/* * yosys -- Yosys Open SYnthesis Suite * * Copyright (C) 2020 Marcelina Kościelnicka * * 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/ffinit.h" #include "kernel/ff.h" USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN enum FfType { FF_DFF, FF_DFFE, FF_ADFF, FF_ADFFE, FF_ALDFF, FF_ALDFFE, FF_DFFSR, FF_DFFSRE, FF_SDFF, FF_SDFFE, FF_SDFFCE, FF_RLATCH, FF_SR, FF_DLATCH, FF_ADLATCH, FF_DLATCHSR, NUM_FFTYPES, }; enum FfNeg { NEG_CE = 0x1, NEG_R = 0x2, NEG_S = 0x4, NEG_L = 0x8, NEG_C = 0x10, NUM_NEG = 0x20, }; enum FfInit { INIT_X = 0x1, INIT_0 = 0x2, INIT_1 = 0x4, INIT_X_R0 = 0x10, INIT_0_R0 = 0x20, INIT_1_R0 = 0x40, INIT_X_R1 = 0x100, INIT_0_R1 = 0x200, INIT_1_R1 = 0x400, }; struct DffLegalizePass : public Pass { DffLegalizePass() : Pass("dfflegalize", "convert FFs to types supported by the target") { } void help() override { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" dfflegalize [options] [selection]\n"); log("\n"); log("Converts FFs to types supported by the target.\n"); log("\n"); log(" -cell \n"); log(" specifies a supported group of FF cells. \n"); log(" is a yosys internal fine cell name, where ? characters can be\n"); log(" as a wildcard matching any character. specifies\n"); log(" which initialization values these FF cells can support, and can\n"); log(" be one of:\n"); log("\n"); log(" - x (no init value supported)\n"); log(" - 0\n"); log(" - 1\n"); log(" - r (init value has to match reset value, only for some FF types)\n"); log(" - 01 (both 0 and 1 supported).\n"); log("\n"); log(" -mince \n"); log(" specifies a minimum number of FFs that should be using any given\n"); log(" clock enable signal. If a clock enable signal doesn't meet this\n"); log(" threshold, it is unmapped into soft logic.\n"); log("\n"); log(" -minsrst \n"); log(" specifies a minimum number of FFs that should be using any given\n"); log(" sync set/reset signal. If a sync set/reset signal doesn't meet this\n"); log(" threshold, it is unmapped into soft logic.\n"); log("\n"); log("The following cells are supported by this pass (ie. will be ingested,\n"); log("and can be specified as allowed targets):\n"); log("\n"); log("- $_DFF_[NP]_\n"); log("- $_DFFE_[NP][NP]_\n"); log("- $_DFF_[NP][NP][01]_\n"); log("- $_DFFE_[NP][NP][01][NP]_\n"); log("- $_ALDFF_[NP][NP]_\n"); log("- $_ALDFFE_[NP][NP][NP]_\n"); log("- $_DFFSR_[NP][NP][NP]_\n"); log("- $_DFFSRE_[NP][NP][NP][NP]_\n"); log("- $_SDFF_[NP][NP][01]_\n"); log("- $_SDFFE_[NP][NP][01][NP]_\n"); log("- $_SDFFCE_[NP][NP][01][NP]_\n"); log("- $_SR_[NP][NP]_\n"); log("- $_DLATCH_[NP]_\n"); log("- $_DLATCH_[NP][NP][01]_\n"); log("- $_DLATCHSR_[NP][NP][NP]_\n"); log("\n"); log("The following transformations are performed by this pass:\n"); log("\n"); log("- upconversion from a less capable cell to a more capable cell, if the less\n"); log(" capable cell is not supported (eg. dff -> dffe, or adff -> dffsr)\n"); log("- unmapping FFs with clock enable (due to unsupported cell type or -mince)\n"); log("- unmapping FFs with sync reset (due to unsupported cell type or -minsrst)\n"); log("- adding inverters on the control pins (due to unsupported polarity)\n"); log("- adding inverters on the D and Q pins and inverting the init/reset values\n"); log(" (due to unsupported init or reset value)\n"); log("- converting sr into adlatch (by tying D to 1 and using E as set input)\n"); log("- emulating unsupported dffsr cell by adff + adff + sr + mux\n"); log("- emulating unsupported dlatchsr cell by adlatch + adlatch + sr + mux\n"); log("- emulating adff when the (reset, init) value combination is unsupported by\n"); log(" dff + adff + dlatch + mux\n"); log("- emulating adlatch when the (reset, init) value combination is unsupported by\n"); log("- dlatch + adlatch + dlatch + mux\n"); log("If the pass is unable to realize a given cell type (eg. adff when only plain dff\n"); log("is available), an error is raised.