USING_YOSYS_NAMESPACE
PRIVATE_NAMESPACE_BEGIN
+struct ShregmapTech
+{
+ virtual ~ShregmapTech() { }
+ virtual void init(const Module * /*module*/, const SigMap &/*sigmap*/) {}
+ virtual void non_chain_user(const SigBit &/*bit*/, const Cell* /*cell*/, IdString /*port*/) {}
+ virtual bool analyze_first(const Cell* /*first_cell*/, const SigMap &/*sigmap*/) { return true; }
+ virtual bool analyze(vector<int> &taps, const vector<SigBit> &qbits) = 0;
+ virtual Cell* fixup(Cell *cell, const vector<int> &taps, const vector<SigBit> &qbits) = 0;
+};
+
struct ShregmapOptions
{
int minlen, maxlen;
int keep_before, keep_after;
+ bool zinit, init, params, ffe;
dict<IdString, pair<IdString, IdString>> ffcells;
+ ShregmapTech *tech;
ShregmapOptions()
{
maxlen = 0;
keep_before = 0;
keep_after = 0;
+ zinit = false;
+ init = false;
+ params = false;
+ ffe = false;
+ tech = nullptr;
+ }
+};
+
+struct ShregmapTechGreenpak4 : ShregmapTech
+{
+ virtual bool analyze(vector<int> &taps, const vector<SigBit> &/*qbits*/) override
+ {
+ if (GetSize(taps) > 2 && taps[0] == 0 && taps[2] < 17) {
+ taps.clear();
+ return true;
+ }
+
+ if (GetSize(taps) > 2)
+ return false;
+
+ if (taps.back() > 16) return false;
+
+ return true;
+ }
+
+ virtual Cell* fixup(Cell *cell, const vector<int> &taps, const vector<SigBit> &qbits) override
+ {
+ auto D = cell->getPort("\\D");
+ auto C = cell->getPort("\\C");
+
+ auto newcell = cell->module->addCell(NEW_ID, "\\GP_SHREG");
+ newcell->setPort("\\nRST", State::S1);
+ newcell->setPort("\\CLK", C);
+ newcell->setPort("\\IN", D);
+
+ int i = 0;
+ for (auto tap : taps) {
+ newcell->setPort(i ? "\\OUTB" : "\\OUTA", qbits[tap]);
+ newcell->setParam(i ? "\\OUTB_TAP" : "\\OUTA_TAP", tap + 1);
+ i++;
+ }
+
+ cell->setParam("\\OUTA_INVERT", 0);
+ return newcell;
+ }
+};
+
+struct ShregmapTechXilinx7Static : ShregmapTech
+{
+ dict<SigBit, Cell*> sigbit_to_cell;
+ const ShregmapOptions &opts;
+
+ virtual void init(const Module* module, const SigMap &sigmap) override
+ {
+ for (const auto &i : module->cells_) {
+ auto cell = i.second;
+ if (!cell->type.in("\\FDRE", "\\FDRE_1","\\FDSE", "\\FDSE_1",
+ "\\FDCE", "\\FDCE_1", "\\FDPE", "\\FDPE_1"))
+ continue;
+
+ sigbit_to_cell[sigmap(cell->getPort("\\Q"))] = cell;
+ }
+ }
+
+ ShregmapTechXilinx7Static(const ShregmapOptions &opts) : opts(opts) {}
+
+ virtual bool analyze_first(const Cell* first_cell, const SigMap &sigmap) override
+ {
+ if (first_cell->type.in("\\FDRE", "\\FDRE_1")) {
+ bool is_R_inverted = false;
+ if (first_cell->hasParam("\\IS_R_INVERTED"))
+ is_R_inverted = first_cell->getParam("\\IS_R_INVERTED").as_bool();
+ SigBit R = sigmap(first_cell->getPort("\\R"));
+ if (R != RTLIL::S0 && R != RTLIL::S1)
+ return false;
+ if ((!is_R_inverted && R != RTLIL::S0) || (is_R_inverted && R != RTLIL::S1))
+ return false;
+ return true;
+ }
+ if (first_cell->type.in("\\FDSE", "\\FDSE_1")) {
+ bool is_S_inverted = false;
+ if (first_cell->hasParam("\\IS_S_INVERTED"))
+ is_S_inverted = first_cell->getParam("\\IS_S_INVERTED").as_bool();
