yosys/passes/opt/opt_lut.cc

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/*
* yosys -- Yosys Open SYnthesis Suite
*
* Copyright (C) 2018 whitequark <whitequark@whitequark.org>
*
* 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/yosys.h"
#include "kernel/sigtools.h"
#include "kernel/modtools.h"
USING_YOSYS_NAMESPACE
PRIVATE_NAMESPACE_BEGIN
struct OptLutWorker
{
dict<IdString, dict<int, IdString>> &dlogic;
RTLIL::Module *module;
ModIndex index;
SigMap sigmap;
pool<RTLIL::Cell*> luts;
dict<RTLIL::Cell*, int> luts_arity;
dict<RTLIL::Cell*, pool<RTLIL::Cell*>> luts_dlogics;
dict<RTLIL::Cell*, pool<int>> luts_dlogic_inputs;
int eliminated_count = 0, combined_count = 0;
bool evaluate_lut(RTLIL::Cell *lut, dict<SigBit, bool> inputs)
{
SigSpec lut_input = sigmap(lut->getPort("\\A"));
int lut_width = lut->getParam("\\WIDTH").as_int();
Const lut_table = lut->getParam("\\LUT");
int lut_index = 0;
for (int i = 0; i < lut_width; i++)
{
SigBit input = sigmap(lut_input[i]);
if (inputs.count(input))
{
lut_index |= inputs[input] << i;
}
else
{
lut_index |= SigSpec(lut_input[i]).as_bool() << i;
}
}
return lut_table.extract(lut_index).as_bool();
}
void show_stats_by_arity()
{
dict<int, int> arity_counts;
dict<IdString, int> dlogic_counts;
int max_arity = 0;
for (auto lut_arity : luts_arity)
{
max_arity = max(max_arity, lut_arity.second);
arity_counts[lut_arity.second]++;
}
for (auto &lut_dlogics : luts_dlogics)
{
for (auto &lut_dlogic : lut_dlogics.second)
{
dlogic_counts[lut_dlogic->type]++;
}
}
log("Number of LUTs: %8zu\n", luts.size());
for (int arity = 1; arity <= max_arity; arity++)
{
if (arity_counts[arity])
log(" %d-LUT %16d\n", arity, arity_counts[arity]);
}
for (auto &dlogic_count : dlogic_counts)
{
log(" with %-12s %4d\n", dlogic_count.first.c_str(), dlogic_count.second);
}
}
OptLutWorker(dict<IdString, dict<int, IdString>> &dlogic, RTLIL::Module *module, int limit) :
dlogic(dlogic), module(module), index(module), sigmap(module)
{
log("Discovering LUTs.\n");
for (auto cell : module->selected_cells())
{
if (cell->type == "$lut")
{
int lut_width = cell->getParam("\\WIDTH").as_int();
SigSpec lut_input = cell->getPort("\\A");
int lut_arity = 0;
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log_debug("Found $lut\\WIDTH=%d cell %s.%s.\n", lut_width, log_id(module), log_id(cell));
luts.insert(cell);
// First, find all dedicated logic we're connected to. This results in an overapproximation
// of such connections.
pool<RTLIL::Cell*> lut_all_dlogics;
for (int i = 0; i < lut_width; i++)
{
SigBit bit = lut_input[i];
for (auto &port : index.query_ports(bit))
{
if (dlogic.count(port.cell->type))
{
auto &dlogic_map = dlogic[port.cell->type];
if (dlogic_map.count(i))
{
if (port.port == dlogic_map[i])
{
lut_all_dlogics.insert(port.cell);
}
}
}
}
}
// Second, make sure that the connection to dedicated logic is legal. If it is not legal,
// it means one of the two things:
// * The connection is spurious. I.e. this is dedicated logic that will be packed
// with some other LUT, and it just happens to be connected to this LUT as well.
// * The connection is illegal.