\n"); } // Table of all supported cell types. // First index in the array is one of the FF_* values, second // index is the set of negative-polarity inputs (OR of NEG_* // values), and the value is the set of supported init values // (OR of INIT_* values). int supported_cells_neg[NUM_FFTYPES][NUM_NEG]; // Aggregated table ignoring signal polarity. int supported_cells[NUM_FFTYPES]; // Aggregated for all *dff* cells. int supported_dff; // Aggregated for all *dffe* cells. int supported_dffe; // Aggregated for all dffsr* cells. int supported_dffsr; // Aggregated for all aldff cells. int supported_aldff; // Aggregated for all aldffe cells. int supported_aldffe; // Aggregated for all adff* cells and trivial emulations. int supported_adff; // Aggregated for all adffe* cells and trivial emulations. int supported_adffe; // Aggregated for all sdff* cells. int supported_sdff; // Aggregated for all ways to obtain a SR latch. int supported_sr; int supported_sr_plain; // Aggregated for all *dlatch* cells. int supported_dlatch; int supported_dlatch_plain; // Aggregated for all ways to obtain an R latch. int supported_rlatch; // Aggregated for all adlatch cells and trivial emulations. int supported_adlatch; int mince; int minsrst; dict ce_used; dict srst_used; SigMap sigmap; FfInitVals initvals; int flip_initmask(int mask) { int res = mask & INIT_X; if (mask & INIT_0) res |= INIT_1; if (mask & INIT_1) res |= INIT_0; if (mask & INIT_X_R0) res |= INIT_X_R1; if (mask & INIT_0_R0) res |= INIT_1_R1; if (mask & INIT_1_R0) res |= INIT_0_R1; if (mask & INIT_X_R1) res |= INIT_X_R0; if (mask & INIT_0_R1) res |= INIT_1_R0; if (mask & INIT_1_R1) res |= INIT_0_R0; return res; } int get_ff_type(const FfData &ff) { if (ff.has_clk) { if (ff.has_sr) { return ff.has_ce ? FF_DFFSRE : FF_DFFSR; } else if (ff.has_arst) { return ff.has_ce ? FF_ADFFE : FF_ADFF; } else if (ff.has_aload) { return ff.has_ce ? FF_ALDFFE : FF_ALDFF; } else if (ff.has_srst) { if (ff.has_ce) return ff.ce_over_srst ? FF_SDFFCE : FF_SDFFE; else return FF_SDFF; } else { return ff.has_ce ? FF_DFFE : FF_DFF; } } else { if (ff.has_aload) { if (ff.has_sr) return FF_DLATCHSR; else if (ff.has_arst) return FF_ADLATCH; else return FF_DLATCH; } else { if (ff.has_sr) { return FF_SR; } else if (ff.has_arst) { return FF_RLATCH; } else { log_assert(0); return 0; } } } } int get_initmask(FfData &ff) { int res = 0; if (ff.val_init[0] == State::S0) res = INIT_0; else if (ff.val_init[0] == State::S1) res = INIT_1; else res = INIT_X; if (ff.has_arst) { if (ff.val_arst[0] == State::S0) res <<= 4; else if (ff.val_arst[0] == State::S1) res <<= 8; } else if (ff.has_srst) { if (ff.val_srst[0] == State::S0) res <<= 4; else if (ff.val_srst[0] == State::S1) res <<= 8; } return res; } void fail_ff(const FfData &ff, const char *reason) { log_error("FF %s.%s (type %s) cannot be legalized: %s\n", log_id(ff.module->name), log_id(ff.cell->name), log_id(ff.cell->type), reason); } bool try_flip(FfData &ff, int supported_mask) { int initmask = get_initmask(ff); if (supported_mask & initmask) return true; if (supported_mask & flip_initmask(initmask)) { ff.flip_bits({0}); return true; } return false; } void emulate_split_init_arst(FfData &ff) { ff.remove(); FfData ff_dff(ff.module, &initvals, NEW_ID); ff_dff.width = ff.width; ff_dff.has_aload = ff.has_aload; ff_dff.sig_aload = ff.sig_aload; ff_dff.pol_aload = ff.pol_aload; ff_dff.sig_ad = ff.sig_ad; ff_dff.has_clk = ff.has_clk; ff_dff.sig_clk = ff.sig_clk; ff_dff.pol_clk = ff.pol_clk; ff_dff.sig_d = ff.sig_d; ff_dff.has_ce = ff.has_ce; ff_dff.sig_ce = ff.sig_ce; ff_dff.pol_ce = ff.pol_ce; ff_dff.sig_q = ff.module->addWire(NEW_ID, ff.width); ff_dff.val_init = ff.val_init; ff_dff.is_fine = ff.is_fine; FfData ff_adff(ff.module, &initvals, NEW_ID); ff_adff.width = ff.width; ff_adff.has_aload = ff.has_aload; ff_adff.sig_aload = ff.sig_aload; ff_adff.pol_aload = ff.pol_aload; ff_adff.sig_ad = ff.sig_ad; ff_adff.has_clk = ff.has_clk; ff_adff.sig_clk = ff.sig_clk; ff_adff.pol_clk = ff.pol_clk; ff_adff.sig_d = ff.sig_d; ff_adff.has_ce = ff.has_ce; ff_adff.sig_ce = ff.sig_ce; ff_adff.pol_ce = ff.pol_ce; ff_adff.sig_q = ff.module->addWire(NEW_ID, ff.width); ff_adff.val_init = Const(State::Sx, ff.width); ff_adff.has_arst = true; ff_adff.sig_arst = ff.sig_arst; ff_adff.pol_arst = ff.pol_arst; ff_adff.val_arst = ff.val_arst; ff_adff.is_fine = ff.is_fine; FfData ff_sel(ff.module, &initvals, NEW_ID); ff_sel.width = 1; ff_sel.sig_q = ff.module->addWire(NEW_ID); ff_sel.has_arst = true; ff_sel.sig_arst = ff.sig_arst; ff_sel.pol_arst = ff.pol_arst; ff_sel.val_arst = State::S1; ff_sel.val_init = State::S0; ff_sel.is_fine = ff.is_fine; if (ff.is_fine) ff.module->addMuxGate(NEW_ID, ff_dff.sig_q, ff_adff.sig_q, ff_sel.sig_q, ff.sig_q); else ff.module->addMux(NEW_ID, ff_dff.sig_q, ff_adff.sig_q, ff_sel.sig_q, ff.sig_q); legalize_ff(ff_dff); legalize_ff(ff_adff); legalize_ff(ff_sel); } void emulate_split_set_clr(FfData &ff) { // No native DFFSR. However, if we can conjure // a SR latch and ADFF, it can still be emulated. int initmask = get_initmask(ff); int flipmask = flip_initmask(initmask); bool init_clr = true; bool init_set = true; State initsel = State::Sx; int supported_arst = ff.has_clk ? supported_adff : supported_adlatch; bool init_clr_ok = (supported_arst & initmask << 4) || (supported_arst & flipmask << 8); bool init_set_ok = (supported_arst & initmask << 8) || (supported_arst & flipmask << 4); if (init_clr_ok && init_set_ok && supported_sr) { // OK } else if (init_clr_ok && (supported_sr & INIT_0)) { init_set = false; initsel = State::S0; } else if (init_set_ok && (supported_sr & INIT_1)) { init_clr = false; initsel = State::S1; } else if (init_clr_ok && (supported_sr & INIT_1)) { init_set = false; initsel = State::S0; } else if (init_set_ok && (supported_sr & INIT_0)) { init_clr = false; initsel = State::S1; } else { if (ff.has_clk) { if (!supported_dffsr) fail_ff(ff, "dffs with async set and reset are not supported"); else fail_ff(ff, "initialized dffs with async set and reset are not supported"); } else { if (!supported_cells[FF_DLATCHSR]) fail_ff(ff, "dlatch with async set and reset are not supported"); else fail_ff(ff, "initialized dlatch with async set and reset are not supported"); } } // If we have to unmap enable anyway, do it before breakdown. if (ff.has_ce && !supported_cells[FF_ADFFE]) ff.unmap_ce(); log_warning("Emulating async set + reset with several FFs and a mux for %s.%s\n", log_id(ff.module->name), log_id(ff.cell->name)); log_assert(ff.width == 1); ff.remove(); FfData ff_clr(ff.module, &initvals, NEW_ID); ff_clr.width = ff.width; ff_clr.has_aload = ff.has_aload; ff_clr.sig_aload = ff.sig_aload; ff_clr.pol_aload = ff.pol_aload; ff_clr.sig_ad = ff.sig_ad; ff_clr.has_clk = ff.has_clk; ff_clr.sig_clk = ff.sig_clk; ff_clr.pol_clk = ff.pol_clk; ff_clr.sig_d = ff.sig_d; ff_clr.has_ce = ff.has_ce; ff_clr.sig_ce = ff.sig_ce; ff_clr.pol_ce = ff.pol_ce; ff_clr.has_arst = true; ff_clr.sig_arst = ff.sig_clr; ff_clr.pol_arst = ff.pol_clr; ff_clr.val_arst = Const(State::S0, ff.width); ff_clr.sig_q = ff.module->addWire(NEW_ID, ff.width); ff_clr.val_init = init_clr ? ff.val_init : Const(State::Sx, ff.width); ff_clr.is_fine = ff.is_fine; FfData ff_set(ff.module, &initvals, NEW_ID); ff_set.width = ff.width; ff_set.has_aload = ff.has_aload; ff_set.sig_aload = ff.sig_aload; ff_set.pol_aload = ff.pol_aload; ff_set.sig_ad = ff.sig_ad; ff_set.has_clk = ff.has_clk; ff_set.sig_clk = ff.sig_clk; ff_set.pol_clk = ff.pol_clk; ff_set.sig_d = ff.sig_d; ff_set.has_ce = ff.has_ce; ff_set.sig_ce = ff.sig_ce; ff_set.pol_ce = ff.pol_ce; ff_set.has_arst = true; ff_set.sig_arst = ff.sig_set; ff_set.pol_arst = ff.pol_set; ff_set.val_arst = Const(State::S1, ff.width); ff_set.sig_q = ff.module->addWire(NEW_ID, ff.width); ff_set.val_init = init_set ? ff.val_init : Const(State::Sx, ff.width); ff_set.is_fine = ff.is_fine; FfData ff_sel(ff.module, &initvals, NEW_ID); ff_sel.width = ff.width; ff_sel.has_sr = true; ff_sel.pol_clr = ff.pol_clr; ff_sel.pol_set = ff.pol_set; ff_sel.sig_clr = ff.sig_clr; ff_sel.sig_set = ff.sig_set; ff_sel.sig_q = ff.module->addWire(NEW_ID, ff.width); ff_sel.val_init = Const(initsel, ff.width); ff_sel.is_fine = ff.is_fine; if (!ff.is_fine) ff.module->addMux(NEW_ID, ff_clr.sig_q, ff_set.sig_q, ff_sel.sig_q, ff.sig_q); else ff.module->addMuxGate(NEW_ID, ff_clr.sig_q, ff_set.sig_q, ff_sel.sig_q, ff.sig_q); legalize_ff(ff_clr); legalize_ff(ff_set); legalize_ff(ff_sel); } void legalize_dff(FfData &ff) { if (!try_flip(ff, supported_dff)) { if (!supported_dff) fail_ff(ff, "D flip-flops are not supported"); else fail_ff(ff, "initialized D flip-flops are not supported"); } int initmask = get_initmask(ff); // Some DFF is supported with this init val. Just pick a type. if (ff.has_ce && !(supported_dffe & initmask)) { ff.unmap_ce(); } if (!ff.has_ce) { if (supported_cells[FF_DFF] & initmask) { legalize_finish(ff); return; } // Try adding a set or reset pin. if (supported_cells[FF_SDFF] & initmask) { ff.add_dummy_srst(); legalize_finish(ff); return; } if (supported_cells[FF_ADFF] & initmask) { ff.add_dummy_arst(); legalize_finish(ff); return; } // Try adding async load. if (supported_cells[FF_ALDFF] & initmask) { ff.add_dummy_aload(); legalize_finish(ff); return; } // Try adding both. if (supported_cells[FF_DFFSR] & initmask) { ff.add_dummy_sr(); legalize_finish(ff); return; } // Nope. Will need to add enable and go the DFFE route. ff.add_dummy_ce(); } if (supported_cells[FF_DFFE] & initmask) { legalize_finish(ff); return; } // Try adding a set or reset pin. if (supported_cells[FF_SDFFCE] & initmask) { ff.add_dummy_srst(); ff.ce_over_srst = true; legalize_finish(ff); return; } if (supported_cells[FF_SDFFE] & initmask) { ff.add_dummy_srst(); legalize_finish(ff); return; } if (supported_cells[FF_ADFFE] & initmask) { ff.add_dummy_arst(); legalize_finish(ff); return; } if (supported_cells[FF_ALDFFE] & initmask) { ff.add_dummy_aload(); legalize_finish(ff); return; } // Try adding both. if (supported_cells[FF_DFFSRE] & initmask) { ff.add_dummy_sr(); legalize_finish(ff); return; } log_assert(0); } void legalize_sdffce(FfData &ff) { if (!try_flip(ff, supported_cells[FF_SDFFCE] | supported_cells[FF_SDFFE])) { ff.unmap_srst(); legalize_dff(ff); return; } int initmask = get_initmask(ff); if (supported_cells[FF_SDFFCE] & initmask) { // OK } else if (supported_cells[FF_SDFFE] & initmask) { ff.convert_ce_over_srst(false); } else { log_assert(0); } legalize_finish(ff); } void legalize_sdff(FfData &ff) { if (!try_flip(ff, supported_sdff)) { ff.unmap_srst(); legalize_dff(ff); return; } int initmask = get_initmask(ff); if (!ff.has_ce) { if (supported_cells[FF_SDFF] & initmask) { // OK } else if (supported_cells[FF_SDFFE] & initmask) { ff.add_dummy_ce(); } else if (supported_cells[FF_SDFFCE] & initmask) { ff.add_dummy_ce(); ff.ce_over_srst = true; } else { log_assert(0); } } else { log_assert(!ff.ce_over_srst); if (supported_cells[FF_SDFFE] & initmask) { // OK } else if (supported_cells[FF_SDFFCE] & initmask) { ff.convert_ce_over_srst(true); } else if (supported_cells[FF_SDFF] & initmask) { ff.unmap_ce(); } else { log_assert(0); } } legalize_finish(ff); } void legalize_adff(FfData &ff) { if (!try_flip(ff, supported_adff)) { if (!supported_adff) fail_ff(ff, "dffs with async set or reset are not supported"); if (!(supported_dff & (INIT_0 | INIT_1))) fail_ff(ff, "initialized dffs are not supported"); // If we got here, initialized dff is supported, but not this // particular reset+init combination (nor its negation). // The only hope left is breaking down to adff + dff + dlatch + mux. if (!((supported_rlatch) & (INIT_0_R1 | INIT_1_R0))) fail_ff(ff, "unsupported initial value and async reset value combination"); // If we have to unmap enable anyway, do it before breakdown. if (ff.has_ce && !supported_cells[FF_ADFFE]) ff.unmap_ce(); if (ff.cell) log_warning("Emulating mismatched async reset and init with several FFs and a mux for %s.%s\n", log_id(ff.module->name), log_id(ff.cell->name)); emulate_split_init_arst(ff); return; } int initmask = get_initmask(ff); if (ff.has_ce && !