+ SigBit S = sigmap(first_cell->getPort("\\S"));
+ if (S != RTLIL::S0 && S != RTLIL::S1)
+ return false;
+ if ((!is_S_inverted && S != RTLIL::S0) || (is_S_inverted && S != RTLIL::S1))
+ return false;
+ return true;
+ }
+ if (first_cell->type.in("\\FDCE", "\\FDCE_1")) {
+ bool is_CLR_inverted = false;
+ if (first_cell->hasParam("\\IS_CLR_INVERTED"))
+ is_CLR_inverted = first_cell->getParam("\\IS_CLR_INVERTED").as_bool();
+ SigBit CLR = sigmap(first_cell->getPort("\\CLR"));
+ if (CLR != RTLIL::S0 && CLR != RTLIL::S1)
+ return false;
+ if ((!is_CLR_inverted && CLR != RTLIL::S0) || (is_CLR_inverted && CLR != RTLIL::S1))
+ return false;
+ return true;
+ }
+ if (first_cell->type.in("\\FDPE", "\\FDPE_1")) {
+ bool is_PRE_inverted = false;
+ if (first_cell->hasParam("\\IS_PRE_INVERTED"))
+ is_PRE_inverted = first_cell->getParam("\\IS_PRE_INVERTED").as_bool();
+ SigBit PRE = sigmap(first_cell->getPort("\\PRE"));
+ if (PRE != RTLIL::S0 && PRE != RTLIL::S1)
+ return false;
+ if ((!is_PRE_inverted && PRE != RTLIL::S0) || (is_PRE_inverted && PRE != RTLIL::S1))
+ return false;
+ return true;
+ }
+ return true;
+ }
+
+ virtual bool analyze(vector<int> &taps, const vector<SigBit> &/*qbits*/) override
+ {
+ return GetSize(taps) == 1 && taps[0] >= opts.minlen-1;
+ }
+
+ virtual Cell* fixup(Cell *cell, const vector<int> &/*taps*/, const vector<SigBit> &qbits) override
+ {
+ auto newcell = cell->module->addCell(NEW_ID, "$__SHREG_");
+ newcell->set_src_attribute(cell->get_src_attribute());
+ newcell->setParam("\\DEPTH", cell->getParam("\\DEPTH"));
+
+ if (cell->type.in("$__SHREG_DFF_N_", "$__SHREG_DFF_P_",
+ "$__SHREG_DFFE_NN_", "$__SHREG_DFFE_NP_", "$__SHREG_DFFE_PN_", "$__SHREG_DFFE_PP_")) {
+ int param_clkpol = -1;
+ int param_enpol = 2;
+ if (cell->type == "$__SHREG_DFF_N_") param_clkpol = 0;
+ else if (cell->type == "$__SHREG_DFF_P_") param_clkpol = 1;
+ else if (cell->type == "$__SHREG_DFFE_NN_") param_clkpol = 0, param_enpol = 0;
+ else if (cell->type == "$__SHREG_DFFE_NP_") param_clkpol = 0, param_enpol = 1;
+ else if (cell->type == "$__SHREG_DFFE_PN_") param_clkpol = 1, param_enpol = 0;
+ else if (cell->type == "$__SHREG_DFFE_PP_") param_clkpol = 1, param_enpol = 1;
+ else log_abort();
+
+ log_assert(param_clkpol >= 0);
+ newcell->setParam("\\CLKPOL", param_clkpol);
+ newcell->setParam("\\ENPOL", param_enpol);
+ newcell->setParam("\\INIT", cell->getParam("\\INIT"));
+
+ if (cell->hasPort("\\E"))
+ newcell->setPort("\\E", cell->getPort("\\E"));
+ }
+ else if (cell->type.in("$__SHREG_FDRE", "$__SHREG_FDRE_1","$__SHREG_FDSE", "$__SHREG_FDSE_1",
+ "$__SHREG_FDCE", "$__SHREG_FDCE_1", "$__SHREG_FDPE", "$__SHREG_FDPE_1")) {
+ int param_clkpol = 1;
+ if (cell->hasParam("\\IS_C_INVERTED") && cell->getParam("\\IS_C_INVERTED").as_bool())
+ param_clkpol = 0;
+ newcell->setParam("\\CLKPOL", param_clkpol);
+ newcell->setParam("\\ENPOL", 1);
+ log_assert(cell->getParam("\\INIT").is_fully_undef());
+ SigSpec INIT;
+ for (auto q : qbits) {
