/* * 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/yosys.h" #include "kernel/utils.h" #include "kernel/sigtools.h" #include "libs/sha1/sha1.h" #include #include #include #include "simplemap.h" #include "passes/techmap/techmap.inc" YOSYS_NAMESPACE_BEGIN // see maccmap.cc extern void maccmap(RTLIL::Module *module, RTLIL::Cell *cell, bool unmap = false); YOSYS_NAMESPACE_END USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN void apply_prefix(IdString prefix, IdString &id) { if (id[0] == '\\') id = stringf("%s.%s", prefix.c_str(), id.c_str()+1); else id = stringf("$techmap%s.%s", prefix.c_str(), id.c_str()); } void apply_prefix(IdString prefix, RTLIL::SigSpec &sig, RTLIL::Module *module) { vector chunks = sig; for (auto &chunk : chunks) if (chunk.wire != NULL) { IdString wire_name = chunk.wire->name; apply_prefix(prefix, wire_name); log_assert(module->wires_.count(wire_name) > 0); chunk.wire = module->wires_[wire_name]; } sig = chunks; } struct TechmapWorker { std::map simplemap_mappers; std::map>, RTLIL::Module*> techmap_cache; std::map techmap_do_cache; std::set> module_queue; dict sigmaps; pool flatten_do_list; pool flatten_done_list; pool flatten_keep_list; pool log_msg_cache; struct TechmapWireData { RTLIL::Wire *wire; RTLIL::SigSpec value; }; typedef std::map> TechmapWires; bool extern_mode; bool assert_mode; bool flatten_mode; bool recursive_mode; bool autoproc_mode; bool ignore_wb; TechmapWorker() { extern_mode = false; assert_mode = false; flatten_mode = false; recursive_mode = false; autoproc_mode = false; ignore_wb = false; } std::string constmap_tpl_name(SigMap &sigmap, RTLIL::Module *tpl, RTLIL::Cell *cell, bool verbose) { std::string constmap_info; std::map> connbits_map; for (auto conn : cell->connections()) for (int i = 0; i < GetSize(conn.second); i++) { RTLIL::SigBit bit = sigmap(conn.second[i]); if (bit.wire == nullptr) { if (verbose) log(" Constant input on bit %d of port %s: %s\n", i, log_id(conn.first), log_signal(bit)); constmap_info += stringf("|%s %d %d", log_id(conn.first), i, bit.data); } else if (connbits_map.count(bit)) { if (verbose) log(" Bit %d of port %s and bit %d of port %s are connected.\n", i, log_id(conn.first), connbits_map.at(bit).second, log_id(connbits_map.at(bit).first)); constmap_info += stringf("|%s %d %s %d", log_id(conn.first), i, log_id(connbits_map.at(bit).first), connbits_map.at(bit).second); } else { connbits_map[bit] = std::pair(conn.first, i); constmap_info += stringf("|%s %d", log_id(conn.first), i); } } return stringf("$paramod$constmap:%s%s", sha1(constmap_info).c_str(), tpl->name.c_str()); } TechmapWires techmap_find_special_wires(RTLIL::Module *module) { TechmapWires result; if (module == NULL) return result; for (auto &it : module->wires_) { const char *p = it.first.c_str(); if (*p == '$') continue; const char *q = strrchr(p+1, '.'); p = q ? q+1 : p+1; if (!strncmp(p, "_TECHMAP_", 9)) { TechmapWireData record; record.wire = it.second; record.value = it.second; result[p].push_back(record); it.second->attributes[ID::keep] = RTLIL::Const(1); it.second->attributes[ID(_techmap_special_)] = RTLIL::Const(1); } } if (!result.empty()) { SigMap sigmap(module); for (auto &it1 : result) for (auto &it2 : it1.second) sigmap.apply(it2.value); } return result; } void techmap_module_worker(RTLIL::Design *design, RTLIL::Module *module, RTLIL::Cell *cell, RTLIL::Module *tpl) { if (tpl->processes.size() != 0) { log("Technology map yielded processes:"); for (auto &it : tpl->processes) log(" %s",RTLIL::id2cstr(it.first)); log("\n"); if (autoproc_mode) { Pass::call_on_module(tpl->design, tpl, "proc"); log_assert(GetSize(tpl->processes) == 0); } else log_error("Technology map yielded processes -> this is not supported (use -autoproc to run 'proc' automatically).\n"); } std::string orig_cell_name; pool extra_src_attrs = cell->get_strpool_attribute(ID(src)); if (!flatten_mode) { for (auto &it : tpl->cells_) if (it.first == ID(_TECHMAP_REPLACE_)) { orig_cell_name = cell->name.str(); module->rename(cell, stringf("$techmap%d", autoidx++) + cell->name.str()); break; } } dict memory_renames; for (auto &it : tpl->memories) { IdString m_name = it.first; apply_prefix(cell->name, m_name); RTLIL::Memory *m = new RTLIL::Memory; m->name = m_name; m->width = it.second->width; m->start_offset = it.second->start_offset; m->size = it.second->size; m->attributes = it.second->attributes; if (m->attributes.count(ID(src))) m->add_strpool_attribute(ID(src), extra_src_attrs); module->memories[m->name] = m; memory_renames[it.first] = m->name; design->select(module, m); } std::map positional_ports; dict temp_renamed_wires; pool autopurge_tpl_bits; for (auto &it : tpl->wires_) { if (it.second->port_id > 0) { IdString posportname = stringf("$%d", it.second->port_id); positional_ports[posportname] = it.first; if (!flatten_mode && it.second->get_bool_attribute(ID(techmap_autopurge)) && (!cell->hasPort(it.second->name) || !GetSize(cell->getPort(it.second->name))) && (!cell->hasPort(posportname) || !GetSize(cell->getPort(posportname)))) { if (sigmaps.count(tpl) == 0) sigmaps[tpl].set(tpl); for (auto bit : sigmaps.at(tpl)(it.second)) if (bit.wire != nullptr) autopurge_tpl_bits.insert(bit); } } IdString w_name = it.second->name; apply_prefix(cell->name, w_name); RTLIL::Wire *w = module->wire(w_name); if (w != nullptr) { if (!flatten_mode || !w->get_bool_attribute(ID(hierconn))) { temp_renamed_wires[w] = w->name; module->rename(w, NEW_ID); w = nullptr; } else { w->attributes.erase(ID(hierconn)); if (GetSize(w) < GetSize(it.second)) { log_warning("Widening signal %s.