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yosys/kernel/celltypes.h
Emil J. Tywoniak c3ffbf6fae WIP
2026-06-12 00:18:53 +02:00

561 lines
19 KiB
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/*
* yosys -- Yosys Open SYnthesis Suite
*
* Copyright (C) 2012 Claire Xenia Wolf <claire@yosyshq.com>
*
* 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"
#include "kernel/newcelltypes.h"
YOSYS_NAMESPACE_BEGIN
struct CellType
{
TwineRef type;
pool<TwineRef> inputs, outputs;
bool is_evaluable;
bool is_combinatorial;
bool is_synthesizable;
};
struct CellTypes
{
dict<TwineRef, CellType> 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_internals_anyinit();
setup_stdcells();
setup_stdcells_mem();
}
void setup_type(TwineRef type, const pool<TwineRef> &inputs, const pool<TwineRef> &outputs, bool is_evaluable = false, bool is_combinatorial = false, bool is_synthesizable = false)
{
CellType ct = {type, inputs, outputs, is_evaluable, is_combinatorial, is_synthesizable};
cell_types[ct.type] = ct;
}
void setup_type(const std::string &type_str, const pool<TwineRef> &inputs, const pool<TwineRef> &outputs, bool is_evaluable = false, bool is_combinatorial = false, bool is_synthesizable = false)
{
setup_type(TW::lookup(type_str), inputs, outputs, is_evaluable, is_combinatorial, is_synthesizable);
}
void setup_module(RTLIL::Module *module)
{
pool<TwineRef> inputs, outputs;
for (auto wire_name : module->ports) {
RTLIL::Wire *wire = module->wire(wire_name);
if (wire->port_input)
inputs.insert(wire->meta_->name);
if (wire->port_output)
outputs.insert(wire->meta_->name);
}
setup_type(module->meta_->name, inputs, outputs);
}
void setup_design(RTLIL::Design *design)
{
for (auto module : design->modules())
setup_module(module);
}
void setup_internals()
{
setup_internals_eval();
setup_type(TW($tribuf), {TW::A, TW::EN}, {TW::Y});
setup_type(TW($assert), {TW::A, TW::EN}, pool<TwineRef>());
setup_type(TW($assume), {TW::A, TW::EN}, pool<TwineRef>());
setup_type(TW($live), {TW::A, TW::EN}, pool<TwineRef>());
setup_type(TW($fair), {TW::A, TW::EN}, pool<TwineRef>());
setup_type(TW($cover), {TW::A, TW::EN}, pool<TwineRef>());
setup_type(TW($initstate), pool<TwineRef>(), {TW::Y});
setup_type(TW($anyconst), pool<TwineRef>(), {TW::Y});
setup_type(TW($anyseq), pool<TwineRef>(), {TW::Y});
setup_type(TW($allconst), pool<TwineRef>(), {TW::Y});
setup_type(TW($allseq), pool<TwineRef>(), {TW::Y});
setup_type(TW($equiv), {TW::A, TW::B}, {TW::Y});
setup_type(TW($specify2), {TW::EN, TW::SRC, TW::DST}, pool<TwineRef>());
setup_type(TW($specify3), {TW::EN, TW::SRC, TW::DST, TW::DAT}, pool<TwineRef>());
setup_type(TW($specrule), {TW::SRC_EN, TW::DST_EN, TW::SRC, TW::DST}, pool<TwineRef>());
setup_type(TW($print), {TW::EN, TW::ARGS, TW::TRG}, pool<TwineRef>());
setup_type(TW($check), {TW::A, TW::EN, TW::ARGS, TW::TRG}, pool<TwineRef>());
