/* * yosys -- Yosys Open SYnthesis Suite * * Copyright (C) 2012 Claire Xenia 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/log.h" #include "kernel/mem.h" #include #include #include USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN struct MemoryMapWorker { bool attr_icase = false; bool rom_only = false; bool keepdc = false; bool formal = false; dict> attributes; RTLIL::Design *design; RTLIL::Module *module; SigMap sigmap; FfInitVals initvals; std::map, RTLIL::SigBit> decoder_cache; MemoryMapWorker(RTLIL::Design *design, RTLIL::Module *module) : design(design), module(module), sigmap(module), initvals(&sigmap, module) {} std::string map_case(std::string value) const { if (attr_icase) { for (char &c : value) c = tolower(c); } return value; } RTLIL::Const map_case(RTLIL::Const value) const { if (value.flags & RTLIL::CONST_FLAG_STRING) return map_case(value.decode_string()); return value; } std::string genid(RTLIL::IdString name, std::string token1 = "", int i = -1, std::string token2 = "", int j = -1, std::string token3 = "", int k = -1, std::string token4 = "") { std::stringstream sstr; sstr << "$memory" << name.str() << token1; if (i >= 0) sstr << "[" << i << "]"; sstr << token2; if (j >= 0) sstr << "[" << j << "]"; sstr << token3; if (k >= 0) sstr << "[" << k << "]"; sstr << token4 << "$" << (autoidx++); return sstr.str(); } RTLIL::Wire *addr_decode(RTLIL::SigSpec addr_sig, RTLIL::SigSpec addr_val) { std::pair key(addr_sig, addr_val); log_assert(GetSize(addr_sig) == GetSize(addr_val)); if (decoder_cache.count(key) == 0) { if (GetSize(addr_sig) < 2) { decoder_cache[key] = module->Eq(NEW_ID, addr_sig, addr_val); } else { int split_at = GetSize(addr_sig) / 2; RTLIL::SigBit left_eq = addr_decode(addr_sig.extract(0, split_at), addr_val.extract(0, split_at)); RTLIL::SigBit right_eq = addr_decode(addr_sig.extract(split_at, GetSize(addr_sig) - split_at), addr_val.extract(split_at, GetSize(addr_val) - split_at)); decoder_cache[key] = module->And(NEW_ID, left_eq, right_eq); } } RTLIL::SigBit bit = decoder_cache.at(key); log_assert(bit.wire != nullptr && GetSize(bit.wire) == 1); return bit.wire; } void handle_memory(Mem &mem) { std::set static_ports; std::map static_cells_map; SigSpec init_data = mem.get_init_data(); if (!mem.wr_ports.empty() && rom_only) return; // check if attributes allow us to infer FFRAM for this memory for (const auto &attr : attributes) { if (mem.attributes.count(attr.first)) { const auto &cell_attr = mem.attributes[attr.first]; if (attr.second.empty()) { log("Not mapping memory %s in module %s (attribute %s is set).\n", mem.memid.c_str(), module->name.c_str(), attr.first.c_str()); return; } bool found = false; for (auto &value : attr.second) { if (map_case(cell_attr) == map_case(value)) { found = true; break; } } if (!found) { if (cell_attr.flags & RTLIL::CONST_FLAG_STRING) { log("Not mapping memory %s in module %s (attribute %s is set to \"%s\").\n", mem.memid.c_str(), module->name.c_str(), attr.first.c_str(), cell_attr.decode_string().c_str()); } else { log("Not mapping memory %s in module %s (attribute %s is set to %d).