this however requires the code to *not* be designed to use nmigen.If,
nmigen.Case, or other constructs: only Mux and other logic.
-http://bugs.libre-riscv.org/show_bug.cgi?id=132
+* http://bugs.libre-riscv.org/show_bug.cgi?id=132
"""
from ieee754.part_mul_add.adder import PartitionedAdder
-#from ieee754.part_cmp.equal_ortree import PartitionedEq
from ieee754.part_cmp.eq_gt_ge import PartitionedEqGtGe
+from ieee754.part_shift.part_shift_dynamic import PartitionedDynamicShift
+from ieee754.part_shift.part_shift_scalar import PartitionedScalarShift
from ieee754.part_mul_add.partpoints import make_partition
from operator import or_, xor, and_, not_
-from nmigen import (Signal,
- )
-def applyop(op1, op2, op):
+from nmigen import (Signal, Const)
+
+
+def getsig(op1):
if isinstance(op1, PartitionedSignal):
op1 = op1.sig
- if isinstance(op2, PartitionedSignal):
- op2 = op2.sig
- return op(op1, op2)
+ return op1
+
+
+def applyop(op1, op2, op):
+ return op(getsig(op1), getsig(op2))
class PartitionedSignal:
def __init__(self, mask, *args, **kwargs):
self.sig = Signal(*args, **kwargs)
- width = self.sig.shape()[0] # get signal width
- self.partpoints = make_partition(mask, width) # create partition points
+ width = self.sig.shape()[0] # get signal width
+ # create partition points
+ self.partpoints = make_partition(mask, width)
self.modnames = {}
- for name in ['add', 'eq']:
+ for name in ['add', 'eq', 'gt', 'ge', 'ls']:
self.modnames[name] = 0
def set_module(self, m):
def get_modname(self, category):
self.modnames[category] += 1
- return "%s%d" % (category, self.modnames[category])
+ return "%s_%d" % (category, self.modnames[category])
def eq(self, val):
- return self.sig.eq(val)
+ return self.sig.eq(getsig(val))
+
+ # unary ops that do not require partitioning
+
+ def __invert__(self):
+ return ~self.sig
+
+ # unary ops that require partitioning
+
+ def __neg__(self):
+ z = Const(0, len(self.partpoints)+1)
+ result, _ = self.add_op(self, ~0, carry=z) # TODO, subop
+ return result
+
+ # binary ops that don't require partitioning
def __and__(self, other):
return applyop(self, other, and_)
def __rxor__(self, other):
return applyop(other, self, xor)
- def __add__(self, other):
- shape = self.sig.shape()
+ # binary ops that need partitioning
+
+ # TODO: detect if the 2nd operand is a Const, a Signal or a
+ # PartitionedSignal. if it's a Const or a Signal, a global shift
+ # can occur. if it's a PartitionedSignal, that's much more interesting.
+ def ls_op(self, op1, op2, carry, shr_flag=0):
+ op1 = getsig(op1)
+ if isinstance(op2, Const) or isinstance(op2, Signal):
+ scalar = True
+ shape = op1.shape()
+ pa = PartitionedScalarShift(shape[0], self.partpoints)
+ else:
+ scalar = False
+ op2 = getsig(op2)
+ shape = op1.shape()
+ pa = PartitionedDynamicShift(shape[0], self.partpoints)
+ setattr(self.m.submodules, self.get_modname('ls'), pa)
+ comb = self.m.d.comb
+ if scalar:
+ comb += pa.data.eq(op1)
+ comb += pa.shifter.eq(op2)
+ comb += pa.shift_right.eq(shr_flag)
+ else:
+ comb += pa.a.eq(op1)
+ comb += pa.b.eq(op2)
+ comb += pa.shift_right.eq(shr_flag)
+ # XXX TODO: carry-in, carry-out
+ #comb += pa.carry_in.eq(carry)
+ return (pa.output, 0)
+
+ def __lshift__(self, other):
+ z = Const(0, len(self.partpoints)+1)
+ result, _ = self.ls_op(self, other, carry=z) # TODO, carry
+ return result
+
+ def __rlshift__(self, other):
+ raise NotImplementedError
+ return Operator("<<", [other, self])
+
+ def __rshift__(self, other):
+ z = Const(0, len(self.partpoints)+1)
+ result, _ = self.ls_op(self, other, carry=z, shr_flag=1) # TODO, carry
+ return result
+
+ def __rrshift__(self, other):
+ raise NotImplementedError
+ return Operator(">>", [other, self])
+
+ def add_op(self, op1, op2, carry):
+ op1 = getsig(op1)
+ op2 = getsig(op2)
+ shape = op1.shape()
pa = PartitionedAdder(shape[0], self.partpoints)
setattr(self.m.submodules, self.get_modname('add'), pa)
comb = self.m.d.comb
- comb += pa.a.eq(self.sig)
- if isinstance(other, PartitionedSignal):
- comb += pa.b.eq(other.sig)
- else:
- comb += pa.b.eq(other)
- return pa.output
+ comb += pa.a.eq(op1)
+ comb += pa.b.eq(op2)
+ comb += pa.carry_in.eq(carry)
+ return (pa.output, pa.carry_out)
- def __eq__(self, other):
- print ("eq", self, other)
- shape = self.sig.shape()
- pa = PartitionedEqGtGe(shape[0], self.partpoints)
- setattr(self.m.submodules, self.get_modname('eq'), pa)
+ def sub_op(self, op1, op2, carry=~0):
+ op1 = getsig(op1)
+ op2 = getsig(op2)
+ shape = op1.shape()
+ pa = PartitionedAdder(shape[0], self.partpoints)
+ setattr(self.m.submodules, self.get_modname('add'), pa)
+ comb = self.m.d.comb
+ comb += pa.a.eq(op1)
+ comb += pa.b.eq(~op2)
+ comb += pa.carry_in.eq(carry)
+ return (pa.output, pa.carry_out)
+
+ def __add__(self, other):
+ result, _ = self.add_op(self, other, carry=0)
+ return result
+
+ def __radd__(self, other):
+ result, _ = self.add_op(other, self)
+ return result
+
+ def __sub__(self, other):
+ result, _ = self.sub_op(self, other)
+ return result
+
+ def __rsub__(self, other):
+ result, _ = self.sub_op(other, self)
+ return result
+
+ def __mul__(self, other):
+ return Operator("*", [self, other])
+
+ def __rmul__(self, other):
+ return Operator("*", [other, self])
+
+ def __check_divisor(self):
+ width, signed = self.shape()
+ if signed:
+ # Python's division semantics and Verilog's division semantics
+ # differ for negative divisors (Python uses div/mod, Verilog
+ # uses quo/rem); for now, avoid the issue
+ # completely by prohibiting such division operations.
