/* * nextpnr -- Next Generation Place and Route * * Copyright (C) 2018 SymbioticEDA * * jsonparse.cc -- liberally copied from the yosys file of the same name by * * Copyright (C) 2018 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 "jsonparse.h" #include #include #include #include #include #include #include #include "nextpnr.h" NEXTPNR_NAMESPACE_BEGIN extern bool check_all_nets_driven(Context *ctx); namespace JsonParser { const bool json_debug = false; typedef std::string string; template int GetSize(const T &obj) { return obj.size(); } struct JsonNode { char type; // S=String, N=Number, A=Array, D=Dict string data_string; int data_number; std::vector data_array; std::map data_dict; std::vector data_dict_keys; JsonNode(std::istream &f, int &lineno) { type = 0; data_number = 0; while (1) { int ch = f.get(); if (ch == EOF) log_error("Unexpected EOF in JSON file.\n"); if (ch == '\n') lineno++; if (ch == ' ' || ch == '\t' || ch == '\r' || ch == '\n') continue; if (ch == '\"') { type = 'S'; while (1) { ch = f.get(); if (ch == EOF) log_error("Unexpected EOF in JSON string.\n"); if (ch == '\"') break; if (ch == '\\') { int ch = f.get(); if (ch == EOF) log_error("Unexpected EOF in JSON string.\n"); } data_string += ch; } break; } if (('0' <= ch && ch <= '9') || ('-' == ch)) { type = 'N'; if (ch == '-') data_number = 0; else data_number = ch - '0'; data_string += ch; while (1) { ch = f.get(); if (ch == EOF) break; if (ch == '.') goto parse_real; if (ch < '0' || '9' < ch) { f.unget(); break; } data_number = data_number * 10 + (ch - '0'); data_string += ch; } if (data_string[0] == '-') data_number = -data_number; data_string = ""; break; parse_real: type = 'S'; data_number = 0; data_string += ch; while (1) { ch = f.get(); if (ch == EOF) break; if (ch < '0' || '9' < ch) { f.unget(); break; } data_string += ch; } break; } if (ch == '[') { type = 'A'; while (1) { ch = f.get(); if (ch == EOF) log_error("Unexpected EOF in JSON file.\n"); if (ch == '\n') lineno++; if (ch == ' ' || ch == '\t' || ch == '\r' || ch == '\n' || ch == ',') continue; if (ch == ']') break; f.unget(); data_array.push_back(new JsonNode(f, lineno)); } break; } if (ch == '{') { type = 'D'; while (1) { ch = f.get(); if (ch == EOF) log_error("Unexpected EOF in JSON file.\n"); if (ch == '\n') lineno++; if (ch == ' ' || ch == '\t' || ch == '\r' || ch == '\n' || ch == ',') continue; if (ch == '}') break; f.unget(); JsonNode key(f, lineno); while (1) { ch = f.get(); if (ch == EOF) log_error("Unexpected EOF in JSON file.\n"); if (ch == '\n') lineno++; if (ch == ' ' || ch == '\t' || ch == '\r' || ch == '\n' || ch == ':') continue; f.unget(); break; } JsonNode *value = new JsonNode(f, lineno); if (key.type != 'S') log_error("Unexpected non-string key in JSON dict, line %d.\n", lineno); data_dict[key.data_string] = value; data_dict_keys.push_back(key.data_string); } break; } log_error("Unexpected character in JSON file, line %d: '%c'\n", lineno, ch); } } ~JsonNode() { for (auto it : data_array) delete it; for (auto &it : data_dict) delete it.second; } }; void ground_net(Context *ctx, NetInfo *net) { std::unique_ptr cell = std::unique_ptr(new CellInfo); PortInfo port_info; PortRef port_ref; cell->name = ctx->id(net->name.str(ctx) + ".GND"); cell->type = ctx->id("GND"); port_info.name = ctx->id(cell->name.str(ctx) + "[]"); port_info.net = net; port_info.type = PORT_OUT; port_ref.cell = cell.get(); port_ref.port = port_info.name; net->driver = port_ref; cell->ports[port_info.name] = port_info; ctx->cells[cell->name] = std::move(cell); } void vcc_net(Context *ctx, NetInfo *net) { std::unique_ptr cell = std::unique_ptr(new CellInfo); PortInfo port_info; PortRef port_ref; cell->name = ctx->id(net->name.str(ctx) + ".VCC"); cell->type = ctx->id("VCC"); port_info.name = ctx->id(cell->name.str(ctx) + "[]"); port_info.net = net; port_info.type = PORT_OUT; port_ref.cell = cell.get(); port_ref.port = port_info.name; net->driver = port_ref; cell->ports[port_info.name] = port_info; ctx->cells[cell->name] = std::move(cell); } // // is_blackbox // // Checks the JsonNode for an attributes dictionary, with a "blackbox" entry. // An item is deemed to be a blackbox if this entry exists and if its // value is not zero. If the item is a black box, this routine will return // true, false otherwise bool is_blackbox(JsonNode *node) { JsonNode *attr_node, *bbox_node; if (node->data_dict.count("attributes") == 0) return false; attr_node = node->data_dict.at("attributes"); if (attr_node == NULL) return false; if (attr_node->type != 'D') return false; if (GetSize(attr_node->data_dict) == 0) return false; if (attr_node->data_dict.count("blackbox") == 0) return false; bbox_node = attr_node->data_dict.at("blackbox"); if (bbox_node == NULL) return false; if (bbox_node->type != 'N') log_error("JSON module blackbox is not a number\n"); if (bbox_node->data_number == 0) return false; return true; } void json_import_cell_params(Context *ctx, string &modname, CellInfo *cell, JsonNode *param_node, std::unordered_map *dest, int param_id) { // JsonNode *param; IdString pId; // param = param_node->data_dict.at(param_node->data_dict_keys[param_id]); pId = ctx->id(param_node->data_dict_keys[param_id]); if (param->type == 'N') { (*dest)[pId].setNumber(param->data_number); } else if (param->type == 'S') (*dest)[pId].setString(param->data_string); else log_error("JSON parameter type of \"%s\' of cell \'%s\' not supported\n", pId.c_str(ctx), cell->name.c_str(ctx)); if (json_debug) log_info(" Added parameter \'%s\'=%s to cell \'%s\' " "of module \'%s\'\n", pId.c_str(ctx), cell->params[pId].c_str(), cell->name.c_str(ctx), modname.c_str()); } void json_import_net_attrib(Context *ctx, string &modname, NetInfo *net, JsonNode *param_node, std::unordered_map *dest, int param_id) { // JsonNode *param; IdString pId; // param = param_node->data_dict.at(param_node->data_dict_keys[param_id]); pId = ctx->id(param_node->data_dict_keys[param_id]); if (param->type == 'N') { (*dest)[pId].setNumber(param->data_number); } else if (param->type == 'S') (*dest)[pId].setString(param->data_string); else log_error("JSON parameter type of \"%s\' of net \'%s\' not supported\n", pId.c_str(ctx), net->name.c_str(ctx)); if (json_debug) log_info(" Added parameter \'%s\'=%s to net \'%s\' " "of module \'%s\'\n", pId.c_str(ctx), net->attrs[pId].c_str(), net->name.c_str(ctx), modname.c_str()); } void json_import_top_attrib(Context *ctx, string &modname, JsonNode *param_node, std::unordered_map *dest, int param_id) { // JsonNode *param; IdString pId; // param = param_node->data_dict.at(param_node->data_dict_keys[param_id]); pId = ctx->id(param_node->data_dict_keys[param_id]); if (param->type == 'N') { (*dest)[pId].setNumber(param->data_number); } else if (param->type == 'S') (*dest)[pId].setString(param->data_string); else log_error("JSON parameter type of \"%s\' of module not supported\n", pId.c_str(ctx)); if (json_debug) log_info(" Added parameter \'%s\'=%s module \'%s\'\n", pId.c_str(ctx), (*dest)[pId].c_str(), modname.c_str()); } static int const_net_idx = 0; template void json_import_ports(Context *ctx, const string &modname, const