%s to match size of %s.%s (via %s.%s).\n", log_id(module), log_id(w), log_id(tpl), log_id(it.second), log_id(module), log_id(cell)); w->width = GetSize(it.second); } } } if (w == nullptr) { w = module->addWire(w_name, it.second); w->port_input = false; w->port_output = false; w->port_id = 0; if (!flatten_mode) w->attributes.erase(ID(techmap_autopurge)); if (it.second->get_bool_attribute(ID(_techmap_special_))) w->attributes.clear(); if (w->attributes.count(ID(src))) w->add_strpool_attribute(ID(src), extra_src_attrs); } design->select(module, w); } SigMap tpl_sigmap(tpl); pool tpl_written_bits; for (auto &it1 : tpl->cells_) for (auto &it2 : it1.second->connections_) if (it1.second->output(it2.first)) for (auto bit : tpl_sigmap(it2.second)) tpl_written_bits.insert(bit); for (auto &it1 : tpl->connections_) for (auto bit : tpl_sigmap(it1.first)) tpl_written_bits.insert(bit); SigMap port_signal_map; SigSig port_signal_assign; for (auto &it : cell->connections()) { RTLIL::IdString portname = it.first; if (positional_ports.count(portname) > 0) portname = positional_ports.at(portname); if (tpl->wires_.count(portname) == 0 || tpl->wires_.at(portname)->port_id == 0) { if (portname.begins_with("$")) log_error("Can't map port `%s' of cell `%s' to template `%s'!\n", portname.c_str(), cell->name.c_str(), tpl->name.c_str()); continue; } if (GetSize(it.second) == 0) continue; RTLIL::Wire *w = tpl->wires_.at(portname); RTLIL::SigSig c, extra_connect; if (w->port_output && !w->port_input) { c.first = it.second; c.second = RTLIL::SigSpec(w); apply_prefix(cell->name, c.second, module); extra_connect.first = c.second; extra_connect.second = c.first; } else if (!w->port_output && w->port_input) { c.first = RTLIL::SigSpec(w); c.second = it.second; apply_prefix(cell->name, c.first, module); extra_connect.first = c.first; extra_connect.second = c.second; } else { SigSpec sig_tpl = w, sig_tpl_pf = w, sig_mod = it.second; apply_prefix(cell->name, sig_tpl_pf, module); for (int i = 0; i < GetSize(sig_tpl) && i < GetSize(sig_mod); i++) { if (tpl_written_bits.count(tpl_sigmap(sig_tpl[i]))) { c.first.append(sig_mod[i]); c.second.append(sig_tpl_pf[i]); } else { c.first.append(sig_tpl_pf[i]); c.second.append(sig_mod[i]); } } extra_connect.first = sig_tpl_pf; extra_connect.second = sig_mod; } if (c.second.size() > c.first.size()) c.second.remove(c.first.size(), c.second.size() - c.first.size()); if (c.second.size() < c.first.size()) c.second.append(RTLIL::SigSpec(RTLIL::State::S0, c.first.size() - c.second.size())); log_assert(c.first.size() == c.second.size()); if (flatten_mode) { // more conservative approach: // connect internal and external wires if (sigmaps.count(module) == 0) sigmaps[module].set(module); if (sigmaps.at(module)(c.first).has_const()) log_error("Mismatch in directionality for cell port %s.%s.%s: %s <= %s\n", log_id(module), log_id(cell), log_id(it.first), log_signal(c.first), log_signal(c.second)); module->connect(c); } else { // approach that yields nicer outputs: // replace internal wires that are connected to external wires if (w->port_output && !w->port_input) { port_signal_map.add(c.second, c.first); } else if (!w->port_output && w->port_input) { port_signal_map.add(c.first, c.second); } else { module->connect(c); extra_connect = SigSig(); } for (auto &attr : w->attributes) { if (attr.first == ID(src)) continue; auto lhs = GetSize(extra_connect.first); auto rhs = GetSize(extra_connect.second); if (lhs > rhs) extra_connect.first.remove(rhs, lhs-rhs); else if (rhs > lhs) extra_connect.second.remove(lhs, rhs-lhs); module->connect(extra_connect); break; } } } for (auto &it : tpl->cells_) { IdString c_name = it.second->name.str(); bool techmap_replace_cell = (!flatten_mode) && (c_name == ID(_TECHMAP_REPLACE_)); if (techmap_replace_cell) c_name = orig_cell_name; else apply_prefix(cell->name, c_name); RTLIL::Cell *c = module->addCell(c_name, it.second); design->select(module, c); if (!flatten_mode && c->type.begins_with("\\$")) c->type = c->type.substr(1); vector autopurge_ports; for (auto &it2 : c->connections_) { bool autopurge = false; if (!autopurge_tpl_bits.empty()) { autopurge = GetSize(it2.second) != 0; for (auto &bit : sigmaps.at(tpl)(it2.second)) if (!autopurge_tpl_bits.count(bit)) { autopurge = false; break; } } if (autopurge) { autopurge_ports.push_back(it2.first); } else { apply_prefix(cell->name, it2.second, module); port_signal_map.apply(it2.second); } } for (auto &it2 : autopurge_ports) c->unsetPort(it2); if (c->type.in(ID($memrd), ID($memwr), ID($meminit))) { IdString memid = c->getParam(ID(MEMID)).decode_string(); log_assert(memory_renames.count(memid) != 0); c->setParam(ID(MEMID), Const(memory_renames[memid].str())); } if (c->type == ID($mem)) { IdString memid = c->getParam(ID(MEMID)).decode_string(); apply_prefix(cell->name, memid); c->setParam(ID(MEMID), Const(memid.c_str())); } if (c->attributes.count(ID(src))) c->add_strpool_attribute(ID(src), extra_src_attrs); if (techmap_replace_cell) for (auto attr : cell->attributes) if (!c->attributes.count(attr.first)) c->attributes[attr.first] = attr.second; } for (auto &it : tpl->connections()) { RTLIL::SigSig c = it; apply_prefix(cell->name.str(), c.first, module); apply_prefix(cell->name.str(), c.second, module); port_signal_map.apply(c.first); port_signal_map.apply(c.second); module->connect(c); } module->remove(cell); for (auto &it : temp_renamed_wires) { Wire *w = it.first; IdString name = it.second; IdString altname = module->uniquify(name); Wire *other_w = module->wire(name); module->rename(other_w, altname); module->rename(w, name); } } bool techmap_module(RTLIL::Design *design, RTLIL::Module *module, RTLIL::Design *map, std::set &handled_cells, const std::map> &celltypeMap, bool in_recursion) { std::string mapmsg_prefix = in_recursion ? "Recursively mapping" : "Mapping"; if (!design->selected(module) || module->get_blackbox_attribute(ignore_wb)) return false; bool log_continue = false; bool did_something = false; LogMakeDebugHdl mkdebug; SigMap sigmap(module); dict init_bits; pool remove_init_bits; for (auto wire : module->wires()) { if (wire->attributes.count("\\init")) { Const value = wire->attributes.at("\\init"); for (int i = 0; i < min(GetSize(value), GetSize(wire)); i++) if (value[i] != State::Sx) init_bits[sigmap(SigBit(wire, i))] = value[i]; } } TopoSort> cells; std::map> cell_to_inbit; std::map> outbit_to_cell; for (auto cell : module->cells()) { if (!design->selected(module, cell) || handled_cells.count(cell) > 0) continue; std::string cell_type = cell->type.str(); if (in_recursion && cell->type.begins_with("\\$")) cell_type = cell_type.substr(1); if (celltypeMap.count(cell_type) == 0) { if (assert_mode && cell_type.back() != '_') log_error("(ASSERT MODE) No matching template cell for type %s found.\n", log_id(cell_type)); continue; } if (flatten_mode) { bool keepit = cell->get_bool_attribute(ID(keep_hierarchy)); for (auto &tpl_name : celltypeMap.at(cell_type)) if (map->modules_[tpl_name]->get_bool_attribute(ID(keep_hierarchy))) keepit = true; if (keepit) { if (!flatten_keep_list[cell]) { log("Keeping %s.%s (found keep_hierarchy property).\n", log_id(module), log_id(cell)); flatten_keep_list.insert(cell); } if (!flatten_done_list[cell->type]) flatten_do_list.insert(cell->type); continue; } } for (auto &conn : cell->connections()) { RTLIL::SigSpec sig = sigmap(conn.second); sig.remove_const(); if (GetSize(sig) == 0) continue; for (auto &tpl_name : celltypeMap.at(cell_type)) { RTLIL::Module *tpl = map->modules_[tpl_name]; RTLIL::Wire *port = tpl->wire(conn.first); if (port && port->port_input) cell_to_inbit[cell].insert(sig.begin(), sig.end()); if (port && port->port_output) 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) { log_assert(handled_cells.count(cell) == 0); log_assert(cell == module->cell(cell->name)); bool mapped_cell = false; std::string cell_type = cell->type.str(); if (in_recursion && cell->type.begins_with("\\$")) cell_type = cell_type.substr(1); for (auto &tpl_name : celltypeMap.at(cell_type)) { RTLIL::IdString derived_name = tpl_name; RTLIL::Module *tpl = map->modules_[tpl_name]; std::map parameters(cell->parameters.begin(), cell->parameters.end()); if (tpl->get_blackbox_attribute(ignore_wb)) continue; if (!flatten_mode) { std::string extmapper_name; if (tpl->get_bool_attribute(ID(techmap_simplemap))) extmapper_name = "simplemap"; if (tpl->get_bool_attribute(ID(techmap_maccmap))) extmapper_name = "maccmap"; if (tpl->attributes.count(ID(techmap_wrap))) extmapper_name = "wrap"; if (!extmapper_name.empty()) { cell->type = cell_type; if ((extern_mode && !in_recursion) || extmapper_name == "wrap") { std::string m_name = stringf("$extern:%s:%s", extmapper_name.c_str(), log_id(cell->type)); for (auto &c : cell->parameters) m_name += stringf(":%s=%s", log_id(c.first), log_signal(c.second)); if (extmapper_name == "wrap") m_name += ":" + sha1(tpl->attributes.at(ID(techmap_wrap)).decode_string()); RTLIL::Design *extmapper_design = extern_mode && !in_recursion ? design : tpl->design; RTLIL::Module *extmapper_module = extmapper_design->module(m_name); if (extmapper_module == nullptr) { extmapper_module = extmapper_design->addModule(m_name); RTLIL::Cell *extmapper_cell = extmapper_module->addCell(cell->type, cell); extmapper_cell->set_src_attribute(cell->get_src_attribute()); int port_counter = 1; for (auto &c : extmapper_cell->connections_) { RTLIL::Wire *w = extmapper_module->addWire(c.first, GetSize(c.second)); if (w->name.in(ID::Y, ID(Q))) w->port_output = true; else w->port_input = true; w->port_id = port_counter++; c.second = w; } extmapper_module->fixup_ports(); extmapper_module->check(); if (extmapper_name == "simplemap") { log("Creating %s with simplemap.\n", log_id(extmapper_module)); if (simplemap_mappers.count(extmapper_cell->type) == 0) log_error("No simplemap mapper for cell type %s found!\n", log_id(extmapper_cell->type)); simplemap_mappers.at(extmapper_cell->type)(extmapper_module, extmapper_cell); extmapper_module->remove(extmapper_cell); } if (extmapper_name == "maccmap") { log("Creating %s with maccmap.