(supported_adffe & initmask)) { ff.unmap_ce(); } if (!ff.has_ce) { if (supported_cells[FF_ADFF] & initmask) { legalize_finish(ff); return; } // Try converting to async load. if (supported_cells[FF_ALDFF] & initmask) { ff.arst_to_aload(); legalize_finish(ff); return; } // Try convertint to SR. if (supported_cells[FF_DFFSR] & initmask) { ff.arst_to_sr(); legalize_finish(ff); return; } ff.add_dummy_ce(); } if (supported_cells[FF_ADFFE] & initmask) { legalize_finish(ff); return; } // Try converting to async load. if (supported_cells[FF_ALDFFE] & initmask) { ff.arst_to_aload(); legalize_finish(ff); return; } // Try convertint to SR. if (supported_cells[FF_DFFSRE] & initmask) { ff.arst_to_sr(); legalize_finish(ff); return; } log_assert(0); } void legalize_aldff(FfData &ff) { if (!try_flip(ff, supported_aldff)) { ff.aload_to_sr(); emulate_split_set_clr(ff); return; } int initmask = get_initmask(ff); if (ff.has_ce && !(supported_aldffe & initmask)) { ff.unmap_ce(); } if (!ff.has_ce) { if (supported_cells[FF_ALDFF] & initmask) { legalize_finish(ff); return; } if (supported_cells[FF_DFFSR] & initmask) { ff.aload_to_sr(); legalize_finish(ff); return; } ff.add_dummy_ce(); } if (supported_cells[FF_ALDFFE] & initmask) { legalize_finish(ff); return; } if (supported_cells[FF_DFFSRE] & initmask) { ff.aload_to_sr(); legalize_finish(ff); return; } log_assert(0); } void legalize_dffsr(FfData &ff) { if (!try_flip(ff, supported_dffsr)) { emulate_split_set_clr(ff); return; } int initmask = get_initmask(ff); if (ff.has_ce && !(supported_cells[FF_DFFSRE] & initmask)) { ff.unmap_ce(); } if (!ff.has_ce) { if (supported_cells[FF_DFFSR] & initmask) { legalize_finish(ff); return; } ff.add_dummy_ce(); } log_assert(supported_cells[FF_DFFSRE] & initmask); legalize_finish(ff); } void legalize_dlatch(FfData &ff) { if (!try_flip(ff, supported_dlatch)) { if (!supported_dlatch) fail_ff(ff, "D latches are not supported"); else fail_ff(ff, "initialized D latches are not supported"); } int initmask = get_initmask(ff); // Some DLATCH is supported with this init val. Just pick a type. if (supported_cells[FF_DLATCH] & initmask) { legalize_finish(ff); } else if (supported_cells[FF_ADLATCH] & initmask) { ff.add_dummy_arst(); legalize_finish(ff); } else if (supported_cells[FF_DLATCHSR] & initmask) { ff.add_dummy_sr(); legalize_finish(ff); } else if (supported_cells[FF_ALDFF] & initmask) { ff.add_dummy_clk(); legalize_finish(ff); } else if (supported_cells[FF_ALDFFE] & initmask) { ff.add_dummy_clk(); ff.add_dummy_ce(); legalize_finish(ff); } else if (supported_sr & initmask) { ff.aload_to_sr(); legalize_sr(ff); } else { log_assert(0); } } void legalize_adlatch(FfData &ff) { if (!try_flip(ff, supported_adlatch)) { if (!supported_adlatch) fail_ff(ff, "D latches with async set or reset are not supported"); if (!(supported_dlatch & (INIT_0 | INIT_1))) fail_ff(ff, "initialized D latches are not supported"); // If we got here, initialized dlatch is supported, but not this // particular reset+init combination (nor its negation). // The only hope left is breaking down to adlatch + dlatch + dlatch + mux. if (ff.cell) log_warning("Emulating mismatched async reset and init with several latches and a mux for %s.%s\n", log_id(ff.module->name), log_id(ff.cell->name)); ff.remove(); emulate_split_init_arst(ff); return; } int initmask = get_initmask(ff); if (supported_cells[FF_ADLATCH] & initmask) { // OK } else if (supported_cells[FF_DLATCHSR] & initmask) { ff.arst_to_sr(); } else { log_assert(0); } legalize_finish(ff); } void legalize_dlatchsr(FfData &ff) { if (!try_flip(ff, supported_cells[FF_DLATCHSR])) { emulate_split_set_clr(ff); return; } legalize_finish(ff); } void legalize_rlatch(FfData &ff) { if (!try_flip(ff, supported_rlatch)) { if (!supported_dlatch) fail_ff(ff, "D latches are not supported"); else fail_ff(ff, "initialized D latches are not supported"); } int initmask = get_initmask(ff); if (((supported_dlatch_plain & 7) * 