#include "StrFmt.h" #include "StrUtil.h" #include "cfmt.h" #include "util/endian.hpp" #include "util/logs.hpp" #include "util/v128.hpp" #include #include #include #include #include "Thread.h" #ifdef _WIN32 #include #else #include #endif #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable : 4996) #elif defined(__clang__) #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wdeprecated-declarations" #else #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wdeprecated-declarations" #endif std::string wchar_to_utf8(std::wstring_view src) { #ifdef _WIN32 std::string utf8_string; const int size = ::narrow(src.size()); const auto tmp_size = WideCharToMultiByte(CP_UTF8, 0, src.data(), size, nullptr, 0, nullptr, nullptr); utf8_string.resize(tmp_size); WideCharToMultiByte(CP_UTF8, 0, src.data(), size, utf8_string.data(), tmp_size, nullptr, nullptr); return utf8_string; #else std::wstring_convert, wchar_t> converter{}; return converter.to_bytes(src.data()); #endif } std::string utf16_to_utf8(std::u16string_view src) { std::wstring_convert, char16_t> converter{}; return converter.to_bytes(src.data()); } std::u16string utf8_to_utf16(std::string_view src) { std::wstring_convert, char16_t> converter{}; return converter.from_bytes(src.data()); } std::wstring utf8_to_wchar(std::string_view src) { #ifdef _WIN32 std::wstring wchar_string; const int size = ::narrow(src.size()); const auto tmp_size = MultiByteToWideChar(CP_UTF8, 0, src.data(), size, nullptr, 0); wchar_string.resize(tmp_size); MultiByteToWideChar(CP_UTF8, 0, src.data(), size, wchar_string.data(), tmp_size); return wchar_string; #else std::wstring_convert, wchar_t> converter{}; return converter.from_bytes(src.data()); #endif } #ifdef _MSC_VER #pragma warning(pop) #elif defined(__clang__) #pragma clang diagnostic pop #else #pragma GCC diagnostic pop #endif #ifdef _WIN32 std::string fmt::win_error_to_string(unsigned long error, void* module_handle) { std::string message; LPWSTR message_buffer = nullptr; if (FormatMessageW((module_handle ? FORMAT_MESSAGE_FROM_HMODULE : FORMAT_MESSAGE_FROM_SYSTEM) | FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_IGNORE_INSERTS, module_handle, error, 0, reinterpret_cast(&message_buffer), 0, nullptr)) { message = fmt::format("%s (0x%x)", fmt::trim(wchar_to_utf8(message_buffer), " \t\n\r\f\v"), error); } else { message = fmt::format("0x%x", error); } if (message_buffer) { LocalFree(message_buffer); } return message; } std::string fmt::win_error_to_string(const fmt::win_error& error) { return fmt::win_error_to_string(error.error, error.module_handle); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%s", fmt::win_error_to_string(get_object(arg))); } #endif template <> void fmt_class_string>::format(std::string& out, u64 arg) { // Dynamic format arg const auto& pair = get_object(arg); if (pair.first) { pair.first->fmt_string(out, pair.second); } } template <> void fmt_class_string::format(std::string& out, u64 arg) { const auto& _arg = get_object(arg); if (_arg.data && _arg.size) { // Precomputed tail sizes if input data is not multiple of 8 static constexpr u8 s_tail[8] = {0, 2, 3, 5, 6, 7, 9, 10}; // Get full output size const usz out_size = _arg.size / 8 * 11 + s_tail[_arg.size % 8]; out.resize(out.size() + out_size); const auto ptr = &out.front() + (out.size() - out_size); // Each 8 bytes of input data produce 11 bytes of base57 output for (usz i = 0, p = 0; i < _arg.size; i += 8, p += 11) { // Load up to 8 bytes be_t be_value; if (_arg.size - i < sizeof(be_value)) { std::memset(&be_value, 0, sizeof(be_value)); std::memcpy(&be_value, _arg.data + i, _arg.size - i); } else { std::memcpy(&be_value, _arg.data + i, sizeof(be_value)); } u64 value = be_value; for (int j = 10; j >= 0; j--) { if (p + j < out_size) { ptr[p + j] = "0123456789ACEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz"[value % 57]; } value /= 57; } } } } fmt::base57_result fmt::base57_result::from_string(std::string_view str) { fmt::base57_result result(str.size() / 11 * 8 + (str.size() % 11 ? 