/* * 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. * */ #ifndef CELLTYPES_H #define CELLTYPES_H #include "kernel/yosys.h" YOSYS_NAMESPACE_BEGIN struct CellType { RTLIL::IdString type; pool inputs, outputs; bool is_evaluable; }; struct CellTypes { dict cell_types; CellTypes() { } CellTypes(RTLIL::Design *design) { setup(design); } void setup(RTLIL::Design *design = NULL) { if (design) setup_design(design); setup_internals(); setup_internals_mem(); setup_stdcells(); setup_stdcells_mem(); } void setup_type(RTLIL::IdString type, const pool &inputs, const pool &outputs, bool is_evaluable = false) { CellType ct = {type, inputs, outputs, is_evaluable}; cell_types[ct.type] = ct; } void setup_module(RTLIL::Module *module) { pool inputs, outputs; for (RTLIL::IdString wire_name : module->ports) { RTLIL::Wire *wire = module->wire(wire_name); if (wire->port_input) inputs.insert(wire->name); if (wire->port_output) outputs.insert(wire->name); } setup_type(module->name, inputs, outputs); } void setup_design(RTLIL::Design *design) { for (auto module : design->modules()) setup_module(module); } void setup_internals() { setup_internals_eval(); IdString A = "\\A", B = "\\B", EN = "\\EN", Y = "\\Y"; IdString SRC = "\\SRC", DST = "\\DST", DAT = "\\DAT"; IdString EN_SRC = "\\EN_SRC", EN_DST = "\\EN_DST"; setup_type("$tribuf", {A, EN}, {Y}, true); setup_type("$assert", {A, EN}, pool(), true); setup_type("$assume", {A, EN}, pool(), true); setup_type("$live", {A, EN}, pool(), true); setup_type("$fair", {A, EN}, pool(), true); setup_type("$cover", {A, EN}, pool(), true); setup_type("$initstate", pool(), {Y}, true); setup_type("$anyconst", pool(), {Y}, true); setup_type("$anyseq", pool(), {Y}, true); setup_type("$allconst", pool(), {Y}, true); setup_type("$allseq", pool(), {Y}, true); setup_type("$equiv", {A, B}, {Y}, true); setup_type("$specify2", {EN, SRC, DST}, pool(), true); setup_type("$specify3", {EN, SRC, DST, DAT}, pool(), true); setup_type("$specrule", {EN_SRC, EN_DST, SRC, DST}, pool(), true); } void setup_internals_eval() { std::vector unary_ops = { "$not", "$pos", "$neg", "$reduce_and", "$reduce_or", "$reduce_xor", "$reduce_xnor", "$reduce_bool", "$logic_not", "$slice", "$lut", "$sop" }; std::vector binary_ops = { "$and", "$or", "$xor", "$xnor", "$shl", "$shr", "$sshl", "$sshr", "$shift", "$shiftx", "$lt", "$le", "$eq", "$ne", "$eqx", "$nex", "$ge", "$gt", "$add", "$sub", "$mul", "$div", "$mod", "$pow", "$logic_and", "$logic_or", "$concat", "$macc" }; IdString A = "\\A", B = "\\B", S = "\\S", Y = "\\Y"; IdString P = "\\P", G = "\\G", C = "\\C", X = "\\X"; IdString BI = "\\BI", CI = "\\CI", CO = "\\CO", EN = "\\EN"; for (auto type : unary_ops) setup_type(type, {A}, {Y}, true); for (auto type : binary_ops) setup_type(type, {A, B}, {Y}, true); for (auto type : std::vector({"$mux", "$pmux"})) setup_type(type, {A, B, S}, {Y}, true); setup_type("$lcu", {P, G, CI}, {CO}, true); setup_type("$alu", {A, B, CI, BI}, {X, Y, CO}, true); setup_type("$fa", {A, B, C}, {X, Y}, true); } void setup_internals_mem() { IdString SET = "\\SET", CLR = "\\CLR", CLK = "\\CLK", ARST = "\\ARST", EN = "\\EN"; IdString Q = "\\Q", D = "\\D", ADDR = "\\ADDR", DATA = "\\DATA", RD_EN = "\\RD_EN"; IdString RD_CLK = "\\RD_CLK", RD_ADDR = "\\RD_ADDR", WR_CLK = "\\WR_CLK", WR_EN = "\\WR_EN"; IdString WR_ADDR = "\\WR_ADDR", WR_DATA = "\\WR_DATA", RD_DATA = "\\RD_DATA"; IdString CTRL_IN = "\\CTRL_IN", CTRL_OUT = "\\CTRL_OUT"; setup_type("$sr", {SET, CLR}, {Q}); setup_type("$ff", {D}, {Q}); setup_type("$dff", {CLK, D}, {Q}); setup_type("$dffe", {CLK, EN, D}, {Q}); setup_type("$dffsr", {CLK, SET, CLR, D}, {Q}); setup_type("$adff", {CLK, ARST, D}, {Q}); setup_type("$dlatch", {EN, D}, {Q}); setup_type("$dlatchsr", {EN, SET, CLR, D}, {Q}); setup_type("$memrd", {CLK, EN, ADDR}, {DATA}); setup_type("$memwr", {CLK, EN, ADDR, DATA}, pool()); setup_type("$meminit", {ADDR, DATA}, pool()); setup_type("$mem", {RD_CLK, RD_EN, RD_ADDR, WR_CLK, WR_EN, WR_ADDR, WR_DATA}, {RD_DATA}); setup_type("$fsm", {CLK, ARST, CTRL_IN}, {CTRL_OUT}); } void setup_stdcells() { setup_stdcells_eval(); IdString A = "\\A", E = "\\E", Y = "\\Y"; setup_type("$_TBUF_", {A, E}, {Y}, true); } void setup_stdcells_eval() { IdString A = "\\A", B = "\\B", C = "\\C", D = "\\D"; IdString E = "\\E", F = "\\F", G = "\\G", H = "\\H"; IdString I = "\\I", J = "\\J", K = "\\K", L = "\\L"; IdString M = "\\M", N = "\\N", O = "\\O", P = "\\P"; IdString S = "\\S", T = "\\T", U = "\\U", V = "\\V"; IdString Y = "\\Y"; setup_type("$_BUF_", {A}, {Y}, true); setup_type("$_NOT_", {A}, {Y}, true); setup_type("$_AND_", {A, B}, {Y}, true); setup_type("$_NAND_", {A, B}, {Y}, true); setup_type("$_OR_", {A, B}, {Y}, true); setup_type("$_NOR_", {A, B}, {Y}, true); setup_type("$_XOR_", {A, B}, {Y}, true); setup_type("$_XNOR_", {A, B}, {Y}, true); setup_type("$_ANDNOT_", {A, B}, {Y}, true); setup_type("$_ORNOT_", {A, B}, {Y}, true); setup_type("$_MUX_", {A, B, S}, {Y}, true); setup_type("$_MUX4_", {A, B, C, D, S, T}, {Y}, true); setup_type("$_MUX8_", {A, B, C, D, E, F, G, H, S, T, U}, {Y}, true); setup_type("$_MUX16_", {A, B, C, D, E, F, G, H, I, J, K, L, M, N, O, P, S, T, U, V}, {Y}, true); setup_type("$_AOI3_", {A, B, C}, {Y}, true); setup_type("$_OAI3_", {A, B, C}, {Y}, true); setup_type("$_AOI4_", {A, B, C, D}, {Y}, true); setup_type("$_OAI4_", {A, B, C, D}, {Y}, true); } void setup_stdcells_mem() { IdString S = "\\S", R = "\\R", C = "\\C"; IdString D = "\\D", Q = "\\Q", E = "\\E"; std::vector list_np = {'N', 'P'}, list_01 = {'0', '1'}; for (auto c1 : list_np) for (auto c2 : list_np) setup_type(stringf("$_SR_%c%c_", c1, c2), {S, R}, {Q}); setup_type("$_FF_", {D}, {Q}); for (auto c1 : list_np) setup_type(stringf("$_DFF_%c_", c1), {C, D}, {Q}); for (auto c1 : list_np) for (auto c2 : list_np) setup_type(stringf("$_DFFE_%c%c_", c1, c2), {C, D, E}, {Q}); for (auto c1 : list_np) for (auto c2 : list_np) for (auto c3 : list_01) setup_type(stringf("$_DFF_%c%c%c_", c1, c2, c3), {C, R, D}, {Q}); for (auto c1 : list_np) for (auto c2 : list_np) for (auto c3 : list_np) setup_type(stringf("$_DFFSR_%c%c%c_", c1, c2, c3), {C, S, R, D}, {Q}); for (auto c1 : list_np) setup_type(stringf("$_DLATCH_%c_", c1), {E, D}, {Q}); for (auto c1 : list_np) for (auto c2 : list_np) for (auto c3 : list_np) setup_type(stringf("$_DLATCHSR_%c%c%c_", c1, c2, c3), {E, S, R, D}, {Q}); } void clear() { cell_types.clear(); } bool cell_known(RTLIL::IdString type) { return cell_types.count(type) != 0; } bool cell_output(RTLIL::IdString type, RTLIL::IdString