setup_type(TW($set_tag), {TW::A, TW::SET, TW::CLR}, {TW::Y});
setup_type(TW($get_tag), {TW::A}, {TW::Y});
setup_type(TW($overwrite_tag), {TW::A, TW::SET, TW::CLR}, pool<TwineRef>());
setup_type(TW($original_tag), {TW::A}, {TW::Y});
setup_type(TW($future_ff), {TW::A}, {TW::Y});
setup_type(TW($scopeinfo), {}, {});
setup_type(TW($input_port), {}, {TW::Y});
setup_type(TW($output_port), {TW::A}, {});
setup_type(TW($public), {TW::A}, {});
setup_type(TW($connect), {TW::A, TW::B}, {});
}
void setup_internals_eval()
{
std::vector<TwineRef> unary_ops = {
TW($not), TW($pos), TW($buf), TW($neg),
TW($reduce_and), TW($reduce_or), TW($reduce_xor), TW($reduce_xnor), TW($reduce_bool),
TW($logic_not), TW($slice), TW($lut), TW($sop)
};
std::vector<TwineRef> binary_ops = {
TW($and), TW($or), TW($xor), TW($xnor),
TW($shl), TW($shr), TW($sshl), TW($sshr), TW($shift), TW($shiftx),
TW($lt), TW($le), TW($eq), TW($ne), TW($eqx), TW($nex), TW($ge), TW($gt),
TW($add), TW($sub), TW($mul), TW($div), TW($mod), TW($divfloor), TW($modfloor), TW($pow),
TW($logic_and), TW($logic_or), TW($concat), TW($macc),
TW($bweqx)
};
for (auto type : unary_ops)
setup_type(type, {TW::A}, {TW::Y}, true);
for (auto type : binary_ops)
setup_type(type, {TW::A, TW::B}, {TW::Y}, true);
for (auto type : std::vector<TwineRef>({TW($mux), TW($pmux), TW($bwmux)}))
setup_type(type, {TW::A, TW::B, TW::S}, {TW::Y}, true);
for (auto type : std::vector<TwineRef>({TW($bmux), TW($demux)}))
setup_type(type, {TW::A, TW::S}, {TW::Y}, true);
setup_type(TW($lcu), {TW::P, TW::G, TW::CI}, {TW::CO}, true);
setup_type(TW($alu), {TW::A, TW::B, TW::CI, TW::BI}, {TW::X, TW::Y, TW::CO}, true);
setup_type(TW($macc_v2), {TW::A, TW::B, TW::C}, {TW::Y}, true);
setup_type(TW($fa), {TW::A, TW::B, TW::C}, {TW::X, TW::Y}, true);
}
void setup_internals_ff()
{
setup_type(TW($sr), {TW::SET, TW::CLR}, {TW::Q});
setup_type(TW($ff), {TW::D}, {TW::Q});
setup_type(TW($dff), {TW::CLK, TW::D}, {TW::Q});
setup_type(TW($dffe), {TW::CLK, TW::EN, TW::D}, {TW::Q});
setup_type(TW($dffsr), {TW::CLK, TW::SET, TW::CLR, TW::D}, {TW::Q});
setup_type(TW($dffsre), {TW::CLK, TW::SET, TW::CLR, TW::D, TW::EN}, {TW::Q});
setup_type(TW($adff), {TW::CLK, TW::ARST, TW::D}, {TW::Q});
setup_type(TW($adffe), {TW::CLK, TW::ARST, TW::D, TW::EN}, {TW::Q});
setup_type(TW($aldff), {TW::CLK, TW::ALOAD, TW::AD, TW::D}, {TW::Q});
setup_type(TW($aldffe), {TW::CLK, TW::ALOAD, TW::AD, TW::D, TW::EN}, {TW::Q});
setup_type(TW($sdff), {TW::CLK, TW::SRST, TW::D}, {TW::Q});
setup_type(TW($sdffe), {TW::CLK, TW::SRST, TW::D, TW::EN}, {TW::Q});
setup_type(TW($sdffce), {TW::CLK, TW::SRST, TW::D, TW::EN}, {TW::Q});
setup_type(TW($dlatch), {TW::EN, TW::D}, {TW::Q});
setup_type(TW($adlatch), {TW::EN, TW::D, TW::ARST}, {TW::Q});
setup_type(TW($dlatchsr), {TW::EN, TW::SET, TW::CLR, TW::D}, {TW::Q});
}
void setup_internals_anyinit()
{