// In either of these cases, we don't need to concern ourselves with preserving the connection
// between this LUT and this dedicated logic cell.
pool<RTLIL::Cell*> lut_legal_dlogics;
pool<int> lut_dlogic_inputs;
for (auto lut_dlogic : lut_all_dlogics)
{
auto &dlogic_map = dlogic[lut_dlogic->type];
bool legal = true;
for (auto &dlogic_conn : dlogic_map)
{
if (lut_width <= dlogic_conn.first)
{
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log_debug(" LUT has illegal connection to %s cell %s.%s.\n", lut_dlogic->type.c_str(), log_id(module), log_id(lut_dlogic));
log_debug(" LUT input A[%d] not present.\n", dlogic_conn.first);
legal = false;
break;
}
if (sigmap(lut_input[dlogic_conn.first]) != sigmap(lut_dlogic->getPort(dlogic_conn.second)))
{
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log_debug(" LUT has illegal connection to %s cell %s.%s.\n", lut_dlogic->type.c_str(), log_id(module), log_id(lut_dlogic));
log_debug(" LUT input A[%d] (wire %s) not connected to %s port %s (wire %s).\n", dlogic_conn.first, log_signal(lut_input[dlogic_conn.first]), lut_dlogic->type.c_str(), dlogic_conn.second.c_str(), log_signal(lut_dlogic->getPort(dlogic_conn.second)));
legal = false;
break;
}
}
if (legal)
{
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log_debug(" LUT has legal connection to %s cell %s.%s.\n", lut_dlogic->type.c_str(), log_id(module), log_id(lut_dlogic));
lut_legal_dlogics.insert(lut_dlogic);
for (auto &dlogic_conn : dlogic_map)
lut_dlogic_inputs.insert(dlogic_conn.first);
}
}
// Third, determine LUT arity. An n-wide LUT that has k constant inputs and m inputs shared with dedicated
// logic implements an (n-k-m)-ary function.
for (int i = 0; i < lut_width; i++)
{
SigBit bit = lut_input[i];
if (bit.wire || lut_dlogic_inputs.count(i))
lut_arity++;
}
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log_debug(" Cell implements a %d-LUT.\n", lut_arity);
luts_arity[cell] = lut_arity;
luts_dlogics[cell] = lut_legal_dlogics;
luts_dlogic_inputs[cell] = lut_dlogic_inputs;
}
}
show_stats_by_arity();
log("\n");
log("Eliminating LUTs.\n");
pool<RTLIL::Cell*> worklist = luts;
while (worklist.size())
{
if (limit == 0)
{
log("Limit reached.\n");
break;
}
auto lut = worklist.pop();
SigSpec lut_input = sigmap(lut->getPort("\\A"));
pool<int> &lut_dlogic_inputs = luts_dlogic_inputs[lut];
vector<SigBit> lut_inputs;
for (auto &bit : lut_input)
{
if (bit.wire)
lut_inputs.push_back(sigmap(bit));
}
bool const0_match = true;
bool const1_match = true;
vector<bool> input_matches;
for (size_t i = 0; i < lut_inputs.size(); i++)
input_matches.push_back(true);
for (int eval = 0; eval < 1 << lut_inputs.size(); eval++)
{
dict<SigBit, bool> eval_inputs;
for (size_t i = 0; i < lut_inputs.size(); i++)
eval_inputs[lut_inputs[i]] = (eval >> i) & 1;
bool value = evaluate_lut(lut, eval_inputs);
if (value != 0)
const0_match = false;
if (value != 1)
const1_match = false;
for (size_t i = 0; i < lut_inputs.size(); i++)
{
if (value != eval_inputs[lut_inputs[i]])
input_matches[i] = false;
}
}
int input_match = -1;
for (size_t i = 0; i < lut_inputs.size(); i++)
if (input_matches[i])
input_match = i;
if (const0_match || const1_match || input_match != -1)
{
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log_debug("Found redundant cell %s.%s.\n", log_id(module), log_id(lut));
SigBit value;
if (const0_match)
{
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log_debug(" Cell evaluates constant 0.\n");
value = State::S0;
}
if (const1_match)
{
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log_debug(" Cell evaluates constant 1.\n");