+ Cell* reg = sigbit_to_cell.at(q);
+ INIT.append(SigBit(reg->getParam("\\INIT").as_bool()));
+ }
+
+ newcell->setPort("\\E", cell->getPort("\\CE"));
+ }
+ else log_abort();
+
+ newcell->setParam("\\ENPOL", 1);
+
+ newcell->setPort("\\C", cell->getPort("\\C"));
+ newcell->setPort("\\D", cell->getPort("\\D"));
+ newcell->setPort("\\Q", cell->getPort("\\Q"));
+
+ return newcell;
+ }
+};
+
+struct ShregmapTechXilinx7Dynamic : ShregmapTechXilinx7Static
+{
+ dict<SigBit, std::tuple<Cell*,int,int>> sigbit_to_shiftx_offset;
+
+ ShregmapTechXilinx7Dynamic(const ShregmapOptions &opts) : ShregmapTechXilinx7Static(opts) {}
+
+ virtual void init(const Module* module, const SigMap &sigmap) override
+ {
+ for (const auto &i : module->cells_) {
+ auto cell = i.second;
+ if (cell->type == "$shiftx") {
+ if (cell->getParam("\\Y_WIDTH") != 1) continue;
+ int j = 0;
+ for (auto bit : sigmap(cell->getPort("\\A")))
+ sigbit_to_shiftx_offset[bit] = std::make_tuple(cell, j++, 0);
+ log_assert(j == cell->getParam("\\A_WIDTH").as_int());
+ }
+ else if (cell->type == "$mux") {
+ int j = 0;
+ for (auto bit : sigmap(cell->getPort("\\A")))
+ sigbit_to_shiftx_offset[bit] = std::make_tuple(cell, 0, j++);
+ j = 0;
+ for (auto bit : sigmap(cell->getPort("\\B")))
+ sigbit_to_shiftx_offset[bit] = std::make_tuple(cell, 1, j++);
+ }
+ }
+ }
+
+ virtual void non_chain_user(const SigBit &bit, const Cell *cell, IdString port) override
+ {
+ auto it = sigbit_to_shiftx_offset.find(bit);
+ if (it == sigbit_to_shiftx_offset.end())
+ return;
+ if (cell) {
+ if (cell->type == "$shiftx" && port == "\\A")
+ return;
+ if (cell->type == "$mux" && (port == "\\A" || port == "\\B"))
+ return;
+ }
+ sigbit_to_shiftx_offset.erase(it);
+ }
+
+ virtual bool analyze(vector<int> &taps, const vector<SigBit> &qbits) override
+ {
+ if (GetSize(taps) == 1)
+ return taps[0] >= opts.minlen-1 && sigbit_to_shiftx_offset.count(qbits[0]);
+
+ if (taps.back() < opts.minlen-1)
+ return false;
+
+ Cell *shiftx = nullptr;
+ int group = 0;
+ for (int i = 0; i < GetSize(taps); ++i) {
+ // Check taps are sequential
+ if (i != taps[i])
+ return false;
+
+ auto it = sigbit_to_shiftx_offset.find(qbits[i]);
+ if (it == sigbit_to_shiftx_offset.end())
+ return false;
+
+ // Check taps are not connected to a shift register,
+ // or sequential to the same shift register
+ if (i == 0) {
+ int offset;
+ std::tie(shiftx,offset,group) = it->second;
+ if (offset != i)
+ return false;
+ }
+ else {
+ Cell *shiftx_ = std::get<0>(it->second);
+ if (shiftx_ != shiftx)
+ return false;
+ int offset = std::get<1>(it->second);
+ if (offset != i)
+ return false;
+ int group_ = std::get<2>(it->second);
+ if (group_ != group)
+ return false;
+ }
+ }
+ log_assert(shiftx);
+
+ // Only map if $shiftx exclusively covers the shift register
+ if (shiftx->type == "$shiftx") {
+ if (GetSize(taps) > shiftx->getParam("\\A_WIDTH").as_int())
+ return false;
+ // Due to padding the most significant bits of A may be 1'bx,
+ // and if so, discount them
