From: Eddie Hung Date: Fri, 7 Jun 2019 22:44:57 +0000 (-0700) Subject: Fix spacing from spaces to tabs X-Git-Tag: yosys-0.9~78 X-Git-Url: https://git.libre-soc.org/?a=commitdiff_plain;h=2b350401c4577d54c0d460240e2d2847d2eeadc4;p=yosys.git Fix spacing from spaces to tabs --- diff --git a/frontends/aiger/aigerparse.cc b/frontends/aiger/aigerparse.cc index 32be4cf6c..68552fd06 100644 --- a/frontends/aiger/aigerparse.cc +++ b/frontends/aiger/aigerparse.cc @@ -34,389 +34,389 @@ YOSYS_NAMESPACE_BEGIN AigerReader::AigerReader(RTLIL::Design *design, std::istream &f, RTLIL::IdString module_name, RTLIL::IdString clk_name) - : design(design), f(f), clk_name(clk_name) + : design(design), f(f), clk_name(clk_name) { - module = new RTLIL::Module; - module->name = module_name; - if (design->module(module->name)) - log_error("Duplicate definition of module %s!\n", log_id(module->name)); + module = new RTLIL::Module; + module->name = module_name; + if (design->module(module->name)) + log_error("Duplicate definition of module %s!\n", log_id(module->name)); } void AigerReader::parse_aiger() { - std::string header; - f >> header; - if (header != "aag" && header != "aig") - log_error("Unsupported AIGER file!\n"); - - // Parse rest of header - if (!(f >> M >> I >> L >> O >> A)) - log_error("Invalid AIGER header\n"); - - // Optional values - B = C = J = F = 0; - if (f.peek() != ' ') goto end_of_header; - if (!(f >> B)) log_error("Invalid AIGER header\n"); - if (f.peek() != ' ') goto end_of_header; - if (!(f >> C)) log_error("Invalid AIGER header\n"); - if (f.peek() != ' ') goto end_of_header; - if (!(f >> J)) log_error("Invalid AIGER header\n"); - if (f.peek() != ' ') goto end_of_header; - if (!(f >> F)) log_error("Invalid AIGER header\n"); + std::string header; + f >> header; + if (header != "aag" && header != "aig") + log_error("Unsupported AIGER file!\n"); + + // Parse rest of header + if (!(f >> M >> I >> L >> O >> A)) + log_error("Invalid AIGER header\n"); + + // Optional values + B = C = J = F = 0; + if (f.peek() != ' ') goto end_of_header; + if (!(f >> B)) log_error("Invalid AIGER header\n"); + if (f.peek() != ' ') goto end_of_header; + if (!(f >> C)) log_error("Invalid AIGER header\n"); + if (f.peek() != ' ') goto end_of_header; + if (!(f >> J)) log_error("Invalid AIGER header\n"); + if (f.peek() != ' ') goto end_of_header; + if (!(f >> F)) log_error("Invalid AIGER header\n"); end_of_header: - std::string line; - std::getline(f, line); // Ignore up to start of next line, as standard - // says anything that follows could be used for - // optional sections - - log_debug("M=%u I=%u L=%u O=%u A=%u B=%u C=%u J=%u F=%u\n", M, I, L, O, A, B, C, J, F); - - line_count = 1; - - if (header == "aag") - parse_aiger_ascii(); - else if (header == "aig") - parse_aiger_binary(); - else - log_abort(); - - RTLIL::Wire* n0 = module->wire("\\n0"); - if (n0) - module->connect(n0, RTLIL::S0); - - for (unsigned i = 0; i < outputs.size(); ++i) { - RTLIL::Wire *wire = outputs[i]; - if (wire->port_input) { - RTLIL::Wire *o_wire = module->addWire(wire->name.str() + "_o"); - o_wire->port_output = true; - wire->port_output = false; - module->connect(o_wire, wire); - outputs[i] = o_wire; - } - } - - // Parse footer (symbol table, comments, etc.) - unsigned l1; - std::string s; - for (int c = f.peek(); c != EOF; c = f.peek(), ++line_count) { - if (c == 'i' || c == 'l' || c == 'o' || c == 'b') { - f.ignore(1); - if (!(f >> l1 >> s)) - log_error("Line %u cannot be interpreted as a symbol entry!