value = State::S1;
}
if (input_match != -1) {
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log_debug(" Cell evaluates signal %s.\n", log_signal(lut_inputs[input_match]));
value = lut_inputs[input_match];
}
if (lut_dlogic_inputs.size())
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log_debug(" Not eliminating cell (connected to dedicated logic).\n");
else
{
SigSpec lut_output = lut->getPort("\\Y");
for (auto &port : index.query_ports(lut_output))
{
if (port.cell != lut && luts.count(port.cell))
worklist.insert(port.cell);
}
module->connect(lut_output, value);
sigmap.add(lut_output, value);
module->remove(lut);
luts.erase(lut);
luts_arity.erase(lut);
luts_dlogics.erase(lut);
luts_dlogic_inputs.erase(lut);
eliminated_count++;
if (limit > 0)
limit--;
}
}
}
show_stats_by_arity();
log("\n");
log("Combining LUTs.\n");
worklist = luts;
while (worklist.size())
{
if (limit == 0)
{
log("Limit reached.\n");
break;
}
auto lutA = worklist.pop();
SigSpec lutA_input = sigmap(lutA->getPort("\\A"));
SigSpec lutA_output = sigmap(lutA->getPort("\\Y")[0]);
int lutA_width = lutA->getParam("\\WIDTH").as_int();
int lutA_arity = luts_arity[lutA];
pool<int> &lutA_dlogic_inputs = luts_dlogic_inputs[lutA];
auto lutA_output_ports = index.query_ports(lutA->getPort("\\Y"));
if (lutA_output_ports.size() != 2)
continue;
for (auto &port : lutA_output_ports)
{
if (port.cell == lutA)
continue;
if (luts.count(port.cell))
{
auto lutB = port.cell;
SigSpec lutB_input = sigmap(lutB->getPort("\\A"));
SigSpec lutB_output = sigmap(lutB->getPort("\\Y")[0]);
int lutB_width = lutB->getParam("\\WIDTH").as_int();
int lutB_arity = luts_arity[lutB];
pool<int> &lutB_dlogic_inputs = luts_dlogic_inputs[lutB];
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log_debug("Found %s.%s (cell A) feeding %s.%s (cell B).\n", log_id(module), log_id(lutA), log_id(module), log_id(lutB));
if (index.query_is_output(lutA->getPort("\\Y")))
{
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log_debug(" Not combining LUTs (cascade connection feeds module output).\n");
continue;
}
pool<SigBit> lutA_inputs;
pool<SigBit> lutB_inputs;
for (auto &bit : lutA_input)
{
if (bit.wire)
lutA_inputs.insert(sigmap(bit));
}
for (auto &bit : lutB_input)
{
if (bit.wire)
lutB_inputs.insert(sigmap(bit));
}
pool<SigBit> common_inputs;
for (auto &bit : lutA_inputs)
{
if (lutB_inputs.count(bit))
common_inputs.insert(bit);
}
int lutM_arity = lutA_arity + lutB_arity - 1 - common_inputs.size();
if (lutA_dlogic_inputs.size())
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log_debug(" Cell A is a %d-LUT with %zu dedicated connections. ", lutA_arity, lutA_dlogic_inputs.size());
else
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log_debug(" Cell A is a %d-LUT. ", lutA_arity);
if (lutB_dlogic_inputs.size())
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log_debug("Cell B is a %d-LUT with %zu dedicated connections.\n", lutB_arity, lutB_dlogic_inputs.size());
else
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log_debug("Cell B is a %d-LUT.\n", lutB_arity);
log_debug(" Cells share %zu input(s) and can be merged into one %d-LUT.\n", common_inputs.size(), lutM_arity);
const int COMBINE_A = 1, COMBINE_B = 2, COMBINE_EITHER = COMBINE_A | COMBINE_B;
int combine_mask = 0;
if (lutM_arity > lutA_width)
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log_debug(" Not combining LUTs into cell A (combined LUT wider than cell A).\n");
else if (lutB_dlogic_inputs.size() > 0)
