
VMEbus Resets
The VMEbus resets are connected to the VMEbus as indicated in Figure 40 on page 364 through
external buffers.
E.3.1.2
PCI bus Resets
Use of the PCI bus resets will be application dependent. The RST_ input to the Universe II should
typically be tied in some fashion to the PCI bus reset signal of the same name. This will ensure that all
Universe II PCI related functions are reset together with the PCI bus.
The LRST_ pin is a totem-pole output which is asserted due to any of the following initiators:
•
PWRRST_,
•
VRSYSRST_,
•
local software reset (in the MISC_CTL register), or
•
VME CSR reset (in the VCSR_SET register).
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E. Typical Applications > Manufacturing Test Pins
The designer may wish to disallow the Universe II from resetting the PCI bus in which case this output
may be left unconnected. Otherwise LRST_ should be grouped with other PCI reset generators to assert
the RST_ signal such that:
RST_ = LRST_ and reset_source1 and reset_source2 and...
If the Universe II is the only initiator of PCI reset, LRST_ may be directly connected to RST_.
Assertion of VME_RESET causes the Universe II to assert VXSYSRST.
This signal must not by tied to the PCI RST_ signal unless the Universe II LRST_
output will not generate a PCI bus reset. Connecting both LRST_ and
VME_RESET_ to RST_ will cause a feedback loop on the reset circuitry forcing
the entire system into a endless reset.
To reset the VMEbus through this signal it is recommended that it be asserted for several clock cycles,
until the Universe II asserts RST_, and then released. This ensures a break is made in the feedback
path.
E.3.1.3
Power-Up Reset
The PWRRST_ input is used to provide reset to the Universe II until the power supply has reached a
stable level. It should be held asserted for 100 milliseconds after power is stable. Typically this can be
achieved through a resistor/capacitor combination although more accurate solutions using under
voltage sensing circuits (e.g. MC34064) are often implemented. The power-up options are latched on
the rising edge of PWRRST_.
E.3.1.4
JTAG Reset
The JTAG reset, TRST_, should be tied into the master system JTAG controller. It resets the Universe
II internal JTAG controller. If JTAG is not being used, this pin should be tied to ground.
E.3.2
Local Interrupts
The Universe II provides eight local bus interrupts, only one of which has drive strength that is fully
PCI compliant. If any of the other seven interrupts are to be used as interrupt outputs to the local bus
(all eight may be defined as either input or output), an analysis must be done on the design to determine
whether the 4 mA of drive that the Universe II provides on these lines is sufficient for the design. If
more drive is required, the lines may simply be buffered.
All Universe II interrupts are initially defined as inputs. To prevent excess power dissipation, any
interrupts defined as inputs should always be driven to either high or low. Pull-ups should be used for
this purpose rather than direct drive since a mis-programming of the interrupt registers may cause the
local interrupts to be configured as outputs and potentially damage the device.
E.4
Manufacturing Test Pins
The Universe II has several signals used for manufacturing test purposes. They are listed in Table 24 on
page 140, along with the source to which they should be tied.
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�E. Typical Applications > Decoupling VDD and VSS on the Universe II
E.5
371
Decoupling VDD and VSS on the Universe II
This section is intended to be a guide for decoupling the power and ground pins on the Universe II. A
separate analog power and ground plane is not required to provide power to the analog portion of the
Universe II. However, to ensure a jitter free PLL operation, the analog AVDD and AVSS pins must be
noise free. The following are recommended solutions for noise free PLL operation. The design could
implement one of these solutions, but not both.
The Analog Isolation Scheme consists of the following:
•
a 0.1µF capacitor between the AVDD and AVSS pins, and
•
corresponding inductors between the pins and the board power and ground planes (See Figure 44).
These inductors are not necessary, but they are recommended.
Figure 44: Analog Isolation Scheme
Board VDD
1.5 - 220 µH
AVDD
0.1 µF
AVSS
1.5 - 220 µH
Board VSS
The Noise Filter Scheme filters out the noise using two capacitors to filter high and low frequencies
(See Figure 45).
Figure 45: Noise Filter Scheme
Board VDD
10-38 †
AVDD
0.01 µF
(High Freq. Bias)
22 µF
(Low Freq. Bias)
AVSS
Board VSS
For both schemes, it is recommended that the components involved be tied as close as possible to the
associated analog pins.