\n", mem.memid.c_str(), module->name.c_str(), attr.first.c_str(), cell_attr.as_int()); } return; } } } // delete unused memory cell if (mem.rd_ports.empty()) { mem.remove(); return; } // all write ports must share the same clock RTLIL::SigSpec refclock; bool refclock_pol = false; bool async_wr = false; bool static_only = true; for (int i = 0; i < GetSize(mem.wr_ports); i++) { auto &port = mem.wr_ports[i]; if (port.en.is_fully_const() && !port.en.as_bool()) { static_ports.insert(i); continue; } if (!port.clk_enable) { if (port.addr.is_fully_const() && port.en.is_fully_ones()) { for (int sub = 0; sub < (1 << port.wide_log2); sub++) static_cells_map[port.addr.as_int() + sub] = port.data.extract(sub * mem.width, mem.width); static_ports.insert(i); continue; } static_only = false; if (GetSize(refclock) != 0) log("Not mapping memory %s in module %s (mixed clocked and async write ports).\n", mem.memid.c_str(), module->name.c_str()); if (!formal) log("Not mapping memory %s in module %s (write port %d has no clock).\n", mem.memid.c_str(), module->name.c_str(), i); async_wr = true; continue; } static_only = false; if (async_wr) log("Not mapping memory %s in module %s (mixed clocked and async write ports).\n", mem.memid.c_str(), module->name.c_str()); if (refclock.size() == 0) { refclock = port.clk; refclock_pol = port.clk_polarity; } if (port.clk != refclock || port.clk_polarity != refclock_pol) { log("Not mapping memory %s in module %s (write clock %d is incompatible with other clocks).\n", mem.memid.c_str(), module->name.c_str(), i); return; } } log("Mapping memory %s in module %s:\n", mem.memid.c_str(), module->name.c_str()); int abits = ceil_log2(mem.size); std::vector data_reg_in(1 << abits); std::vector data_reg_out(1 << abits); std::vector &data_read = async_wr ? data_reg_in : data_reg_out; int count_static = 0; for (int i = 0; i < mem.size; i++) { int addr = i + mem.start_offset; int idx = addr & ((1 << abits) - 1); SigSpec w_init = init_data.extract(i*mem.width, mem.width); if (static_cells_map.count(addr) > 0) { data_read[idx] = static_cells_map[addr]; count_static++; } else if (static_only && (!keepdc || w_init.is_fully_def())) { data_read[idx] = w_init; } else { RTLIL::Cell *c; auto ff_id = genid(mem.memid, "", addr); if (static_only) { // non-static part is a ROM, we only reach this with keepdc if (formal) { c = module->addCell(ff_id, ID($ff)); } else { c = module->addCell(ff_id, ID($dff)); c->parameters[ID::CLK_POLARITY] = RTLIL::Const(RTLIL::State::S1); c->setPort(ID::CLK, RTLIL::SigSpec(RTLIL::State::S0)); } } else if (async_wr) { log_assert(formal); // General async write not implemented yet, checked against above c = module->addCell(ff_id, ID($ff)); } else { c = module->addCell(ff_id, ID($dff)); c->parameters[ID::CLK_POLARITY] = RTLIL::Const(refclock_pol); c->setPort(ID::CLK, refclock); } c->parameters[ID::WIDTH] = mem.width; RTLIL::Wire *w_in = module->addWire(genid(mem.memid, "", addr, "$d"), mem.width); data_reg_in[idx] = w_in; c->setPort(ID::D, w_in); std::string w_out_name = stringf("%s[%d]", mem.memid.c_str(), addr); if (module->wires_.count(w_out_name) > 0) w_out_name = genid(mem.memid, "", addr, "$q"); RTLIL::Wire *w_out = module->addWire(w_out_name, mem.width); if (formal && mem.packed && mem.cell->name.c_str()[0] == '\\') { auto hdlname = mem.cell->get_hdlname_attribute(); if (hdlname.empty()) hdlname.push_back(mem.cell->name.c_str() + 1); hdlname.push_back(stringf("[%d]", addr)); w_out->set_hdlname_attribute(hdlname); } if (!w_init.is_fully_undef()) w_out->attributes[ID::init] = w_init.as_const(); data_reg_out[idx] = w_out; c->setPort(ID::Q, w_out); if (static_only) module->connect(RTLIL::SigSig(w_in, w_out)); } } log(" created %d %s cells and %d static cells of width %d.