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log_debug(" Not combining LUTs into cell A (cell B is connected to dedicated logic).\n");
else if (lutB->get_bool_attribute("\\lut_keep"))
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log_debug(" Not combining LUTs into cell A (cell B has attribute \\lut_keep).\n");
else
combine_mask |= COMBINE_A;
if (lutM_arity > lutB_width)
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log_debug(" Not combining LUTs into cell B (combined LUT wider than cell B).\n");
else if (lutA_dlogic_inputs.size() > 0)
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log_debug(" Not combining LUTs into cell B (cell A is connected to dedicated logic).\n");
else if (lutA->get_bool_attribute("\\lut_keep"))
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log_debug(" Not combining LUTs into cell B (cell A has attribute \\lut_keep).\n");
else
combine_mask |= COMBINE_B;
int combine = combine_mask;
if (combine == COMBINE_EITHER)
{
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log_debug(" Can combine into either cell.\n");
if (lutA_arity == 1)
{
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log_debug(" Cell A is a buffer or inverter, combining into cell B.\n");
combine = COMBINE_B;
}
else if (lutB_arity == 1)
{
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log_debug(" Cell B is a buffer or inverter, combining into cell A.\n");
combine = COMBINE_A;
}
else
{
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log_debug(" Arbitrarily combining into cell A.\n");
combine = COMBINE_A;
}
}
RTLIL::Cell *lutM, *lutR;
pool<SigBit> lutM_inputs, lutR_inputs;
pool<int> lutM_dlogic_inputs;
if (combine == COMBINE_A)
{
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log_debug(" Combining LUTs into cell A.\n");
lutM = lutA;
lutM_inputs = lutA_inputs;
lutM_dlogic_inputs = lutA_dlogic_inputs;
lutR = lutB;
lutR_inputs = lutB_inputs;
}
else if (combine == COMBINE_B)
{
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log_debug(" Combining LUTs into cell B.\n");
lutM = lutB;
lutM_inputs = lutB_inputs;
lutM_dlogic_inputs = lutB_dlogic_inputs;
lutR = lutA;
lutR_inputs = lutA_inputs;
}
else
{
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log_debug(" Cannot combine LUTs.\n");
continue;
}
pool<SigBit> lutR_unique;
for (auto &bit : lutR_inputs)
{
if (!common_inputs.count(bit) && bit != lutA_output)
lutR_unique.insert(bit);
}
int lutM_width = lutM->getParam("\\WIDTH").as_int();
SigSpec lutM_input = sigmap(lutM->getPort("\\A"));
std::vector<SigBit> lutM_new_inputs;
for (int i = 0; i < lutM_width; i++)
{
bool input_unused = false;
if (sigmap(lutM_input[i]) == lutA_output)
input_unused = true;
if (!lutM_input[i].wire && !lutM_dlogic_inputs.count(i))
input_unused = true;
if (input_unused && lutR_unique.size())
{
SigBit new_input = lutR_unique.pop();
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log_debug(" Connecting input %d as %s.\n", i, log_signal(new_input));
lutM_new_inputs.push_back(new_input);
}
else if (sigmap(lutM_input[i]) == lutA_output)
{
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log_debug(" Disconnecting cascade input %d.\n", i);
lutM_new_inputs.push_back(SigBit());
}
else
{
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log_debug(" Leaving input %d as %s.\n", i, log_signal(lutM_input[i]));
lutM_new_inputs.push_back(lutM_input[i]);
}
}
log_assert(lutR_unique.size() == 0);
RTLIL::Const lutM_new_table(State::Sx, 1 << lutM_width);
for (int eval = 0; eval < 1 << lutM_width; eval++)
{
dict<SigBit, bool> eval_inputs;
