-"""IEEE754 Floating Point Divider
+"""IEEE754 Floating Point Divider
Relevant bugreport: http://bugs.libre-riscv.org/show_bug.cgi?id=99
"""
-from nmigen import Module, Signal, Cat, Elaboratable
+from nmigen import Module, Signal, Cat, Elaboratable, Const
from nmigen.cli import main, verilog
from ieee754.fpcommon.fpbase import (FPNumBaseRecord, Overflow)
from ieee754.div_rem_sqrt_rsqrt.div_pipe import DivPipeInputData
-# TODO: delete (replace by DivPipeCoreInputData)
-class FPDivStage0Data:
-
- def __init__(self, pspec):
- self.z = FPNumBaseRecord(pspec.width, False)
- self.out_do_z = Signal(reset_less=True)
- self.oz = Signal(pspec.width, reset_less=True)
-
- self.ctx = FPPipeContext(pspec.width, pspec) # context: muxid, operator etc.
- self.muxid = self.ctx.muxid # annoying. complicated.
-
- # TODO: here is where Q and R would be put, and passed
- # down to Stage1 processing.
-
- mw = (self.z.m_width)*2 - 1 + 3 # sticky/round/guard bits + (2*mant) - 1
- self.product = Signal(mw, reset_less=True)
-
- def eq(self, i):
- return [self.z.eq(i.z), self.out_do_z.eq(i.out_do_z), self.oz.eq(i.oz),
- self.product.eq(i.product), self.ctx.eq(i.ctx)]
-
-
class FPDivStage0Mod(Elaboratable):
def __init__(self, pspec):
return FPSCData(self.pspec, False)
def ospec(self):
- # XXX TODO: replace with DivPipeCoreInputData, here
- return FPDivStage0Data(self.pspec)
+ return DivPipeInputData(self.pspec)
def process(self, i):
return self.o
# pipeline chain) - see ospec.
# INPUT SPEC: FPSCData
- # OUTPUT SPEC: DivPipeCoreInputData
+ # OUTPUT SPEC: DivPipeInputData
# NOTE: this stage does *NOT* do *ACTUAL* DIV processing,
# it is PURELY the *ENTRY* point into the chain, performing
with m.If(~self.i.out_do_z):
# do conversion here, of both self.i.a and self.i.b,
- # into DivPipeCoreInputData dividend and divisor.
+ # into DivPipeInputData dividend and divisor.
+
+ # XXX *sigh* magic constants...
+ if self.pspec.width == 16:
+ if self.pspec.log2_radix == 1:
+ extra = 2
+ elif self.pspec.log2_radix == 3:
+ extra = 2
+ else:
+ extra = 3
+ elif self.pspec.width == 32:
+ if self.pspec.log2_radix == 1:
+ extra = 3
+ else:
+ extra = 4
+ elif self.pspec.width == 64:
+ if self.pspec.log2_radix == 1:
+ extra = 2
+ elif self.pspec.log2_radix == 3:
+ extra = 2
+ else:
+ extra = 3
+
+ # the mantissas, having been de-normalised (and containing
+ # a "1" in the MSB) represent numbers in the range 0.5 to
+ # 0.9999999-recurring. the min and max range of the
+ # result is therefore 0.4999999 (0.5/0.99999) and 1.9999998
+ # (0.99999/0.5).
+
+ # zero-extend the mantissas (room for sticky/round/guard)
+ # plus the extra MSB.
+ am0 = Signal(len(self.i.a.m)+3, reset_less=True)
+ bm0 = Signal(len(self.i.b.m)+3, reset_less=True)
+ m.d.comb += [
+ am0.eq(Cat(0,0,0,self.i.a.m, 0)),
+ bm0.eq(Cat(0,0,0,self.i.b.m, 0)),
+ ]
m.d.comb += [self.o.z.e.eq(self.i.a.e - self.i.b.e + 1),
- self.o.z.s.eq(self.i.a.s ^ self.i.b.s)
- self.o.dividend.eq(self.i.a.m), # TODO: check
- self.o.divisor_radicand.eq(self.i.b.m), # TODO: check
- self.o.operation.eq(Const(0)) # TODO (set from ctx.op)
+ self.o.z.s.eq(self.i.a.s ^ self.i.b.s),
+ self.o.dividend[len(self.i.a.m)+extra:].eq(am0),
+ self.o.divisor_radicand.eq(bm0),
+ self.o.operation.eq(Const(0)) # XXX DIV operation
]
# these are required and must not be touched
class FPDivStage0(FPState):
- """ First stage of div.
+ """ First stage of div.
"""
def __init__(self, pspec):