// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2020 The Bitcoin Core developers // Copyright (c) 2016-2024 The Hush developers // Distributed under the GPLv3 software license, see the accompanying // file COPYING or https://www.gnu.org/licenses/gpl-3.0.en.html /** * Utilities for converting data from/to strings. */ #ifndef BITCOIN_UTIL_STRENCODINGS_H #define BITCOIN_UTIL_STRENCODINGS_H #include "attributes.h" #include "span.h" #include #include #include #include #define BEGIN(a) ((char*)&(a)) #define END(a) ((char*)&((&(a))[1])) #define UBEGIN(a) ((unsigned char*)&(a)) #define UEND(a) ((unsigned char*)&((&(a))[1])) #define ARRAYLEN(array) (sizeof(array)/sizeof((array)[0])) /** This is needed because the foreach macro can't get over the comma in pair */ #define PAIRTYPE(t1, t2) std::pair /** Used by SanitizeString() */ enum SafeChars { SAFE_CHARS_DEFAULT, //!< The full set of allowed chars SAFE_CHARS_UA_COMMENT, //!< BIP-0014 subset SAFE_CHARS_FILENAME, //!< Chars allowed in filenames SAFE_CHARS_URI, //!< Chars allowed in URIs (RFC 3986) }; std::string SanitizeFilename(const std::string& str); /** * Remove unsafe chars. Safe chars chosen to allow simple messages/URLs/email * addresses, but avoid anything even possibly remotely dangerous like & or > * @param[in] str The string to sanitize * @param[in] rule The set of safe chars to choose (default: least restrictive) * @return A new string without unsafe chars */ std::string SanitizeString(const std::string& str, int rule = SAFE_CHARS_DEFAULT); std::string HexInt(uint32_t val); uint32_t ParseHexToUInt32(const std::string& str); std::vector ParseHex(const char* psz); std::vector ParseHex(const std::string& str); signed char HexDigit(char c); /* Returns true if each character in str is a hex character, and has an even * number of hex digits.*/ bool IsHex(const std::string& str); /** * Return true if the string is a hex number, optionally prefixed with "0x" */ bool IsHexNumber(const std::string& str); std::vector DecodeBase64(const char* p, bool* pf_invalid = nullptr); std::string DecodeBase64(const std::string& str, bool* pf_invalid = nullptr); std::string EncodeBase64(Span input); std::string EncodeBase64(const unsigned char* pch, size_t len); std::string EncodeBase64(const std::string& str); std::vector DecodeBase32(const char* p, bool* pf_invalid = nullptr); std::string DecodeBase32(const std::string& str, bool* pf_invalid = nullptr); /** * Base32 encode. * If `pad` is true, then the output will be padded with '=' so that its length * is a multiple of 8. */ std::string EncodeBase32(Span input, bool pad = true); /** * Base32 encode. * If `pad` is true, then the output will be padded with '=' so that its length * is a multiple of 8. */ std::string EncodeBase32(const std::string& str, bool pad = true); void SplitHostPort(std::string in, int& portOut, std::string& hostOut); std::string i64tostr(int64_t n); std::string itostr(int n); int64_t atoi64(const char* psz); int64_t atoi64(const std::string& str); int atoi(const std::string& str); /** * Tests if the given character is a decimal digit. * @param[in] c character to test * @return true if the argument is a decimal digit; otherwise false. */ constexpr bool IsDigit(char c) { return c >= '0' && c <= '9'; } /** * Tests if the given character is a whitespace character. The whitespace characters * are: space, form-feed ('\f'), newline ('\n'), carriage return ('\r'), horizontal * tab ('\t'), and vertical tab ('\v'). * * This function is locale independent. Under the C locale this function gives the * same result as std::isspace. * * @param[in] c character to test * @return true if the argument is a whitespace character; otherwise false */ constexpr inline bool IsSpace(char c) noexcept { return c == ' ' || c == '\f' || c == '\n' || c == '\r' || c == '\t' || c == '\v'; } /** * Convert string to signed 32-bit integer with strict parse error feedback. * @returns true if the entire string could be parsed as valid integer, * false if not the entire string could be parsed or when overflow or underflow occurred. */ bool ParseInt32(const std::string& str, int32_t *out); /** * Convert string to signed 64-bit integer with strict parse error feedback. * @returns true if the entire string could be parsed as valid integer, * false if not the entire string could be parsed or when overflow or underflow occurred. */ bool ParseInt64(const std::string& str, int64_t *out); /** * Convert decimal string to unsigned 8-bit integer with strict parse error feedback. * @returns true if the entire string could be parsed as valid integer, * false if not the entire string could be parsed or when overflow or underflow occurred. */ bool ParseUInt8(const std::string& str, uint8_t *out); /** * Convert decimal string to unsigned 32-bit integer with strict parse error feedback. * @returns true if the entire string could be parsed as valid integer, * false