/* * yosys -- Yosys Open SYnthesis Suite * * Copyright (C) 2012 Clifford Wolf * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * */ #include "kernel/register.h" #include "kernel/sigtools.h" #include "kernel/celltypes.h" #include "kernel/utils.h" #include "kernel/log.h" #include #include #include USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN bool did_something; void replace_undriven(RTLIL::Design *design, RTLIL::Module *module) { CellTypes ct(design); SigMap sigmap(module); SigPool driven_signals; SigPool used_signals; SigPool all_signals; for (auto cell : module->cells()) for (auto &conn : cell->connections()) { if (!ct.cell_known(cell->type) || ct.cell_output(cell->type, conn.first)) driven_signals.add(sigmap(conn.second)); if (!ct.cell_known(cell->type) || ct.cell_input(cell->type, conn.first)) used_signals.add(sigmap(conn.second)); } for (auto wire : module->wires()) { if (wire->port_input) driven_signals.add(sigmap(wire)); if (wire->port_output) used_signals.add(sigmap(wire)); all_signals.add(sigmap(wire)); } all_signals.del(driven_signals); RTLIL::SigSpec undriven_signals = all_signals.export_all(); for (auto &c : undriven_signals.chunks()) { RTLIL::SigSpec sig = c; if (c.wire->name[0] == '$') sig = used_signals.extract(sig); if (sig.size() == 0) continue; log("Setting undriven signal in %s to undef: %s\n", RTLIL::id2cstr(module->name), log_signal(c)); module->connect(RTLIL::SigSig(c, RTLIL::SigSpec(RTLIL::State::Sx, c.width))); did_something = true; } } void replace_cell(SigMap &assign_map, RTLIL::Module *module, RTLIL::Cell *cell, std::string info, std::string out_port, RTLIL::SigSpec out_val) { RTLIL::SigSpec Y = cell->getPort(out_port); out_val.extend_u0(Y.size(), false); log("Replacing %s cell `%s' (%s) in module `%s' with constant driver `%s = %s'.\n", cell->type.c_str(), cell->name.c_str(), info.c_str(), module->name.c_str(), log_signal(Y), log_signal(out_val)); // log_cell(cell); assign_map.add(Y, out_val); module->connect(Y, out_val); module->remove(cell); did_something = true; } bool group_cell_inputs(RTLIL::Module *module, RTLIL::Cell *cell, bool commutative, SigMap &sigmap) { std::string b_name = cell->hasPort("\\B") ? "\\B" : "\\A"; bool a_signed = cell->parameters.at("\\A_SIGNED").as_bool(); bool b_signed = cell->parameters.at(b_name + "_SIGNED").as_bool(); RTLIL::SigSpec sig_a = sigmap(cell->getPort("\\A")); RTLIL::SigSpec sig_b = sigmap(cell->getPort(b_name)); RTLIL::SigSpec sig_y = sigmap(cell->getPort("\\Y")); sig_a.extend_u0(sig_y.size(), a_signed); sig_b.extend_u0(sig_y.size(), b_signed); std::vector bits_a = sig_a, bits_b = sig_b, bits_y = sig_y; enum { GRP_DYN, GRP_CONST_A, GRP_CONST_B, GRP_CONST_AB, GRP_N }; std::map, std::set> grouped_bits[GRP_N]; for (int i = 0; i < GetSize(bits_y); i++) { int group_idx = GRP_DYN; RTLIL::SigBit bit_a = bits_a[i], bit_b = bits_b[i]; if (cell->type == "$or" && (bit_a == RTLIL::State::S1 || bit_b == RTLIL::State::S1)) bit_a = bit_b = RTLIL::State::S1; if (cell->type == "$and" && (bit_a == RTLIL::State::S0 || bit_b == RTLIL::State::S0)) bit_a = bit_b = RTLIL::State::S0; if (bit_a.wire == NULL && bit_b.wire == NULL) group_idx = GRP_CONST_AB; else if (bit_a.wire == NULL) group_idx = GRP_CONST_A; else if (bit_b.wire == NULL && commutative) group_idx = GRP_CONST_A, std::swap(bit_a, bit_b); else if (bit_b.wire == NULL) group_idx = GRP_CONST_B; grouped_bits[group_idx][std::pair(bit_a, bit_b)].insert(bits_y[i]); } for (int i = 0; i < GRP_N; i++) if (GetSize(grouped_bits[i]) == GetSize(bits_y)) return false; log("Replacing %s cell `%s' in module `%s' with cells using grouped bits:\n", log_id(cell->type), log_id(cell), log_id(module)); for (int i = 0; i < GRP_N; i++) { if (grouped_bits[i].empty()) continue; RTLIL::Wire *new_y = module->addWire(NEW_ID, GetSize(grouped_bits[i])); RTLIL::SigSpec new_a, new_b; RTLIL::SigSig new_conn; for (auto &it : grouped_bits[i]) { for (auto &bit : it.second) { new_conn.first.append_bit(bit); new_conn.second.append_bit(RTLIL::SigBit(new_y, new_a.size())); } new_a.append_bit(it.first.first); new_b.append_bit(it.first.second); } RTLIL::Cell *c = module->addCell(NEW_ID, cell->type); c->setPort("\\A", new_a); c->parameters["\\A_WIDTH"] = new_a.size(); c->parameters["\\A_SIGNED"] = false; if (b_name == "\\B") { c->setPort("\\B", new_b); c->parameters["\\B_WIDTH"] = new_b.size(); c->parameters["\\B_SIGNED"] = false; } c->setPort("\\Y", new_y); c->parameters["\\Y_WIDTH"] = new_y->width; c->check(); module->connect(new_conn); log(" New cell `%s': A=%s", log_id(c), log_signal(new_a)); if (b_name == "\\B") log(", B=%s", log_signal(new_b)); log("\n"); } cover_list("opt.opt_expr.fine.group", "$not", "$pos", "$and", "$or", "$xor", "$xnor", cell->type.str()); module->remove(cell); did_something = true; return true; } void handle_polarity_inv(Cell *cell, IdString port, IdString param, const SigMap &assign_map, const dict &invert_map) { SigSpec sig = assign_map(cell->getPort(port)); if (invert_map.count(sig)) { log("Inverting %s of %s cell `%s' in module `%s': %s -> %s\n", log_id(port), log_id(cell->type), log_id(cell), log_id(cell->module), log_signal(sig), log_signal(invert_map.at(sig))); cell->setPort(port, (invert_map.at(sig))); cell->setParam(param, !cell->getParam(param).as_bool()); } } void handle_clkpol_celltype_swap(Cell *cell, string type1, string type2, IdString port, const SigMap &assign_map, const dict &invert_map) { log_assert(GetSize(type1) == GetSize(type2)); string cell_type = cell->type.str(); if (GetSize(type1) != GetSize(cell_type)) return; for (int i = 0; i < GetSize(type1); i++) { log_assert((type1[i] == '?') == (type2[i] == '?')); if (type1[i] == '?') { if (cell_type[i] != '0' && cell_type[i] != '1' && cell_type[i] != 'N' && cell_type[i] != 'P') return; type1[i] = cell_type[i]; type2[i] = cell_type[i]; } } if (cell->type.in(type1, type2)) { SigSpec sig = assign_map(cell->getPort(port)); if (invert_map.count(sig)) { log("Inverting %s of %s cell `%s' in module `%s': %s -> %s\n", log_id(port), log_id(cell->type), log_id(cell), log_id(cell->module), log_signal(sig), log_signal(invert_map.at(sig))); cell->setPort(port, (invert_map.at(sig))); cell->type = cell->type == type1 ? type2 : type1; } } } bool is_one_or_minus_one(const Const &value, bool is_signed, bool &is_negative) { bool all_bits_one = true; bool last_bit_one = true; if (GetSize(value.bits) < 1) return false; if (GetSize(value.bits) == 1) { if (value.bits[0] != State::S1) return false; if (is_signed) is_negative = true; return true; } for (int i = 0; i < GetSize(value.bits); i++) { if (value.bits[i] != State::S1) all_bits_one = false; if (value.bits[i] != (i ? State::S0 : State::S1)) last_bit_one = false; } if (all_bits_one && is_signed) { is_negative = true; return true; } return last_bit_one; } // if the signal has only one bit set, return the index of that bit. // otherwise return -1 int get_onehot_bit_index(RTLIL::SigSpec signal) { int bit_index = -1; for (int i = 0; i < GetSize(signal); i++) { if (signal[i] == RTLIL::State::S0) continue; if (signal[i] != RTLIL::State::S1) return -1; if (bit_index != -1) return -1; bit_index = i; } return bit_index; } void replace_const_cells(RTLIL::Design *design, RTLIL::Module *module, bool consume_x, bool mux_undef, bool mux_bool, bool do_fine, bool keepdc, bool clkinv) { if (!design->selected(module)) return; CellTypes ct_combinational; ct_combinational.setup_internals(); ct_combinational.setup_stdcells(); SigMap assign_map(module); dict invert_map; TopoSort> cells; dict> cell_to_inbit; dict> outbit_to_cell; for (auto cell : module->cells()) if (design->selected(module, cell) && cell->type[0] == '$') { if ((cell->type == "$_NOT_" || cell->type == "$not" || cell->type == "$logic_not") && cell->getPort("\\A").size() == 1 && cell->getPort("\\Y").size() == 1) invert_map[assign_map(cell->getPort("\\Y"))] = assign_map(cell->getPort("\\A")); if ((cell->type == "$mux" || cell->type == "$_MUX_") && cell->getPort("\\A") == SigSpec(State::S1) && cell->getPort("\\B") == SigSpec(State::S0)) invert_map[assign_map(cell->getPort("\\Y"))] = assign_map(cell->getPort("\\S")); if (ct_combinational.cell_known(cell->type)) for (auto &conn : cell->connections()) { RTLIL::SigSpec sig = assign_map(conn.second); sig.remove_const(); if (ct_combinational.cell_input(cell->type, conn.first)) cell_to_inbit[cell].insert(sig.begin(), sig.end()); if (ct_combinational.cell_output(cell->type, conn.first)) for (auto &bit : sig) outbit_to_cell[bit].insert(cell); } cells.node(cell); } for (auto &it_right : cell_to_inbit) for (auto &it_sigbit : it_right.second) for (auto &it_left : outbit_to_cell[it_sigbit]) cells.edge(it_left, it_right.first); cells.sort(); for (auto cell : cells.sorted) { #define ACTION_DO(_p_, _s_) do { cover("opt.opt_expr.action_" S__LINE__); replace_cell(assign_map, module, cell, input.as_string(), _p_, _s_); goto next_cell; } while (0) #define ACTION_DO_Y(_v_) ACTION_DO("\\Y", RTLIL::SigSpec(RTLIL::State::S ## _v_)) if (clkinv) { if (cell->type.in("$dff", "$dffe", "$dffsr", "$adff", "$fsm", "$memrd", "$memwr")) handle_polarity_inv(cell, "\\CLK", "\\CLK_POLARITY", assign_map, invert_map); if (cell->type.in("$sr", "$dffsr", "$dlatchsr")) { handle_polarity_inv(cell, "\\SET", "\\SET_POLARITY", assign_map, invert_map); handle_polarity_inv(cell, "\\CLR", "\\CLR_POLARITY", assign_map, invert_map); } if (cell->type.in("$dffe", "$dlatch", "$dlatchsr")) handle_polarity_inv(cell, "\\EN", "\\EN_POLARITY", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_SR_N?_", "$_SR_P?_", "\\S", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_SR_?N_", "$_SR_?P_", "\\R", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DFF_N_", "$_DFF_P_", "\\C", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DFFE_N?_", "$_DFFE_P?_", "\\C", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DFFE_?N_", "$_DFFE_?P_", "\\E", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DFF_N??_", "$_DFF_P??_", "\\C", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DFF_?N?_", "$_DFF_?P?_", "\\R", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DFFSR_N??_", "$_DFFSR_P??_", "\\C", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DFFSR_?N?_", "$_DFFSR_?P?_", "\\S", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DFFSR_??N_", "$_DFFSR_??P_", "\\R", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DLATCH_N_", "$_DLATCH_P_", "\\E", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DLATCHSR_N??_", "$_DLATCHSR_P??_", "\\E", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DLATCHSR_?N?_", "$_DLATCHSR_?P?_", "\\S", assign_map, invert_map); handle_clkpol_celltype_swap(cell, "$_DLATCHSR_??N_", "$_DLATCHSR_??P_", "\\R", assign_map, invert_map); } bool detect_const_and = false; bool detect_const_or = false; if (cell->type.in("$reduce_and", "$_AND_")) detect_const_and = true; if (cell->type.in("$and", "$logic_and") && GetSize(cell->getPort("\\A")) == 1 && GetSize(cell->getPort("\\B")) == 1 && !cell->getParam("\\A_SIGNED").as_bool()) detect_const_and = true; if (cell->type.in("$reduce_or", "$reduce_bool", "$_OR_")) detect_const_or = true; if (cell->type.in("$or", "$logic_or") && GetSize(cell->getPort("\\A")) == 1 && GetSize(cell->getPort("\\B")) == 1 && !cell->getParam("\\A_SIGNED").as_bool()) detect_const_or = true; if (detect_const_and || detect_const_or) { pool input_bits = assign_map(cell->getPort("\\A")).to_sigbit_pool(); bool found_zero = false, found_one = false, found_undef = false, found_inv = false, many_conconst = false; SigBit non_const_input = State::Sm; if (cell->hasPort("\\B")) { vector more_bits = assign_map(cell->getPort("\\B")).to_sigbit_vector(); input_bits.insert(more_bits.begin(), more_bits.end()); } for (auto bit : input_bits) { if (bit.wire) { if (invert_map.count(bit) && input_bits.count(invert_map.at(bit))) found_inv = true; if (non_const_input != State::Sm) many_conconst = true; non_const_input = many_conconst ? State::Sm : bit; } else { if (bit == State::S0) found_zero = true; else if (bit == State::S1) found_one = true; else found_undef = true; } } if (detect_const_and && (found_zero || found_inv)) { cover("opt.opt_expr.const_and"); replace_cell(assign_map, module, cell, "const_and", "\\Y", RTLIL::State::S0); goto next_cell; } if (detect_const_or && (found_one || found_inv)) { cover("opt.opt_expr.const_or"); replace_cell(assign_map, module, cell, "const_or", "\\Y", RTLIL::State::S1); goto next_cell; } if (non_const_input != State::Sm && !found_undef) { cover("opt.opt_expr.and_or_buffer"); replace_cell(assign_map, module, cell, "and_or_buffer", "\\Y", non_const_input); goto next_cell; } } if (cell->type.in("$reduce_and", "$reduce_or", "$reduce_bool", "$reduce_xor", "$reduce_xnor", "$neg") && GetSize(cell->getPort("\\A")) == 1 && GetSize(cell->getPort("\\Y")) == 1) { if (cell->type == "$reduce_xnor") { cover("opt.opt_expr.reduce_xnor_not"); log("Replacing %s cell `%s' in module `%s' with $not cell.