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https://github.com/openssl/openssl.git
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46ac83eaf3
Adding KRB5 test vector 'NextIV' values to evp_test data for AES CTS indicated that the CTS decrypt functions incorrectly returned the wrong IV. The returned IV should match the value returned by the encrypt methods. Reviewed-by: Paul Dale <pauli@openssl.org> (Merged from https://github.com/openssl/openssl/pull/16286)
380 lines
12 KiB
C
380 lines
12 KiB
C
/*
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* Copyright 2020-2021 The OpenSSL Project Authors. All Rights Reserved.
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*
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* Licensed under the Apache License 2.0 (the "License"). You may not use
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* this file except in compliance with the License. You can obtain a copy
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* in the file LICENSE in the source distribution or at
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* https://www.openssl.org/source/license.html
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*/
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/*
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* Helper functions for 128 bit CBC CTS ciphers (Currently AES and Camellia).
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*
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* The function dispatch tables are embedded into cipher_aes.c
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* and cipher_camellia.c using cipher_aes_cts.inc and cipher_camellia_cts.inc
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*/
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/*
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* Refer to SP800-38A-Addendum
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*
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* Ciphertext stealing encrypts plaintext using a block cipher, without padding
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* the message to a multiple of the block size, so the ciphertext is the same
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* size as the plaintext.
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* It does this by altering processing of the last two blocks of the message.
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* The processing of all but the last two blocks is unchanged, but a portion of
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* the second-last block's ciphertext is "stolen" to pad the last plaintext
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* block. The padded final block is then encrypted as usual.
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* The final ciphertext for the last two blocks, consists of the partial block
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* (with the "stolen" portion omitted) plus the full final block,
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* which are the same size as the original plaintext.
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* Decryption requires decrypting the final block first, then restoring the
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* stolen ciphertext to the partial block, which can then be decrypted as usual.
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* AES_CBC_CTS has 3 variants:
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* (1) CS1 The NIST variant.
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* If the length is a multiple of the blocksize it is the same as CBC mode.
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* otherwise it produces C1||C2||(C(n-1))*||Cn.
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* Where C(n-1)* is a partial block.
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* (2) CS2
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* If the length is a multiple of the blocksize it is the same as CBC mode.
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* otherwise it produces C1||C2||Cn||(C(n-1))*.
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* Where C(n-1)* is a partial block.
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* (3) CS3 The Kerberos5 variant.
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* Produces C1||C2||Cn||(C(n-1))* regardless of the length.
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* If the length is a multiple of the blocksize it looks similar to CBC mode
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* with the last 2 blocks swapped.
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* Otherwise it is the same as CS2.
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*/
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#include "e_os.h" /* strcasecmp */
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#include <openssl/core_names.h>
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#include "prov/ciphercommon.h"
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#include "internal/nelem.h"
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#include "cipher_cts.h"
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/* The value assigned to 0 is the default */
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#define CTS_CS1 0
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#define CTS_CS2 1
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#define CTS_CS3 2
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#define CTS_BLOCK_SIZE 16
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typedef union {
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size_t align;
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unsigned char c[CTS_BLOCK_SIZE];
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} aligned_16bytes;
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typedef struct cts_mode_name2id_st {
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unsigned int id;
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const char *name;
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} CTS_MODE_NAME2ID;
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static CTS_MODE_NAME2ID cts_modes[] =
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{
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{ CTS_CS1, OSSL_CIPHER_CTS_MODE_CS1 },
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{ CTS_CS2, OSSL_CIPHER_CTS_MODE_CS2 },
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{ CTS_CS3, OSSL_CIPHER_CTS_MODE_CS3 },
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};
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const char *ossl_cipher_cbc_cts_mode_id2name(unsigned int id)
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{
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size_t i;
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for (i = 0; i < OSSL_NELEM(cts_modes); ++i) {
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if (cts_modes[i].id == id)
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return cts_modes[i].name;
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}
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return NULL;
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}
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int ossl_cipher_cbc_cts_mode_name2id(const char *name)
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{
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size_t i;
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for (i = 0; i < OSSL_NELEM(cts_modes); ++i) {
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if (strcasecmp(name, cts_modes[i].name) == 0)
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return (int)cts_modes[i].id;
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}
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return -1;
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}
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static size_t cts128_cs1_encrypt(PROV_CIPHER_CTX *ctx, const unsigned char *in,
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unsigned char *out, size_t len)
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{
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aligned_16bytes tmp_in;
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size_t residue;
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residue = len % CTS_BLOCK_SIZE;
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len -= residue;
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if (!ctx->hw->cipher(ctx, out, in, len))
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return 0;
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if (residue == 0)