\n", line_count); - - if ((c == 'i' && l1 > inputs.size()) || (c == 'l' && l1 > latches.size()) || (c == 'o' && l1 > outputs.size())) - log_error("Line %u has invalid symbol position!\n", line_count); - - RTLIL::Wire* wire; - if (c == 'i') wire = inputs[l1]; - else if (c == 'l') wire = latches[l1]; - else if (c == 'o') wire = outputs[l1]; - else if (c == 'b') wire = bad_properties[l1]; - else log_abort(); - - module->rename(wire, stringf("\\%s", s.c_str())); - } - else if (c == 'j' || c == 'f') { - // TODO - } - else if (c == 'c') { - f.ignore(1); - if (f.peek() == '\n') - break; - // Else constraint (TODO) - } - else - log_error("Line %u: cannot interpret first character '%c'!\n", line_count, c); - std::getline(f, line); // Ignore up to start of next line - } - - module->fixup_ports(); - design->add(module); + std::string line; + std::getline(f, line); // Ignore up to start of next line, as standard + // says anything that follows could be used for + // optional sections + + log_debug("M=%u I=%u L=%u O=%u A=%u B=%u C=%u J=%u F=%u\n", M, I, L, O, A, B, C, J, F); + + line_count = 1; + + if (header == "aag") + parse_aiger_ascii(); + else if (header == "aig") + parse_aiger_binary(); + else + log_abort(); + + RTLIL::Wire* n0 = module->wire("\\n0"); + if (n0) + module->connect(n0, RTLIL::S0); + + for (unsigned i = 0; i < outputs.size(); ++i) { + RTLIL::Wire *wire = outputs[i]; + if (wire->port_input) { + RTLIL::Wire *o_wire = module->addWire(wire->name.str() + "_o"); + o_wire->port_output = true; + wire->port_output = false; + module->connect(o_wire, wire); + outputs[i] = o_wire; + } + } + + // Parse footer (symbol table, comments, etc.) + unsigned l1; + std::string s; + for (int c = f.peek(); c != EOF; c = f.peek(), ++line_count) { + if (c == 'i' || c == 'l' || c == 'o' || c == 'b') { + f.ignore(1); + if (!(f >> l1 >> s)) + log_error("Line %u cannot be interpreted as a symbol entry!\n", line_count); + + if ((c == 'i' && l1 > inputs.size()) || (c == 'l' && l1 > latches.size()) || (c == 'o' && l1 > outputs.size())) + log_error("Line %u has invalid symbol position!\n", line_count); + + RTLIL::Wire* wire; + if (c == 'i') wire = inputs[l1]; + else if (c == 'l') wire = latches[l1]; + else if (c == 'o') wire = outputs[l1]; + else if (c == 'b') wire = bad_properties[l1]; + else log_abort(); + + module->rename(wire, stringf("\\%s", s.c_str())); + } + else if (c == 'j' || c == 'f') { + // TODO + } + else if (c == 'c') { + f.ignore(1); + if (f.peek() == '\n') + break; + // Else constraint (TODO) + } + else + log_error("Line %u: cannot interpret first character '%c'!\n", line_count, c); + std::getline(f, line); // Ignore up to start of next line + } + + module->fixup_ports(); + design->add(module); } static RTLIL::Wire* createWireIfNotExists(RTLIL::Module *module, unsigned literal) { - const unsigned variable = literal >> 1; - const bool invert = literal & 1; - RTLIL::IdString wire_name(stringf("\\n%d%s", variable, invert ? "_inv" : "")); // FIXME: is "_inv" the right suffix? - RTLIL::Wire *wire = module->wire(wire_name); - if (wire) return wire; - log_debug("Creating %s\n", wire_name.c_str()); - wire = module->addWire(wire_name); - if (!invert) return wire; - RTLIL::IdString wire_inv_name(stringf("\\n%d", variable)); - RTLIL::Wire *wire_inv = module->wire(wire_inv_name); - if (wire_inv) { - if (module->cell(wire_inv_name)) return wire; - } - else { - log_debug("Creating %s\n", wire_inv_name.c_str()); - wire_inv = module->addWire(wire_inv_name); - } - - log_debug("Creating %s = ~%s\n", wire_name.c_str(), wire_inv_name.c_str()); - module->addNotGate(stringf("\\n%d_not", variable), wire_inv, wire); // FIXME: is "_not" the right suffix? - - return wire; + const unsigned variable = literal >> 1; + const bool invert = literal & 1; + RTLIL::IdString wire_name(stringf("\\n%d%s", variable, invert ? "_inv" : "")); // FIXME: is "_inv" the right suffix? + RTLIL::Wire *wire = module->wire(wire_name); + if (wire) return wire; + log_debug("Creating %s\n", wire_name.c_str()); + wire = module->addWire(wire_name); + if (!invert) return wire; + RTLIL::IdString wire_inv_name(stringf("\\n%d", variable)); + RTLIL::Wire *wire_inv = module->wire(wire_inv_name); + if (wire_inv) { + if (module->cell(wire_inv_name)) return wire; + } + else { + log_debug("Creating %s\n", wire_inv_name.c_str()); + wire_inv = module->addWire(wire_inv_name); + } + + log_debug("Creating %s = ~%s\n", wire_name.c_str(), wire_inv_name.c_str()); + module->addNotGate(stringf("\\n%d_not", variable), wire_inv, wire); // FIXME: is "_not" the right suffix? + + return wire; } void AigerReader::parse_aiger_ascii() { - std::string line; - std::stringstream ss; - - unsigned l1, l2, l3; - - // Parse inputs - for (unsigned i = 1; i <= I; ++i, ++line_count) { - if (!(f >> l1)) - log_error("Line %u cannot be interpreted as an input!\n", line_count); - log_debug("%d is an input\n", l1); - log_assert(!(l1 & 1)); // TODO: Inputs can't be inverted? - RTLIL::Wire *wire = createWireIfNotExists(module, l1); - wire->port_input = true; - inputs.push_back(wire); - } - - // Parse latches - RTLIL::Wire *clk_wire = nullptr; - if (L > 0) { - clk_wire = module->wire(clk_name); - log_assert(!clk_wire); - log_debug("Creating %s\n", clk_name.c_str()); - clk_wire = module->addWire(clk_name); - clk_wire->port_input = true; - } - for (unsigned i = 0; i < L; ++i, ++line_count) { - if (!(f >> l1 >> l2)) - log_error("Line %u cannot be interpreted as a latch!\n", line_count); - log_debug("%d %d is a latch\n", l1, l2); - log_assert(!(l1 & 1)); // TODO: Latch outputs can't be inverted? - RTLIL::Wire *q_wire = createWireIfNotExists(module, l1); - RTLIL::Wire *d_wire = createWireIfNotExists(module, l2); - - module->addDffGate(NEW_ID, clk_wire, d_wire, q_wire); - - // Reset logic is optional in AIGER 1.9 - if (f.peek() == ' ') { - if (!(f >> l3)) - log_error("Line %u cannot be interpreted as a latch!\n", line_count); - - if (l3 == 0) - q_wire->attributes["\\init"] = RTLIL::S0; - else if (l3 == 1) - q_wire->attributes["\\init"] = RTLIL::S1; - else if (l3 == l1) { - //q_wire->attributes["\\init"] = RTLIL::Const(RTLIL::State::Sx); - } - else - log_error("Line %u has invalid reset literal for latch!\n", line_count); - } - else { - // AIGER latches are assumed to be initialized to zero - q_wire->attributes["\\init"] = RTLIL::S0; - } - latches.push_back(q_wire); - } - - // Parse outputs - for (unsigned i = 0; i < O; ++i, ++line_count) { - if (!(f >> l1)) - log_error("Line %u cannot be interpreted as an output!\n", line_count); - - log_debug("%d is an output\n", l1); - RTLIL::Wire *wire = createWireIfNotExists(module, l1); - wire->port_output = true; - outputs.push_back(wire); - } - - // Parse bad properties - for (unsigned i = 0; i < B; ++i, ++line_count) { - if (!(f >> l1)) - log_error("Line %u cannot be interpreted as a bad state property!