\n", log_id(cell->type), log_id(cell->name), log_id(module)); cell->type = "$not"; } else { cover("opt.opt_expr.unary_buffer"); replace_cell(assign_map, module, cell, "unary_buffer", "\\Y", cell->getPort("\\A")); } goto next_cell; } if (do_fine) { if (cell->type == "$not" || cell->type == "$pos" || cell->type == "$and" || cell->type == "$or" || cell->type == "$xor" || cell->type == "$xnor") if (group_cell_inputs(module, cell, true, assign_map)) goto next_cell; if (cell->type == "$logic_not" || cell->type == "$logic_and" || cell->type == "$logic_or" || cell->type == "$reduce_or" || cell->type == "$reduce_and" || cell->type == "$reduce_bool") { SigBit neutral_bit = cell->type == "$reduce_and" ? State::S1 : State::S0; RTLIL::SigSpec sig_a = assign_map(cell->getPort("\\A")); RTLIL::SigSpec new_sig_a; for (auto bit : sig_a) if (bit != neutral_bit) new_sig_a.append(bit); if (GetSize(new_sig_a) == 0) new_sig_a.append(neutral_bit); if (GetSize(new_sig_a) < GetSize(sig_a)) { cover_list("opt.opt_expr.fine.neutral_A", "$logic_not", "$logic_and", "$logic_or", "$reduce_or", "$reduce_and", "$reduce_bool", cell->type.str()); log("Replacing port A of %s cell `%s' in module `%s' with shorter expression: %s -> %s\n", cell->type.c_str(), cell->name.c_str(), module->name.c_str(), log_signal(sig_a), log_signal(new_sig_a)); cell->setPort("\\A", new_sig_a); cell->parameters.at("\\A_WIDTH") = GetSize(new_sig_a); did_something = true; } } if (cell->type == "$logic_and" || cell->type == "$logic_or") { SigBit neutral_bit = State::S0; RTLIL::SigSpec sig_b = assign_map(cell->getPort("\\B")); RTLIL::SigSpec new_sig_b; for (auto bit : sig_b) if (bit != neutral_bit) new_sig_b.append(bit); if (GetSize(new_sig_b) == 0) new_sig_b.append(neutral_bit); if (GetSize(new_sig_b) < GetSize(sig_b)) { cover_list("opt.opt_expr.fine.neutral_B", "$logic_and", "$logic_or", cell->type.str()); log("Replacing port B of %s cell `%s' in module `%s' with shorter expression: %s -> %s\n", cell->type.c_str(), cell->name.c_str(), module->name.c_str(), log_signal(sig_b), log_signal(new_sig_b)); cell->setPort("\\B", new_sig_b); cell->parameters.at("\\B_WIDTH") = GetSize(new_sig_b); did_something = true; } } if (cell->type == "$reduce_and") { RTLIL::SigSpec sig_a = assign_map(cell->getPort("\\A")); RTLIL::State new_a = RTLIL::State::S1; for (auto &bit : sig_a.to_sigbit_vector()) if (bit == RTLIL::State::Sx) { if (new_a == RTLIL::State::S1) new_a = RTLIL::State::Sx; } else if (bit == RTLIL::State::S0) { new_a = RTLIL::State::S0; break; } else if (bit.wire != NULL) { new_a = RTLIL::State::Sm; } if (new_a != RTLIL::State::Sm && RTLIL::SigSpec(new_a) != sig_a) { cover("opt.opt_expr.fine.$reduce_and"); log("Replacing port A of %s cell `%s' in module `%s' with constant driver: %s -> %s\n", cell->type.c_str(), cell->name.c_str(), module->name.c_str(), log_signal(sig_a), log_signal(new_a)); cell->setPort("\\A", sig_a = new_a); cell->parameters.at("\\A_WIDTH") = 1; did_something = true; } } if (cell->type == "$logic_not" || cell->type == "$logic_and" || cell->type == "$logic_or" || cell->type == "$reduce_or" || cell->type == "$reduce_bool") { RTLIL::SigSpec sig_a = assign_map(cell->getPort("\\A")); RTLIL::State new_a = RTLIL::State::S0; for (auto &bit : sig_a.to_sigbit_vector()) if (bit == RTLIL::State::Sx) { if (new_a == RTLIL::State::S0) new_a = RTLIL::State::Sx; } else if (bit == RTLIL::State::S1) { new_a = RTLIL::State::S1; break; } else if (bit.wire != NULL) { new_a = RTLIL::State::Sm; } if (new_a != RTLIL::State::Sm && RTLIL::SigSpec(new_a) != sig_a) { cover_list("opt.opt_expr.fine.A", "$logic_not", "$logic_and", "$logic_or", "$reduce_or", "$reduce_bool", cell->type.str()); log("Replacing port A of %s cell `%s' in module `%s' with constant driver: %s -> %s\n", cell->type.c_str(), cell->name.c_str(), module->name.c_str(), log_signal(sig_a), log_signal(new_a)); cell->setPort("\\A", sig_a = new_a); cell->parameters.at("\\A_WIDTH") = 1; did_something = true; } } if (cell->type == "$logic_and" || cell->type == "$logic_or") { RTLIL::SigSpec sig_b = assign_map(cell->getPort("\\B")); RTLIL::State new_b = RTLIL::State::S0; for (auto &bit : sig_b.to_sigbit_vector()) if (bit == RTLIL::State::Sx) { if (new_b == RTLIL::State::S0) new_b = RTLIL::State::Sx; } else if (bit == RTLIL::State::S1) { new_b = RTLIL::State::S1; break; } else if (bit.wire != NULL) { new_b = RTLIL::State::Sm; } if (new_b != RTLIL::State::Sm && RTLIL::SigSpec(new_b) != sig_b) { cover_list("opt.opt_expr.fine.B", "$logic_and", "$logic_or", cell->type.str()); log("Replacing port B of %s cell `%s' in module `%s' with constant driver: %s -> %s\n", cell->type.c_str(), cell->name.c_str(), module->name.c_str(), log_signal(sig_b), log_signal(new_b)); cell->setPort("\\B", sig_b = new_b); cell->parameters.at("\\B_WIDTH") = 1; did_something = true; } } } if (cell->type == "$reduce_xor" || cell->type == "$reduce_xnor" || cell->type == "$shift" || cell->type == "$shiftx" || cell->type == "$shl" || cell->type == "$shr" || cell->type == "$sshl" || cell->type == "$sshr" || cell->type == "$lt" || cell->type == "$le" || cell->type == "$ge" || cell->type == "$gt" || cell->type == "$neg" || cell->type == "$add" || cell->type == "$sub" || cell->type == "$mul" || cell->type == "$div" || cell->type == "$mod" || cell->type == "$pow") { RTLIL::SigSpec sig_a = assign_map(cell->getPort("\\A")); RTLIL::SigSpec sig_b = cell->hasPort("\\B") ? assign_map(cell->getPort("\\B")) : RTLIL::SigSpec(); if (cell->type == "$shl" || cell->type == "$shr" || cell->type == "$sshl" || cell->type == "$sshr" || cell->type == "$shift" || cell->type == "$shiftx") sig_a = RTLIL::SigSpec(); for (auto &bit : sig_a.to_sigbit_vector()) if (bit == RTLIL::State::Sx) goto found_the_x_bit; for (auto &bit : sig_b.to_sigbit_vector()) if (bit == RTLIL::State::Sx) goto found_the_x_bit; if (0) { found_the_x_bit: cover_list("opt.opt_expr.xbit", "$reduce_xor", "$reduce_xnor", "$shl", "$shr", "$sshl", "$sshr", "$shift", "$shiftx", "$lt", "$le", "$ge", "$gt", "$neg", "$add", "$sub", "$mul", "$div", "$mod", "$pow", cell->type.str()); if (cell->type == "$reduce_xor" || cell->type == "$reduce_xnor" || cell->type == "$lt" || cell->type == "$le" || cell->type == "$ge" || cell->type == "$gt") replace_cell(assign_map, module, cell, "x-bit in input", "\\Y", RTLIL::State::Sx); else replace_cell(assign_map, module, cell, "x-bit in input", "\\Y", RTLIL::SigSpec(RTLIL::State::Sx, cell->getPort("\\Y").size())); goto next_cell; } } if ((cell->type == "$_NOT_" || cell->type == "$not" || cell->type == "$logic_not") && cell->getPort("\\Y").size() == 1 && invert_map.count(assign_map(cell->getPort("\\A"))) != 0) { cover_list("opt.opt_expr.invert.double", "$_NOT_", "$not", "$logic_not", cell->type.str()); replace_cell(assign_map, module, cell, "double_invert", "\\Y", invert_map.at(assign_map(cell->getPort("\\A")))); goto next_cell; } if ((cell->type == "$_MUX_" || cell->type == "$mux") && invert_map.count(assign_map(cell->getPort("\\S"))) != 0) { cover_list("opt.opt_expr.invert.muxsel", "$_MUX_", "$mux", cell->type.str()); log("Optimizing away select inverter for %s cell `%s' in module `%s'.\n", log_id(cell->type), log_id(cell), log_id(module)); RTLIL::SigSpec tmp = cell->getPort("\\A"); cell->setPort("\\A", cell->getPort("\\B")); cell->setPort("\\B", tmp); cell->setPort("\\S", invert_map.at(assign_map(cell->getPort("\\S")))); did_something = true; goto next_cell; } if (cell->type == "$_NOT_") { RTLIL::SigSpec input = cell->getPort("\\A"); assign_map.apply(input); if (input.match("1")) ACTION_DO_Y(0); if (input.match("0")) ACTION_DO_Y(1); if (input.match("*")) ACTION_DO_Y(x); } if (cell->type == "$_AND_") { RTLIL::SigSpec input; input.append(cell->getPort("\\B")); input.append(cell->getPort("\\A")); assign_map.apply(input); if (input.match(" 0")) ACTION_DO_Y(0); if (input.match("0 ")) ACTION_DO_Y(0); if (input.match("11")) ACTION_DO_Y(1); if (input.match("**")) ACTION_DO_Y(x); if (input.match("1*")) ACTION_DO_Y(x); if (input.match("*1")) ACTION_DO_Y(x); if (consume_x) { if (input.match(" *")) ACTION_DO_Y(0); if (input.match("* ")) ACTION_DO_Y(0); } if (input.match(" 1")) ACTION_DO("\\Y", input.extract(1, 1)); if (input.match("1 ")) ACTION_DO("\\Y", input.extract(0, 1)); } if (cell->type == "$_OR_") { RTLIL::SigSpec input; input.append(cell->getPort("\\B")); input.append(cell->getPort("\\A")); assign_map.apply(input); if (input.match(" 1")) ACTION_DO_Y(1); if (input.match("1 ")) ACTION_DO_Y(1); if (input.match("00")) ACTION_DO_Y(0); if (input.match("**")) ACTION_DO_Y(x); if (input.match("0*")) ACTION_DO_Y(x); if (input.match("*0")) ACTION_DO_Y(x); if (consume_x) { if (input.match(" *")) ACTION_DO_Y(1); if (input.match("* ")) ACTION_DO_Y(1); } if (input.match(" 0")) ACTION_DO("\\Y", input.extract(1, 1)); if (input.match("0 ")) ACTION_DO("\\Y", input.extract(0, 1)); } if (cell->type == "$_XOR_") { RTLIL::SigSpec input; input.append(cell->getPort("\\B")); input.append(cell->getPort("\\A")); assign_map.apply(input); if (input.match("00")) ACTION_DO_Y(0); if (input.match("01")) ACTION_DO_Y(1); if (input.match("10")) ACTION_DO_Y(1); if (input.match("11")) ACTION_DO_Y(0); if (input.match(" *")) ACTION_DO_Y(x); if (input.match("* ")) ACTION_DO_Y(x); if (input.match(" 0")) ACTION_DO("\\Y", input.extract(1, 1)); if (input.match("0 ")) ACTION_DO("\\Y", input.extract(0, 1)); } if (cell->type == "$_MUX_") { RTLIL::SigSpec input; input.append(cell->getPort("\\S")); input.append(cell->getPort("\\B")); input.append(cell->getPort("\\A")); assign_map.apply(input); if (input.extract(2, 1) == input.extract(1, 1)) ACTION_DO("\\Y", input.extract(2, 1)); if (input.match(" 0")) ACTION_DO("\\Y", input.extract(2, 1)); if (input.match(" 1")) ACTION_DO("\\Y", input.extract(1, 1)); if (input.match("01 ")) ACTION_DO("\\Y", input.extract(0, 1)); if (input.match("10 ")) { cover("opt.opt_expr.mux_to_inv"); cell->type = "$_NOT_"; cell->setPort("\\A", input.extract(0, 1)); cell->unsetPort("\\B"); cell->unsetPort("\\S"); goto next_cell; } if (input.match("11 ")) ACTION_DO_Y(1); if (input.match("00 ")) ACTION_DO_Y(0); if (input.match("** ")) ACTION_DO_Y(x); if (input.match("01*")) ACTION_DO_Y(x); if (input.match("10*")) ACTION_DO_Y(x); if (mux_undef) { if (input.match("* ")) ACTION_DO("\\Y", input.extract(1, 1)); if (input.match(" * ")) ACTION_DO("\\Y", input.extract(2, 1)); if (input.match(" *")) ACTION_DO("\\Y", input.extract(2, 1)); } } if (cell->type == "$_TBUF_" || cell->type == "$tribuf") { RTLIL::SigSpec input = cell->getPort(cell->type == "$_TBUF_" ? "\\E" : "\\EN"); RTLIL::SigSpec a = cell->getPort("\\A"); assign_map.apply(input); assign_map.apply(a); if (input == State::S1) ACTION_DO("\\Y", cell->getPort("\\A")); if (input == State::S0 && !a.is_fully_undef()) { cover("opt.opt_expr.action_" S__LINE__); log("Replacing data input of %s cell `%s' in module `%s' with constant undef.\n", cell->type.c_str(), cell->name.c_str(), module->name.c_str()); cell->setPort("\\A", SigSpec(State::Sx, GetSize(a))); did_something = true; goto next_cell; } } if (cell->type == "$eq" || cell->type == "$ne" || cell->type == "$eqx" || cell->type == "$nex") { RTLIL::SigSpec a = cell->getPort("\\A"); RTLIL::SigSpec b = cell->getPort("\\B"); if (cell->parameters["\\A_WIDTH"].as_int() != cell->parameters["\\B_WIDTH"].as_int()) { int width = max(cell->parameters["\\A_WIDTH"].as_int(), cell->parameters["\\B_WIDTH"].as_int()); a.extend_u0(width, cell->parameters["\\A_SIGNED"].as_bool() && cell->parameters["\\B_SIGNED"].as_bool()); b.extend_u0(width, cell->parameters["\\A_SIGNED"].as_bool() && cell->parameters["\\B_SIGNED"].as_bool()); } RTLIL::SigSpec new_a, new_b; log_assert(GetSize(a) == GetSize(b)); for (int i = 0; i < GetSize(a); i++) { if (a[i].wire == NULL && b[i].wire == NULL && a[i] != b[i] && a[i].data <= RTLIL::State::S1 && b[i].data <= RTLIL::State::S1) { cover_list("opt.opt_expr.eqneq.isneq", "$eq", "$ne", "$eqx", "$nex", cell->type.str()); RTLIL::SigSpec new_y = RTLIL::SigSpec((cell->type == "$eq" || cell->type == "$eqx") ? RTLIL::State::S0 : RTLIL::State::S1); new_y.extend_u0(cell->parameters["\\Y_WIDTH"].as_int(), false); replace_cell(assign_map, module, cell, "isneq", "\\Y", new_y); goto