// ////////////////////////////////////////////////////////// // sha256.cpp // Copyright (c) 2014,2015,2021 Stephan Brumme. All rights reserved. // see http://create.stephan-brumme.com/disclaimer.html // #include "sha256.h" // big endian architectures need #define __BYTE_ORDER __BIG_ENDIAN #ifndef _MSC_VER #include #endif //#define SHA2_224_SEED_VECTOR /// same as reset() SHA256::SHA256() { reset(); } /// restart void SHA256::reset() { m_numBytes = 0; m_bufferSize = 0; // according to RFC 1321 // "These words were obtained by taking the first thirty-two bits of the // fractional parts of the square roots of the first eight prime numbers" m_hash[0] = 0x6a09e667; m_hash[1] = 0xbb67ae85; m_hash[2] = 0x3c6ef372; m_hash[3] = 0xa54ff53a; m_hash[4] = 0x510e527f; m_hash[5] = 0x9b05688c; m_hash[6] = 0x1f83d9ab; m_hash[7] = 0x5be0cd19; #ifdef SHA2_224_SEED_VECTOR // if you want SHA2-224 instead then use these seeds // and throw away the last 32 bits of getHash m_hash[0] = 0xc1059ed8; m_hash[1] = 0x367cd507; m_hash[2] = 0x3070dd17; m_hash[3] = 0xf70e5939; m_hash[4] = 0xffc00b31; m_hash[5] = 0x68581511; m_hash[6] = 0x64f98fa7; m_hash[7] = 0xbefa4fa4; #endif } namespace { inline uint32_t rotate(uint32_t a, uint32_t c) { return (a >> c) | (a << (32 - c)); } inline uint32_t swap(uint32_t x) { #if defined(__GNUC__) || defined(__clang__) return __builtin_bswap32(x); #endif #ifdef MSC_VER return _byteswap_ulong(x); #endif return (x >> 24) | ((x >> 8) & 0x0000FF00) | ((x << 8) & 0x00FF0000) | (x << 24); } // mix functions for processBlock() inline uint32_t f1(uint32_t e, uint32_t f, uint32_t g) { uint32_t term1 = rotate(e, 6) ^ rotate(e, 11) ^ rotate(e, 25); uint32_t term2 = (e & f) ^ (~e & g); //(g ^ (e & (f ^ g))) return term1 + term2; } inline uint32_t f2(uint32_t a, uint32_t b, uint32_t c) { uint32_t term1 = rotate(a, 2) ^ rotate(a, 13) ^ rotate(a, 22); uint32_t term2 = ((a | b) & c) | (a & b); //(a & (b ^ c)) ^ (b & c); return term1 + term2; } } /// process 64 bytes void SHA256::processBlock(const void* data) { // get last hash uint32_t a = m_hash[0]; uint32_t b = m_hash[1]; uint32_t c = m_hash[2]; uint32_t d = m_hash[3]; uint32_t e = m_hash[4]; uint32_t f = m_hash[5]; uint32_t g = m_hash[6]; uint32_t h = m_hash[7]; // data represented as 16x 32-bit words const uint32_t* input = (uint32_t*) data; // convert to big endian uint32_t words[64]; int i; for (i = 0; i < 16; i++) #if defined(__BYTE_ORDER) && (__BYTE_ORDER != 0) && (__BYTE_ORDER == __BIG_ENDIAN) words[i] = input[i]; #else words[i] = swap(input[i]); #endif uint32_t x,y; // temporaries // first round x = h + f1(e,f,g) + 0x428a2f98 + words[ 0]; y = f2(a,b,c); d += x; h = x + y; x = g + f1(d,e,f) + 0x71374491 + words[ 1]; y = f2(h,a,b); c += x; g = x + y; x = f + f1(c,d,e) + 0xb5c0fbcf + words[ 2]; y = f2(g,h,a); b += x; f = x + y; x = e + f1(b,c,d) + 0xe9b5dba5 + words[ 3]; y = f2(f,g,h); a += x; e = x + y; x = d + f1(a,b,c) + 0x3956c25b + words[ 4]; y = f2(e,f,g); h += x; d = x + y; x = c + f1(h,a,b) + 0x59f111f1 + words[ 5]; y = f2(d,e,f); g += x; c = x + y; x = b + f1(g,h,a) + 0x923f82a4 + words[ 6]; y = f2(c,d,e); f += x; b = x + y; x = a + f1(f,g,h) + 0xab1c5ed5 + words[ 7]; y = f2(b,c,d); e += x; a = x + y; // secound round x = h + f1(e,f,g) + 0xd807aa98 + words[ 