setup_type(TW($anyinit), {TW::D}, {TW::Q});
}
void setup_internals_mem()
{
setup_internals_ff();
setup_type(TW($memrd), {TW::CLK, TW::EN, TW::ADDR}, {TW::DATA});
setup_type(TW($memrd_v2), {TW::CLK, TW::EN, TW::ARST, TW::SRST, TW::ADDR}, {TW::DATA});
setup_type(TW($memwr), {TW::CLK, TW::EN, TW::ADDR, TW::DATA}, pool<TwineRef>());
setup_type(TW($memwr_v2), {TW::CLK, TW::EN, TW::ADDR, TW::DATA}, pool<TwineRef>());
setup_type(TW($meminit), {TW::ADDR, TW::DATA}, pool<TwineRef>());
setup_type(TW($meminit_v2), {TW::ADDR, TW::DATA, TW::EN}, pool<TwineRef>());
setup_type(TW($mem), {TW::RD_CLK, TW::RD_EN, TW::RD_ADDR, TW::WR_CLK, TW::WR_EN, TW::WR_ADDR, TW::WR_DATA}, {TW::RD_DATA});
setup_type(TW($mem_v2), {TW::RD_CLK, TW::RD_EN, TW::RD_ARST, TW::RD_SRST, TW::RD_ADDR, TW::WR_CLK, TW::WR_EN, TW::WR_ADDR, TW::WR_DATA}, {TW::RD_DATA});
setup_type(TW($fsm), {TW::CLK, TW::ARST, TW::CTRL_IN}, {TW::CTRL_OUT});
}
void setup_stdcells()
{
setup_stdcells_eval();
setup_type(TW($_TBUF_), {TW::A, TW::E}, {TW::Y});
}
void setup_stdcells_eval()
{
setup_type(TW($_BUF_), {TW::A}, {TW::Y}, true);
setup_type(TW($_NOT_), {TW::A}, {TW::Y}, true);
setup_type(TW($_AND_), {TW::A, TW::B}, {TW::Y}, true);
setup_type(TW($_NAND_), {TW::A, TW::B}, {TW::Y}, true);
setup_type(TW($_OR_), {TW::A, TW::B}, {TW::Y}, true);
setup_type(TW($_NOR_), {TW::A, TW::B}, {TW::Y}, true);
setup_type(TW($_XOR_), {TW::A, TW::B}, {TW::Y}, true);
setup_type(TW($_XNOR_), {TW::A, TW::B}, {TW::Y}, true);
setup_type(TW($_ANDNOT_), {TW::A, TW::B}, {TW::Y}, true);
setup_type(TW($_ORNOT_), {TW::A, TW::B}, {TW::Y}, true);
setup_type(TW($_MUX_), {TW::A, TW::B, TW::S}, {TW::Y}, true);
setup_type(TW($_NMUX_), {TW::A, TW::B, TW::S}, {TW::Y}, true);
setup_type(TW($_MUX4_), {TW::A, TW::B, TW::C, TW::D, TW::S, TW::T}, {TW::Y}, true);
setup_type(TW($_MUX8_), {TW::A, TW::B, TW::C, TW::D, TW::E, TW::F, TW::G, TW::H, TW::S, TW::T, TW::U}, {TW::Y}, true);
setup_type(TW($_MUX16_), {TW::A, TW::B, TW::C, TW::D, TW::E, TW::F, TW::G, TW::H, TW::I, TW::J, TW::K, TW::L, TW::M, TW::N, TW::O, TW::P, TW::S, TW::T, TW::U, TW::V}, {TW::Y}, true);
setup_type(TW($_AOI3_), {TW::A, TW::B, TW::C}, {TW::Y}, true);
setup_type(TW($_OAI3_), {TW::A, TW::B, TW::C}, {TW::Y}, true);
setup_type(TW($_AOI4_), {TW::A, TW::B, TW::C, TW::D}, {TW::Y}, true);
setup_type(TW($_OAI4_), {TW::A, TW::B, TW::C, TW::D}, {TW::Y}, true);
}
void setup_stdcells_mem()
{
std::vector<char> list_np = {'N', 'P'}, list_01 = {'0', '1'};
for (auto c1 : list_np)
for (auto c2 : list_np)
setup_type(stringf("$_SR_%c%c_", c1, c2), {TW::S, TW::R}, {TW::Q});
setup_type(TW($_FF_), {TW::D}, {TW::Q});
for (auto c1 : list_np)
setup_type(stringf("$_DFF_%c_", c1), {TW::C, TW::D}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
setup_type(stringf("$_DFFE_%c%c_", c1, c2), {TW::C, TW::D, TW::E}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_01)