std::vector &netnames, const string &obj_name, const string &port_name, JsonNode *dir_node, JsonNode *wire_group_node, F visitor) { // Examine a port of a cell or the design. For every bit of the port, // the connected net will be processed and `visitor` will be called // with (PortType dir, std::string name, NetInfo *net) assert(dir_node); if (json_debug) log_info(" Examining port %s, node %s\n", port_name.c_str(), obj_name.c_str()); if (!wire_group_node) log_error("JSON no connection match " "for port_direction \'%s\' of node \'%s\' " "in module \'%s\'\n", port_name.c_str(), obj_name.c_str(), modname.c_str()); assert(wire_group_node); assert(dir_node->type == 'S'); assert(wire_group_node->type == 'A'); PortInfo port_info; port_info.name = ctx->id(port_name); if (dir_node->data_string.compare("input") == 0) port_info.type = PORT_IN; else if (dir_node->data_string.compare("output") == 0) port_info.type = PORT_OUT; else if (dir_node->data_string.compare("inout") == 0) port_info.type = PORT_INOUT; else log_error("JSON unknown port direction \'%s\' in node \'%s\' " "of module \'%s\'\n", dir_node->data_string.c_str(), obj_name.c_str(), modname.c_str()); // // Find an update, or create a net to connect // to this port. // NetInfo *this_net = nullptr; bool is_bus; // // If this port references a bus, then there will be multiple nets // connected to it, all specified as part of an array. // is_bus = (wire_group_node->data_array.size() > 1); // Now loop through all of the connections to this port. if (wire_group_node->data_array.size() == 0) { // // There is/are no connections to this port. // // Create the port, but leave the net NULL visitor(port_info.type, port_info.name.str(ctx), nullptr); if (json_debug) log_info(" Port \'%s\' has no connection in \'%s\'\n", port_info.name.c_str(ctx), obj_name.c_str()); } else for (int index = 0; index < int(wire_group_node->data_array.size()); index++) { // JsonNode *wire_node; PortInfo this_port; IdString net_id; // wire_node = wire_group_node->data_array[index]; // // Pick a name for this port if (is_bus) this_port.name = ctx->id(port_info.name.str(ctx) + "[" + std::to_string(index) + "]"); else this_port.name = port_info.name; this_port.type = port_info.type; if (wire_node->type == 'N') { int net_num; // A simple net, specified by a number net_num = wire_node->data_number; if (net_num < int(netnames.size())) net_id = netnames.at(net_num); else net_id = ctx->id(std::to_string(net_num)); if (ctx->nets.count(net_id) == 0) { // The net doesn't exist in the design (yet) // Create in now if (json_debug) log_info(" Generating a new net, \'%d\'\n", net_num); std::unique_ptr net = std::unique_ptr(new NetInfo()); net->name = net_id; net->driver.cell = NULL; net->driver.port = IdString(); ctx->nets[net_id] = std::move(net); this_net = ctx->nets[net_id].get(); } else { // // The net already exists within the design. // We'll connect to it // this_net = ctx->nets[net_id].get(); if (json_debug) log_info(" Reusing net \'%s\', id \'%s\', " "with driver \'%s\'\n", this_net->name.c_str(ctx), net_id.c_str(ctx), (this_net->driver.cell != NULL) ? this_net->driver.port.c_str(ctx) : "NULL"); } } else if (wire_node->type == 'S') { // Strings are only used to drive wires for the fixed // values "0", "1", and "x". Handle those constant // values here. // // Constants always get their own new net std::unique_ptr net = std::unique_ptr(new NetInfo()); net->name = ctx->id("$const_" + std::to_string(const_net_idx++)); if (wire_node->data_string.compare(string("0")) == 0) { if (json_debug) log_info(" Generating