/* * yosys -- Yosys Open SYnthesis Suite * * Copyright (C) 2020 Alberto Gonzalez * * 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/register.h" #include "kernel/rtlil.h" #include "kernel/utils.h" #include "kernel/log.h" USING_YOSYS_NAMESPACE PRIVATE_NAMESPACE_BEGIN struct GliftWorker { private: bool is_top_module = false; bool opt_create_precise_model = false, opt_create_imprecise_model = false, opt_create_instrumented_model = false; bool opt_taintconstants = false, opt_keepoutputs = false, opt_simplecostmodel = false, opt_nocostmodel = false; bool opt_instrumentmore = false; std::vector new_taint_outputs; std::vector> meta_mux_selects; RTLIL::Module *module = nullptr; const RTLIL::IdString cost_model_wire_name = ID(__glift_weight); const RTLIL::IdString glift_attribute_name = ID(glift); RTLIL::SigSpec get_corresponding_taint_signal(RTLIL::SigSpec sig) { RTLIL::SigSpec ret; //Get the connected wire for the cell port: log_assert(sig.is_wire() || sig.is_fully_const()); log_assert(sig.is_wire() || sig.is_fully_const()); //Get a SigSpec for the corresponding taint signal for the cell port, creating one if necessary: if (sig.is_wire()) { RTLIL::Wire *w = module->wire(sig.as_wire()->name.str() + "_t"); if (w == nullptr) w = module->addWire(sig.as_wire()->name.str() + "_t", 1); ret = w; } else if (sig.is_fully_const() && opt_taintconstants) ret = RTLIL::State::S1; else if (sig.is_fully_const()) ret = RTLIL::State::S0; else log_cmd_error("Cell port SigSpec has unexpected type.\n"); //Finally, if the cell port was a module input or output, make sure the corresponding taint signal is marked, too: if(sig.is_wire() && sig.as_wire()->port_input) ret.as_wire()->port_input = true; if(sig.is_wire() && sig.as_wire()->port_output) new_taint_outputs.push_back(ret.as_wire()); return ret; } void add_precise_GLIFT_logic(const RTLIL::Cell *cell, RTLIL::SigSpec &port_a, RTLIL::SigSpec &port_a_taint, RTLIL::SigSpec &port_b, RTLIL::SigSpec &port_b_taint, RTLIL::SigSpec &port_y_taint) { //AKA AN2_SH2 or OR2_SH2 bool is_and = cell->type.in(ID($_AND_), ID($_NAND_)); RTLIL::SigSpec n_port_a = module->LogicNot(cell->name.str() + "_t_1_1", port_a, false, cell->get_src_attribute()); RTLIL::SigSpec n_port_b = module->LogicNot(cell->name.str() + "_t_1_2", port_b, false, cell->get_src_attribute()); auto subexpr1 = module->And(cell->name.str() + "_t_1_3", is_and? port_a : n_port_a, port_b_taint, false, cell->get_src_attribute()); auto subexpr2 = module->And(cell->name.str() + "_t_1_4", is_and? port_b : n_port_b, port_a_taint, false, cell->get_src_attribute()); auto subexpr3 = module->And(cell->name.str() + "_t_1_5", port_a_taint, port_b_taint, false, cell->get_src_attribute()); auto subexpr4 = module->Or(cell->name.str() + "_t_1_6", subexpr1, subexpr2, false, cell->get_src_attribute()); module->addOr(cell->name.str() + "_t_1_7", subexpr4, subexpr3, port_y_taint, false, cell->get_src_attribute()); } void add_imprecise_GLIFT_logic_1(const RTLIL::Cell *cell, RTLIL::SigSpec &port_a, RTLIL::SigSpec &port_a_taint, RTLIL::SigSpec &port_b, RTLIL::SigSpec &port_b_taint, RTLIL::SigSpec &port_y_taint) { //AKA AN2_SH3 or OR2_SH3 bool is_and = cell->type.in(ID($_AND_), ID($_NAND_)); RTLIL::SigSpec n_port_a = module->LogicNot(cell->name.str() + "_t_2_1", port_a, false, cell->get_src_attribute()); auto subexpr1 = module->And(cell->name.str() + "_t_2_2", is_and? port_b : n_port_a, is_and? port_a_taint : port_b_taint, false, cell->get_src_attribute()); module->addOr(cell->name.str() + "_t_2_3", is_and? port_b_taint : port_a_taint, subexpr1, port_y_taint, false, cell->get_src_attribute()); } void add_imprecise_GLIFT_logic_2(const RTLIL::Cell *cell, RTLIL::SigSpec &port_a, RTLIL::SigSpec &port_a_taint, RTLIL::SigSpec &port_b, RTLIL::SigSpec &port_b_taint, RTLIL::SigSpec &port_y_taint) { //AKA AN2_SH4 or OR2_SH4 bool is_and = cell->type.in(ID($_AND_), ID($_NAND_)); RTLIL::SigSpec n_port_b = module->LogicNot(cell->name.str() + "_t_3_1", port_b, false, cell->get_src_attribute()); auto subexpr1 = module->And(cell->name.str() + "_t_3_2", is_and? port_a : n_port_b, is_and? port_b_taint : port_a_taint, false, cell->get_src_attribute()); module->addOr(cell->name.str() + "_t_3_3", is_and? port_a_taint : port_b_taint, subexpr1, port_y_taint, false, cell->get_src_attribute()); } void add_imprecise_GLIFT_logic_3(const RTLIL::Cell *cell, RTLIL::SigSpec &port_a_taint, RTLIL::SigSpec &port_b_taint, RTLIL::SigSpec &port_y_taint) { //AKA AN2_SH5 or OR2_SH5 or XR2_SH2 module->addOr(cell->name.str() + "_t_4_1", port_a_taint, port_b_taint, port_y_taint, false, cell->get_src_attribute()); } void add_imprecise_GLIFT_logic_4(RTLIL::SigSpec &port_a_taint, RTLIL::SigSpec &port_y_taint) { module->connect(port_y_taint, port_a_taint); } void add_imprecise_GLIFT_logic_5(RTLIL::SigSpec &port_b_taint, RTLIL::SigSpec &port_y_taint) { module->connect(port_y_taint, port_b_taint); } void add_imprecise_GLIFT_logic_6(RTLIL::SigSpec &port_y_taint) { module->connect(port_y_taint, RTLIL::Const(1, 1)); } void add_imprecise_GLIFT_logic_7(RTLIL::SigSpec &port_y_taint) { module->connect(port_y_taint, RTLIL::Const(0, 1)); } void add_precise_GLIFT_mux(const RTLIL::Cell *cell, RTLIL::SigSpec &port_a, RTLIL::SigSpec &port_a_taint, RTLIL::SigSpec &port_b, RTLIL::SigSpec &port_b_taint, RTLIL::SigSpec &port_s, RTLIL::SigSpec &port_s_taint, RTLIL::SigSpec &port_y_taint) { //S&At | ~S&Bt | ~A&B&St | A&~B&St | At&St | Bt&St RTLIL::SigSpec n_port_a = module->LogicNot(cell->name.str() + "_t_4_1", port_a, false, cell->get_src_attribute()); RTLIL::SigSpec n_port_b = module->LogicNot(cell->name.str() + "_t_4_2", port_b, false, cell->get_src_attribute()); RTLIL::SigSpec n_port_s = module->LogicNot(cell->name.str() + "_t_4_3", port_s, false, cell->get_src_attribute()); auto subexpr1 = module->And(cell->name.str() + "_t_4_4", port_s, port_a_taint, false, cell->get_src_attribute()); auto subexpr2 = module->And(cell->name.str() + "_t_4_5", n_port_s, port_b_taint, false, cell->get_src_attribute()); auto subexpr3 = module->And(cell->name.str() + "_t_4_6", n_port_a, port_b, false, cell->get_src_attribute()); auto subexpr4 = module->And(cell->name.str() + "_t_4_7", subexpr3, port_s_taint, false, cell->get_src_attribute()); auto subexpr5 = module->And(cell->name.str() + "_t_4_8", port_a, n_port_b, false, cell->get_src_attribute()); auto subexpr6 = module->And(cell->name.str() + "_t_4_9", subexpr5, port_s_taint, false, cell->get_src_attribute()); auto subexpr7 = module->And(cell->name.str() + "_t_4_10", port_a_taint, port_s_taint, false, cell->get_src_attribute()); auto subexpr8 = module->And(cell->name.str() + "_t_4_11", port_b_taint, port_s_taint, false, cell->get_src_attribute()); auto subexpr9 = module->Or(cell->name.str() + "_t_4_12", subexpr1, subexpr2, false, cell->get_src_attribute()); auto