\n", mem.size-count_static, formal && (static_only || async_wr) ? "$ff" : "$dff", count_static, mem.width); int count_dff = 0, count_mux = 0, count_wrmux = 0; for (int i = 0; i < GetSize(mem.rd_ports); i++) { auto &port = mem.rd_ports[i]; if (mem.extract_rdff(i, &initvals)) count_dff++; RTLIL::SigSpec rd_addr = port.addr; rd_addr.extend_u0(abits, false); std::vector rd_signals; rd_signals.push_back(port.data); for (int j = 0; j < abits - port.wide_log2; j++) { std::vector next_rd_signals; for (size_t k = 0; k < rd_signals.size(); k++) { RTLIL::Cell *c = module->addCell(genid(mem.memid, "$rdmux", i, "", j, "", k), ID($mux)); c->parameters[ID::WIDTH] = GetSize(port.data); c->setPort(ID::Y, rd_signals[k]); c->setPort(ID::S, rd_addr.extract(abits-j-1, 1)); count_mux++; c->setPort(ID::A, module->addWire(genid(mem.memid, "$rdmux", i, "", j, "", k, "$a"), GetSize(port.data))); c->setPort(ID::B, module->addWire(genid(mem.memid, "$rdmux", i, "", j, "", k, "$b"), GetSize(port.data))); next_rd_signals.push_back(c->getPort(ID::A)); next_rd_signals.push_back(c->getPort(ID::B)); } next_rd_signals.swap(rd_signals); } for (int j = 0; j < (1 << abits); j++) if (data_read[j] != SigSpec()) module->connect(RTLIL::SigSig(rd_signals[j >> port.wide_log2].extract((j & ((1 << port.wide_log2) - 1)) * mem.width, mem.width), data_read[j])); } log(" read interface: %d $dff and %d $mux cells.\n", count_dff, count_mux); if (!static_only) { for (int i = 0; i < mem.size; i++) { int addr = i + mem.start_offset; int idx = addr & ((1 << abits) - 1); if (static_cells_map.count(addr) > 0) continue; RTLIL::SigSpec sig = data_reg_out[idx]; for (int j = 0; j < GetSize(mem.wr_ports); j++) { auto &port = mem.wr_ports[j]; RTLIL::SigSpec wr_addr = port.addr.extract_end(port.wide_log2); RTLIL::Wire *w_seladdr = addr_decode(wr_addr, RTLIL::SigSpec(addr >> port.wide_log2, GetSize(wr_addr))); int sub = addr & ((1 << port.wide_log2) - 1); int wr_offset = 0; while (wr_offset < mem.width) { int wr_width = 1; RTLIL::SigSpec wr_bit = port.en.extract(wr_offset + sub * mem.width, 1); while (wr_offset + wr_width < mem.width) { RTLIL::SigSpec next_wr_bit = port.en.extract(wr_offset + wr_width + sub * mem.width, 1); if (next_wr_bit != wr_bit) break; wr_width++; } RTLIL::Wire *w = w_seladdr; if (wr_bit != State::S1) { RTLIL::Cell *c = module->addCell(genid(mem.memid, "$wren", addr, "", j, "", wr_offset), ID($and)); c->parameters[ID::A_SIGNED] = RTLIL::Const(0); c->parameters[ID::B_SIGNED] = RTLIL::Const(0); c->parameters[ID::A_WIDTH] = RTLIL::Const(1); c->parameters[ID::B_WIDTH] = RTLIL::Const(1); c->parameters[ID::Y_WIDTH] = RTLIL::Const(1); c->setPort(ID::A, w); c->setPort(ID::B, wr_bit); w = module->addWire(genid(mem.memid, "$wren", addr, "", j, "", wr_offset, "$y")); c->setPort(ID::Y, RTLIL::SigSpec(w)); } RTLIL::Cell *c = module->addCell(genid(mem.memid, "$wrmux", addr, "", j, "", wr_offset), ID($mux)); c->parameters[ID::WIDTH] = wr_width; c->setPort(ID::A, sig.extract(wr_offset, wr_width)); c->setPort(ID::B, port.data.extract(wr_offset + sub * mem.width, wr_width)); c->setPort(ID::S, RTLIL::SigSpec(w)); w = module->addWire(genid(mem.memid, "$wrmux", addr, "", j, "", wr_offset, "$y"), wr_width); c->setPort(ID::Y, w); sig.replace(wr_offset, w); wr_offset += wr_width; count_wrmux++; } } module->connect(RTLIL::SigSig(data_reg_in[idx], sig)); } } log(" write interface: %d write mux blocks.