/* * This is an OpenSSL-compatible implementation of the RSA Data Security, Inc. * MD4 Message-Digest Algorithm (RFC 1320). * * Homepage: * http://openwall.info/wiki/people/solar/software/public-domain-source-code/md4 * * Author: * Alexander Peslyak, better known as Solar Designer * * This software was written by Alexander Peslyak in 2001. No copyright is * claimed, and the software is hereby placed in the public domain. * In case this attempt to disclaim copyright and place the software in the * public domain is deemed null and void, then the software is * Copyright (c) 2001 Alexander Peslyak and it is hereby released to the * general public under the following terms: * * Redistribution and use in source and binary forms, with or without * modification, are permitted. * * There's ABSOLUTELY NO WARRANTY, express or implied. * * (This is a heavily cut-down "BSD license".) * * This differs from Colin Plumb's older public domain implementation in that * no exactly 32-bit integer data type is required (any 32-bit or wider * unsigned integer data type will do), there's no compile-time endianness * configuration, and the function prototypes match OpenSSL's. No code from * Colin Plumb's implementation has been reused; this comment merely compares * the properties of the two independent implementations. * * The primary goals of this implementation are portability and ease of use. * It is meant to be fast, but not as fast as possible. Some known * optimizations are not included to reduce source code size and avoid * compile-time configuration. * * Modified for hash-wasm by Dani BirĂ³ */ #define WITH_BUFFER #include "hash-wasm.h" struct MD4_CTX { uint32_t lo, hi; uint32_t a, b, c, d; uint8_t buffer[64]; uint32_t block[16]; }; struct MD4_CTX sctx; struct MD4_CTX *ctx = &sctx; /* * The basic MD4 functions. * * F and G are optimized compared to their RFC 1320 definitions, with the * optimization for F borrowed from Colin Plumb's MD5 implementation. */ #define F(x, y, z) ((z) ^ ((x) & ((y) ^ (z)))) #define G(x, y, z) (((x) & ((y) | (z))) | ((y) & (z))) #define H(x, y, z) ((x) ^ (y) ^ (z)) /* * The MD4 transformation for all three rounds. */ #define STEP(f, a, b, c, d, x, s) \ (a) += f((b), (c), (d)) + (x); \ (a) = (((a) << (s)) | (((a) & 0xffffffff) >> (32 - (s)))); /* * SET reads 4 input bytes in little-endian byte order and stores them in a * properly aligned word in host byte order. * * The check for little-endian architectures that tolerate unaligned memory * accesses is just an optimization. Nothing will break if it fails to detect * a suitable architecture. * * Unfortunately, this optimization may be a C strict aliasing rules violation * if the caller's data buffer has effective type that cannot be aliased by * uint32_t. In practice, this problem may occur if these MD4 routines are * inlined into a calling function, or with future and dangerously advanced * link-time optimizations. For the time being, keeping these MD4 routines in * their own translation unit avoids the problem. */ #define SET(n) (*(uint32_t *)&ptr[(n)*4]) #define GET(n) SET(n) /* * This processes one or more 64-byte data blocks, but does NOT update the bit * counters. There are no alignment requirements. */ static const void *body(const void *data, uint32_t size) { const uint8_t *ptr; uint32_t a, b, c, d; uint32_t saved_a, saved_b, saved_c, saved_d; const uint32_t ac1 = 0x5a827999, ac2 = 0x6ed9eba1; ptr = (const uint8_t *)data; a = ctx->a; b = ctx->b; c = ctx->c; d = ctx->d; do { saved_a = a; saved_b = b; saved_c = c; saved_d = d; /* Round 1 */ STEP(F, a, b, c, d, SET(0), 3) STEP(F, d, a, b, c, SET(1), 