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The following describes the IEEE-Standard-754 compliant, double-precision floating point unit,
written in Verilog. The module consists of the following files:
1. fpu_double.v (top level)
2. fpu_add.v
3. fpu_sub.v
4. fpu_mul.v
5. fpu_div.v
6. fpu_round.v
7. fpu_exceptions.v
And a testbench file is included, containing 50 test-case operations:
1. fpu_tb.v
This unit has been extensively simulated, covering all operations, rounding modes, exceptions
like underflow and overflow, and even the obscure corner cases, like when overflowing from
denormalized to normalized, and vice-versa.
The floating point unit supports denormalized numbers,
4 operations (add, subtract, multiply, divide), and 4 rounding
modes (nearest, zero, + inf, - inf). The unit was synthesized with an
estimated frequency of 230 MHz, for a Virtex5 target device. The synthesis results
are below. fpu_double.v is the top-level module, and it contains the input
and output signals from the unit. The unit was designed to be synchronous with
one global clock, and all of the registers can be reset with an synchronous global reset.
When the inputs signals (a and b operands, fpu operation code, rounding mode code) are
available, set the enable input high, then set it low after 2 clock cycles. When the
operation is complete and the output is available, the ready signal will go high. To start
the next operation, set the enable input high.
Each operation takes the following amount of clock cycles to complete:
1. addition : 20 clock cycles
2. subtraction: 21 clock cycles
3. multiplication: 24 clock cycles
4. division: 71 clock cycles
This is longer than other floating point units, but supporting denormalized numbers
requires more signals and logic levels to accommodate gradual underflow. The supported
clock speed of 230 MHz makes up for the large number of clock cycles required for each
operation to complete. If you have a lower clock speed, the code can be changed to
reduce the number of registers and latency of each operation. I purposely increased the
number of logic levels to get the code to synthesize to a faster clock frequency, but of course,
this led to longer latency. I guess it depends on your application what is more important.
The following output signals are also available: underflow, overflow, inexact, exception,
and invalid. They are compliant with the IEEE-754 definition of each signal. The unit
will handle QNaN and SNaN inputs per the standard.
I'm planning on adding more operations, like square root, sin, cos, tan, etc.,
so check back for updates.
Multiply:
The multiply module is written specifically for a Virtex5 target device. The DSP48E slices
can perform a 25-bit by 18-bit Twos-complement multiply (24 by 17 unsigned multiply). I broke up the multiply to
fit these DSP48E slices. The breakdown is similar to the design in Figure 4-15 of the
Xilinx User Guide Document, "Virtex-5 FPGA XtremeDSP Design Considerations", also known as UG193.
You can find this document at xilinx.com by searching for "UG193".
Depending on your device, the multiply can be changed to match the bit-widths of the available
multipliers. A total of 9 DSP48E slices are used to do the 53-bit by 53-bit multiply of 2
floating point numbers.
If you have any questions, please email me at: davidklun@gmail.com
Thanks,
David Lundgren
-----
Synthesis Results:
Performance Summary
*******************
Worst slack in design: -0.971
Requested Estimated Requested Estimated Clock C
5409
lock
Starting Clock Frequency Frequency Period Period Slack Type Group
-----------------------------------------------------------------------------------------------------------
fpu|clk 300.0 MHz 232.3 MHz 3.333 4.304 -0.971 inferred
==========================================================================
---------------------------------------
Resource Usage Report for fpu
Mapping to part: xc5vsx95tff1136-2
Cell usage:
DSP48E 9 uses
FD 5 uses
FDR 519 uses
FDRE 3920 uses
FDRSE 1 use
GND 6 uses
LD 6 uses
MUXCY 35 uses
MUXCY_L 704 uses
MUXF7 1 use
VCC 5 uses
XORCY 491 uses
XORCY_L 12 uses
LUT1 185 uses
LUT2 725 uses
LUT3 1523 uses
LUT4 738 uses
LUT5 604 uses
LUT6 2506 uses
I/O ports: 206
I/O primitives: 205
IBUF 135 uses
OBUF 70 uses
BUFGP 1 use
I/O Register bits: 0
Register bits not including I/Os: 4445 (7%)
Latch bits not including I/Os: 6 (0%)
Global Clock Buffers: 1 of 32 (3%)
Total load per clock:
fpu|clk: 4454
Mapping Summary:
Total LUTs: 6281 (10%)