passes/pmgen/xilinx_dsp.cc - third_party/yosys - Git at Google

 /*
  *  yosys -- Yosys Open SYnthesis Suite
  *
  *  Copyright (C) 2012  Clifford Wolf <clifford@clifford.at>
  *                2019  Eddie Hung    <eddie@fpgeh.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.
  *
  */

 #include "kernel/yosys.h"
 #include "kernel/sigtools.h"
 #include <deque>

 USING_YOSYS_NAMESPACE
 PRIVATE_NAMESPACE_BEGIN

 #include "passes/pmgen/xilinx_dsp_pm.h"
 #include "passes/pmgen/xilinx_dsp_CREG_pm.h"
 #include "passes/pmgen/xilinx_dsp_cascade_pm.h"

 static Cell* addDsp(Module *module) {
 	Cell *cell = module->addCell(NEW_ID, ID(DSP48E1));
 	cell->setParam(ID(ACASCREG), 0);
 	cell->setParam(ID(ADREG), 0);
 	cell->setParam(ID(A_INPUT), Const("DIRECT"));
 	cell->setParam(ID(ALUMODEREG), 0);
 	cell->setParam(ID(AREG), 0);
 	cell->setParam(ID(BCASCREG), 0);
 	cell->setParam(ID(B_INPUT), Const("DIRECT"));
 	cell->setParam(ID(BREG), 0);
 	cell->setParam(ID(CARRYINREG), 0);
 	cell->setParam(ID(CARRYINSELREG), 0);
 	cell->setParam(ID(CREG), 0);
 	cell->setParam(ID(DREG), 0);
 	cell->setParam(ID(INMODEREG), 0);
 	cell->setParam(ID(MREG), 0);
 	cell->setParam(ID(OPMODEREG), 0);
 	cell->setParam(ID(PREG), 0);
 	cell->setParam(ID(USE_MULT), Const("NONE"));
 	cell->setParam(ID(USE_SIMD), Const("ONE48"));
 	cell->setParam(ID(USE_DPORT), Const("FALSE"));

 	cell->setPort(ID(D), Const(0, 25));
 	cell->setPort(ID(INMODE), Const(0, 5));
 	cell->setPort(ID(ALUMODE), Const(0, 4));
 	cell->setPort(ID(OPMODE), Const(0, 7));
 	cell->setPort(ID(CARRYINSEL), Const(0, 3));
 	cell->setPort(ID(ACIN), Const(0, 30));
 	cell->setPort(ID(BCIN), Const(0, 18));
 	cell->setPort(ID(PCIN), Const(0, 48));
 	cell->setPort(ID(CARRYIN), Const(0, 1));
 	return cell;
 }

 void xilinx_simd_pack(Module *module, const std::vector<Cell*> &selected_cells)
 {
 	std::deque<Cell*> simd12_add, simd12_sub;
 	std::deque<Cell*> simd24_add, simd24_sub;

 	for (auto cell : selected_cells) {
 		if (!cell->type.in(ID($add), ID($sub)))
 			continue;
 		SigSpec Y = cell->getPort(ID(Y));
 		if (!Y.is_chunk())
 			continue;
 		if (!Y.as_chunk().wire->get_strpool_attribute(ID(use_dsp)).count("simd"))
 			continue;
 		if (GetSize(Y) > 25)
 			continue;
 		SigSpec A = cell->getPort(ID(A));
 		SigSpec B = cell->getPort(ID(B));
 		if (GetSize(Y) <= 13) {
 			if (GetSize(A) > 12)
 				continue;
 			if (GetSize(B) > 12)
 				continue;
 			if (cell->type == ID($add))
 				simd12_add.push_back(cell);
 			else if (cell->type == ID($sub))
 				simd12_sub.push_back(cell);
 		}
 		else if (GetSize(Y) <= 25) {
 			if (GetSize(A) > 24)
 				continue;
 			if (GetSize(B) > 24)
 				continue;
 			if (cell->type == ID($add))
 				simd24_add.push_back(cell);
 			else if (cell->type == ID($sub))
 				simd24_sub.push_back(cell);
 		}
 		else
 			log_abort();
 	}

 	auto f12 = [module](SigSpec &AB, SigSpec &C, SigSpec &P, SigSpec &CARRYOUT, Cell *lane) {
 		SigSpec A = lane->getPort(ID(A));
 		SigSpec B = lane->getPort(ID(B));
 		SigSpec Y = lane->getPort(ID(Y));
 		A.extend_u0(12, lane->getParam(ID(A_SIGNED)).as_bool());
 		B.extend_u0(12, lane->getParam(ID(B_SIGNED)).as_bool());
 		AB.append(A);
 		C.append(B);
 		if (GetSize(Y) < 13)
 			Y.append(module->addWire(NEW_ID, 13-GetSize(Y)));
 		else
 			log_assert(GetSize(Y) == 13);
 		P.append(Y.extract(0, 12));
 		CARRYOUT.append(Y[12]);
 	};
 	auto g12 = [&f12,module](std::deque<Cell*> &simd12) {
 		while (simd12.size() > 1) {
 			SigSpec AB, C, P, CARRYOUT;

 			Cell *lane1 = simd12.front();
 			simd12.pop_front();
 			Cell *lane2 = simd12.front();
 			simd12.pop_front();
 			Cell *lane3 = nullptr;
 			Cell *lane4 = nullptr;

 			if (!simd12.empty()) {
 				lane3 = simd12.front();
 				simd12.pop_front();
 				if (!simd12.empty()) {
 					lane4 = simd12.front();
 					simd12.pop_front();
 				}
 			}

 			log("Analysing %s.%s for Xilinx DSP SIMD12 packing.\n", log_id(module), log_id(lane1));

 			Cell *cell = addDsp(module);
 			cell->setParam(ID(USE_SIMD), Const("FOUR12"));
 			// X = A:B
 			// Y = 0
 			// Z = C
 			cell->setPort(ID(OPMODE), Const::from_string("0110011"));

 			log_assert(lane1);
 			log_assert(lane2);
 			f12(AB, C, P, CARRYOUT, lane1);
 			f12(AB, C, P, CARRYOUT, lane2);
 			if (lane3) {
 				f12(AB, C, P, CARRYOUT, lane3);
 				if (lane4)
 					f12(AB, C, P, CARRYOUT, lane4);
 				else {
 					AB.append(Const(0, 12));
 					C.append(Const(0, 12));
 					P.append(module->addWire(NEW_ID, 12));
 					CARRYOUT.append(module->addWire(NEW_ID, 1));
 				}
 			}
 			else {
 				AB.append(Const(0, 24));
 				C.append(Const(0, 24));
 				P.append(module->addWire(NEW_ID, 24));
 				CARRYOUT.append(module->addWire(NEW_ID, 2));
 			}
 			log_assert(GetSize(AB) == 48);
 			log_assert(GetSize(C) == 48);
 			log_assert(GetSize(P) == 48);
 			log_assert(GetSize(CARRYOUT) == 4);
 			cell->setPort(ID(A), AB.extract(18, 30));
 			cell->setPort(ID(B), AB.extract(0, 18));
 			cell->setPort(ID(C), C);
 			cell->setPort(ID(P), P);
 			cell->setPort(ID(CARRYOUT), CARRYOUT);
 			if (lane1->type == ID($sub))
 				cell->setPort(ID(ALUMODE), Const::from_string("0011"));

