/* * nextpnr -- Next Generation Place and Route * * Copyright (C) 2018 Claire Xenia Wolf * Copyright (C) 2021 William D. Jones * * 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 #include #include "embed.h" #include "nextpnr.h" #include "placer1.h" #include "placer_heap.h" #include "router1.h" #include "router2.h" #include "util.h" NEXTPNR_NAMESPACE_BEGIN // ----------------------------------------------------------------------- void IdString::initialize_arch(const BaseCtx *ctx) { #define X(t) initialize_add(ctx, #t, ID_##t); #include "constids.inc" #undef X } // --------------------------------------------------------------- static const ChipInfoPOD *get_chip_info(ArchArgs::ArchArgsTypes chip) { std::string chipdb; if (chip == ArchArgs::LCMXO2_256HC) { chipdb = "machxo2/chipdb-256.bin"; } else if (chip == ArchArgs::LCMXO2_640HC) { chipdb = "machxo2/chipdb-640.bin"; } else if (chip == ArchArgs::LCMXO2_1200HC) { chipdb = "machxo2/chipdb-1200.bin"; } else if (chip == ArchArgs::LCMXO2_2000HC) { chipdb = "machxo2/chipdb-2000.bin"; } else if (chip == ArchArgs::LCMXO2_4000HC) { chipdb = "machxo2/chipdb-4000.bin"; } else if (chip == ArchArgs::LCMXO2_7000HC) { chipdb = "machxo2/chipdb-7000.bin"; } else { log_error("Unknown chip\n"); } auto ptr = reinterpret_cast *>(get_chipdb(chipdb)); if (ptr == nullptr) return nullptr; return ptr->get(); } // --------------------------------------------------------------- Arch::Arch(ArchArgs args) : args(args) { chip_info = get_chip_info(args.type); if (chip_info == nullptr) log_error("Unsupported MachXO2 chip type.\n"); if (chip_info->const_id_count != DB_CONST_ID_COUNT) log_error("Chip database 'bba' and nextpnr code are out of sync; please rebuild (or contact distribution " "maintainer)!\n"); package_info = nullptr; for (int i = 0; i < chip_info->num_packages; i++) { if (args.package == chip_info->package_info[i].name.get()) { package_info = &(chip_info->package_info[i]); break; } } if (!package_info) log_error("Unsupported package '%s' for '%s'.\n", args.package.c_str(), getChipName().c_str()); BaseArch::init_cell_types(); BaseArch::init_bel_buckets(); for (int i = 0; i < chip_info->width; i++) x_ids.push_back(idf("X%d", i)); for (int i = 0; i < chip_info->height; i++) y_ids.push_back(idf("Y%d", i)); for (int i = 0; i < chip_info->width; i++) { IdString x_id = idf("X%d", i); x_ids.push_back(x_id); id_to_x[x_id] = i; } for (int i = 0; i < chip_info->height; i++) { IdString y_id = idf("Y%d", i); y_ids.push_back(y_id); id_to_y[y_id] = i; } } bool Arch::is_available(ArchArgs::ArchArgsTypes chip) { return get_chip_info(chip) != nullptr; } std::vector Arch::get_supported_packages(ArchArgs::ArchArgsTypes chip) { const ChipInfoPOD *chip_info = get_chip_info(chip); std::vector pkgs; for (int i = 0; i < chip_info->num_packages; i++) { pkgs.push_back(chip_info->package_info[i].name.get()); } return pkgs; } std::string Arch::getChipName() const { if (args.type == ArchArgs::LCMXO2_256HC) { return "LCMXO2-256HC"; } else if (args.type == ArchArgs::LCMXO2_640HC) { return "LCMXO2-640HC"; } else if (args.type == ArchArgs::LCMXO2_1200HC) { return "LCMXO2-1200HC"; } else if (args.type == ArchArgs::LCMXO2_2000HC) { return "LCMXO2-2000HC"; } else if (args.type == ArchArgs::LCMXO2_4000HC) { return "LCMXO2-4000HC"; } else if (args.type == ArchArgs::LCMXO2_7000HC) { return "LCMXO2-7000HC"; } else { log_error("Unknown chip\n"); } } std::string Arch::get_full_chip_name() const { std::string name = getChipName(); name += "-"; switch (args.speed) { case ArchArgs::SPEED_1: name += "1"; break; case ArchArgs::SPEED_2: name += "2"; break; case ArchArgs::SPEED_3: name += "3"; break; case ArchArgs::SPEED_4: name += "4"; break; case ArchArgs::SPEED_5: name += "5"; break; case ArchArgs::SPEED_6: name += "6"; break; } name += args.package; return name; } IdString Arch::archArgsToId(ArchArgs args) const { if (args.type == ArchArgs::LCMXO2_256HC) { return id_lcmxo2_256hc; } else if (args.type == ArchArgs::LCMXO2_640HC) { return id_lcmxo2_640hc; } else if (args.type == ArchArgs::LCMXO2_1200HC) { return id_lcmxo2_1200hc; } else if (args.type == ArchArgs::LCMXO2_2000HC) { return id_lcmxo2_2000hc; } else if (args.type == ArchArgs::LCMXO2_4000HC) { return id_lcmxo2_4000hc; } else if (args.type == ArchArgs::LCMXO2_7000HC) { return id_lcmxo2_7000hc; } return IdString(); } // --------------------------------------------------------------- BelId Arch::getBelByName(IdStringList name) const { if (name.size() != 3) return BelId(); BelId ret; Location loc; loc.x = id_to_x.at(name[0]); loc.y = id_to_y.at(name[1]); ret.location = loc; const TileTypePOD *loci = tile_info(ret); for (int i = 0; i < loci->num_bels; i++) { if (std::strcmp(loci->bel_data[i].name.get(), name[2].c_str(this)) == 0) { ret.index = i; return ret; } } return BelId(); } BelId Arch::getBelByLocation(Loc loc) const { BelId ret; if (loc.x >= chip_info->width || loc.y >= chip_info->height) return BelId(); ret.location.x = loc.x; ret.location.y = loc.y; const TileTypePOD *tilei = tile_info(ret); for (int i = 0; i < tilei->num_bels; i++) { if (tilei->bel_data[i].z == loc.z) { ret.index = i; return ret; } } return BelId(); } BelRange Arch::getBelsByTile(int x, int y) const { BelRange br; br.b.cursor_tile = y * chip_info->width + x; br.e.cursor_tile = y * chip_info->width + x; br.b.cursor_index = 0; br.e.cursor_index = chip_info->tiles[y * chip_info->width + x].num_bels - 1; br.b.chip = chip_info; br.e.chip = chip_info; if (br.e.cursor_index == -1) ++br.e.cursor_index; else ++br.e; return br; } bool Arch::getBelGlobalBuf(BelId bel) const { return false; } WireId Arch::getBelPinWire(BelId bel, IdString pin) const { NPNR_ASSERT(bel != BelId()); int num_bel_wires = tile_info(bel)->bel_data[bel.index].num_bel_wires; const BelWirePOD *bel_wires = &*tile_info(bel)->bel_data[bel.index].bel_wires; for (int i = 0; i < num_bel_wires; i++) if (bel_wires[i].port == pin.index) { WireId ret; ret.location.x = bel_wires[i].rel_wire_loc.x; ret.location.y = bel_wires[i].rel_wire_loc.y; ret.index = bel_wires[i].wire_index; return ret; } return WireId(); } PortType Arch::getBelPinType(BelId bel, IdString pin) const { NPNR_ASSERT(bel != BelId()); int num_bel_wires = tile_info(bel)->bel_data[bel.index].num_bel_wires; const BelWirePOD *bel_wires = &*tile_info(bel)->bel_data[bel.index].bel_wires; for (int i = 0; i < num_bel_wires; i++) if (bel_wires[i].port == pin.index) return PortType(bel_wires[i].dir); return PORT_INOUT; } std::vector Arch::getBelPins(BelId bel) const { std::vector ret; NPNR_ASSERT(bel != BelId()); int num_bel_wires = tile_info(bel)->bel_data[bel.index].num_bel_wires; const BelWirePOD *bel_wires = &*tile_info(bel)->bel_data[bel.index].bel_wires; for (int i = 0; i < num_bel_wires; i++) { IdString id(bel_wires[i].port); ret.push_back(id); } return ret; } // --------------------------------------------------------------- BelId Arch::getPackagePinBel(const std::string &pin) const { for (int i = 0; i < package_info->num_pins; i++) { if (package_info->pin_data[i].name.get() == pin) { BelId bel; bel.location = package_info->pin_data[i].abs_loc; bel.index = package_info->pin_data[i].bel_index; return bel; } } return BelId(); } // --------------------------------------------------------------- WireId Arch::getWireByName(IdStringList name) const { if (name.size() != 3) return WireId(); WireId ret; Location loc; loc.x = id_to_x.at(name[0]); loc.y = id_to_y.at(name[1]); ret.location = loc; const TileTypePOD *loci = tile_info(ret); for (int i = 0; i < loci->num_wires; i++) { if (std::strcmp(loci->wire_data[i].name.get(), name[2].c_str(this)) == 0) { ret.index = i; return ret; } } return WireId(); } // --------------------------------------------------------------- PipId Arch::getPipByName(IdStringList name) const { if (name.size() != 3) return PipId(); auto it = pip_by_name.find(name); if (it != pip_by_name.end()) return it->second; PipId ret; Location loc; std::string basename; loc.x = id_to_x.at(name[0]); loc.y = id_to_y.at(name[1]); ret.location = loc; const TileTypePOD *loci = tile_info(ret); for (int