8]; y = f2(a,b,c); d += x; h = x + y; x = g + f1(d,e,f) + 0x12835b01 + words[ 9]; y = f2(h,a,b); c += x; g = x + y; x = f + f1(c,d,e) + 0x243185be + words[10]; y = f2(g,h,a); b += x; f = x + y; x = e + f1(b,c,d) + 0x550c7dc3 + words[11]; y = f2(f,g,h); a += x; e = x + y; x = d + f1(a,b,c) + 0x72be5d74 + words[12]; y = f2(e,f,g); h += x; d = x + y; x = c + f1(h,a,b) + 0x80deb1fe + words[13]; y = f2(d,e,f); g += x; c = x + y; x = b + f1(g,h,a) + 0x9bdc06a7 + words[14]; y = f2(c,d,e); f += x; b = x + y; x = a + f1(f,g,h) + 0xc19bf174 + words[15]; y = f2(b,c,d); e += x; a = x + y; // extend to 24 words for (; i < 24; i++) words[i] = words[i-16] + (rotate(words[i-15], 7) ^ rotate(words[i-15], 18) ^ (words[i-15] >> 3)) + words[i-7] + (rotate(words[i- 2], 17) ^ rotate(words[i- 2], 19) ^ (words[i- 2] >> 10)); // third round x = h + f1(e,f,g) + 0xe49b69c1 + words[16]; y = f2(a,b,c); d += x; h = x + y; x = g + f1(d,e,f) + 0xefbe4786 + words[17]; y = f2(h,a,b); c += x; g = x + y; x = f + f1(c,d,e) + 0x0fc19dc6 + words[18]; y = f2(g,h,a); b += x; f = x + y; x = e + f1(b,c,d) + 0x240ca1cc + words[19]; y = f2(f,g,h); a += x; e = x + y; x = d + f1(a,b,c) + 0x2de92c6f + words[20]; y = f2(e,f,g); h += x; d = x + y; x = c + f1(h,a,b) + 0x4a7484aa + words[21]; y = f2(d,e,f); g += x; c = x + y; x = b + f1(g,h,a) + 0x5cb0a9dc + words[22]; y = f2(c,d,e); f += x; b = x + y; x = a + f1(f,g,h) + 0x76f988da + words[23]; y = f2(b,c,d); e += x; a = x + y; // extend to 32 words for (; i < 32; i++) words[i] = words[i-16] + (rotate(words[i-15], 7) ^ rotate(words[i-15], 18) ^ (words[i-15] >> 3)) + words[i-7] + (rotate(words[i- 2], 17) ^ rotate(words[i- 2], 19) ^ (words[i- 2] >> 10)); // fourth round x = h + f1(e,f,g) + 0x983e5152 + words[24]; y = f2(a,b,c); d += x; h = x + y; x = g + f1(d,e,f) + 0xa831c66d + words[25]; y = f2(h,a,b); c += x; g = x + y; x = f + f1(c,d,e) + 0xb00327c8 + words[26]; y = f2(g,h,a); b += x; f = x + y; x = e + f1(b,c,d) + 0xbf597fc7 + words[27]; y = f2(f,g,h); a += x; e = x + y; x = d + f1(a,b,c) + 0xc6e00bf3 + words[28]; y = f2(e,f,g); h += x; d = x + y; x = c + f1(h,a,b) + 0xd5a79147 + words[29]; y = f2(d,e,f); g += x; c = x + y; x = b + f1(g,h,a) + 0x06ca6351 + words[30]; y = f2(c,d,e); f += x; b = x + y; x = a + f1(f,g,h) + 0x14292967 + words[31]; y = f2(b,c,d); e += x; a = x + y; // extend to 40 words for (; i < 40; i++) words[i] = words[i-16] + (rotate(words[i-15], 7) ^ rotate(words[i-15], 18) ^ (words[i-15] >> 3)) + words[i-7] + (rotate(words[i- 2], 17) ^ rotate(words[i- 2], 19) ^ (words[i- 2] >> 10)); // fifth round x = h + f1(e,f,g) + 0x27b70a85 + words[32]; y = f2(a,b,c); d += x; h = x + y; x = g + f1(d,e,f) + 0x2e1b2138 + words[33]; y = f2(h,a,b); c += x; g = x + y; x = f + f1(c,d,e) + 0x4d2c6dfc + words[34]; y = f2(g,h,a); b += x; f = x + y; x = e + f1(b,c,d) + 0x53380d13 + words[35]; y = f2(f,g,h); a += x; e = x + y; x = d + f1(a,b,c) + 0x650a7354 + words[36]; y = f2(e,f,g); h += x; d = x + y; x = c + f1(h,a,b) + 0x766a0abb + words[37]; y = f2(d,e,f); g += x; c = x + y; x = b + f1(g,h,a) + 0x81c2c92e + words[38]; y = f2(c,d,e); f += x; b = x + y; x = a + f1(f,g,h) + 0x92722c85 + words[39]; y = f2(b,c,d); e += x; a = x + y; // extend to 48 words for (; i < 48; i++) words[i] = words[i-16] + (rotate(words[i-15], 