 			module->remove(lane1);
 			module->remove(lane2);
 			if (lane3) module->remove(lane3);
 			if (lane4) module->remove(lane4);

 			module->design->select(module, cell);
 		}
 	};
 	g12(simd12_add);
 	g12(simd12_sub);

 	auto f24 = [module](SigSpec &AB, SigSpec &C, SigSpec &P, SigSpec &CARRYOUT, Cell *lane) {
 		SigSpec A = lane->getPort(ID(A));
 		SigSpec B = lane->getPort(ID(B));
 		SigSpec Y = lane->getPort(ID(Y));
 		A.extend_u0(24, lane->getParam(ID(A_SIGNED)).as_bool());
 		B.extend_u0(24, lane->getParam(ID(B_SIGNED)).as_bool());
 		C.append(A);
 		AB.append(B);
 		if (GetSize(Y) < 25)
 			Y.append(module->addWire(NEW_ID, 25-GetSize(Y)));
 		else
 			log_assert(GetSize(Y) == 25);
 		P.append(Y.extract(0, 24));
 		CARRYOUT.append(module->addWire(NEW_ID)); // TWO24 uses every other bit
 		CARRYOUT.append(Y[24]);
 	};
 	auto g24 = [&f24,module](std::deque<Cell*> &simd24) {
 		while (simd24.size() > 1) {
 			SigSpec AB;
 			SigSpec C;
 			SigSpec P;
 			SigSpec CARRYOUT;

 			Cell *lane1 = simd24.front();
 			simd24.pop_front();
 			Cell *lane2 = simd24.front();
 			simd24.pop_front();

 			log("Analysing %s.%s for Xilinx DSP SIMD24 packing.\n", log_id(module), log_id(lane1));

 			Cell *cell = addDsp(module);
 			cell->setParam(ID(USE_SIMD), Const("TWO24"));
 			// X = A:B
 			// Y = 0
 			// Z = C
 			cell->setPort(ID(OPMODE), Const::from_string("0110011"));

 			log_assert(lane1);
 			log_assert(lane2);
 			f24(AB, C, P, CARRYOUT, lane1);
 			f24(AB, C, P, CARRYOUT, lane2);
 			log_assert(GetSize(AB) == 48);
 			log_assert(GetSize(C) == 48);
 			log_assert(GetSize(P) == 48);
 			log_assert(GetSize(CARRYOUT) == 4);
 			cell->setPort(ID(A), AB.extract(18, 30));
 			cell->setPort(ID(B), AB.extract(0, 18));
 			cell->setPort(ID(C), C);
 			cell->setPort(ID(P), P);
 			cell->setPort(ID(CARRYOUT), CARRYOUT);
 			if (lane1->type == ID($sub))
 				cell->setPort(ID(ALUMODE), Const::from_string("0011"));

 			module->remove(lane1);
 			module->remove(lane2);

 			module->design->select(module, cell);
 		}
 	};
 	g24(simd24_add);
 	g24(simd24_sub);
 }

 void xilinx_dsp_pack(xilinx_dsp_pm &pm)
 {
 	auto &st = pm.st_xilinx_dsp_pack;

 	log("Analysing %s.%s for Xilinx DSP packing.\n", log_id(pm.module), log_id(st.dsp));

 	log_debug("preAdd:     %s\n", log_id(st.preAdd, "--"));
 	log_debug("ffAD:       %s %s %s\n", log_id(st.ffAD, "--"), log_id(st.ffADcemux, "--"), log_id(st.ffADrstmux, "--"));
 	log_debug("ffA2:       %s %s %s\n", log_id(st.ffA2, "--"), log_id(st.ffA2cemux, "--"), log_id(st.ffA2rstmux, "--"));
 	log_debug("ffA1:       %s %s %s\n", log_id(st.ffA1, "--"), log_id(st.ffA1cemux, "--"), log_id(st.ffA1rstmux, "--"));
 	log_debug("ffB2:       %s %s %s\n", log_id(st.ffB2, "--"), log_id(st.ffB2cemux, "--"), log_id(st.ffB2rstmux, "--"));
 	log_debug("ffB1:       %s %s %s\n", log_id(st.ffB1, "--"), log_id(st.ffB1cemux, "--"), log_id(st.ffB1rstmux, "--"));
 	log_debug("ffD:        %s %s %s\n", log_id(st.ffD, "--"), log_id(st.ffDcemux, "--"), log_id(st.ffDrstmux, "--"));
 	log_debug("dsp:        %s\n", log_id(st.dsp, "--"));
 	log_debug("ffM:        %s %s %s\n", log_id(st.ffM, "--"), log_id(st.ffMcemux, "--"), log_id(st.ffMrstmux, "--"));
 	log_debug("postAdd:    %s\n", log_id(st.postAdd, "--"));
 	log_debug("postAddMux: %s\n", log_id(st.postAddMux, "--"));
 	log_debug("ffP:        %s %s %s\n", log_id(st.ffP, "--"), log_id(st.ffPcemux, "--"), log_id(st.ffPrstmux, "--"));
 	log_debug("overflow:   %s\n", log_id(st.overflow, "--"));

 	Cell *cell = st.dsp;

 	if (st.preAdd) {
 		log("  preadder %s (%s)\n", log_id(st.preAdd), log_id(st.preAdd->type));
 		bool A_SIGNED = st.preAdd->getParam(ID(A_SIGNED)).as_bool();
 		bool D_SIGNED = st.preAdd->getParam(ID(B_SIGNED)).as_bool();
 		if (st.sigA == st.preAdd->getPort(ID(B)))
 			std::swap(A_SIGNED, D_SIGNED);
 		st.sigA.extend_u0(30, A_SIGNED);
 		st.sigD.extend_u0(25, D_SIGNED);
 		cell->setPort(ID(A), st.sigA);
 		cell->setPort(ID(D), st.sigD);
 		cell->setPort(ID(INMODE), Const::from_string("00100"));

 		if (st.ffAD) {
 			if (st.ffADcemux) {
 				SigSpec S = st.ffADcemux->getPort(ID(S));
 				cell->setPort(ID(CEAD), st.ffADcepol ? S : pm.module->Not(NEW_ID, S));
 			}
 			else
 				cell->setPort(ID(CEAD), State::S1);
 			cell->setParam(ID(ADREG), 1);
 		}

 		cell->setParam(ID(USE_DPORT), Const("TRUE"));

 		pm.autoremove(st.preAdd);
 	}
 	if (st.postAdd) {
 		log("  postadder %s (%s)\n", log_id(st.postAdd), log_id(st.postAdd->type));

