/* * yosys -- Yosys Open SYnthesis Suite * * Copyright (C) 2012 Clifford Wolf * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. * */ #include "kernel/yosys.h" #include "kernel/sigtools.h" USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN typedef std::pair> LutData; // Compute a LUT implementing (select ^ select_inv) ? alt_data : data. Returns true if successful. bool merge_lut(LutData &result, const LutData &data, const LutData select, bool select_inv, SigBit alt_data, int max_lut_size) { // First, gather input signals -- insert new signals at the beginning // of the vector, so they don't disturb the likely-critical D LUT input // timings. result.second = data.second; // D lut inputs initially start at 0. int idx_data = 0; // Now add the control input LUT inputs. std::vector idx_sel; for (auto bit : select.second) { int idx = -1; for (int i = 0; i < GetSize(result.second); i++) if (result.second[i] == bit) idx = i; if (idx == -1) { idx = 0; // Insert new signal at the beginning and bump all indices. result.second.insert(result.second.begin(), bit); idx_data++; for (int &sidx : idx_sel) sidx++; } idx_sel.push_back(idx); } // Insert the Q signal, if any, to the slowest input -- it will have // no problem meeting timing. int idx_alt = -1; if (alt_data.wire) { // Check if we already have it. for (int i = 0; i < GetSize(result.second); i++) if (result.second[i] == alt_data) idx_alt = i; // If not, add it. if (idx_alt == -1) { idx_alt = 0; result.second.insert(result.second.begin(), alt_data); idx_data++; for (int &sidx : idx_sel) sidx++; } } // If LUT would be too large, bail. if (GetSize(result.second) > max_lut_size) return false; // Okay, we're doing it — compute the LUT mask. result.first = Const(0, 1 << GetSize(result.second)); for (int i = 0; i < GetSize(result.first); i++) { int sel_lut_idx = 0; for (int j = 0; j < GetSize(select.second); j++) if (i & 1 << idx_sel[j]) sel_lut_idx |= 1 << j; bool select_val = (select.first.bits[sel_lut_idx] == State::S1); bool new_bit; if (select_val ^ select_inv) { // Use alt_data. if (alt_data.wire) new_bit = (i & 1 << idx_alt) != 0; else new_bit = alt_data.data == State::S1; } else { // Use original LUT. int lut_idx = i >> idx_data & ((1 << GetSize(data.second)) - 1); new_bit = data.first.bits[lut_idx] == State::S1; } result.first.bits[i] = new_bit ? State::S1 : State::S0; } return true; } struct XilinxDffOptPass : public Pass { XilinxDffOptPass() : Pass("xilinx_dffopt", "Xilinx: optimize FF control signal usage") { } void help() YS_OVERRIDE { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" xilinx_dffopt [options] [selection]\n"); log("\n"); log("Converts hardware clock enable and set/reset signals on FFs to emulation\n"); log("using LUTs, if doing so would improve area. Operates on post-techmap Xilinx\n"); log("cells (LUT*, FD*).\n"); log("\n"); log(" -lut4\n"); log(" Assume a LUT4-based device (instead of a LUT6-based device).\n"); log("\n"); } void execute(std::vector args, RTLIL::Design *design) YS_OVERRIDE { log_header(design, "Executing XILINX_DFFOPT pass (optimize FF control signal usage).\n"); size_t argidx; int max_lut_size = 6; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-lut4") { max_lut_size = 4; continue; } break; } extra_args(args, argidx, design); for (auto module : design->selected_modules()) { log("Optimizing FFs in %s.