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E. Typical Applications > Decoupling VDD and VSS on the Universe II
In addition to the decoupling schemes shown above, it is recommended that 0.1µF bypass capacitors
should be tied between every three pairs of VDD pins and the board ground plane. These bypass
capacitors should also be tied as close as possible to the package.
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F.
Ordering Information
This appendix discusses Universe II’s ordering information.
F.1
Ordering Information
IDT products are designated by a product code. When ordering, refer to products by their full code.
Table 47 details the available part numbers.
Table 47: Standard Ordering Information
Part Number
PCI Frequency
Voltage
Temperature
Package
CA91C142D-33CE
33 MHz
5V
Commercial
(0° to 70°C)
PBGA
CA91C142D-33CEV
33 MHz
5V
Commercial
(0° to 70°C)
CA91C142D-33IE
33 MHz
5V
Industrial
(-40° to 85°C)
CA91C142D-33IEV
33 MHz
5V
Industrial
(-40° to 85°C)
CA91C142D-25EE
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25 MHz
5V
Extended
(-55° to 125°C)
PBGA
(RoHS/Green)
PBGA
PBGA
(RoHS/Green)
PBGA
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F. Ordering Information > Ordering Information
The IDT “Tsi” part numbering system is explained as follows.
Prototype version status
Operating environment
Package type
RoHS/Green compliance
Operating frequency
IDT product identifier
Product number
Tsi NNN(N) - SS(S) E P G (Z#)
•
( ) – Indicates optional characters.
•
Tsi – IDT “Tsi” product identifier.
•
NNNN – Product number (may be three or four digits).
•
SS(S) – Maximum operating frequency or data transfer rate of the fastest interface. For operating
frequency numbers, M and G represent MHz and GHz. For transfer rate numbers, M and G
represent Mbps and Gbps.
•
E – Operating environment in which the product is guaranteed. This code may be one of the
following characters:
— C - Commercial temperature range (0 to +70°C)
— I - Industrial temperature range (-40 to +85°C)
— E - Extended temperature range (-55 to +125°C)
•
P – The Package type of the product:
— B - Ceramic ball grid array (CBGA)
— E, L, J, and K - Plastic ball grid array (PBGA)
— G - Ceramic pin grid array (CPGA)
— M - Small outline integrated circuit (SOIC)
— Q - Plastic quad flatpack (QFP)
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�F. Ordering Information > Ordering Information
•
375
G – IDT “Tsi” products fit into three RoHS-compliance categories:
— Y - RoHS Compliant (6of6) – These products contain none of the six restricted substances
above the limits set in the EU Directive 2002/95/EC.
— Y - RoHS Compliant (Flip Chip) – These products contain only one of the six restricted
substances: Lead (Pb). These flip-chip products are RoHS compliant through the Lead
exemption for Flip Chip technology, Commission Decision 2005/747/EC, which allows Lead
in solders to complete a viable electrical connection between semiconductor die and carrier
within integrated circuit Flip Chip packages.
— V - RoHS Compliant/Green - These products follow the above definitions for RoHS
Compliance and meet JIG (Joint Industry Guide) Level B requirements for Brominated Flame
Retardants (other than PBBs and PBDEs).
•
Z# – Prototype version status (optional). If a product is released as a prototype then a “Z” is added
to the end of the part number. Further revisions to the prototype prior to production release would
add a sequential numeric digit. For example, the first prototype version of device would have a
“Z,” a second version would have “Z1,” and so on. The prototype version code is dropped once the
product reaches production status.
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Universe II User Manual
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F. Ordering Information > Ordering Information
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for SALES:
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phone: 408-360-1538
Document: May 12, 2010
DISCLAIMER Integrated Device Technology, Inc. (IDT) and its subsidiaries reserve the right to modify the products and/or specifications described herein at any time and at IDT’s sole discretion. All information in this document, including descriptions of
product features and performance, is subject to change without notice. Performance specifications and the operating parameters of the described products are determined in the independent state and are not guaranteed to perform the same way when
installed in customer products. The information contained herein is provided without representation or warranty of any kind, whether express or implied, including, but not limited to, the suitability of IDT’s products for any particular purpose, an implied
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