subexpr10 = module->Or(cell->name.str() + "_t_4_13", subexpr4, subexpr6, false, cell->get_src_attribute()); auto subexpr11 = module->Or(cell->name.str() + "_t_4_14", subexpr7, subexpr8, false, cell->get_src_attribute()); auto subexpr12 = module->Or(cell->name.str() + "_t_4_15", subexpr9, subexpr10, false, cell->get_src_attribute()); module->addOr(cell->name.str() + "_t_4_16", subexpr11, subexpr12, port_y_taint, false, cell->get_src_attribute()); } RTLIL::SigSpec score_metamux_select(const RTLIL::SigSpec &metamux_select, const RTLIL::IdString celltype) { log_assert(metamux_select.is_wire()); if (opt_simplecostmodel) { //The complex model is an area model, so a lower score should mean smaller. //In this case, a nonzero hole metamux select value means less logic. //Thus we should invert the ReduceOr over the metamux_select signal. RTLIL::SigSpec pmux_select = module->ReduceOr(metamux_select.as_wire()->name.str() + "_nonzero", metamux_select); return module->Pmux(NEW_ID, RTLIL::Const(1), RTLIL::Const(0), pmux_select, metamux_select.as_wire()->get_src_attribute()); } else { auto select_width = metamux_select.as_wire()->width; std::vector costs; if (celltype == ID($_AND_) || celltype == ID($_OR_)) { costs = {5, 2, 2, 1, 0, 0, 0, 0}; log_assert(select_width == 2 || select_width == 3); log_assert(opt_instrumentmore || select_width == 2); log_assert(!opt_instrumentmore || select_width == 3); } else if (celltype == ID($_XOR_) || celltype == ID($_XNOR_)) { costs = {1, 0, 0, 0}; log_assert(select_width == 2); } std::vector next_pmux_y_ports, pmux_y_ports(costs.begin(), costs.begin() + exp2(select_width)); for (auto i = 0; pmux_y_ports.size() > 1; ++i) { for (auto j = 0; j+1 < GetSize(pmux_y_ports); j += 2) { next_pmux_y_ports.emplace_back(module->Pmux(stringf("%s_mux_%d_%d", metamux_select.as_wire()->name.c_str(), i, j), pmux_y_ports[j], pmux_y_ports[j+1], metamux_select[GetSize(metamux_select) - 1 - i], metamux_select.as_wire()->get_src_attribute())); } if (GetSize(pmux_y_ports) % 2 == 1) next_pmux_y_ports.push_back(pmux_y_ports[GetSize(pmux_y_ports) - 1]); pmux_y_ports.swap(next_pmux_y_ports); next_pmux_y_ports.clear(); } log_assert(pmux_y_ports.size() == 1); return pmux_y_ports[0]; } } void create_glift_logic() { if (module->get_bool_attribute(glift_attribute_name)) return; std::vector connections(module->connections()); for(auto &cell : module->cells().to_vector()) { if (!cell->type.in({ID($_AND_), ID($_NAND_), ID($_OR_), ID($_NOR_), ID($_XOR_), ID($_XNOR_), ID($_MUX_), ID($_NMUX_), ID($_NOT_), ID($anyconst), ID($allconst), ID($assume), ID($assert)}) && module->design->module(cell->type) == nullptr) { log_cmd_error("Unsupported cell type \"%s\" found. Run `techmap` first.\n", cell->type.c_str()); } if (cell->type.in(ID($_AND_), ID($_NAND_), ID($_OR_), ID($_NOR_))) { const unsigned int A = 0, B = 1, Y = 2; const unsigned int NUM_PORTS = 3; RTLIL::SigSpec ports[NUM_PORTS] = {cell->getPort(ID::A), cell->getPort(ID::B), cell->getPort(ID::Y)}; RTLIL::SigSpec port_taints[NUM_PORTS]; if (ports[A].size() != 1 || ports[B].size() != 1 || ports[Y].size() != 1) log_cmd_error("Multi-bit signal found. Run `splitnets` first.