port) { auto it = cell_types.find(type); return it != cell_types.end() && it->second.outputs.count(port) != 0; } bool cell_input(RTLIL::IdString type, RTLIL::IdString port) { auto it = cell_types.find(type); return it != cell_types.end() && it->second.inputs.count(port) != 0; } bool cell_evaluable(RTLIL::IdString type) { auto it = cell_types.find(type); return it != cell_types.end() && it->second.is_evaluable; } static RTLIL::Const eval_not(RTLIL::Const v) { for (auto &bit : v.bits) if (bit == RTLIL::S0) bit = RTLIL::S1; else if (bit == RTLIL::S1) bit = RTLIL::S0; return v; } static RTLIL::Const eval(RTLIL::IdString type, const RTLIL::Const &arg1, const RTLIL::Const &arg2, bool signed1, bool signed2, int result_len, bool *errp = nullptr) { if (type == "$sshr" && !signed1) type = "$shr"; if (type == "$sshl" && !signed1) type = "$shl"; if (type != "$sshr" && type != "$sshl" && type != "$shr" && type != "$shl" && type != "$shift" && type != "$shiftx" && type != "$pos" && type != "$neg" && type != "$not") { if (!signed1 || !signed2) signed1 = false, signed2 = false; } #define HANDLE_CELL_TYPE(_t) if (type == "$" #_t) return const_ ## _t(arg1, arg2, signed1, signed2, result_len); HANDLE_CELL_TYPE(not) HANDLE_CELL_TYPE(and) HANDLE_CELL_TYPE(or) HANDLE_CELL_TYPE(xor) HANDLE_CELL_TYPE(xnor) HANDLE_CELL_TYPE(reduce_and) HANDLE_CELL_TYPE(reduce_or) HANDLE_CELL_TYPE(reduce_xor) HANDLE_CELL_TYPE(reduce_xnor) HANDLE_CELL_TYPE(reduce_bool) HANDLE_CELL_TYPE(logic_not) HANDLE_CELL_TYPE(logic_and) HANDLE_CELL_TYPE(logic_or) HANDLE_CELL_TYPE(shl) HANDLE_CELL_TYPE(shr) HANDLE_CELL_TYPE(sshl) HANDLE_CELL_TYPE(sshr) HANDLE_CELL_TYPE(shift) HANDLE_CELL_TYPE(shiftx) HANDLE_CELL_TYPE(lt) HANDLE_CELL_TYPE(le) HANDLE_CELL_TYPE(eq) HANDLE_CELL_TYPE(ne) HANDLE_CELL_TYPE(eqx) HANDLE_CELL_TYPE(nex) HANDLE_CELL_TYPE(ge) HANDLE_CELL_TYPE(gt) HANDLE_CELL_TYPE(add) HANDLE_CELL_TYPE(sub) HANDLE_CELL_TYPE(mul) HANDLE_CELL_TYPE(div) HANDLE_CELL_TYPE(mod) HANDLE_CELL_TYPE(pow) HANDLE_CELL_TYPE(pos) HANDLE_CELL_TYPE(neg) #undef HANDLE_CELL_TYPE if (type == "$_BUF_") return arg1; if (type == "$_NOT_") return eval_not(arg1); if (type == "$_AND_") return const_and(arg1, arg2, false, false, 1); if (type == "$_NAND_") return eval_not(const_and(arg1, arg2, false, false, 1)); if (type == "$_OR_") return const_or(arg1, arg2, false, false, 1); if (type == "$_NOR_") return eval_not(const_or(arg1, arg2, false, false, 1)); if (type == "$_XOR_") return const_xor(arg1, arg2, false, false, 1); if (type == "$_XNOR_") return const_xnor(arg1, arg2, false, false, 1); if (type == "$_ANDNOT_") return const_and(arg1, eval_not(arg2), false, false, 1); if (type == "$_ORNOT_") return const_or(arg1, eval_not(arg2), false, false, 1); if (errp != nullptr) { *errp = true; return State::Sm; } log_abort(); } static RTLIL::Const eval(RTLIL::Cell *cell, const RTLIL::Const &arg1, const RTLIL::Const &arg2, bool *errp = nullptr) { if (cell->type == "$slice") { RTLIL::Const ret; int width = cell->parameters.at("\\Y_WIDTH").as_int(); int offset = cell->parameters.at("\\OFFSET").as_int(); ret.bits.insert(ret.bits.end(), arg1.bits.begin()+offset, arg1.bits.begin()+offset+width); return ret; } if (cell->type == "$concat") { RTLIL::Const ret = arg1; ret.bits.insert(ret.bits.end(), arg2.bits.begin(), arg2.bits.end()); return ret; } if (cell->type == "$lut") { int width = cell->parameters.at("\\WIDTH").as_int(); std::vector t = cell->parameters.at("\\LUT").bits; while (GetSize(t) < (1 << width)) t.push_back(RTLIL::S0); t.resize(1 << width); for (int i = width-1; i >= 0; i--) { RTLIL::State sel = arg1.bits.at(i); std::vector new_t; if (sel == RTLIL::S0) new_t = std::vector(t.begin(), t.begin() + GetSize(t)/2); else if (sel == RTLIL::S1) new_t = std::vector(t.begin() + GetSize(t)/2, t.end()); else for (int j = 0; j < GetSize(t)/2; j++) new_t.push_back(t[j] == t[j + GetSize(t)/2] ? t[j] : RTLIL::Sx); t.swap(new_t); } log_assert(GetSize(t) == 1); return t; } if (cell->type == "$sop") { int width = cell->parameters.at("\\WIDTH").as_int(); int depth = cell->parameters.at("\\DEPTH").as_int(); std::vector t = cell->parameters.at("\\TABLE").bits; while (GetSize(t) < width*depth*2) t.push_back(RTLIL::S0); RTLIL::State default_ret = State::S0; for (int i = 0; i < depth; i++) { bool match = true; bool match_x = true; for (int j = 0; j < width; j++) { RTLIL::State a = arg1.bits.at(j); if (t.at(2*width*i + 2*j + 0) == State::S1) { if (a == State::S1) match_x = false; if (a != State::S0) match = false; } if (t.at(2*width*i + 2*j + 1) == State::S1) { if (a == State::S0) match_x = false; if (a != State::S1) match = false; } } if (match) return State::S1; if (match_x) default_ret = State::Sx; } return default_ret; } bool signed_a = cell->parameters.count("\\A_SIGNED") > 0 && cell->parameters["\\A_SIGNED"].as_bool(); bool signed_b = cell->parameters.count("\\B_SIGNED") > 0 && cell->parameters["\\B_SIGNED"].as_bool(); int result_len = cell->parameters.count("\\Y_WIDTH") > 0 ? cell->parameters["\\Y_WIDTH"].as_int() : -1; return eval(cell->type, arg1, arg2, signed_a, signed_b, result_len, errp); } static RTLIL::Const eval(RTLIL::Cell *cell, const RTLIL::Const &arg1, const RTLIL::Const &arg2, const RTLIL::Const &arg3, bool *errp = nullptr) { if (cell->type.in("$mux", "$pmux", "$_MUX_")) { RTLIL::Const ret = arg1; for (size_t i = 0; i < arg3.bits.size(); i++) if (arg3.bits[i] == RTLIL::State::S1) { std::vector bits(arg2.bits.begin() + i*arg1.bits.size(), arg2.bits.begin() + (i+1)*arg1.bits.size()); ret = RTLIL::Const(bits); } return ret; } if (cell->type == "$_AOI3_") return eval_not(const_or(const_and(arg1, arg2, false, false, 1), arg3, false, false, 1)); if (cell->type == "$_OAI3_") return eval_not(const_and(const_or(arg1, arg2, false, false, 1), arg3, false, false, 1)); log_assert(arg3.bits.size() == 0); return eval(cell, arg1, arg2, errp); } static RTLIL::Const eval(RTLIL::Cell *cell, const RTLIL::Const &arg1, const RTLIL::Const &arg2, const RTLIL::Const &arg3, const RTLIL::Const &arg4, bool *errp = nullptr) { if (cell->type == "$_AOI4_") return eval_not(const_or(const_and(arg1, arg2, false, false, 1), const_and(arg3, arg4, false, false, 1), false, false, 1)); if (cell->type == "$_OAI4_") return eval_not(const_and(const_or(arg1, arg2, false, false, 1), const_and(arg3, arg4, false, false, 1), false, false, 1)); log_assert(arg4.bits.size() == 0); return eval(cell, arg1, arg2, arg3, errp); } }; // initialized by yosys_setup() extern CellTypes yosys_celltypes; YOSYS_NAMESPACE_END #endif