 		SigSpec &opmode = cell->connections_.at(ID(OPMODE));
 		if (st.postAddMux) {
 			log_assert(st.ffP);
 			opmode[4] = st.postAddMux->getPort(ID(S));
 			pm.autoremove(st.postAddMux);
 		}
 		else if (st.ffP && st.sigC == st.sigP)
 			opmode[4] = State::S0;
 		else
 			opmode[4] = State::S1;
 		opmode[6] = State::S0;
 		opmode[5] = State::S1;

 		if (opmode[4] != State::S0) {
 			if (st.postAddMuxAB == ID(A))
 				st.sigC.extend_u0(48, st.postAdd->getParam(ID(B_SIGNED)).as_bool());
 			else
 				st.sigC.extend_u0(48, st.postAdd->getParam(ID(A_SIGNED)).as_bool());
 			cell->setPort(ID(C), st.sigC);
 		}

 		pm.autoremove(st.postAdd);
 	}
 	if (st.overflow) {
 		log("  overflow %s (%s)\n", log_id(st.overflow), log_id(st.overflow->type));
 		cell->setParam(ID(USE_PATTERN_DETECT), Const("PATDET"));
 		cell->setParam(ID(SEL_PATTERN), Const("PATTERN"));
 		cell->setParam(ID(SEL_MASK), Const("MASK"));

 		if (st.overflow->type == ID($ge)) {
 			Const B = st.overflow->getPort(ID(B)).as_const();
 			log_assert(std::count(B.bits.begin(), B.bits.end(), State::S1) == 1);
 			// Since B is an exact power of 2, subtract 1
 			//   by inverting all bits up until hitting
 			//   that one hi bit
 			for (auto &b : B.bits)
 				if (b == State::S0) b = State::S1;
 				else if (b == State::S1) {
 					b = State::S0;
 					break;
 				}
 			B.extu(48);

 			cell->setParam(ID(MASK), B);
 			cell->setParam(ID(PATTERN), Const(0, 48));
 			cell->setPort(ID(OVERFLOW), st.overflow->getPort(ID(Y)));
 		}
 		else log_abort();

 		pm.autoremove(st.overflow);
 	}

 	if (st.clock != SigBit())
 	{
 		cell->setPort(ID(CLK), st.clock);

 		auto f = [&pm,cell](SigSpec &A, Cell* ff, Cell* cemux, bool cepol, IdString ceport, Cell* rstmux, bool rstpol, IdString rstport) {
 			SigSpec D = ff->getPort(ID(D));
 			SigSpec Q = pm.sigmap(ff->getPort(ID(Q)));
 			if (!A.empty())
 				A.replace(Q, D);
 			if (rstmux) {
 				SigSpec Y = rstmux->getPort(ID(Y));
 				SigSpec AB = rstmux->getPort(rstpol ? ID(A) : ID(B));
 				if (!A.empty())
 					A.replace(Y, AB);
 				if (rstport != IdString()) {
 					SigSpec S = rstmux->getPort(ID(S));
 					cell->setPort(rstport, rstpol ? S : pm.module->Not(NEW_ID, S));
 				}
 			}
 			else if (rstport != IdString())
 				cell->setPort(rstport, State::S0);
 			if (cemux) {
 				SigSpec Y = cemux->getPort(ID(Y));
 				SigSpec BA = cemux->getPort(cepol ? ID(B) : ID(A));
 				SigSpec S = cemux->getPort(ID(S));
 				if (!A.empty())
 					A.replace(Y, BA);
 				cell->setPort(ceport, cepol ? S : pm.module->Not(NEW_ID, S));
 			}
 			else
 				cell->setPort(ceport, State::S1);

 			for (auto c : Q.chunks()) {
 				auto it = c.wire->attributes.find(ID(init));
 				if (it == c.wire->attributes.end())
 					continue;
 				for (int i = c.offset; i < c.offset+c.width; i++) {
 					log_assert(it->second[i] == State::S0 || it->second[i] == State::Sx);
 					it->second[i] = State::Sx;
 				}
 			}
 		};

 		if (st.ffA2) {
 			SigSpec A = cell->getPort(ID(A));
 			f(A, st.ffA2, st.ffA2cemux, st.ffA2cepol, ID(CEA2), st.ffA2rstmux, st.ffArstpol, ID(RSTA));
 			if (st.ffA1) {
 				f(A, st.ffA1, st.ffA1cemux, st.ffA1cepol, ID(CEA1), st.ffA1rstmux, st.ffArstpol, IdString());
 				cell->setParam(ID(AREG), 2);
 				cell->setParam(ID(ACASCREG), 2);
 			}
 			else {
 				cell->setParam(ID(AREG), 1);
 				cell->setParam(ID(ACASCREG), 1);
 			}
 			pm.add_siguser(A, cell);
 			cell->setPort(ID(A), A);
 		}
 		if (st.ffB2) {
 			SigSpec B = cell->getPort(ID(B));
 			f(B, st.ffB2, st.ffB2cemux, st.ffB2cepol, ID(CEB2), st.ffB2rstmux, st.ffBrstpol, ID(RSTB));
 			if (st.ffB1) {
 				f(B, st.ffB1, st.ffB1cemux, st.ffB1cepol, ID(CEB1), st.ffB1rstmux, st.ffBrstpol, IdString());
 				cell->setParam(ID(BREG), 2);
 				cell->setParam(ID(BCASCREG), 2);
 			}
 			else {
 				cell->setParam(ID(BREG), 1);
 				cell->setParam(ID(BCASCREG), 1);
 			}
 			pm.add_siguser(B, cell);
 			cell->setPort(ID(B), B);
 		}
 		if (st.ffD) {
 			SigSpec D = cell->getPort(ID(D));
 			f(D, st.ffD, st.ffDcemux, st.ffDcepol, ID(CED), st.ffDrstmux, st.ffDrstpol, ID(RSTD));
 			pm.add_siguser(D, cell);
 			cell->setPort(ID(D), D);
 			cell->setParam(ID(DREG), 1);
 		}
 		if (st.ffM) {
 			SigSpec M; // unused
 			f(M, st.ffM, st.ffMcemux, st.ffMcepol, ID(CEM), st.ffMrstmux, st.ffMrstpol, ID(RSTM));
 			st.ffM->connections_.at(ID(Q)).replace(st.sigM, pm.module->addWire(NEW_ID, GetSize(st.sigM)));
 			cell->setParam(ID(MREG), State::S1);
 		}
 		if (st.ffP) {
 			SigSpec P; // unused
 			f(P, st.ffP, st.ffPcemux, st.ffPcepol, ID(CEP), st.ffPrstmux, st.ffPrstpol, ID(RSTP));
 			st.ffP->connections_.at(ID(Q)).replace(st.sigP, pm.module->addWire(NEW_ID, GetSize(st.sigP)));
 			cell->setParam(ID(PREG), State::S1);
 		}

 		log("  clock: %s (%s)", log_signal(st.clock), "posedge");

 		if (st.ffA2) {
 			log(" ffA2:%s", log_id(st.ffA2));
 			if (st.ffA1)
 				log(" ffA1:%s", log_id(st.ffA1));
 		}

 		if (st.ffAD)
 			log(" ffAD:%s", log_id(st.ffAD));

 		if (st.ffB2) {
 			log(" ffB2:%s", log_id(st.ffB2));
 			if (st.ffB1)
 				log(" ffB1:%s", log_id(st.ffB1));
 		}

 		if (st.ffD)
 			log(" ffD:%s", log_id(st.ffD));

 		if (st.ffM)
 			log(" ffM:%s", log_id(st.ffM));

 		if (st.ffP)
 			log(" ffP:%s", log_id(st.ffP));
 	}
 	log("\n");