\n", log_id(module)); SigMap sigmap(module); dict> bit_to_lut; dict bit_uses; // Gather LUTs. for (auto cell : module->selected_cells()) { for (auto port : cell->connections()) for (auto bit : port.second) bit_uses[sigmap(bit)]++; if (cell->get_bool_attribute(ID::keep)) continue; if (cell->type == ID(INV)) { SigBit sigout = sigmap(cell->getPort(ID::O)); SigBit sigin = sigmap(cell->getPort(ID::I)); bit_to_lut[sigout] = make_pair(LutData(Const(1, 2), {sigin}), cell); } else if (cell->type.in(ID(LUT1), ID(LUT2), ID(LUT3), ID(LUT4), ID(LUT5), ID(LUT6))) { SigBit sigout = sigmap(cell->getPort(ID::O)); const Const &init = cell->getParam(ID::INIT); std::vector sigin; sigin.push_back(sigmap(cell->getPort(ID(I0)))); if (cell->type == ID(LUT1)) goto lut_sigin_done; sigin.push_back(sigmap(cell->getPort(ID(I1)))); if (cell->type == ID(LUT2)) goto lut_sigin_done; sigin.push_back(sigmap(cell->getPort(ID(I2)))); if (cell->type == ID(LUT3)) goto lut_sigin_done; sigin.push_back(sigmap(cell->getPort(ID(I3)))); if (cell->type == ID(LUT4)) goto lut_sigin_done; sigin.push_back(sigmap(cell->getPort(ID(I4)))); if (cell->type == ID(LUT5)) goto lut_sigin_done; sigin.push_back(sigmap(cell->getPort(ID(I5)))); lut_sigin_done: bit_to_lut[sigout] = make_pair(LutData(init, sigin), cell); } } for (auto wire : module->wires()) if (wire->port_output || wire->port_input) for (int i = 0; i < GetSize(wire); i++) bit_uses[sigmap(SigBit(wire, i))]++; // Iterate through FFs. for (auto cell : module->selected_cells()) { bool has_s = false, has_r = false; if (cell->type.in(ID(FDCE), ID(FDPE), ID(FDCPE), ID(FDCE_1), ID(FDPE_1), ID(FDCPE_1))) { // Async reset. } else if (cell->type.in(ID(FDRE), ID(FDRE_1))) { has_r = true; } else if (cell->type.in(ID(FDSE), ID(FDSE_1))) { has_s = true; } else if (cell->type.in(ID(FDRSE), ID(FDRSE_1))) { has_r = true; has_s = true; } else { // Not a FF. continue; } if (cell->get_bool_attribute(ID::keep)) continue; // Don't bother if D has more than one use. SigBit sig_D = sigmap(cell->getPort(ID::D)); if (bit_uses[sig_D] > 2) continue; // Find the D LUT. auto it_D = bit_to_lut.find(sig_D); if (it_D == bit_to_lut.end()) continue; LutData lut_d = it_D->second.first; Cell *cell_d = it_D->second.second; if (cell->hasParam(ID(IS_D_INVERTED)) && cell->getParam(ID(IS_D_INVERTED)).as_bool()) { // Flip all bits in the LUT. for (int i = 0; i < GetSize(lut_d.first); i++) lut_d.first.bits[i] = (lut_d.first.bits[i] == State::S1) ? State::S0 : State::S1; } LutData lut_d_post_ce; LutData lut_d_post_s; LutData lut_d_post_r; bool worthy_post_ce = false; bool worthy_post_s = false; bool worthy_post_r = false; // First, unmap CE. SigBit sig_Q = sigmap(cell->getPort(ID::Q)); SigBit sig_CE = sigmap(cell->getPort(ID(CE))); LutData lut_ce = LutData(Const(2, 2), {sig_CE}); auto it_CE = bit_to_lut.find(sig_CE); if (it_CE != bit_to_lut.end()) lut_ce = it_CE->second.first; if (sig_CE.wire) { // Merge CE LUT and D LUT into one. If it cannot be done, nothing to do about this FF. if (!merge_lut(lut_d_post_ce, lut_d, lut_ce, true, sig_Q, max_lut_size)) continue; // If this gets rid of a CE LUT, it's worth it. If not, it still may be worth it, if we can remove set/reset as well. if (it_CE != bit_to_lut.end()) worthy_post_ce = true; } else if (sig_CE.data != State::S1) { // Strange. Should not happen in a reasonable flow, so bail. continue; } else { lut_d_post_ce = lut_d; } // Second, unmap S, if any. lut_d_post_s = lut_d_post_ce; if (has_s) { SigBit sig_S = sigmap(cell->getPort(ID::S)); LutData lut_s = LutData(Const(2, 2), {sig_S}); bool inv_s = cell->hasParam(ID(IS_S_INVERTED)) && cell->getParam(ID(IS_S_INVERTED)).as_bool(); auto