/* * 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/rtlil.h" #include "kernel/register.h" #include "kernel/sigtools.h" #include "kernel/celltypes.h" #include "kernel/log.h" #include USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN struct Smt2Worker { CellTypes ct; SigMap sigmap; RTLIL::Module *module; bool bvmode, memmode, wiresmode, verbose; int idcounter; std::vector decls, trans, hier; std::map bit_driver; std::set exported_cells, hiercells; pool recursive_cells, registers; std::map> fcache; std::map memarrays; std::map bvsizes; std::vector ids; Smt2Worker(RTLIL::Module *module, bool bvmode, bool memmode, bool wiresmode, bool verbose) : ct(module->design), sigmap(module), module(module), bvmode(bvmode), memmode(memmode), wiresmode(wiresmode), verbose(verbose), idcounter(0) { decls.push_back(stringf("(declare-sort |%s_s| 0)\n", get_id(module))); decls.push_back(stringf("(declare-fun |%s_is| (|%s_s|) Bool)\n", get_id(module), get_id(module))); for (auto cell : module->cells()) for (auto &conn : cell->connections()) { bool is_input = ct.cell_input(cell->type, conn.first); bool is_output = ct.cell_output(cell->type, conn.first); if (is_output && !is_input) for (auto bit : sigmap(conn.second)) { if (bit_driver.count(bit)) log_error("Found multiple drivers for %s.\n", log_signal(bit)); bit_driver[bit] = cell; } else if (is_output || !is_input) log_error("Unsupported or unknown directionality on port %s of cell %s.%s (%s).\n", log_id(conn.first), log_id(module), log_id(cell), log_id(cell->type)); } } const char *get_id(IdString n) { std::string str = log_id(n); for (int i = 0; i < GetSize(str); i++) { if (str[i] == '\\') str[i] = '/'; } ids.push_back(str); return ids.back().c_str(); } const char *get_id(Module *m) { return get_id(m->name); } const char *get_id(Cell *c) { return get_id(c->name); } const char *get_id(Wire *w) { return get_id(w->name); } void register_bool(RTLIL::SigBit bit, int id) { if (verbose) log("%*s-> register_bool: %s %d\n", 2+2*GetSize(recursive_cells), "", log_signal(bit), id); sigmap.apply(bit); log_assert(fcache.count(bit) == 0); fcache[bit] = std::pair(id, -1); } void register_bv(RTLIL::SigSpec sig, int id) { if (verbose) log("%*s-> register_bv: %s %d\n", 2+2*GetSize(recursive_cells), "", log_signal(sig), id); log_assert(bvmode); sigmap.apply(sig); log_assert(bvsizes.count(id) == 0); bvsizes[id] = GetSize(sig); for (int i = 0; i < GetSize(sig); i++) { log_assert(fcache.count(sig[i]) == 0); fcache[sig[i]] = std::pair(id, i); } } void register_boolvec(RTLIL::SigSpec sig, int id) { if (verbose) log("%*s-> register_boolvec: %s %d\n", 2+2*GetSize(recursive_cells), "", log_signal(sig), id); log_assert(bvmode); sigmap.apply(sig); register_bool(sig[0], id); for (int i = 1; i < GetSize(sig); i++) sigmap.add(sig[i], RTLIL::State::S0); } std::string get_bool(RTLIL::SigBit bit, const char *state_name = "state") { sigmap.apply(bit); if (bit.wire == nullptr) return bit == RTLIL::State::S1 ? "true" : "false"; if (bit_driver.count(bit)) export_cell(bit_driver.at(bit)); sigmap.apply(bit); if (fcache.count(bit) == 0) { if (verbose) log("%*s-> external bool: %s\n", 2+2*GetSize(recursive_cells), "", log_signal(bit)); decls.push_back(stringf("(declare-fun |%s#%d| (|%s_s|) Bool) ; %s\n", get_id(module), idcounter, get_id(module), log_signal(bit))); register_bool(bit, idcounter++); } auto f = fcache.at(bit); if (f.second >= 0) return stringf("(= ((_ extract %d %d) (|%s#%d| %s)) #b1)", f.second, f.second, get_id(module), f.first, state_name); return stringf("(|%s#%d| %s)", get_id(module), f.first, state_name); } std::string get_bool(RTLIL::SigSpec sig, const char *state_name = "state") { return get_bool(sig.as_bit(), state_name); } std::string get_bv(RTLIL::SigSpec sig, const char *state_name = "state") { log_assert(bvmode); sigmap.apply(sig); std::vector subexpr; SigSpec orig_sig; while (orig_sig != sig) { for (auto bit : sig) if (bit_driver.count(bit)) export_cell(bit_driver.at(bit)); orig_sig = sig; sigmap.apply(sig); } for (int i = 0, j = 1; i < GetSize(sig); i += j, j = 1) { if (sig[i].wire == nullptr) { while (i+j < GetSize(sig) && sig[i+j].wire == nullptr) j++; subexpr.push_back("#b"); for (int k = i+j-1; k >= i; k--) subexpr.back() += sig[k] == RTLIL::State::S1 ? "1" : "0"; continue; } if (fcache.count(sig[i]) && fcache.at(sig[i]).second == -1) { subexpr.push_back(stringf("(ite %s #b1 #b0)", get_bool(sig[i], state_name).c_str())); continue; } if (fcache.count(sig[i])) { auto t1 = fcache.at(sig[i]); while (i+j < GetSize(sig)) { if (fcache.count(sig[i+j]) == 0) break; auto t2 = fcache.at(sig[i+j]); if (t1.first != t2.first) break; if (t1.second+j != t2.second) break; j++; } if (t1.second == 0 && j == bvsizes.at(t1.first)) subexpr.push_back(stringf("(|%s#%d| %s)", get_id(module), t1.first, state_name)); else subexpr.push_back(stringf("((_ extract %d %d) (|%s#%d| %s))", t1.second + j - 1, t1.second, get_id(module), t1.first, state_name)); continue; } std::set seen_bits = { sig[i] }; while (i+j < GetSize(sig) && sig[i+j].wire && !fcache.count(sig[i+j]) && !seen_bits.count(sig[i+j])) seen_bits.insert(sig[i+j]), j++; if (verbose) log("%*s-> external bv: %s\n", 2+2*GetSize(recursive_cells), "", log_signal(sig.extract(i, j))); for (auto bit : sig.extract(i, j)) log_assert(bit_driver.count(bit) == 0); decls.push_back(stringf("(declare-fun |%s#%d| (|%s_s|) (_ BitVec %d)) ; %s\n", get_id(module), idcounter, get_id(module), j, log_signal(sig.extract(i, j)))); subexpr.push_back(stringf("(|%s#%d| %s)", get_id(module), idcounter, state_name)); register_bv(sig.extract(i, j), idcounter++); } if (GetSize(subexpr) > 1) { std::string expr = "", end_str = ""; for (int i = GetSize(subexpr)-1; i >= 0; i--) { if (i > 0) expr += " (concat", end_str += ")"; expr += " " + subexpr[i]; } return expr.substr(1) + end_str; } else { log_assert(GetSize(subexpr) == 1); return subexpr[0]; } } void export_gate(RTLIL::Cell *cell, std::string expr) { RTLIL::SigBit bit = sigmap(cell->getPort("\\Y").as_bit()); std::string processed_expr; for (char ch : expr) { if (ch == 'A') processed_expr += get_bool(cell->getPort("\\A")); else if (ch == 'B') processed_expr += get_bool(cell->getPort("\\B")); else if (ch == 'C') processed_expr += get_bool(cell->getPort("\\C")); else if (ch == 'D') processed_expr += get_bool(cell->getPort("\\D")); else if (ch == 'S') processed_expr += get_bool(cell->getPort("\\S")); else processed_expr += ch; } if (verbose) log("%*s-> import cell: %s\n", 2+2*GetSize(recursive_cells), "", log_id(cell)); decls.push_back(stringf("(define-fun |%s#%d| ((state |%s_s|)) Bool %s) ; %s\n", get_id(module), idcounter, get_id(module), processed_expr.c_str(), log_signal(bit))); register_bool(bit, idcounter++); recursive_cells.erase(cell); } void export_bvop(RTLIL::Cell *cell, std::string expr, char type = 0) { RTLIL::SigSpec sig_a, sig_b; RTLIL::SigSpec sig_y = sigmap(cell->getPort("\\Y")); bool is_signed = cell->getParam("\\A_SIGNED").as_bool(); int width = GetSize(sig_y); if (type == 's' || type == 'd' || type == 'b') { width = max(width, GetSize(cell->getPort("\\A"))); width = max(width, GetSize(cell->getPort("\\B"))); } if (cell->hasPort("\\A")) { sig_a = cell->getPort("\\A"); sig_a.extend_u0(width, is_signed); } if (cell->hasPort("\\B")) { sig_b = cell->getPort("\\B"); sig_b.extend_u0(width, is_signed && !(type == 's')); } std::string processed_expr; for (char ch : expr) { if (ch == 'A') processed_expr += get_bv(sig_a); else if (ch == 'B') processed_expr += get_bv(sig_b); else if (ch == 'L') processed_expr += is_signed ? "a" : "l"; else if (ch == 'U') processed_expr += is_signed ? "s" : "u"; else processed_expr += ch; } if (width != GetSize(sig_y) && type != 'b') processed_expr = stringf("((_ extract %d 0) %s)", GetSize(sig_y)-1, processed_expr.c_str()); if (verbose) log("%*s-> import cell: %s\n", 2+2*GetSize(recursive_cells), "", log_id(cell)); if (type == 'b') { decls.push_back(stringf("(define-fun |%s#%d| ((state |%s_s|)) Bool %s) ; %s\n", get_id(module), idcounter, get_id(module), processed_expr.c_str(), log_signal(sig_y))); register_boolvec(sig_y, idcounter++); } else { decls.push_back(stringf("(define-fun |%s#%d| ((state |%s_s|)) (_ BitVec %d) %s) ; %s\n", get_id(module), idcounter, get_id(module), GetSize(sig_y), processed_expr.c_str(), log_signal(sig_y))); register_bv(sig_y, idcounter++); } recursive_cells.erase(cell); } void export_reduce(RTLIL::Cell *cell, std::string expr, bool