 	SigSpec P = st.sigP;
 	if (GetSize(P) < 48)
 		P.append(pm.module->addWire(NEW_ID, 48-GetSize(P)));
 	cell->setPort(ID(P), P);

 	pm.blacklist(cell);
 }

 void xilinx_dsp_packC(xilinx_dsp_CREG_pm &pm)
 {
 	auto &st = pm.st_xilinx_dsp_packC;

 	log_debug("Analysing %s.%s for Xilinx DSP packing (CREG).\n", log_id(pm.module), log_id(st.dsp));
 	log_debug("ffC:        %s %s %s\n", log_id(st.ffC, "--"), log_id(st.ffCcemux, "--"), log_id(st.ffCrstmux, "--"));

 	Cell *cell = st.dsp;

 	if (st.clock != SigBit())
 	{
 		cell->setPort(ID(CLK), st.clock);

 		auto f = [&pm,cell](SigSpec &A, Cell* ff, Cell* cemux, bool cepol, IdString ceport, Cell* rstmux, bool rstpol, IdString rstport) {
 			SigSpec D = ff->getPort(ID(D));
 			SigSpec Q = pm.sigmap(ff->getPort(ID(Q)));
 			if (!A.empty())
 				A.replace(Q, D);
 			if (rstmux) {
 				SigSpec Y = rstmux->getPort(ID(Y));
 				SigSpec AB = rstmux->getPort(rstpol ? ID(A) : ID(B));
 				if (!A.empty())
 					A.replace(Y, AB);
 				if (rstport != IdString()) {
 					SigSpec S = rstmux->getPort(ID(S));
 					cell->setPort(rstport, rstpol ? S : pm.module->Not(NEW_ID, S));
 				}
 			}
 			else if (rstport != IdString())
 				cell->setPort(rstport, State::S0);
 			if (cemux) {
 				SigSpec Y = cemux->getPort(ID(Y));
 				SigSpec BA = cemux->getPort(cepol ? ID(B) : ID(A));
 				SigSpec S = cemux->getPort(ID(S));
 				if (!A.empty())
 					A.replace(Y, BA);
 				cell->setPort(ceport, cepol ? S : pm.module->Not(NEW_ID, S));
 			}
 			else
 				cell->setPort(ceport, State::S1);

 			for (auto c : Q.chunks()) {
 				auto it = c.wire->attributes.find(ID(init));
 				if (it == c.wire->attributes.end())
 					continue;
 				for (int i = c.offset; i < c.offset+c.width; i++) {
 					log_assert(it->second[i] == State::S0 || it->second[i] == State::Sx);
 					it->second[i] = State::Sx;
 				}
 			}
 		};

 		if (st.ffC) {
 			SigSpec C = cell->getPort(ID(C));
 			f(C, st.ffC, st.ffCcemux, st.ffCcepol, ID(CEC), st.ffCrstmux, st.ffCrstpol, ID(RSTC));
 			pm.add_siguser(C, cell);
 			cell->setPort(ID(C), C);
 			cell->setParam(ID(CREG), 1);
 		}

 		log("  clock: %s (%s)", log_signal(st.clock), "posedge");

 		if (st.ffC)
 			log(" ffC:%s", log_id(st.ffC));
 		log("\n");
 	}

 	pm.blacklist(cell);
 }

 struct XilinxDspPass : public Pass {
 	XilinxDspPass() : Pass("xilinx_dsp", "Xilinx: pack resources into DSPs") { }
 	void help() YS_OVERRIDE
 	{
 		//   |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
 		log("\n");
 		log("    xilinx_dsp [options] [selection]\n");
 		log("\n");
 		log("Pack input registers (A2, A1, B2, B1, C, D, AD; with optional enable/reset),\n");
 		log("pipeline registers (M; with optional enable/reset), output registers (P; with\n");
 		log("optional enable/reset), pre-adder and/or post-adder into Xilinx DSP resources.\n");
 		log("\n");
 		log("Multiply-accumulate operations using the post-adder with feedback on the 'C'\n");
 		log("input will be folded into the DSP. In this scenario only, the 'C' input can be\n");
 		log("used to override the current accumulation result with a new value, which will\n");
 		log("be added to the multiplier result to form the next accumulation result.\n");
 		log("\n");
 		log("Use of the dedicated 'PCOUT' -> 'PCIN' cascade path is detected for 'P' -> 'C'\n");
 		log("connections (optionally, where 'P' is right-shifted by 17-bits and used as an\n");
 		log("input to the post-adder -- a pattern common for summing partial products to\n");
 		log("implement wide multipliers). Limited support also exists for similar cascading\n");
 		log("for A and B using '[AB]COUT' -> '[AB]CIN'. Currently, cascade chains are limited\n");
 		log("to a maximum length of 20 cells, corresponding to the smallest Xilinx 7 Series\n");
 		log("device.\n");
 		log("\n");
 		log("\n");
 		log("Experimental feature: addition/subtractions less than 12 or 24 bits with the\n");
 		log("'(* use_dsp=\"simd\" *)' attribute attached to the output wire or attached to\n");
 		log("the add/subtract operator will cause those operations to be implemented using\n");
 		log("the 'SIMD' feature of DSPs.\n");
 		log("\n");
 		log("Experimental feature: the presence of a `$ge' cell attached to the registered\n");
 		log("P output implementing the operation \"(P >= <power-of-2>)\" will be transformed\n");
 		log("into using the DSP48E1's pattern detector feature for overflow detection.\n");
 		log("\n");
 	}
 	void execute(std::vector<std::string> args, RTLIL::Design *design) YS_OVERRIDE
 	{
 		log_header(design, "Executing XILINX_DSP pass (pack resources into DSPs).\n");

 		size_t argidx;
 		for (argidx = 1; argidx < args.size(); argidx++)
 		{
 			// if (args[argidx] == "-singleton") {
 			// 	singleton_mode = true;
 			// 	continue;
 			// }
 			break;
 		}
 		extra_args(args, argidx, design);

 		for (auto module : design->selected_modules()) {
 			// Experimental feature: pack $add/$sub cells with
 			//   (* use_dsp48="simd" *) into DSP48E1's using its
 			//   SIMD feature
 			xilinx_simd_pack(module, module->selected_cells());