\n", line_count); - - log_debug("%d is a bad state property\n", l1); - RTLIL::Wire *wire = createWireIfNotExists(module, l1); - wire->port_output = true; - bad_properties.push_back(wire); - } - - // TODO: Parse invariant constraints - for (unsigned i = 0; i < C; ++i, ++line_count) - std::getline(f, line); // Ignore up to start of next line - - // TODO: Parse justice properties - for (unsigned i = 0; i < J; ++i, ++line_count) - std::getline(f, line); // Ignore up to start of next line - - // TODO: Parse fairness constraints - for (unsigned i = 0; i < F; ++i, ++line_count) - std::getline(f, line); // Ignore up to start of next line - - // Parse AND - for (unsigned i = 0; i < A; ++i) { - if (!(f >> l1 >> l2 >> l3)) - log_error("Line %u cannot be interpreted as an AND!\n", line_count); - - log_debug("%d %d %d is an AND\n", l1, l2, l3); - log_assert(!(l1 & 1)); // TODO: Output of ANDs can't be inverted? - RTLIL::Wire *o_wire = createWireIfNotExists(module, l1); - RTLIL::Wire *i1_wire = createWireIfNotExists(module, l2); - RTLIL::Wire *i2_wire = createWireIfNotExists(module, l3); - module->addAndGate(NEW_ID, i1_wire, i2_wire, o_wire); - } - std::getline(f, line); // Ignore up to start of next line + std::string line; + std::stringstream ss; + + unsigned l1, l2, l3; + + // Parse inputs + for (unsigned i = 1; i <= I; ++i, ++line_count) { + if (!(f >> l1)) + log_error("Line %u cannot be interpreted as an input!\n", line_count); + log_debug("%d is an input\n", l1); + log_assert(!(l1 & 1)); // TODO: Inputs can't be inverted? + RTLIL::Wire *wire = createWireIfNotExists(module, l1); + wire->port_input = true; + inputs.push_back(wire); + } + + // Parse latches + RTLIL::Wire *clk_wire = nullptr; + if (L > 0) { + clk_wire = module->wire(clk_name); + log_assert(!clk_wire); + log_debug("Creating %s\n", clk_name.c_str()); + clk_wire = module->addWire(clk_name); + clk_wire->port_input = true; + } + for (unsigned i = 0; i < L; ++i, ++line_count) { + if (!(f >> l1 >> l2)) + log_error("Line %u cannot be interpreted as a latch!\n", line_count); + log_debug("%d %d is a latch\n", l1, l2); + log_assert(!(l1 & 1)); // TODO: Latch outputs can't be inverted? + RTLIL::Wire *q_wire = createWireIfNotExists(module, l1); + RTLIL::Wire *d_wire = createWireIfNotExists(module, l2); + + module->addDffGate(NEW_ID, clk_wire, d_wire, q_wire); + + // Reset logic is optional in AIGER 1.9 + if (f.peek() == ' ') { + if (!(f >> l3)) + log_error("Line %u cannot be interpreted as a latch!\n", line_count); + + if (l3 == 0) + q_wire->attributes["\\init"] = RTLIL::S0; + else if (l3 == 1) + q_wire->attributes["\\init"] = RTLIL::S1; + else if (l3 == l1) { + //q_wire->attributes["\\init"] = RTLIL::Const(RTLIL::State::Sx); + } + else + log_error("Line %u has invalid reset literal for latch!\n", line_count); + } + else { + // AIGER latches are assumed to be initialized to zero + q_wire->attributes["\\init"] = RTLIL::S0; + } + latches.push_back(q_wire); + } + + // Parse outputs + for (unsigned i = 0; i < O; ++i, ++line_count) { + if (!(f >> l1)) + log_error("Line %u cannot be interpreted as an output!\n", line_count); + + log_debug("%d is an output\n", l1); + RTLIL::Wire *wire = createWireIfNotExists(module, l1); + wire->port_output = true; + outputs.push_back(wire); + } + + // Parse bad properties + for (unsigned i = 0; i < B; ++i, ++line_count) { + if (!(f >> l1)) + log_error("Line %u cannot be interpreted as a bad state property!