/* * nextpnr -- Next Generation Place and Route * * Copyright (C) 2018 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. * */ #ifndef NEXTPNR_H #error Include "arch.h" via "nextpnr.h" only. #endif #ifdef NEXTPNR_ARCH_TOP NEXTPNR_NAMESPACE_BEGIN typedef int delay_t; struct DelayInfo { delay_t delay = 0; delay_t raiseDelay() const { return delay; } delay_t fallDelay() const { return delay; } delay_t avgDelay() const { return delay; } DelayInfo operator+(const DelayInfo &other) const { DelayInfo ret; ret.delay = this->delay + other.delay; return ret; } }; // ----------------------------------------------------------------------- enum BelType : int32_t { TYPE_NONE, TYPE_ICESTORM_LC, TYPE_ICESTORM_RAM, TYPE_SB_IO, TYPE_SB_GB, TYPE_ICESTORM_PLL, TYPE_SB_WARMBOOT, TYPE_SB_MAC16, TYPE_ICESTORM_HFOSC, TYPE_ICESTORM_LFOSC, TYPE_SB_I2C, TYPE_SB_SPI, TYPE_IO_I3C, TYPE_SB_LEDDA_IP, TYPE_SB_RGBA_DRV, TYPE_SB_SPRAM256KA, }; enum PortPin : int32_t { PIN_NONE, #define X(t) PIN_##t, #include "portpins.inc" #undef X PIN_MAXIDX }; enum WireType : int8_t { WIRE_TYPE_NONE = 0, WIRE_TYPE_LOCAL = 1, WIRE_TYPE_GLOBAL = 2, WIRE_TYPE_SP4_VERT = 3, WIRE_TYPE_SP4_HORZ = 4, WIRE_TYPE_SP12_HORZ = 5, WIRE_TYPE_SP12_VERT = 6 }; // ----------------------------------------------------------------------- /**** Everything in this section must be kept in sync with chipdb.py ****/ template struct RelPtr { int32_t offset; // void set(const T *ptr) { // offset = reinterpret_cast(ptr) - // reinterpret_cast(this); // } const T *get() const { return reinterpret_cast(reinterpret_cast(this) + offset); } const T &operator[](size_t index) const { return get()[index]; } const T &operator*() const { return *(get()); } const T *operator->() const { return get(); } }; struct BelWirePOD { int32_t wire_index; PortPin port; } __attribute__((packed)); struct BelInfoPOD { RelPtr name; BelType type; int32_t num_bel_wires; RelPtr bel_wires; int8_t x, y, z; int8_t padding_0; } __attribute__((packed)); struct BelPortPOD { int32_t bel_index; PortPin port; } __attribute__((packed)); struct PipInfoPOD { int32_t src, dst; int32_t delay; int8_t x, y; int16_t switch_mask; int32_t switch_index; } __attribute__((packed)); struct WireInfoPOD { RelPtr name; int32_t num_uphill, num_downhill; RelPtr pips_uphill, pips_downhill; int32_t num_bels_downhill; BelPortPOD bel_uphill; RelPtr bels_downhill; int8_t x, y; WireType type; int8_t padding_0; } __attribute__((packed)); struct PackagePinPOD { RelPtr name; int32_t bel_index; } __attribute__((packed)); struct PackageInfoPOD { RelPtr name; int32_t num_pins; RelPtr pins; } __attribute__((packed)); enum TileType : uint32_t { TILE_NONE = 0, TILE_LOGIC = 1, TILE_IO = 2, TILE_RAMB = 3, TILE_RAMT = 4, TILE_DSP0 = 5, TILE_DSP1 = 6, TILE_DSP2 = 7, TILE_DSP3 = 8, TILE_IPCON = 9 }; struct ConfigBitPOD { int8_t row, col; } __attribute__((packed)); struct ConfigEntryPOD { RelPtr name; int32_t num_bits; RelPtr bits; } __attribute__((packed)); struct TileInfoPOD { int8_t cols, rows; int16_t num_config_entries; RelPtr entries; } __attribute__((packed)); static const int max_switch_bits = 5; struct SwitchInfoPOD { int32_t num_bits; int8_t x, y; ConfigBitPOD cbits[max_switch_bits]; } __attribute__((packed)); struct IerenInfoPOD { int8_t iox, ioy, ioz; int8_t ierx, iery, ierz; } __attribute__((packed)); struct BitstreamInfoPOD { int32_t num_switches, num_ierens; RelPtr tiles_nonrouting; RelPtr switches; RelPtr ierens; } __attribute__((packed)); struct ChipInfoPOD { int32_t width, height; int32_t num_bels, num_wires, num_pips; int32_t num_switches, num_packages; RelPtr bel_data; RelPtr wire_data; RelPtr pip_data; RelPtr tile_grid; RelPtr bits_info; RelPtr packages_data; } __attribute__((packed)); extern const char chipdb_blob_384[]; extern const char chipdb_blob_1k[]; extern const char chipdb_blob_5k[]; extern const char chipdb_blob_8k[]; /************************ End of chipdb section. ************************/ // ----------------------------------------------------------------------- struct BelId { int32_t index = -1; bool operator==(const BelId &other) const { return index == other.index; } bool operator!