#include #include #include #include #include #include #include #include #include #include #include #include #include #include "embedded_data.h" #include "executable_wrapper.h" #include "simdutf.h" #include "uv.h" #if defined(_WIN32) #include // _S_IREAD _S_IWRITE #ifndef S_IRUSR #define S_IRUSR _S_IREAD #endif // S_IRUSR #ifndef S_IWUSR #define S_IWUSR _S_IWRITE #endif // S_IWUSR #endif namespace node { namespace js2c { int Main(int argc, char* argv[]); static bool is_verbose = false; void Debug(const char* format, ...) { va_list arguments; va_start(arguments, format); if (is_verbose) { vfprintf(stderr, format, arguments); } va_end(arguments); } void PrintUvError(const char* syscall, const char* filename, int error) { fprintf(stderr, "[%s] %s: %s\n", syscall, filename, uv_strerror(error)); } int GetStats(const char* path, std::function func) { uv_fs_t req; int r = uv_fs_stat(nullptr, &req, path, nullptr); if (r == 0) { func(static_cast(req.ptr)); } uv_fs_req_cleanup(&req); return r; } bool IsDirectory(const std::string& filename, int* error) { bool result = false; *error = GetStats(filename.c_str(), [&](const uv_stat_t* stats) { result = !!(stats->st_mode & S_IFDIR); }); if (*error != 0) { PrintUvError("stat", filename.c_str(), *error); } return result; } size_t GetFileSize(const std::string& filename, int* error) { size_t result = 0; *error = GetStats(filename.c_str(), [&](const uv_stat_t* stats) { result = stats->st_size; }); return result; } bool EndsWith(const std::string& str, std::string_view suffix) { size_t suffix_len = suffix.length(); size_t str_len = str.length(); if (str_len < suffix_len) { return false; } return str.compare(str_len - suffix_len, suffix_len, suffix) == 0; } bool StartsWith(const std::string& str, std::string_view prefix) { size_t prefix_len = prefix.length(); size_t str_len = str.length(); if (str_len < prefix_len) { return false; } return str.compare(0, prefix_len, prefix) == 0; } bool FilenameIsConfigGypi(const std::string& path) { return path == "config.gypi" || EndsWith(path, "/config.gypi"); } typedef std::vector FileList; typedef std::map FileMap; bool SearchFiles(const std::string& dir, FileMap* file_map, const std::string& extension) { uv_fs_t scan_req; int result = uv_fs_scandir(nullptr, &scan_req, dir.c_str(), 0, nullptr); bool errored = false; if (result < 0) { PrintUvError("scandir", dir.c_str(), result); errored = true; } else { auto it = file_map->insert({extension, FileList()}).first; FileList& files = it->second; files.reserve(files.size() + result); uv_dirent_t dent; while (true) { result = uv_fs_scandir_next(&scan_req, &dent); if (result == UV_EOF) { break; } if (result != 0) { PrintUvError("scandir_next", dir.c_str(), result); errored = true; break; } std::string path = dir + '/' + dent.name; if (EndsWith(path, extension)) { files.emplace_back(path); continue; } if (!IsDirectory(path, &result)) { if (result == 0) { // It's a file, no need to search further. continue; } else { errored = true; break; } } if (!SearchFiles(path, file_map, extension)) { errored = true; break; } } } uv_fs_req_cleanup(&scan_req); return !errored; } constexpr std::string_view kMjsSuffix = ".mjs"; constexpr std::string_view kJsSuffix = ".js"; constexpr std::string_view kGypiSuffix = ".gypi"; constexpr std::string_view depsPrefix = "deps/"; constexpr std::string_view libPrefix = "lib/"; std::set kAllowedExtensions{ kGypiSuffix, kJsSuffix, kMjsSuffix}; std::string_view HasAllowedExtensions(const std::string& filename) { for (const auto& ext : kAllowedExtensions) { if (EndsWith(filename, ext)) { return ext; } } return {}; } using Fragment = std::vector; using Fragments = std::vector>; std::vector Join(const Fragments& fragments, const std::string& separator) { size_t length = separator.size() * (fragments.size() - 1); for (size_t i = 0; i < fragments.size(); ++i) { length += fragments[i].size(); } std::vector buf(length, 0); size_t cursor = 0; for (size_t i = 0; i < fragments.size(); ++i) { const Fragment& fragment = fragments[i]; // Avoid using snprintf on large chunks of data because it's much slower. // It's fine to use it on small amount of data though. if (i != 0) { memcpy(buf.data() + cursor, separator.c_str(), separator.size()); cursor += separator.size(); } memcpy(buf.data() + cursor, fragment.data(), fragment.size()); cursor += fragment.size(); } buf.resize(cursor); return buf; } const char* kTemplate = R"( #include "env-inl.h" #include "node_builtins.h" #include "node_external_reference.h" #include "node_internals.h" namespace node { namespace builtins { %.