\n", line_count); + + log_debug("%d is a bad state property\n", l1); + RTLIL::Wire *wire = createWireIfNotExists(module, l1); + wire->port_output = true; + bad_properties.push_back(wire); + } + + // TODO: Parse invariant constraints + for (unsigned i = 0; i < C; ++i, ++line_count) + std::getline(f, line); // Ignore up to start of next line + + // TODO: Parse justice properties + for (unsigned i = 0; i < J; ++i, ++line_count) + std::getline(f, line); // Ignore up to start of next line + + // TODO: Parse fairness constraints + for (unsigned i = 0; i < F; ++i, ++line_count) + std::getline(f, line); // Ignore up to start of next line + + // Parse AND + for (unsigned i = 0; i < A; ++i) { + if (!(f >> l1 >> l2 >> l3)) + log_error("Line %u cannot be interpreted as an AND!\n", line_count); + + log_debug("%d %d %d is an AND\n", l1, l2, l3); + log_assert(!(l1 & 1)); // TODO: Output of ANDs can't be inverted? + RTLIL::Wire *o_wire = createWireIfNotExists(module, l1); + RTLIL::Wire *i1_wire = createWireIfNotExists(module, l2); + RTLIL::Wire *i2_wire = createWireIfNotExists(module, l3); + module->addAndGate(NEW_ID, i1_wire, i2_wire, o_wire); + } + std::getline(f, line); // Ignore up to start of next line } static unsigned parse_next_delta_literal(std::istream &f, unsigned ref) { - unsigned x = 0, i = 0; - unsigned char ch; - while ((ch = f.get()) & 0x80) - x |= (ch & 0x7f) << (7 * i++); - return ref - (x | (ch << (7 * i))); + unsigned x = 0, i = 0; + unsigned char ch; + while ((ch = f.get()) & 0x80) + x |= (ch & 0x7f) << (7 * i++); + return ref - (x | (ch << (7 * i))); } void AigerReader::parse_aiger_binary() { - unsigned l1, l2, l3; - std::string line; - - // Parse inputs - for (unsigned i = 1; i <= I; ++i) { - RTLIL::Wire *wire = createWireIfNotExists(module, i << 1); - wire->port_input = true; - inputs.push_back(wire); - } - - // Parse latches - RTLIL::Wire *clk_wire = nullptr; - if (L > 0) { - clk_wire = module->wire(clk_name); - log_assert(!clk_wire); - log_debug("Creating %s\n", clk_name.c_str()); - clk_wire = module->addWire(clk_name); - clk_wire->port_input = true; - } - l1 = (I+1) * 2; - for (unsigned i = 0; i < L; ++i, ++line_count, l1 += 2) { - if (!(f >> l2)) - log_error("Line %u cannot be interpreted as a latch!\n", line_count); - log_debug("%d %d is a latch\n", l1, l2); - RTLIL::Wire *q_wire = createWireIfNotExists(module, l1); - RTLIL::Wire *d_wire = createWireIfNotExists(module, l2); - - module->addDff(NEW_ID, clk_wire, d_wire, q_wire); - - // Reset logic is optional in AIGER 1.9 - if (f.peek() == ' ') { - if (!(f >> l3)) - log_error("Line %u cannot be interpreted as a latch!\n", line_count); - - if (l3 == 0) - q_wire->attributes["\\init"] = RTLIL::S0; - else if (l3 == 1) - q_wire->attributes["\\init"] = RTLIL::S1; - else if (l3 == l1) { - //q_wire->attributes["\\init"] = RTLIL::Const(RTLIL::State::Sx); - } - else - log_error("Line %u has invalid reset literal for latch!\n", line_count); - } - else { - // AIGER latches are assumed to be initialized to zero - q_wire->attributes["\\init"] = RTLIL::S0; - } - latches.push_back(q_wire); - } - - // Parse outputs - for (unsigned i = 0; i < O; ++i, ++line_count) { - if (!(f >> l1)) - log_error("Line %u cannot be interpreted as an output!\n", line_count); - - log_debug("%d is an output\n", l1); - RTLIL::Wire *wire = createWireIfNotExists(module, l1); - wire->port_output = true; - outputs.push_back(wire); - } - std::getline(f, line); // Ignore up to start of next line - - // Parse bad properties - for (unsigned i = 0; i < B; ++i, ++line_count) { - if (!(f >> l1)) - log_error("Line %u cannot be interpreted as a bad state property!