7) STEP(F, c, d, a, b, SET(2), 11) STEP(F, b, c, d, a, SET(3), 19) STEP(F, a, b, c, d, SET(4), 3) STEP(F, d, a, b, c, SET(5), 7) STEP(F, c, d, a, b, SET(6), 11) STEP(F, b, c, d, a, SET(7), 19) STEP(F, a, b, c, d, SET(8), 3) STEP(F, d, a, b, c, SET(9), 7) STEP(F, c, d, a, b, SET(10), 11) STEP(F, b, c, d, a, SET(11), 19) STEP(F, a, b, c, d, SET(12), 3) STEP(F, d, a, b, c, SET(13), 7) STEP(F, c, d, a, b, SET(14), 11) STEP(F, b, c, d, a, SET(15), 19) /* Round 2 */ STEP(G, a, b, c, d, GET(0) + ac1, 3) STEP(G, d, a, b, c, GET(4) + ac1, 5) STEP(G, c, d, a, b, GET(8) + ac1, 9) STEP(G, b, c, d, a, GET(12) + ac1, 13) STEP(G, a, b, c, d, GET(1) + ac1, 3) STEP(G, d, a, b, c, GET(5) + ac1, 5) STEP(G, c, d, a, b, GET(9) + ac1, 9) STEP(G, b, c, d, a, GET(13) + ac1, 13) STEP(G, a, b, c, d, GET(2) + ac1, 3) STEP(G, d, a, b, c, GET(6) + ac1, 5) STEP(G, c, d, a, b, GET(10) + ac1, 9) STEP(G, b, c, d, a, GET(14) + ac1, 13) STEP(G, a, b, c, d, GET(3) + ac1, 3) STEP(G, d, a, b, c, GET(7) + ac1, 5) STEP(G, c, d, a, b, GET(11) + ac1, 9) STEP(G, b, c, d, a, GET(15) + ac1, 13) /* Round 3 */ STEP(H, a, b, c, d, GET(0) + ac2, 3) STEP(H, d, a, b, c, GET(8) + ac2, 9) STEP(H, c, d, a, b, GET(4) + ac2, 11) STEP(H, b, c, d, a, GET(12) + ac2, 15) STEP(H, a, b, c, d, GET(2) + ac2, 3) STEP(H, d, a, b, c, GET(10) + ac2, 9) STEP(H, c, d, a, b, GET(6) + ac2, 11) STEP(H, b, c, d, a, GET(14) + ac2, 15) STEP(H, a, b, c, d, GET(1) + ac2, 3) STEP(H, d, a, b, c, GET(9) + ac2, 9) STEP(H, c, d, a, b, GET(5) + ac2, 11) STEP(H, b, c, d, a, GET(13) + ac2, 15) STEP(H, a, b, c, d, GET(3) + ac2, 3) STEP(H, d, a, b, c, GET(11) + ac2, 9) STEP(H, c, d, a, b, GET(7) + ac2, 11) STEP(H, b, c, d, a, GET(15) + ac2, 15) a += saved_a; b += saved_b; c += saved_c; d += saved_d; ptr += 64; } while (size -= 64); ctx->a = a; ctx->b = b; ctx->c = c; ctx->d = d; return ptr; } WASM_EXPORT void Hash_Init() { ctx->a = 0x67452301; ctx->b = 0xefcdab89; ctx->c = 0x98badcfe; ctx->d = 0x10325476; ctx->lo = 0; ctx->hi = 0; } WASM_EXPORT void Hash_Update(uint32_t size) { const uint8_t *data = main_buffer; uint32_t saved_lo; uint32_t used, available; saved_lo = ctx->lo; if ((ctx->lo = (saved_lo + size) & 0x1fffffff) < saved_lo) { ctx->hi++; } ctx->hi += size >> 29; used = saved_lo & 0x3f; if (used) { available = 64 - used; if (size < available) { for (uint32_t i = 0; i < size; i++) { ctx->buffer[used + i] = data[i]; } return; } for (uint32_t i = 0; i < available; i++) { ctx->buffer[used + i] = data[i]; } data = (const uint8_t *)data + available; size -= available; body(ctx->buffer, 64); } if (size >= 64) { data = body(data, size & ~(uint32_t)0x3f); size &= 0x3f; } for (uint32_t i = 0; i < size; i++) { ctx->buffer[i] = data[i]; } } #define OUT(dst, src) \ (dst)[0] = (uint8_t)(src); \ (dst)[1] = (uint8_t)((src) >> 8); \ (dst)[2] = (uint8_t)((src) >> 16); \ (dst)[3] = (uint8_t)((src) >> 24); WASM_EXPORT void Hash_Final() { uint8_t *result = main_buffer; uint32_t used, available; used = ctx->lo & 0x3f; ctx->buffer[used++] = 0x80; available = 64 - used; if (available < 8) { for (int i = 0; i < available; i++) { ctx->buffer[used + i] = 0; } body(ctx->buffer, 64); used = 0; available = 64; } for (int i = available - 9; i >= 0; i--) { ctx->buffer[used + i] = 0; } ctx->lo <<= 3; OUT(&ctx->buffer[56], ctx->lo) OUT(&ctx->buffer[60], ctx->hi) body(ctx->buffer, 64); OUT(&result[0], ctx->a) OUT(&result[4], ctx->b) OUT(&result[8], ctx->c) OUT(&result[12], ctx->d) } WASM_EXPORT const uint32_t STATE_SIZE = sizeof(*ctx); WASM_EXPORT uint8_t* Hash_GetState() { return (uint8_t*) ctx; } WASM_EXPORT void Hash_Calculate(uint32_t length) { Hash_Init(); Hash_Update(length); Hash_Final(); }