*s namespace { const ThreadsafeCopyOnWrite global_source_map { BuiltinSourceMap { %.*s } // BuiltinSourceMap }; // ThreadsafeCopyOnWrite } // anonymous namespace void BuiltinLoader::LoadJavaScriptSource() { source_ = global_source_map; } void RegisterExternalReferencesForInternalizedBuiltinCode( ExternalReferenceRegistry* registry) { %.*s } UnionBytes BuiltinLoader::GetConfig() { return UnionBytes(&config_resource); } } // namespace builtins } // namespace node )"; Fragment Format(const Fragments& definitions, const Fragments& initializers, const Fragments& registrations) { std::vector def_buf = Join(definitions, "\n"); size_t def_size = def_buf.size(); std::vector init_buf = Join(initializers, "\n"); size_t init_size = init_buf.size(); std::vector reg_buf = Join(registrations, "\n"); size_t reg_size = reg_buf.size(); size_t result_size = def_size + init_size + reg_size + strlen(kTemplate) + 100; std::vector result(result_size, 0); int r = snprintf(result.data(), result_size, kTemplate, static_cast(def_buf.size()), def_buf.data(), static_cast(init_buf.size()), init_buf.data(), static_cast(reg_buf.size()), reg_buf.data()); result.resize(r); return result; } std::vector ReadFileSync(const char* path, size_t size, int* error) { uv_fs_t req; Debug("ReadFileSync %s with size %zu\n", path, size); uv_file file = uv_fs_open(nullptr, &req, path, O_RDONLY, 0, nullptr); if (req.result < 0) { uv_fs_req_cleanup(&req); *error = req.result; return std::vector(); } uv_fs_req_cleanup(&req); std::vector contents(size); size_t offset = 0; while (offset < size) { uv_buf_t buf = uv_buf_init(contents.data() + offset, size - offset); int bytes_read = uv_fs_read(nullptr, &req, file, &buf, 1, offset, nullptr); offset += bytes_read; *error = req.result; uv_fs_req_cleanup(&req); if (*error < 0) { uv_fs_close(nullptr, &req, file, nullptr); // We can't do anything if uv_fs_close returns error, so just return. return std::vector(); } if (bytes_read <= 0) { break; } } assert(offset == size); *error = uv_fs_close(nullptr, &req, file, nullptr); return contents; } int WriteFileSync(const std::vector& out, const char* path) { Debug("WriteFileSync %zu bytes to %s\n", out.size(), path); uv_fs_t req; uv_file file = uv_fs_open(nullptr, &req, path, UV_FS_O_CREAT | UV_FS_O_WRONLY | UV_FS_O_TRUNC, S_IWUSR | S_IRUSR, nullptr); int err = req.result; uv_fs_req_cleanup(&req); if (err < 0) { return err; } uv_buf_t buf = uv_buf_init(const_cast(out.data()), out.size()); err = uv_fs_write(nullptr, &req, file, &buf, 1, 0, nullptr); uv_fs_req_cleanup(&req); int r = uv_fs_close(nullptr, &req, file, nullptr); uv_fs_req_cleanup(&req); if (err < 0) { // We can't do anything if uv_fs_close returns error, so just return. return err; } return r; } int WriteIfChanged(const Fragment& out, const std::string& dest) { Debug("output size %zu\n", out.size()); int error = 0; size_t size = GetFileSize(dest, &error); if (error != 0 && error != UV_ENOENT) { return error; } Debug("existing size %zu\n", size); bool changed = true; // If it's not the same size, the file is definitely changed so we'll // just proceed to update. Otherwise check the content before deciding // whether we want to write it. if (error != UV_ENOENT && size == out.size()) { std::vector content = ReadFileSync(dest.c_str(), size, &error); if (error == 0) { // In case of error, always write the file. changed = (memcmp(content.data(), out.data(), size) != 0); } } if (!changed) { Debug("No change, return\n"); return 0; } return WriteFileSync(out, dest.c_str()); } std::string GetFileId(const std::string& filename) { size_t end = filename.size(); size_t