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548 lines
19 KiB
C
548 lines
19 KiB
C
/*
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---------------------------------------------------------------------------
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Copyright (c) 1998-2010, Brian Gladman, Worcester, UK. All rights reserved.
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The redistribution and use of this software (with or without changes)
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is allowed without the payment of fees or royalties provided that:
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source code distributions include the above copyright notice, this
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list of conditions and the following disclaimer;
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binary distributions include the above copyright notice, this list
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of conditions and the following disclaimer in their documentation.
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This software is provided 'as is' with no explicit or implied warranties
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in respect of its operation, including, but not limited to, correctness
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and fitness for purpose.
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---------------------------------------------------------------------------
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Issue Date: 30/03/2011
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My thanks to:
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Colin Sinclair for finding an error and suggesting a number of
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improvements to this code.
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John Viega and David McGrew for their support in the development
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of this code and to David for testing it on a big-endIAN system.
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Mark Rodenkirch and Jason Papadopoulos for their help in finding
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a bug in the fast buffer operations on big endian systems.
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*/
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#include "aesgcm.h"
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#include "mode_hdr.h"
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/* This GCM implementation needs a Galois Field multiplier for GF(2^128).
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which operates on field elements using a polynomial field representation
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x^127 + x^126 + ... + x^2 + x + 1 using the bits in a bit sequence that
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will be numbered by the power of x that they represent. GCM uses the
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polynomial x^128 + x^7 + x^2 + x + 1 as its basis for representation.
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The obvious way of representing this in a computer system is to map GF
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'x' to the binary integer '2' - but this was way too obvious for any
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cryptographer to adopt!
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Here bytes are numbered in memory order and bits within bytes according
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to their integer numeric significance. The term 'little endian' is then
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used to describe mappings in which numeric (power of 2) or field (power
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of x) significance increase with increasing bit or byte numbers with
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'big endian' being used to describe the inverse situation.
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GCM uses little endian byte ordering and big endian bit ordering, a
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representation that will be described as LB. Hence the low end of the
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field polynomial is in byte[0], which has the value 0xe1 rather than
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0x87 in the more obvious mappings.
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The related field multipler can use this mapping but if you want to
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use an alternative (e.g hardware) multiplier that uses a different
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polynomial field representation, you can do so by changing the form
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used for the field elements when this alternative multiplier is used.
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If GF_REPRESENTATION is defined as one of:
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REVERSE_BITS // change to LL
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REVERSE_BYTES | REVERSE_BITS // change to BL
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REVERSE_NONE // no change
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REVERSE_BYTES // change to BB
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then an appropriate change of representation will occur before and
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after calls to your revised field multiplier. To use this you need
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to add gf_convert.c to your application.
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*/
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#if defined(__cplusplus)
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extern "C"
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{
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#endif