identity_val) { RTLIL::SigSpec sig_y = sigmap(cell->getPort("\\Y")); std::string processed_expr; for (char ch : expr) if (ch == 'A' || ch == 'B') { RTLIL::SigSpec sig = sigmap(cell->getPort(stringf("\\%c", ch))); for (auto bit : sig) processed_expr += " " + get_bool(bit); if (GetSize(sig) == 1) processed_expr += identity_val ? " true" : " false"; } else processed_expr += ch; if (verbose) log("%*s-> import cell: %s\n", 2+2*GetSize(recursive_cells), "", log_id(cell)); decls.push_back(stringf("(define-fun |%s#%d| ((state |%s_s|)) Bool %s) ; %s\n", get_id(module), idcounter, get_id(module), processed_expr.c_str(), log_signal(sig_y))); register_boolvec(sig_y, idcounter++); recursive_cells.erase(cell); } void export_cell(RTLIL::Cell *cell) { if (verbose) log("%*s=> export_cell %s (%s) [%s]\n", 2+2*GetSize(recursive_cells), "", log_id(cell), log_id(cell->type), exported_cells.count(cell) ? "old" : "new"); if (recursive_cells.count(cell)) log_error("Found logic loop in module %s! See cell %s.\n", get_id(module), get_id(cell)); if (exported_cells.count(cell)) return; exported_cells.insert(cell); recursive_cells.insert(cell); if (cell->type == "$initstate") { SigBit bit = sigmap(cell->getPort("\\Y").as_bit()); decls.push_back(stringf("(define-fun |%s#%d| ((state |%s_s|)) Bool (|%s_is| state)) ; %s\n", get_id(module), idcounter, get_id(module), get_id(module), log_signal(bit))); register_bool(bit, idcounter++); recursive_cells.erase(cell); return; } if (cell->type == "$_DFF_P_" || cell->type == "$_DFF_N_") { registers.insert(cell); decls.push_back(stringf("(declare-fun |%s#%d| (|%s_s|) Bool) ; %s\n", get_id(module), idcounter, get_id(module), log_signal(cell->getPort("\\Q")))); register_bool(cell->getPort("\\Q"), idcounter++); recursive_cells.erase(cell); return; } if (cell->type == "$_BUF_") return export_gate(cell, "A"); if (cell->type == "$_NOT_") return export_gate(cell, "(not A)"); if (cell->type == "$_AND_") return export_gate(cell, "(and A B)"); if (cell->type == "$_NAND_") return export_gate(cell, "(not (and A B))"); if (cell->type == "$_OR_") return export_gate(cell, "(or A B)"); if (cell->type == "$_NOR_") return export_gate(cell, "(not (or A B))"); if (cell->type == "$_XOR_") return export_gate(cell, "(xor A B)"); if (cell->type == "$_XNOR_") return export_gate(cell, "(not (xor A B))"); if (cell->type == "$_MUX_") return export_gate(cell, "(ite S B A)"); if (cell->type == "$_AOI3_") return export_gate(cell, "(not (or (and A B) C))"); if (cell->type == "$_OAI3_") return export_gate(cell, "(not (and (or A B) C))"); if (cell->type == "$_AOI4_") return export_gate(cell, "(not (or (and A B) (and C D)))"); if (cell->type == "$_OAI4_") return export_gate(cell, "(not (and (or A B) (or C D)))"); // FIXME: $lut if (bvmode) { if (cell->type == "$dff") { registers.insert(cell); decls.push_back(stringf("(declare-fun |%s#%d| (|%s_s|) (_ BitVec %d)) ; %s\n", get_id(module), idcounter, get_id(module), GetSize(cell->getPort("\\Q")), log_signal(cell->getPort("\\Q")))); register_bv(cell->getPort("\\Q"), idcounter++); recursive_cells.erase(cell); return; } if (cell->type == "$and") return export_bvop(cell, "(bvand A B)"); if (cell->type == "$or") return export_bvop(cell, "(bvor A B)"); if (cell->type == "$xor") return export_bvop(cell, "(bvxor A B)"); if (cell->type == "$xnor") return export_bvop(cell, "(bvxnor A B)"); if (cell->type == "$shl") return export_bvop(cell, "(bvshl A B)", 's'); if (cell->type == "$shr") return export_bvop(cell, "(bvlshr A B)", 's'); if (cell->type == "$sshl") return export_bvop(cell, "(bvshl A B)", 's'); if (cell->type == "$sshr") return export_bvop(cell, "(bvLshr A B)", 's'); if (cell->type.in("$shift", "$shiftx")) { if (cell->getParam("\\B_SIGNED").as_bool()) { /* FIXME */ } else { return export_bvop(cell, "(bvlshr A B)", 's'); } } if (cell->type == "$lt") return export_bvop(cell, "(bvUlt A B)", 'b'); if (cell->type == "$le") return export_bvop(cell, "(bvUle A B)", 'b'); if (cell->type == "$ge") return export_bvop(cell, "(bvUge A B)", 'b'); if (cell->type == "$gt") return export_bvop(cell, "(bvUgt A B)", 'b'); if (cell->type == "$ne") return export_bvop(cell, "(distinct A B)", 'b'); if (cell->type == "$nex") return export_bvop(cell, "(distinct