+ if (GetSize(taps) < shiftx->getParam("\\A_WIDTH").as_int()) {
+ const SigSpec A = shiftx->getPort("\\A");
+ const int A_width = shiftx->getParam("\\A_WIDTH").as_int();
+ for (int i = GetSize(taps); i < A_width; ++i)
+ if (A[i] != RTLIL::Sx) return false;
+ }
+ else if (GetSize(taps) != shiftx->getParam("\\A_WIDTH").as_int())
+ return false;
+ }
+ else if (shiftx->type == "$mux") {
+ if (GetSize(taps) != 2)
+ return false;
+ }
+ else log_abort();
+
+ return true;
+ }
+
+ virtual Cell* fixup(Cell *cell, const vector<int> &taps, const vector<SigBit> &qbits) override
+ {
+ auto bit = qbits[taps.front()];
+
+ auto it = sigbit_to_shiftx_offset.find(bit);
+ log_assert(it != sigbit_to_shiftx_offset.end());
+
+ Cell* newcell = ShregmapTechXilinx7Static::fixup(cell, taps, qbits);
+ log_assert(newcell);
+ log_assert(newcell->type == "$__SHREG_");
+ newcell->type = "$__XILINX_SHREG_";
+
+ Cell* shiftx = std::get<0>(it->second);
+ RTLIL::SigSpec l_wire;
+ if (shiftx->type == "$shiftx")
+ l_wire = shiftx->getPort("\\B");
+ else if (shiftx->type == "$mux")
+ l_wire = shiftx->getPort("\\S");
+ else log_abort();
+
+ newcell->setPort("\\L", l_wire);
+ newcell->setPort("\\Q", shiftx->getPort("\\Y"));
+ shiftx->setPort("\\Y", cell->module->addWire(NEW_ID));
+
+ return newcell;
}
};
+
struct ShregmapWorker
{
Module *module;
const ShregmapOptions &opts;
int dff_count, shreg_count;
+
pool<Cell*> remove_cells;
+ pool<SigBit> remove_init;
dict<SigBit, bool> sigbit_init;
dict<SigBit, Cell*> sigbit_chain_next;
{
for (auto wire : module->wires())
{
- if (wire->port_output) {
- for (auto bit : sigmap(wire))
+ if (wire->port_output || wire->get_bool_attribute("\\keep")) {
+ for (auto bit : sigmap(wire)) {
sigbit_with_non_chain_users.insert(bit);
+ if (opts.tech) opts.tech->non_chain_user(bit, nullptr, {});
+ }
}
if (wire->attributes.count("\\init")) {
SigSpec initsig = sigmap(wire);
Const initval = wire->attributes.at("\\init");
for (int i = 0; i < GetSize(initsig) && i < GetSize(initval); i++)
- if (initval[i] == State::S0)
+ if (initval[i] == State::S0 && !opts.zinit)
sigbit_init[initsig[i]] = false;
else if (initval[i] == State::S1)
sigbit_init[initsig[i]] = true;
for (auto cell : module->cells())
{
- if (opts.ffcells.count(cell->type))
+ if (opts.ffcells.count(cell->type) && !cell->get_bool_attribute("\\keep"))
{
IdString d_port = opts.ffcells.at(cell->type).first;
IdString q_port = opts.ffcells.at(cell->type).second;
SigBit d_bit = sigmap(cell->getPort(d_port).as_bit());
SigBit q_bit = sigmap(cell->getPort(q_port).as_bit());
- if (sigbit_init.count(q_bit) == 0) {
+ if (opts.init || sigbit_init.count(q_bit) == 0)
+ {
if (sigbit_chain_next.count(d_bit)) {
sigbit_with_non_chain_users.insert(d_bit);
} else
for (auto conn : cell->connections())
if (cell->input(conn.first))
- for (auto bit : sigmap(conn.second))
+ for (auto bit : sigmap(conn.second)) {
sigbit_with_non_chain_users.insert(bit);
+ if (opts.tech) opts.tech->non_chain_user(bit, cell, conn.first);
+ }
}
}
{