setup_type(stringf("$_DFF_%c%c%c_", c1, c2, c3), {TW::C, TW::R, TW::D}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_01)
for (auto c4 : list_np)
setup_type(stringf("$_DFFE_%c%c%c%c_", c1, c2, c3, c4), {TW::C, TW::R, TW::D, TW::E}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
setup_type(stringf("$_ALDFF_%c%c_", c1, c2), {TW::C, TW::L, TW::AD, TW::D}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_np)
setup_type(stringf("$_ALDFFE_%c%c%c_", c1, c2, c3), {TW::C, TW::L, TW::AD, TW::D, TW::E}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_np)
setup_type(stringf("$_DFFSR_%c%c%c_", c1, c2, c3), {TW::C, TW::S, TW::R, TW::D}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_np)
for (auto c4 : list_np)
setup_type(stringf("$_DFFSRE_%c%c%c%c_", c1, c2, c3, c4), {TW::C, TW::S, TW::R, TW::D, TW::E}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_01)
setup_type(stringf("$_SDFF_%c%c%c_", c1, c2, c3), {TW::C, TW::R, TW::D}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_01)
for (auto c4 : list_np)
setup_type(stringf("$_SDFFE_%c%c%c%c_", c1, c2, c3, c4), {TW::C, TW::R, TW::D, TW::E}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_01)
for (auto c4 : list_np)
setup_type(stringf("$_SDFFCE_%c%c%c%c_", c1, c2, c3, c4), {TW::C, TW::R, TW::D, TW::E}, {TW::Q});
for (auto c1 : list_np)
setup_type(stringf("$_DLATCH_%c_", c1), {TW::E, TW::D}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_01)
setup_type(stringf("$_DLATCH_%c%c%c_", c1, c2, c3), {TW::E, TW::R, TW::D}, {TW::Q});
for (auto c1 : list_np)
for (auto c2 : list_np)
for (auto c3 : list_np)
setup_type(stringf("$_DLATCHSR_%c%c%c_", c1, c2, c3), {TW::E, TW::S, TW::R, TW::D}, {TW::Q});
}
void clear()
{
cell_types.clear();
}
bool cell_known(TwineRef type) const
{
return cell_types.count(type) != 0;
}
bool cell_output(TwineRef type, TwineRef port) const
{
auto it = cell_types.find(type);
return it != cell_types.end() && it->second.outputs.count(port) != 0;
}
bool cell_input(TwineRef type, TwineRef port) const
{
auto it = cell_types.find(type);
return it != cell_types.end() && it->second.inputs.count(port) != 0;
}
RTLIL::PortDir cell_port_dir(TwineRef type, TwineRef port) const
{
auto it = cell_types.find(type);
if (it == cell_types.end())
return RTLIL::PD_UNKNOWN;
bool is_input = it->second.inputs.count(port);
bool is_output = it->second.outputs.count(port);
return RTLIL::PortDir(is_input + is_output * 2);
}
bool cell_evaluable(TwineRef type) const
{
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)
if (bit == State::S0) bit = State::S1;
else if (bit == State::S1) bit = State::S0;
return v;
}
// Consider using the ConstEval struct instead if you need named ports and/or multiple outputs
static RTLIL::Const eval(TwineRef type, const RTLIL::Const &arg1, const RTLIL::Const &arg2, bool signed1, bool signed2, int result_len, bool *errp = nullptr)
