l11/12: reconfigurable logic architecturesl11/12: 6.111 spring 2004 introductory digital systems...
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L11/12: 6.111 Spring 2004 1Introductory Digital Systems Laboratory
L11/12: Reconfigurable Logic L11/12: Reconfigurable Logic ArchitecturesArchitectures
Acknowledgements:
Materials in this lecture are courtesy of the following people and used with permission.
Computer Science)- Randy H. Katz (University of California, Berkeley, Department of Electrical Engineering &
- Frank Honorehttp://www.cs.washington.edu/370)- Gaetano Borriello (University of Washington, Department of Computer Science & Engineering,
L11/12: 6.111 Spring 2004 2Introductory Digital Systems Laboratory
History of Computational FabricsHistory of Computational Fabrics
Discrete devices: relays, transistors (1940s-50s)Discrete logic gates (1950s-60s)Integrated circuits (1960s-70s)
e.g. TTL packages: Data Book for 100’s of different parts
Gate Arrays (IBM 1970s)Transistors are pre-placed on the chip & Place and Route software puts the chip together automatically – only program the interconnect (mask programming)
Software Based Schemes (1970’s- present)Run instructions on a general purpose core
ASIC Design (1980’s to present)Turn Verilog directly into layout using a library of standard cells Effective for high-volume and efficient use of silicon area
Programmable Logic (1980’s to present)A chip that be reprogrammed after it has been fabricatedExamples: PALs, EPROM, EEPROM, PLDs, FPGAsExcellent support for mapping from Verilog
L11/12: 6.111 Spring 2004 3Introductory Digital Systems Laboratory
Reconfigurable LogicReconfigurable Logic
Logic blocksTo implement combinationaland sequential logic
InterconnectWires to connect inputs andoutputs to logic blocks
I/O blocksSpecial logic blocks at periphery of device forexternal connections
Key questions:How to make logic blocks programmable?(after chip has been fabbed!)What should the logic granularity be?How to make the wires programmable?(after chip has been fabbed!)Specialized wiring structures for localvs. long distance routes?How many wires per logic block?
LogicLogic
Configuration
Inputs Outputsn m
Q
QSET
CLR
D
L11/12: 6.111 Spring 2004 4Introductory Digital Systems Laboratory
Programmable Array Logic (PAL)Programmable Array Logic (PAL)
Based on the fact that any combinational logic can be realized as a sum-of-productsPALs feature an array of AND-OR gates with programmable interconnect
inputsignals
ANDarray OR array
outputsignals
programming of product terms
programming of sum terms
L11/12: 6.111 Spring 2004 6Introductory Digital Systems Laboratory
Inside the 22v10 “Inside the 22v10 “MacrocellMacrocell” Block” Block
Outputs may be registered or combinational, positive or invertedRegistered output may be fed back to AND array for FSMs, etc.
(Courtesy of Lattice Semiconductor Corporation. Used with permission.)
L11/12: 6.111 Spring 2004 8Introductory Digital Systems Laboratory
AntiAnti--FuseFuse--Based Approach (Based Approach (ActelActel))
Rows of programmablelogic building blocks
+
rows of interconnect
Anti-fuse Technology:Program Once
I/O Buffers, Programming and Test Logic
Logic Module Wiring Tracks
I/O Buffers, Programming and Test Logic
I/O B
uffe
rs, P
rogr
amm
ing
and
Test
Log
ic
I/O B
uffers, Programm
ing and Test LogicUse Anti-fuses to buildup long wiring runs from
short segments
8 input, single output combinational logic blocks
FFs constructed from discrete cross coupled gates
L11/12: 6.111 Spring 2004 9Introductory Digital Systems Laboratory
ActelActel Logic ModuleLogic Module
Combinational block does not have the output FFExample Gate Mapping
00011011
GNDA
BC
DE
Y
S-R Flip-Flop
GND
GND
VDDR
S
VDD00011011
Q
L11/12: 6.111 Spring 2004 10Introductory Digital Systems Laboratory
ActelActel Routing & ProgrammingRouting & Programming
Logic Module
Output SegmentsLong Vertical Tracks
Input Segments
Outputs
Inputs
HorizontalChannel
Vpp
Vpp/2
Vpp/2Gnd
Programming an Antifuse
Antifuseshorted
Vpp/2
Vpp/2Vpp/2
Vpp/2
PrechargePhase
(Courtesy of Actel. Used with permission.)
L11/12: 6.111 Spring 2004 11Introductory Digital Systems Laboratory
RAM Based Field Programmable RAM Based Field Programmable Logic Logic -- XilinxXilinx
CLB
CLB
CLB
CLB
SwitchMatrix
ProgrammableInterconnect I/O Blocks (IOBs)
ConfigurableLogic Blocks (CLBs)
D Q
SlewRate
Control
PassivePull-Up,
Pull-Down
Delay
Vcc
OutputBuffer
InputBuffer
Q D
Pad
D QSD
RDEC
S/RControl
D QSD
RDEC
S/RControl
1
1
F'G'
H'
DIN
F'G'
H'
DIN
F'
G'H'
H'
HFunc.Gen.
GFunc.Gen.
FFunc.Gen.