for (auto it : sigbit_chain_next)
{
- if (sigbit_with_non_chain_users.count(it.first))
- continue;
+ if (opts.tech == nullptr && sigbit_with_non_chain_users.count(it.first))
+ goto start_cell;
if (sigbit_chain_prev.count(it.first) != 0)
{
if (opts.maxlen > 0)
depth = std::min(opts.maxlen, depth);
- Cell *first_cell = chain[cursor], *last_cell = chain[cursor+depth-1];
+ Cell *first_cell = chain[cursor];
+ IdString q_port = opts.ffcells.at(first_cell->type).second;
+ vector<SigBit> qbits;
+ vector<int> taps;
- if (depth < 2)
- return;
+ if (opts.tech)
+ {
+ if (!opts.tech->analyze_first(first_cell, sigmap)) {
+ cursor += depth;
+ continue;
+ }
+
+ for (int i = 0; i < depth; i++)
+ {
+ Cell *cell = chain[cursor+i];
+ auto qbit = sigmap(cell->getPort(q_port));
+ qbits.push_back(qbit);
+
+ if (sigbit_with_non_chain_users.count(qbit))
+ taps.push_back(i);
+ }
+
+ while (depth > 0)
+ {
+ if (taps.empty() || taps.back() < depth-1)
+ taps.push_back(depth-1);
+
+ if (opts.tech->analyze(taps, qbits))
+ break;
+
+ taps.pop_back();
+ depth--;
+ }
+
+ depth = 0;
+ for (auto tap : taps) {
+ log_assert(depth < tap+1);
+ depth = tap+1;
+ }
+ }
+
+ if (depth < 2) {
+ cursor++;
+ continue;
+ }
+
+ Cell *last_cell = chain[cursor+depth-1];
log("Converting %s.%s ... %s.%s to a shift register with depth %d.\n",
log_id(module), log_id(first_cell), log_id(module), log_id(last_cell), depth);
shreg_count += 1;
string shreg_cell_type_str = "$__SHREG";
- if (first_cell->type[1] != '_')
+ if (opts.params) {
shreg_cell_type_str += "_";
- shreg_cell_type_str += first_cell->type.substr(1);
+ } else {
+ if (first_cell->type[1] != '_')
+ shreg_cell_type_str += "_";
+ shreg_cell_type_str += first_cell->type.substr(1);
+ }
+
+ if (opts.init) {
+ vector<State> initval;
+ for (int i = depth-1; i >= 0; i--) {
+ SigBit bit = sigmap(chain[cursor+i]->getPort(q_port).as_bit());
+ if (sigbit_init.count(bit) == 0)
+ initval.push_back(State::Sx);
+ else if (sigbit_init.at(bit))
+ initval.push_back(State::S1);
+ else
+ initval.push_back(State::S0);
+ remove_init.insert(bit);
+ }
+ first_cell->setParam("\\INIT", initval);
+ }
+
+ if (opts.zinit)
+ for (int i = depth-1; i >= 0; i--) {
+ SigBit bit = sigmap(chain[cursor+i]->getPort(q_port).as_bit());
+ remove_init.insert(bit);
+ }
+
+ if (opts.params)
+ {
+ int param_clkpol = -1;
+ int param_enpol = 2;
+
+ if (first_cell->type == "$_DFF_N_") param_clkpol = 0;
+ if (first_cell->type == "$_DFF_P_") param_clkpol = 1;
+
+ if (first_cell->type == "$_DFFE_NN_") param_clkpol = 0, param_enpol = 0;
+ if (first_cell->type == "$_DFFE_NP_") param_clkpol = 0, param_enpol = 1;
+ if (first_cell->type == "$_DFFE_PN_") param_clkpol = 1, param_enpol = 0;
+ if (first_cell->type == "$_DFFE_PP_") param_clkpol = 1, param_enpol = 1;
+
+ log_assert(param_clkpol >= 0);
+ first_cell->setParam("\\CLKPOL", param_clkpol);
+ if (opts.ffe) first_cell->setParam("\\ENPOL", param_enpol);
+ }
- IdString q_port = opts.ffcells.at(first_cell->type).second;
first_cell->type = shreg_cell_type_str;