\n"); for (unsigned int i = 0; i < NUM_PORTS; ++i) port_taints[i] = get_corresponding_taint_signal(ports[i]); if (opt_create_precise_model) add_precise_GLIFT_logic(cell, ports[A], port_taints[A], ports[B], port_taints[B], port_taints[Y]); else if (opt_create_imprecise_model) add_imprecise_GLIFT_logic_3(cell, port_taints[A], port_taints[B], port_taints[Y]); else if (opt_create_instrumented_model) { std::vector taint_version; int num_versions = opt_instrumentmore? 8 : 4; for (auto i = 1; i <= num_versions; ++i) taint_version.emplace_back(RTLIL::SigSpec(module->addWire(stringf("%s_y%d", cell->name.c_str(), i), 1))); for (auto i = 0; i < num_versions; ++i) { switch(i) { case 0: add_precise_GLIFT_logic(cell, ports[A], port_taints[A], ports[B], port_taints[B], taint_version[i]); break; case 1: add_imprecise_GLIFT_logic_1(cell, ports[A], port_taints[A], ports[B], port_taints[B], taint_version[i]); break; case 2: add_imprecise_GLIFT_logic_2(cell, ports[A], port_taints[A], ports[B], port_taints[B], taint_version[i]); break; case 3: add_imprecise_GLIFT_logic_3(cell, port_taints[A], port_taints[B], taint_version[i]); break; case 4: add_imprecise_GLIFT_logic_4(port_taints[A], taint_version[i]); break; case 5: add_imprecise_GLIFT_logic_5(port_taints[B], taint_version[i]); break; case 6: add_imprecise_GLIFT_logic_6(taint_version[i]); break; case 7: add_imprecise_GLIFT_logic_7(taint_version[i]); break; default: log_assert(false); } } auto select_width = log2(num_versions); log_assert(exp2(select_width) == num_versions); RTLIL::SigSpec meta_mux_select(module->addWire(cell->name.str() + "_sel", select_width)); meta_mux_selects.push_back(make_pair(meta_mux_select, cell->type)); module->connect(meta_mux_select, module->Anyconst(cell->name.str() + "_hole", select_width, cell->get_src_attribute())); std::vector next_meta_mux_y_ports, meta_mux_y_ports(taint_version); for (auto i = 0; meta_mux_y_ports.size() > 1; ++i) { for (auto j = 0; j+1 < GetSize(meta_mux_y_ports); j += 2) { next_meta_mux_y_ports.emplace_back(module->Mux(stringf("%s_mux_%d_%d", cell->name.c_str(), i, j), meta_mux_y_ports[j], meta_mux_y_ports[j+1], meta_mux_select[GetSize(meta_mux_select) - 1 - i])); } if (GetSize(meta_mux_y_ports) % 2 == 1) next_meta_mux_y_ports.push_back(meta_mux_y_ports[GetSize(meta_mux_y_ports) - 1]); meta_mux_y_ports.swap(next_meta_mux_y_ports); next_meta_mux_y_ports.clear(); } log_assert(meta_mux_y_ports.size() == 1); module->connect(port_taints[Y], meta_mux_y_ports[0]); } else log_cmd_error("This is a bug (1).\n"); } else if (cell->type.in(ID($_XOR_), ID($_XNOR_))) { const unsigned int A = 0, B = 1, Y = 2; const unsigned int NUM_PORTS = 3; RTLIL::SigSpec ports[NUM_PORTS] = {cell->getPort(ID::A), cell->getPort(ID::B), cell->getPort(ID::Y)}; RTLIL::SigSpec port_taints[NUM_PORTS]; if (ports[A].size() != 1 || ports[B].size() != 1 || ports[Y].size() != 1) log_cmd_error("Multi-bit signal found. Run `splitnets` first.\n"); for (unsigned int i = 0; i < NUM_PORTS; ++i) port_taints[i] = get_corresponding_taint_signal(ports[i]); if (opt_create_precise_model || opt_create_imprecise_model) add_imprecise_GLIFT_logic_3(cell, port_taints[A], port_taints[B], port_taints[Y]); else if (opt_create_instrumented_model) { std::vector taint_version; int num_versions = 4; auto select_width = log2(num_versions); log_assert(exp2(select_width) == num_versions); for (auto i = 1; i <= num_versions; ++i) taint_version.emplace_back(RTLIL::SigSpec(module->addWire(stringf("%s_y%d", cell->name.c_str(), i), 1))); for (auto i = 0; i < num_versions; ++i) { switch(i) { case 