0x111) & initmask) { ff.arst_to_aload(); legalize_dlatch(ff); } else if (supported_sr & initmask) { ff.arst_to_sr(); legalize_sr(ff); } else if (supported_adff & initmask) { ff.add_dummy_clk(); legalize_adff(ff); } else { log_assert(0); } } void legalize_sr(FfData &ff) { if (!try_flip(ff, supported_sr)) { if (!supported_sr) fail_ff(ff, "sr latches are not supported"); else fail_ff(ff, "initialized sr latches are not supported"); } int initmask = get_initmask(ff); if (supported_cells[FF_SR] & initmask) { // OK } else if (supported_cells[FF_DLATCHSR] & initmask) { // Upgrade to DLATCHSR. ff.add_dummy_aload(); } else if (supported_cells[FF_DFFSR] & initmask) { // Upgrade to DFFSR. ff.add_dummy_clk(); } else if (supported_cells[FF_DFFSRE] & initmask) { // Upgrade to DFFSRE. ff.add_dummy_clk(); ff.add_dummy_ce(); } else if (supported_cells[FF_ADLATCH] & (initmask << 4)) { ff.has_sr = false; ff.has_aload = true; ff.has_arst = true; ff.pol_arst = ff.pol_clr; ff.sig_arst = ff.sig_clr; ff.sig_aload = ff.sig_set; ff.pol_aload = ff.pol_set; ff.sig_ad = State::S1; ff.val_arst = State::S0; } else if (supported_cells[FF_ADLATCH] & (flip_initmask(initmask) << 8)) { ff.has_sr = false; ff.has_aload = true; ff.has_arst = true; ff.pol_arst = ff.pol_clr; ff.sig_arst = ff.sig_clr; ff.sig_aload = ff.sig_set; ff.pol_aload = ff.pol_set; ff.sig_ad = State::S0; ff.val_arst = State::S1; ff.remove_init(); Wire *new_q = ff.module->addWire(NEW_ID); if (ff.is_fine) ff.module->addNotGate(NEW_ID, new_q, ff.sig_q); else ff.module->addNot(NEW_ID, new_q, ff.sig_q); ff.sig_q = new_q; if (ff.val_init == State::S0) ff.val_init = State::S1; else if (ff.val_init == State::S1) ff.val_init = State::S0; } else { log_assert(0); } legalize_finish(ff); } void fixup_reset_x(FfData &ff, int supported) { for (int i = 0; i < ff.width; i++) { int mask; if (ff.val_init[i] == State::S0) mask = INIT_0; else if (ff.val_init[i] == State::S1) mask = INIT_1; else mask = INIT_X; if (ff.has_arst) { if (ff.val_arst[i] == State::Sx) { if (!(supported & (mask << 8))) ff.val_arst[i] = State::S0; if (!(supported & (mask << 4))) ff.val_arst[i] = State::S1; } } if (ff.has_srst) { if (ff.val_srst[i] == State::Sx) { if (!(supported & (mask << 8))) ff.val_srst[i] = State::S0; if (!(supported & (mask << 4))) ff.val_srst[i] = State::S1; } } } } void legalize_ff(FfData &ff) { if (ff.has_gclk) return; // TODO: consider supporting coarse as well. if (!ff.is_fine) return; if (mince && ff.has_ce && ff.sig_ce[0].wire && ce_used[ff.sig_ce[0]] < mince) ff.unmap_ce(); if (minsrst && ff.has_srst && ff.sig_srst[0].wire && srst_used[ff.sig_srst[0]] < minsrst) ff.unmap_srst(); if (ff.has_clk) { if (ff.has_sr) { legalize_dffsr(ff); } else if (ff.has_aload) { legalize_aldff(ff); } else if (ff.has_arst) { legalize_adff(ff); } else if (ff.has_srst) { if (ff.has_ce && ff.ce_over_srst) legalize_sdffce(ff); else legalize_sdff(ff); } else { legalize_dff(ff); } } else if (ff.has_aload) { if (ff.has_sr) { legalize_dlatchsr(ff); } else if (ff.has_arst) { legalize_adlatch(ff); } else { legalize_dlatch(ff); } } else { if (ff.has_sr) { legalize_sr(ff); } else if (ff.has_arst) { legalize_rlatch(ff); } else { log_assert(0); } } } void flip_pol(FfData &ff, SigSpec &sig, bool &pol) { if (sig == State::S0) { sig = State::S1; } else if (sig == State::S1) { sig = State::S0; } else if (ff.is_fine) { sig = ff.module->NotGate(NEW_ID, sig); } else { sig = ff.module->Not(NEW_ID, sig); } pol = !pol; } void legalize_finish(FfData &ff) { int ff_type = get_ff_type(ff); int initmask = get_initmask(ff); log_assert(supported_cells[ff_type] & initmask); int ff_neg = 0; if (ff.has_sr) { if (!ff.pol_clr) ff_neg |= NEG_R; if (!ff.pol_set) ff_neg |= NEG_S; } if (ff.has_arst) { if (!ff.pol_arst) ff_neg |= NEG_R; } if (ff.has_srst) { if (!ff.pol_srst) ff_neg |= NEG_R; } if (ff.has_aload) { if (!ff.pol_aload) ff_neg |= NEG_L; } if (ff.has_clk) { if (!ff.pol_clk) ff_neg |= NEG_C; } if (ff.has_ce) { if (!ff.pol_ce) ff_neg |= NEG_CE; } if (!