it_S = bit_to_lut.find(sig_S); if (it_S != bit_to_lut.end()) lut_s = it_S->second.first; if (sig_S.wire) { // Merge S LUT and D LUT into one. If it cannot be done, try to at least merge CE. if (!merge_lut(lut_d_post_s, lut_d_post_ce, lut_s, inv_s, SigBit(State::S1), max_lut_size)) goto unmap; // If this gets rid of an S LUT, it's worth it. if (it_S != bit_to_lut.end()) worthy_post_s = true; } else if (sig_S.data != (inv_s ? State::S1 : State::S0)) { // Strange. Should not happen in a reasonable flow, so bail. continue; } } // Third, unmap R, if any. lut_d_post_r = lut_d_post_s; if (has_r) { SigBit sig_R = sigmap(cell->getPort(ID::R)); LutData lut_r = LutData(Const(2, 2), {sig_R}); bool inv_r = cell->hasParam(ID(IS_R_INVERTED)) && cell->getParam(ID(IS_R_INVERTED)).as_bool(); auto it_R = bit_to_lut.find(sig_R); if (it_R != bit_to_lut.end()) lut_r = it_R->second.first; if (sig_R.wire) { // Merge R LUT and D LUT into one. If it cannot be done, try to at least merge CE/S. if (!merge_lut(lut_d_post_r, lut_d_post_s, lut_r, inv_r, SigBit(State::S0), max_lut_size)) goto unmap; // If this gets rid of an S LUT, it's worth it. if (it_R != bit_to_lut.end()) worthy_post_r = true; } else if (sig_R.data != (inv_r ? State::S1 : State::S0)) { // Strange. Should not happen in a reasonable flow, so bail. continue; } } unmap: LutData final_lut; if (worthy_post_r) { final_lut = lut_d_post_r; log(" Merging R LUT for %s/%s (%d -> %d)\n", log_id(cell), log_id(sig_Q.wire), GetSize(lut_d.second), GetSize(final_lut.second)); } else if (worthy_post_s) { final_lut = lut_d_post_s; log(" Merging S LUT for %s/%s (%d -> %d)\n", log_id(cell), log_id(sig_Q.wire), GetSize(lut_d.second), GetSize(final_lut.second)); } else if (worthy_post_ce) { final_lut = lut_d_post_ce; log(" Merging CE LUT for %s/%s (%d -> %d)\n", log_id(cell), log_id(sig_Q.wire), GetSize(lut_d.second), GetSize(final_lut.second)); } else { // Nothing to do here. continue; } // Okay, we're doing it. Unmap ports. if (worthy_post_r) { cell->unsetParam(ID(IS_R_INVERTED)); cell->setPort(ID::R, Const(0, 1)); } if (has_s && (worthy_post_r || worthy_post_s)) { cell->unsetParam(ID(IS_S_INVERTED)); cell->setPort(ID::S, Const(0, 1)); } cell->setPort(ID(CE), Const(1, 1)); cell->unsetParam(ID(IS_D_INVERTED)); // Create the new LUT. Cell *lut_cell = 0; switch (GetSize(final_lut.second)) { case 1: lut_cell = module->addCell(NEW_ID, ID(LUT1)); break; case 2: lut_cell = module->addCell(NEW_ID, ID(LUT2)); break; case 3: lut_cell = module->addCell(NEW_ID, ID(LUT3)); break; case 4: lut_cell = module->addCell(NEW_ID, ID(LUT4)); break; case 5: lut_cell = module->addCell(NEW_ID, ID(LUT5)); break; case 6: lut_cell = module->addCell(NEW_ID, ID(LUT6)); break; default: log_assert(!"unknown lut size"); } lut_cell->attributes = cell_d->attributes; Wire *lut_out = module->addWire(NEW_ID); lut_cell->setParam(ID::INIT, final_lut.first); cell->setPort(ID::D, lut_out); lut_cell->setPort(ID::O, lut_out); lut_cell->setPort(ID(I0), final_lut.second[0]); if (GetSize(final_lut.second) >= 2) lut_cell->setPort(ID(I1), final_lut.second[1]); if (GetSize(final_lut.second) >= 3) lut_cell->setPort(ID(I2), final_lut.second[2]); if (GetSize(final_lut.second) >= 4) lut_cell->setPort(ID(I3), final_lut.second[3]); if (GetSize(final_lut.second) >= 5) lut_cell->setPort(ID(I4), final_lut.second[4]); if (GetSize(final_lut.second) >= 6) lut_cell->setPort(ID(I5), final_lut.second[5]); } } } } XilinxDffOptPass; PRIVATE_NAMESPACE_END