{
if (type == TW($sshr) && !signed1)
type = TW($shr);
if (type == TW($sshl) && !signed1)
type = TW($shl);
if (type != TW($sshr) && type != TW($sshl) && type != TW($shr) && type != TW($shl) && type != TW($shift) && type != TW($shiftx) &&
type != TW($pos) && type != TW($buf) && type != TW($neg) && type != TW($not)) {
if (!signed1 || !signed2)
signed1 = false, signed2 = false;
}
#define HANDLE_CELL_TYPE(_t) if (type == TW($##_t)) return const_ ## _t(arg1, arg2, signed1, signed2, result_len);
HANDLE_CELL_TYPE(not)
HANDLE_CELL_TYPE(and)
HANDLE_CELL_TYPE(or)
HANDLE_CELL_TYPE(xor)
HANDLE_CELL_TYPE(xnor)
HANDLE_CELL_TYPE(reduce_and)
HANDLE_CELL_TYPE(reduce_or)
HANDLE_CELL_TYPE(reduce_xor)
HANDLE_CELL_TYPE(reduce_xnor)
HANDLE_CELL_TYPE(reduce_bool)
HANDLE_CELL_TYPE(logic_not)
HANDLE_CELL_TYPE(logic_and)
HANDLE_CELL_TYPE(logic_or)
HANDLE_CELL_TYPE(shl)
HANDLE_CELL_TYPE(shr)
HANDLE_CELL_TYPE(sshl)
HANDLE_CELL_TYPE(sshr)
HANDLE_CELL_TYPE(shift)
HANDLE_CELL_TYPE(shiftx)
HANDLE_CELL_TYPE(lt)
HANDLE_CELL_TYPE(le)
HANDLE_CELL_TYPE(eq)
HANDLE_CELL_TYPE(ne)
HANDLE_CELL_TYPE(eqx)
HANDLE_CELL_TYPE(nex)
HANDLE_CELL_TYPE(ge)
HANDLE_CELL_TYPE(gt)
HANDLE_CELL_TYPE(add)
HANDLE_CELL_TYPE(sub)
HANDLE_CELL_TYPE(mul)
HANDLE_CELL_TYPE(div)
HANDLE_CELL_TYPE(mod)
HANDLE_CELL_TYPE(divfloor)
HANDLE_CELL_TYPE(modfloor)
HANDLE_CELL_TYPE(pow)
HANDLE_CELL_TYPE(pos)
HANDLE_CELL_TYPE(neg)
#undef HANDLE_CELL_TYPE
if (type.in(TW($_BUF_), TW($buf)))
return arg1;
if (type == TW($_NOT_))
return eval_not(arg1);
if (type == TW($_AND_))
return const_and(arg1, arg2, false, false, 1);
if (type == TW($_NAND_))
return eval_not(const_and(arg1, arg2, false, false, 1));
if (type == TW($_OR_))
return const_or(arg1, arg2, false, false, 1);
if (type == TW($_NOR_))
return eval_not(const_or(arg1, arg2, false, false, 1));
if (type == TW($_XOR_))
return const_xor(arg1, arg2, false, false, 1);
if (type == TW($_XNOR_))
return const_xnor(arg1, arg2, false, false, 1);
if (type == TW($_ANDNOT_))
return const_and(arg1, eval_not(arg2), false, false, 1);
if (type == TW($_ORNOT_))
return const_or(arg1, eval_not(arg2), false, false, 1);
if (errp != nullptr) {
*errp = true;
return State::Sm;
}
log_abort();
}
// Consider using the ConstEval struct instead if you need named ports and/or multiple outputs
static RTLIL::Const eval(RTLIL::Cell *cell, const RTLIL::Const &arg1, const RTLIL::Const &arg2, bool *errp = nullptr)
{
if (cell->type == TW($slice)) {
int width = cell->parameters.at(ID::Y_WIDTH).as_int();
int offset = cell->parameters.at(ID::OFFSET).as_int();
return arg1.extract(offset, width);
}
if (cell->type == TW($concat)) {
RTLIL::Const ret = arg1;
ret.append(arg2);
return ret;
}
if (cell->type == TW($bmux))
{
return const_bmux(arg1, arg2);
}
if (cell->type == TW($demux))
{
return const_demux(arg1, arg2);
}
if (cell->type == TW($bweqx))
{
