-from nmigen import Module, Signal
+from nmigen import Module, Signal, Cat, Mux, Array, Const
from nmigen.cli import main, verilog
-from fpbase import FPNum, FPOp, Overflow, FPBase
+from fpbase import FPNumIn, FPNumOut, FPOp, Overflow, FPBase, FPState
+from fpcommon.getop import FPGetOp
+from singlepipe import eq
class FPMUL(FPBase):
self.in_b = FPOp(width)
self.out_z = FPOp(width)
+ self.states = []
+
+ def add_state(self, state):
+ self.states.append(state)
+ return state
+
def get_fragment(self, platform=None):
""" creates the HDL code-fragment for FPMUL
"""
m = Module()
# Latches
- a = FPNum(self.width, False)
- b = FPNum(self.width, False)
- z = FPNum(self.width, False)
+ a = FPNumIn(None, self.width, False)
+ b = FPNumIn(None, self.width, False)
+ z = FPNumOut(self.width, False)
- mw = (self.m_width)*2 - 1 + 3 # sticky/round/guard bits + (2*mant) - 1
+ mw = (z.m_width)*2 - 1 + 3 # sticky/round/guard bits + (2*mant) - 1
product = Signal(mw)
of = Overflow()
+ m.submodules.of = of
+ m.submodules.a = a
+ m.submodules.b = b
+ m.submodules.z = z
+
+ m.d.comb += a.v.eq(self.a.v)
+ m.d.comb += b.v.eq(self.b.v)
with m.FSM() as fsm:
# gets operand a
with m.State("get_a"):
- self.get_op(m, self.in_a, a, "get_b")
+ res = self.get_op(m, self.in_a, a, "get_b")
+ m.d.sync += eq([a, self.in_a.ack], res)
# ******
# gets operand b
with m.State("get_b"):
- self.get_op(m, self.in_b, b, "special_cases")
+ res = self.get_op(m, self.in_b, b, "special_cases")
+ m.d.sync += eq([b, self.in_b.ack], res)
# ******
# special cases
with m.State("special_cases"):
- m.next = "normalise_a"
#if a or b is NaN return NaN
- with m.If(a.is_nan() | b.is_nan()):
- m.next += "put_z"
+ with m.If(a.is_nan | b.is_nan):
+ m.next = "put_z"
m.d.sync += z.nan(1)
#if a is inf return inf
- with m.Elif(a.is_inf()):
- m.next += "put_z"
- m.d.sync += z.inf(0)
- #if b is zero return NaN
- with m.If(b.is_zero()):
- m.d.sync += z.nan(1)
+ with m.Elif(a.is_inf):
+ m.next = "put_z"
+ m.d.sync += z.inf(a.s ^ b.s)
+ #if b is zero return NaN
+ with m.If(b.is_zero):
+ m.d.sync += z.nan(1)
#if b is inf return inf
- with m.Elif(b.is_inf()):
- m.next += "put_z"
- m.d.sync += z.inf(0)
- #if a is zero return NaN
- with m.If(a.is_zero()):
- m.next += "put_z"
- m.d.sync += z.nan(1)
+ with m.Elif(b.is_inf):
+ m.next = "put_z"
+ m.d.sync += z.inf(a.s ^ b.s)
+ #if a is zero return NaN
+ with m.If(a.is_zero):
+ m.next = "put_z"
+ m.d.sync += z.nan(1)
#if a is zero return zero
- with m.Elif(a.is_zero()):
- m.next += "put_z"
- m.d.sync += z.zero(0)
+ with m.Elif(a.is_zero):
+ m.next = "put_z"
+ m.d.sync += z.zero(a.s ^ b.s)
#if b is zero return zero
- with m.Elif(b.is_zero()):
- m.next += "put_z"
- m.d.sync += z.zero(0)
+ with m.Elif(b.is_zero):
+ m.next = "put_z"
+ m.d.sync += z.zero(a.s ^ b.s)
# Denormalised Number checks
with m.Else():
- m.next += "normalise_a"
+ m.next = "normalise_a"
self.denormalise(m, a)
self.denormalise(m, b)
#multiply_0
with m.State("multiply_0"):
- m.next += "multiply_1"
+ m.next = "multiply_1"
m.d.sync += [
z.s.eq(a.s ^ b.s),
z.e.eq(a.e + b.e + 1),
#multiply_1
with m.State("multiply_1"):
- m.next += "normalise_1"
+ mw = z.m_width
+ m.next = "normalise_1"
m.d.sync += [
- z.m.eq(product[26:50]),
- guard.eq(product[25]),
- round_bit.eq(product[24]),
- sticky.eq(product[0:23] != 0)
+ z.m.eq(product[mw+2:]),
+ of.guard.eq(product[mw+1]),
