in tls/s2n_record_read_cbc.c [29:125]
int s2n_record_parse_cbc(
const struct s2n_cipher_suite *cipher_suite,
struct s2n_connection *conn,
uint8_t content_type,
uint16_t encrypted_length,
uint8_t *implicit_iv,
struct s2n_hmac_state *mac,
uint8_t *sequence_number,
struct s2n_session_key *session_key)
{
struct s2n_blob iv = { .data = implicit_iv, .size = cipher_suite->record_alg->cipher->io.cbc.record_iv_size };
uint8_t ivpad[S2N_TLS_MAX_IV_LEN];
/* Add the header to the HMAC */
uint8_t *header = s2n_stuffer_raw_read(&conn->header_in, S2N_TLS_RECORD_HEADER_LENGTH);
POSIX_ENSURE_REF(header);
POSIX_ENSURE_LTE(cipher_suite->record_alg->cipher->io.cbc.record_iv_size, S2N_TLS_MAX_IV_LEN);
/* For TLS >= 1.1 the IV is in the packet */
if (conn->actual_protocol_version > S2N_TLS10) {
POSIX_GUARD(s2n_stuffer_read(&conn->in, &iv));
POSIX_ENSURE_GTE(encrypted_length, iv.size);
encrypted_length -= iv.size;
}
struct s2n_blob en = { .size = encrypted_length, .data = s2n_stuffer_raw_read(&conn->in, encrypted_length) };
POSIX_ENSURE_REF(en.data);
uint16_t payload_length = encrypted_length;
uint8_t mac_digest_size = 0;
POSIX_GUARD(s2n_hmac_digest_size(mac->alg, &mac_digest_size));
POSIX_ENSURE_GTE(payload_length, mac_digest_size);
payload_length -= mac_digest_size;
/* Decrypt stuff! */
/* Check that we have some data to decrypt */
POSIX_ENSURE_NE(en.size, 0);
/* ... and that we have a multiple of the block size */
POSIX_ENSURE_EQ(en.size % iv.size, 0);
/* Copy the last encrypted block to be the next IV */
if (conn->actual_protocol_version < S2N_TLS11) {
POSIX_CHECKED_MEMCPY(ivpad, en.data + en.size - iv.size, iv.size);
}
POSIX_GUARD(cipher_suite->record_alg->cipher->io.cbc.decrypt(session_key, &iv, &en, &en));
if (conn->actual_protocol_version < S2N_TLS11) {
POSIX_CHECKED_MEMCPY(implicit_iv, ivpad, iv.size);
}
/* Subtract the padding length */
POSIX_ENSURE_GT(en.size, 0);
uint32_t out = 0;
POSIX_GUARD(s2n_sub_overflow(payload_length, en.data[en.size - 1] + 1, &out));
payload_length = out;
/* Update the MAC */
header[3] = (payload_length >> 8);
header[4] = payload_length & 0xff;
POSIX_GUARD(s2n_hmac_reset(mac));
POSIX_GUARD(s2n_hmac_update(mac, sequence_number, S2N_TLS_SEQUENCE_NUM_LEN));
if (conn->actual_protocol_version == S2N_SSLv3) {
POSIX_GUARD(s2n_hmac_update(mac, header, 1));
POSIX_GUARD(s2n_hmac_update(mac, header + 3, 2));
} else {
POSIX_GUARD(s2n_hmac_update(mac, header, S2N_TLS_RECORD_HEADER_LENGTH));
}
struct s2n_blob seq = { .data = sequence_number, .size = S2N_TLS_SEQUENCE_NUM_LEN };
POSIX_GUARD(s2n_increment_sequence_number(&seq));
/* Padding. This finalizes the provided HMAC. */
if (s2n_verify_cbc(conn, mac, &en) < 0) {
POSIX_BAIL(S2N_ERR_BAD_MESSAGE);
}
/* O.k., we've successfully read and decrypted the record, now we need to align the stuffer
* for reading the plaintext data.
*/
POSIX_GUARD(s2n_stuffer_reread(&conn->in));
POSIX_GUARD(s2n_stuffer_reread(&conn->header_in));
/* Skip the IV, if any */
if (conn->actual_protocol_version > S2N_TLS10) {
POSIX_GUARD(s2n_stuffer_skip_read(&conn->in, cipher_suite->record_alg->cipher->io.cbc.record_iv_size));
}
/* Truncate and wipe the MAC and any padding */
POSIX_GUARD(s2n_stuffer_wipe_n(&conn->in, s2n_stuffer_data_available(&conn->in) - payload_length));
conn->in_status = PLAINTEXT;
return 0;
}