/* * Copyright (c) 2008-2022 Jonathan Schleifer <js@nil.im> * * All rights reserved. * * This file is part of ObjFW. It may be distributed under the terms of the * Q Public License 1.0, which can be found in the file LICENSE.QPL included in * the packaging of this file. * * Alternatively, it may be distributed under the terms of the GNU General * Public License, either version 2 or 3, which can be found in the file * LICENSE.GPLv2 or LICENSE.GPLv3 respectively included in the packaging of this * file. */ #include "config.h" #include <string.h> #import "OFSHA1Hash.h" #import "OFSecureData.h" #import "OFHashAlreadyCalculatedException.h" #import "OFOutOfRangeException.h" static const size_t digestSize = 20; static const size_t blockSize = 64; OF_DIRECT_MEMBERS @interface OFSHA1Hash () - (void)of_resetState; @end #define F(a, b, c, d) ((d) ^ ((b) & ((c) ^ (d)))) #define G(a, b, c, d) ((b) ^ (c) ^ (d)) #define H(a, b, c, d) (((b) & (c)) | ((d) & ((b) | (c)))) #define I(a, b, c, d) ((b) ^ (c) ^ (d)) static OF_INLINE void byteSwapVectorIfLE(uint32_t *vector, uint_fast8_t length) { #ifndef OF_BIG_ENDIAN for (uint_fast8_t i = 0; i < length; i++) vector[i] = OFByteSwap32(vector[i]); #endif } static void processBlock(uint32_t *state, uint32_t *buffer) { uint32_t new[5]; uint_fast8_t i; new[0] = state[0]; new[1] = state[1]; new[2] = state[2]; new[3] = state[3]; new[4] = state[4]; byteSwapVectorIfLE(buffer, 16); for (i = 16; i < 80; i++) { uint32_t tmp = buffer[i - 3] ^ buffer[i - 8] ^ buffer[i - 14] ^ buffer[i - 16]; buffer[i] = OFRotateLeft(tmp, 1); } #define LOOP_BODY(f, k) \ { \ uint32_t tmp = OFRotateLeft(new[0], 5) + \ f(new[0], new[1], new[2], new[3]) + \ new[4] + k + buffer[i]; \ new[4] = new[3]; \ new[3] = new[2]; \ new[2] = OFRotateLeft(new[1], 30); \ new[1] = new[0]; \ new[0] = tmp; \ } for (i = 0; i < 20; i++) LOOP_BODY(F, 0x5A827999) for (; i < 40; i++) LOOP_BODY(G, 0x6ED9EBA1) for (; i < 60; i++) LOOP_BODY(H, 0x8F1BBCDC) for (; i < 80; i++) LOOP_BODY(I, 0xCA62C1D6) #undef LOOP_BODY state[0] += new[0]; state[1] += new[1]; state[2] += new[2]; state[3] += new[3]; state[4] += new[4]; } @implementation OFSHA1Hash @synthesize calculated = _calculated; @synthesize allowsSwappableMemory = _allowsSwappableMemory; + (size_t)digestSize { return digestSize; } + (size_t)blockSize { return blockSize; } + (instancetype)hashWithAllowsSwappableMemory: (bool)allowsSwappableMemory { return [[[self alloc] initWithAllowsSwappableMemory: allowsSwappableMemory] autorelease]; } - (instancetype)initWithAllowsSwappableMemory: (bool)allowsSwappableMemory { self = [super init]; @try { _iVarsData = [[OFSecureData alloc] initWithCount: sizeof(*_iVars) allowsSwappableMemory: allowsSwappableMemory]; _iVars = _iVarsData.mutableItems; _allowsSwappableMemory = allowsSwappableMemory; [self of_resetState]; } @catch (id e) { [self release]; @throw e; } return self; } - (instancetype)init { OF_INVALID_INIT_METHOD } - (instancetype)of_init { return [super init]; } - (void)dealloc { [_iVarsData release]; [super dealloc]; } - (size_t)digestSize { return digestSize; } - (size_t)blockSize { return blockSize; } - (id)copy { OFSHA1Hash *copy = [[OFSHA1Hash alloc] of_init]; copy->_iVarsData = [_iVarsData copy]; copy->_iVars = copy->_iVarsData.mutableItems; copy->_allowsSwappableMemory = _allowsSwappableMemory; copy->_calculated = _calculated; return copy; } - (void)of_resetState { _iVars->state[0] = 0x67452301; _iVars->state[1] = 0xEFCDAB89; _iVars->state[2] = 0x98BADCFE; _iVars->state[3] = 0x10325476; _iVars->state[4] = 0xC3D2E1F0; } - (void)updateWithBuffer: (const void *)buffer_ length: (size_t)length { const unsigned char *buffer = buffer_; if (_calculated) @throw [OFHashAlreadyCalculatedException exceptionWithObject: self]; if (length > SIZE_MAX / 8) @throw [OFOutOfRangeException exception]; _iVars->bits += (length * 8); while (length > 0) { size_t min = 64 - _iVars->bufferLength; if (min > length) min = length; memcpy(_iVars->buffer.bytes + _iVars->bufferLength, buffer, min); _iVars->bufferLength += min; buffer += min; length -= min; if (_iVars->bufferLength == 64) { processBlock(_iVars->state, _iVars->buffer.words); _iVars->bufferLength = 0; } } } - (const unsigned char *)digest { if (_calculated) return (const unsigned char *)_iVars->state; _iVars->buffer.bytes[_iVars->bufferLength] = 0x80; OFZeroMemory(_iVars->buffer.bytes + _iVars->bufferLength + 1, 64 - _iVars->bufferLength - 1); if (_iVars->bufferLength >= 56) { processBlock(_iVars->state, _iVars->buffer.words); OFZeroMemory(_iVars->buffer.bytes, 64); } _iVars->buffer.words[14] = OFToBigEndian32((uint32_t)(_iVars->bits >> 32)); _iVars->buffer.words[15] = OFToBigEndian32((uint32_t)(_iVars->bits & 0xFFFFFFFF)); processBlock(_iVars->state, _iVars->buffer.words); OFZeroMemory(&_iVars->buffer, sizeof(_iVars->buffer)); byteSwapVectorIfLE(_iVars->state, 5); _calculated = true; return (const unsigned char *)_iVars->state; } - (void)reset { [self of_resetState]; _iVars->bits = 0; OFZeroMemory(&_iVars->buffer, sizeof(_iVars->buffer)); _iVars->bufferLength = 0; _calculated = false; } @end