+ raise NotImplementedError(
+ "Division by a signed value is not supported")
+
+ def __mod__(self, other):
+ raise NotImplementedError
+ other = Value.cast(other)
+ other.__check_divisor()
+ return Operator("%", [self, other])
+
+ def __rmod__(self, other):
+ raise NotImplementedError
+ self.__check_divisor()
+ return Operator("%", [other, self])
+
+ def __floordiv__(self, other):
+ raise NotImplementedError
+ other = Value.cast(other)
+ other.__check_divisor()
+ return Operator("//", [self, other])
+
+ def __rfloordiv__(self, other):
+ raise NotImplementedError
+ self.__check_divisor()
+ return Operator("//", [other, self])
+
+ # binary comparison ops that need partitioning
+
+ def _compare(self, width, op1, op2, opname, optype):
+ # print (opname, op1, op2)
+ pa = PartitionedEqGtGe(width, self.partpoints)
+ setattr(self.m.submodules, self.get_modname(opname), pa)
comb = self.m.d.comb
- comb += pa.opcode.eq(PartitionedEqGtGe.EQ) # set opcode to EQ
- comb += pa.a.eq(self.sig)
- if isinstance(other, PartitionedSignal):
- comb += pa.b.eq(other.sig)
+ comb += pa.opcode.eq(optype) # set opcode
+ if isinstance(op1, PartitionedSignal):
+ comb += pa.a.eq(op1.sig)
+ else:
+ comb += pa.a.eq(op1)
+ if isinstance(op2, PartitionedSignal):
+ comb += pa.b.eq(op2.sig)
else:
- comb += pa.b.eq(other)
+ comb += pa.b.eq(op2)
return pa.output
+
+ def __eq__(self, other):
+ width = self.sig.shape()[0]
+ return self._compare(width, self, other, "eq", PartitionedEqGtGe.EQ)
+
+ def __ne__(self, other):
+ width = self.sig.shape()[0]
+ eq = self._compare(width, self, other, "eq", PartitionedEqGtGe.EQ)
+ ne = Signal(eq.width)
+ self.m.d.comb += ne.eq(~eq)
+ return ne
+
+ def __gt__(self, other):
+ width = self.sig.shape()[0]
+ return self._compare(width, self, other, "gt", PartitionedEqGtGe.GT)
+
+ def __lt__(self, other):
+ width = self.sig.shape()[0]
+ return self._compare(width, other, self, "gt", PartitionedEqGtGe.GT)
+
+ def __ge__(self, other):
+ width = self.sig.shape()[0]
+ return self._compare(width, self, other, "ge", PartitionedEqGtGe.GE)
+
+ def __le__(self, other):
+ width = self.sig.shape()[0]
+ return self._compare(width, other, self, "ge", PartitionedEqGtGe.GE)
+
+ # useful operators
+
+ def bool(self):
+ """Conversion to boolean.
+
+ Returns
+ -------
+ Value, out
+ ``1`` if any bits are set, ``0`` otherwise.
+ """
+ raise NotImplementedError
+ return Operator("b", [self])
+
+ def any(self):
+ """Check if any bits are ``1``.
+
+ Returns
+ -------
+ Value, out
+ ``1`` if any bits are set, ``0`` otherwise.
+ """
+ raise NotImplementedError
+ return Operator("r|", [self])
+
+ def all(self):
+ """Check if all bits are ``1``.
+
+ Returns
+ -------
+ Value, out
+ ``1`` if all bits are set, ``0`` otherwise.
+ """
+ raise NotImplementedError
+ return Operator("r&", [self])
+
+ def xor(self):
+ """Compute pairwise exclusive-or of every bit.
+
+ Returns
+ -------
+ Value, out
+ ``1`` if an odd number of bits are set, ``0`` if an
+ even number of bits are set.
+ """
+ # XXXX TODO: return partition-mask-sized set of bits
+ raise NotImplementedError
+ return Operator("r^", [self])
+
+ def implies(premise, conclusion):
+ """Implication.
+
+ Returns
+ -------
+ Value, out
+ ``0`` if ``premise`` is true and ``conclusion`` is not,
+ ``1`` otherwise.
+ """
+ # amazingly, this should actually work.
+ return ~premise | conclusion