8 : 0)); // Each 11 chars of input produces 8 bytes of byte output for (usz i = 0, p = 0; i < result.size; i += 8, p += 11) { // Load up to 8 bytes const std::string_view be_value = str.substr(p); be_t value = 0; for (u64 j = 10, multiplier = 0; j != umax; j--) { if (multiplier == 0) { multiplier = 1; } else { // Do it first to avoid overflow multiplier *= 57; } if (j < be_value.size()) { auto to_val = [](u8 c) -> u64 { if (std::isdigit(c)) { return c - '0'; } if (std::isupper(c)) { // Omitted characters if (c == 'B' || c == 'D' || c == 'I' || c == 'O') { return umax; } if (c > 'O') { c -= 4; } else if (c > 'I') { c -= 3; } else if (c > 'D') { c -= 2; } else if (c > 'B') { c--; } return c - 'A' + 10; } if (std::islower(c)) { // Omitted characters if (c == 'l') { return umax; } if (c > 'l') { c--; } return c - 'a' + 10 + 22; } return umax; }; const u64 res = to_val(be_value[j]); if (res == umax) { // Invalid input character result = {}; break; } if (u64{umax} / multiplier < res) { // Overflow result = {}; break; } const u64 addend = res * multiplier; if (~value < addend) { // Overflow result = {}; break; } value += addend; } } if (!result.size) { break; } if (result.size - i < sizeof(value)) { std::memcpy(result.memory.get() + i, &value, result.size - i); } else { std::memcpy(result.memory.get() + i, &value, sizeof(value)); } } return result; } void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%p", arg); } void fmt_class_string::format(std::string& out, u64 arg) { if (arg) { out += reinterpret_cast(arg); } else { out += "(NULLSTR)"; } } void fmt_class_string::format(std::string& out, u64 arg) { out += wchar_to_utf8(reinterpret_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { out += get_object(arg); } template <> void fmt_class_string::format(std::string& out, u64 arg) { out += get_object(arg); } template <> void fmt_class_string>::format(std::string& out, u64 arg) { const std::vector& obj = get_object(arg); out.append(obj.cbegin(), obj.cend()); } template <> void fmt_class_string::format(std::string& out, u64 arg) { const std::u8string& obj = get_object(arg); out.append(obj.cbegin(), obj.cend()); } template <> void fmt_class_string::format(std::string& out, u64 arg) { const std::u8string_view& obj = get_object(arg); out.append(obj.cbegin(), obj.cend()); } template <> void fmt_class_string>::format(std::string& out, u64 arg) { const std::vector& obj = get_object(arg); out.append(obj.cbegin(), obj.cend()); } template <> void fmt_class_string::format(std::string& out, u64 arg) { const auto& _arg = get_object(arg); const std::vector buf(_arg.buf, _arg.buf + _arg.len); out.reserve(out.size() + (buf.size() * 3)); static constexpr char hex[16] = {'0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'A', 'B', 'C', 'D', 'E', 'F'}; const bool use_linebreak = _arg.line_length > 0; for (usz index = 0; index < buf.size(); index++) { if (index > 0) { if (use_linebreak && (index % _arg.line_length) == 0) out += '\n'; else out += ' '; } if (_arg.with_prefix) out += "0x"; out += hex[buf[index] >> 4]; out += hex[buf[index] & 15]; } } void format_byte_array(std::string& out, const uchar* data, usz size) { if (!size) { out += "{ EMPTY }"; return; } out += "{ "; for (usz i = 0;; i++) { if (i == size - 1) { fmt::append(out, "%02X", data[i]); break; } if ((i % 4) == 3) { // Place a comma each 4 bytes for ease of byte placement finding fmt::append(out, "%02X, ", data[i]); continue; } fmt::append(out, "%02X ", data[i]); } out += " }"; } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#hhx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#hhx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#hhx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#hx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#hx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#x", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#x", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#lx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#lx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#llx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%#llx", static_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%gf", static_cast(std::bit_cast(arg))); } template <> void fmt_class_string::format(std::string& out, u64 arg) { fmt::append(out, "%g", std::bit_cast(arg)); } template <> void fmt_class_string::format(std::string& out, u64 arg) { out += arg ? "true" : "false"; } template <> void fmt_class_string::format(std::string& out, u64 arg) { out += get_object(arg) ? "true" : "false"; } template <> void fmt_class_string::format(std::string& out, u64 arg) { const v128& vec = get_object(arg); fmt::append(out, "0x%016llx%016llx", vec._u64[1], vec._u64[0]); } template <> void fmt_class_string::format(std::string& out, u64 arg) { // TODO: it should be supported as full-fledged integral type (with %u, %d, etc, fmt) const u128& num = get_object(arg); if (!num) { out += '0'; return; } #ifdef _MSC_VER fmt::append(out, "0x%016llx%016llx", num.hi, num.lo); #else fmt::append(out, "0x%016llx%016llx", static_cast(num >> 64), static_cast(num)); #endif } template <> void fmt_class_string::format(std::string& out, u64 arg) { return fmt_class_string::format(out, arg); } template <> void fmt_class_string::format(std::string& out, u64 arg) { const std::source_location& loc = get_object(arg); auto is_valid = [](auto num) { return num && num != umax; }; const bool has_line = is_valid(loc.line()); if (has_line && is_valid(loc.column())) { fmt::append(out, "\n(in file %s:%u[:%u]", loc.file_name(), loc.line(), loc.column()); } else if (has_line) { fmt::append(out, "\n(in file %s:%u", loc.file_name(), loc.line()); } // Let's not care about such useless corner cases // else if (is_valid(loc.column()) else { fmt::append(out, "\n(in file %s", loc.file_name()); } if (auto func = loc.function_name(); func && func[0]) { fmt::append(out, ", in function %s)", func); } else { out += ')'; } // Print error code (may be irrelevant) #ifdef _WIN32 if (DWORD error = GetLastError()) { fmt::append(out, " (error=%s)", error, fmt::win_error_to_string(error)); } #else if (int error = errno) { fmt::append(out, " (errno=%d=%s)", error, strerror(errno)); } #endif } namespace fmt { [[noreturn]] void raw_verify_error(std::source_location loc, const char8_t* msg) { std::string out; fmt::append(out, "%s%s", msg ? msg : u8"Verification failed", loc); thread_ctrl::emergency_exit(out); } [[noreturn]] void raw_throw_exception(std::source_location loc, const char* fmt, const fmt_type_info* sup, const u64* args) { std::string out; raw_append(out, fmt, sup, args); fmt::append(out, "%s", loc); thread_ctrl::emergency_exit(out); } struct cfmt_src; } // Temporary implementation struct fmt::cfmt_src { const fmt_type_info* sup; const u64* args; bool test(usz index) const { if (!sup[index].fmt_string) { return false; } return true; } template T get(usz index) const { T res{}; std::memcpy(&res, reinterpret_cast(args + index), sizeof(res)); return res; } void skip(usz extra) { sup += extra + 1; args += extra + 1; } usz fmt_string(std::string& out, usz extra) const { const usz start = out.size(); sup[extra].fmt_string(out, args[extra]); return out.size() - start; } // Returns type size (0 if unknown, pointer, unsigned, assumed max) usz type(usz extra) const { // Hack: use known function pointers to determine type #define TYPE(type) \ if (sup[extra].fmt_string == &fmt_class_string::format) return sizeof(type); TYPE(int); TYPE(llong); TYPE(schar); TYPE(short); if (std::is_signed_v) TYPE(char); TYPE(long); TYPE(s128); #undef TYPE if (sup[extra].fmt_string == &fmt_class_string::format) return -1; return 0; } static constexpr usz size_char = 1; static constexpr usz size_short = 2; static constexpr usz size_int = 0; static constexpr usz size_long = sizeof(ulong); static constexpr usz size_llong = sizeof(ullong); static constexpr usz size_size = sizeof(usz); static constexpr usz size_max = sizeof(std::uintmax_t); static constexpr usz size_diff = sizeof(std::ptrdiff_t); }; void fmt::raw_append(std::string& out, const char* fmt, const fmt_type_info* sup, const u64* args) noexcept { cfmt_append(out, fmt, cfmt_src{sup, args}); } std::string fmt::replace_all(std::string_view src, std::string_view from, std::string_view to, usz count) { std::string target; target.reserve(src.size() + to.size()); for (usz i = 0, replaced = 0; i < src.size();) { const usz pos = src.find(from, i); if (pos == umax || replaced++ >= count) { // No match or too many encountered, append the rest of the string as is target.append(src.substr(i)); break; } // Append source until the matched string position target.append(src.substr(i, pos - i)); // Replace string target.append(to); i = pos + from.size(); } return target; } std::vector fmt::split(std::string_view source, std::initializer_list separators, bool is_skip_empty) { std::vector result; for (usz index = 0; index < source.size();) { usz pos = -1; usz sep_size = 0; for (auto& separator : separators) { if (usz pos0 = source.find(separator, index); pos0 < pos) { pos = pos0; sep_size = separator.size(); } } if (!sep_size) { result.emplace_back(&source[index], source.size() - index); return result; } std::string_view piece = {&source[index], pos - index}; index = pos + sep_size; if (piece.empty() && is_skip_empty) { continue; } result.emplace_back(std::string(piece)); } if (result.empty() && !is_skip_empty) { result.emplace_back(); } return result; } std::string fmt::trim(const std::string& source, std::string_view values) { const usz begin = source.find_first_not_of(values); if (begin == source.npos) return {}; return source.substr(begin, source.find_last_not_of(values) + 1); } std::string fmt::trim_front(const std::string& source, std::string_view values) { const usz begin = source.find_first_not_of(values); if (begin == source.npos) return {}; return source.substr(begin); } void fmt::trim_back(std::string& source, std::string_view values) { const usz index = source.find_last_not_of(values); source.resize(index + 1); } std::string fmt::to_upper(std::string_view string) { std::string result; result.resize(string.size()); std::transform(string.begin(), string.end(), result.begin(), ::toupper); return result; } std::string fmt::to_lower(std::string_view string) { std::string result; result.resize(string.size()); std::transform(string.begin(), string.end(), result.begin(), ::tolower); return result; } std::string fmt::truncate(std::string_view src, usz length) { return std::string(src.begin(), src.begin() + std::min(src.size(), length)); } bool fmt::match(const std::string& source, const std::string& mask) { usz source_position = 0, mask_position = 0; for (; source_position < source.size() && mask_position < mask.size(); ++mask_position, ++source_position) { switch (mask[mask_position]) { case '?': break; case '*': for (usz test_source_position = source_position; test_source_position < source.size(); ++test_source_position) { if (match(source.substr(test_source_position), mask.substr(mask_position + 1))) { return true; } } return false; default: if (source[source_position] != mask[mask_position]) { return false; } break; } } if (source_position != source.size()) return false; if (mask_position != mask.size()) return false; return true; } std::string get_file_extension(const std::string& file_path) { if (usz dotpos = file_path.find_last_of('.'); dotpos != std::string::npos && dotpos + 1 < file_path.size()) { return file_path.substr(dotpos + 1); } return {}; }