a constant " "zero net\n"); ground_net(ctx, net.get()); } else if (wire_node->data_string.compare(string("1")) == 0) { if (json_debug) log_info(" Generating a constant " "one net\n"); vcc_net(ctx, net.get()); } else if (wire_node->data_string.compare(string("x")) == 0) { ground_net(ctx, net.get()); } else log_error(" Unknown fixed type wire node " "value, \'%s\'\n", wire_node->data_string.c_str()); IdString n = net->name; ctx->nets[net->name] = std::move(net); this_net = ctx->nets[n].get(); } if (json_debug) log_info(" Inserting port \'%s\' into cell \'%s\'\n", this_port.name.c_str(ctx), obj_name.c_str()); visitor(this_port.type, this_port.name.str(ctx), this_net); } } void json_import_cell(Context *ctx, string modname, const std::vector &netnames, JsonNode *cell_node, string cell_name) { JsonNode *cell_type, *param_node, *attr_node; cell_type = cell_node->data_dict.at("type"); if (cell_type == NULL) return; std::unique_ptr cell = std::unique_ptr(new CellInfo); cell->name = ctx->id(cell_name); assert(cell_type->type == 'S'); cell->type = ctx->id(cell_type->data_string); // No BEL assignment here/yet if (json_debug) log_info(" Processing %s $ %s\n", modname.c_str(), cell->name.c_str(ctx)); param_node = cell_node->data_dict.at("parameters"); if (param_node->type != 'D') log_error("JSON parameter list of \'%s\' is not a data dictionary\n", cell->name.c_str(ctx)); // // Loop through all parameters, adding them into the // design to annotate the cell // for (int paramid = 0; paramid < GetSize(param_node->data_dict_keys); paramid++) { json_import_cell_params(ctx, modname, cell.get(), param_node, &cell->params, paramid); } attr_node = cell_node->data_dict.at("attributes"); if (attr_node->type != 'D') log_error("JSON attribute list of \'%s\' is not a data dictionary\n", cell->name.c_str(ctx)); // // Loop through all attributes, adding them into the // design to annotate the cell // for (int attrid = 0; attrid < GetSize(attr_node->data_dict_keys); attrid++) { json_import_cell_params(ctx, modname, cell.get(), attr_node, &cell->attrs, attrid); } // // Now connect the ports of this module. The ports are defined by // both the port directions node as well as the connections node. // Both should contain dictionaries having the same keys. // JsonNode *pdir_node = NULL; if (cell_node->data_dict.count("port_directions") > 0) { pdir_node = cell_node->data_dict.at("port_directions"); if (pdir_node->type != 'D') log_error("JSON port_directions node of \'%s\' " "in module \'%s\' is not a " "dictionary\n", cell->name.c_str(ctx), modname.c_str()); } else if (cell_node->data_dict.count("ports") > 0) { pdir_node = cell_node->data_dict.at("ports"); if (pdir_node->type != 'D') log_error("JSON ports node of \'%s\' " "in module \'%s\' is not a " "dictionary\n", cell->name.c_str(ctx), modname.c_str()); } JsonNode *connections = cell_node->data_dict.at("connections"); if (connections->type != 'D') log_error("JSON connections node of \'%s\' " "in module \'%s\' is not a " "dictionary\n", cell->name.c_str(ctx), modname.c_str()); if (GetSize(pdir_node->data_dict_keys) != GetSize(connections->data_dict_keys)) log_error("JSON number of connections doesnt " "match number of ports in node \'%s\' " "of module \'%s\'\n", cell->name.c_str(ctx), modname.c_str()); // // Loop through all of the ports of this logic element // for (int portid = 0; portid < GetSize(pdir_node->data_dict_keys); portid++) { // string port_name; JsonNode *dir_node, *wire_group_node; // port_name = pdir_node->data_dict_keys[portid]; dir_node = pdir_node->data_dict.at(port_name); wire_group_node = connections->data_dict.at(port_name); json_import_ports(ctx, modname, netnames, cell->name.str(ctx), port_name, dir_node, wire_group_node, [&cell, ctx](PortType type, const std::string &name, NetInfo *net) { cell->ports[ctx->id(name)] = PortInfo{ctx->id(name), net, type}; PortRef pr; pr.cell = cell.get(); pr.port = ctx->id(name); if (net != nullptr) { if (type == PORT_IN || type == PORT_INOUT) { net->users.push_back(pr); } else if (type == PORT_OUT) { if (net->driver.cell != nullptr) log_error("multiple drivers on net '%s' (%s.%s and %s.%s)\n", net->name.c_str(ctx), net->driver.cell->name.c_str(ctx), net->driver.port.c_str(ctx), pr.cell->name.c_str(ctx), pr.port.c_str(ctx)); net->driver = pr; } } }); } ctx->cells[cell->name] = std::move(cell); // check_all_nets_driven(ctx); } static void insert_iobuf(Context *ctx, NetInfo *net, PortType type, const string &name) { // Instantiate a architecture-independent IO buffer connected to a given // net, of a given type, and named after the IO port. // // During packing, this generic IO buffer will be converted to an // architecure primitive. // std::unique_ptr iobuf = std::unique_ptr(new CellInfo()); iobuf->name = ctx->id(name); std::copy(net->attrs.begin(), net->attrs.end(), std::inserter(iobuf->attrs, iobuf->attrs.begin())); if (type == PORT_IN) { if (ctx->verbose) log_info("processing input port %s\n", name.c_str()); iobuf->type = ctx->id("$nextpnr_ibuf"); iobuf->ports[ctx->id("O")] = PortInfo{ctx->id("O"), net, PORT_OUT}; // Special case: input, etc, directly drives inout if (net->driver.cell != nullptr) { if (net->driver.cell->type != ctx->id("$nextpnr_iobuf")) log_error("Top-level input '%s' also driven by %s.%s.\n", name.c_str(), net->driver.cell->name.c_str(ctx), net->driver.port.c_str(ctx)); net = net->driver.cell->ports.at(ctx->id("I")).net; } assert(net->driver.cell == nullptr); net->driver.port = ctx->id("O"); net->driver.cell = iobuf.get(); } else if (type == PORT_OUT) { if (ctx->verbose) log_info("processing output port %s\n", name.c_str()); iobuf->type = ctx->id("$nextpnr_obuf"); iobuf->ports[ctx->id("I")] = PortInfo{ctx->id("I"), net, PORT_IN}; PortRef ref; ref.cell = iobuf.get(); ref.port = ctx->id("I"); net->users.push_back(ref); } else if (type == PORT_INOUT) { if (ctx->verbose) log_info("processing inout port %s\n", name.c_str()); iobuf->type = ctx->id("$nextpnr_iobuf"); iobuf->ports[ctx->id("I")] = PortInfo{ctx->id("I"), nullptr, PORT_IN}; // Split the input and output nets for bidir ports std::unique_ptr net2 = std::unique_ptr(new NetInfo()); net2->name = ctx->id("$" + net->name.str(ctx) + "$iobuf_i"); net2->driver = net->driver; if (net->driver.cell != nullptr) { net2->driver.cell->ports[net2->driver.port].net = net2.get(); net->driver.cell = nullptr; } iobuf->ports[ctx->id("I")].net = net2.get(); PortRef ref; ref.cell = iobuf.get(); ref.port = ctx->id("I"); net2->users.push_back(ref); ctx->nets[net2->name] = std::move(net2); iobuf->ports[ctx->id("O")] = PortInfo{ctx->id("O"), net, PORT_OUT}; assert(net->driver.cell == nullptr); net->driver.port = ctx->id("O"); net->driver.cell = iobuf.get(); } else { assert(false); } ctx->cells[iobuf->name] = std::move(iobuf); } void json_import_toplevel_port(Context *ctx, const string &modname, const std::vector &netnames, const string &portname, JsonNode *node) { JsonNode *dir_node = node->data_dict.at("direction"); JsonNode *nets_node = node->data_dict.at("bits"); json_import_ports( ctx, modname, netnames, "Top Level IO", portname, dir_node, nets_node, [ctx](PortType type, const