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return len;
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in += len;
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out += len;
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memset(tmp_in.c, 0, sizeof(tmp_in));
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memcpy(tmp_in.c, in, residue);
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if (!ctx->hw->cipher(ctx, out - CTS_BLOCK_SIZE + residue, tmp_in.c,
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CTS_BLOCK_SIZE))
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return 0;
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return len + residue;
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}
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static void do_xor(const unsigned char *in1, const unsigned char *in2,
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size_t len, unsigned char *out)
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{
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size_t i;
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for (i = 0; i < len; ++i)
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out[i] = in1[i] ^ in2[i];
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}
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static size_t cts128_cs1_decrypt(PROV_CIPHER_CTX *ctx, const unsigned char *in,
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unsigned char *out, size_t len)
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{
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aligned_16bytes mid_iv, ct_mid, cn, pt_last;
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size_t residue;
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residue = len % CTS_BLOCK_SIZE;
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if (residue == 0) {
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/* If there are no partial blocks then it is the same as CBC mode */
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if (!ctx->hw->cipher(ctx, out, in, len))
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return 0;
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return len;
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}
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/* Process blocks at the start - but leave the last 2 blocks */
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len -= CTS_BLOCK_SIZE + residue;
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if (len > 0) {
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if (!ctx->hw->cipher(ctx, out, in, len))
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return 0;
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in += len;
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out += len;
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}
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/* Save the iv that will be used by the second last block */
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memcpy(mid_iv.c, ctx->iv, CTS_BLOCK_SIZE);
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/* Save the C(n) block */
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memcpy(cn.c, in + residue, CTS_BLOCK_SIZE);
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/* Decrypt the last block first using an iv of zero */
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memset(ctx->iv, 0, CTS_BLOCK_SIZE);
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if (!ctx->hw->cipher(ctx, pt_last.c, in + residue, CTS_BLOCK_SIZE))
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return 0;
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/*
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* Rebuild the ciphertext of the second last block as a combination of
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* the decrypted last block + replace the start with the ciphertext bytes
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* of the partial second last block.
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*/
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memcpy(ct_mid.c, in, residue);
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memcpy(ct_mid.c + residue, pt_last.c + residue, CTS_BLOCK_SIZE - residue);
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/*
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* Restore the last partial ciphertext block.
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* Now that we have the cipher text of the second last block, apply
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* that to the partial plaintext end block. We have already decrypted the
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* block using an IV of zero. For decryption the IV is just XORed after
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* doing an Cipher CBC block - so just XOR in the cipher text.
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*/
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do_xor(ct_mid.c, pt_last.c, residue, out + CTS_BLOCK_SIZE);
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/* Restore the iv needed by the second last block */
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memcpy(ctx->iv, mid_iv.c, CTS_BLOCK_SIZE);
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/*
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* Decrypt the second last plaintext block now that we have rebuilt the
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* ciphertext.
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*/
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if (!ctx->hw->cipher(ctx, out, ct_mid.c, CTS_BLOCK_SIZE))
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return 0;
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/* The returned iv is the C(n) block */
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memcpy(ctx->iv, cn.c, CTS_BLOCK_SIZE);
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return len + CTS_BLOCK_SIZE + residue;
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}
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static size_t cts128_cs3_encrypt(PROV_CIPHER_CTX *ctx, const unsigned char *in,
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unsigned char *out, size_t len)
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{
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aligned_16bytes tmp_in;
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size_t residue;
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if (len < CTS_BLOCK_SIZE) /* CS3 requires at least one block */
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return 0;
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/* If we only have one block then just process the aligned block */
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if (len == CTS_BLOCK_SIZE)
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return ctx->hw->cipher(ctx, out, in, len) ? len : 0;
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residue = len % CTS_BLOCK_SIZE;
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if (residue == 0)
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residue = CTS_BLOCK_SIZE;
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len -= residue;
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if (!ctx->hw->cipher(ctx, out, in, len))
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return 0;
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in += len;
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out += len;
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memset(tmp_in.c, 0, sizeof(tmp_in));
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memcpy(tmp_in.c, in, residue);
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memcpy(out, out - CTS_BLOCK_SIZE, residue);
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if (!ctx->hw->cipher(ctx, out - CTS_BLOCK_SIZE, tmp_in.c, CTS_BLOCK_SIZE))
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return 0;
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return len + residue;
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}
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/*
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* Note:
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* The cipher text (in) is of the form C(0), C(1), ., C(n), C(n-1)* where
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* C(n) is a full block and C(n-1)* can be a partial block
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* (but could be a full block).
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* This means that the output plaintext (out) needs to swap the plaintext of
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* the last two decoded ciphertext blocks.