i = 0; i < loci->num_pips; i++) { PipId curr; curr.location = loc; curr.index = i; pip_by_name[getPipName(curr)] = curr; } if (pip_by_name.find(name) == pip_by_name.end()) NPNR_ASSERT_FALSE_STR("no pip named " + name.str(getCtx())); return pip_by_name[name]; } IdStringList Arch::getPipName(PipId pip) const { auto &pip_data = tile_info(pip)->pips_data[pip.index]; WireId src = getPipSrcWire(pip), dst = getPipDstWire(pip); const char *src_name = tile_info(src)->wire_data[src.index].name.get(); const char *dst_name = tile_info(dst)->wire_data[dst.index].name.get(); std::string pip_name = stringf("%d_%d_%s->%d_%d_%s", pip_data.src.x - pip.location.x, pip_data.src.y - pip.location.y, src_name, pip_data.dst.x - pip.location.x, pip_data.dst.y - pip.location.y, dst_name); std::array ids{x_ids.at(pip.location.x), y_ids.at(pip.location.y), id(pip_name)}; return IdStringList(ids); } // --------------------------------------------------------------- delay_t Arch::estimateDelay(WireId src, WireId dst) const { // Taxicab distance multiplied by pipDelay (0.01) and fake wireDelay (0.01). // TODO: This function will not work well for entrance to global routing, // as the entrances are located physically far from the DCCAs. return (abs(dst.location.x - src.location.x) + abs(dst.location.y - src.location.y)) * (0.01 + 0.01); } delay_t Arch::predictDelay(BelId src_bel, IdString src_pin, BelId dst_bel, IdString dst_pin) const { NPNR_UNUSED(src_pin); NPNR_UNUSED(dst_pin); NPNR_ASSERT(src_bel != BelId()); NPNR_ASSERT(dst_bel != BelId()); // TODO: Same deal applies here as with estimateDelay. return (abs(dst_bel.location.x - src_bel.location.x) + abs(dst_bel.location.y - src_bel.location.y)) * (0.01 + 0.01); } BoundingBox Arch::getRouteBoundingBox(WireId src, WireId dst) const { BoundingBox bb; bb.x0 = std::min(src.location.x, dst.location.x); bb.y0 = std::min(src.location.y, dst.location.y); bb.x1 = std::max(src.location.x, dst.location.x); bb.y1 = std::max(src.location.y, dst.location.y); return bb; } // --------------------------------------------------------------- bool Arch::place() { std::string placer = str_or_default(settings, id_placer, defaultPlacer); if (placer == "sa") { bool retVal = placer1(getCtx(), Placer1Cfg(getCtx())); getCtx()->settings[id_place] = 1; archInfoToAttributes(); return retVal; } else if (placer == "heap") { PlacerHeapCfg cfg(getCtx()); cfg.ioBufTypes.insert(id_FACADE_IO); bool retVal = placer_heap(getCtx(), cfg); getCtx()->settings[id_place] = 1; archInfoToAttributes(); return retVal; } else { log_error("MachXO2 architecture does not support placer '%s'\n", placer.c_str()); } } bool Arch::route() { std::string router = str_or_default(settings, id_router, defaultRouter); bool result; if (router == "router1") { result = router1(getCtx(), Router1Cfg(getCtx())); } else if (router == "router2") { router2(getCtx(), Router2Cfg(getCtx())); result = true; } else { log_error("MachXO2 architecture does not support router '%s'\n", router.c_str()); } getCtx()->settings[id_route] = 1; archInfoToAttributes(); return result; } // --------------------------------------------------------------- bool Arch::isBelLocationValid(BelId bel, bool explain_invalid) const { // FIXME: Same deal as isValidBelForCell. return true; } #ifdef WITH_HEAP const std::string Arch::defaultPlacer = "heap"; #else const std::string Arch::defaultPlacer = "sa"; #endif const std::vector Arch::availablePlacers = {"sa", #ifdef WITH_HEAP "heap" #endif }; const std::string Arch::defaultRouter = "router1"; const std::vector Arch::availableRouters = {"router1", "router2"}; bool Arch::cells_compatible(const CellInfo **cells, int count) const { return false; } std::vector> Arch::get_tiles_at_location(int row, int col) { std::vector> ret; auto &tileloc = chip_info->tile_info[row * chip_info->width + col]; for (int i = 0; i < tileloc.num_tiles; i++) { ret.push_back(std::make_pair(tileloc.tile_names[i].name.get(), chip_info->tiletype_names[tileloc.tile_names[i].type_idx].get())); } return ret; } NEXTPNR_NAMESPACE_END