0: add_imprecise_GLIFT_logic_3(cell, port_taints[A], port_taints[B], taint_version[i]); break; case 1: add_imprecise_GLIFT_logic_4(port_taints[A], taint_version[i]); break; case 2: add_imprecise_GLIFT_logic_5(port_taints[B], taint_version[i]); break; case 3: add_imprecise_GLIFT_logic_6(taint_version[i]); break; default: log_assert(false); } } RTLIL::SigSpec meta_mux_select(module->addWire(cell->name.str() + "_sel", select_width)); meta_mux_selects.push_back(make_pair(meta_mux_select, cell->type)); module->connect(meta_mux_select, module->Anyconst(cell->name.str() + "_hole", select_width, cell->get_src_attribute())); std::vector next_meta_mux_y_ports, meta_mux_y_ports(taint_version); for (auto i = 0; meta_mux_y_ports.size() > 1; ++i) { for (auto j = 0; j+1 < GetSize(meta_mux_y_ports); j += 2) { next_meta_mux_y_ports.emplace_back(module->Mux(stringf("%s_mux_%d_%d", cell->name.c_str(), i, j), meta_mux_y_ports[j], meta_mux_y_ports[j+1], meta_mux_select[GetSize(meta_mux_select) - 1 - i])); } if (GetSize(meta_mux_y_ports) % 2 == 1) next_meta_mux_y_ports.push_back(meta_mux_y_ports[GetSize(meta_mux_y_ports) - 1]); meta_mux_y_ports.swap(next_meta_mux_y_ports); next_meta_mux_y_ports.clear(); } log_assert(meta_mux_y_ports.size() == 1); module->connect(port_taints[Y], meta_mux_y_ports[0]); } else log_cmd_error("This is a bug (2).\n"); } else if (cell->type.in(ID($_MUX_), ID($_NMUX_))) { const unsigned int A = 0, B = 1, S = 2, Y = 3; const unsigned int NUM_PORTS = 4; RTLIL::SigSpec ports[NUM_PORTS] = {cell->getPort(ID::A), cell->getPort(ID::B), cell->getPort(ID::S), cell->getPort(ID::Y)}; RTLIL::SigSpec port_taints[NUM_PORTS]; if (ports[A].size() != 1 || ports[B].size() != 1 || ports[S].size() != 1 || ports[Y].size() != 1) log_cmd_error("Multi-bit signal found. Run `splitnets` first.\n"); for (unsigned int i = 0; i < NUM_PORTS; ++i) port_taints[i] = get_corresponding_taint_signal(ports[i]); add_precise_GLIFT_mux(cell, ports[A], port_taints[A], ports[B], port_taints[B], ports[S], port_taints[S], port_taints[Y]); } else if (cell->type.in(ID($_NOT_))) { const unsigned int A = 0, Y = 1; const unsigned int NUM_PORTS = 2; RTLIL::SigSpec ports[NUM_PORTS] = {cell->getPort(ID::A), cell->getPort(ID::Y)}; RTLIL::SigSpec port_taints[NUM_PORTS]; if (ports[A].size() != 1 || ports[Y].size() != 1) log_cmd_error("Multi-bit signal found. Run `splitnets` first.\n"); for (unsigned int i = 0; i < NUM_PORTS; ++i) port_taints[i] = get_corresponding_taint_signal(ports[i]); if (cell->type == ID($_NOT_)) { module->connect(port_taints[Y], port_taints[A]); } else log_cmd_error("This is a bug (3).\n"); } else if (module->design->module(cell->type) != nullptr) { //User cell type //This function is called on modules according to topological order, so we do not need to //recurse to GLIFT model the child module. However, we need to augment the ports list //with taint signals and connect the new ports to the corresponding taint signals. RTLIL::Module *cell_module_def = module->design->module(cell->type); dict orig_ports = cell->connections(); log("Adding cell %s\n", cell_module_def->name.c_str()); for (auto &it : orig_ports) { RTLIL::SigSpec port = it.second; RTLIL::SigSpec port_taint = get_corresponding_taint_signal(port); log_assert(port_taint.is_wire()); log_assert(std::find(cell_module_def->ports.begin(), cell_module_def->ports.end(), port_taint.as_wire()->name) != cell_module_def->ports.end()); cell->setPort(port_taint.as_wire()->name, port_taint); } } else log_cmd_error("This is a bug (4).