=(const BelId &other) const { return index != other.index; } }; struct WireId { int32_t index = -1; bool operator==(const WireId &other) const { return index == other.index; } bool operator!=(const WireId &other) const { return index != other.index; } }; struct PipId { int32_t index = -1; bool operator==(const PipId &other) const { return index == other.index; } bool operator!=(const PipId &other) const { return index != other.index; } }; struct BelPin { BelId bel; PortPin pin; }; NEXTPNR_NAMESPACE_END namespace std { template <> struct hash { std::size_t operator()(const NEXTPNR_NAMESPACE_PREFIX BelId &bel) const noexcept { return hash()(bel.index); } }; template <> struct hash { std::size_t operator()(const NEXTPNR_NAMESPACE_PREFIX WireId &wire) const noexcept { return hash()(wire.index); } }; template <> struct hash { std::size_t operator()(const NEXTPNR_NAMESPACE_PREFIX PipId &pip) const noexcept { return hash()(pip.index); } }; template <> struct hash : hash { }; template <> struct hash : hash { }; } // namespace std NEXTPNR_NAMESPACE_BEGIN // ----------------------------------------------------------------------- struct BelIterator { int cursor; BelIterator operator++() { cursor++; return *this; } BelIterator operator++(int) { BelIterator prior(*this); cursor++; return prior; } bool operator!=(const BelIterator &other) const { return cursor != other.cursor; } bool operator==(const BelIterator &other) const { return cursor == other.cursor; } BelId operator*() const { BelId ret; ret.index = cursor; return ret; } }; struct BelRange { BelIterator b, e; BelIterator begin() const { return b; } BelIterator end() const { return e; } }; // ----------------------------------------------------------------------- struct BelPinIterator { const BelPortPOD *ptr = nullptr; void operator++() { ptr++; } bool operator!=(const BelPinIterator &other) const { return ptr != other.ptr; } BelPin operator*() const { BelPin ret; ret.bel.index = ptr->bel_index; ret.pin = ptr->port; return ret; } }; struct BelPinRange { BelPinIterator b, e; BelPinIterator begin() const { return b; } BelPinIterator end() const { return e; } }; // ----------------------------------------------------------------------- struct WireIterator { int cursor = -1; void operator++() { cursor++; } bool operator!=(const WireIterator &other) const { return cursor != other.cursor; } WireId operator*() const { WireId ret; ret.index = cursor; return ret; } }; struct WireRange { WireIterator b, e; WireIterator begin() const { return b; } WireIterator end() const { return e; } }; // ----------------------------------------------------------------------- struct AllPipIterator { int cursor = -1; void operator++() { cursor++; } bool operator!=(const AllPipIterator &other) const { return cursor != other.cursor; } PipId operator*() const { PipId ret; ret.index = cursor; return ret; } }; struct AllPipRange { AllPipIterator b, e; AllPipIterator begin() const { return b; } AllPipIterator end() const { return e; } }; // ----------------------------------------------------------------------- struct PipIterator { const int *cursor = nullptr; void operator++() { cursor++; } bool operator!=(const PipIterator &other) const { return cursor != other.cursor; } PipId operator*() const { PipId ret; ret.index = *cursor; return ret; } }; struct PipRange { PipIterator b, e; PipIterator begin() const { return b; } PipIterator end() const { return e; } }; NEXTPNR_NAMESPACE_END #endif // NEXTPNR_ARCH_TOP // ----------------------------------------------------------------------- #ifdef NEXTPNR_ARCH_BOTTOM NEXTPNR_NAMESPACE_BEGIN struct ArchArgs { enum { NONE, LP384, LP1K, LP8K, HX1K, HX8K, UP5K } type = NONE; std::string package; }; struct Arch : BaseCtx { const ChipInfoPOD *chip_info; const PackageInfoPOD *package_info; mutable std::unordered_map bel_by_name; mutable std::unordered_map wire_by_name; mutable std::unordered_map pip_by_name; std::vector bel_to_cell; std::vector wire_to_net; std::vector pip_to_net; std::vector switches_locked; ArchArgs args; Arch(ArchArgs args); std::string