next_cell; } if (a[i] == b[i]) continue; new_a.append(a[i]); new_b.append(b[i]); } if (new_a.size() == 0) { cover_list("opt.opt_expr.eqneq.empty", "$eq", "$ne", "$eqx", "$nex", cell->type.str()); RTLIL::SigSpec new_y = RTLIL::SigSpec((cell->type == "$eq" || cell->type == "$eqx") ? RTLIL::State::S1 : RTLIL::State::S0); new_y.extend_u0(cell->parameters["\\Y_WIDTH"].as_int(), false); replace_cell(assign_map, module, cell, "empty", "\\Y", new_y); goto next_cell; } if (new_a.size() < a.size() || new_b.size() < b.size()) { cover_list("opt.opt_expr.eqneq.resize", "$eq", "$ne", "$eqx", "$nex", cell->type.str()); cell->setPort("\\A", new_a); cell->setPort("\\B", new_b); cell->parameters["\\A_WIDTH"] = new_a.size(); cell->parameters["\\B_WIDTH"] = new_b.size(); } } if ((cell->type == "$eq" || cell->type == "$ne") && cell->parameters["\\Y_WIDTH"].as_int() == 1 && cell->parameters["\\A_WIDTH"].as_int() == 1 && cell->parameters["\\B_WIDTH"].as_int() == 1) { RTLIL::SigSpec a = assign_map(cell->getPort("\\A")); RTLIL::SigSpec b = assign_map(cell->getPort("\\B")); if (a.is_fully_const() && !b.is_fully_const()) { cover_list("opt.opt_expr.eqneq.swapconst", "$eq", "$ne", cell->type.str()); cell->setPort("\\A", b); cell->setPort("\\B", a); std::swap(a, b); } if (b.is_fully_const()) { if (b.as_bool() == (cell->type == "$eq")) { RTLIL::SigSpec input = b; ACTION_DO("\\Y", cell->getPort("\\A")); } else { cover_list("opt.opt_expr.eqneq.isnot", "$eq", "$ne", cell->type.str()); log("Replacing %s cell `%s' in module `%s' with inverter.\n", log_id(cell->type), log_id(cell), log_id(module)); cell->type = "$not"; cell->parameters.erase("\\B_WIDTH"); cell->parameters.erase("\\B_SIGNED"); cell->unsetPort("\\B"); did_something = true; } goto next_cell; } } if ((cell->type == "$eq" || cell->type == "$ne") && (assign_map(cell->getPort("\\A")).is_fully_zero() || assign_map(cell->getPort("\\B")).is_fully_zero())) { cover_list("opt.opt_expr.eqneq.cmpzero", "$eq", "$ne", cell->type.str()); log("Replacing %s cell `%s' in module `%s' with %s.\n", log_id(cell->type), log_id(cell), log_id(module), "$eq" ? "$logic_not" : "$reduce_bool"); cell->type = cell->type == "$eq" ? "$logic_not" : "$reduce_bool"; if (assign_map(cell->getPort("\\A")).is_fully_zero()) { cell->setPort("\\A", cell->getPort("\\B")); cell->setParam("\\A_SIGNED", cell->getParam("\\B_SIGNED")); cell->setParam("\\A_WIDTH", cell->getParam("\\B_WIDTH")); } cell->unsetPort("\\B"); cell->unsetParam("\\B_SIGNED"); cell->unsetParam("\\B_WIDTH"); did_something = true; goto next_cell; } if (cell->type.in("$shl", "$shr", "$sshl", "$sshr", "$shift", "$shiftx") && assign_map(cell->getPort("\\B")).is_fully_const()) { bool sign_ext = cell->type == "$sshr" && cell->getParam("\\A_SIGNED").as_bool(); int shift_bits = assign_map(cell->getPort("\\B")).as_int(cell->type.in("$shift", "$shiftx") && cell->getParam("\\B_SIGNED").as_bool()); if (cell->type.in("$shl", "$sshl")) shift_bits *= -1; RTLIL::SigSpec sig_a = assign_map(cell->getPort("\\A")); RTLIL::SigSpec sig_y(cell->type == "$shiftx" ? RTLIL::State::Sx : RTLIL::State::S0, cell->getParam("\\Y_WIDTH").as_int()); if (GetSize(sig_a) < GetSize(sig_y)) sig_a.extend_u0(GetSize(sig_y), cell->getParam("\\A_SIGNED").as_bool()); for (int i = 0; i < GetSize(sig_y); i++) { int idx = i + shift_bits; if (0 <= idx && idx < GetSize(sig_a)) sig_y[i] = sig_a[idx]; else if (GetSize(sig_a) <= idx && sign_ext) sig_y[i] = sig_a[GetSize(sig_a)-1]; } cover_list("opt.opt_expr.constshift", "$shl", "$shr", "$sshl", "$sshr", "$shift", "$shiftx", cell->type.str()); log("Replacing %s cell `%s' (B=%s, SHR=%d) in module `%s' with fixed wiring: %s\n", log_id(cell->type), log_id(cell), log_signal(assign_map(cell->getPort("\\B"))), shift_bits, log_id(module), log_signal(sig_y)); module->connect(cell->getPort("\\Y"), sig_y); module->remove(cell); did_something = true; goto next_cell; } if (!keepdc) { bool identity_wrt_a = false; bool identity_wrt_b = false; bool arith_inverse = false; if (cell->type == "$add" || cell->type == "$sub" || cell->type == "$or" || cell->type == "$xor") { RTLIL::SigSpec a = assign_map(cell->getPort("\\A")); RTLIL::SigSpec b = assign_map(cell->getPort("\\B")); if (cell->type != "$sub" && a.is_fully_const() && a.as_bool() == false) identity_wrt_b = true; if (b.is_fully_const() && b.as_bool() == false) identity_wrt_a = true; } if (cell->type == "$shl" || cell->type == "$shr" || cell->type == "$sshl" || cell->type == "$sshr" || cell->type == "$shift" || cell->type == "$shiftx") { RTLIL::SigSpec b = assign_map(cell->getPort("\\B")); if (b.is_fully_const() && b.as_bool() == false) identity_wrt_a = true; } if (cell->type == "$mul") { RTLIL::SigSpec a = assign_map(cell->getPort("\\A")); RTLIL::SigSpec b = assign_map(cell->getPort("\\B")); if (a.is_fully_const() && is_one_or_minus_one(a.as_const(), cell->getParam("\\A_SIGNED").as_bool(), arith_inverse)) identity_wrt_b = true; else if (b.is_fully_const() && is_one_or_minus_one(b.as_const(), cell->getParam("\\B_SIGNED").as_bool(), arith_inverse)) identity_wrt_a = true; } if (cell->type == "$div") { RTLIL::SigSpec b = assign_map(cell->getPort("\\B")); if (b.is_fully_const() && b.size() <= 32 && b.as_int() == 1) identity_wrt_a = true; } if (identity_wrt_a || identity_wrt_b) { if (identity_wrt_a) cover_list("opt.opt_expr.identwrt.a", "$add", "$sub", "$or", "$xor", "$shl", "$shr", "$sshl", "$sshr", "$shift", "$shiftx", "$mul", "$div", cell->type.str()); if (identity_wrt_b) cover_list("opt.opt_expr.identwrt.b", "$add", "$sub", "$or", "$xor", "$shl", "$shr", "$sshl", "$sshr", "$shift", "$shiftx", "$mul", "$div", cell->type.str()); log("Replacing %s cell `%s' in module `%s' with identity for port %c.\n", cell->type.c_str(), cell->name.c_str(), module->name.c_str(), identity_wrt_a ? 