for (size_t i = 0; i < lutM_new_inputs.size(); i++)
{
eval_inputs[lutM_new_inputs[i]] = (eval >> i) & 1;
}
eval_inputs[lutA_output] = evaluate_lut(lutA, eval_inputs);
lutM_new_table[eval] = (RTLIL::State) evaluate_lut(lutB, eval_inputs);
}
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log_debug(" Cell A truth table: %s.\n", lutA->getParam("\\LUT").as_string().c_str());
log_debug(" Cell B truth table: %s.\n", lutB->getParam("\\LUT").as_string().c_str());
log_debug(" Merged truth table: %s.\n", lutM_new_table.as_string().c_str());
lutM->setParam("\\LUT", lutM_new_table);
lutM->setPort("\\A", lutM_new_inputs);
lutM->setPort("\\Y", lutB_output);
luts_arity[lutM] = lutM_arity;
luts.erase(lutR);
luts_arity.erase(lutR);
lutR->module->remove(lutR);
worklist.insert(lutM);
worklist.erase(lutR);
combined_count++;
if (limit > 0)
limit--;
}
}
}
show_stats_by_arity();
}
};
static void split(std::vector<std::string> &tokens, const std::string &text, char sep)
{
size_t start = 0, end = 0;
while ((end = text.find(sep, start)) != std::string::npos) {
tokens.push_back(text.substr(start, end - start));
start = end + 1;
}
tokens.push_back(text.substr(start));
}
struct OptLutPass : public Pass {
OptLutPass() : Pass("opt_lut", "optimize LUT cells") { }
void help() YS_OVERRIDE
{
// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
log("\n");
log(" opt_lut [options] [selection]\n");
log("\n");
log("This pass combines cascaded $lut cells with unused inputs.\n");
log("\n");
log(" -dlogic <type>:<cell-port>=<LUT-input>[:<cell-port>=<LUT-input>...]\n");
log(" preserve connections to dedicated logic cell <type> that has ports\n");
log(" <cell-port> connected to LUT inputs <LUT-input>. this includes\n");
log(" the case where both LUT and dedicated logic input are connected to\n");
log(" the same constant.\n");
log("\n");
log(" -limit N\n");
log(" only perform the first N combines, then stop. useful for debugging.\n");
log("\n");
}
void execute(std::vector<std::string> args, RTLIL::Design *design) YS_OVERRIDE
{
log_header(design, "Executing OPT_LUT pass (optimize LUTs).\n");
dict<IdString, dict<int, IdString>> dlogic;
int limit = -1;
size_t argidx;
for (argidx = 1; argidx < args.size(); argidx++)
{
if (args[argidx] == "-dlogic" && argidx+1 < args.size())
{
std::vector<std::string> tokens;
split(tokens, args[++argidx], ':');
if (tokens.size() < 2)
log_cmd_error("The -dlogic option requires at least one connection.\n");
IdString type = "\\" + tokens[0];
for (auto it = tokens.begin() + 1; it != tokens.end(); ++it) {
std::vector<std::string> conn_tokens;
split(conn_tokens, *it, '=');
if (conn_tokens.size() != 2)
log_cmd_error("Invalid format of -dlogic signal mapping.\n");
IdString logic_port = "\\" + conn_tokens[0];
int lut_input = atoi(conn_tokens[1].c_str());
dlogic[type][lut_input] = logic_port;
}
continue;
}
if (args[argidx] == "-limit" && argidx + 1 < args.size())
{
limit = atoi(args[++argidx].c_str());
continue;
}
break;
}
extra_args(args, argidx, design);
int eliminated_count = 0, combined_count = 0;
for (auto module : design->selected_modules())
{
OptLutWorker worker(dlogic, module, limit - eliminated_count - combined_count);
eliminated_count += worker.eliminated_count;
combined_count += worker.combined_count;
}
if (eliminated_count)
design->scratchpad_set_bool("opt.did_something", true);
if (combined_count)
design->scratchpad_set_bool("opt.did_something", true);
log("\n");
log("Eliminated %d LUTs.\n", eliminated_count);
log("Combined %d LUTs.\n", combined_count);
}
} OptLutPass;
PRIVATE_NAMESPACE_END