start = 0; std::string prefix; // Strip .mjs and .js suffix if (EndsWith(filename, kMjsSuffix)) { end -= kMjsSuffix.size(); } else if (EndsWith(filename, kJsSuffix)) { end -= kJsSuffix.size(); } // deps/acorn/acorn/dist/acorn.js -> internal/deps/acorn/acorn/dist/acorn if (StartsWith(filename, depsPrefix)) { start = depsPrefix.size(); prefix = "internal/deps/"; } else if (StartsWith(filename, libPrefix)) { // lib/internal/url.js -> internal/url start = libPrefix.size(); prefix = ""; } return prefix + std::string(filename.begin() + start, filename.begin() + end); } std::string GetVariableName(const std::string& id) { std::string result = id; size_t length = result.size(); for (size_t i = 0; i < length; ++i) { if (result[i] == '.' || result[i] == '-' || result[i] == '/') { result[i] = '_'; } } return result; } std::vector GetCodeTable() { size_t size = 1 << 16; std::vector code_table(size); for (size_t i = 0; i < size; ++i) { code_table[i] = std::to_string(i) + ','; } return code_table; } const std::string& GetCode(uint16_t index) { static std::vector table = GetCodeTable(); return table[index]; } #ifdef NODE_JS2C_USE_STRING_LITERALS const char* string_literal_def_template = "static const %s *%s_raw = "; constexpr std::string_view latin1_string_literal_start = "reinterpret_cast(\""; constexpr std::string_view ascii_string_literal_start = "reinterpret_cast(R\"JS2C1b732aee("; constexpr std::string_view utf16_string_literal_start = "reinterpret_cast(uR\"JS2C1b732aee("; constexpr std::string_view latin1_string_literal_end = "\");"; constexpr std::string_view utf_string_literal_end = ")JS2C1b732aee\");"; #else const char* array_literal_def_template = "static const %s %s_raw[] = "; constexpr std::string_view array_literal_start = "{\n"; constexpr std::string_view array_literal_end = "\n};\n\n"; #endif // Definitions: // static const uint8_t fs_raw[] = { // .... // }; // // static StaticExternalOneByteResource fs_resource(fs_raw, 1234, nullptr); // // static const uint16_t internal_cli_table_raw[] = { // .... // }; // // static StaticExternalTwoByteResource // internal_cli_table_resource(internal_cli_table_raw, 1234, nullptr); // // If NODE_JS2C_USE_STRING_LITERALS is defined, the data is output as C++ // raw strings (i.e. R"JS2C1b732aee(...)JS2C1b732aee") rather than as an // array. This speeds up compilation for gcc/clang. enum class CodeType { kAscii, // Code points are all within 0-127 kLatin1, // Code points are all within 0-255 kTwoByte, }; template Fragment GetDefinitionImpl(const std::vector& code, const std::string& var, CodeType type) { constexpr bool is_two_byte = std::is_same_v; static_assert(is_two_byte || std::is_same_v); size_t count = is_two_byte ? simdutf::utf16_length_from_utf8(code.data(), code.size()) : code.size(); constexpr const char* arr_type = is_two_byte ? "uint16_t" : "uint8_t"; constexpr const char* resource_type = is_two_byte ? "StaticExternalTwoByteResource" : "StaticExternalOneByteResource"; #ifdef NODE_JS2C_USE_STRING_LITERALS const char* literal_def_template = string_literal_def_template; // For code that contains Latin-1 characters, be conservative and assume // they all need escaping: one "\" and three digits. size_t unit = type == CodeType::kLatin1 ? 4 : 1; size_t def_size = 512 + code.size() * unit; #else const char* literal_def_template = array_literal_def_template; constexpr size_t unit = (is_two_byte ? 5 : 3) + 1; // 0-65536 or 0-255 and a "," size_t def_size = 512 + count * unit; #endif Fragment result(def_size, 0); int cur = snprintf( result.data(), def_size, literal_def_template, arr_type, var.c_str()); assert(cur != 0); #ifdef NODE_JS2C_USE_STRING_LITERALS std::string_view start_string_view; switch (type) { case CodeType::kAscii: start_string_view = ascii_string_literal_start; break; case CodeType::kLatin1: start_string_view = latin1_string_literal_start; break; case CodeType::kTwoByte: start_string_view = utf16_string_literal_start; break; } memcpy( result.data() + cur, start_string_view.data(), start_string_view.size()); cur += start_string_view.size(); if (type != CodeType::kLatin1) { memcpy(result.data() + cur, code.data(), code.size()); cur += code.size(); } else { const uint8_t* ptr = reinterpret_cast(code.data()); for (size_t i = 0; i < count; ++i) { // Avoid using snprintf on large chunks of data because it's much slower. // It's fine to use it on small amount of data though. uint8_t ch = ptr[i]; if (ch > 127) { Debug("In %s, found non-ASCII Latin-1 character at %zu: %d\n", var.c_str(), i, ch); } const std::string& str = GetOctalCode(ch); memcpy(result.data() + cur, str.c_str(), str.size()); cur += str.size(); } } std::string_view string_literal_end; switch (type) { case CodeType::kAscii: string_literal_end = utf_string_literal_end; break; case CodeType::kLatin1: string_literal_end = latin1_string_literal_end; break; case CodeType::kTwoByte: string_literal_end = utf_string_literal_end; break; } memcpy(result.data() + cur, string_literal_end.data(), string_literal_end.size()); cur += string_literal_end.size(); #else memcpy(result.data() + cur, array_literal_start.data(), array_literal_start.size()); cur += array_literal_start.size(); // Avoid using snprintf on large chunks of data because it's much slower. // It's fine to use it on small amount of data though. if constexpr (is_two_byte) { std::vector utf16_codepoints; utf16_codepoints.resize(count); size_t utf16_count = simdutf::convert_utf8_to_utf16( code.data(), code.size(), reinterpret_cast(utf16_codepoints.data())); assert(utf16_count != 0); utf16_codepoints.resize(utf16_count); Debug("static size %zu\n", utf16_count); for (size_t i = 0; i < utf16_count; ++i) { const std::string& str = GetCode(utf16_codepoints[i]); memcpy(result.data() + cur, str.c_str(), str.size()); cur += str.size(); } } else { const uint8_t* ptr = reinterpret_cast(code.data()); for (size_t i = 0; i < count; ++i) { uint16_t ch = static_cast(ptr[i]); if (ch > 127) { Debug("In %s, found non-ASCII Latin-1 character at %zu: %d\n", var.c_str(), i, ch); } const std::string& str = GetCode(ch); memcpy(result.data() + cur, str.c_str(), str.size()); cur += str.size(); } } memcpy( result.data() + cur, array_literal_end.data(), array_literal_end.size()); cur += array_literal_end.size(); #endif int end_size = snprintf(result.data() + cur, result.size() - cur, "static %s %s_resource(%s_raw, %zu, nullptr);\n", resource_type, var.c_str(), var.c_str(), count); cur += end_size; result.resize(cur); return result; } bool Simplify(const std::vector& code, const std::string& var, std::vector* simplified) { // Allowlist files to avoid false positives. // TODO(joyeecheung): this could be removed if undici updates itself // to replace "’" with "'" though we could still keep this skeleton in // place for future hot fixes that are verified by humans. if (var != "internal_deps_undici_undici") { return false; } size_t code_size = code.size(); simplified->reserve(code_size); const uint8_t* ptr = reinterpret_cast(code.data()); size_t simplified_count = 0; for (size_t i = 0; i < code_size; ++i) { switch (ptr[i]) { case 226: { // ’ [ 226, 128, 153 ] -> ' if (i + 2 < code_size && ptr[i + 1] == 128 && ptr[i + 2] == 153) { simplified->push_back('\''); i += 2; simplified_count++; break; } [[fallthrough]]; } default: { simplified->push_back(code[i]); break; } } } if (simplified_count > 0) { Debug("Simplified %lu characters, ", simplified_count); Debug("old size %lu, new size %lu\n", code_size, simplified->size()); return true; } return false; } Fragment GetDefinition(const std::string& var, const std::vector& code) { Debug("GetDefinition %s, code size %zu\n", var.c_str(), code.size()); bool is_ascii = simdutf::validate_ascii(code.data(), code.size()); if (is_ascii) { Debug("ASCII-only, static size %zu\n", code.size()); return GetDefinitionImpl(code, var, CodeType::kAscii); } std::vector latin1(code.size()); auto result = simdutf::convert_utf8_to_latin1_with_errors( code.data(), code.size(), latin1.data()); if (!result.error) { latin1.resize(result.count); Debug("Latin-1-only, old size %zu, new size %zu\n", code.size(), latin1.size()); return GetDefinitionImpl(latin1, var, CodeType::kLatin1); } // Since