'A' : 'B'); if (!identity_wrt_a) { cell->setPort("\\A", cell->getPort("\\B")); cell->parameters.at("\\A_WIDTH") = cell->parameters.at("\\B_WIDTH"); cell->parameters.at("\\A_SIGNED") = cell->parameters.at("\\B_SIGNED"); } cell->type = arith_inverse ? "$neg" : "$pos"; cell->unsetPort("\\B"); cell->parameters.erase("\\B_WIDTH"); cell->parameters.erase("\\B_SIGNED"); cell->check(); did_something = true; goto next_cell; } } if (mux_bool && (cell->type == "$mux" || cell->type == "$_MUX_") && cell->getPort("\\A") == RTLIL::SigSpec(0, 1) && cell->getPort("\\B") == RTLIL::SigSpec(1, 1)) { cover_list("opt.opt_expr.mux_bool", "$mux", "$_MUX_", cell->type.str()); replace_cell(assign_map, module, cell, "mux_bool", "\\Y", cell->getPort("\\S")); goto next_cell; } if (mux_bool && (cell->type == "$mux" || cell->type == "$_MUX_") && cell->getPort("\\A") == RTLIL::SigSpec(1, 1) && cell->getPort("\\B") == RTLIL::SigSpec(0, 1)) { cover_list("opt.opt_expr.mux_invert", "$mux", "$_MUX_", cell->type.str()); log("Replacing %s cell `%s' in module `%s' with inverter.\n", log_id(cell->type), log_id(cell), log_id(module)); cell->setPort("\\A", cell->getPort("\\S")); cell->unsetPort("\\B"); cell->unsetPort("\\S"); if (cell->type == "$mux") { Const width = cell->parameters["\\WIDTH"]; cell->parameters["\\A_WIDTH"] = width; cell->parameters["\\Y_WIDTH"] = width; cell->parameters["\\A_SIGNED"] = 0; cell->parameters.erase("\\WIDTH"); cell->type = "$not"; } else cell->type = "$_NOT_"; did_something = true; goto next_cell; } if (consume_x && mux_bool && (cell->type == "$mux" || cell->type == "$_MUX_") && cell->getPort("\\A") == RTLIL::SigSpec(0, 1)) { cover_list("opt.opt_expr.mux_and", "$mux", "$_MUX_", cell->type.str()); log("Replacing %s cell `%s' in module `%s' with and-gate.\n", log_id(cell->type), log_id(cell), log_id(module)); cell->setPort("\\A", cell->getPort("\\S")); cell->unsetPort("\\S"); if (cell->type == "$mux") { Const width = cell->parameters["\\WIDTH"]; cell->parameters["\\A_WIDTH"] = width; cell->parameters["\\B_WIDTH"] = width; cell->parameters["\\Y_WIDTH"] = width; cell->parameters["\\A_SIGNED"] = 0; cell->parameters["\\B_SIGNED"] = 0; cell->parameters.erase("\\WIDTH"); cell->type = "$and"; } else cell->type = "$_AND_"; did_something = true; goto next_cell; } if (consume_x && mux_bool && (cell->type == "$mux" || cell->type == "$_MUX_") && cell->getPort("\\B") == RTLIL::SigSpec(1, 1)) { cover_list("opt.opt_expr.mux_or", "$mux", "$_MUX_", cell->type.str()); log("Replacing %s cell `%s' in module `%s' with or-gate.\n", log_id(cell->type), log_id(cell), log_id(module)); cell->setPort("\\B", cell->getPort("\\S")); cell->unsetPort("\\S"); if (cell->type == "$mux") { Const width = cell->parameters["\\WIDTH"]; cell->parameters["\\A_WIDTH"] = width; cell->parameters["\\B_WIDTH"] = width; cell->parameters["\\Y_WIDTH"] = width; cell->parameters["\\A_SIGNED"] = 0; cell->parameters["\\B_SIGNED"] = 0; cell->parameters.erase("\\WIDTH"); cell->type = "$or"; } else cell->type = "$_OR_"; did_something = true; goto next_cell; } if (mux_undef && (cell->type == "$mux" || cell->type == "$pmux")) { RTLIL::SigSpec new_a, new_b, new_s; int width = cell->getPort("\\A").size(); if ((cell->getPort("\\A").is_fully_undef() && cell->getPort("\\B").is_fully_undef()) || cell->getPort("\\S").is_fully_undef()) { cover_list("opt.opt_expr.mux_undef", "$mux", "$pmux", cell->type.str()); replace_cell(assign_map, module, cell, "mux_undef", "\\Y", cell->getPort("\\A")); goto next_cell; } for (int i = 0; i < cell->getPort("\\S").size(); i++) { RTLIL::SigSpec old_b = cell->getPort("\\B").extract(i*width, width); RTLIL::SigSpec old_s = cell->getPort("\\S").extract(i, 1); if (old_b.is_fully_undef() || old_s.is_fully_undef()) continue; new_b.append(old_b); new_s.append(old_s); } new_a = cell->getPort("\\A"); if (new_a.is_fully_undef() && new_s.size() > 0) { new_a = new_b.extract((new_s.size()-1)*width, width); new_b = new_b.extract(0, (new_s.size()-1)*width); new_s = new_s.extract(0, new_s.size()-1); } if (new_s.size() == 0) { cover_list("opt.opt_expr.mux_empty", "$mux", "$pmux", cell->type.str()); replace_cell(assign_map, module, cell, "mux_empty", "\\Y", new_a); goto next_cell; } if (new_a == RTLIL::SigSpec(RTLIL::State::S0) && new_b == RTLIL::SigSpec(RTLIL::State::S1)) { cover_list("opt.opt_expr.mux_sel01", "$mux", "$pmux", cell->type.str()); replace_cell(assign_map, module, cell, "mux_sel01", "\\Y", new_s); goto next_cell; } if (cell->getPort("\\S").size() != new_s.size()) { cover_list("opt.opt_expr.mux_reduce", "$mux", "$pmux", cell->type.str()); log("Optimized away %d select inputs of %s cell `%s' in module `%s'.\n", GetSize(cell->getPort("\\S")) - GetSize(new_s), log_id(cell->type), log_id(cell), log_id(module)); cell->setPort("\\A", new_a); cell->setPort("\\B", new_b); cell->setPort("\\S", new_s); if (new_s.size() > 1) { cell->type = "$pmux"; cell->parameters["\\S_WIDTH"] = new_s.size(); } else { cell->type = "$mux"; cell->parameters.erase("\\S_WIDTH"); } did_something = true; } } #define FOLD_1ARG_CELL(_t) \ if (cell->type == "$" #_t) { \ RTLIL::SigSpec a = cell->getPort("\\A"); \ assign_map.apply(a); \ if (a.is_fully_const()) { \ RTLIL::Const dummy_arg(RTLIL::State::S0, 1); \ RTLIL::SigSpec y(RTLIL::const_ ## _t(a.as_const(), dummy_arg, \ cell->parameters["\\A_SIGNED"].as_bool(), false, \ cell->parameters["\\Y_WIDTH"].as_int())); \ cover("opt.opt_expr.const.$" #_t); \ replace_cell(assign_map, module, cell, stringf("%s", log_signal(a)), "\\Y", y); \ goto next_cell; \ } \ } #define FOLD_2ARG_CELL(_t) \ if (cell->type == "$" #_t) { \ RTLIL::SigSpec a = cell->getPort("\\A"); \ RTLIL::SigSpec b = cell->getPort("\\B"); \ assign_map.apply(a), assign_map.apply(b); \ if (a.is_fully_const() && b.is_fully_const()) { \ RTLIL::SigSpec y(RTLIL::const_ ## _t(a.as_const(), b.as_const(), \ cell->parameters["\\A_SIGNED"].as_bool(), \ cell->parameters["\\B_SIGNED"].as_bool(), \ cell->parameters["\\Y_WIDTH"].as_int())); \ cover("opt.opt_expr.const.