 			// Match for all features ([ABDMP][12]?REG, pre-adder,
 			// post-adder, pattern detector, etc.) except for CREG
 			{
 				xilinx_dsp_pm pm(module, module->selected_cells());
 				pm.run_xilinx_dsp_pack(xilinx_dsp_pack);
 			}
 			// Separating out CREG packing is necessary since there
 			//   is no guarantee that the cell ordering corresponds
 			//   to the "expected" case (i.e. the order in which
 			//   they appear in the source) thus the possiblity
 			//   existed that a register got packed as a CREG into a
 			//   downstream DSP that should have otherwise been a
 			//   PREG of an upstream DSP that had not been visited
 			//   yet
 			{
 				xilinx_dsp_CREG_pm pm(module, module->selected_cells());
 				pm.run_xilinx_dsp_packC(xilinx_dsp_packC);
 			}
 			// Lastly, identify and utilise PCOUT -> PCIN,
 			//   ACOUT -> ACIN, and BCOUT-> BCIN dedicated cascade
 			//   chains
 			{
 				xilinx_dsp_cascade_pm pm(module, module->selected_cells());
 				pm.run_xilinx_dsp_cascade();
 			}
 		}
 	}
 } XilinxDspPass;

 PRIVATE_NAMESPACE_END
	/*
	* yosys -- Yosys Open SYnthesis Suite
	*
	* Copyright (C) 2012 Clifford Wolf <clifford@clifford.at>
	* 2019 Eddie Hung <eddie@fpgeh.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.
	*
	*/

	#include "kernel/yosys.h"
	#include "kernel/sigtools.h"
	#include <deque>

	USING_YOSYS_NAMESPACE
	PRIVATE_NAMESPACE_BEGIN

	#include "passes/pmgen/xilinx_dsp_pm.h"
	#include "passes/pmgen/xilinx_dsp_CREG_pm.h"
	#include "passes/pmgen/xilinx_dsp_cascade_pm.h"

	static Cell* addDsp(Module *module) {
	Cell *cell = module->addCell(NEW_ID, ID(DSP48E1));
	cell->setParam(ID(ACASCREG), 0);
	cell->setParam(ID(ADREG), 0);
	cell->setParam(ID(A_INPUT), Const("DIRECT"));
	cell->setParam(ID(ALUMODEREG), 0);
	cell->setParam(ID(AREG), 0);
	cell->setParam(ID(BCASCREG), 0);
	cell->setParam(ID(B_INPUT), Const("DIRECT"));
	cell->setParam(ID(BREG), 0);
	cell->setParam(ID(CARRYINREG), 0);
	cell->setParam(ID(CARRYINSELREG), 0);
	cell->setParam(ID(CREG), 0);
	cell->setParam(ID(DREG), 0);
	cell->setParam(ID(INMODEREG), 0);
	cell->setParam(ID(MREG), 0);
	cell->setParam(ID(OPMODEREG), 0);
	cell->setParam(ID(PREG), 0);
	cell->setParam(ID(USE_MULT), Const("NONE"));
	cell->setParam(ID(USE_SIMD), Const("ONE48"));
	cell->setParam(ID(USE_DPORT), Const("FALSE"));

	cell->setPort(ID(D), Const(0, 25));
	cell->setPort(ID(INMODE), Const(0, 5));
	cell->setPort(ID(ALUMODE), Const(0, 4));
	cell->setPort(ID(OPMODE), Const(0, 7));
	cell->setPort(ID(CARRYINSEL), Const(0, 3));
	cell->setPort(ID(ACIN), Const(0, 30));
	cell->setPort(ID(BCIN), Const(0, 18));
	cell->setPort(ID(PCIN), Const(0, 48));
	cell->setPort(ID(CARRYIN), Const(0, 1));
	return cell;
	}

	void xilinx_simd_pack(Module module, const std::vector<Cell> &selected_cells)
	{
	std::deque<Cell*> simd12_add, simd12_sub;
	std::deque<Cell*> simd24_add, simd24_sub;

	for (auto cell : selected_cells) {
	if (!cell->type.in(ID($add), ID($sub)))
	continue;
	SigSpec Y = cell->getPort(ID(Y));
	if (!Y.is_chunk())
	continue;
	if (!Y.as_chunk().wire->get_strpool_attribute(ID(use_dsp)).count("simd"))
	continue;
	if (GetSize(Y) > 25)
	continue;
	SigSpec A = cell->getPort(ID(A));
	SigSpec B = cell->getPort(ID(B));
	if (GetSize(Y) <= 13) {
	if (GetSize(A) > 12)
	continue;
	if (GetSize(B) > 12)
	continue;
	if (cell->type == ID($add))
	simd12_add.push_back(cell);
	else if (cell->type == ID($sub))
	simd12_sub.push_back(cell);
	}
	else if (GetSize(Y) <= 25) {
	if (GetSize(A) > 24)
	continue;
	if (GetSize(B) > 24)
	continue;
	if (cell->type == ID($add))
	simd24_add.push_back(cell);
	else if (cell->type == ID($sub))
	simd24_sub.push_back(cell);
	}
	else
	log_abort();
	}

	auto f12 = [module](SigSpec &AB, SigSpec &C, SigSpec &P, SigSpec &CARRYOUT, Cell *lane) {
	SigSpec A = lane->getPort(ID(A));
	SigSpec B = lane->getPort(ID(B));
	SigSpec Y = lane->getPort(ID(Y));
	A.extend_u0(12, lane->getParam(ID(A_SIGNED)).as_bool());
	B.extend_u0(12, lane->getParam(ID(B_SIGNED)).as_bool());
	AB.append(A);
	C.append(B);
	if (GetSize(Y) < 13)
	Y.append(module->addWire(NEW_ID, 13-GetSize(Y)));
	else
	log_assert(GetSize(Y) == 13);
	P.append(Y.extract(0, 12));
	CARRYOUT.append(Y[12]);
	};
	auto g12 = [&f12,module](std::deque<Cell*> &simd12) {
	while (simd12.size() > 1) {
	SigSpec AB, C, P, CARRYOUT;

	Cell *lane1 = simd12.front();
	simd12.pop_front();
	Cell *lane2 = simd12.front();
	simd12.pop_front();
	Cell *lane3 = nullptr;
	Cell *lane4 = nullptr;

	if (!simd12.empty()) {
	lane3 = simd12.front();
	simd12.pop_front();
	if (!simd12.empty()) {
	lane4 = simd12.front();
	simd12.pop_front();
	}
	}

	log("Analysing %s.%s for Xilinx DSP SIMD12 packing.\n", log_id(module), log_id(lane1));