V8 only supports Latin-1 and UTF16 as underlying representation // we have to encode all files containing two-byte characters as UTF16. // While some files do need two-byte characters, some just // unintentionally have them. Replace certain characters that are known // to have sane one-byte equivalent to save space. std::vector simplified; if (Simplify(code, var, &simplified)) { // Changed. Debug("%s is simplified, re-generate definition\n", var.c_str()); return GetDefinition(var, simplified); } // Simplification did not turn the code into 1-byte string. Just // use the original. return GetDefinitionImpl(code, var, CodeType::kTwoByte); } int AddModule(const std::string& filename, Fragments* definitions, Fragments* initializers, Fragments* registrations) { Debug("AddModule %s start\n", filename.c_str()); int error = 0; size_t file_size = GetFileSize(filename, &error); if (error != 0) { return error; } std::vector code = ReadFileSync(filename.c_str(), file_size, &error); if (error != 0) { return error; } std::string file_id = GetFileId(filename); std::string var = GetVariableName(file_id); definitions->emplace_back(GetDefinition(var, code)); // Initializers of the BuiltinSourceMap: // {"fs", UnionBytes{&fs_resource}}, Fragment& init_buf = initializers->emplace_back(Fragment(256, 0)); int init_size = snprintf(init_buf.data(), init_buf.size(), " {\"%s\", UnionBytes(&%s_resource) },", file_id.c_str(), var.c_str()); init_buf.resize(init_size); // Registrations: // registry->Register(&fs_resource); Fragment& reg_buf = registrations->emplace_back(Fragment(256, 0)); int reg_size = snprintf(reg_buf.data(), reg_buf.size(), " registry->Register(&%s_resource);", var.c_str()); reg_buf.resize(reg_size); return 0; } std::vector ReplaceAll(const std::vector& data, const std::string& search, const std::string& replacement) { auto cur = data.begin(); auto last = data.begin(); std::vector result; result.reserve(data.size()); while ((cur = std::search(last, data.end(), search.begin(), search.end())) != data.end()) { result.insert(result.end(), last, cur); result.insert(result.end(), replacement.c_str(), replacement.c_str() + replacement.size()); last = cur + search.size(); } result.insert(result.end(), last, data.end()); return result; } std::vector StripComments(const std::vector& input) { std::vector result; result.reserve(input.size()); auto last_hash = input.cbegin(); auto line_begin = input.cbegin(); auto end = input.cend(); while ((last_hash = std::find(line_begin, end, '#')) != end) { result.insert(result.end(), line_begin, last_hash); line_begin = std::find(last_hash, end, '\n'); if (line_begin != end) { line_begin += 1; } } result.insert(result.end(), line_begin, end); return result; } // This is technically unused for our config.gypi, but just porting it here to // mimic js2c.py. std::vector JoinMultilineString(const std::vector& input) { std::vector result; result.reserve(input.size()); auto closing_quote = input.cbegin(); auto last_inserted = input.cbegin(); auto end = input.cend(); std::string search = "'\n"; while ((closing_quote = std::search( last_inserted, end, search.begin(), search.end())) != end) { if (closing_quote != last_inserted) { result.insert(result.end(), last_inserted, closing_quote - 1); last_inserted = closing_quote - 1; } auto opening_quote = closing_quote + 2; while (opening_quote != end && isspace(*opening_quote)) { opening_quote++; } if (opening_quote == end) { break; } if (*opening_quote == '\'') { last_inserted = opening_quote + 1; } else { result.insert(result.end(), last_inserted, opening_quote); last_inserted = opening_quote; } } result.insert(result.end(), last_inserted, end); return result; } std::vector JSONify(const std::vector& code) { // 1. Remove string comments std::vector stripped = StripComments(code); // 2. join multiline strings std::vector joined = JoinMultilineString(stripped); // 3. normalize string literals from ' into " for (size_t i = 0; i < joined.size(); ++i) { if (joined[i] == '\'') { joined[i] = '"'; } } // 4. turn pseudo-booleans strings into Booleans