7) ^ rotate(words[i-15], 18) ^ (words[i-15] >> 3)) + words[i-7] + (rotate(words[i- 2], 17) ^ rotate(words[i- 2], 19) ^ (words[i- 2] >> 10)); // sixth round x = h + f1(e,f,g) + 0xa2bfe8a1 + words[40]; y = f2(a,b,c); d += x; h = x + y; x = g + f1(d,e,f) + 0xa81a664b + words[41]; y = f2(h,a,b); c += x; g = x + y; x = f + f1(c,d,e) + 0xc24b8b70 + words[42]; y = f2(g,h,a); b += x; f = x + y; x = e + f1(b,c,d) + 0xc76c51a3 + words[43]; y = f2(f,g,h); a += x; e = x + y; x = d + f1(a,b,c) + 0xd192e819 + words[44]; y = f2(e,f,g); h += x; d = x + y; x = c + f1(h,a,b) + 0xd6990624 + words[45]; y = f2(d,e,f); g += x; c = x + y; x = b + f1(g,h,a) + 0xf40e3585 + words[46]; y = f2(c,d,e); f += x; b = x + y; x = a + f1(f,g,h) + 0x106aa070 + words[47]; y = f2(b,c,d); e += x; a = x + y; // extend to 56 words for (; i < 56; i++) words[i] = words[i-16] + (rotate(words[i-15], 7) ^ rotate(words[i-15], 18) ^ (words[i-15] >> 3)) + words[i-7] + (rotate(words[i- 2], 17) ^ rotate(words[i- 2], 19) ^ (words[i- 2] >> 10)); // seventh round x = h + f1(e,f,g) + 0x19a4c116 + words[48]; y = f2(a,b,c); d += x; h = x + y; x = g + f1(d,e,f) + 0x1e376c08 + words[49]; y = f2(h,a,b); c += x; g = x + y; x = f + f1(c,d,e) + 0x2748774c + words[50]; y = f2(g,h,a); b += x; f = x + y; x = e + f1(b,c,d) + 0x34b0bcb5 + words[51]; y = f2(f,g,h); a += x; e = x + y; x = d + f1(a,b,c) + 0x391c0cb3 + words[52]; y = f2(e,f,g); h += x; d = x + y; x = c + f1(h,a,b) + 0x4ed8aa4a + words[53]; y = f2(d,e,f); g += x; c = x + y; x = b + f1(g,h,a) + 0x5b9cca4f + words[54]; y = f2(c,d,e); f += x; b = x + y; x = a + f1(f,g,h) + 0x682e6ff3 + words[55]; y = f2(b,c,d); e += x; a = x + y; // extend to 64 words for (; i < 64; i++) words[i] = words[i-16] + (rotate(words[i-15], 7) ^ rotate(words[i-15], 18) ^ (words[i-15] >> 3)) + words[i-7] + (rotate(words[i- 2], 17) ^ rotate(words[i- 2], 19) ^ (words[i- 2] >> 10)); // eigth round x = h + f1(e,f,g) + 0x748f82ee + words[56]; y = f2(a,b,c); d += x; h = x + y; x = g + f1(d,e,f) + 0x78a5636f + words[57]; y = f2(h,a,b); c += x; g = x + y; x = f + f1(c,d,e) + 0x84c87814 + words[58]; y = f2(g,h,a); b += x; f = x + y; x = e + f1(b,c,d) + 0x8cc70208 + words[59]; y = f2(f,g,h); a += x; e = x + y; x = d + f1(a,b,c) + 0x90befffa + words[60]; y = f2(e,f,g); h += x; d = x + y; x = c + f1(h,a,b) + 0xa4506ceb + words[61]; y = f2(d,e,f); g += x; c = x + y; x = b + f1(g,h,a) + 0xbef9a3f7 + words[62]; y = f2(c,d,e); f += x; b = x + y; x = a + f1(f,g,h) + 0xc67178f2 + words[63]; y = f2(b,c,d); e += x; a = x + y; // update hash m_hash[0] += a; m_hash[1] += b; m_hash[2] += c; m_hash[3] += d; m_hash[4] += e; m_hash[5] += f; m_hash[6] += g; m_hash[7] += h; } /// add arbitrary number of bytes void SHA256::add(const void* data, size_t numBytes) { const uint8_t* current = (const uint8_t*) data; if (m_bufferSize > 0) { while (numBytes > 0 && m_bufferSize < BlockSize) { m_buffer[m_bufferSize++] = *current++; numBytes--; } } // full buffer if (m_bufferSize == BlockSize) { processBlock(m_buffer); m_numBytes += BlockSize; m_bufferSize = 0; } // no more data ? if (numBytes == 0) return; // process full blocks while (numBytes >= BlockSize) { processBlock(current); current += BlockSize; m_numBytes += BlockSize; numBytes -= BlockSize; } // keep remaining bytes in