From: Luke Kenneth Casson Leighton Date: Thu, 22 Aug 2019 01:27:02 +0000 (+0100) Subject: move and reorg create_next_terms in AddReduceSingle, call in elaborate X-Git-Tag: ls180-24jan2020~428 X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=9ef106effbe8acfcf2e47c849c137d1657e411f4;p=ieee754fpu.git move and reorg create_next_terms in AddReduceSingle, call in elaborate --- diff --git a/src/ieee754/part_mul_add/multiply.py b/src/ieee754/part_mul_add/multiply.py index 6f770842..c74c80e6 100644 --- a/src/ieee754/part_mul_add/multiply.py +++ b/src/ieee754/part_mul_add/multiply.py @@ -418,18 +418,20 @@ class AddReduceSingle(Elaboratable): raise ValueError( "not enough adder levels for specified register levels") - # this is annoying. we have to create the modules (and terms) - # because we need to know what they are (in order to set up the - # interconnects back in AddReduce), but cannot do the m.d.comb += - # etc because this is not in elaboratable. self.groups = AddReduceSingle.full_adder_groups(n_inputs) - self._intermediate_terms = [] - self.adders = [] - if len(self.groups) != 0: - self.create_next_terms() + n_terms = AddReduceSingle.calc_n_inputs(n_inputs, self.groups) + self.o = AddReduceData(partition_points, n_terms, output_width, n_parts) - self.o = AddReduceData(partition_points, len(self._intermediate_terms), - output_width, n_parts) + @staticmethod + def calc_n_inputs(n_inputs, groups): + retval = len(groups)*2 + if n_inputs % FULL_ADDER_INPUT_COUNT == 1: + retval += 1 + elif n_inputs % FULL_ADDER_INPUT_COUNT == 2: + retval += 2 + else: + assert n_inputs % FULL_ADDER_INPUT_COUNT == 0 + return retval @staticmethod def get_max_level(input_count): @@ -454,12 +456,43 @@ class AddReduceSingle(Elaboratable): input_count - FULL_ADDER_INPUT_COUNT + 1, FULL_ADDER_INPUT_COUNT) + def create_next_terms(self): + """ create next intermediate terms, for linking up in elaborate, below + """ + terms = [] + adders = [] + + # create full adders for this recursive level. + # this shrinks N terms to 2 * (N // 3) plus the remainder + for i in self.groups: + adder_i = MaskedFullAdder(self.output_width) + adders.append((i, adder_i)) + # add both the sum and the masked-carry to the next level. + # 3 inputs have now been reduced to 2... + terms.append(adder_i.sum) + terms.append(adder_i.mcarry) + # handle the remaining inputs. + if self.n_inputs % FULL_ADDER_INPUT_COUNT == 1: + terms.append(self.i.inputs[-1]) + elif self.n_inputs % FULL_ADDER_INPUT_COUNT == 2: + # Just pass the terms to the next layer, since we wouldn't gain + # anything by using a half adder since there would still be 2 terms + # and just passing the terms to the next layer saves gates. + terms.append(self.i.inputs[-2]) + terms.append(self.i.inputs[-1]) + else: + assert self.n_inputs % FULL_ADDER_INPUT_COUNT == 0 + + return terms, adders + def elaborate(self, platform): """Elaborate this module.""" m = Module() + terms, adders = self.create_next_terms() + # copy the intermediate terms to the output - for i, value in enumerate(self._intermediate_terms): + for i, value in enumerate(terms): m.d.comb += self.o.inputs[i].eq(value) # copy reg part points and part ops to output @@ -474,7 +507,7 @@ class AddReduceSingle(Elaboratable): m.d.comb += part_mask.eq(mask) # add and link the intermediate term modules - for i, (iidx, adder_i) in enumerate(self.adders): + for i, (iidx, adder_i) in enumerate(adders): setattr(m.submodules, f"adder_{i}", adder_i) m.d.comb += adder_i.in0.eq(self.i.inputs[iidx]) @@ -484,36 +517,6 @@ class AddReduceSingle(Elaboratable): return m - def create_next_terms(self): - - _intermediate_terms = [] - - def add_intermediate_term(value): - _intermediate_terms.append(value) - - # create full adders for this recursive level. - # this shrinks N terms to 2 * (N // 3) plus the remainder - for i in self.groups: - adder_i = MaskedFullAdder(self.output_width) - self.adders.append((i, adder_i)) - # add both the sum and the masked-carry to the next level. - # 3 inputs have now been reduced to 2... - add_intermediate_term(adder_i.sum) - add_intermediate_term(adder_i.mcarry) - # handle the remaining inputs. - if self.n_inputs % FULL_ADDER_INPUT_COUNT == 1: - add_intermediate_term(self.i.inputs[-1]) - elif self.n_inputs % FULL_ADDER_INPUT_COUNT == 2: - # Just pass the terms to the next layer, since we wouldn't gain - # anything by using a half adder since there would still be 2 terms - # and just passing the terms to the next layer saves gates. - add_intermediate_term(self.i.inputs[-2]) - add_intermediate_term(self.i.inputs[-1]) - else: - assert self.n_inputs % FULL_ADDER_INPUT_COUNT == 0 - - self._intermediate_terms = _intermediate_terms - class AddReduce(Elaboratable): """Recursively Add list of numbers together.