abinf = Signal(reset_less=True)
comb += abinf.eq(a1.is_inf & b1.is_inf)
- with m.If(self.i.ctx.op == 0): # DIV
-
- # if a is NaN or b is NaN return NaN
- with m.If(abnan):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.nan(0)
-
- # if a is inf and b is Inf return NaN
- with m.Elif(abinf):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.nan(0)
-
- # if a is inf return inf
- with m.Elif(a1.is_inf):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.inf(sabx)
-
- # if b is inf return zero
- with m.Elif(b1.is_inf):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.zero(sabx)
-
- # if a is zero return zero (or NaN if b is zero)
- with m.Elif(a1.is_zero):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.zero(sabx)
- # b is zero return NaN
- with m.If(b1.is_zero):
+ with m.Switch(self.i.ctx.op):
+
+ with m.Case(int(DP.UDivRem)): # DIV
+
+ # if a is NaN or b is NaN return NaN
+ with m.If(abnan):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.nan(0)
+
+ # if a is inf and b is Inf return NaN
+ with m.Elif(abinf):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.nan(0)
+
+ # if a is inf return inf
+ with m.Elif(a1.is_inf):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.inf(sabx)
+
+ # if b is inf return zero
+ with m.Elif(b1.is_inf):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.zero(sabx)
+
+ # if a is zero return zero (or NaN if b is zero)
+ with m.Elif(a1.is_zero):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.zero(sabx)
+ # b is zero return NaN
+ with m.If(b1.is_zero):
+ comb += self.o.z.nan(0)
+
+ # if b is zero return Inf
+ with m.Elif(b1.is_zero):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.inf(sabx)
+
+ # Denormalised Number checks next, so pass a/b data through
+ with m.Else():
+ comb += self.o.out_do_z.eq(0)
+
+ with m.Case(int(DP.SqrtRem)): # SQRT
+
+ # if a is zero return zero
+ with m.If(a1.is_zero):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.zero(a1.s)
+
+ # -ve number is NaN
+ with m.Elif(a1.s):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.nan(0)
+
+ # if a is inf return inf
+ with m.Elif(a1.is_inf):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.inf(sabx)
+
+ # if a is NaN return NaN
+ with m.Elif(a1.is_nan):
+ comb += self.o.out_do_z.eq(1)
comb += self.o.z.nan(0)
- # if b is zero return Inf
- with m.Elif(b1.is_zero):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.inf(sabx)
-
- # Denormalised Number checks next, so pass a/b data through
- with m.Else():
- comb += self.o.out_do_z.eq(0)
-
- with m.If(self.i.ctx.op == 1): # SQRT
-
- # if a is zero return zero
- with m.If(a1.is_zero):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.zero(a1.s)
-
- # -ve number is NaN
- with m.Elif(a1.s):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.nan(0)
-
- # if a is inf return inf
- with m.Elif(a1.is_inf):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.inf(sabx)
-
- # if a is NaN return NaN
- with m.Elif(a1.is_nan):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.nan(0)
-
- # Denormalised Number checks next, so pass a/b data through
- with m.Else():
- comb += self.o.out_do_z.eq(0)
-
- with m.If(self.i.ctx.op == 2): # RSQRT
-
- # if a is NaN return canonical NaN
- with m.If(a1.is_nan):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.nan(0)
-
- # if a is +/- zero return +/- INF
- with m.Elif(a1.is_zero):
- comb += self.o.out_do_z.eq(1)
- # this includes the "weird" case 1/sqrt(-0) == -Inf
- comb += self.o.z.inf(a1.s)
-
- # -ve number is canonical NaN
- with m.Elif(a1.s):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.nan(0)
-
- # if a is inf return zero (-ve already excluded, above)
- with m.Elif(a1.is_inf):
- comb += self.o.out_do_z.eq(1)
- comb += self.o.z.zero(0)
-
- # Denormalised Number checks next, so pass a/b data through
- with m.Else():
- comb += self.o.out_do_z.eq(0)
+ # Denormalised Number checks next, so pass a/b data through
+ with m.Else():
+ comb += self.o.out_do_z.eq(0)
+
+ with m.Case(int(DP.RSqrtRem)): # RSQRT
+
+ # if a is NaN return canonical NaN
+ with m.If(a1.is_nan):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.nan(0)
+
+ # if a is +/- zero return +/- INF
+ with m.Elif(a1.is_zero):
+ comb += self.o.out_do_z.eq(1)
+ # this includes the "weird" case 1/sqrt(-0) == -Inf
+ comb += self.o.z.inf(a1.s)
+
+ # -ve number is canonical NaN
+ with m.Elif(a1.s):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.nan(0)
+
+ # if a is inf return zero (-ve already excluded, above)
+ with m.Elif(a1.is_inf):
+ comb += self.o.out_do_z.eq(1)
+ comb += self.o.z.zero(0)
+
+ # Denormalised Number checks next, so pass a/b data through
+ with m.Else():
+ comb += self.o.out_do_z.eq(0)
comb += self.o.oz.eq(self.o.z.v)
comb += self.o.ctx.eq(self.i.ctx)
projects / ieee754fpu.git / commitdiff