\n", line_count); - - log_debug("%d is a bad state property\n", l1); - RTLIL::Wire *wire = createWireIfNotExists(module, l1); - wire->port_output = true; - bad_properties.push_back(wire); - } - if (B > 0) - std::getline(f, line); // Ignore up to start of next line - - // TODO: Parse invariant constraints - for (unsigned i = 0; i < C; ++i, ++line_count) - std::getline(f, line); // Ignore up to start of next line - - // TODO: Parse justice properties - for (unsigned i = 0; i < J; ++i, ++line_count) - std::getline(f, line); // Ignore up to start of next line - - // TODO: Parse fairness constraints - for (unsigned i = 0; i < F; ++i, ++line_count) - std::getline(f, line); // Ignore up to start of next line - - // Parse AND - l1 = (I+L+1) << 1; - for (unsigned i = 0; i < A; ++i, ++line_count, l1 += 2) { - l2 = parse_next_delta_literal(f, l1); - l3 = parse_next_delta_literal(f, l2); - - log_debug("%d %d %d is an AND\n", l1, l2, l3); - log_assert(!(l1 & 1)); // TODO: Output of ANDs can't be inverted? - RTLIL::Wire *o_wire = createWireIfNotExists(module, l1); - RTLIL::Wire *i1_wire = createWireIfNotExists(module, l2); - RTLIL::Wire *i2_wire = createWireIfNotExists(module, l3); - - RTLIL::Cell *and_cell = module->addCell(NEW_ID, "$_AND_"); - and_cell->setPort("\\A", i1_wire); - and_cell->setPort("\\B", i2_wire); - and_cell->setPort("\\Y", o_wire); - } + unsigned l1, l2, l3; + std::string line; + + // Parse inputs + for (unsigned i = 1; i <= I; ++i) { + RTLIL::Wire *wire = createWireIfNotExists(module, i << 1); + wire->port_input = true; + inputs.push_back(wire); + } + + // Parse latches + RTLIL::Wire *clk_wire = nullptr; + if (L > 0) { + clk_wire = module->wire(clk_name); + log_assert(!clk_wire); + log_debug("Creating %s\n", clk_name.c_str()); + clk_wire = module->addWire(clk_name); + clk_wire->port_input = true; + } + l1 = (I+1) * 2; + for (unsigned i = 0; i < L; ++i, ++line_count, l1 += 2) { + if (!(f >> l2)) + log_error("Line %u cannot be interpreted as a latch!\n", line_count); + log_debug("%d %d is a latch\n", l1, l2); + RTLIL::Wire *q_wire = createWireIfNotExists(module, l1); + RTLIL::Wire *d_wire = createWireIfNotExists(module, l2); + + module->addDff(NEW_ID, clk_wire, d_wire, q_wire); + + // Reset logic is optional in AIGER 1.9 + if (f.peek() == ' ') { + if (!(f >> l3)) + log_error("Line %u cannot be interpreted as a latch!\n", line_count); + + if (l3 == 0) + q_wire->attributes["\\init"] = RTLIL::S0; + else if (l3 == 1) + q_wire->attributes["\\init"] = RTLIL::S1; + else if (l3 == l1) { + //q_wire->attributes["\\init"] = RTLIL::Const(RTLIL::State::Sx); + } + else + log_error("Line %u has invalid reset literal for latch!\n", line_count); + } + else { + // AIGER latches are assumed to be initialized to zero + q_wire->attributes["\\init"] = RTLIL::S0; + } + latches.push_back(q_wire); + } + + // Parse outputs + for (unsigned i = 0; i < O; ++i, ++line_count) { + if (!(f >> l1)) + log_error("Line %u cannot be interpreted as an output!\n", line_count); + + log_debug("%d is an output\n", l1); + RTLIL::Wire *wire = createWireIfNotExists(module, l1); + wire->port_output = true; + outputs.push_back(wire); + } + std::getline(f, line); // Ignore up to start of next line + + // Parse bad properties + for (unsigned i = 0; i < B; ++i, ++line_count) { + if (!(f >> l1)) + log_error("Line %u cannot be interpreted as a bad state property!