first_cell->setPort(q_port, last_cell->getPort(q_port));
first_cell->setParam("\\DEPTH", depth);
+ if (opts.tech != nullptr && opts.tech->fixup(first_cell, taps, qbits))
+ remove_cells.insert(first_cell);
+
for (int i = 1; i < depth; i++)
remove_cells.insert(chain[cursor+i]);
cursor += depth;
for (auto cell : remove_cells)
module->remove(cell);
+ for (auto wire : module->wires())
+ {
+ if (wire->attributes.count("\\init") == 0)
+ continue;
+
+ SigSpec initsig = sigmap(wire);
+ Const &initval = wire->attributes.at("\\init");
+
+ for (int i = 0; i < GetSize(initsig) && i < GetSize(initval); i++)
+ if (remove_init.count(initsig[i]))
+ initval[i] = State::Sx;
+
+ if (SigSpec(initval).is_fully_undef())
+ wire->attributes.erase("\\init");
+ }
+
remove_cells.clear();
sigbit_chain_next.clear();
sigbit_chain_prev.clear();
ShregmapWorker(Module *module, const ShregmapOptions &opts) :
module(module), sigmap(module), opts(opts), dff_count(0), shreg_count(0)
{
- make_sigbit_chain_next_prev();
+ if (opts.tech)
+ opts.tech->init(module, sigmap);
+ make_sigbit_chain_next_prev();
find_chain_start_cells();
for (auto c : chain_start_cells) {
struct ShregmapPass : public Pass {
ShregmapPass() : Pass("shregmap", "map shift registers") { }
- virtual void help()
+ void help() YS_OVERRIDE
{
// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
log("\n");
log(" shregmap [options] [selection]\n");
log("\n");
- log("This pass converts chains of $_DFF_[NP]_ gates to target specific shift register.\n");
+ log("This pass converts chains of $_DFF_[NP]_ gates to target specific shift register\n");
log("primitives. The generated shift register will be of type $__SHREG_DFF_[NP]_ and\n");
log("will use the same interface as the original $_DFF_*_ cells. The cell parameter\n");
log("'DEPTH' will contain the depth of the shift register. Use a target-specific\n");
log(" by default. E.g. the option '-clkpol pos' is just an alias for\n");
log(" '-match $_DFF_P_', which is an alias for '-match $_DFF_P_:D:Q'.\n");
log("\n");
+ log(" -params\n");
+ log(" instead of encoding the clock and enable polarity in the cell name by\n");
+ log(" deriving from the original cell name, simply name all generated cells\n");
+ log(" $__SHREG_ and use CLKPOL and ENPOL parameters. An ENPOL value of 2 is\n");
+ log(" used to denote cells without enable input. The ENPOL parameter is\n");
+ log(" omitted when '-enpol none' (or no -enpol option) is passed.\n");
+ log("\n");
+ log(" -zinit\n");
+ log(" assume the shift register is automatically zero-initialized, so it\n");
+ log(" becomes legal to merge zero initialized FFs into the shift register.\n");
+ log("\n");
+ log(" -init\n");
+ log(" map initialized registers to the shift reg, add an INIT parameter to\n");
+ log(" generated cells with the initialization value. (first bit to shift out\n");
+ log(" in LSB position)\n");
+ log("\n");
+ log(" -tech greenpak4\n");
+ log(" map to greenpak4 shift registers.\n");
+ log("\n");
}