\n"); } //end foreach cell in cells for (auto &conn : connections) { RTLIL::SigSpec first = get_corresponding_taint_signal(conn.first); RTLIL::SigSpec second = get_corresponding_taint_signal(conn.second); module->connect(first, second); if(conn.second.is_wire() && conn.second.as_wire()->port_input) second.as_wire()->port_input = true; if(conn.first.is_wire() && conn.first.as_wire()->port_output) new_taint_outputs.push_back(first.as_wire()); } //end foreach conn in connections //Create a rough model of area by summing the (potentially simplified) "weight" score of each meta-mux select: if (!opt_nocostmodel) { std::vector meta_mux_select_sums; std::vector meta_mux_select_sums_buf; for (auto &it : meta_mux_selects) { meta_mux_select_sums.emplace_back(score_metamux_select(it.first, it.second)); } for (unsigned int i = 0; meta_mux_select_sums.size() > 1; ) { meta_mux_select_sums_buf.clear(); for (i = 0; i + 1 < meta_mux_select_sums.size(); i += 2) { meta_mux_select_sums_buf.push_back(module->Add(meta_mux_select_sums[i].as_wire()->name.str() + "_add", meta_mux_select_sums[i], meta_mux_select_sums[i+1], false)); } if (meta_mux_select_sums.size() % 2 == 1) meta_mux_select_sums_buf.push_back(meta_mux_select_sums[meta_mux_select_sums.size()-1]); meta_mux_select_sums.swap(meta_mux_select_sums_buf); } if (meta_mux_select_sums.size() > 0) { meta_mux_select_sums[0].as_wire()->set_bool_attribute("\\minimize"); meta_mux_select_sums[0].as_wire()->set_bool_attribute("\\keep"); module->rename(meta_mux_select_sums[0].as_wire(), cost_model_wire_name); } } //Mark new module outputs: for (auto &port_name : module->ports) { RTLIL::Wire *port = module->wire(port_name); log_assert(port != nullptr); if (is_top_module && port->port_output && !opt_keepoutputs) port->port_output = false; } for (auto &output : new_taint_outputs) output->port_output = true; module->fixup_ports(); //we have some new taint signals in the module interface module->set_bool_attribute(glift_attribute_name, true); } public: GliftWorker(RTLIL::Module *_module, bool _is_top_module, bool _opt_create_precise_model, bool _opt_create_imprecise_model, bool _opt_create_instrumented_model, bool _opt_taintconstants, bool _opt_keepoutputs, bool _opt_simplecostmodel, bool _opt_nocostmodel, bool _opt_instrumentmore) { module = _module; is_top_module = _is_top_module; opt_create_precise_model = _opt_create_precise_model; opt_create_imprecise_model = _opt_create_imprecise_model; opt_create_instrumented_model = _opt_create_instrumented_model; opt_taintconstants = _opt_taintconstants; opt_keepoutputs = _opt_keepoutputs; opt_simplecostmodel = _opt_simplecostmodel; opt_nocostmodel = _opt_nocostmodel; opt_instrumentmore = _opt_instrumentmore; create_glift_logic(); } }; struct GliftPass : public Pass { GliftPass() : Pass("glift", "create GLIFT models and optimization problems") {} void help() override { // |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---| log("\n"); log(" glift [options] [selection]\n"); log("\n"); log("Augments the current or specified module with gate-level information flow tracking\n"); log("(GLIFT) logic using the \"constructive mapping\" approach. Also can set up QBF-SAT\n"); log("optimization problems in order to optimize GLIFT models or trade off precision and\n"); log("complexity.