\n", log_id(extmapper_module)); if (extmapper_cell->type != ID($macc)) log_error("The maccmap mapper can only map $macc (not %s) cells!\n", log_id(extmapper_cell->type)); maccmap(extmapper_module, extmapper_cell); extmapper_module->remove(extmapper_cell); } if (extmapper_name == "wrap") { std::string cmd_string = tpl->attributes.at(ID(techmap_wrap)).decode_string(); log("Running \"%s\" on wrapper %s.\n", cmd_string.c_str(), log_id(extmapper_module)); mkdebug.on(); Pass::call_on_module(extmapper_design, extmapper_module, cmd_string); log_continue = true; } } cell->type = extmapper_module->name; cell->parameters.clear(); if (!extern_mode || in_recursion) { tpl = extmapper_module; goto use_wrapper_tpl; } auto msg = stringf("Using extmapper %s for cells of type %s.", log_id(extmapper_module), log_id(cell->type)); if (!log_msg_cache.count(msg)) { log_msg_cache.insert(msg); log("%s\n", msg.c_str()); } log_debug("%s %s.%s (%s) to %s.\n", mapmsg_prefix.c_str(), log_id(module), log_id(cell), log_id(cell->type), log_id(extmapper_module)); } else { auto msg = stringf("Using extmapper %s for cells of type %s.", extmapper_name.c_str(), log_id(cell->type)); if (!log_msg_cache.count(msg)) { log_msg_cache.insert(msg); log("%s\n", msg.c_str()); } log_debug("%s %s.%s (%s) with %s.\n", mapmsg_prefix.c_str(), log_id(module), log_id(cell), log_id(cell->type), extmapper_name.c_str()); if (extmapper_name == "simplemap") { if (simplemap_mappers.count(cell->type) == 0) log_error("No simplemap mapper for cell type %s found!\n", RTLIL::id2cstr(cell->type)); simplemap_mappers.at(cell->type)(module, cell); } if (extmapper_name == "maccmap") { if (cell->type != ID($macc)) log_error("The maccmap mapper can only map $macc (not %s) cells!\n", log_id(cell->type)); maccmap(module, cell); } module->remove(cell); cell = NULL; } did_something = true; mapped_cell = true; break; } for (auto conn : cell->connections()) { if (conn.first.begins_with("$")) continue; if (tpl->wires_.count(conn.first) > 0 && tpl->wires_.at(conn.first)->port_id > 0) continue; if (!conn.second.is_fully_const() || parameters.count(conn.first) > 0 || tpl->avail_parameters.count(conn.first) == 0) goto next_tpl; parameters[conn.first] = conn.second.as_const(); } if (0) { next_tpl: continue; } if (tpl->avail_parameters.count(ID(_TECHMAP_CELLTYPE_)) != 0) parameters[ID(_TECHMAP_CELLTYPE_)] = RTLIL::unescape_id(cell->type); for (auto conn : cell->connections()) { if (tpl->avail_parameters.count(stringf("\\_TECHMAP_CONSTMSK_%s_", RTLIL::id2cstr(conn.first))) != 0) { std::vector v = sigmap(conn.second).to_sigbit_vector(); for (auto &bit : v) bit = RTLIL::SigBit(bit.wire == NULL ? RTLIL::State::S1 : RTLIL::State::S0); parameters[stringf("\\_TECHMAP_CONSTMSK_%s_", RTLIL::id2cstr(conn.first))] = RTLIL::SigSpec(v).as_const(); } if (tpl->avail_parameters.count(stringf("\\_TECHMAP_CONSTVAL_%s_", RTLIL::id2cstr(conn.first))) != 0) { std::vector v = sigmap(conn.second).to_sigbit_vector(); for (auto &bit : v) if (bit.wire != NULL) bit = RTLIL::SigBit(RTLIL::State::Sx); parameters[stringf("\\_TECHMAP_CONSTVAL_%s_", RTLIL::id2cstr(conn.first))] = RTLIL::SigSpec(v).as_const(); } if (tpl->avail_parameters.count(stringf("\\_TECHMAP_WIREINIT_%s_", RTLIL::id2cstr(conn.first))) != 0) { auto sig = sigmap(conn.second); RTLIL::Const value(State::Sx, sig.size()); for (int i = 0; i < sig.size(); i++) { auto it = init_bits.find(sig[i]); if (it != init_bits.end()) { value[i] = it->second; } } parameters[stringf("\\_TECHMAP_WIREINIT_%s_", RTLIL::id2cstr(conn.first))] = value; } } int unique_bit_id_counter = 0; std::map unique_bit_id; unique_bit_id[RTLIL::State::S0] = unique_bit_id_counter++; unique_bit_id[RTLIL::State::S1] = unique_bit_id_counter++; unique_bit_id[RTLIL::State::Sx] = unique_bit_id_counter++; unique_bit_id[RTLIL::State::Sz] = unique_bit_id_counter++; for (auto conn : cell->connections()) if (tpl->avail_parameters.count(stringf("\\_TECHMAP_CONNMAP_%s_", RTLIL::id2cstr(conn.first))) != 0) { for (auto &bit : sigmap(conn.second).to_sigbit_vector()) if (unique_bit_id.count(bit) == 0) unique_bit_id[bit] = unique_bit_id_counter++; } // Find highest bit set int bits = 0; for (int i = 0; i < 32; i++) if (((unique_bit_id_counter-1) & (1 << i)) != 0) bits = i; // Increment index by one to get number of bits bits++; if (tpl->avail_parameters.count(ID(_TECHMAP_BITS_CONNMAP_))) parameters[ID(_TECHMAP_BITS_CONNMAP_)] = bits; for (auto conn : cell->connections()) if (tpl->avail_parameters.count(stringf("\\_TECHMAP_CONNMAP_%s_", RTLIL::id2cstr(conn.first))) != 0) { RTLIL::Const value; for (auto &bit : sigmap(conn.second).to_sigbit_vector()) { RTLIL::Const chunk(unique_bit_id.at(bit), bits); value.bits.insert(value.bits.end(), chunk.bits.begin(), chunk.bits.end()); } parameters[stringf("\\_TECHMAP_CONNMAP_%s_", RTLIL::id2cstr(conn.first))] = value; } } if (0) { use_wrapper_tpl:; // do not register techmap_wrap modules with techmap_cache } else { std::pair> key(tpl_name, parameters); if (techmap_cache.count(key) > 0) { tpl = techmap_cache[key]; } else { if (parameters.size() != 0) { mkdebug.on(); derived_name = tpl->derive(map, dict(parameters.begin(), parameters.end())); tpl = map->module(derived_name); log_continue = true; } techmap_cache[key] = tpl; } } if (flatten_mode) { techmap_do_cache[tpl] = true; } else { RTLIL::Module *constmapped_tpl = map->module(constmap_tpl_name(sigmap, tpl, cell, false)); if (constmapped_tpl != nullptr) tpl = constmapped_tpl; } if (techmap_do_cache.count(tpl) == 0) { bool keep_running = true; techmap_do_cache[tpl] = true; std::set techmap_wire_names; while (keep_running) { TechmapWires twd = techmap_find_special_wires(tpl); keep_running = false; for (auto &it : twd) techmap_wire_names.insert(it.first); for (auto &it : twd["_TECHMAP_FAIL_"]) { RTLIL::SigSpec value = it.value; if (value.is_fully_const() && value.as_bool()) { log("Not using module `%s' from techmap as it contains a %s marker wire with non-zero value %s.