- virtual void execute(std::vector<std::string> args, RTLIL::Design *design)
+ void execute(std::vector<std::string> args, RTLIL::Design *design) YS_OVERRIDE
{
ShregmapOptions opts;
string clkpol, enpol;
- log_header("Executing SHREGMAP pass (map shift registers).\n");
+ log_header(design, "Executing SHREGMAP pass (map shift registers).\n");
size_t argidx;
for (argidx = 1; argidx < args.size(); argidx++)
opts.keep_after = atoi(args[++argidx].c_str());
continue;
}
+ if (args[argidx] == "-tech" && argidx+1 < args.size() && opts.tech == nullptr) {
+ string tech = args[++argidx];
+ if (tech == "greenpak4") {
+ clkpol = "pos";
+ opts.zinit = true;
+ opts.tech = new ShregmapTechGreenpak4;
+ }
+ else if (tech == "xilinx_static" || tech == "xilinx_dynamic") {
+ opts.init = true;
+ opts.ffcells["$_DFF_P_"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["$_DFF_N_"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["$_DFFE_PP_"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["$_DFFE_PN_"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["$_DFFE_NP_"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["$_DFFE_NN_"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["\\FDRE"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["\\FDRE_1"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["\\FDSE"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["\\FDSE_1"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["\\FDCE"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["\\FDCE_1"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["\\FDPE"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ opts.ffcells["\\FDPE_1"] = make_pair(IdString("\\D"), IdString("\\Q"));
+ if (tech == "xilinx_static")
+ opts.tech = new ShregmapTechXilinx7Static(opts);
+ else if (tech == "xilinx_dynamic")
+ opts.tech = new ShregmapTechXilinx7Dynamic(opts);
+ } else {
+ argidx--;
+ break;
+ }
+ continue;
+ }
+ if (args[argidx] == "-zinit") {
+ opts.zinit = true;
+ continue;
+ }
+ if (args[argidx] == "-init") {
+ opts.init = true;
+ continue;
+ }
+ if (args[argidx] == "-params") {
+ opts.params = true;
+ continue;
+ }
break;
}
extra_args(args, argidx, design);
+ if (opts.zinit && opts.init)
+ log_cmd_error("Options -zinit and -init are exclusive!\n");
+
if (opts.ffcells.empty())
{
bool clk_pos = clkpol == "" || clkpol == "pos" || clkpol == "any";
opts.ffcells["$_DFFE_NP_"] = make_pair(IdString("\\D"), IdString("\\Q"));
if (clk_neg && en_neg)
opts.ffcells["$_DFFE_NN_"] = make_pair(IdString("\\D"), IdString("\\Q"));
+
+ if (en_pos || en_neg)
+ opts.ffe = true;
}
else
{
log_cmd_error("Options -clkpol and -match are exclusive!\n");
if (!enpol.empty())
log_cmd_error("Options -enpol and -match are exclusive!\n");
+ if (opts.params)
+ log_cmd_error("Options -params and -match are exclusive!\n");
}
int dff_count = 0;
}
log("Converted %d dff cells into %d shift registers.\n", dff_count, shreg_count);
+
+ if (opts.tech != nullptr) {
+ delete opts.tech;
+ opts.tech = nullptr;
+ }
}
} ShregmapPass;