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#if 1
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# undef GF_REPRESENTATION
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#elif 0
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# define GF_REPRESENTATION REVERSE_BITS
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#elif 0
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# define GF_REPRESENTATION REVERSE_BYTES | REVERSE_BITS
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#elif 0
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# define GF_REPRESENTATION REVERSE_NONE
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#elif 0
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# define GF_REPRESENTATION REVERSE_BITS
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#endif
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#define BLOCK_SIZE GCM_BLOCK_SIZE /* block length */
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#define BLK_ADR_MASK (BLOCK_SIZE - 1) /* mask for 'in block' address */
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#define CTR_POS 12
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#define inc_ctr(x) \
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{ int i = BLOCK_SIZE; while(i-- > CTR_POS && !++(UI8_PTR(x)[i])) ; }
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ret_type gcm_init_and_key( /* initialise mode and set key */
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const unsigned char key[], /* the key value */
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unsigned long key_len, /* and its length in bytes */
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gcm_ctx ctx[1]) /* the mode context */
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{
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memset(ctx->ghash_h, 0, sizeof(ctx->ghash_h));
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/* set the AES key */
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aes_encrypt_key(key, key_len, ctx->aes);
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/* compute E(0) (for the hash function) */
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aes_encrypt(UI8_PTR(ctx->ghash_h), UI8_PTR(ctx->ghash_h), ctx->aes);
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#if defined( GF_REPRESENTATION )
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convert_representation(ctx->ghash_h, ctx->ghash_h, GF_REPRESENTATION);
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#endif
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#if defined( TABLES_64K )
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init_64k_table(ctx->ghash_h, ctx->gf_t64k);
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#elif defined( TABLES_8K )
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init_8k_table(ctx->ghash_h, ctx->gf_t8k);
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#elif defined( TABLES_4K )
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init_4k_table(ctx->ghash_h, ctx->gf_t4k);
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#elif defined( TABLES_256 )
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init_256_table(ctx->ghash_h, ctx->gf_t256);
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#endif
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#if defined( GF_REPRESENTATION )
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convert_representation(ctx->ghash_h, ctx->ghash_h, GF_REPRESENTATION);
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#endif
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return RETURN_GOOD;
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}
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void gf_mul_hh(gf_t a, gcm_ctx ctx[1])
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{
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#if defined( GF_REPRESENTATION ) || !defined( NO_TABLES )
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gf_t scr = {0};
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#endif
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#if defined( GF_REPRESENTATION )
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convert_representation(a, a, GF_REPRESENTATION);
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#endif
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#if defined( TABLES_64K )
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gf_mul_64k(a, ctx->gf_t64k, scr);
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#elif defined( TABLES_8K )
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gf_mul_8k(a, ctx->gf_t8k, scr);
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#elif defined( TABLES_4K )
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gf_mul_4k(a, ctx->gf_t4k, scr);
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#elif defined( TABLES_256 )
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gf_mul_256(a, ctx->gf_t256, scr);
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#else
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# if defined( GF_REPRESENTATION )
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convert_representation(scr, ctx->ghash_h, GF_REPRESENTATION);
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gf_mul(a, scr);
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# else
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gf_mul(a, ctx->ghash_h);
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# endif
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#endif
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#if defined( GF_REPRESENTATION )
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convert_representation(a, a, GF_REPRESENTATION);
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#endif
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}
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ret_type gcm_init_message( /* initialise a new message */
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const unsigned char iv[], /* the initialisation vector */