\n"); log("\n"); log("\n"); log("Commands:\n"); log("\n"); log(" -create-precise-model\n"); log(" Replaces the current or specified module with one that has corresponding \"taint\"\n"); log(" inputs, outputs, and internal nets along with precise taint tracking logic.\n"); log(" For example, precise taint tracking logic for an AND gate is:\n"); log("\n"); log(" y_t = a & b_t | b & a_t | a_t & b_t\n"); log("\n"); log("\n"); log(" -create-imprecise-model\n"); log(" Replaces the current or specified module with one that has corresponding \"taint\"\n"); log(" inputs, outputs, and internal nets along with imprecise \"All OR\" taint tracking\n"); log(" logic:\n"); log("\n"); log(" y_t = a_t | b_t\n"); log("\n"); log("\n"); log(" -create-instrumented-model\n"); log(" Replaces the current or specified module with one that has corresponding \"taint\"\n"); log(" inputs, outputs, and internal nets along with 4 varying-precision versions of taint\n"); log(" tracking logic. Which version of taint tracking logic is used for a given gate is\n"); log(" determined by a MUX selected by an $anyconst cell. By default, unless the\n"); log(" `-no-cost-model` option is provided, an additional wire named `__glift_weight` with\n"); log(" the `keep` and `minimize` attributes is added to the module along with pmuxes and\n"); log(" adders to calculate a rough estimate of the number of logic gates in the GLIFT model\n"); log(" given an assignment for the $anyconst cells. The four versions of taint tracking logic\n"); log(" for an AND gate are:"); log("\n"); log(" y_t = a & b_t | b & a_t | a_t & b_t (like `-create-precise-model`)\n"); log(" y_t = a_t | a & b_t\n"); log(" y_t = b_t | b & a_t\n"); log(" y_t = a_t | b_t (like `-create-imprecise-model`)\n"); log("\n"); log("\n"); log("Options:\n"); log("\n"); log(" -taint-constants\n"); log(" Constant values in the design are labeled as tainted.\n"); log(" (default: label constants as un-tainted)\n"); log("\n"); log(" -keep-outputs\n"); log(" Do not remove module outputs. Taint tracking outputs will appear in the module ports\n"); log(" alongside the orignal outputs.\n"); log(" (default: original module outputs are removed)\n"); log("\n"); log(" -simple-cost-model\n"); log(" Do not model logic area. Instead model the number of non-zero assignments to $anyconsts.\n"); log(" Taint tracking logic versions vary in their size, but all reduced-precision versions are\n"); log(" significantly smaller than the fully-precise version. A non-zero $anyconst assignment means\n"); log(" that reduced-precision taint tracking logic was chosen for some gate.\n"); log(" Only applicable in combination with `-create-instrumented-model`.\n"); log(" (default: use a complex model and give that wire the \"keep\" and \"minimize\" attributes)\n"); log("\n"); log(" -no-cost-model\n"); log(" Do not model taint tracking logic area and do not create a `__glift_weight` wire.\n"); log(" Only applicable in combination with `-create-instrumented-model`.\n"); log(" (default: model area and give that wire the \"keep\" and \"minimize\" attributes)\n"); log("\n"); log(" -instrument-more\n"); log(" Allow choice from more versions of (even simpler) taint tracking logic. A total\n"); log(" of 8 versions of taint tracking logic will be added per gate, including the 4\n"); log(" versions from `-create-instrumented-model` and these additional versions:\n"); log("\n"); log(" y_t = a_t\n"); log(" y_t = b_t\n"); log(" y_t = 1\n"); log(" y_t = 0\n"); log("\n"); log(" Only applicable in combination with `-create-instrumented-model`.