/* * yosys -- Yosys Open SYnthesis Suite * * Copyright (C) 2012 Clifford Wolf * 2019 Bogdan Vukobratovic * * 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/log.h" #include "kernel/register.h" #include "kernel/rtlil.h" #include "kernel/sigtools.h" #include #include #include USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN SigMap assign_map; struct OpMuxConn { RTLIL::SigSpec sig; RTLIL::Cell *mux; RTLIL::Cell *op; int mux_port_id; int mux_port_offset; int op_outsig_offset; bool operator<(const OpMuxConn &other) const { if (mux != other.mux) return mux < other.mux; if (mux_port_id != other.mux_port_id) return mux_port_id < other.mux_port_id; return mux_port_offset < other.mux_port_offset; } }; // Helper class to track additiona information about a SigSpec, like whether it is signed and the semantics of the port it is connected to struct ExtSigSpec { RTLIL::SigSpec sig; RTLIL::SigSpec sign; bool is_signed; RTLIL::IdString semantics; ExtSigSpec() {} ExtSigSpec(RTLIL::SigSpec s, RTLIL::SigSpec sign = RTLIL::Const(0, 1), bool is_signed = false, RTLIL::IdString semantics = RTLIL::IdString()) : sig(s), sign(sign), is_signed(is_signed), semantics(semantics) {} bool empty() const { return sig.empty(); } bool operator<(const ExtSigSpec &other) const { if (sig != other.sig) return sig < other.sig; if (sign != other.sign) return sign < other.sign; if (is_signed != other.is_signed) return is_signed < other.is_signed; return semantics < other.semantics; } bool operator==(const RTLIL::SigSpec &other) const { return (sign != RTLIL::Const(0, 1)) ? false : sig == other; } bool operator==(const ExtSigSpec &other) const { return is_signed == other.is_signed && sign == other.sign && sig == other.sig && semantics == other.semantics; } }; #define BITWISE_OPS ID($_AND_), ID($_NAND_), ID($_OR_), ID($_NOR_), ID($_XOR_), ID($_XNOR_), ID($_ANDNOT_), ID($_ORNOT_), ID($and), ID($or), ID($xor), ID($xnor) #define REDUCTION_OPS ID($reduce_and), ID($reduce_or), ID($reduce_xor), ID($reduce_xnor), ID($reduce_bool), ID($reduce_nand) #define LOGICAL_OPS ID($logic_and), ID($logic_or) #define SHIFT_OPS ID($shl), ID($shr), ID($sshl), ID($sshr), ID($shift), ID($shiftx) #define RELATIONAL_OPS ID($lt), ID($le), ID($eq), ID($ne), ID($eqx), ID($nex), ID($ge), ID($gt) bool cell_supported(RTLIL::Cell *cell) { if (cell->type.in(ID($alu))) { RTLIL::SigSpec sig_bi = cell->getPort(ID(BI)); RTLIL::SigSpec sig_ci = cell->getPort(ID(CI)); if (sig_bi.is_fully_const() && sig_ci.is_fully_const() && sig_bi == sig_ci) return true; } else if (cell->type.in(LOGICAL_OPS, SHIFT_OPS, BITWISE_OPS, RELATIONAL_OPS, ID($add), ID($sub), ID($mul), ID($div), ID($mod), ID($concat))) { return true; } return false; } std::map mergeable_type_map{ {ID($sub), ID($add)}, }; bool mergeable(RTLIL::Cell *a, RTLIL::Cell *b) { auto a_type = a->type; if (mergeable_type_map.count(a_type)) a_type = mergeable_type_map.at(a_type); auto b_type = b->type; if (mergeable_type_map.count(b_type)) b_type = mergeable_type_map.at(b_type); return a_type == b_type; } RTLIL::IdString decode_port_semantics(RTLIL::Cell *cell, RTLIL::IdString port_name) { if (cell->type.in(ID($lt), ID($le), ID($ge), ID($gt), ID($div), ID($mod), ID($concat), SHIFT_OPS) && port_name == ID::B) return port_name; return ""; } RTLIL::SigSpec