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unsigned long iv_len, /* and its length in bytes */
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gcm_ctx ctx[1]) /* the mode context */
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{ uint32_t i = 0, n_pos = 0;
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uint8_t *p = NULL;
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memset(ctx->ctr_val, 0, BLOCK_SIZE);
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if(iv_len == CTR_POS)
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{
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memcpy(ctx->ctr_val, iv, CTR_POS); UI8_PTR(ctx->ctr_val)[15] = 0x01;
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}
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else
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{ n_pos = iv_len;
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while(n_pos >= BLOCK_SIZE)
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{
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xor_block_aligned(ctx->ctr_val, ctx->ctr_val, iv);
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n_pos -= BLOCK_SIZE;
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iv += BLOCK_SIZE;
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gf_mul_hh(ctx->ctr_val, ctx);
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}
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if(n_pos)
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{
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p = UI8_PTR(ctx->ctr_val);
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while(n_pos-- > 0)
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*p++ ^= *iv++;
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gf_mul_hh(ctx->ctr_val, ctx);
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}
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n_pos = (iv_len << 3);
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for(i = BLOCK_SIZE - 1; n_pos; --i, n_pos >>= 8)
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UI8_PTR(ctx->ctr_val)[i] ^= (unsigned char)n_pos;
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gf_mul_hh(ctx->ctr_val, ctx);
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}
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ctx->y0_val = *UI32_PTR(UI8_PTR(ctx->ctr_val) + CTR_POS);
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memset(ctx->hdr_ghv, 0, BLOCK_SIZE);
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memset(ctx->txt_ghv, 0, BLOCK_SIZE);
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ctx->hdr_cnt = 0;
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ctx->txt_ccnt = ctx->txt_acnt = 0;
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return RETURN_GOOD;
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}
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ret_type gcm_auth_header( /* authenticate the header */
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const unsigned char hdr[], /* the header buffer */
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unsigned long hdr_len, /* and its length in bytes */
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gcm_ctx ctx[1]) /* the mode context */
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{ uint32_t cnt = 0, b_pos = (uint32_t)ctx->hdr_cnt & BLK_ADR_MASK;
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if(!hdr_len)
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return RETURN_GOOD;
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if(ctx->hdr_cnt && b_pos == 0)
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gf_mul_hh(ctx->hdr_ghv, ctx);
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if(!((hdr - (UI8_PTR(ctx->hdr_ghv) + b_pos)) & BUF_ADRMASK))
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{
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while(cnt < hdr_len && (b_pos & BUF_ADRMASK))
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UI8_PTR(ctx->hdr_ghv)[b_pos++] ^= hdr[cnt++];
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while(cnt + BUF_INC <= hdr_len && b_pos <= BLOCK_SIZE - BUF_INC)
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{
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*UNIT_PTR(UI8_PTR(ctx->hdr_ghv) + b_pos) ^= *UNIT_PTR(hdr + cnt);
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cnt += BUF_INC; b_pos += BUF_INC;
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}
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while(cnt + BLOCK_SIZE <= hdr_len)
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{
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gf_mul_hh(ctx->hdr_ghv, ctx);
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xor_block_aligned(ctx->hdr_ghv, ctx->hdr_ghv, hdr + cnt);
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cnt += BLOCK_SIZE;
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}
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}
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else
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{
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while(cnt < hdr_len && b_pos < BLOCK_SIZE)
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UI8_PTR(ctx->hdr_ghv)[b_pos++] ^= hdr[cnt++];
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while(cnt + BLOCK_SIZE <= hdr_len)
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{
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gf_mul_hh(ctx->hdr_ghv, ctx);
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xor_block(ctx->hdr_ghv, ctx->hdr_ghv, hdr + cnt);
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cnt += BLOCK_SIZE;
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}
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}
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while(cnt < hdr_len)
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{
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if(b_pos == BLOCK_SIZE)
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{
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gf_mul_hh(ctx->hdr_ghv, ctx);
