-# IEEE Floating Point Adder (Single Precision)
-# Copyright (C) Jonathan P Dawson 2013
-# 2013-12-12
+"""IEEE754 Floating Point Library
-from nmigen import Module, Signal
+Copyright (C) 2019 Luke Kenneth Casson Leighton <lkcl@lkcl.net>
+
+"""
+
+from nmigen import Module, Mux
from nmigen.cli import main, verilog
from math import log
-from ieee754.fpcommon.modbase import FPModBase
-from ieee754.fpcommon.fpbase import FPNumBaseRecord
+from nmutil.pipemodbase import PipeModBase
from ieee754.fpcommon.fpbase import FPNumBase
-from ieee754.fpcommon.getop import FPPipeContext
+from ieee754.fpcommon.pscdata import FPSCData
-class FPSCData:
-
- def __init__(self, pspec, m_extra):
- width = pspec.width
- # NOTE: difference between z and oz is that oz is created by
- # special-cases module(s) and will propagate, along with its
- # "bypass" signal out_do_z, through the pipeline, *disabling*
- # all processing of all subsequent stages.
- self.a = FPNumBaseRecord(width, m_extra, name="a") # operand a
- self.b = FPNumBaseRecord(width, m_extra, name="b") # operand b
- self.z = FPNumBaseRecord(width, False, name="z") # denormed result
- self.oz = Signal(width, reset_less=True) # "finished" (bypass) result
- self.out_do_z = Signal(reset_less=True) # "bypass" enabled
- self.ctx = FPPipeContext(pspec)
- self.muxid = self.ctx.muxid
-
- def __iter__(self):
- yield from self.a
- yield from self.b
- yield from self.z
- yield self.oz
- yield self.out_do_z
- yield from self.ctx
-
- def eq(self, i):
- ret = [self.z.eq(i.z), self.out_do_z.eq(i.out_do_z), self.oz.eq(i.oz),
- self.a.eq(i.a), self.b.eq(i.b), self.ctx.eq(i.ctx)]
- return ret
-
-
-class FPAddDeNormMod(FPModBase):
+class FPAddDeNormMod(PipeModBase):
def __init__(self, pspec, m_extra):
self.m_extra = m_extra
m.submodules.denorm_in_a = in_a = FPNumBase(self.i.a)
m.submodules.denorm_in_b = in_b = FPNumBase(self.i.b)
- with m.If(~self.i.out_do_z):
- # XXX hmmm, don't like repeating identical code
- comb += self.o.a.eq(self.i.a)
- with m.If(in_a.exp_n127):
- comb += self.o.a.e.eq(self.i.a.N126) # limit a exponent
- with m.Else():
- comb += self.o.a.m[-1].eq(1) # set top mantissa bit
-
- comb += self.o.b.eq(self.i.b)
- with m.If(in_b.exp_n127):
- comb += self.o.b.e.eq(self.i.b.N126) # limit a exponent
- with m.Else():
- comb += self.o.b.m[-1].eq(1) # set top mantissa bit
+ # XXX hmmm, don't like repeating identical code
+ comb += self.o.a.eq(self.i.a)
+ ae = self.i.a.e
+ am = self.i.a.m
+ # either limit exponent, or set top mantissa bit
+ comb += self.o.a.e.eq(Mux(in_a.exp_n127, self.i.a.N126, ae))
+ comb += self.o.a.m[-1].eq(Mux(in_a.exp_n127, am[-1], 1))
+
+ # XXX code now repeated for b
+ comb += self.o.b.eq(self.i.b)
+ be = self.i.b.e
+ bm = self.i.b.m
+ # either limit exponent, or set top mantissa bit
+ comb += self.o.b.e.eq(Mux(in_b.exp_n127, self.i.b.N126, be))
+ comb += self.o.b.m[-1].eq(Mux(in_b.exp_n127, bm[-1], 1))
comb += self.o.ctx.eq(self.i.ctx)
comb += self.o.z.eq(self.i.z)
comb += self.o.oz.eq(self.i.oz)
return m
-
-