\n", line_count); + + log_debug("%d is a bad state property\n", l1); + RTLIL::Wire *wire = createWireIfNotExists(module, l1); + wire->port_output = true; + bad_properties.push_back(wire); + } + if (B > 0) + std::getline(f, line); // Ignore up to start of next line + + // TODO: Parse invariant constraints + for (unsigned i = 0; i < C; ++i, ++line_count) + std::getline(f, line); // Ignore up to start of next line + + // TODO: Parse justice properties + for (unsigned i = 0; i < J; ++i, ++line_count) + std::getline(f, line); // Ignore up to start of next line + + // TODO: Parse fairness constraints + for (unsigned i = 0; i < F; ++i, ++line_count) + std::getline(f, line); // Ignore up to start of next line + + // Parse AND + l1 = (I+L+1) << 1; + for (unsigned i = 0; i < A; ++i, ++line_count, l1 += 2) { + l2 = parse_next_delta_literal(f, l1); + l3 = parse_next_delta_literal(f, l2); + + log_debug("%d %d %d is an AND\n", l1, l2, l3); + log_assert(!(l1 & 1)); // TODO: Output of ANDs can't be inverted? + RTLIL::Wire *o_wire = createWireIfNotExists(module, l1); + RTLIL::Wire *i1_wire = createWireIfNotExists(module, l2); + RTLIL::Wire *i2_wire = createWireIfNotExists(module, l3); + + RTLIL::Cell *and_cell = module->addCell(NEW_ID, "$_AND_"); + and_cell->setPort("\\A", i1_wire); + and_cell->setPort("\\B", i2_wire); + and_cell->setPort("\\Y", o_wire); + } } struct AigerFrontend : public Frontend { - AigerFrontend() : Frontend("aiger", "read AIGER file") { } - void help() YS_OVERRIDE - { - // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| - log("\n"); - log(" read_aiger [options] [filename]\n"); - log("\n"); - log("Load module from an AIGER file into the current design.\n"); - log("\n"); - log(" -module_name \n"); - log(" Name of module to be created (default: )" + AigerFrontend() : Frontend("aiger", "read AIGER file") { } + void help() YS_OVERRIDE + { + // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| + log("\n"); + log(" read_aiger [options] [filename]\n"); + log("\n"); + log("Load module from an AIGER file into the current design.\n"); + log("\n"); + log(" -module_name \n"); + log(" Name of module to be created (default: " #ifdef _WIN32 - "top" // FIXME + "top" // FIXME #else - "" + "" #endif - ")\n"); - log("\n"); - log(" -clk_name \n"); - log(" AIGER latches to be transformed into posedge DFFs clocked by wire of"); - log(" this name (default: clk)\n"); - log("\n"); - } - void execute(std::istream *&f, std::string filename, std::vector args, RTLIL::Design *design) YS_OVERRIDE - { - log_header(design, "Executing AIGER frontend.\n"); - - RTLIL::IdString clk_name = "\\clk"; - RTLIL::IdString module_name; + ")\n"); + log("\n"); + log(" -clk_name \n"); + log(" AIGER latches to be transformed into posedge DFFs clocked by wire of"); + log(" this name (default: clk)\n"); + log("\n"); + } + void execute(std::istream *&f, std::string filename, std::vector args, RTLIL::Design *design) YS_OVERRIDE + { + log_header(design, "Executing AIGER frontend.\n"); + + RTLIL::IdString clk_name = "\\clk"; + RTLIL::IdString module_name; size_t argidx; for (argidx = 1; argidx < args.size(); argidx++) { @@ -433,19 +433,19 @@ struct AigerFrontend : public Frontend { } extra_args(f, filename, args, argidx); - if (module_name.empty()) { + if (module_name.empty()) { #ifdef _WIN32 - module_name = "top"; // FIXME: basename equivalent on Win32? + module_name = "top"; // FIXME: basename equivalent on Win32? #else - char* bn = strdup(filename.c_str()); - module_name = RTLIL::escape_id(bn); - free(bn); + char* bn = strdup(filename.c_str()); + module_name = RTLIL::escape_id(bn); + free(bn); #endif - } + } - AigerReader reader(design, *f, module_name, clk_name); + AigerReader reader(design, *f, module_name, clk_name); reader.parse_aiger(); - } + } } AigerFrontend; YOSYS_NAMESPACE_END