decode_port_sign(RTLIL::Cell *cell, RTLIL::IdString port_name) { if (cell->type == ID($alu) && port_name == ID::B) return cell->getPort(ID(BI)); else if (cell->type == ID($sub) && port_name == ID::B) return RTLIL::Const(1, 1); return RTLIL::Const(0, 1); } bool decode_port_signed(RTLIL::Cell *cell, RTLIL::IdString port_name) { if (cell->type.in(BITWISE_OPS, LOGICAL_OPS)) return false; if (cell->hasParam(port_name.str() + "_SIGNED")) return cell->getParam(port_name.str() + "_SIGNED").as_bool(); return false; } ExtSigSpec decode_port(RTLIL::Cell *cell, RTLIL::IdString port_name, SigMap *sigmap) { auto sig = (*sigmap)(cell->getPort(port_name)); RTLIL::SigSpec sign = decode_port_sign(cell, port_name); RTLIL::IdString semantics = decode_port_semantics(cell, port_name); bool is_signed = decode_port_signed(cell, port_name); return ExtSigSpec(sig, sign, is_signed, semantics); } void merge_operators(RTLIL::Module *module, RTLIL::Cell *mux, const std::vector &ports, const ExtSigSpec &operand) { std::vector muxed_operands; int max_width = 0; for (const auto& p : ports) { auto op = p.op; RTLIL::IdString muxed_port_name = ID::A; if (decode_port(op, ID::A, &assign_map) == operand) muxed_port_name = ID::B; auto operand = decode_port(op, muxed_port_name, &assign_map); if (operand.sig.size() > max_width) max_width = operand.sig.size(); muxed_operands.push_back(operand); } auto shared_op = ports[0].op; if (std::any_of(muxed_operands.begin(), muxed_operands.end(), [&](ExtSigSpec &op) { return op.sign != muxed_operands[0].sign; })) max_width = std::max(max_width, shared_op->getParam(ID(Y_WIDTH)).as_int()); for (auto &operand : muxed_operands) operand.sig.extend_u0(max_width, operand.is_signed); for (const auto& p : ports) { auto op = p.op; if (op == shared_op) continue; module->remove(op); } for (auto &muxed_op : muxed_operands) if (muxed_op.sign != muxed_operands[0].sign) muxed_op = ExtSigSpec(module->Neg(NEW_ID, muxed_op.sig, muxed_op.is_signed)); RTLIL::SigSpec mux_y = mux->getPort(ID::Y); RTLIL::SigSpec mux_a = mux->getPort(ID::A); RTLIL::SigSpec mux_b = mux->getPort(ID::B); RTLIL::SigSpec mux_s = mux->getPort(ID(S)); RTLIL::SigSpec shared_pmux_a = RTLIL::Const(RTLIL::State::Sx, max_width); RTLIL::SigSpec shared_pmux_b; RTLIL::SigSpec shared_pmux_s; int conn_width = ports[0].sig.size(); int conn_offset = ports[0].mux_port_offset; shared_op->setPort(ID::Y, shared_op->getPort(ID::Y).extract(0, conn_width)); if (mux->type == ID($pmux)) { shared_pmux_s = RTLIL::SigSpec(); for (const auto &p : ports) { shared_pmux_s.append(mux_s[p.mux_port_id]); mux_b.replace(p.mux_port_id * mux_a.size() + conn_offset, shared_op->getPort(ID::Y)); } } else { shared_pmux_s = RTLIL::SigSpec{mux_s, module->Not(NEW_ID, mux_s)}; mux_a.replace(conn_offset, shared_op->getPort(ID::Y)); mux_b.replace(conn_offset, shared_op->getPort(ID::Y)); } mux->setPort(ID::A, mux_a); mux->setPort(ID::B, mux_b); mux->setPort(ID::Y, mux_y); mux->setPort(ID(S), mux_s); for (const auto &op : muxed_operands) shared_pmux_b.append(op.sig); auto mux_to_oper = module->Pmux(NEW_ID, shared_pmux_a, shared_pmux_b, shared_pmux_s); if (shared_op->type.in(ID($alu))) { RTLIL::SigSpec alu_x = shared_op->getPort(ID(X)); RTLIL::SigSpec alu_co = shared_op->getPort(ID(CO)); shared_op->setPort(ID(X), alu_x.extract(0, conn_width)); shared_op->setPort(ID(CO), alu_co.extract(0, conn_width)); } shared_op->setParam(ID(Y_WIDTH), conn_width); if (decode_port(shared_op, ID::A, &assign_map) == operand) { shared_op->setPort(ID::B, mux_to_oper); shared_op->setParam(ID(B_WIDTH), max_width); } else { shared_op->setPort(ID::A, mux_to_oper); shared_op->setParam(ID(A_WIDTH), max_width); } } typedef struct { RTLIL::Cell *mux; std::vector ports; ExtSigSpec shared_operand; } merged_op_t; template void remove_val(std::vector &v, const std::vector &vals) { auto val_iter = vals.rbegin(); for (auto i = v.rbegin(); i != v.rend(); ++i) if ((val_iter != vals.rend()) && (*i == *val_iter)) { v.erase(i.base() - 1); ++val_iter; } } void check_muxed_operands(std::vector &ports, const ExtSigSpec &shared_operand) { auto it = ports.begin(); ExtSigSpec seed; while (it != ports.end()) { auto p = *it; auto op = p->op; RTLIL::IdString muxed_port_name = ID::A; if (decode_port(op, ID::A, &assign_map) == shared_operand) { muxed_port_name = ID::B; } auto operand = decode_port(op, muxed_port_name, &assign_map); if (seed.empty()) seed = operand; if (operand.is_signed != seed.is_signed) { ports.erase(it); } else { ++it; } } } ExtSigSpec find_shared_operand(const OpMuxConn* seed, std::vector &ports, const std::map> &operand_to_users) { std::set ops_using_operand; std::set ops_set; for(const auto& p: ports) ops_set.insert(p->op); ExtSigSpec oper; auto op_a = seed->op; for (RTLIL::IdString port_name : {ID::A, ID::B}) { oper = decode_port(op_a, port_name, &assign_map); auto operand_users = operand_to_users.at(oper); if (operand_users.size() == 1) continue; ops_using_operand.clear(); for (auto mux_ops: ops_set) if (operand_users.count(mux_ops)) ops_using_operand.insert(mux_ops); if (ops_using_operand.size() > 1) { ports.erase(std::remove_if(ports.begin(), ports.end(), [&](const OpMuxConn *p) { return !ops_using_operand.count(p->op); }), ports.end()); return oper; } } return ExtSigSpec(); } dict find_valid_op_mux_conns(RTLIL::Module *module, dict &op_outbit_to_outsig, dict outsig_to_operator, dict &op_aux_to_outsig) { dict op_outsig_user_track; dict op_mux_conn_map; std::function remove_outsig = [&](RTLIL::SigSpec outsig) { for (auto op_outbit : outsig) op_outbit_to_outsig.erase(op_outbit); if (op_mux_conn_map.count(outsig)) op_mux_conn_map.erase(outsig); }; std::function remove_outsig_from_aux_bit = [&](RTLIL::SigBit auxbit) { auto aux_outsig = op_aux_to_outsig.at(auxbit); auto op = outsig_to_operator.at(aux_outsig); auto op_outsig = assign_map(op->getPort(ID::Y)); remove_outsig(op_outsig); for (auto aux_outbit : aux_outsig) op_aux_to_outsig.erase(aux_outbit); }; std::function find_op_mux_conns = [&](RTLIL::Cell *mux) { RTLIL::SigSpec sig; int mux_port_size; if (mux->type.in(ID($mux), ID($_MUX_))) { mux_port_size = mux->getPort(ID::A).size(); sig = RTLIL::SigSpec{mux->getPort(ID::B), mux->getPort(ID::A)}; } else { mux_port_size = mux->getPort(ID::A).size(); sig = mux->getPort(ID::B); } auto mux_insig = assign_map(sig); for (int i = 0; i < mux_insig.size(); ++i) { if (op_aux_to_outsig.count(mux_insig[i])) { remove_outsig_from_aux_bit(mux_insig[i]); continue; } if (!op_outbit_to_outsig.count(mux_insig[i])) continue; auto op_outsig = op_outbit_to_outsig.at(mux_insig[i]); if (op_mux_conn_map.count(op_outsig)) { remove_outsig(op_outsig); continue; } int mux_port_id = i / mux_port_size; int mux_port_offset = i % mux_port_size; int op_outsig_offset; for (op_outsig_offset = 0; op_outsig[op_outsig_offset] != mux_insig[i]; ++op_outsig_offset) ; int j = op_outsig_offset; do { if (!op_outbit_to_outsig.count(mux_insig[i])) break; if (op_outbit_to_outsig.at(mux_insig[i]) != op_outsig) break; ++i; ++j; } while ((i / mux_port_size == mux_port_id) && (j < op_outsig.size())); int op_conn_width = j - op_outsig_offset; OpMuxConn inp = { op_outsig.extract(op_outsig_offset, op_conn_width), mux, outsig_to_operator.at(op_outsig), mux_port_id, mux_port_offset, op_outsig_offset, }; op_mux_conn_map[op_outsig] = inp; --i; } }; std::function remove_connected_ops = [&](RTLIL::SigSpec sig) { auto mux_insig = assign_map(sig); for (auto outbit : mux_insig) { if (op_aux_to_outsig.count(outbit)) { remove_outsig_from_aux_bit(outbit); continue; } if (!op_outbit_to_outsig.count(outbit)) continue; remove_outsig(op_outbit_to_outsig.at(outbit)); } }; for (auto cell : module->cells()) { if (cell->type.in(ID($mux), ID($_MUX_), ID($pmux))) { remove_connected_ops(cell->getPort(ID(S))); find_op_mux_conns(cell); } else { for (auto &conn : cell->connections()) if (cell->input(conn.first)) remove_connected_ops(conn.second); } } for (auto w : module->wires()) { if (!w->port_output) continue; remove_connected_ops(w); } return op_mux_conn_map; } struct OptSharePass : public Pass { OptSharePass() : Pass("opt_share", "merge mutually exclusive cells of the same type that share an input signal") {} void help() YS_OVERRIDE { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" opt_share [selection]\n"); log("\n"); log("This pass identifies mutually exclusive cells of the same type that:\n"); log(" (a) share an input signal,\n"); log(" (b) drive the same $mux, $_MUX_, or $pmux multiplexing cell,\n"); log("\n"); log("allowing the cell to be merged and the multiplexer to be moved from\n"); log("multiplexing its output to multiplexing the non-shared input signals.\n"); log("\n"); } void execute(std::vector args, RTLIL::Design *design) YS_OVERRIDE { log_header(design, "Executing OPT_SHARE pass.\n"); extra_args(args, 1, design); for (auto module : design->selected_modules()) { assign_map.clear(); assign_map.set(module); std::map> operand_to_users; dict outsig_to_operator; dict op_outbit_to_outsig; dict op_aux_to_outsig; bool any_shared_operands = false; std::vector op_insigs; for (auto cell : module->cells()) { if (!cell_supported(cell)) continue; if (cell->type == ID($alu)) { for (RTLIL::IdString port_name : {ID(X), ID(CO)}) { auto mux_insig = assign_map(cell->getPort(port_name)); outsig_to_operator[mux_insig] = cell; for (auto outbit : mux_insig) op_aux_to_outsig[outbit] = mux_insig; } } auto mux_insig = assign_map(cell->getPort(ID::Y)); outsig_to_operator[mux_insig] = cell; for (auto outbit : mux_insig) op_outbit_to_outsig[outbit] = mux_insig; for (RTLIL::IdString port_name : {ID::A, ID::B}) { auto op_insig = decode_port(cell, port_name, &assign_map); op_insigs.push_back(op_insig); operand_to_users[op_insig].insert(cell); if (operand_to_users[op_insig].size() > 1) any_shared_operands = true; } } if (!any_shared_operands) continue; // Operator outputs need to be exclusively