\n", derived_name.c_str(), RTLIL::id2cstr(it.wire->name), log_signal(value)); techmap_do_cache[tpl] = false; } } if (!techmap_do_cache[tpl]) break; for (auto &it : twd) { if (it.first.compare(0, 12, "_TECHMAP_DO_") != 0 || it.second.empty()) continue; auto &data = it.second.front(); if (!data.value.is_fully_const()) log_error("Techmap yielded config wire %s with non-const value %s.\n", RTLIL::id2cstr(data.wire->name), log_signal(data.value)); techmap_wire_names.erase(it.first); const char *p = data.wire->name.c_str(); const char *q = strrchr(p+1, '.'); q = q ? q : p+1; std::string cmd_string = data.value.as_const().decode_string(); restart_eval_cmd_string: if (cmd_string.rfind("CONSTMAP; ", 0) == 0) { cmd_string = cmd_string.substr(strlen("CONSTMAP; ")); log("Analyzing pattern of constant bits for this cell:\n"); RTLIL::IdString new_tpl_name = constmap_tpl_name(sigmap, tpl, cell, true); log("Creating constmapped module `%s'.\n", log_id(new_tpl_name)); log_assert(map->module(new_tpl_name) == nullptr); RTLIL::Module *new_tpl = map->addModule(new_tpl_name); tpl->cloneInto(new_tpl); techmap_do_cache.erase(tpl); techmap_do_cache[new_tpl] = true; tpl = new_tpl; std::map port_new2old_map; std::map port_connmap; std::map cellbits_to_tplbits; for (auto wire : tpl->wires().to_vector()) { if (!wire->port_input || wire->port_output) continue; RTLIL::IdString port_name = wire->name; tpl->rename(wire, NEW_ID); RTLIL::Wire *new_wire = tpl->addWire(port_name, wire); wire->port_input = false; wire->port_id = 0; for (int i = 0; i < wire->width; i++) { port_new2old_map[RTLIL::SigBit(new_wire, i)] = RTLIL::SigBit(wire, i); port_connmap[RTLIL::SigBit(wire, i)] = RTLIL::SigBit(new_wire, i); } } for (auto conn : cell->connections()) for (int i = 0; i < GetSize(conn.second); i++) { RTLIL::SigBit bit = sigmap(conn.second[i]); RTLIL::SigBit tplbit(tpl->wire(conn.first), i); if (bit.wire == nullptr) { RTLIL::SigBit oldbit = port_new2old_map.at(tplbit); port_connmap.at(oldbit) = bit; } else if (cellbits_to_tplbits.count(bit)) { RTLIL::SigBit oldbit = port_new2old_map.at(tplbit); port_connmap.at(oldbit) = cellbits_to_tplbits[bit]; } else cellbits_to_tplbits[bit] = tplbit; } RTLIL::SigSig port_conn; for (auto &it : port_connmap) { port_conn.first.append_bit(it.first); port_conn.second.append_bit(it.second); } tpl->connect(port_conn); tpl->check(); goto restart_eval_cmd_string; } if (cmd_string.rfind("RECURSION; ", 0) == 0) { cmd_string = cmd_string.substr(strlen("RECURSION; ")); while (techmap_module(map, tpl, map, handled_cells, celltypeMap, true)) { } goto restart_eval_cmd_string; } Pass::call_on_module(map, tpl, cmd_string); log_assert(!strncmp(q, "_TECHMAP_DO_", 12)); std::string new_name = data.wire->name.substr(0, q-p) + "_TECHMAP_DONE_" + data.wire->name.substr(q-p+12); while (tpl->wires_.count(new_name)) new_name += "_"; tpl->rename(data.wire->name, new_name); keep_running = true; break; } } TechmapWires twd = techmap_find_special_wires(tpl); for (auto &it : twd) { if (it.first != "_TECHMAP_FAIL_" && (it.first.substr(0, 20) != "_TECHMAP_REMOVEINIT_" || it.first[it.first.size()-1] != '_') && it.first.substr(0, 12) != "_TECHMAP_DO_" && it.first.substr(0, 14) != "_TECHMAP_DONE_") log_error("Techmap yielded unknown config wire %s.\n", it.first.c_str()); if (techmap_do_cache[tpl]) for (auto &it2 : it.second) if (!it2.value.is_fully_const()) log_error("Techmap yielded config wire %s with non-const value %s.\n", RTLIL::id2cstr(it2.wire->name), log_signal(it2.value)); if (it.first.substr(0, 20) == "_TECHMAP_REMOVEINIT_" && techmap_do_cache[tpl]) { for (auto &it2 : it.second) { auto val = it2.value.as_const(); auto wirename = RTLIL::escape_id(it.first.substr(20, it.first.size() - 20 - 1)); auto it = cell->connections().find(wirename); if (it != cell->connections().end()) { auto sig = sigmap(it->second); for (int i = 0; i < sig.size(); i++) if (val[i] == State::S1) remove_init_bits.insert(sig[i]); } } } techmap_wire_names.erase(it.first); } for (auto &it : techmap_wire_names) log_error("Techmap special wire %s disappeared. This is considered a fatal error.\n", RTLIL::id2cstr(it)); if (recursive_mode) { if (log_continue) { log_header(design, "Continuing TECHMAP pass.\n"); log_continue = false; mkdebug.off(); } while (techmap_module(map, tpl, map, handled_cells, celltypeMap, true)) { } } } if (techmap_do_cache.at(tpl) == false) continue; if (log_continue) { log_header(design, "Continuing TECHMAP pass.