+ of.round_bit.eq(product[mw]),
+ of.sticky.eq(product[0:mw] != 0)
]
# ******
# rounding stage
with m.State("round"):
- self.roundz(m, z, of, "corrections")
+ self.roundz(m, z, of.roundz)
+ m.next = "corrections"
# ******
# correction stage
return m
-"""
-special_cases:
- begin
- //if a is NaN or b is NaN return NaN
- if ((a_e == 128 && a_m != 0) || (b_e == 128 && b_m != 0)) begin
- z[31] <= 1;
- z[30:23] <= 255;
- z[22] <= 1;
- z[21:0] <= 0;
- state <= put_z;
- //if a is inf return inf
- end else if (a_e == 128) begin
- z[31] <= a_s ^ b_s;
- z[30:23] <= 255;
- z[22:0] <= 0;
- //if b is zero return NaN
- if (($signed(b_e) == -127) && (b_m == 0)) begin
- z[31] <= 1;
- z[30:23] <= 255;
- z[22] <= 1;
- z[21:0] <= 0;
- end
- state <= put_z;
- //if b is inf return inf
- end else if (b_e == 128) begin
- z[31] <= a_s ^ b_s;
- z[30:23] <= 255;
- z[22:0] <= 0;
- //if a is zero return NaN
- if (($signed(a_e) == -127) && (a_m == 0)) begin
- z[31] <= 1;
- z[30:23] <= 255;
- z[22] <= 1;
- z[21:0] <= 0;
- end
- state <= put_z;
- //if a is zero return zero
- end else if (($signed(a_e) == -127) && (a_m == 0)) begin
- z[31] <= a_s ^ b_s;
- z[30:23] <= 0;
- z[22:0] <= 0;
- state <= put_z;
- //if b is zero return zero
- end else if (($signed(b_e) == -127) && (b_m == 0)) begin
- z[31] <= a_s ^ b_s;
- z[30:23] <= 0;
- z[22:0] <= 0;
- state <= put_z;
- //^ done up to here
- end else begin
- //Denormalised Number
- if ($signed(a_e) == -127) begin
- a_e <= -126;
- end else begin
- a_m[23] <= 1;
- end
- //Denormalised Number
- if ($signed(b_e) == -127) begin
- b_e <= -126;
- end else begin
- b_m[23] <= 1;
- end
- state <= normalise_a;
- end
- end
-
- normalise_a:
- begin
- if (a_m[23]) begin
- state <= normalise_b;
- end else begin
- a_m <= a_m << 1;
- a_e <= a_e - 1;
- end
- end
-
- normalise_b:
- begin
- if (b_m[23]) begin
- state <= multiply_0;
- end else begin
- b_m <= b_m << 1;
- b_e <= b_e - 1;
- end
- end
-
- multiply_0:
- begin
- z_s <= a_s ^ b_s;
- z_e <= a_e + b_e + 1;
- product <= a_m * b_m * 4;
- state <= multiply_1;
- end
-
- multiply_1:
- begin
- z_m <= product[49:26];
- guard <= product[25];
- round_bit <= product[24];
- sticky <= (product[23:0] != 0);
- state <= normalise_1;
- end
-
- normalise_1:
- begin
- if (z_m[23] == 0) begin
- z_e <= z_e - 1;
- z_m <= z_m << 1;
- z_m[0] <= guard;
- guard <= round_bit;
- round_bit <= 0;
- end else begin
- state <= normalise_2;
- end
- end
-
- normalise_2:
- begin
- if ($signed(z_e) < -126) begin
- z_e <= z_e + 1;
- z_m <= z_m >> 1;
- guard <= z_m[0];
- round_bit <= guard;
- sticky <= sticky | round_bit;
- end else begin
- state <= round;
- end
- end
-
- round:
- begin
- if (guard && (round_bit | sticky | z_m[0])) begin
- z_m <= z_m + 1;
- if (z_m == 24'hffffff) begin
- z_e <=z_e + 1;
- end
- end
- state <= pack;
- end
-
- pack:
- begin
- z[22 : 0] <= z_m[22:0];
- z[30 : 23] <= z_e[7:0] + 127;
- z[31] <= z_s;
- if ($signed(z_e) == -126 && z_m[23] == 0) begin
- z[30 : 23] <= 0;
- end
- //if overflow occur
- s, return inf
- if ($signed(z_e) > 127) begin
- z[22 : 0] <= 0;
- z[30 : 23] <= 255;
- z[31] <= z_s;
- end
- state <= put_z;
- end
-
- put_z:
- begin
- s_output_z_stb <= 1;
- s_output_z <= z;
- if (s_output_z_stb && output_z_ack) begin
- s_output_z_stb <= 0;
- state <= get_a;
- end
-end
-
-"""
if __name__ == "__main__":
alu = FPMUL(width=32)