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*/
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static size_t cts128_cs3_decrypt(PROV_CIPHER_CTX *ctx, const unsigned char *in,
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unsigned char *out, size_t len)
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{
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aligned_16bytes mid_iv, ct_mid, cn, pt_last;
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size_t residue;
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if (len < CTS_BLOCK_SIZE) /* CS3 requires at least one block */
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return 0;
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/* If we only have one block then just process the aligned block */
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if (len == CTS_BLOCK_SIZE)
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return ctx->hw->cipher(ctx, out, in, len) ? len : 0;
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/* Process blocks at the start - but leave the last 2 blocks */
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residue = len % CTS_BLOCK_SIZE;
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if (residue == 0)
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residue = CTS_BLOCK_SIZE;
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len -= CTS_BLOCK_SIZE + residue;
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if (len > 0) {
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if (!ctx->hw->cipher(ctx, out, in, len))
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return 0;
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in += len;
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out += len;
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}
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/* Save the iv that will be used by the second last block */
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memcpy(mid_iv.c, ctx->iv, CTS_BLOCK_SIZE);
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/* Save the C(n) block : For CS3 it is C(1)||...||C(n-2)||C(n)||C(n-1)* */
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memcpy(cn.c, in, CTS_BLOCK_SIZE);
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/* Decrypt the C(n) block first using an iv of zero */
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memset(ctx->iv, 0, CTS_BLOCK_SIZE);
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if (!ctx->hw->cipher(ctx, pt_last.c, in, CTS_BLOCK_SIZE))
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return 0;
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/*
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* Rebuild the ciphertext of C(n-1) as a combination of
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* the decrypted C(n) block + replace the start with the ciphertext bytes
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* of the partial last block.
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*/
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memcpy(ct_mid.c, in + CTS_BLOCK_SIZE, residue);
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if (residue != CTS_BLOCK_SIZE)
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memcpy(ct_mid.c + residue, pt_last.c + residue, CTS_BLOCK_SIZE - residue);
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/*
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* Restore the last partial ciphertext block.
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* Now that we have the cipher text of the second last block, apply
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* that to the partial plaintext end block. We have already decrypted the
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* block using an IV of zero. For decryption the IV is just XORed after
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* doing an AES block - so just XOR in the ciphertext.
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*/
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do_xor(ct_mid.c, pt_last.c, residue, out + CTS_BLOCK_SIZE);
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/* Restore the iv needed by the second last block */
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memcpy(ctx->iv, mid_iv.c, CTS_BLOCK_SIZE);
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/*
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* Decrypt the second last plaintext block now that we have rebuilt the
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* ciphertext.
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*/
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if (!ctx->hw->cipher(ctx, out, ct_mid.c, CTS_BLOCK_SIZE))
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return 0;
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/* The returned iv is the C(n) block */
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memcpy(ctx->iv, cn.c, CTS_BLOCK_SIZE);
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return len + CTS_BLOCK_SIZE + residue;
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}
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static size_t cts128_cs2_encrypt(PROV_CIPHER_CTX *ctx, const unsigned char *in,
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unsigned char *out, size_t len)
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{
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if (len % CTS_BLOCK_SIZE == 0) {
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/* If there are no partial blocks then it is the same as CBC mode */
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if (!ctx->hw->cipher(ctx, out, in, len))
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return 0;
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return len;
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}
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/* For partial blocks CS2 is equivalent to CS3 */
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return cts128_cs3_encrypt(ctx, in, out, len);
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}
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static size_t cts128_cs2_decrypt(PROV_CIPHER_CTX *ctx, const unsigned char *in,
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unsigned char *out, size_t len)
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{
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if (len % CTS_BLOCK_SIZE == 0) {
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/* If there are no partial blocks then it is the same as CBC mode */
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if (!ctx->hw->cipher(ctx, out, in, len))
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return 0;
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return len;
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}
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/* For partial blocks CS2 is equivalent to CS3 */
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return cts128_cs3_decrypt(ctx, in, out, len);
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}
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int ossl_cipher_cbc_cts_block_update(void *vctx, unsigned char *out, size_t *outl,
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size_t outsize, const unsigned char *in,
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size_t inl)
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{
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PROV_CIPHER_CTX *ctx = (PROV_CIPHER_CTX *)vctx;
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size_t sz = 0;
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if (inl < CTS_BLOCK_SIZE) /* There must be at least one block for CTS mode */
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return 0;
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if (outsize < inl)
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return 0;
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if (out == NULL) {
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*outl = inl;
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return 1;
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}
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/*
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* Return an error if the update is called multiple times, only one shot
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* is supported.
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*/
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if (ctx->updated == 1)
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return 0;
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if (ctx->enc) {
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if (ctx->cts_mode == CTS_CS1)
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sz = cts128_cs1_encrypt(ctx, in, out, inl);
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else if (ctx->cts_mode == CTS_CS2)
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sz = cts128_cs2_encrypt(ctx, in, out, inl);
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else if (ctx->cts_mode == CTS_CS3)
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sz = cts128_cs3_encrypt(ctx, in, out, inl);
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} else {
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if (ctx->cts_mode == CTS_CS1)
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sz = cts128_cs1_decrypt(ctx, in, out, inl);
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else if (ctx->cts_mode == CTS_CS2)
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sz = cts128_cs2_decrypt(ctx, in, out, inl);
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else if (ctx->cts_mode == CTS_CS3)
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sz = cts128_cs3_decrypt(ctx, in, out, inl);
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}
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if (sz == 0)
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return 0;
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ctx->updated = 1; /* Stop multiple updates being allowed */
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*outl = sz;
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return 1;
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}
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int ossl_cipher_cbc_cts_block_final(void *vctx, unsigned char *out, size_t *outl,
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size_t outsize)
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{
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*outl = 0;
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return 1;
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}
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