\n"); log_continue = false; mkdebug.off(); } if (extern_mode && !in_recursion) { std::string m_name = stringf("$extern:%s", log_id(tpl)); if (!design->module(m_name)) { RTLIL::Module *m = design->addModule(m_name); tpl->cloneInto(m); for (auto cell : m->cells()) { if (cell->type.begins_with("\\$")) cell->type = cell->type.substr(1); } module_queue.insert(m); } log_debug("%s %s.%s to imported %s.\n", mapmsg_prefix.c_str(), log_id(module), log_id(cell), log_id(m_name)); cell->type = m_name; cell->parameters.clear(); } else { auto msg = stringf("Using template %s for cells of type %s.", log_id(tpl), log_id(cell->type)); if (!log_msg_cache.count(msg)) { log_msg_cache.insert(msg); log("%s\n", msg.c_str()); } log_debug("%s %s.%s (%s) using %s.\n", mapmsg_prefix.c_str(), log_id(module), log_id(cell), log_id(cell->type), log_id(tpl)); techmap_module_worker(design, module, cell, tpl); cell = NULL; } did_something = true; mapped_cell = true; break; } if (assert_mode && !mapped_cell) log_error("(ASSERT MODE) Failed to map cell %s.%s (%s).\n", log_id(module), log_id(cell), log_id(cell->type)); handled_cells.insert(cell); } if (!remove_init_bits.empty()) { for (auto wire : module->wires()) if (wire->attributes.count("\\init")) { Const &value = wire->attributes.at("\\init"); bool do_cleanup = true; for (int i = 0; i < min(GetSize(value), GetSize(wire)); i++) { SigBit bit = sigmap(SigBit(wire, i)); if (remove_init_bits.count(bit)) value[i] = State::Sx; else if (value[i] != State::Sx) do_cleanup = false; } if (do_cleanup) { log("Removing init attribute from wire %s.%s.\n", log_id(module), log_id(wire)); wire->attributes.erase("\\init"); } } } if (log_continue) { log_header(design, "Continuing TECHMAP pass.\n"); log_continue = false; mkdebug.off(); } return did_something; } }; struct TechmapPass : public Pass { TechmapPass() : Pass("techmap", "generic technology mapper") { } void help() YS_OVERRIDE { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" techmap [-map filename] [selection]\n"); log("\n"); log("This pass implements a very simple technology mapper that replaces cells in\n"); log("the design with implementations given in form of a Verilog or ilang source\n"); log("file.\n"); log("\n"); log(" -map filename\n"); log(" the library of cell implementations to be used.\n"); log(" without this parameter a builtin library is used that\n"); log(" transforms the internal RTL cells to the internal gate\n"); log(" library.\n"); log("\n"); log(" -map %%\n"); log(" like -map above, but with an in-memory design instead of a file.\n"); log("\n"); log(" -extern\n"); log(" load the cell implementations as separate modules into the design\n"); log(" instead of inlining them.\n"); log("\n"); log(" -max_iter \n"); log(" only run the specified number of iterations on each module.\n"); log(" default: unlimited\n"); log("\n"); log(" -recursive\n"); log(" instead of the iterative breadth-first algorithm use a recursive\n"); log(" depth-first algorithm. both methods should yield equivalent results,\n"); log(" but may differ in performance.\n"); log("\n"); log(" -autoproc\n"); log(" Automatically call \"proc\" on implementations that contain processes.\n"); log("\n"); log(" -wb\n"); log(" Ignore the 'whitebox' attribute on cell implementations.\n"); log("\n"); log(" -assert\n"); log(" this option will cause techmap to exit with an error if it can't map\n"); log(" a selected cell. only cell types that end on an underscore are accepted\n"); log(" as final cell types by this mode.\n"); log("\n"); log(" -D , -I \n"); log(" this options are passed as-is to the Verilog frontend for loading the\n"); log(" map file. Note that the Verilog frontend is also called with the\n"); log(" '-nooverwrite' option set.\n"); log("\n"); log("When a module in the map file has the 'techmap_celltype' attribute set, it will\n"); log("match cells with a type that match the text value of this attribute. Otherwise\n"); log("the module name will be used to match the cell.\n"); log("\n"); log("When a module in the map file has the 'techmap_simplemap' attribute set, techmap\n"); log("will use 'simplemap' (see 'help simplemap') to map cells matching the module.\n"); log("\n"); log("When a module in the map file has the 'techmap_maccmap' attribute set, techmap\n"); log("will use 'maccmap' (see 'help maccmap') to map cells matching the module.\n"); log("\n"); log("When a module in the map file has the 'techmap_wrap' attribute set, techmap\n"); log("will create a wrapper for the cell and then run the command string that the\n"); log("attribute is set to on the wrapper module.\n"); log("\n"); log("When a port on a module in the map file has the 'techmap_autopurge' attribute\n"); log("set, and that port is not connected in the instantiation that is mapped, then\n"); log("then a cell port connected only to such wires will be omitted in the mapped\n"); log("version of the circuit.\n"); log("\n"); log("All wires in the modules from the map file matching the pattern _TECHMAP_*\n"); log("or *._TECHMAP_* are special wires that are used to pass instructions from\n"); log("the mapping module to the techmap command. At the moment the following special\n"); log("wires are supported:\n"); log("\n"); log(" _TECHMAP_FAIL_\n"); log(" When this wire is set to a non-zero constant value, techmap will not\n"); log(" use this module and instead try the next module with a matching\n"); log(" 'techmap_celltype' attribute.