G4G3G2G1
F4F3F2F1
C4C1 C2 C3
K
Y
X
H1 DIN S/R EC
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 12Introductory Digital Systems Laboratory
The The XilinxXilinx 4000 CLB4000 CLB
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 13Introductory Digital Systems Laboratory
Two 4Two 4--input Functions, Registered Outputinput Functions, Registered Outputand a Two Input Functionand a Two Input Function
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 14Introductory Digital Systems Laboratory
55--input Function, Combinational Outputinput Function, Combinational Output
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 15Introductory Digital Systems Laboratory
LUT MappingLUT Mapping
N-LUT direct implementation of a truth table: any function of n-inputs.N-LUT requires 2N storage elements (latches)N-inputs select one latch location (like a memory)
Inputs
Why Latches and Not Registers?
Output
Latches set by configuration bitstream
4LUT example (Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 16Introductory Digital Systems Laboratory
Configuring the CLB as a RAMConfiguring the CLB as a RAM
Memory is built using Latches not FFs
Read is same a LUT Function!
16x2
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 17Introductory Digital Systems Laboratory
XilinxXilinx 4000 Interconnect4000 Interconnect
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 18Introductory Digital Systems Laboratory
XilinxXilinx 4000 Interconnect Details4000 Interconnect Details
Wires are not ideal!
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 19Introductory Digital Systems Laboratory
Add Bells & WhistlesAdd Bells & Whistles
HardProcessor
I/O
BRAM
Gigabit Serial
Multiplier
ProgrammableTermination
Z
VCCIO
Z
Z
ImpedanceControl Clock
Mgmt
18 Bit
18 Bit36 Bit
Courtesy of David B. Parlour. Used with permission., ISSCC 2004 Tutorial, “The Reality and Promise of Reconfigurable Computing in Digital Signal Processing”
L11/12: 6.111 Spring 2004 20Introductory Digital Systems Laboratory
XilinxXilinx 4000 Flexible IOB4000 Flexible IOB
Adjust Transition Time
Adjust the Sampling Edge
Outputs through FF or bypassed
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 21Introductory Digital Systems Laboratory
The The VirtexVirtex II CLB (Half Slice Shown)II CLB (Half Slice Shown)
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 22Introductory Digital Systems Laboratory
Adder ImplementationAdder Implementation
Y = A ⊕ B ⊕ CinB
Cin
Cout
A
LUT: A⊕B
1 half-Slice = 1-bit adder
Dedicated carry logic
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 23Introductory Digital Systems Laboratory
Carry ChainCarry Chain
1 CLB = 4 Slices = 2, 4-bit adders
64-bit Adder: 16 CLBs
+
CLB15
CLB0A[3:0]B[3:0]
A[63:60]B[63:60]
A[63:0]
B[63:0]Y[63:0]
Y[3:0]
Y[63:60]
Y[64]
CLBs must be in same column
CLB1A[7:4]B[7:4] Y[7:4]
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 24Introductory Digital Systems Laboratory
VirtexVirtex II FeaturesII Features
Digital Clock ManagerDouble Data Rate registers
Embedded Multiplier Block SelectRAM(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 25Introductory Digital Systems Laboratory
The Latest Generation: The Latest Generation: VirtexVirtex--II ProII Pro
Embedded memoriesFPGA Fabric
High-speed I/O
Embedded PowerPc
Hardwired multipliers
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 31Introductory Digital Systems Laboratory
Design Flow Design Flow -- MappingMapping
Technology Mapping: Schematic/HDL to Physical Logic unitsCompile functions into basic LUT-based groups (function of target architecture)
Q
QSET
CLR
D
LUTQ
QSET
CLR
D
abc
db
always @(posedge Clock or negedge Reset)beginif (! Reset)
q <= 0;else
q <= (a & b & c) | (b & d);end
L11/12: 6.111 Spring 2004 32Introductory Digital Systems Laboratory
Design Flow Design Flow –– Placement & RoutePlacement & Route
Placement – assign logic location on a particular device
LUT
LUT
LUT
Routing – iterative process to connect CLB inputs/outputs and IOBs. Optimizes critical path delay – can take hours or days for large, dense designs
Iterate placement if timing not met
Satisfy timing? Generate Bitstream to config device
Challenge! Cannot use full chip for reasonable speeds (wires are not ideal). Typically no more than 50% utilization.
L11/12: 6.111 Spring 2004 33Introductory Digital Systems Laboratory
Example: Example: VerilogVerilog to FPGAto FPGA
module adder64 (a, b, sum);
Virtex II – XC2V2000
• Synthesis• Tech Map• Place&Route
input [63:0] a, b; output [63:0] sum;
assign sum = a + b;
endmodule
64-bit Adder Example
(Courtesy of Xilinx. Used with permission.)
L11/12: 6.111 Spring 2004 34Introductory Digital Systems Laboratory
How are How are FPGAsFPGAs Used?Used?
PrototypingEnsemble of gate arrays used to emulate a circuit to be manufacturedGet more/better/faster debugging done than with simulation
Reconfigurable hardwareOne hardware block used to implement more than one function
Special-purpose computation enginesHardware dedicated to solving one problem (or class of problems)Accelerators attached to general-purpose computers (e.g., in a cell phone!)
L11/12: 6.111 Spring 2004 35Introductory Digital Systems Laboratory
SummarySummary
FPGA provide a flexible platform for implementing digital computingA rich set of macros and I/Os supported (multipliers, block RAMS, ROMS, high-speed I/O)A wide range of applications from prototyping (to validate a design before ASIC mapping) to high-performance spatial computingInterconnects are a major bottleneck (physical design and locality are important considerations)
“College students will study concurrent programming instead of “C” as their first
computing experience.”
-- David B. Parlour, ISSCC 2004 Tutorial