/* macros.h * */ /* nettle, low-level cryptographics library * * Copyright (C) 2001, 2010 Niels Möller * * The nettle library is free software; you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as published by * the Free Software Foundation; either version 2.1 of the License, or (at your * option) any later version. * * The nettle library is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public * License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with the nettle library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, * MA 02111-1307, USA. */ #ifndef NETTLE_MACROS_H_INCLUDED #define NETTLE_MACROS_H_INCLUDED /* Reads a 64-bit integer, in network, big-endian, byte order */ #define READ_UINT64(p) \ ( (((uint64_t) (p)[0]) << 56) \ | (((uint64_t) (p)[1]) << 48) \ | (((uint64_t) (p)[2]) << 40) \ | (((uint64_t) (p)[3]) << 32) \ | (((uint64_t) (p)[4]) << 24) \ | (((uint64_t) (p)[5]) << 16) \ | (((uint64_t) (p)[6]) << 8) \ | ((uint64_t) (p)[7])) #define WRITE_UINT64(p, i) \ do { \ (p)[0] = ((i) >> 56) & 0xff; \ (p)[1] = ((i) >> 48) & 0xff; \ (p)[2] = ((i) >> 40) & 0xff; \ (p)[3] = ((i) >> 32) & 0xff; \ (p)[4] = ((i) >> 24) & 0xff; \ (p)[5] = ((i) >> 16) & 0xff; \ (p)[6] = ((i) >> 8) & 0xff; \ (p)[7] = (i) & 0xff; \ } while(0) /* Reads a 32-bit integer, in network, big-endian, byte order */ #define READ_UINT32(p) \ ( (((uint32_t) (p)[0]) << 24) \ | (((uint32_t) (p)[1]) << 16) \ | (((uint32_t) (p)[2]) << 8) \ | ((uint32_t) (p)[3])) #define WRITE_UINT32(p, i) \ do { \ (p)[0] = ((i) >> 24) & 0xff; \ (p)[1] = ((i) >> 16) & 0xff; \ (p)[2] = ((i) >> 8) & 0xff; \ (p)[3] = (i) & 0xff; \ } while(0) /* Analogous macros, for 24 and 16 bit numbers */ #define READ_UINT24(p) \ ( (((uint32_t) (p)[0]) << 16) \ | (((uint32_t) (p)[1]) << 8) \ | ((uint32_t) (p)[2])) #define WRITE_UINT24(p, i) \ do { \ (p)[0] = ((i) >> 16) & 0xff; \ (p)[1] = ((i) >> 8) & 0xff; \ (p)[2] = (i) & 0xff; \ } while(0) #define READ_UINT16(p) \ ( (((uint32_t) (p)[0]) << 8) \ | ((uint32_t) (p)[1])) #define WRITE_UINT16(p, i) \ do { \ (p)[0] = ((i) >> 8) & 0xff; \ (p)[1] = (i) & 0xff; \ } while(0) /* And the other, little-endian, byteorder */ #define LE_READ_UINT32(p) \ ( (((uint32_t) (p)[3]) << 24) \ | (((uint32_t) (p)[2]) << 16) \ | (((uint32_t) (p)[1]) << 8) \ | ((uint32_t) (p)[0])) #define LE_WRITE_UINT32(p, i) \ do { \ (p)[3] = ((i) >> 24) & 0xff; \ (p)[2] = ((i) >> 16) & 0xff; \ (p)[1] = ((i) >> 8) & 0xff; \ (p)[0] = (i) & 0xff; \ } while(0) /* Analogous macros, for 16 bit numbers */ #define LE_READ_UINT16(p) \ ( (((uint32_t) (p)[1]) << 8) \ | ((uint32_t) (p)[0])) #define LE_WRITE_UINT16(p, i) \ do { \ (p)[1] = ((i) >> 8) & 0xff; \ (p)[0] = (i) & 0xff; \ } while(0) /* Macro to make it easier to loop over several blocks. */ #define FOR_BLOCKS(length, dst, src, blocksize) \ assert( !((length) % (blocksize))); \ for (; (length); ((length) -= (blocksize), \ (dst) += (blocksize), \ (src) += (blocksize)) ) /* Requires that size >= 2 */ #define INCREMENT(size, ctr) \ do { \ unsigned increment_i = (size) - 1; \ if (++(ctr)[increment_i] == 0) \ { \ while (++(ctr)[--increment_i] == 0 \ && increment_i > 0) \ ; \ } \ } while (0) /* Helper macro for Merkle-Damgård hash functions. Assumes the context structs includes the following fields: xxx count_low, count_high; // Two word block count uint8_t block[...]; // Buffer holding one block unsigned int index; // Index into block */ /* FIXME: Should probably switch to using uint64_t for the count, but due to alignment and byte order that may be an ABI change. */ #define MD_INCR(ctx) ((ctx)->count_high += !++(ctx)->count_low) /* Takes the compression function f as argument. NOTE: also clobbers length and data. */ #define MD_UPDATE(ctx, length, data, f, incr) \ do { \ if ((ctx)->index) \ { \ /* Try to fill partial block */ \ unsigned __md_left = sizeof((ctx)->block) - (ctx)->index; \ if ((length) < __md_left) \ { \ memcpy((ctx)->block + (ctx)->index, (data), (length)); \ (ctx)->index += (length); \ goto __md_done; /* Finished */ \ } \ else \ { \ memcpy((ctx)->block + (ctx)->index, (data), __md_left); \ \ f((ctx), (ctx)->block); \ (incr); \ \ (data) += __md_left; \ (length) -= __md_left; \ } \ } \ while ((length) >= sizeof((ctx)->block)) \ { \ f((ctx), (data)); \ (incr); \ \ (data) += sizeof((ctx)->block); \ (length) -= sizeof((ctx)->block); \ } \ memcpy ((ctx)->block, (data), (length)); \ (ctx)->index = (length); \ __md_done: \ ; \ } while (0) /* Pads the block to a block boundary with the bit pattern 1 0*, leaving size octets for the length field at the end. If needed, compresses the block and starts a new one. */ #define MD_PAD(ctx, size, f) \ do { \ unsigned __md_i; \ __md_i = (ctx)->index; \ \ /* Set the first char of padding to 0x80. This is safe since there \ is always at least one byte free */ \ \ assert(__md_i < sizeof((ctx)->block)); \ (ctx)->block[__md_i++] = 0x80; \ \ if (__md_i > (sizeof((ctx)->block) - 2*sizeof((ctx)->count_low))) \ { /* No room for length in this block. Process it and \ pad with another one */ \ memset((ctx)->block + __md_i, 0, sizeof((ctx)->block) - __md_i); \ \ f((ctx), (ctx)->block); \ __md_i = 0; \ } \ memset((ctx)->block + __md_i, 0, \ sizeof((ctx)->block) - (size) - __md_i); \ \ } while (0) #endif /* NETTLE_MACROS_H_INCLUDED */