/******************************************************************************* * * Copyright (c) 2011, 2012, 2013, 2014, 2015 Olaf Bergmann (TZI) and others. * All rights reserved. This program and the accompanying materials * are made available under the terms of the Eclipse Public License v1.0 * and Eclipse Distribution License v. 1.0 which accompanies this distribution. * * The Eclipse Public License is available at http://www.eclipse.org/legal/epl-v10.html * and the Eclipse Distribution License is available at * http://www.eclipse.org/org/documents/edl-v10.php. * * Contributors: * Olaf Bergmann - initial API and implementation * Hauke Mehrtens - memory optimization, ECC integration * *******************************************************************************/ #include #include "tinydtls.h" #include "global.h" #include "numeric.h" #include "ccm.h" #ifdef HAVE_ASSERT_H # include #endif #define CCM_FLAGS(A,M,L) (((A > 0) << 6) | (((M - 2)/2) << 3) | (L - 1)) #define MASK_L(_L) ((1 << 8 * _L) - 1) #define SET_COUNTER(A,L,cnt,C) { \ unsigned int i_; \ memset((A) + DTLS_CCM_BLOCKSIZE - (L), 0, (L)); \ (C) = (cnt) & MASK_L(L); \ for (i_ = DTLS_CCM_BLOCKSIZE - 1; (C) && (i_ > (L)); --i_, (C) >>= 8) \ (A)[i_] |= (C) & 0xFF; \ } static inline void block0(size_t M, /* number of auth bytes */ size_t L, /* number of bytes to encode message length */ size_t la, /* l(a) octets additional authenticated data */ size_t lm, /* l(m) message length */ const unsigned char nonce[DTLS_CCM_BLOCKSIZE], unsigned char *result) { unsigned int i; result[0] = CCM_FLAGS(la, M, L); /* copy the nonce */ memcpy(result + 1, nonce, DTLS_CCM_BLOCKSIZE - L - 1); for (i=0; i < L; i++) { result[15-i] = lm & 0xff; lm >>= 8; } } /** * Creates the CBC-MAC for the additional authentication data that * is sent in cleartext. * * \param ctx The crypto context for the AES encryption. * \param msg The message starting with the additional authentication data. * \param la The number of additional authentication bytes in \p msg. * \param B The input buffer for crypto operations. When this function * is called, \p B must be initialized with \c B0 (the first * authentication block. * \param X The output buffer where the result of the CBC calculation * is placed. */ static void add_auth_data(rijndael_ctx *ctx, const unsigned char *msg, uint64_t la, unsigned char B[DTLS_CCM_BLOCKSIZE], unsigned char X[DTLS_CCM_BLOCKSIZE]) { uint64_t i,j; rijndael_encrypt(ctx, B, X); memset(B, 0, DTLS_CCM_BLOCKSIZE); if (!la) return; #ifndef WITH_CONTIKI if (la < 0xFF00) { /* 2^16 - 2^8 */ j = 2; dtls_int_to_uint16(B, la); } else if (la <= UINT32_MAX) { j = 6; dtls_int_to_uint16(B, 0xFFFE); dtls_int_to_uint32(B+2, la); } else { j = 10; dtls_int_to_uint16(B, 0xFFFF); dtls_int_to_uint64(B+2, la); } #else /* WITH_CONTIKI */ /* With Contiki, we are building for small devices and thus * anticipate that the number of additional authentication bytes * will not exceed 65280 bytes (0xFF00) and we can skip the * workarounds required for j=6 and j=10 on devices with a word size * of 32 bits or 64 bits, respectively. */ assert(la < 0xFF00); j = 2; dtls_int_to_uint16(B, la); #endif /* WITH_CONTIKI */ i = min(DTLS_CCM_BLOCKSIZE - j, la); memcpy(B + j, msg, i); la -= i; msg += i; memxor(B, X, DTLS_CCM_BLOCKSIZE); rijndael_encrypt(ctx, B, X); while (la > DTLS_CCM_BLOCKSIZE) { for (i = 0; i < DTLS_CCM_BLOCKSIZE; ++i) B[i] = X[i] ^ *msg++; la -= DTLS_CCM_BLOCKSIZE; rijndael_encrypt(ctx, B, X); } if (la) { memset(B, 0, DTLS_CCM_BLOCKSIZE); memcpy(B, msg, la); memxor(B, X, DTLS_CCM_BLOCKSIZE); rijndael_encrypt(ctx, B, X); } } static inline void encrypt(rijndael_ctx *ctx, size_t L, unsigned long counter, unsigned char *msg, size_t len, unsigned char A[DTLS_CCM_BLOCKSIZE], unsigned char S[DTLS_CCM_BLOCKSIZE]) { static unsigned long