#include #include #include #include #include #include #define IMGUI_DEFINE_MATH_OPERATORS #include #if defined(OS_WINDOWS) #include #elif defined(OS_LINUX) #include #elif defined(OS_MACOS) #include #include #endif namespace hex { long double operator""_scaled(long double value) { return value * ImHexApi::System::getGlobalScale(); } long double operator""_scaled(unsigned long long value) { return value * ImHexApi::System::getGlobalScale(); } ImVec2 scaled(const ImVec2 &vector) { return vector * ImHexApi::System::getGlobalScale(); } std::string to_string(u128 value) { char data[45] = { 0 }; u8 index = sizeof(data) - 2; while (value != 0 && index != 0) { data[index] = '0' + value % 10; value /= 10; index--; } return { data + index + 1 }; } std::string to_string(i128 value) { char data[45] = { 0 }; u128 unsignedValue = value < 0 ? -value : value; u8 index = sizeof(data) - 2; while (unsignedValue != 0 && index != 0) { data[index] = '0' + unsignedValue % 10; unsignedValue /= 10; index--; } if (value < 0) { data[index] = '-'; return { data + index }; } else return { data + index + 1 }; } std::string toByteString(u64 bytes) { double value = bytes; u8 unitIndex = 0; while (value > 1024) { value /= 1024; unitIndex++; if (unitIndex == 6) break; } std::string result; if (unitIndex == 0) result = hex::format("{0:}", value); else result = hex::format("{0:.2f}", value); switch (unitIndex) { case 0: result += ((value == 1) ? " Byte" : " Bytes"); break; case 1: result += " kiB"; break; case 2: result += " MiB"; break; case 3: result += " GiB"; break; case 4: result += " TiB"; break; case 5: result += " PiB"; break; case 6: result += " EiB"; break; default: result = "A lot!"; } return result; } std::string makeStringPrintable(const std::string &string) { std::string result; for (char c : string) { if (std::isprint(c)) result += c; else result += hex::format("\\x{0:02X}", u8(c)); } return result; } std::string makePrintable(u8 c) { switch (c) { case 0: return "NUL"; case 1: return "SOH"; case 2: return "STX"; case 3: return "ETX"; case 4: return "EOT"; case 5: return "ENQ"; case 6: return "ACK"; case 7: return "BEL"; case 8: return "BS"; case 9: return "TAB"; case 10: return "LF"; case 11: return "VT"; case 12: return "FF"; case 13: return "CR"; case 14: return "SO"; case 15: return "SI"; case 16: return "DLE"; case 17: return "DC1"; case 18: return "DC2"; case 19: return "DC3"; case 20: return "DC4"; case 21: return "NAK"; case 22: return "SYN"; case 23: return "ETB"; case 24: return "CAN"; case 25: return "EM"; case 26: return "SUB"; case 27: return "ESC"; case 28: return "FS"; case 29: return "GS"; case 30: return "RS"; case 31: return "US"; case 32: return "Space"; case 127: return "DEL"; case 128 ... 255: return " "; default: return std::string() + static_cast(c); } } std::vector splitString(const std::string &string, const std::string &delimiter) { size_t start = 0, end = 0; std::string token; std::vector res; while ((end = string.find(delimiter, start)) != std::string::npos) { size_t size = end - start; if (start + size > string.length()) break; token = string.substr(start, end - start); start = end + delimiter.length(); res.push_back(token); } res.emplace_back(string.substr(start)); return res; } std::string combineStrings(const std::vector &strings, const std::string &delimiter) { std::string result; for (const auto &string : strings) { result += string; result += delimiter; } return result.substr(0, result.length() - delimiter.length()); } std::string toEngineeringString(double value) { constexpr std::array Suffixes = { "a", "f", "p", "n", "u", "m", "", "k", "M", "G", "T", "P", "E" }; int8_t suffixIndex = 6; while (suffixIndex != 0 && suffixIndex != 12 && (value >= 1000 || value < 1) && value != 0) { if (value >= 1000) { value /= 1000; suffixIndex++; } else if (value < 1) { value *= 1000; suffixIndex--; } } return std::to_string(value).substr(0, 