\n"); log(" (default: do not add more versions of taint tracking logic.\n"); log("\n"); } void execute(std::vector args, RTLIL::Design *design) override { bool opt_create_precise_model = false, opt_create_imprecise_model = false, opt_create_instrumented_model = false; bool opt_taintconstants = false, opt_keepoutputs = false, opt_simplecostmodel = false, opt_nocostmodel = false; bool opt_instrumentmore = false; log_header(design, "Executing GLIFT pass (creating and manipulating GLIFT models).\n"); std::vector::size_type argidx; for (argidx = 1; argidx < args.size(); argidx++) { if (args[argidx] == "-create-precise-model") { opt_create_precise_model = true; continue; } if (args[argidx] == "-create-imprecise-model") { opt_create_imprecise_model = true; continue; } if (args[argidx] == "-create-instrumented-model") { opt_create_instrumented_model = true; continue; } if (args[argidx] == "-taint-constants") { opt_taintconstants = true; continue; } if (args[argidx] == "-keep-outputs") { opt_keepoutputs = true; continue; } if (args[argidx] == "-simple-cost-model") { opt_simplecostmodel = true; continue; } if (args[argidx] == "-no-cost-model") { opt_nocostmodel = true; continue; } if (args[argidx] == "-instrument-more") { opt_instrumentmore = true; continue; } break; } if(!opt_create_precise_model && !opt_create_imprecise_model && !opt_create_instrumented_model) log_cmd_error("No command provided. See help for usage.\n"); if(static_cast(opt_create_precise_model) + static_cast(opt_create_imprecise_model) + static_cast(opt_create_instrumented_model) != 1) log_cmd_error("Only one command may be specified. See help for usage.\n"); if(opt_simplecostmodel && opt_nocostmodel) log_cmd_error("Only one of `-simple-cost-model` and `-no-cost-model` may be specified. See help for usage.\n"); if((opt_simplecostmodel || opt_nocostmodel) && !opt_create_instrumented_model) log_cmd_error("Options `-simple-cost-model` and `-no-cost-model` may only be used with `-create-instrumented-model`. See help for usage.\n"); extra_args(args, argidx, design); if (GetSize(design->selected_modules()) == 0) log_cmd_error("Can't operate on an empty selection!\n"); TopoSort> topo_modules; //cribbed from passes/techmap/flatten.cc auto worklist = design->selected_modules(); pool non_top_modules; while (!worklist.empty()) { RTLIL::Module *module = *(worklist.begin()); worklist.erase(worklist.begin()); topo_modules.node(module); for (auto cell : module->selected_cells()) { RTLIL::Module *tpl = design->module(cell->type); if (tpl != nullptr) { if (topo_modules.database.count(tpl) == 0) worklist.push_back(tpl); topo_modules.edge(tpl, module); non_top_modules.insert(cell->type); } } } if (!topo_modules.sort()) log_cmd_error("Cannot handle recursive module instantiations.\n"); for (auto i = 0; i < GetSize(topo_modules.sorted); ++i) { RTLIL::Module *module = topo_modules.sorted[i]; GliftWorker(module, !non_top_modules[module->name], opt_create_precise_model, opt_create_imprecise_model, opt_create_instrumented_model, opt_taintconstants, opt_keepoutputs, opt_simplecostmodel, opt_nocostmodel, opt_instrumentmore); } } } GliftPass; PRIVATE_NAMESPACE_END