connected to the $mux inputs in order to be mergeable. Hence we count to // how many points are operator output bits connected. dict op_mux_conn_map = find_valid_op_mux_conns(module, op_outbit_to_outsig, outsig_to_operator, op_aux_to_outsig); // Group op connections connected to same ports of the same $mux. Sort them in ascending order of their port offset dict>> mux_port_op_conns; for (auto& val: op_mux_conn_map) { OpMuxConn p = val.second; auto& mux_port_conns = mux_port_op_conns[p.mux]; if (mux_port_conns.size() == 0) { int mux_port_num; if (p.mux->type.in(ID($mux), ID($_MUX_))) mux_port_num = 2; else mux_port_num = p.mux->getPort(ID(S)).size(); mux_port_conns.resize(mux_port_num); } mux_port_conns[p.mux_port_id].insert(p); } std::vector merged_ops; for (auto& val: mux_port_op_conns) { RTLIL::Cell* cell = val.first; auto &mux_port_conns = val.second; const OpMuxConn *seed = NULL; // Look through the bits of the $mux inputs and see which of them are connected to the operator // results. Operator results can be concatenated with other signals before led to the $mux. while (true) { // Remove either the merged ports from the last iteration or the seed that failed to yield a merger if (seed != NULL) { mux_port_conns[seed->mux_port_id].erase(*seed); seed = NULL; } // For a new merger, find the seed op connection that starts at lowest port offset among port connections for (auto &port_conns : mux_port_conns) { if (!port_conns.size()) continue; const OpMuxConn *next_p = &(*port_conns.begin()); if ((seed == NULL) || (seed->mux_port_offset > next_p->mux_port_offset)) seed = next_p; } // Cannot find the seed -> nothing to do for this $mux anymore if (seed == NULL) break; // Find all other op connections that start from the same port offset, and whose ops can be merged with the seed op std::vector mergeable_conns; for (auto &port_conns : mux_port_conns) { if (!port_conns.size()) continue; const OpMuxConn *next_p = &(*port_conns.begin()); if ((next_p->op_outsig_offset == seed->op_outsig_offset) && (next_p->mux_port_offset == seed->mux_port_offset) && mergeable(next_p->op, seed->op) && next_p->sig.size() == seed->sig.size()) mergeable_conns.push_back(next_p); } // We need at least two mergeable connections for the merger if (mergeable_conns.size() < 2) continue; // Filter mergeable connections whose ops share an operand with seed connection's op auto shared_operand = find_shared_operand(seed, mergeable_conns, operand_to_users); if (shared_operand.empty()) continue; check_muxed_operands(mergeable_conns, shared_operand); if (mergeable_conns.size() < 2) continue; // Remember the combination for the merger std::vector merged_ports; for (auto p : mergeable_conns) { merged_ports.push_back(*p); mux_port_conns[p->mux_port_id].erase(*p); } seed = NULL; merged_ops.push_back(merged_op_t{cell, merged_ports, shared_operand}); design->scratchpad_set_bool("opt.did_something", true); } } for (auto &shared : merged_ops) { log(" Found cells that share an operand and can be merged by moving the %s %s in front " "of " "them:\n", log_id(shared.mux->type), log_id(shared.mux)); for (const auto& op : shared.ports) log(" %s\n", log_id(op.op)); log("\n"); merge_operators(module, shared.mux, shared.ports, shared.shared_operand); } } } } OptSharePass; PRIVATE_NAMESPACE_END