The Verilog Pli Handbook: A User's Guide and Comprehensive Reference on the Verilog Programming Language Interface
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The Verilog Pli Handbook: A User's Guide and Comprehensive Reference on the Verilog Programming Language Interface

 CDROM, 004
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CDROM, 004
Stuart Sutherland
1243 g
243x165x42 mm
666, Kluwer International Series in

Dedication. About the Author. List of Examples. Foreword. Acknowledgments. Introduction. Part One: The VPI Portion of the Verilog PLI Standard. 1. Creating PLI Applications Using VPI Routines. 2. Interfacing VPI Applications to Verilog Simulators. 3. How to Use the VPI Routines. 4. Details about the VPI Routine Library. 5. Reading and Modifying Values Using VPI Routines. 6. Synchronizing to Simulations Using VPI Callbacks. 7. Interfacing to C Models Using VPI Routines. Part Two: The TF/ACC Portion of the Verilog PLI Standard. 8. Creating PLI Applications Using TF and ACC Routines. 9. Interfacing TF/ACC Applications to Verilog Simulators. 10. How to Use the TF Routines. 11. Reading and Writing Values Using TF Routines. 12. Synchronizing to Simulations Using Misctf Routines. 13. Interfacing to C Models Using TF Routines. 14. How to Use the ACC Routines. 15. Details on the ACC Routine Library. 16. Reading and Modifying Values Using ACC Routines. 17. Using the Value Change Link (VCL). 18. Interfacing to C Models Using ACC Routines. Appendices. Appendix A: Linking PLI Applications to Verilog Simulators. Appendix B: The IEEE 1364-2001 TF Routine Library. Appendix C: The IEEE 1364-2001 ACC Routine Library. Appendix D: The IEEE 1364-2001 VPI Routine Library. Index. About the CD.
by Maq Mannan President and CEO, DSM Technologies Chairman of the IEEE 1364 Verilog Standards Group Past Chairman of Open Verilog International One of the major strengths of the Verilog language is the Programming Language Interface (PLI), which allows users and Verilog application developers to infinitely extend the capabilities of the Verilog language and the Verilog simulator. In fact, the overwhelming success of the Verilog language can be partly attributed to the exi- ence of its PLI. Using the PLI, add-on products, such as graphical waveform displays or pre and post simulation analysis tools, can be easily developed. These products can then be used with any Verilog simulator that supports the Verilog PLI. This ability to create thi- party add-on products for Verilog simulators has created new markets and provided the Verilog user base with multiple sources of software tools. Hardware design engineers can, and should, use the Verilog PLI to customize their Verilog simulation environment. A Company that designs graphics chips, for ex- ple, may wish to see the simulation results of a new design in some custom graphical display. The Verilog PLI makes it possible, and even trivial, to integrate custom so- ware, such as a graphical display program, into a Verilog simulator. The simulation results can then dynamically be displayed in the custom format during simulation. And, if the company uses Verilog simulators from multiple simulator vendors, this integrated graphical display will work with all the simulators.