return const_bweqx(arg1, arg2);
}
if (cell->type == TW($lut))
{
int width = cell->parameters.at(ID::WIDTH).as_int();
std::vector<RTLIL::State> t = cell->parameters.at(ID::LUT).to_bits();
while (GetSize(t) < (1 << width))
t.push_back(State::S0);
t.resize(1 << width);
return const_bmux(t, arg1);
}
if (cell->type == TW($sop))
{
int width = cell->parameters.at(ID::WIDTH).as_int();
int depth = cell->parameters.at(ID::DEPTH).as_int();
std::vector<RTLIL::State> t = cell->parameters.at(ID::TABLE).to_bits();
while (GetSize(t) < width*depth*2)
t.push_back(State::S0);
RTLIL::State default_ret = State::S0;
for (int i = 0; i < depth; i++)
{
bool match = true;
bool match_x = true;
for (int j = 0; j < width; j++) {
RTLIL::State a = arg1.at(j);
if (t.at(2*width*i + 2*j + 0) == State::S1) {
if (a == State::S1) match_x = false;
if (a != State::S0) match = false;
}
if (t.at(2*width*i + 2*j + 1) == State::S1) {
if (a == State::S0) match_x = false;
if (a != State::S1) match = false;
}
}
if (match)
return State::S1;
if (match_x)
default_ret = State::Sx;
}
return default_ret;
}
bool signed_a = cell->parameters.count(ID::A_SIGNED) > 0 && cell->parameters[ID::A_SIGNED].as_bool();
bool signed_b = cell->parameters.count(ID::B_SIGNED) > 0 && cell->parameters[ID::B_SIGNED].as_bool();
int result_len = cell->parameters.count(ID::Y_WIDTH) > 0 ? cell->parameters[ID::Y_WIDTH].as_int() : -1;
return eval(cell->type_impl, arg1, arg2, signed_a, signed_b, result_len, errp);
}
// Consider using the ConstEval struct instead if you need named ports and/or multiple outputs
static RTLIL::Const eval(RTLIL::Cell *cell, const RTLIL::Const &arg1, const RTLIL::Const &arg2, const RTLIL::Const &arg3, bool *errp = nullptr)
{
if (cell->type.in(TW($mux), TW($_MUX_)))
return const_mux(arg1, arg2, arg3);
if (cell->type == TW($_NMUX_))
return eval_not(const_mux(arg1, arg2, arg3));
if (cell->type == TW($bwmux))
return const_bwmux(arg1, arg2, arg3);
if (cell->type == TW($pmux))
return const_pmux(arg1, arg2, arg3);
if (cell->type == TW($_AOI3_))
return eval_not(const_or(const_and(arg1, arg2, false, false, 1), arg3, false, false, 1));
if (cell->type == TW($_OAI3_))
return eval_not(const_and(const_or(arg1, arg2, false, false, 1), arg3, false, false, 1));
log_assert(arg3.size() == 0);
return eval(cell, arg1, arg2, errp);
}
// Consider using the ConstEval struct instead if you need named ports and/or multiple outputs
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 == TW($_AOI4_))
return eval_not(const_or(const_and(arg1, arg2, false, false, 1), const_and(arg3, arg4, false, false, 1), false, false, 1));
if (cell->type == TW($_OAI4_))
return eval_not(const_and(const_or(arg1, arg2, false, false, 1), const_or(arg3, arg4, false, false, 1), false, false, 1));
log_assert(arg4.size() == 0);
return eval(cell, arg1, arg2, arg3, errp);
}
};
YOSYS_NAMESPACE_END
#endif