buffer while (numBytes > 0) { m_buffer[m_bufferSize++] = *current++; numBytes--; } } /// process final block, less than 64 bytes void SHA256::processBuffer() { // the input bytes are considered as bits strings, where the first bit is the most significant bit of the byte // - append "1" bit to message // - append "0" bits until message length in bit mod 512 is 448 // - append length as 64 bit integer // number of bits size_t paddedLength = m_bufferSize * 8; // plus one bit set to 1 (always appended) paddedLength++; // number of bits must be (numBits % 512) = 448 size_t lower11Bits = paddedLength & 511; if (lower11Bits <= 448) paddedLength += 448 - lower11Bits; else paddedLength += 512 + 448 - lower11Bits; // convert from bits to bytes paddedLength /= 8; // only needed if additional data flows over into a second block unsigned char extra[BlockSize]; // append a "1" bit, 128 => binary 10000000 if (m_bufferSize < BlockSize) m_buffer[m_bufferSize] = 128; else extra[0] = 128; size_t i; for (i = m_bufferSize + 1; i < BlockSize; i++) m_buffer[i] = 0; for (; i < paddedLength; i++) extra[i - BlockSize] = 0; // add message length in bits as 64 bit number uint64_t msgBits = 8 * (m_numBytes + m_bufferSize); // find right position unsigned char* addLength; if (paddedLength < BlockSize) addLength = m_buffer + paddedLength; else addLength = extra + paddedLength - BlockSize; // must be big endian *addLength++ = (unsigned char)((msgBits >> 56) & 0xFF); *addLength++ = (unsigned char)((msgBits >> 48) & 0xFF); *addLength++ = (unsigned char)((msgBits >> 40) & 0xFF); *addLength++ = (unsigned char)((msgBits >> 32) & 0xFF); *addLength++ = (unsigned char)((msgBits >> 24) & 0xFF); *addLength++ = (unsigned char)((msgBits >> 16) & 0xFF); *addLength++ = (unsigned char)((msgBits >> 8) & 0xFF); *addLength = (unsigned char)( msgBits & 0xFF); // process blocks processBlock(m_buffer); // flowed over into a second block ? if (paddedLength > BlockSize) processBlock(extra); } /// return latest hash as 64 hex characters std::string SHA256::getHash() { // compute hash (as raw bytes) unsigned char rawHash[HashBytes]; getHash(rawHash); // convert to hex string std::string result; result.reserve(2 * HashBytes); for (int i = 0; i < HashBytes; i++) { static const char dec2hex[16+1] = "0123456789abcdef"; result += dec2hex[(rawHash[i] >> 4) & 15]; result += dec2hex[ rawHash[i] & 15]; } return result; } /// return latest hash as bytes void SHA256::getHash(unsigned char buffer[SHA256::HashBytes]) { // save old hash if buffer is partially filled uint32_t oldHash[HashValues]; for (int i = 0; i < HashValues; i++) oldHash[i] = m_hash[i]; // process remaining bytes processBuffer(); unsigned char* current = buffer; for (int i = 0; i < HashValues; i++) { *current++ = (m_hash[i] >> 24) & 0xFF; *current++ = (m_hash[i] >> 16) & 0xFF; *current++ = (m_hash[i] >> 8) & 0xFF; *current++ = m_hash[i] & 0xFF; // restore old hash m_hash[i] = oldHash[i]; } } /// compute SHA256 of a memory block std::string SHA256::operator()(const void* data, size_t numBytes) { reset(); add(data, numBytes); return getHash(); } /// compute SHA256 of a string, excluding final zero std::string SHA256::operator()(const std::string& text) { reset(); add(text.c_str(), text.size()); return getHash(); }