	Cell *cell = addDsp(module);
	cell->setParam(ID(USE_SIMD), Const("FOUR12"));
	// X = A:B
	// Y = 0
	// Z = C
	cell->setPort(ID(OPMODE), Const::from_string("0110011"));

	log_assert(lane1);
	log_assert(lane2);
	f12(AB, C, P, CARRYOUT, lane1);
	f12(AB, C, P, CARRYOUT, lane2);
	if (lane3) {
	f12(AB, C, P, CARRYOUT, lane3);
	if (lane4)
	f12(AB, C, P, CARRYOUT, lane4);
	else {
	AB.append(Const(0, 12));
	C.append(Const(0, 12));
	P.append(module->addWire(NEW_ID, 12));
	CARRYOUT.append(module->addWire(NEW_ID, 1));
	}
	}
	else {
	AB.append(Const(0, 24));
	C.append(Const(0, 24));
	P.append(module->addWire(NEW_ID, 24));
	CARRYOUT.append(module->addWire(NEW_ID, 2));
	}
	log_assert(GetSize(AB) == 48);
	log_assert(GetSize(C) == 48);
	log_assert(GetSize(P) == 48);
	log_assert(GetSize(CARRYOUT) == 4);
	cell->setPort(ID(A), AB.extract(18, 30));
	cell->setPort(ID(B), AB.extract(0, 18));
	cell->setPort(ID(C), C);
	cell->setPort(ID(P), P);
	cell->setPort(ID(CARRYOUT), CARRYOUT);
	if (lane1->type == ID($sub))
	cell->setPort(ID(ALUMODE), Const::from_string("0011"));

	module->remove(lane1);
	module->remove(lane2);
	if (lane3) module->remove(lane3);
	if (lane4) module->remove(lane4);

	module->design->select(module, cell);
	}
	};
	g12(simd12_add);
	g12(simd12_sub);

	auto f24 = [module](SigSpec &AB, SigSpec &C, SigSpec &P, SigSpec &CARRYOUT, Cell *lane) {
	SigSpec A = lane->getPort(ID(A));
	SigSpec B = lane->getPort(ID(B));
	SigSpec Y = lane->getPort(ID(Y));
	A.extend_u0(24, lane->getParam(ID(A_SIGNED)).as_bool());
	B.extend_u0(24, lane->getParam(ID(B_SIGNED)).as_bool());
	C.append(A);
	AB.append(B);
	if (GetSize(Y) < 25)
	Y.append(module->addWire(NEW_ID, 25-GetSize(Y)));
	else
	log_assert(GetSize(Y) == 25);
	P.append(Y.extract(0, 24));
	CARRYOUT.append(module->addWire(NEW_ID)); // TWO24 uses every other bit
	CARRYOUT.append(Y[24]);
	};
	auto g24 = [&f24,module](std::deque<Cell*> &simd24) {
	while (simd24.size() > 1) {
	SigSpec AB;
	SigSpec C;
	SigSpec P;
	SigSpec CARRYOUT;

	Cell *lane1 = simd24.front();
	simd24.pop_front();
	Cell *lane2 = simd24.front();
	simd24.pop_front();

	log("Analysing %s.%s for Xilinx DSP SIMD24 packing.\n", log_id(module), log_id(lane1));

	Cell *cell = addDsp(module);
	cell->setParam(ID(USE_SIMD), Const("TWO24"));
	// X = A:B
	// Y = 0
	// Z = C
	cell->setPort(ID(OPMODE), Const::from_string("0110011"));

	log_assert(lane1);
	log_assert(lane2);
	f24(AB, C, P, CARRYOUT, lane1);
	f24(AB, C, P, CARRYOUT, lane2);
	log_assert(GetSize(AB) == 48);
	log_assert(GetSize(C) == 48);
	log_assert(GetSize(P) == 48);
	log_assert(GetSize(CARRYOUT) == 4);
	cell->setPort(ID(A), AB.extract(18, 30));
	cell->setPort(ID(B), AB.extract(0, 18));
	cell->setPort(ID(C), C);
	cell->setPort(ID(P), P);
	cell->setPort(ID(CARRYOUT), CARRYOUT);
	if (lane1->type == ID($sub))
	cell->setPort(ID(ALUMODE), Const::from_string("0011"));

	module->remove(lane1);
	module->remove(lane2);

	module->design->select(module, cell);
	}
	};
	g24(simd24_add);
	g24(simd24_sub);
	}

	void xilinx_dsp_pack(xilinx_dsp_pm &pm)
	{
	auto &st = pm.st_xilinx_dsp_pack;

	log("Analysing %s.%s for Xilinx DSP packing.\n", log_id(pm.module), log_id(st.dsp));

	log_debug("preAdd: %s\n", log_id(st.preAdd, "--"));
	log_debug("ffAD: %s %s %s\n", log_id(st.ffAD, "--"), log_id(st.ffADcemux, "--"), log_id(st.ffADrstmux, "--"));
	log_debug("ffA2: %s %s %s\n", log_id(st.ffA2, "--"), log_id(st.ffA2cemux, "--"), log_id(st.ffA2rstmux, "--"));
	log_debug("ffA1: %s %s %s\n", log_id(st.ffA1, "--"), log_id(st.ffA1cemux, "--"), log_id(st.ffA1rstmux, "--"));
	log_debug("ffB2: %s %s %s\n", log_id(st.ffB2, "--"), log_id(st.ffB2cemux, "--"), log_id(st.ffB2rstmux, "--"));
	log_debug("ffB1: %s %s %s\n", log_id(st.ffB1, "--"), log_id(st.ffB1cemux, "--"), log_id(st.ffB1rstmux, "--"));
	log_debug("ffD: %s %s %s\n", log_id(st.ffD, "--"), log_id(st.ffDcemux, "--"), log_id(st.ffDrstmux, "--"));
	log_debug("dsp: %s\n", log_id(st.dsp, "--"));
	log_debug("ffM: %s %s %s\n", log_id(st.ffM, "--"), log_id(st.ffMcemux, "--"), log_id(st.ffMrstmux, "--"));
	log_debug("postAdd: %s\n", log_id(st.postAdd, "--"));
	log_debug("postAddMux: %s\n", log_id(st.postAddMux, "--"));
	log_debug("ffP: %s %s %s\n", log_id(st.ffP, "--"), log_id(st.ffPcemux, "--"), log_id(st.ffPrstmux, "--"));
	log_debug("overflow: %s\n", log_id(st.overflow, "--"));

	Cell *cell = st.dsp;

	if (st.preAdd) {
	log(" preadder %s (%s)\n", log_id(st.preAdd), log_id(st.preAdd->type));
	bool A_SIGNED = st.preAdd->getParam(ID(A_SIGNED)).as_bool();
	bool D_SIGNED = st.preAdd->getParam(ID(B_SIGNED)).as_bool();
	if (st.sigA == st.preAdd->getPort(ID(B)))
	std::swap(A_SIGNED, D_SIGNED);
	st.sigA.extend_u0(30, A_SIGNED);
	st.sigD.extend_u0(25, D_SIGNED);
	cell->setPort(ID(A), st.sigA);
	cell->setPort(ID(D), st.sigD);
	cell->setPort(ID(INMODE), Const::from_string("00100"));

	if (st.ffAD) {
	if (st.ffADcemux) {
	SigSpec S = st.ffADcemux->getPort(ID(S));
	cell->setPort(ID(CEAD), st.ffADcepol ? S : pm.module->Not(NEW_ID, S));
	}
	else
	cell->setPort(ID(CEAD), State::S1);
	cell->setParam(ID(ADREG), 1);
	}

	cell->setParam(ID(USE_DPORT), Const("TRUE"));

	pm.autoremove(st.preAdd);
	}
	if (st.postAdd) {
	log(" postadder %s (%s)\n", log_id(st.postAdd), log_id(st.postAdd->type));