counter_tmp; SET_COUNTER(A, L, counter, counter_tmp); rijndael_encrypt(ctx, A, S); memxor(msg, S, len); } static inline void mac(rijndael_ctx *ctx, unsigned char *msg, size_t len, unsigned char B[DTLS_CCM_BLOCKSIZE], unsigned char X[DTLS_CCM_BLOCKSIZE]) { size_t i; for (i = 0; i < len; ++i) B[i] = X[i] ^ msg[i]; rijndael_encrypt(ctx, B, X); } long int dtls_ccm_encrypt_message(rijndael_ctx *ctx, size_t M, size_t L, const unsigned char nonce[DTLS_CCM_BLOCKSIZE], unsigned char *msg, size_t lm, const unsigned char *aad, size_t la) { size_t i, len; unsigned long counter_tmp; unsigned long counter = 1; /* \bug does not work correctly on ia32 when lm >= 2^16 */ unsigned char A[DTLS_CCM_BLOCKSIZE]; /* A_i blocks for encryption input */ unsigned char B[DTLS_CCM_BLOCKSIZE]; /* B_i blocks for CBC-MAC input */ unsigned char S[DTLS_CCM_BLOCKSIZE]; /* S_i = encrypted A_i blocks */ unsigned char X[DTLS_CCM_BLOCKSIZE]; /* X_i = encrypted B_i blocks */ len = lm; /* save original length */ /* create the initial authentication block B0 */ block0(M, L, la, lm, nonce, B); add_auth_data(ctx, aad, la, B, X); /* initialize block template */ A[0] = L-1; /* copy the nonce */ memcpy(A + 1, nonce, DTLS_CCM_BLOCKSIZE - L - 1); while (lm >= DTLS_CCM_BLOCKSIZE) { /* calculate MAC */ mac(ctx, msg, DTLS_CCM_BLOCKSIZE, B, X); /* encrypt */ encrypt(ctx, L, counter, msg, DTLS_CCM_BLOCKSIZE, A, S); /* update local pointers */ lm -= DTLS_CCM_BLOCKSIZE; msg += DTLS_CCM_BLOCKSIZE; counter++; } if (lm) { /* Calculate MAC. The remainder of B must be padded with zeroes, so * B is constructed to contain X ^ msg for the first lm bytes (done in * mac() and X ^ 0 for the remaining DTLS_CCM_BLOCKSIZE - lm bytes * (i.e., we can use memcpy() here). */ memcpy(B + lm, X + lm, DTLS_CCM_BLOCKSIZE - lm); mac(ctx, msg, lm, B, X); /* encrypt */ encrypt(ctx, L, counter, msg, lm, A, S); /* update local pointers */ msg += lm; } /* calculate S_0 */ SET_COUNTER(A, L, 0, counter_tmp); rijndael_encrypt(ctx, A, S); for (i = 0; i < M; ++i) *msg++ = X[i] ^ S[i]; return len + M; } long int dtls_ccm_decrypt_message(rijndael_ctx *ctx, size_t M, size_t L, const unsigned char nonce[DTLS_CCM_BLOCKSIZE], unsigned char *msg, size_t lm, const unsigned char *aad, size_t la) { size_t len; unsigned long counter_tmp; unsigned long counter = 1; /* \bug does not work correctly on ia32 when lm >= 2^16 */ unsigned char A[DTLS_CCM_BLOCKSIZE]; /* A_i blocks for encryption input */ unsigned char B[DTLS_CCM_BLOCKSIZE]; /* B_i blocks for CBC-MAC input */ unsigned char S[DTLS_CCM_BLOCKSIZE]; /* S_i = encrypted A_i blocks */ unsigned char X[DTLS_CCM_BLOCKSIZE]; /* X_i = encrypted B_i blocks */ if (lm < M) goto error; len = lm; /* save original length */ lm -= M; /* detract MAC size*/ /* create the initial authentication block B0 */ block0(M, L, la, lm, nonce, B); add_auth_data(ctx, aad, la, B, X); /* initialize block template */ A[0] = L-1; /* copy the nonce */ memcpy(A + 1, nonce, DTLS_CCM_BLOCKSIZE - L - 1); while (lm >= DTLS_CCM_BLOCKSIZE) { /* decrypt */ encrypt(ctx, L, counter, msg, DTLS_CCM_BLOCKSIZE, A, S); /* calculate MAC */ mac(ctx, msg, DTLS_CCM_BLOCKSIZE, B, X); /* update local pointers */ lm -= DTLS_CCM_BLOCKSIZE; msg += DTLS_CCM_BLOCKSIZE; counter++; } if (lm) { /* decrypt */ encrypt(ctx, L, counter, msg, lm, A, S); /* Calculate MAC. Note that msg ends in the MAC so we must * construct B to contain X ^ msg for the first lm bytes (done in * mac() and X ^ 0 for the remaining DTLS_CCM_BLOCKSIZE - lm bytes * (i.e., we can use memcpy() here). */ memcpy(B + lm, X + lm, DTLS_CCM_BLOCKSIZE - lm); mac(ctx, msg, lm, B, X); /* update local pointers */ msg += lm; } /* calculate S_0 */ SET_COUNTER(A, L, 0, counter_tmp); rijndael_encrypt(ctx, A, S); memxor(msg, S, M); /* return length if MAC is valid, otherwise continue with error handling */ if (equals(X, msg, M)) return len - M; error: return -1; }