std::string &name, NetInfo *net) { insert_iobuf(ctx, net, type, name); }); } void json_import(Context *ctx, string modname, JsonNode *node) { if (is_blackbox(node)) return; log_info("Importing module %s\n", modname.c_str()); ctx->attrs[ctx->id("module")] = modname; JsonNode *attr_node = node->data_dict.at("attributes"); for (int attrid = 0; attrid < GetSize(attr_node->data_dict_keys); attrid++) { json_import_top_attrib(ctx, modname, attr_node, &ctx->attrs, attrid); } ctx->settings[ctx->id("synth")] = "1"; JsonNode *ports_parent = nullptr; if (node->data_dict.count("ports") > 0) ports_parent = node->data_dict.at("ports"); // Multiple labels might refer to the same net. For now we resolve conflicts thus: // - (toplevel) ports are always preferred // - names with fewer $ are always prefered // - between equal $ counts, fewer .s are prefered // - ties are resolved alphabetically auto prefer_netlabel = [ports_parent](const std::string &a, const std::string &b) { if (ports_parent != nullptr) { if (ports_parent->data_dict.count(a)) return true; if (ports_parent->data_dict.count(b)) return false; } if (b.empty()) return true; long a_dollars = std::count(a.begin(), a.end(), '$'), b_dollars = std::count(b.begin(), b.end(), '$'); if (a_dollars < b_dollars) return true; else if (a_dollars > b_dollars) return false; long a_dots = std::count(a.begin(), a.end(), '.'), b_dots = std::count(b.begin(), b.end(), '.'); if (a_dots < b_dots) return true; else if (a_dots > b_dots) return false; return a < b; }; // Import netnames std::vector netlabels; if (node->data_dict.count("netnames")) { JsonNode *cell_parent = node->data_dict.at("netnames"); for (int nnid = 0; nnid < GetSize(cell_parent->data_dict_keys); nnid++) { JsonNode *here; here = cell_parent->data_dict.at(cell_parent->data_dict_keys[nnid]); std::string basename = cell_parent->data_dict_keys[nnid]; if (here->data_dict.count("bits")) { JsonNode *bits = here->data_dict.at("bits"); assert(bits->type == 'A'); size_t num_bits = bits->data_array.size(); for (size_t i = 0; i < num_bits; i++) { int netid = bits->data_array.at(i)->data_number; if (netid >= int(netlabels.size())) netlabels.resize(netid + 1); std::string name = basename + (num_bits == 1 ? "" : std::string("[") + std::to_string(i) + std::string("]")); if (prefer_netlabel(name, netlabels.at(netid))) netlabels.at(netid) = name; } } } } std::vector netids; std::transform(netlabels.begin(), netlabels.end(), std::back_inserter(netids), [ctx](const std::string &s) { return ctx->id(s); }); if (node->data_dict.count("cells")) { JsonNode *cell_parent = node->data_dict.at("cells"); // // // Loop through all of the logic elements in a flattened design // // for (int cellid = 0; cellid < GetSize(cell_parent->data_dict_keys); cellid++) { JsonNode *here = cell_parent->data_dict.at(cell_parent->data_dict_keys[cellid]); json_import_cell(ctx, modname, netids, here, cell_parent->data_dict_keys[cellid]); } } if (ports_parent != nullptr) { // N.B. ports must be imported after cells for tristate behaviour // to be correct // Loop through all ports, first non-tristate then tristate to handle // interconnected ports correctly for (int portid = 0; portid < GetSize(ports_parent->data_dict_keys); portid++) { JsonNode *here; here = ports_parent->data_dict.at(ports_parent->data_dict_keys[portid]); JsonNode *dir_node = here->data_dict.at("direction"); NPNR_ASSERT(dir_node->type == 'S'); if (dir_node->data_string == "inout") continue; json_import_toplevel_port(ctx, modname, netids, ports_parent->data_dict_keys[portid], here); } for (int portid = 0; portid < GetSize(ports_parent->data_dict_keys); portid++) { JsonNode *here; here = ports_parent->data_dict.at(ports_parent->data_dict_keys[portid]); JsonNode *dir_node = here->data_dict.at("direction"); NPNR_ASSERT(dir_node->type == 'S'); if (dir_node->data_string != "inout") continue; json_import_toplevel_port(ctx, modname, netids, ports_parent->data_dict_keys[portid], here); } } if (node->data_dict.count("netnames")) { JsonNode *net_parent = node->data_dict.at("netnames"); for (int nnid = 0; nnid < GetSize(net_parent->data_dict_keys); nnid++) { JsonNode *here; here = net_parent->data_dict.at(net_parent->data_dict_keys[nnid]); std::string basename = net_parent->data_dict_keys[nnid]; if (here->data_dict.count("bits")) { JsonNode *bits = here->data_dict.at("bits"); assert(bits->type == 'A'); size_t num_bits = bits->data_array.size(); for (size_t i = 0; i < num_bits; i++) { std::string name = basename + (num_bits == 1 ? "" : std::string("[") + std::to_string(i) + std::string("]")); IdString net_id = ctx->id(name); if (here->data_dict.count("attributes") && ctx->nets.find(net_id)!=ctx->nets.end()) { NetInfo *this_net = ctx->nets[net_id].get(); JsonNode *attr_node = here->data_dict.at("attributes"); if (attr_node->type != 'D') log_error("JSON attribute list of \'%s\' is not a data dictionary\n", this_net->name.c_str(ctx)); // // Loop through all attributes, adding them into the // design to annotate the cell // for (int attrid = 0; attrid < GetSize(attr_node->data_dict_keys); attrid++) { json_import_net_attrib(ctx, modname, this_net, attr_node, &this_net->attrs, attrid); } } } } } } check_all_nets_driven(ctx); } }; // End Namespace JsonParser bool parse_json_file(std::istream &f, std::string &filename, Context *ctx) { try { using namespace JsonParser; if (!f) log_error("failed to open JSON file.\n"); int lineno = 1; JsonNode root(f, lineno); if (root.type != 'D') log_error("JSON root node is not a dictionary.\n"); if (root.data_dict.count("modules") != 0) { JsonNode *modules = root.data_dict.at("modules"); if (modules->type != 'D') log_error("JSON modules node is not a dictionary.\n"); for (auto &it : modules->data_dict) json_import(ctx, it.first, it.second); } log_info("Checksum: 0x%08x\n", ctx->checksum()); log_break(); ctx->attributesToArchInfo(); return true; } catch (log_execution_error_exception) { return false; } } bool load_json_settings(std::istream &f, std::string &filename, std::unordered_map &values) { try { using namespace JsonParser; if (!f) log_error("failed to open JSON file.\n"); int lineno = 1; JsonNode root(f, lineno); if (root.type != 'D') log_error("JSON root node is not a dictionary.\n"); if (root.data_dict.count("modules") != 0) { JsonNode *modules = root.data_dict.at("modules"); if (modules->type != 'D') log_error("JSON modules node is not a dictionary.\n"); for (auto &it : modules->data_dict) { JsonNode *node = it.second; if (is_blackbox(node)) continue; if (node->data_dict.count("settings")) { JsonNode *attr_node = node->data_dict.at("settings"); for (int attrid = 0; attrid < GetSize(attr_node->data_dict_keys); attrid++) { JsonNode *param = attr_node->data_dict.at(attr_node->data_dict_keys[attrid]); std::string pId = attr_node->data_dict_keys[attrid]; if (param->type == 'N') { values[pId].setNumber(param->data_number); } else if (param->type == 'S') values[pId].setString(param->data_string); else log_error("JSON parameter type of \"%s\' of module not supported\n", pId.c_str()); } } } } return true; } catch (log_execution_error_exception) { return false; } } NEXTPNR_NAMESPACE_END