\n"); log("\n"); log(" When such a wire exists but does not have a constant value after all\n"); log(" _TECHMAP_DO_* commands have been executed, an error is generated.\n"); log("\n"); log(" _TECHMAP_DO_*\n"); log(" This wires are evaluated in alphabetical order. The constant text value\n"); log(" of this wire is a yosys command (or sequence of commands) that is run\n"); log(" by techmap on the module. A common use case is to run 'proc' on modules\n"); log(" that are written using always-statements.\n"); log("\n"); log(" When such a wire has a non-constant value at the time it is to be\n"); log(" evaluated, an error is produced. That means it is possible for such a\n"); log(" wire to start out as non-constant and evaluate to a constant value\n"); log(" during processing of other _TECHMAP_DO_* commands.\n"); log("\n"); log(" A _TECHMAP_DO_* command may start with the special token 'CONSTMAP; '.\n"); log(" in this case techmap will create a copy for each distinct configuration\n"); log(" of constant inputs and shorted inputs at this point and import the\n"); log(" constant and connected bits into the map module. All further commands\n"); log(" are executed in this copy. This is a very convenient way of creating\n"); log(" optimized specializations of techmap modules without using the special\n"); log(" parameters described below.\n"); log("\n"); log(" A _TECHMAP_DO_* command may start with the special token 'RECURSION; '.\n"); log(" then techmap will recursively replace the cells in the module with their\n"); log(" implementation. This is not affected by the -max_iter option.\n"); log("\n"); log(" It is possible to combine both prefixes to 'RECURSION; CONSTMAP; '.\n"); log("\n"); log(" _TECHMAP_REMOVEINIT__\n"); log(" When this wire is set to a constant value, the init attribute of the wire(s)\n"); log(" connected to this port will be consumed. This wire must have the same\n"); log(" width as the given port, and for every bit that is set to 1 in the value,\n"); log(" the corresponding init attribute bit will be changed to 1'bx. If all\n"); log(" bits of an init attribute are left as x, it will be removed.\n"); log("\n"); log("In addition to this special wires, techmap also supports special parameters in\n"); log("modules in the map file:\n"); log("\n"); log(" _TECHMAP_CELLTYPE_\n"); log(" When a parameter with this name exists, it will be set to the type name\n"); log(" of the cell that matches the module.\n"); log("\n"); log(" _TECHMAP_CONSTMSK__\n"); log(" _TECHMAP_CONSTVAL__\n"); log(" When this pair of parameters is available in a module for a port, then\n"); log(" former has a 1-bit for each constant input bit and the latter has the\n"); log(" value for this bit. The unused bits of the latter are set to undef (x).\n"); log("\n"); log(" _TECHMAP_WIREINIT__\n"); log(" When a parameter with this name exists, it will be set to the initial\n"); log(" value of the wire(s) connected to the given port, as specified by the init\n"); log(" attribute. If the attribute doesn't exist, x will be filled for the\n"); log(" missing bits. To remove the init attribute bits used, use the\n"); log(" _TECHMAP_REMOVEINIT_*_ wires.\n"); log("\n"); log(" _TECHMAP_BITS_CONNMAP_\n"); log(" _TECHMAP_CONNMAP__\n"); log(" For an N-bit port, the _TECHMAP_CONNMAP__ parameter, if it\n"); log(" exists, will be set to an N*_TECHMAP_BITS_CONNMAP_ bit vector containing\n"); log(" N words (of _TECHMAP_BITS_CONNMAP_ bits each) that assign each single\n"); log(" bit driver a unique id. The values 0-3 are reserved for 0, 1, x, and z.\n"); log(" This can be used to detect shorted inputs.\n"); log("\n"); log("When a module in the map file has a parameter where the according cell in the\n"); log("design has a port, the module from the map file is only used if the port in\n"); log("the design is connected to a constant value. The parameter is then set to the\n"); log("constant value.\n"); log("\n"); log("A cell with the name _TECHMAP_REPLACE_ in the map file will inherit the name\n"); log("and attributes of the cell that is being replaced.\n"); log("\n"); log("See 'help extract' for a pass that does the opposite thing.\n"); log("\n"); log("See 'help flatten' for a pass that does flatten the design (which is\n"); log("essentially techmap but using the design itself as map library).\n"); log("\n"); } void execute(std::vector args, RTLIL::Design *design) YS_OVERRIDE { log_header(design, "Executing TECHMAP pass (map to technology primitives).