\n", count_wrmux); mem.remove(); } void run() { for (auto &mem : Mem::get_selected_memories(module)) handle_memory(mem); } }; struct MemoryMapPass : public Pass { MemoryMapPass() : Pass("memory_map", "translate multiport memories to basic cells") { } void help() override { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" memory_map [options] [selection]\n"); log("\n"); log("This pass converts multiport memory cells as generated by the memory_collect\n"); log("pass to word-wide DFFs and address decoders.\n"); log("\n"); log(" -attr !\n"); log(" do not map memories that have attribute set.\n"); log("\n"); log(" -attr [=]\n"); log(" for memories that have attribute set, only map them if its value\n"); log(" is a string (if specified), or an integer 1 (otherwise). if this\n"); log(" option is specified multiple times, map the memory if the attribute is\n"); log(" to any of the values.\n"); log("\n"); log(" -iattr\n"); log(" for -attr, suppress case sensitivity in matching of .\n"); log("\n"); log(" -rom-only\n"); log(" only perform conversion for ROMs (memories with no write ports).\n"); log("\n"); log(" -keepdc\n"); log(" when mapping ROMs, keep x-bits shared across read ports.\n"); log("\n"); log(" -formal\n"); log(" map memories for a global clock based formal verification flow.\n"); log(" This implies -keepdc, uses $ff cells for ROMs and sets hdlname\n"); log(" attributes. It also has limited support for async write ports\n"); log(" as generated by clk2fflogic.\n"); log("\n"); } void execute(std::vector args, RTLIL::Design *design) override { bool attr_icase = false; bool rom_only = false; bool keepdc = false; bool formal = false; dict> attributes; log_header(design, "Executing MEMORY_MAP pass (converting memories to logic and flip-flops).\n"); size_t argidx; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-attr" && argidx + 1 < args.size()) { std::string attr_arg = args[++argidx]; std::string name; RTLIL::Const value; size_t eq_at = attr_arg.find('='); if (eq_at != std::string::npos) { name = attr_arg.substr(0, eq_at); value = attr_arg.substr(eq_at + 1); } else { name = attr_arg; value = RTLIL::Const(1); } if (attr_arg.size() > 1 && attr_arg[0] == '!') { if (value != RTLIL::Const(1)) { --argidx; break; // we don't support -attr != } attributes[RTLIL::escape_id(name.substr(1))].clear(); } else { attributes[RTLIL::escape_id(name)].push_back(value); } continue; } if (args[argidx] == "-iattr") { attr_icase = true; continue; } if (args[argidx] == "-rom-only") { rom_only = true; continue; } if (args[argidx] == "-keepdc") { keepdc = true; continue; } if (args[argidx] == "-formal") { formal = true; keepdc = true; continue; } break; } extra_args(args, argidx, design); for (auto mod : design->selected_modules()) { if (mod->has_processes_warn()) continue; MemoryMapWorker worker(design, mod); worker.attr_icase = attr_icase; worker.attributes = attributes; worker.rom_only = rom_only; worker.keepdc = keepdc; worker.formal = formal; worker.run(); } } } MemoryMapPass; PRIVATE_NAMESPACE_END