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EE121 John Wakerly Lecture #15

EE121 John Wakerly Lecture #15. CPLDs FPGAs. CPLDs vs. FPGAs. CPLD architecture Small number of largish PLDs (e.g., “36V18”) on a single chip Programmable interconnect between PLDs. FPGA architecture Much larger number of smaller programmable logic blocks.

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EE121 John Wakerly Lecture #15

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  1. EE121 John Wakerly Lecture #15 CPLDs FPGAs

  2. CPLDs vs. FPGAs • CPLD architecture • Small number of largish PLDs (e.g., “36V18”) on a single chip • Programmable interconnect between PLDs

  3. FPGAarchitecture • Much larger number of smaller programmable logic blocks. • Embedded in a sea of lots and lots of programmable interconnect.

  4. How to expand PLD architecture? • Increase # of inputs and outputs in a conventional PLD? • E.g., 16V8 --> 20V8 --> 22V10. • Why not --> 32V16 --> 128V64 ? • Problems: • n times the number of inputs and outputs requires n2 as much chip area -- too costly • logic gets slower as number of inputs to AND array increases • Solution: multiple PLDs with a relatively small programmable interconnect. • Less general than a single large PLD, but can use software “fitter” to partition into smaller PLD blocks.

  5. CPLD families • Identical individual PLD blocks (Xilinx “FBs”) replicated in different family members. • Different number of PLD blocks • Different number of I/O pins • Many CPLDs have fewer I/O pins than macrocells • “Buried” Macrocells -- provide needed logic terms internally but these outputs are not connected externally. • IC package size dictates # of I/O pins but not the total # of macrocells. • Typical CPLD families have devices with differing resources in the same IC package.

  6. Xilinx CPLDs • Notice overlap in resource availability in a particular package.

  7. 72 ==>XC9572 Xilinx 9500-family CPLD architecture

  8. 9500-family function blocks (FBs) • 18 macrocells per FB • 36 inputs per FB (partitioning challenge, but also reason for relatively compact size of FBs) • Macrocell outputs can go to I/O cells or back into switch matrix to be routed to this or other FBs.

  9. 9500-series macrocell (18 per FB) Set control Programmable inversion or XOR product term Up to 5 product terms Global clock or product-term clock Reset control OE control

  10. programmable steeringelements 9500-series product-term allocator Share terms from above and below

  11. 9500-series I/O block

  12. Switch matrix for XC95108 • Could be anything from a limited set of multiplexers to a full crossbar. • Multiplexer -- small, fast, but difficult fitting • Crossbar -- easy fitting but large and slow

  13. FPGAs • Historically, FPGA architectures and companies began around the same time as CPLDs • FPGAs are closer to “programmable ASICs” -- large emphasis on interconnection routing • Timing is difficult to predict -- multiple hops vs. the fixed delay of a CPLD’s switch matrix. • But more “scalable” to large sizes. • FPGA programmable logic blocks have only a few inputs and 1 or 2 flip-flops, but there are a lot more of them compared to the number of macrocells in a CPLD.

  14. General FPGA chip architecture a.k.a. CLB --“configurable logicblock”

  15. Xilinx 4000-series FPGAs

  16. FPGA specsmanship • Two flip-flops per CLB, plus two per I/O cell. • 25 “gates” per CLB if used for logic. • 32 bits of RAM per CLB if not used for logic. • All of this is valid only if your design has a “perfect fit”.

  17. Configurable Logic Block (CLB)

  18. CLB function generators (F, G, H) • Use RAM to store a truth table • F, G: 4 inputs, 16 bits of RAM each • H: 3 inputs, 8 bits of RAM • RAM is loaded from an external PROM at system initialization. • Broad capability using F, G, and H: • Any 2 funcs of 4 vars, plus a func of 3 vars • Any func of 5 vars • Any func of 4 vars, plus some funcs of 6 vars • Some funcs of 9 vars, including parity and 4-bit cascadable equality checking

  19. CLB input and output connections -- buried in the sea of interconnect

  20. Detail connectionscontrolled byRAM bits

  21. programmable switch element turning the corner, etc. Programmable Switch Matrix

  22. The fitter’s job • Partition logic functions into CLBs • Arrange the CLBs • Interconnect the CLBs • Minimize the number of CLBs used • Minimize the size and delay of interconnect used • Work with constraints • “Locked” I/O pins • Critical-path delays • Setup and hold times of storage elements

  23. Oh, by the way -- I/O blocks

  24. Problems common to CPLDs and FPGAs • Pin locking • Small changes, and certainly large ones, can cause the fitter to pick a different allocation of I/O blocks and pinout. • Locking too early may make the resulting circuit slower or not fit at all. • Running out of resources • Design may “blow up” if it doesn’t all fit on a single device. • On-chip interconnect resources are much richer than off-chip; e.g., barrel-shifter example. • Larger devices are exponentially more expensive.

  25. Midterm Solutions Discussion

  26. Next Time • Synchronous design methodology • Metastability

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