$" #_t); \ replace_cell(assign_map, module, cell, stringf("%s, %s", log_signal(a), log_signal(b)), "\\Y", y); \ goto next_cell; \ } \ } FOLD_1ARG_CELL(not) FOLD_2ARG_CELL(and) FOLD_2ARG_CELL(or) FOLD_2ARG_CELL(xor) FOLD_2ARG_CELL(xnor) FOLD_1ARG_CELL(reduce_and) FOLD_1ARG_CELL(reduce_or) FOLD_1ARG_CELL(reduce_xor) FOLD_1ARG_CELL(reduce_xnor) FOLD_1ARG_CELL(reduce_bool) FOLD_1ARG_CELL(logic_not) FOLD_2ARG_CELL(logic_and) FOLD_2ARG_CELL(logic_or) FOLD_2ARG_CELL(shl) FOLD_2ARG_CELL(shr) FOLD_2ARG_CELL(sshl) FOLD_2ARG_CELL(sshr) FOLD_2ARG_CELL(shift) FOLD_2ARG_CELL(shiftx) FOLD_2ARG_CELL(lt) FOLD_2ARG_CELL(le) FOLD_2ARG_CELL(eq) FOLD_2ARG_CELL(ne) FOLD_2ARG_CELL(gt) FOLD_2ARG_CELL(ge) FOLD_2ARG_CELL(add) FOLD_2ARG_CELL(sub) FOLD_2ARG_CELL(mul) FOLD_2ARG_CELL(div) FOLD_2ARG_CELL(mod) FOLD_2ARG_CELL(pow) FOLD_1ARG_CELL(pos) FOLD_1ARG_CELL(neg) // be very conservative with optimizing $mux cells as we do not want to break mux trees if (cell->type == "$mux") { RTLIL::SigSpec input = assign_map(cell->getPort("\\S")); RTLIL::SigSpec inA = assign_map(cell->getPort("\\A")); RTLIL::SigSpec inB = assign_map(cell->getPort("\\B")); if (input.is_fully_const()) ACTION_DO("\\Y", input.as_bool() ? cell->getPort("\\B") : cell->getPort("\\A")); else if (inA == inB) ACTION_DO("\\Y", cell->getPort("\\A")); } if (!keepdc && cell->type == "$mul") { bool a_signed = cell->parameters["\\A_SIGNED"].as_bool(); bool b_signed = cell->parameters["\\B_SIGNED"].as_bool(); bool swapped_ab = false; RTLIL::SigSpec sig_a = assign_map(cell->getPort("\\A")); RTLIL::SigSpec sig_b = assign_map(cell->getPort("\\B")); RTLIL::SigSpec sig_y = assign_map(cell->getPort("\\Y")); if (sig_b.is_fully_const() && sig_b.size() <= 32) std::swap(sig_a, sig_b), std::swap(a_signed, b_signed), swapped_ab = true; if (sig_a.is_fully_def() && sig_a.size() <= 32) { int a_val = sig_a.as_int(); if (a_val == 0) { cover("opt.opt_expr.mul_shift.zero"); log("Replacing multiply-by-zero cell `%s' in module `%s' with zero-driver.\n", cell->name.c_str(), module->name.c_str()); module->connect(RTLIL::SigSig(sig_y, RTLIL::SigSpec(0, sig_y.size()))); module->remove(cell); did_something = true; goto next_cell; } for (int i = 1; i < (a_signed ? sig_a.size()-1 : sig_a.size()); i++) if (a_val == (1 << i)) { if (swapped_ab) cover("opt.opt_expr.mul_shift.swapped"); else cover("opt.opt_expr.mul_shift.unswapped"); log("Replacing multiply-by-%d cell `%s' in module `%s' with shift-by-%d.\n", a_val, cell->name.c_str(), module->name.c_str(), i); if (!swapped_ab) { cell->setPort("\\A", cell->getPort("\\B")); cell->parameters.at("\\A_WIDTH") = cell->parameters.at("\\B_WIDTH"); cell->parameters.at("\\A_SIGNED") = cell->parameters.at("\\B_SIGNED"); } std::vector new_b = RTLIL::SigSpec(i, 6); while (GetSize(new_b) > 1 && new_b.back() == RTLIL::State::S0) new_b.pop_back(); cell->type = "$shl"; cell->parameters["\\B_WIDTH"] = GetSize(new_b); cell->parameters["\\B_SIGNED"] = false; cell->setPort("\\B", new_b); cell->check(); did_something = true; goto next_cell; } } } if (!keepdc && cell->type.in("$div", "$mod")) { bool b_signed = cell->parameters["\\B_SIGNED"].as_bool(); SigSpec sig_b = assign_map(cell->getPort("\\B")); SigSpec sig_y = assign_map(cell->getPort("\\Y")); if (sig_b.is_fully_def() && sig_b.size() <= 32) { int b_val = sig_b.as_int(); if (b_val == 0) { cover("opt.opt_expr.divmod_zero"); log("Replacing divide-by-zero cell `%s' in module `%s' with undef-driver.\n", cell->name.c_str(), module->name.c_str()); module->connect(RTLIL::SigSig(sig_y, RTLIL::SigSpec(State::Sx, sig_y.size()))); module->remove(cell); did_something = true; goto next_cell; } for (int i = 1; i < (b_signed ? sig_b.size()-1 : sig_b.size()); i++) if (b_val == (1 << i)) { if (cell->type == "$div") { cover("opt.opt_expr.div_shift"); log("Replacing divide-by-%d cell `%s' in module `%s' with shift-by-%d.\n", b_val, cell->name.c_str(), module->name.c_str(), i); std::vector new_b = RTLIL::SigSpec(i, 6); while (GetSize(new_b) > 1 && new_b.back() == RTLIL::State::S0) new_b.pop_back(); cell->type = "$shr"; cell->parameters["\\B_WIDTH"] = GetSize(new_b); cell->parameters["\\B_SIGNED"] = false; cell->setPort("\\B", new_b); cell->check(); } else { cover("opt.opt_expr.mod_mask"); log("Replacing modulo-by-%d cell `%s' in module `%s' with bitmask.\n", b_val, cell->name.c_str(), module->name.c_str()); std::vector new_b = RTLIL::SigSpec(State::S1, i); if (b_signed) new_b.push_back(State::S0); cell->type = "$and"; cell->parameters["\\B_WIDTH"] = GetSize(new_b); cell->setPort("\\B", new_b); cell->check(); } did_something = true; goto next_cell; } } } // remove redundant pairs of bits in ==, ===, !=, and !== // replace cell with const driver if inputs can't be equal if (do_fine && cell->type.in("$eq", "$ne", "$eqx", "$nex")) { pool> redundant_cache; mfp contradiction_cache; contradiction_cache.promote(State::S0); contradiction_cache.promote(State::S1); int a_width = cell->getParam("\\A_WIDTH").as_int(); int b_width = cell->getParam("\\B_WIDTH").as_int(); bool is_signed = cell->getParam("\\A_SIGNED").as_bool(); int width = is_signed ? std::min(a_width, b_width) : std::max(a_width, b_width); SigSpec sig_a = cell->getPort("\\A"); SigSpec sig_b = cell->getPort("\\B"); int redundant_bits = 0; for (int i = width-1; i >= 0; i--) { SigBit bit_a = i < a_width ? assign_map(sig_a[i]) : State::S0; SigBit bit_b = i < b_width ? assign_map(sig_b[i]) : State::S0; if (bit_a != State::Sx && bit_a != State::Sz && bit_b != State::Sx && bit_b != State::Sz) contradiction_cache.merge(bit_a, bit_b); if (bit_b < bit_a) std::swap(bit_a, bit_b); pair key(bit_a, bit_b); if (redundant_cache.count(key)) { if (i < a_width) sig_a.remove(i); if (i < b_width) sig_b.remove(i); redundant_bits++; continue; } redundant_cache.insert(key); } if (contradiction_cache.find(State::S0) == contradiction_cache.find(State::S1)) { SigSpec y_sig = cell->getPort("\\Y"); Const y_value(cell->type.in("$eq", "$eqx") ? 0 : 1, GetSize(y_sig)); log("Replacing cell `%s' in module `%s' with constant driver %s.\n", log_id(cell), log_id(module), log_signal(y_value)); module->connect(y_sig, y_value); module->remove(cell); did_something = true; goto next_cell; } if (redundant_bits) { log("Removed %d redundant input bits from %s cell `%s' in module `%s'.\n", redundant_bits, log_id(cell->type), log_id(cell), log_id(module)); cell->setPort("\\A", sig_a); cell->setPort("\\B", sig_b); cell->setParam("\\A_WIDTH", GetSize(sig_a)); cell->setParam("\\B_WIDTH", GetSize(sig_b)); did_something = true; goto next_cell; } } // replace a<0 or a>=0 with the top bit of a if (do_fine && (cell->type == "$lt" || cell->type == "$ge" || cell->type == "$gt" || cell->type == "$le")) { //used to decide whether the signal needs to be negated bool is_lt = false; //references the variable signal in the comparison RTLIL::SigSpec sigVar; //references the constant signal in the comparison RTLIL::SigSpec sigConst; // note that this signal must be constant for the optimization // to take place, but it is not checked beforehand. // If new passes are added, this signal must be checked for const-ness //width of the variable port int width; int const_width; bool var_signed; if (cell->type == "$lt" || cell->type == "$ge") { is_lt = cell->type == "$lt" ? 