A B)", 'b'); if (cell->type == "$eq") return export_bvop(cell, "(= A B)", 'b'); if (cell->type == "$eqx") return export_bvop(cell, "(= A B)", 'b'); if (cell->type == "$not") return export_bvop(cell, "(bvnot A)"); if (cell->type == "$pos") return export_bvop(cell, "A"); if (cell->type == "$neg") return export_bvop(cell, "(bvneg A)"); if (cell->type == "$add") return export_bvop(cell, "(bvadd A B)"); if (cell->type == "$sub") return export_bvop(cell, "(bvsub A B)"); if (cell->type == "$mul") return export_bvop(cell, "(bvmul A B)"); if (cell->type == "$div") return export_bvop(cell, "(bvUdiv A B)", 'd'); if (cell->type == "$mod") return export_bvop(cell, "(bvUrem A B)", 'd'); if (cell->type == "$reduce_and") return export_reduce(cell, "(and A)", true); if (cell->type == "$reduce_or") return export_reduce(cell, "(or A)", false); if (cell->type == "$reduce_xor") return export_reduce(cell, "(xor A)", false); if (cell->type == "$reduce_xnor") return export_reduce(cell, "(not (xor A))", false); if (cell->type == "$reduce_bool") return export_reduce(cell, "(or A)", false); if (cell->type == "$logic_not") return export_reduce(cell, "(not (or A))", false); if (cell->type == "$logic_and") return export_reduce(cell, "(and (or A) (or B))", false); if (cell->type == "$logic_or") return export_reduce(cell, "(or A B)", false); if (cell->type == "$mux" || cell->type == "$pmux") { int width = GetSize(cell->getPort("\\Y")); std::string processed_expr = get_bv(cell->getPort("\\A")); RTLIL::SigSpec sig_b = cell->getPort("\\B"); RTLIL::SigSpec sig_s = cell->getPort("\\S"); get_bv(sig_b); get_bv(sig_s); for (int i = 0; i < GetSize(sig_s); i++) processed_expr = stringf("(ite %s %s %s)", get_bool(sig_s[i]).c_str(), get_bv(sig_b.extract(i*width, width)).c_str(), processed_expr.c_str()); if (verbose) log("%*s-> import cell: %s\n", 2+2*GetSize(recursive_cells), "", log_id(cell)); RTLIL::SigSpec sig = sigmap(cell->getPort("\\Y")); decls.push_back(stringf("(define-fun |%s#%d| ((state |%s_s|)) (_ BitVec %d) %s) ; %s\n", get_id(module), idcounter, get_id(module), width, processed_expr.c_str(), log_signal(sig))); register_bv(sig, idcounter++); recursive_cells.erase(cell); return; } // FIXME: $slice $concat } if (memmode && cell->type == "$mem") { int arrayid = idcounter++; memarrays[cell] = arrayid; int abits = cell->getParam("\\ABITS").as_int(); int width = cell->getParam("\\WIDTH").as_int(); int rd_ports = cell->getParam("\\RD_PORTS").as_int(); decls.push_back(stringf("(declare-fun |%s#%d#0| (|%s_s|) (Array (_ BitVec %d) (_ BitVec %d))) ; %s\n", get_id(module), arrayid, get_id(module), abits, width, get_id(cell))); decls.push_back(stringf("; yosys-smt2-memory %s %d %d %d\n", get_id(cell), abits, width, rd_ports)); decls.push_back(stringf("(define-fun |%s_m %s| ((state |%s_s|)) (Array (_ BitVec %d) (_ BitVec %d)) (|%s#%d#0| state))\n", get_id(module), get_id(cell), get_id(module), abits, width, get_id(module), arrayid)); for (int i = 0; i < rd_ports; i++) { SigSpec addr_sig = cell->getPort("\\RD_ADDR").extract(abits*i, abits); SigSpec data_sig = cell->getPort("\\RD_DATA").extract(width*i, width); std::string addr = get_bv(addr_sig); if (cell->getParam("\\RD_CLK_ENABLE").extract(i).as_bool()) log_error("Read port %d (%s) of memory %s.%s is clocked. This is not supported by \"write_smt2\"! " "Call \"memory\" with -nordff to avoid this error.\n", i, log_signal(data_sig), log_id(cell), log_id(module)); decls.push_back(stringf("(define-fun |%s_m:%d %s| ((state |%s_s|)) (_ BitVec %d) %s) ; %s\n", get_id(module), i, get_id(cell), get_id(module), abits, addr.c_str(), log_signal(addr_sig))); decls.push_back(stringf("(define-fun |%s#%d| ((state |%s_s|)) (_ BitVec %d) (select (|%s#%d#0| state) %s)) ; %s\n", get_id(module), idcounter, get_id(module), width, get_id(module), arrayid, addr.c_str(), log_signal(data_sig))); register_bv(data_sig, idcounter++); } registers.insert(cell); recursive_cells.erase(cell); return; } Module *m = module->design->module(cell->type); if (m != nullptr) { decls.push_back(stringf("; yosys-smt2-cell %s %s\n", get_id(cell->type), get_id(cell->name))); string cell_state = stringf("(|%s_h %s| state)", get_id(module), get_id(cell->name)); for (auto &conn : cell->connections()) { Wire *w = m->wire(conn.first); SigSpec sig = sigmap(conn.second); if (w->port_output && !w->port_input) { if (GetSize(w) > 1) { if (bvmode) { decls.push_back(stringf("(declare-fun |%s#%d| (|%s_s|) (_ BitVec %d)) ; %s\n", get_id(module), idcounter, get_id(module), GetSize(w), log_signal(sig))); register_bv(sig, idcounter++); } else { for (int i = 0; i < GetSize(w); i++) { decls.push_back(stringf("(declare-fun |%s#%d| (|%s_s|) Bool) ; %s\n", get_id(module), idcounter, get_id(module), log_signal(sig[i]))); register_bool(sig[i], idcounter++); } } } else { decls.push_back(stringf("(declare-fun |%s#%d| (|%s_s|) Bool) ; %s\n", get_id(module), idcounter, get_id(module), log_signal(sig))); register_bool(sig, idcounter++); } } } decls.push_back(stringf("(declare-fun |%s_h %s| (|%s_s|) |%s_s|)\n", get_id(module), get_id(cell->name), get_id(module), get_id(cell->type))); hiercells.insert(cell); recursive_cells.erase(cell); for (auto &conn : cell->connections()) { Wire *w = m->wire(conn.first); SigSpec sig = sigmap(conn.second); if (bvmode || GetSize(w) == 1) { hier.push_back(stringf(" (= %s (|%s_n %s| %s)) ; %s.%s\n", (GetSize(w) > 1 ? get_bv(sig) : get_bool(sig)).c_str(), get_id(cell->type), get_id(w), cell_state.c_str(), get_id(cell->type), get_id(w))); } else { for (int i = 0; i < GetSize(w); i++) hier.push_back(stringf(" (= %s (|%s_n %s %d| %s)) ; %s.%s[%d]\n", get_bool(sig[i]).c_str(), get_id(cell->type), get_id(w), i, cell_state.c_str(), get_id(cell->type), get_id(w), i)); } } return; } log_error("Unsupported cell type %s for cell %s.%s. (Maybe this cell type would be supported in -bv or -mem mode?)\n", log_id(cell->type), log_id(module), log_id(cell)); } void run() { if (verbose) log("=> export logic driving outputs\n"); pool reg_bits; for (auto cell : module->cells()) if (cell->type.in("$_DFF_P_", "$_DFF_N_", "$dff")) { // not using sigmap -- we want the net directly at the dff output for (auto bit : cell->getPort("\\Q")) reg_bits.insert(bit); } for (auto wire : module->wires()) { bool is_register = false; for (auto bit : SigSpec(wire)) if (reg_bits.count(bit)) is_register = true; if (wire->port_id || is_register || wire->get_bool_attribute("\\keep") || (wiresmode && wire->name[0] == '\\')) { RTLIL::SigSpec sig = sigmap(wire); if (wire->port_input) decls.push_back(stringf("; yosys-smt2-input %s %d\n", get_id(wire), wire->width)); if (wire->port_output) decls.push_back(stringf("; yosys-smt2-output %s %d\n", get_id(wire), wire->width)); if (is_register) decls.push_back(stringf("; yosys-smt2-register %s %d\n", get_id(wire), wire->width)); if (wire->get_bool_attribute("\\keep") || (wiresmode && wire->name[0] == '\\')) decls.push_back(stringf("; yosys-smt2-wire %s %d\n", get_id(wire), wire->width)); if (bvmode && GetSize(sig) > 1) { decls.push_back(stringf("(define-fun |%s_n %s| ((state |%s_s|)) (_ BitVec %d) %s)\n", get_id(module), get_id(wire), get_id(module), GetSize(sig), get_bv(sig).c_str())); } else { for (int i = 0; i < GetSize(sig); i++) if (GetSize(sig) > 1) decls.push_back(stringf("(define-fun |%s_n %s %d| ((state |%s_s|)) Bool %s)\n", get_id(module), get_id(wire), i, get_id(module), get_bool(sig[i]).c_str())); else decls.push_back(stringf("(define-fun |%s_n %s| ((state |%s_s|)) Bool %s)\n", get_id(module), get_id(wire), get_id(module), get_bool(sig[i]).c_str())); } } } if (verbose) log("=> export logic associated with the initial state\n"); vector init_list; for (auto wire : module->wires()) if (wire->attributes.count("\\init")) { RTLIL::SigSpec sig = sigmap(wire); Const val = wire->attributes.at("\\init"); val.bits.resize(GetSize(sig)); if (bvmode && GetSize(sig) > 1) { init_list.push_back(stringf("(= %s #b%s) ; %s", get_bv(sig).c_str(), val.as_string().c_str(), get_id(wire))); } else { for (int i = 0; i < GetSize(sig); i++) init_list.push_back(stringf("(= %s %s) ; %s", get_bool(sig[i]).c_str(), val.bits[i] == State::S1 ? "true" : "false", get_id(wire))); } } if (verbose) log("=> export logic driving asserts\n"); vector assert_list, assume_list; for (auto cell : module->cells()) if (cell->type.in("$assert", "$assume")) { string name_a = get_bool(cell->getPort("\\A")); string name_en = get_bool(cell->getPort("\\EN")); decls.push_back(stringf("; yosys-smt2-%s %s#%d %s\n", cell->type.c_str() + 1, get_id(module), idcounter, cell->attributes.count("\\src") ? cell->attributes.at("\\src").decode_string().c_str() : get_id(cell))); decls.push_back(stringf("(define-fun |%s#%d| ((state |%s_s|)) Bool (or %s (not %s))) ; %s\n", get_id(module), idcounter, get_id(module), name_a.c_str(), name_en.c_str(), get_id(cell))); if (cell->type == "$assert") assert_list.push_back(stringf("(|%s#%d| state)", get_id(module), idcounter++)); else assume_list.push_back(stringf("(|%s#%d| state)", get_id(module), idcounter++)); } for (int iter = 1; !registers.empty(); iter++) { pool this_regs; this_regs.swap(registers); if (verbose) log("=> export logic driving registers [iteration %d]\n", iter); for (auto cell : this_regs) { if (cell->type == "$_DFF_P_" || cell->type == "$_DFF_N_") { std::string expr_d = get_bool(cell->getPort("\\D")); std::string expr_q = get_bool(cell->getPort("\\Q"), "next_state"); trans.push_back(stringf(" (= %s %s) ; %s %s\n", expr_d.c_str(), expr_q.c_str(), get_id(cell), log_signal(cell->getPort("\\Q")))); } if (cell->type == "$dff") { std::string expr_d = get_bv(cell->getPort("\\D")); std::string expr_q = get_bv(cell->getPort("\\Q"), "next_state"); trans.push_back(stringf(" (= %s %s) ; %s %s\n", expr_d.c_str(), expr_q.c_str(), get_id(cell), log_signal(cell->getPort("\\Q")))); } if (cell->type == "$mem") { int arrayid = memarrays.at(cell); int abits = cell->getParam("\\ABITS").as_int(); int width = cell->getParam("\\WIDTH").as_int(); int wr_ports = cell->getParam("\\WR_PORTS").as_int(); for (int i = 0; i < wr_ports; i++) { std::string addr = get_bv(cell->getPort("\\WR_ADDR").extract(abits*i, abits)); std::string data = get_bv(cell->getPort("\\WR_DATA").extract(width*i, width)); std::string mask = get_bv(cell->getPort("\\WR_EN").extract(width*i, width)); data = stringf("(bvor (bvand %s %s) (bvand (select (|%s#%d#%d| state) %s) (bvnot %s)))", data.c_str(), mask.c_str(), get_id(module), arrayid, i, addr.c_str(), mask.c_str()); decls.push_back(stringf("(define-fun |%s#%d#%d| ((state |%s_s|)) (Array (_ BitVec %d) (_ BitVec %d)) " "(store (|%s#%d#%d| state) %s %s)) ; %s\n", get_id(module), arrayid, i+1, get_id(module), abits, width, get_id(module), arrayid, i, addr.c_str(), data.c_str(), get_id(cell))); } std::string expr_d = stringf("(|%s#%d#%d| state)", get_id(module), arrayid, wr_ports); std::string expr_q = stringf("(|%s#%d#0| next_state)", get_id(module), arrayid); trans.push_back(stringf(" (= %s %s) ; %s\n", expr_d.c_str(), expr_q.c_str(), get_id(cell))); } } } for (auto c : hiercells) { assert_list.push_back(stringf("(|%s_a| (|%s_h %s| state))", get_id(c->type), get_id(module), get_id(c->name))); assume_list.push_back(stringf("(|%s_u| (|%s_h %s| state))", get_id(c->type), get_id(module), get_id(c->name))); init_list.push_back(stringf("(|%s_i| (|%s_h %s| state))", get_id(c->type), get_id(module), get_id(c->name))); hier.push_back(stringf(" (|%s_h| (|%s_h %s| state))\n", get_id(c->type), get_id(module), get_id(c->name))); trans.push_back(stringf(" (|%s_t| (|%s_h %s| state) (|%s_h %s| next_state))\n", get_id(c->type), get_id(module), get_id(c->name), get_id(module), get_id(c->name))); } string assert_expr = assert_list.empty() ? "true" : "(and"; if (!assert_list.empty()) { for (auto &str : assert_list) assert_expr += stringf("\n %s", str.c_str()); assert_expr += "\n)"; } decls.push_back(stringf("(define-fun |%s_a| ((state |%s_s|)) Bool %s)\n", get_id(module), get_id(module), assert_expr.c_str())); string assume_expr = assume_list.empty() ? "true" : "(and"; if (!assume_list.empty()) { for (auto &str : assume_list) assume_expr += stringf("\n %s", str.c_str()); assume_expr += "\n)"; } decls.push_back(stringf("(define-fun |%s_u| ((state |%s_s|)) Bool %s)\n", get_id(module), get_id(module), assume_expr.c_str())); string init_expr = init_list.empty() ? "true" : "(and"; if (!init_list.empty()) { for (auto &str : init_list) init_expr += stringf("\n %s", str.c_str()); init_expr += "\n)"; } decls.push_back(stringf("(define-fun |%s_i| ((state |%s_s|)) Bool %s)\n", get_id(module), get_id(module), init_expr.c_str())); } void write(std::ostream &f) { f << stringf("; yosys-smt2-module %s\n", get_id(module)); for (auto it : decls) f << it; f << stringf("(define-fun |%s_h| ((state |%s_s|)) Bool ", get_id(module), get_id(module)); if (GetSize(hier) > 1) { f << "(and\n"; for (auto it : hier) f << it; f << "))\n"; } else if (GetSize(hier) == 1) f << "\n" + hier.front() + ")\n"; else f << "true)\n"; f << stringf("(define-fun |%s_t| ((state |%s_s|) (next_state |%s_s|)) Bool ", get_id(module), get_id(module), get_id(module)); if (GetSize(trans) > 1) { f << "(and\n"; for (auto it : trans) f << it; f << "))"; } else if (GetSize(trans) == 1) f << "\n" + trans.front() + ")"; else f << "true)"; f << stringf(" ; end of module %s\n", get_id(module)); } }; struct Smt2Backend : public Backend { Smt2Backend() : Backend("smt2", "write design to SMT-LIBv2 file") { } virtual void help() { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" write_smt2 [options] [filename]\n"); log("\n"); log("Write a SMT-LIBv2 [1] description of the current design. For a module with name\n"); log("'' this will declare the sort '_s' (state of the module) and the\n"); log("functions operating on that state.\n"); log("\n"); log("The '_s' sort represents a module state. Additional '_n' functions\n"); log("are provided that can be used to access the values of the signals in the module.\n"); log("By default only ports, registers, and wires with the 'keep' attribute set are\n"); log("made available via such functions. Without the -bv option, multi-bit wires are\n"); log("exported as separate functions of type Bool for the individual bits. With the\n"); log("-bv option multi-bit wires are exported as single functions of type BitVec.\n"); log("\n"); log("The '_t' function evaluates to 'true' when the given pair of states\n"); log("describes a valid state transition.\n"); log("\n"); log("The '_a' function evaluates to 'true' when the given state satisfies\n"); log("the asserts in the module.\n"); log("\n"); log("The '_u' function evaluates to 'true' when the given state satisfies\n"); log("the assumptions in the module.\n"); log("\n"); log("The '_i' function evaluates to 'true' when the given state conforms\n"); log("to the initial state. Furthermore the '_is' function should be asserted\n"); log("to be true for initial states in addition to '_i', and should be\n"); log("asserted to be false for non-initial states.\n"); log("\n"); log("For hierarchical designs, the '_h' function must be asserted for each\n"); log("state to establish the design hierarchy. The '_h ' function\n"); log("evaluates to the state corresponding to the given cell within .\n"); log("\n"); log(" -verbose\n"); log(" this will print the recursive walk used to export the modules.\n"); log("\n"); log(" -bv\n"); log(" enable support for BitVec (FixedSizeBitVectors theory). with this\n"); log(" option set multi-bit wires are represented using the BitVec sort and\n"); log(" support for coarse grain cells (incl. arithmetic) is enabled.\n"); log("\n"); log(" -mem\n"); log(" enable support for memories (via ArraysEx theory). this option\n"); log(" also implies -bv. only $mem cells without merged registers in\n"); log(" read ports are supported. call \"memory\" with -nordff to make sure\n"); log(" that no registers are merged into $mem read ports. '_m' functions\n"); log(" will be generated for accessing the arrays that are used to represent\n"); log(" memories.\n"); log("\n"); log(" -wires\n"); log(" create '_n' functions for all public wires. by default only ports,\n"); log(" registers, and wires with the 'keep' attribute set are exported.\n"); log("\n"); log(" -tpl \n"); log(" use the given template file. the line containing only the token '%%%%'\n"); log(" is replaced with the regular output of this command.\n"); log("\n"); log("[1] For more information on SMT-LIBv2 visit http://smt-lib.org/ or read David\n"); log("R. Cok's tutorial: http://www.grammatech.com/resources/smt/SMTLIBTutorial.pdf\n"); log("\n"); log("---------------------------------------------------------------------------\n"); log("\n"); log("Example:\n"); log("\n"); log("Consider the following module (test.v). We want to prove that the output can\n"); log("never transition from a non-zero value to a zero value.