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b_pos = 0;
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}
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UI8_PTR(ctx->hdr_ghv)[b_pos++] ^= hdr[cnt++];
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}
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ctx->hdr_cnt += cnt;
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return RETURN_GOOD;
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}
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ret_type gcm_auth_data( /* authenticate ciphertext data */
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const unsigned char data[], /* the data buffer */
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unsigned long data_len, /* and its length in bytes */
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gcm_ctx ctx[1]) /* the mode context */
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{ uint32_t cnt = 0, b_pos = (uint32_t)ctx->txt_acnt & BLK_ADR_MASK;
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if(!data_len)
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return RETURN_GOOD;
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if(ctx->txt_acnt && b_pos == 0)
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gf_mul_hh(ctx->txt_ghv, ctx);
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if(!((data - (UI8_PTR(ctx->txt_ghv) + b_pos)) & BUF_ADRMASK))
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{
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while(cnt < data_len && (b_pos & BUF_ADRMASK))
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UI8_PTR(ctx->txt_ghv)[b_pos++] ^= data[cnt++];
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while(cnt + BUF_INC <= data_len && b_pos <= BLOCK_SIZE - BUF_INC)
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{
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*UNIT_PTR(UI8_PTR(ctx->txt_ghv) + b_pos) ^= *UNIT_PTR(data + cnt);
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cnt += BUF_INC; b_pos += BUF_INC;
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}
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while(cnt + BLOCK_SIZE <= data_len)
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{
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gf_mul_hh(ctx->txt_ghv, ctx);
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xor_block_aligned(ctx->txt_ghv, ctx->txt_ghv, data + cnt);
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cnt += BLOCK_SIZE;
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}
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}
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else
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{
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while(cnt < data_len && b_pos < BLOCK_SIZE)
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UI8_PTR(ctx->txt_ghv)[b_pos++] ^= data[cnt++];
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while(cnt + BLOCK_SIZE <= data_len)
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{
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gf_mul_hh(ctx->txt_ghv, ctx);
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xor_block(ctx->txt_ghv, ctx->txt_ghv, data + cnt);
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cnt += BLOCK_SIZE;
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}
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}
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while(cnt < data_len)
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{
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if(b_pos == BLOCK_SIZE)
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{
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gf_mul_hh(ctx->txt_ghv, ctx);
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b_pos = 0;
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}
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UI8_PTR(ctx->txt_ghv)[b_pos++] ^= data[cnt++];
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}
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ctx->txt_acnt += cnt;
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return RETURN_GOOD;
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}
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ret_type gcm_crypt_data( /* encrypt or decrypt data */
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unsigned char data[], /* the data buffer */
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unsigned long data_len, /* and its length in bytes */
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gcm_ctx ctx[1]) /* the mode context */
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{ uint32_t cnt = 0, b_pos = (uint32_t)ctx->txt_ccnt & BLK_ADR_MASK;
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if(!data_len)
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return RETURN_GOOD;
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if(!((data - (UI8_PTR(ctx->enc_ctr) + b_pos)) & BUF_ADRMASK))
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{
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if(b_pos)
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{
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while(cnt < data_len && (b_pos & BUF_ADRMASK))
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data[cnt++] ^= UI8_PTR(ctx->enc_ctr)[b_pos++];
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while(cnt + BUF_INC <= data_len && b_pos <= BLOCK_SIZE - BUF_INC)
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{
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*UNIT_PTR(data + cnt) ^= *UNIT_PTR(UI8_PTR(ctx->enc_ctr) + b_pos);
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cnt += BUF_INC; b_pos += BUF_INC;
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}
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}
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while(cnt + BLOCK_SIZE <= data_len)
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{