5) + Suffixes[suffixIndex]; } void runCommand(const std::string &command) { #if defined(OS_WINDOWS) auto result = system(hex::format("start {0}", command).c_str()); #elif defined(OS_MACOS) auto result = system(hex::format("open {0}", command).c_str()); #elif defined(OS_LINUX) auto result = system(hex::format("xdg-open {0}", command).c_str()); #endif hex::unused(result); } void openWebpage(std::string url) { if (url.find("://") == std::string::npos) url = "https://" + url; #if defined(OS_WINDOWS) ShellExecute(nullptr, "open", url.c_str(), nullptr, nullptr, SW_SHOWNORMAL); #elif defined(OS_MACOS) openWebpageMacos(url.c_str()); #elif defined(OS_LINUX) auto result = system(hex::format("xdg-open {0}", url).c_str()); hex::unused(result); #else #warning "Unknown OS, can't open webpages" #endif } std::string encodeByteString(const std::vector &bytes) { std::string result; for (u8 byte : bytes) { if (std::isprint(byte) && byte != '\\') result += char(byte); else { switch (byte) { case '\\': result += "\\"; break; case '\a': result += "\\a"; break; case '\b': result += "\\b"; break; case '\f': result += "\\f"; break; case '\n': result += "\\n"; break; case '\r': result += "\\r"; break; case '\t': result += "\\t"; break; case '\v': result += "\\v"; break; default: result += hex::format("\\x{:02X}", byte); break; } } } return result; } std::vector decodeByteString(const std::string &string) { u32 offset = 0; std::vector result; while (offset < string.length()) { auto c = [&] { return string[offset]; }; if (c() == '\\') { if ((offset + 2) >= string.length()) return {}; offset++; char escapeChar = c(); offset++; switch (escapeChar) { case 'a': result.push_back('\a'); break; case 'b': result.push_back('\b'); break; case 'f': result.push_back('\f'); break; case 'n': result.push_back('\n'); break; case 'r': result.push_back('\r'); break; case 't': result.push_back('\t'); break; case 'v': result.push_back('\v'); break; case '\\': result.push_back('\\'); break; case 'x': { u8 byte = 0x00; if ((offset + 1) >= string.length()) return {}; for (u8 i = 0; i < 2; i++) { byte <<= 4; if (c() >= '0' && c() <= '9') byte |= 0x00 + (c() - '0'); else if (c() >= 'A' && c() <= 'F') byte |= 0x0A + (c() - 'A'); else if (c() >= 'a' && c() <= 'f') byte |= 0x0A + (c() - 'a'); else return {}; offset++; } result.push_back(byte); } break; default: return {}; } } else { result.push_back(c()); offset++; } } return result; } float float16ToFloat32(u16 float16) { u32 sign = float16 >> 15; u32 exponent = (float16 >> 10) & 0x1F; u32 mantissa = float16 & 0x3FF; u32 result = 0x00; if (exponent == 0) { if (mantissa == 0) { // +- Zero result = sign << 31; } else { // Subnormal value exponent = 0x7F - 14; while ((mantissa & (1 << 10)) == 0) { exponent--; mantissa <<= 1; } mantissa &= 0x3FF; result = (sign << 31) | (exponent << 23) | (mantissa << 13); } } else if (exponent == 0x1F) { // +-Inf or +-NaN result = (sign << 31) | (0xFF << 23) | (mantissa << 13); } else { // Normal value result = (sign << 31) | ((exponent + (0x7F - 15)) << 23) | (mantissa << 13); } float floatResult = 0; std::memcpy(&floatResult, &result, sizeof(float)); return floatResult; } bool isProcessElevated() { #if defined(OS_WINDOWS) bool elevated = false; HANDLE token = INVALID_HANDLE_VALUE; if (::OpenProcessToken(::GetCurrentProcess(), TOKEN_QUERY, &token)) { TOKEN_ELEVATION elevation; DWORD elevationSize = sizeof(TOKEN_ELEVATION); if (::GetTokenInformation(token, TokenElevation, &elevation, sizeof(elevation), &elevationSize)) elevated = elevation.TokenIsElevated; } if (token != INVALID_HANDLE_VALUE) ::CloseHandle(token); return elevated; #elif defined(OS_LINUX) || defined(OS_MACOS) return getuid() == 0 || getuid() != geteuid(); #endif } std::optional getEnvironmentVariable(const std::string &env) { auto value = std::getenv(env.c_str()); if (value == nullptr) return std::nullopt; else return value; } }