(supported_cells_neg[ff_type][ff_neg] & initmask)) { // Cell is supported, but not with those polarities. // Will need to add some inverters. // Find the smallest value that xored with the neg mask // results in a supported one — this results in preferentially // inverting resets before clocks, etc. int xneg; for (xneg = 0; xneg < NUM_NEG; xneg++) if (supported_cells_neg[ff_type][ff_neg ^ xneg] & initmask) break; log_assert(xneg < NUM_NEG); if (xneg & NEG_CE) flip_pol(ff, ff.sig_ce, ff.pol_ce); if (ff.has_sr) { if (xneg & NEG_R) flip_pol(ff, ff.sig_clr, ff.pol_clr); if (xneg & NEG_S) flip_pol(ff, ff.sig_set, ff.pol_set); } if (ff.has_arst && xneg & NEG_R) flip_pol(ff, ff.sig_arst, ff.pol_arst); if (ff.has_srst && xneg & NEG_R) flip_pol(ff, ff.sig_srst, ff.pol_srst); if (xneg & NEG_L) flip_pol(ff, ff.sig_aload, ff.pol_aload); if (xneg & NEG_C) flip_pol(ff, ff.sig_clk, ff.pol_clk); ff_neg ^= xneg; } fixup_reset_x(ff, supported_cells_neg[ff_type][ff_neg]); ff.emit(); } void execute(std::vector args, RTLIL::Design *design) override { log_header(design, "Executing DFFLEGALIZE pass (convert FFs to types supported by the target).\n"); for (int i = 0; i < NUM_FFTYPES; i++) { for (int j = 0; j < NUM_NEG; j++) supported_cells_neg[i][j] = 0; supported_cells[i] = 0; } mince = 0; minsrst = 0; size_t argidx; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-cell" && argidx + 2 < args.size()) { std::string celltype = args[++argidx]; std::string inittype = args[++argidx]; enum FfType ff_type; char pol_c = 0; char pol_l = 0; char pol_s = 0; char pol_r = 0; char pol_ce = 0; char srval = 0; if (celltype.substr(0, 5) == "$_SR_" && celltype.size() == 8 && celltype[7] == '_') { ff_type = FF_SR; pol_s = celltype[5]; pol_r = celltype[6]; } else if (celltype.substr(0, 6) == "$_DFF_" && celltype.size() == 8 && celltype[7] == '_') { ff_type = FF_DFF; pol_c = celltype[6]; } else if (celltype.substr(0, 7) == "$_DFFE_" && celltype.size() == 10 && celltype[9] == '_') { ff_type = FF_DFFE; pol_c = celltype[7]; pol_ce = celltype[8]; } else if (celltype.substr(0, 6) == "$_DFF_" && celltype.size() == 10 && celltype[9] == '_') { ff_type = FF_ADFF; pol_c = celltype[6]; pol_r = celltype[7]; srval = celltype[8]; } else if (celltype.substr(0, 7) == "$_DFFE_" && celltype.size() == 12 && celltype[11] == '_') { ff_type = FF_ADFFE; pol_c = celltype[7]; pol_r = celltype[8]; srval = celltype[9]; pol_ce = celltype[10]; } else if (celltype.substr(0, 8) == "$_ALDFF_" && celltype.size() == 11 && celltype[10] == '_') { ff_type = FF_ALDFF; pol_c = celltype[8]; pol_l = celltype[9]; } else if (celltype.substr(0, 9) == "$_ALDFFE_" && celltype.size() == 13 && celltype[12] == '_') { ff_type = FF_ALDFFE; pol_c = celltype[9]; pol_l = celltype[10]; pol_ce = celltype[11]; } else if (celltype.substr(0, 8) == "$_DFFSR_" && celltype.size() == 12 && celltype[11] == '_') { ff_type = FF_DFFSR; pol_c = celltype[8]; pol_s = celltype[9]; pol_r = celltype[10]; } else if (celltype.substr(0, 9) == "$_DFFSRE_" && celltype.size() == 14 && celltype[13] == '_') { ff_type = FF_DFFSRE; pol_c = celltype[9]; pol_s = celltype[10]; pol_r = celltype[11]; pol_ce = celltype[12]; } else if (celltype.substr(0, 7) == "$_SDFF_" && celltype.size() == 11 && celltype[10] == '_') { ff_type = FF_SDFF; pol_c = celltype[7]; pol_r = celltype[8]; srval = celltype[9]; } else if (celltype.substr(0, 8) == "$_SDFFE_" && celltype.size() == 13 && celltype[12] == '_') { ff_type = FF_SDFFE; pol_c = celltype[8]; pol_r = celltype[9]; srval = celltype[10]; pol_ce = celltype[11]; } else if (celltype.substr(0, 9) == "$_SDFFCE_" && celltype.size() == 14 && celltype[13] == '_') { ff_type = FF_SDFFCE; pol_c = celltype[9]; pol_r = celltype[10]; srval = celltype[11]; pol_ce = celltype[12]; } else if (celltype.substr(0, 9) == "$_DLATCH_" && celltype.size() == 11 && celltype[10] == '_') { ff_type = FF_DLATCH; pol_l = celltype[9]; } else if (celltype.substr(0, 9) == "$_DLATCH_" && celltype.size() == 13 && celltype[12] == '_') { ff_type = FF_ADLATCH; pol_l = celltype[9]; pol_r = celltype[10]; srval = celltype[11]; } else if (celltype.substr(0, 11) == "$_DLATCHSR_" && celltype.size() == 15 && celltype[14] == '_') { ff_type = FF_DLATCHSR; pol_l = celltype[11]; pol_s = celltype[12]; pol_r = celltype[13]; } else { unrecognized: log_error("unrecognized cell type %s.