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inc_ctr(ctx->ctr_val);
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aes_encrypt(UI8_PTR(ctx->ctr_val), UI8_PTR(ctx->enc_ctr), ctx->aes);
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xor_block_aligned(data + cnt, data + cnt, ctx->enc_ctr);
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cnt += BLOCK_SIZE;
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}
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}
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else
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{
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if(b_pos)
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while(cnt < data_len && b_pos < BLOCK_SIZE)
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data[cnt++] ^= UI8_PTR(ctx->enc_ctr)[b_pos++];
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while(cnt + BLOCK_SIZE <= data_len)
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{
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inc_ctr(ctx->ctr_val);
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aes_encrypt(UI8_PTR(ctx->ctr_val), UI8_PTR(ctx->enc_ctr), ctx->aes);
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xor_block(data + cnt, data + cnt, ctx->enc_ctr);
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cnt += BLOCK_SIZE;
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}
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}
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while(cnt < data_len)
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{
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if(b_pos == BLOCK_SIZE || !b_pos)
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{
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inc_ctr(ctx->ctr_val);
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aes_encrypt(UI8_PTR(ctx->ctr_val), UI8_PTR(ctx->enc_ctr), ctx->aes);
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b_pos = 0;
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}
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data[cnt++] ^= UI8_PTR(ctx->enc_ctr)[b_pos++];
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}
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ctx->txt_ccnt += cnt;
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return RETURN_GOOD;
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}
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ret_type gcm_compute_tag( /* compute authentication tag */
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unsigned char tag[], /* the buffer for the tag */
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unsigned long tag_len, /* and its length in bytes */
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gcm_ctx ctx[1]) /* the mode context */
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{ uint32_t i = 0, ln = 0;
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gf_t tbuf = {0};
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if(ctx->txt_acnt != ctx->txt_ccnt && ctx->txt_ccnt > 0)
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return RETURN_ERROR;
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gf_mul_hh(ctx->hdr_ghv, ctx);
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gf_mul_hh(ctx->txt_ghv, ctx);
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if(ctx->hdr_cnt)
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{
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ln = (uint32_t)((ctx->txt_acnt + BLOCK_SIZE - 1) / BLOCK_SIZE);
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if(ln)
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{
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#if 1 /* alternative versions of the exponentiation operation */
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memcpy(tbuf, ctx->ghash_h, BLOCK_SIZE);
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# if defined( GF_REPRESENTATION )
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convert_representation(tbuf, tbuf, GF_REPRESENTATION);
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convert_representation(ctx->hdr_ghv, ctx->hdr_ghv, GF_REPRESENTATION);
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# endif
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for( ; ; )
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{
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if(ln & 1)
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{
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gf_mul((void*)ctx->hdr_ghv, tbuf);
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}
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if(!(ln >>= 1))
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break;
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gf_mul(tbuf, tbuf);
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}
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#else /* this one seems slower on x86 and x86_64 :-( */
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i = ln | ln >> 1; i |= i >> 2; i |= i >> 4;
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i |= i >> 8; i |= i >> 16; i &= ~(i >> 1);
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memset(tbuf, 0, BLOCK_SIZE);
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UI8_PTR(tbuf)[0] = 0x80;
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while(i)
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{
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# if defined( GF_REPRESENTATION )
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convert_representation(tbuf, tbuf, GF_REPRESENTATION);
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# endif
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gf_mul(tbuf, tbuf);
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# if defined( GF_REPRESENTATION )
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convert_representation(tbuf, tbuf, GF_REPRESENTATION);
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# endif
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if(i & ln)