if not the entire string could be parsed or when overflow or underflow occurred. */ bool ParseUInt32(const std::string& str, uint32_t *out); /** * Convert decimal string to unsigned 64-bit integer with strict parse error feedback. * @returns true if the entire string could be parsed as valid integer, * false if not the entire string could be parsed or when overflow or underflow occurred. */ bool ParseUInt64(const std::string& str, uint64_t *out); /** * Convert string to double with strict parse error feedback. * @returns true if the entire string could be parsed as valid double, * false if not the entire string could be parsed or when overflow or underflow occurred. */ bool ParseDouble(const std::string& str, double *out); template std::string HexStr(const T itbegin, const T itend, bool fSpaces=false) { std::string rv; static const char hexmap[16] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f' }; rv.reserve((itend-itbegin)*3); for(T it = itbegin; it < itend; ++it) { unsigned char val = (unsigned char)(*it); if(fSpaces && it != itbegin) rv.push_back(' '); rv.push_back(hexmap[val>>4]); rv.push_back(hexmap[val&15]); } return rv; } template inline std::string HexStr(const T& vch, bool fSpaces=false) { return HexStr(vch.begin(), vch.end(), fSpaces); } /** * Convert a span of bytes to a lower-case hexadecimal string. */ std::string HexStr(const Span s); inline std::string HexStr(const Span s) { return HexStr(MakeUCharSpan(s)); } /** * Format a paragraph of text to a fixed width, adding spaces for * indentation to any added line. */ std::string FormatParagraph(const std::string& in, size_t width = 79, size_t indent = 0); /** * Timing-attack-resistant comparison. * Takes time proportional to length * of first argument. */ template bool TimingResistantEqual(const T& a, const T& b) { if (b.size() == 0) return a.size() == 0; size_t accumulator = a.size() ^ b.size(); for (size_t i = 0; i < a.size(); i++) accumulator |= a[i] ^ b[i%b.size()]; return accumulator == 0; } /** Parse number as fixed point according to JSON number syntax. * See http://json.org/number.gif * @returns true on success, false on error. * @note The result must be in the range (-10^18,10^18), otherwise an overflow error will trigger. */ bool ParseFixedPoint(const std::string &val, int decimals, int64_t *amount_out); /** Convert from one power-of-2 number base to another. */ template bool ConvertBits(const O& outfn, I it, I end) { size_t acc = 0; size_t bits = 0; constexpr size_t maxv = (1 << tobits) - 1; constexpr size_t max_acc = (1 << (frombits + tobits - 1)) - 1; while (it != end) { acc = ((acc << frombits) | *it) & max_acc; bits += frombits; while (bits >= tobits) { bits -= tobits; outfn((acc >> bits) & maxv); } ++it; } if (pad) { if (bits) outfn((acc << (tobits - bits)) & maxv); } else if (bits >= frombits || ((acc << (tobits - bits)) & maxv)) { return false; } return true; } /** * Converts the given character to its lowercase equivalent. * This function is locale independent. It only converts uppercase * characters in the standard 7-bit ASCII range. * This is a feature, not a limitation. * * @param[in] c the character to convert to lowercase. * @return the lowercase equivalent of c; or the argument * if no conversion is possible. */ constexpr char ToLower(char c) { return (c >= 'A' && c <= 'Z' ? (c - 'A') + 'a' : c); } /** * Returns the lowercase equivalent of the given string. * This function is locale independent. It only converts uppercase * characters in the standard 7-bit ASCII range. * This is a feature, not a limitation. * * @param[in] str the string to convert to lowercase. * @returns lowercased equivalent of str */ std::string ToLower(const std::string& str); /** * Converts the given character to its uppercase equivalent. * This function is locale independent. It only converts lowercase * characters in the standard 7-bit ASCII range. * This is a feature, not a limitation. * * @param[in] c the character to convert to uppercase. * @return the uppercase equivalent of c; or the argument * if no conversion is possible. */ constexpr char ToUpper(char c) { return (c >= 'a' && c <= 'z' ? (c - 'a') + 'A' : c); } /** * Returns the uppercase equivalent of the given string. * This function is locale independent. It only converts lowercase * characters in the standard 7-bit ASCII range. * This is a feature, not a limitation. * * @param[in] str the string to convert to uppercase. * @returns UPPERCASED EQUIVALENT OF str */ std::string ToUpper(const std::string& str); /** * Capitalizes the first character of the given string. * This function is locale independent. It only converts lowercase * characters in the standard 7-bit ASCII range. * This is a feature, not a limitation. * * @param[in] str the string to capitalize. * @returns string with the first letter capitalized. */ std::string Capitalize(std::string str); #endif // BITCOIN_UTIL_STRENCODINGS_H