\n", celltype.c_str()); } int mask = 0; int match = 0; for (auto pair : { std::make_pair(pol_c, NEG_C), std::make_pair(pol_l, NEG_L), std::make_pair(pol_s, NEG_S), std::make_pair(pol_r, NEG_R), std::make_pair(pol_ce, NEG_CE), }) { if (pair.first == 'N') { mask |= pair.second; match |= pair.second; } else if (pair.first == 'P' || pair.first == 0) { mask |= pair.second; } else if (pair.first != '?') { goto unrecognized; } } int initmask; if (inittype == "x") { initmask = 0x111; } else if (inittype == "0") { initmask = 0x333; } else if (inittype == "1") { initmask = 0x555; } else if (inittype == "r") { if (srval == 0) log_error("init type r not valid for cell type %s.\n", celltype.c_str()); initmask = 0x537; } else if (inittype == "01") { initmask = 0x777; } else { log_error("unrecognized init type %s for cell type %s.\n", inittype.c_str(), celltype.c_str()); } if (srval == '0') { initmask &= 0x0ff; } else if (srval == '1') { initmask &= 0xf0f; } else if (srval != 0 && srval != '?') { goto unrecognized; } for (int neg = 0; neg < NUM_NEG; neg++) if ((neg & mask) == match) supported_cells_neg[ff_type][neg] |= initmask; supported_cells[ff_type] |= initmask; continue; } else if (args[argidx] == "-mince" && argidx + 1 < args.size()) { mince = atoi(args[++argidx].c_str()); continue; } else if (args[argidx] == "-minsrst" && argidx + 1 < args.size()) { minsrst = atoi(args[++argidx].c_str()); continue; } break; } extra_args(args, argidx, design); supported_dffsr = supported_cells[FF_DFFSR] | supported_cells[FF_DFFSRE]; supported_aldff = supported_cells[FF_ALDFF] | supported_cells[FF_ALDFFE] | supported_dffsr; supported_aldffe = supported_cells[FF_ALDFFE] | supported_cells[FF_DFFSRE]; supported_adff = supported_cells[FF_ADFF] | supported_cells[FF_ADFFE] | supported_dffsr | supported_aldff; supported_adffe = supported_cells[FF_ADFFE] | supported_cells[FF_ALDFFE] | supported_cells[FF_DFFSRE]; supported_sdff = supported_cells[FF_SDFF] | supported_cells[FF_SDFFE] | supported_cells[FF_SDFFCE]; supported_dff = supported_cells[FF_DFF] | supported_cells[FF_DFFE] | supported_adff | supported_sdff; supported_dffe = supported_cells[FF_DFFE] | supported_cells[FF_DFFSRE] | supported_cells[FF_ALDFFE] | supported_cells[FF_ADFFE] | supported_cells[FF_SDFFE] | supported_cells[FF_SDFFCE]; supported_sr_plain = supported_dffsr | supported_cells[FF_DLATCHSR] | supported_cells[FF_SR]; supported_sr = supported_sr_plain; supported_sr |= (supported_cells[FF_ADLATCH] >> 4 & 7) * 0x111; supported_sr |= (flip_initmask(supported_cells[FF_ADLATCH]) >> 4 & 7) * 0x111; supported_dlatch_plain = supported_cells[FF_DLATCH] | supported_cells[FF_ADLATCH] | supported_cells[FF_DLATCHSR] | supported_cells[FF_ALDFF] | supported_cells[FF_ALDFFE]; supported_dlatch = supported_dlatch_plain | supported_sr_plain; supported_rlatch = supported_adff | (supported_dlatch & 7) * 0x111; supported_adlatch = supported_cells[FF_ADLATCH] | supported_cells[FF_DLATCHSR]; for (auto module : design->selected_modules()) { sigmap.set(module); initvals.set(&sigmap, module); if (mince || minsrst) { ce_used.clear(); srst_used.clear(); for (auto cell : module->cells()) { if (!RTLIL::builtin_ff_cell_types().count(cell->type)) continue; FfData ff(&initvals, cell); if (ff.has_ce && ff.sig_ce[0].wire) ce_used[ff.sig_ce[0]] += ff.width; if (ff.has_srst && ff.sig_srst[0].wire) srst_used[ff.sig_srst[0]] += ff.width; } } for (auto cell : module->selected_cells()) { if (!RTLIL::builtin_ff_cell_types().count(cell->type)) continue; FfData ff(&initvals, cell); legalize_ff(ff); } } sigmap.clear(); initvals.clear(); ce_used.clear(); srst_used.clear(); } } DffLegalizePass; PRIVATE_NAMESPACE_END