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gf_mul_hh(tbuf, ctx);
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i >>= 1;
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}
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# if defined( GF_REPRESENTATION )
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convert_representation(tbuf, tbuf, GF_REPRESENTATION);
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convert_representation(ctx->hdr_ghv, ctx->hdr_ghv, GF_REPRESENTATION);
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# endif
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gf_mul((void*)ctx->hdr_ghv, tbuf);
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#endif
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#if defined( GF_REPRESENTATION )
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convert_representation(ctx->hdr_ghv, ctx->hdr_ghv, GF_REPRESENTATION);
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# endif
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}
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}
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i = BLOCK_SIZE;
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#ifdef BRG_UI64
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{ uint64_t tm = ((uint64_t)ctx->txt_acnt) << 3;
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while(i-- > 0)
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{
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UI8_PTR(ctx->hdr_ghv)[i] ^= UI8_PTR(ctx->txt_ghv)[i] ^ (unsigned char)tm;
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tm = (i == 8 ? (((uint64_t)ctx->hdr_cnt) << 3) : tm >> 8);
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}
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}
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#else
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{ uint32_t tm = ctx->txt_acnt << 3;
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while(i-- > 0)
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{
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UI8_PTR(ctx->hdr_ghv)[i] ^= UI8_PTR(ctx->txt_ghv)[i] ^ (unsigned char)tm;
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if(i & 3)
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tm >>= 8;
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else if(i == 4)
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tm = ctx->txt_acnt >> 29;
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else if(i == 8)
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tm = ctx->hdr_cnt << 3;
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else
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tm = ctx->hdr_cnt >> 29;
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}
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}
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#endif
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gf_mul_hh(ctx->hdr_ghv, ctx);
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memcpy(ctx->enc_ctr, ctx->ctr_val, BLOCK_SIZE);
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*UI32_PTR(UI8_PTR(ctx->enc_ctr) + CTR_POS) = ctx->y0_val;
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aes_encrypt(UI8_PTR(ctx->enc_ctr), UI8_PTR(ctx->enc_ctr), ctx->aes);
|
|
for(i = 0; i < (unsigned int)tag_len; ++i)
|
|
tag[i] = (unsigned char)(UI8_PTR(ctx->hdr_ghv)[i] ^ UI8_PTR(ctx->enc_ctr)[i]);
|
|
|
|
return (ctx->txt_ccnt == ctx->txt_acnt ? RETURN_GOOD : RETURN_WARN);
|
|
}
|
|
|
|
ret_type gcm_end( /* clean up and end operation */
|
|
gcm_ctx ctx[1]) /* the mode context */
|
|
{
|
|
memset(ctx, 0, sizeof(gcm_ctx));
|
|
return RETURN_GOOD;
|
|
}
|
|
|
|
ret_type gcm_encrypt( /* encrypt & authenticate data */
|
|
unsigned char data[], /* the data buffer */
|
|
unsigned long data_len, /* and its length in bytes */
|
|
gcm_ctx ctx[1]) /* the mode context */
|
|
{
|
|
|
|
gcm_crypt_data(data, data_len, ctx);
|
|
gcm_auth_data(data, data_len, ctx);
|
|
return RETURN_GOOD;
|
|
}
|
|
|
|
ret_type gcm_decrypt( /* authenticate & decrypt data */
|
|
unsigned char data[], /* the data buffer */
|
|
unsigned long data_len, /* and its length in bytes */
|
|
gcm_ctx ctx[1]) /* the mode context */
|
|
{
|
|
gcm_auth_data(data, data_len, ctx);
|
|
gcm_crypt_data(data, data_len, ctx);
|
|
return RETURN_GOOD;
|
|
}
|
|
|
|
ret_type gcm_encrypt_message( /* encrypt an entire message */
|
|
const unsigned char iv[], /* the initialisation vector */
|
|
unsigned long iv_len, /* and its length in bytes */
|
|
const unsigned char hdr[], /* the header buffer */
|
|
unsigned long hdr_len, /* and its length in bytes */
|
|
unsigned char msg[], /* the message buffer */
|
|
unsigned long msg_len, /* and its length in bytes */
|
|
unsigned char tag[], /* the buffer for the tag */
|
|
unsigned long tag_len, /* and its length in bytes */
|
|
gcm_ctx ctx[1]) /* the mode context */
|
|
{
|
|
gcm_init_message(iv, iv_len, ctx);
|
|
gcm_auth_header(hdr, hdr_len, ctx);
|
|
gcm_encrypt(msg, msg_len, ctx);
|
|
return gcm_compute_tag(tag, tag_len, ctx) ? RETURN_ERROR : RETURN_GOOD;
|
|
}
|
|
|
|
ret_type gcm_decrypt_message( /* decrypt an entire message */
|
|
const unsigned char iv[], /* the initialisation vector */
|
|
unsigned long iv_len, /* and its length in bytes */
|
|
const unsigned char hdr[], /* the header buffer */
|
|
unsigned long hdr_len, /* and its length in bytes */
|
|
unsigned char msg[], /* the message buffer */
|
|
unsigned long msg_len, /* and its length in bytes */
|
|
const unsigned char tag[], /* the buffer for the tag */
|
|
unsigned long tag_len, /* and its length in bytes */
|
|
gcm_ctx ctx[1]) /* the mode context */
|
|
{ uint8_t local_tag[BLOCK_SIZE] = {0};
|
|
ret_type rr = 0;
|
|
|
|
gcm_init_message(iv, iv_len, ctx);
|
|
gcm_auth_header(hdr, hdr_len, ctx);
|
|
gcm_decrypt(msg, msg_len, ctx);
|
|
rr = gcm_compute_tag(local_tag, tag_len, ctx);
|
|
return (rr != RETURN_GOOD || memcmp(tag, local_tag, tag_len)) ? RETURN_ERROR : RETURN_GOOD;
|
|
}
|
|
|
|
#if defined(__cplusplus)
|
|
}
|
|
#endif
|