	SigSpec &opmode = cell->connections_.at(ID(OPMODE));
	if (st.postAddMux) {
	log_assert(st.ffP);
	opmode[4] = st.postAddMux->getPort(ID(S));
	pm.autoremove(st.postAddMux);
	}
	else if (st.ffP && st.sigC == st.sigP)
	opmode[4] = State::S0;
	else
	opmode[4] = State::S1;
	opmode[6] = State::S0;
	opmode[5] = State::S1;

	if (opmode[4] != State::S0) {
	if (st.postAddMuxAB == ID(A))
	st.sigC.extend_u0(48, st.postAdd->getParam(ID(B_SIGNED)).as_bool());
	else
	st.sigC.extend_u0(48, st.postAdd->getParam(ID(A_SIGNED)).as_bool());
	cell->setPort(ID(C), st.sigC);
	}

	pm.autoremove(st.postAdd);
	}
	if (st.overflow) {
	log(" overflow %s (%s)\n", log_id(st.overflow), log_id(st.overflow->type));
	cell->setParam(ID(USE_PATTERN_DETECT), Const("PATDET"));
	cell->setParam(ID(SEL_PATTERN), Const("PATTERN"));
	cell->setParam(ID(SEL_MASK), Const("MASK"));

	if (st.overflow->type == ID($ge)) {
	Const B = st.overflow->getPort(ID(B)).as_const();
	log_assert(std::count(B.bits.begin(), B.bits.end(), State::S1) == 1);
	// Since B is an exact power of 2, subtract 1
	// by inverting all bits up until hitting
	// that one hi bit
	for (auto &b : B.bits)
	if (b == State::S0) b = State::S1;
	else if (b == State::S1) {
	b = State::S0;
	break;
	}
	B.extu(48);

	cell->setParam(ID(MASK), B);
	cell->setParam(ID(PATTERN), Const(0, 48));
	cell->setPort(ID(OVERFLOW), st.overflow->getPort(ID(Y)));
	}
	else log_abort();

	pm.autoremove(st.overflow);
	}

	if (st.clock != SigBit())
	{
	cell->setPort(ID(CLK), st.clock);

	auto f = [&pm,cell](SigSpec &A, Cell* ff, Cell* cemux, bool cepol, IdString ceport, Cell* rstmux, bool rstpol, IdString rstport) {
	SigSpec D = ff->getPort(ID(D));
	SigSpec Q = pm.sigmap(ff->getPort(ID(Q)));
	if (!A.empty())
	A.replace(Q, D);
	if (rstmux) {
	SigSpec Y = rstmux->getPort(ID(Y));
	SigSpec AB = rstmux->getPort(rstpol ? ID(A) : ID(B));
	if (!A.empty())
	A.replace(Y, AB);
	if (rstport != IdString()) {
	SigSpec S = rstmux->getPort(ID(S));
	cell->setPort(rstport, rstpol ? S : pm.module->Not(NEW_ID, S));
	}
	}
	else if (rstport != IdString())
	cell->setPort(rstport, State::S0);
	if (cemux) {
	SigSpec Y = cemux->getPort(ID(Y));
	SigSpec BA = cemux->getPort(cepol ? ID(B) : ID(A));
	SigSpec S = cemux->getPort(ID(S));
	if (!A.empty())
	A.replace(Y, BA);
	cell->setPort(ceport, cepol ? S : pm.module->Not(NEW_ID, S));
	}
	else
	cell->setPort(ceport, State::S1);

	for (auto c : Q.chunks()) {
	auto it = c.wire->attributes.find(ID(init));
	if (it == c.wire->attributes.end())
	continue;
	for (int i = c.offset; i < c.offset+c.width; i++) {
	log_assert(it->second[i] == State::S0 \|\| it->second[i] == State::Sx);
	it->second[i] = State::Sx;
	}
	}
	};

	if (st.ffA2) {
	SigSpec A = cell->getPort(ID(A));
	f(A, st.ffA2, st.ffA2cemux, st.ffA2cepol, ID(CEA2), st.ffA2rstmux, st.ffArstpol, ID(RSTA));
	if (st.ffA1) {
	f(A, st.ffA1, st.ffA1cemux, st.ffA1cepol, ID(CEA1), st.ffA1rstmux, st.ffArstpol, IdString());
	cell->setParam(ID(AREG), 2);
	cell->setParam(ID(ACASCREG), 2);
	}
	else {
	cell->setParam(ID(AREG), 1);
	cell->setParam(ID(ACASCREG), 1);
	}
	pm.add_siguser(A, cell);
	cell->setPort(ID(A), A);
	}
	if (st.ffB2) {
	SigSpec B = cell->getPort(ID(B));
	f(B, st.ffB2, st.ffB2cemux, st.ffB2cepol, ID(CEB2), st.ffB2rstmux, st.ffBrstpol, ID(RSTB));
	if (st.ffB1) {
	f(B, st.ffB1, st.ffB1cemux, st.ffB1cepol, ID(CEB1), st.ffB1rstmux, st.ffBrstpol, IdString());
	cell->setParam(ID(BREG), 2);
	cell->setParam(ID(BCASCREG), 2);
	}
	else {
	cell->setParam(ID(BREG), 1);
	cell->setParam(ID(BCASCREG), 1);
	}
	pm.add_siguser(B, cell);
	cell->setPort(ID(B), B);
	}
	if (st.ffD) {
	SigSpec D = cell->getPort(ID(D));
	f(D, st.ffD, st.ffDcemux, st.ffDcepol, ID(CED), st.ffDrstmux, st.ffDrstpol, ID(RSTD));
	pm.add_siguser(D, cell);
	cell->setPort(ID(D), D);
	cell->setParam(ID(DREG), 1);
	}
	if (st.ffM) {
	SigSpec M; // unused
	f(M, st.ffM, st.ffMcemux, st.ffMcepol, ID(CEM), st.ffMrstmux, st.ffMrstpol, ID(RSTM));
	st.ffM->connections_.at(ID(Q)).replace(st.sigM, pm.module->addWire(NEW_ID, GetSize(st.sigM)));
	cell->setParam(ID(MREG), State::S1);
	}
	if (st.ffP) {
	SigSpec P; // unused
	f(P, st.ffP, st.ffPcemux, st.ffPcepol, ID(CEP), st.ffPrstmux, st.ffPrstpol, ID(RSTP));
	st.ffP->connections_.at(ID(Q)).replace(st.sigP, pm.module->addWire(NEW_ID, GetSize(st.sigP)));
	cell->setParam(ID(PREG), State::S1);
	}

	log(" clock: %s (%s)", log_signal(st.clock), "posedge");

	if (st.ffA2) {
	log(" ffA2:%s", log_id(st.ffA2));
	if (st.ffA1)
	log(" ffA1:%s", log_id(st.ffA1));
	}

	if (st.ffAD)
	log(" ffAD:%s", log_id(st.ffAD));

	if (st.ffB2) {
	log(" ffB2:%s", log_id(st.ffB2));
	if (st.ffB1)
	log(" ffB1:%s", log_id(st.ffB1));
	}

	if (st.ffD)
	log(" ffD:%s", log_id(st.ffD));

	if (st.ffM)
	log(" ffM:%s", log_id(st.ffM));

	if (st.ffP)
	log(" ffP:%s", log_id(st.ffP));
	}
	log("\n");