\n"); log("\n"); log(" module test(input clk, output reg [3:0] y);\n"); log(" always @(posedge clk)\n"); log(" y <= (y << 1) | ^y;\n"); log(" endmodule\n"); log("\n"); log("For this proof we create the following template (test.tpl).\n"); log("\n"); log(" ; we need QF_UFBV for this poof\n"); log(" (set-logic QF_UFBV)\n"); log("\n"); log(" ; insert the auto-generated code here\n"); log(" %%%%\n"); log("\n"); log(" ; declare two state variables s1 and s2\n"); log(" (declare-fun s1 () test_s)\n"); log(" (declare-fun s2 () test_s)\n"); log("\n"); log(" ; state s2 is the successor of state s1\n"); log(" (assert (test_t s1 s2))\n"); log("\n"); log(" ; we are looking for a model with y non-zero in s1\n"); log(" (assert (distinct (|test_n y| s1) #b0000))\n"); log("\n"); log(" ; we are looking for a model with y zero in s2\n"); log(" (assert (= (|test_n y| s2) #b0000))\n"); log("\n"); log(" ; is there such a model?\n"); log(" (check-sat)\n"); log("\n"); log("The following yosys script will create a 'test.smt2' file for our proof:\n"); log("\n"); log(" read_verilog test.v\n"); log(" hierarchy -check; proc; opt; check -assert\n"); log(" write_smt2 -bv -tpl test.tpl test.smt2\n"); log("\n"); log("Running 'cvc4 test.smt2' will print 'unsat' because y can never transition\n"); log("from non-zero to zero in the test design.\n"); log("\n"); } virtual void execute(std::ostream *&f, std::string filename, std::vector args, RTLIL::Design *design) { std::ifstream template_f; bool bvmode = false, memmode = false, wiresmode = false, verbose = false; log_header(design, "Executing SMT2 backend.\n"); size_t argidx; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-tpl" && argidx+1 < args.size()) { template_f.open(args[++argidx]); if (template_f.fail()) log_error("Can't open template file `%s'.\n", args[argidx].c_str()); continue; } if (args[argidx] == "-bv") { bvmode = true; continue; } if (args[argidx] == "-mem") { bvmode = true; memmode = true; continue; } if (args[argidx] == "-wires") { wiresmode = true; continue; } if (args[argidx] == "-verbose") { verbose = true; continue; } break; } extra_args(f, filename, args, argidx); if (template_f.is_open()) { std::string line; while (std::getline(template_f, line)) { int indent = 0; while (indent < GetSize(line) && (line[indent] == ' ' || line[indent] == '\t')) indent++; if (line.substr(indent, 2) == "%%") break; *f << line << std::endl; } } *f << stringf("; SMT-LIBv2 description generated by %s\n", yosys_version_str); std::vector sorted_modules; // extract module dependencies std::map> module_deps; for (auto &mod_it : design->modules_) { module_deps[mod_it.second] = std::set(); for (auto &cell_it : mod_it.second->cells_) if (design->modules_.count(cell_it.second->type) > 0) module_deps[mod_it.second].insert(design->modules_.at(cell_it.second->type)); } // simple good-enough topological sort // (O(n*m) on n elements and depth m) while (module_deps.size() > 0) { size_t sorted_modules_idx = sorted_modules.size(); for (auto &it : module_deps) { for (auto &dep : it.second) if (module_deps.count(dep) > 0) goto not_ready_yet; // log("Next in topological sort: %s\n", RTLIL::id2cstr(it.first->name)); sorted_modules.push_back(it.first); not_ready_yet:; } if (sorted_modules_idx == sorted_modules.size()) log_error("Cyclic dependency between modules found! Cycle includes module %s.\n", RTLIL::id2cstr(module_deps.begin()->first->name)); while (sorted_modules_idx < sorted_modules.size()) module_deps.erase(sorted_modules.at(sorted_modules_idx++)); } Module *topmod = design->top_module(); std::string topmod_id; for (auto module : sorted_modules) { if (module->get_bool_attribute("\\blackbox") || module->has_memories_warn() || module->has_processes_warn()) continue; log("Creating SMT-LIBv2 representation of module %s.\n", log_id(module)); Smt2Worker worker(module, bvmode, memmode, wiresmode, verbose); worker.run(); worker.write(*f); if (module == topmod) topmod_id = worker.get_id(module); } if (topmod) *f << stringf("; yosys-smt2-topmod %s\n", topmod_id.c_str()); *f << stringf("; end of yosys output\n"); if (template_f.is_open()) { std::string line; while (std::getline(template_f, line)) *f << line << std::endl; } } } Smt2Backend; PRIVATE_NAMESPACE_END