1 : 0; sigVar = cell->getPort("\\A"); sigConst = cell->getPort("\\B"); width = cell->parameters["\\A_WIDTH"].as_int(); const_width = cell->parameters["\\B_WIDTH"].as_int(); var_signed = cell->parameters["\\A_SIGNED"].as_bool(); } else if (cell->type == "$gt" || cell->type == "$le") { is_lt = cell->type == "$gt" ? 1 : 0; sigVar = cell->getPort("\\B"); sigConst = cell->getPort("\\A"); width = cell->parameters["\\B_WIDTH"].as_int(); const_width = cell->parameters["\\A_WIDTH"].as_int(); var_signed = cell->parameters["\\B_SIGNED"].as_bool(); } else log_abort(); // replace a(signed) < 0 with the high bit of a if (sigConst.is_fully_const() && sigConst.is_fully_zero() && var_signed == true) { RTLIL::SigSpec a_prime(RTLIL::State::S0, cell->parameters["\\Y_WIDTH"].as_int()); a_prime[0] = sigVar[width - 1]; if (is_lt) { log("Replacing %s cell `%s' (implementing X<0) with X[%d]: %s\n", log_id(cell->type), log_id(cell), width-1, log_signal(a_prime)); module->connect(cell->getPort("\\Y"), a_prime); module->remove(cell); } else { log("Replacing %s cell `%s' (implementing X>=0) with ~X[%d]: %s\n", log_id(cell->type), log_id(cell), width-1, log_signal(a_prime)); module->addNot(NEW_ID, a_prime, cell->getPort("\\Y")); module->remove(cell); } did_something = true; goto next_cell; } else if (sigConst.is_fully_const() && sigConst.is_fully_def() && var_signed == false) { if (sigConst.is_fully_zero()) { RTLIL::SigSpec a_prime(RTLIL::State::S0, 1); if (is_lt) { log("Replacing %s cell `%s' (implementing unsigned X<0) with constant false.\n", log_id(cell->type), log_id(cell)); a_prime[0] = RTLIL::State::S0; } else { log("Replacing %s cell `%s' (implementing unsigned X>=0) with constant true.\n", log_id(cell->type), log_id(cell)); a_prime[0] = RTLIL::State::S1; } module->connect(cell->getPort("\\Y"), a_prime); module->remove(cell); did_something = true; goto next_cell; } int const_bit_set = get_onehot_bit_index(sigConst); if (const_bit_set >= 0 && const_bit_set < width) { int bit_set = const_bit_set; RTLIL::SigSpec a_prime(RTLIL::State::S0, width - bit_set); for (int i = bit_set; i < width; i++) { a_prime[i - bit_set] = sigVar[i]; } if (is_lt) { log("Replacing %s cell `%s' (implementing unsigned X<%s) with !X[%d:%d]: %s.\n", log_id(cell->type), log_id(cell), log_signal(sigConst), width - 1, bit_set, log_signal(a_prime)); module->addLogicNot(NEW_ID, a_prime, cell->getPort("\\Y")); } else { log("Replacing %s cell `%s' (implementing unsigned X>=%s) with |X[%d:%d]: %s.\n", log_id(cell->type), log_id(cell), log_signal(sigConst), width - 1, bit_set, log_signal(a_prime)); module->addReduceOr(NEW_ID, a_prime, cell->getPort("\\Y")); } module->remove(cell); did_something = true; goto next_cell; } else if(const_bit_set >= width && const_bit_set >= 0){ RTLIL::SigSpec a_prime(RTLIL::State::S0, 1); if(is_lt){ a_prime[0] = RTLIL::State::S1; log("Replacing %s cell `%s' (implementing unsigned X[%d:0] < %s[%d:0]) with constant 0.\n", log_id(cell->type), log_id(cell), width-1, log_signal(sigConst),const_width-1); } else{ log("Replacing %s cell `%s' (implementing unsigned X[%d:0]>= %s[%d:0]) with constant 1.\n", log_id(cell->type), log_id(cell), width-1, log_signal(sigConst),const_width-1); } module->connect(cell->getPort("\\Y"), a_prime); module->remove(cell); did_something = true; goto next_cell; } } } next_cell:; #undef ACTION_DO #undef ACTION_DO_Y #undef FOLD_1ARG_CELL #undef FOLD_2ARG_CELL } } struct OptExprPass : public Pass { OptExprPass() : Pass("opt_expr", "perform const folding and simple expression rewriting") { } void help() YS_OVERRIDE { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" opt_expr [options] [selection]\n"); log("\n"); log("This pass performs const folding on internal cell types with constant inputs.\n"); log("It also performs some simple expression rewritring.\n"); log("\n"); log(" -mux_undef\n"); log(" remove 'undef' inputs from $mux, $pmux and $_MUX_ cells\n"); log("\n"); log(" -mux_bool\n"); log(" replace $mux cells with inverters or buffers when possible\n"); log("\n"); log(" -undriven\n"); log(" replace undriven nets with undef (x) constants\n"); log("\n"); log(" -clkinv\n"); log(" optimize clock inverters by changing FF types\n"); log("\n"); log(" -fine\n"); log(" perform fine-grain optimizations\n"); log("\n"); log(" -full\n"); log(" alias for -mux_undef -mux_bool -undriven -fine\n"); log("\n"); log(" -keepdc\n"); log(" some optimizations change the behavior of the circuit with respect to\n"); log(" don't-care bits. for example in 'a+0' a single x-bit in 'a' will cause\n"); log(" all result bits to be set to x. this behavior changes when 'a+0' is\n"); log(" replaced by 'a'. the -keepdc option disables all such optimizations.\n"); log("\n"); } void execute(std::vector args, RTLIL::Design *design) YS_OVERRIDE { bool mux_undef = false; bool mux_bool = false; bool undriven = false; bool clkinv = false; bool do_fine = false; bool keepdc = false; log_header(design, "Executing OPT_EXPR pass (perform const folding).\n"); log_push(); size_t argidx; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-mux_undef") { mux_undef = true; continue; } if (args[argidx] == "-mux_bool") { mux_bool = true; continue; } if (args[argidx] == "-undriven") { undriven = true; continue; } if (args[argidx] == "-clkinv") { clkinv = true; continue; } if (args[argidx] == "-fine") { do_fine = true; continue; } if (args[argidx] == "-full") { mux_undef = true; mux_bool = true; undriven = true; do_fine = true; continue; } if (args[argidx] == "-keepdc") { keepdc = true; continue; } break; } extra_args(args, argidx, design); for (auto module : design->selected_modules()) { if (undriven) replace_undriven(design, module); do { do { did_something = false; replace_const_cells(design, module, false, mux_undef, mux_bool, do_fine, keepdc, clkinv); if (did_something) design->scratchpad_set_bool("opt.did_something", true); } while (did_something); replace_const_cells(design, module, true, mux_undef, mux_bool, do_fine, keepdc, clkinv); } while (did_something); } log_pop(); } } OptExprPass; PRIVATE_NAMESPACE_END