getChipName(); IdString archId() const { return id("ice40"); } IdString archArgsToId(ArchArgs args) const; IdString belTypeToId(BelType type) const; BelType belTypeFromId(IdString id) const; IdString portPinToId(PortPin type) const; PortPin portPinFromId(IdString id) const; // ------------------------------------------------- BelId getBelByName(IdString name) const; IdString getBelName(BelId bel) const { assert(bel != BelId()); return id(chip_info->bel_data[bel.index].name.get()); } uint32_t getBelChecksum(BelId bel) const { return bel.index; } void bindBel(BelId bel, IdString cell, PlaceStrength strength) { assert(bel != BelId()); assert(bel_to_cell[bel.index] == IdString()); bel_to_cell[bel.index] = cell; cells[cell]->bel = bel; cells[cell]->belStrength = strength; } void unbindBel(BelId bel) { assert(bel != BelId()); assert(bel_to_cell[bel.index] != IdString()); cells[bel_to_cell[bel.index]]->bel = BelId(); cells[bel_to_cell[bel.index]]->belStrength = STRENGTH_NONE; bel_to_cell[bel.index] = IdString(); } bool checkBelAvail(BelId bel) const { assert(bel != BelId()); return bel_to_cell[bel.index] == IdString(); } IdString getBoundBelCell(BelId bel) const { assert(bel != BelId()); return bel_to_cell[bel.index]; } IdString getConflictingBelCell(BelId bel) const { assert(bel != BelId()); return bel_to_cell[bel.index]; } BelRange getBels() const { BelRange range; range.b.cursor = 0; range.e.cursor = chip_info->num_bels; return range; } BelRange getBelsByType(BelType type) const { BelRange range; // FIXME #if 0 if (type == "TYPE_A") { range.b.cursor = bels_type_a_begin; range.e.cursor = bels_type_a_end; } ... #endif return range; } BelRange getBelsAtSameTile(BelId bel) const; BelType getBelType(BelId bel) const { assert(bel != BelId()); return chip_info->bel_data[bel.index].type; } WireId getWireBelPin(BelId bel, PortPin pin) const; BelPin getBelPinUphill(WireId wire) const { BelPin ret; assert(wire != WireId()); if (chip_info->wire_data[wire.index].bel_uphill.bel_index >= 0) { ret.bel.index = chip_info->wire_data[wire.index].bel_uphill.bel_index; ret.pin = chip_info->wire_data[wire.index].bel_uphill.port; } return ret; } BelPinRange getBelPinsDownhill(WireId wire) const { BelPinRange range; assert(wire != WireId()); range.b.ptr = chip_info->wire_data[wire.index].bels_downhill.get(); range.e.ptr = range.b.ptr + chip_info->wire_data[wire.index].num_bels_downhill; return range; } // ------------------------------------------------- WireId getWireByName(IdString name) const; IdString getWireName(WireId wire) const { assert(wire != WireId()); return id(chip_info->wire_data[wire.index].name.get()); } uint32_t getWireChecksum(WireId wire) const { return wire.index; } void bindWire(WireId wire, IdString net, PlaceStrength strength) { assert(wire != WireId()); assert(wire_to_net[wire.index] == IdString()); wire_to_net[wire.index] = net; nets[net]->wires[wire].pip = PipId(); nets[net]->wires[wire].strength = strength; } void unbindWire(WireId wire) { assert(wire != WireId()); assert(wire_to_net[wire.index] != IdString()); auto &net_wires = nets[wire_to_net[wire.index]]->wires; auto it = net_wires.find(wire); assert(it != net_wires.end()); auto pip = it->second.pip; if (pip != PipId()) { pip_to_net[pip.index] = IdString(); switches_locked[chip_info->pip_data[pip.index].switch_index] = IdString(); } net_wires.erase(it); wire_to_net[wire.index] = IdString(); } bool checkWireAvail(WireId wire) const { assert(wire != WireId()); return wire_to_net[wire.index] == IdString(); } IdString getBoundWireNet(WireId wire) const { assert(wire != WireId()); return wire_to_net[wire.index]; } IdString getConflictingWireNet(WireId wire) const { assert(wire != WireId()); return wire_to_net[wire.index]; } WireRange getWires() const { WireRange range; range.b.cursor = 0; range.e.cursor = chip_info->num_wires; return range; } // ------------------------------------------------- PipId getPipByName(IdString name) const; IdString getPipName(PipId pip) const; uint32_t getPipChecksum(PipId pip) const { return pip.index; } void bindPip(PipId pip, IdString net, PlaceStrength