\n"); log_push(); TechmapWorker worker; simplemap_get_mappers(worker.simplemap_mappers); std::vector map_files; std::string verilog_frontend = "verilog -nooverwrite -noblackbox"; int max_iter = -1; size_t argidx; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-map" && argidx+1 < args.size()) { map_files.push_back(args[++argidx]); continue; } if (args[argidx] == "-max_iter" && argidx+1 < args.size()) { max_iter = atoi(args[++argidx].c_str()); continue; } if (args[argidx] == "-D" && argidx+1 < args.size()) { verilog_frontend += " -D " + args[++argidx]; continue; } if (args[argidx] == "-I" && argidx+1 < args.size()) { verilog_frontend += " -I " + args[++argidx]; continue; } if (args[argidx] == "-assert") { worker.assert_mode = true; continue; } if (args[argidx] == "-extern") { worker.extern_mode = true; continue; } if (args[argidx] == "-recursive") { worker.recursive_mode = true; continue; } if (args[argidx] == "-autoproc") { worker.autoproc_mode = true; continue; } if (args[argidx] == "-wb") { worker.ignore_wb = true; continue; } break; } extra_args(args, argidx, design); RTLIL::Design *map = new RTLIL::Design; if (map_files.empty()) { std::istringstream f(stdcells_code); Frontend::frontend_call(map, &f, "", verilog_frontend); } else { for (auto &fn : map_files) if (fn.compare(0, 1, "%") == 0) { if (!saved_designs.count(fn.substr(1))) { delete map; log_cmd_error("Can't saved design `%s'.\n", fn.c_str()+1); } for (auto mod : saved_designs.at(fn.substr(1))->modules()) if (!map->has(mod->name)) map->add(mod->clone()); } else { std::ifstream f; rewrite_filename(fn); f.open(fn.c_str()); yosys_input_files.insert(fn); if (f.fail()) log_cmd_error("Can't open map file `%s'\n", fn.c_str()); Frontend::frontend_call(map, &f, fn, (fn.size() > 3 && fn.compare(fn.size()-3, std::string::npos, ".il") == 0 ? "ilang" : verilog_frontend)); } } log_header(design, "Continuing TECHMAP pass.\n"); std::map> celltypeMap; for (auto &it : map->modules_) { if (it.second->attributes.count(ID(techmap_celltype)) && !it.second->attributes.at(ID(techmap_celltype)).bits.empty()) { char *p = strdup(it.second->attributes.at(ID(techmap_celltype)).decode_string().c_str()); for (char *q = strtok(p, " \t\r\n"); q; q = strtok(NULL, " \t\r\n")) celltypeMap[RTLIL::escape_id(q)].insert(it.first); free(p); } else { string module_name = it.first.str(); if (it.first.begins_with("\\$")) module_name = module_name.substr(1); celltypeMap[module_name].insert(it.first); } } for (auto module : design->modules()) worker.module_queue.insert(module); while (!worker.module_queue.empty()) { RTLIL::Module *module = *worker.module_queue.begin(); worker.module_queue.erase(module); int module_max_iter = max_iter; bool did_something = true; std::set handled_cells; while (did_something) { did_something = false; if (worker.techmap_module(design, module, map, handled_cells, celltypeMap, false)) did_something = true; if (did_something) module->check(); if (module_max_iter > 0 && --module_max_iter == 0) break; } } log("No more expansions possible.\n"); delete map; log_pop(); } } TechmapPass; struct FlattenPass : public Pass { FlattenPass() : Pass("flatten", "flatten design") { } void help() YS_OVERRIDE { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" flatten [options] [selection]\n"); log("\n"); log("This pass flattens the design by replacing cells by their implementation. This\n"); log("pass is very similar to the 'techmap' pass. The only difference is that this\n"); log("pass is using the current design as mapping library.\n"); log("\n"); log("Cells and/or modules with the 'keep_hierarchy' attribute set will not be\n"); log("flattened by this command.\n"); log("\n"); log(" -wb\n"); log(" Ignore the 'whitebox' attribute on cell implementations.\n"); log("\n"); } void execute(std::vector args, RTLIL::Design *design) YS_OVERRIDE { log_header(design, "Executing FLATTEN pass (flatten design).\n"); log_push(); TechmapWorker worker; worker.flatten_mode = true; size_t argidx; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-wb") { worker.ignore_wb = true; continue; } break; } extra_args(args, argidx, design); std::map> celltypeMap; for (auto module : design->modules()) celltypeMap[module->name].insert(module->name); RTLIL::Module *top_mod = NULL; if (design->full_selection()) for (auto mod : design->modules()) if (mod->get_bool_attribute(ID(top))) top_mod = mod; std::set handled_cells; if (top_mod != NULL) { worker.flatten_do_list.insert(top_mod->name); while (!worker.flatten_do_list.empty()) { auto mod = design->module(*worker.flatten_do_list.begin()); while (worker.techmap_module(design, mod, design, handled_cells, celltypeMap, false)) { } worker.flatten_done_list.insert(mod->name); worker.flatten_do_list.erase(mod->name); } } else { for (auto mod : vector(design->modules())) { while (worker.techmap_module(design, mod, design, handled_cells, celltypeMap, false)) { } } } log_suppressed(); log("No more expansions possible.\n"); if (top_mod != NULL) { pool used_modules, new_used_modules; new_used_modules.insert(top_mod->name); while (!new_used_modules.empty()) { pool queue; queue.swap(new_used_modules); for (auto modname : queue) used_modules.insert(modname); for (auto modname : queue) for (auto cell : design->module(modname)->cells()) if (design->module(cell->type) && !used_modules[cell->type]) new_used_modules.insert(cell->type); } dict new_modules; for (auto mod : vector(design->modules())) if (used_modules[mod->name] || mod->get_blackbox_attribute(worker.ignore_wb)) { new_modules[mod->name] = mod; } else { log("Deleting now unused module %s.\n", log_id(mod)); delete mod; } design->modules_.swap(new_modules); } log_pop(); } } FlattenPass; PRIVATE_NAMESPACE_END