std::vector result3 = ReplaceAll(joined, R"("true")", "true"); std::vector result4 = ReplaceAll(result3, R"("false")", "false"); return result4; } int AddGypi(const std::string& var, const std::string& filename, Fragments* definitions) { Debug("AddGypi %s start\n", filename.c_str()); int error = 0; size_t file_size = GetFileSize(filename, &error); if (error != 0) { return error; } std::vector code = ReadFileSync(filename.c_str(), file_size, &error); if (error != 0) { return error; } assert(var == "config"); std::vector transformed = JSONify(code); definitions->emplace_back(GetDefinition(var, transformed)); return 0; } int JS2C(const FileList& js_files, const FileList& mjs_files, const std::string& config, const std::string& dest) { Fragments definitions; definitions.reserve(js_files.size() + mjs_files.size() + 1); Fragments initializers; initializers.reserve(js_files.size() + mjs_files.size()); Fragments registrations; registrations.reserve(js_files.size() + mjs_files.size() + 1); for (const auto& filename : js_files) { int r = AddModule(filename, &definitions, &initializers, ®istrations); if (r != 0) { return r; } } for (const auto& filename : mjs_files) { int r = AddModule(filename, &definitions, &initializers, ®istrations); if (r != 0) { return r; } } assert(FilenameIsConfigGypi(config)); // "config.gypi" -> config_raw. int r = AddGypi("config", config, &definitions); if (r != 0) { return r; } Fragment out = Format(definitions, initializers, registrations); return WriteIfChanged(out, dest); } int PrintUsage(const char* argv0) { fprintf(stderr, "Usage: %s [--verbose] [--root /path/to/project/root] " "path/to/output.cc path/to/directory " "[extra-files ...]\n", argv0); return 1; } int Main(int argc, char* argv[]) { if (argc < 3) { return PrintUsage(argv[0]); } std::vector args; args.reserve(argc); std::string root_dir; for (int i = 1; i < argc; ++i) { std::string arg(argv[i]); if (arg == "--verbose") { is_verbose = true; } else if (arg == "--root") { if (i == argc - 1) { fprintf(stderr, "--root must be followed by a path\n"); return 1; } root_dir = argv[++i]; } else { args.emplace_back(argv[i]); } } if (args.size() < 2) { return PrintUsage(argv[0]); } if (!root_dir.empty()) { int r = uv_chdir(root_dir.c_str()); if (r != 0) { fprintf(stderr, "Cannot switch to the directory specified by --root\n"); PrintUvError("chdir", root_dir.c_str(), r); return 1; } } std::string output = args[0]; FileMap file_map; for (size_t i = 1; i < args.size(); ++i) { int error = 0; const std::string& file = args[i]; if (IsDirectory(file, &error)) { if (!SearchFiles(file, &file_map, std::string(kJsSuffix)) || !SearchFiles(file, &file_map, std::string(kMjsSuffix))) { return 1; } } else if (error != 0) { return 1; } else { // It's a file. std::string_view extension = HasAllowedExtensions(file); if (extension.size() != 0) { auto it = file_map.insert({std::string(extension), FileList()}).first; it->second.push_back(file); } else { fprintf(stderr, "Unsupported file: %s\n", file.c_str()); return 1; } } } // Should have exactly 3 types: `.js`, `.mjs` and `.gypi`. assert(file_map.size() == 3); auto gypi_it = file_map.find(".gypi"); // Currently config.gypi is the only `.gypi` file allowed if (gypi_it == file_map.end() || gypi_it->second.size() != 1 || !FilenameIsConfigGypi(gypi_it->second[0])) { fprintf( stderr, "Arguments should contain one and only one .gypi file: config.gypi\n"); return 1; } auto js_it = file_map.find(".js"); auto mjs_it = file_map.find(".mjs"); assert(js_it != file_map.end() && mjs_it != file_map.end()); auto it = std::find(mjs_it->second.begin(), mjs_it->second.end(), "lib/eslint.config_partial.mjs"); if (it != mjs_it->second.end()) { mjs_it->second.erase(it); } std::sort(js_it->second.begin(), js_it->second.end()); std::sort(mjs_it->second.begin(), mjs_it->second.end()); return JS2C(js_it->second, mjs_it->second, gypi_it->second[0], output); } } // namespace js2c } // namespace node NODE_MAIN(int argc, node::argv_type raw_argv[]) { char** argv; node::FixupMain(argc, raw_argv, &argv); return node::js2c::Main(argc, argv); }