strength) { assert(pip != PipId()); assert(pip_to_net[pip.index] == IdString()); assert(switches_locked[chip_info->pip_data[pip.index].switch_index] == IdString()); pip_to_net[pip.index] = net; switches_locked[chip_info->pip_data[pip.index].switch_index] = net; WireId dst; dst.index = chip_info->pip_data[pip.index].dst; assert(wire_to_net[dst.index] == IdString()); wire_to_net[dst.index] = net; nets[net]->wires[dst].pip = pip; nets[net]->wires[dst].strength = strength; } void unbindPip(PipId pip) { assert(pip != PipId()); assert(pip_to_net[pip.index] != IdString()); assert(switches_locked[chip_info->pip_data[pip.index].switch_index] != IdString()); WireId dst; dst.index = chip_info->pip_data[pip.index].dst; assert(wire_to_net[dst.index] != IdString()); wire_to_net[dst.index] = IdString(); nets[pip_to_net[pip.index]]->wires.erase(dst); pip_to_net[pip.index] = IdString(); switches_locked[chip_info->pip_data[pip.index].switch_index] = IdString(); } bool checkPipAvail(PipId pip) const { assert(pip != PipId()); return switches_locked[chip_info->pip_data[pip.index].switch_index] == IdString(); } IdString getBoundPipNet(PipId pip) const { assert(pip != PipId()); return pip_to_net[pip.index]; } IdString getConflictingPipNet(PipId pip) const { assert(pip != PipId()); return switches_locked[chip_info->pip_data[pip.index].switch_index]; } AllPipRange getPips() const { AllPipRange range; range.b.cursor = 0; range.e.cursor = chip_info->num_pips; return range; } WireId getPipSrcWire(PipId pip) const { WireId wire; assert(pip != PipId()); wire.index = chip_info->pip_data[pip.index].src; return wire; } WireId getPipDstWire(PipId pip) const { WireId wire; assert(pip != PipId()); wire.index = chip_info->pip_data[pip.index].dst; return wire; } DelayInfo getPipDelay(PipId pip) const { DelayInfo delay; assert(pip != PipId()); delay.delay = chip_info->pip_data[pip.index].delay; return delay; } PipRange getPipsDownhill(WireId wire) const { PipRange range; assert(wire != WireId()); range.b.cursor = chip_info->wire_data[wire.index].pips_downhill.get(); range.e.cursor = range.b.cursor + chip_info->wire_data[wire.index].num_downhill; return range; } PipRange getPipsUphill(WireId wire) const { PipRange range; assert(wire != WireId()); range.b.cursor = chip_info->wire_data[wire.index].pips_uphill.get(); range.e.cursor = range.b.cursor + chip_info->wire_data[wire.index].num_uphill; return range; } PipRange getWireAliases(WireId wire) const { PipRange range; assert(wire != WireId()); range.b.cursor = nullptr; range.e.cursor = nullptr; return range; } BelId getPackagePinBel(const std::string &pin) const; std::string getBelPackagePin(BelId bel) const; // ------------------------------------------------- void estimatePosition(BelId bel, int &x, int &y, bool &gb) const; delay_t estimateDelay(WireId src, WireId dst) const; delay_t getDelayEpsilon() const { return 20; } delay_t getRipupDelayPenalty() const { return 200; } float getDelayNS(delay_t v) const { return v * 0.001; } uint32_t getDelayChecksum(delay_t v) const { return v; } // ------------------------------------------------- std::vector getFrameGraphics() const; std::vector getBelGraphics(BelId bel) const; std::vector getWireGraphics(WireId wire) const; std::vector getPipGraphics(PipId pip) const; bool allGraphicsReload = false; bool frameGraphicsReload = false; std::unordered_set belGraphicsReload; std::unordered_set wireGraphicsReload; std::unordered_set pipGraphicsReload; // ------------------------------------------------- // Get the delay through a cell from one port to another, returning false // if no path exists bool getCellDelay(const CellInfo *cell, IdString fromPort, IdString toPort, delay_t &delay) const; // Get the associated clock to a port, or empty if the port is combinational IdString getPortClock(const CellInfo *cell, IdString port) const; // Return true if a port is a clock bool isClockPort(const CellInfo *cell, IdString port) const; // Return true if a port is a net bool isGlobalNet(const NetInfo *net) const; IdString id_glb_buf_out; }; NEXTPNR_NAMESPACE_END #endif // NEXTPNR_ARCH_BOTTOM