	SigSpec P = st.sigP;
	if (GetSize(P) < 48)
	P.append(pm.module->addWire(NEW_ID, 48-GetSize(P)));
	cell->setPort(ID(P), P);

	pm.blacklist(cell);
	}

	void xilinx_dsp_packC(xilinx_dsp_CREG_pm &pm)
	{
	auto &st = pm.st_xilinx_dsp_packC;

	log_debug("Analysing %s.%s for Xilinx DSP packing (CREG).\n", log_id(pm.module), log_id(st.dsp));
	log_debug("ffC: %s %s %s\n", log_id(st.ffC, "--"), log_id(st.ffCcemux, "--"), log_id(st.ffCrstmux, "--"));

	Cell *cell = st.dsp;

	if (st.clock != SigBit())
	{
	cell->setPort(ID(CLK), st.clock);

	auto f = [&pm,cell](SigSpec &A, Cell* ff, Cell* cemux, bool cepol, IdString ceport, Cell* rstmux, bool rstpol, IdString rstport) {
	SigSpec D = ff->getPort(ID(D));
	SigSpec Q = pm.sigmap(ff->getPort(ID(Q)));
	if (!A.empty())
	A.replace(Q, D);
	if (rstmux) {
	SigSpec Y = rstmux->getPort(ID(Y));
	SigSpec AB = rstmux->getPort(rstpol ? ID(A) : ID(B));
	if (!A.empty())
	A.replace(Y, AB);
	if (rstport != IdString()) {
	SigSpec S = rstmux->getPort(ID(S));
	cell->setPort(rstport, rstpol ? S : pm.module->Not(NEW_ID, S));
	}
	}
	else if (rstport != IdString())
	cell->setPort(rstport, State::S0);
	if (cemux) {
	SigSpec Y = cemux->getPort(ID(Y));
	SigSpec BA = cemux->getPort(cepol ? ID(B) : ID(A));
	SigSpec S = cemux->getPort(ID(S));
	if (!A.empty())
	A.replace(Y, BA);
	cell->setPort(ceport, cepol ? S : pm.module->Not(NEW_ID, S));
	}
	else
	cell->setPort(ceport, State::S1);

	for (auto c : Q.chunks()) {
	auto it = c.wire->attributes.find(ID(init));
	if (it == c.wire->attributes.end())
	continue;
	for (int i = c.offset; i < c.offset+c.width; i++) {
	log_assert(it->second[i] == State::S0 \|\| it->second[i] == State::Sx);
	it->second[i] = State::Sx;
	}
	}
	};

	if (st.ffC) {
	SigSpec C = cell->getPort(ID(C));
	f(C, st.ffC, st.ffCcemux, st.ffCcepol, ID(CEC), st.ffCrstmux, st.ffCrstpol, ID(RSTC));
	pm.add_siguser(C, cell);
	cell->setPort(ID(C), C);
	cell->setParam(ID(CREG), 1);
	}

	log(" clock: %s (%s)", log_signal(st.clock), "posedge");

	if (st.ffC)
	log(" ffC:%s", log_id(st.ffC));
	log("\n");
	}

	pm.blacklist(cell);
	}

	struct XilinxDspPass : public Pass {
	XilinxDspPass() : Pass("xilinx_dsp", "Xilinx: pack resources into DSPs") { }
	void help() YS_OVERRIDE
	{
	// \|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|
	log("\n");
	log(" xilinx_dsp [options] [selection]\n");
	log("\n");
	log("Pack input registers (A2, A1, B2, B1, C, D, AD; with optional enable/reset),\n");
	log("pipeline registers (M; with optional enable/reset), output registers (P; with\n");
	log("optional enable/reset), pre-adder and/or post-adder into Xilinx DSP resources.\n");
	log("\n");
	log("Multiply-accumulate operations using the post-adder with feedback on the 'C'\n");
	log("input will be folded into the DSP. In this scenario only, the 'C' input can be\n");
	log("used to override the current accumulation result with a new value, which will\n");
	log("be added to the multiplier result to form the next accumulation result.\n");
	log("\n");
	log("Use of the dedicated 'PCOUT' -> 'PCIN' cascade path is detected for 'P' -> 'C'\n");
	log("connections (optionally, where 'P' is right-shifted by 17-bits and used as an\n");
	log("input to the post-adder -- a pattern common for summing partial products to\n");
	log("implement wide multipliers). Limited support also exists for similar cascading\n");
	log("for A and B using '[AB]COUT' -> '[AB]CIN'. Currently, cascade chains are limited\n");
	log("to a maximum length of 20 cells, corresponding to the smallest Xilinx 7 Series\n");
	log("device.\n");
	log("\n");
	log("\n");
	log("Experimental feature: addition/subtractions less than 12 or 24 bits with the\n");
	log("'(* use_dsp=\"simd\" *)' attribute attached to the output wire or attached to\n");
	log("the add/subtract operator will cause those operations to be implemented using\n");
	log("the 'SIMD' feature of DSPs.\n");
	log("\n");
	log("Experimental feature: the presence of a `$ge' cell attached to the registered\n");
	log("P output implementing the operation \"(P >= <power-of-2>)\" will be transformed\n");
	log("into using the DSP48E1's pattern detector feature for overflow detection.\n");
	log("\n");
	}
	void execute(std::vector<std::string> args, RTLIL::Design *design) YS_OVERRIDE
	{
	log_header(design, "Executing XILINX_DSP pass (pack resources into DSPs).\n");

	size_t argidx;
	for (argidx = 1; argidx < args.size(); argidx++)
	{
	// if (args[argidx] == "-singleton") {
	// singleton_mode = true;
	// continue;
	// }
	break;
	}
	extra_args(args, argidx, design);

	for (auto module : design->selected_modules()) {
	// Experimental feature: pack $add/$sub cells with
	// (* use_dsp48="simd" *) into DSP48E1's using its
	// SIMD feature
	xilinx_simd_pack(module, module->selected_cells());

	// Match for all features ([ABDMP][12]?REG, pre-adder,
	// post-adder, pattern detector, etc.) except for CREG
	{
	xilinx_dsp_pm pm(module, module->selected_cells());
	pm.run_xilinx_dsp_pack(xilinx_dsp_pack);
	}
	// Separating out CREG packing is necessary since there
	// is no guarantee that the cell ordering corresponds
	// to the "expected" case (i.e. the order in which
	// they appear in the source) thus the possiblity
	// existed that a register got packed as a CREG into a
	// downstream DSP that should have otherwise been a
	// PREG of an upstream DSP that had not been visited
	// yet
	{
	xilinx_dsp_CREG_pm pm(module, module->selected_cells());
	pm.run_xilinx_dsp_packC(xilinx_dsp_packC);
	}
	// Lastly, identify and utilise PCOUT -> PCIN,
	// ACOUT -> ACIN, and BCOUT-> BCIN dedicated cascade
	// chains
	{
	xilinx_dsp_cascade_pm pm(module, module->selected_cells());
	pm.run_xilinx_dsp_cascade();
	}
	}
	}
	} XilinxDspPass;

	PRIVATE_NAMESPACE_END