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|
/*
* Copyright Amazon.com, Inc. or its affiliates. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License").
* You may not use this file except in compliance with the License.
* A copy of the License is located at
*
* http://aws.amazon.com/apache2.0
*
* or in the "license" file accompanying this file. This file is distributed
* on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either
* express or implied. See the License for the specific language governing
* permissions and limitations under the License.
*/
#include <sys/param.h>
#include "crypto/s2n_tls13_keys.h"
#include "tls/extensions/s2n_extension_type.h"
#include "tls/s2n_handshake.h"
#include "tls/s2n_tls.h"
#include "tls/s2n_tls13_handshake.h"
#include "tls/s2n_tls13_secrets.h"
#include "utils/s2n_array.h"
#include "utils/s2n_mem.h"
#include "utils/s2n_safety.h"
#define S2N_HASH_ALG_COUNT S2N_HASH_SENTINEL
S2N_RESULT s2n_psk_init(struct s2n_psk *psk, s2n_psk_type type)
{
RESULT_ENSURE_MUT(psk);
RESULT_CHECKED_MEMSET(psk, 0, sizeof(struct s2n_psk));
psk->hmac_alg = S2N_HMAC_SHA256;
psk->type = type;
return S2N_RESULT_OK;
}
struct s2n_psk *s2n_external_psk_new()
{
DEFER_CLEANUP(struct s2n_blob mem = { 0 }, s2n_free);
PTR_GUARD_POSIX(s2n_alloc(&mem, sizeof(struct s2n_psk)));
struct s2n_psk *psk = (struct s2n_psk *) (void *) mem.data;
PTR_GUARD_RESULT(s2n_psk_init(psk, S2N_PSK_TYPE_EXTERNAL));
ZERO_TO_DISABLE_DEFER_CLEANUP(mem);
return psk;
}
int s2n_psk_set_identity(struct s2n_psk *psk, const uint8_t *identity, uint16_t identity_size)
{
POSIX_ENSURE_REF(psk);
POSIX_ENSURE_REF(identity);
POSIX_ENSURE(identity_size != 0, S2N_ERR_INVALID_ARGUMENT);
POSIX_GUARD(s2n_realloc(&psk->identity, identity_size));
POSIX_CHECKED_MEMCPY(psk->identity.data, identity, identity_size);
return S2N_SUCCESS;
}
int s2n_psk_set_secret(struct s2n_psk *psk, const uint8_t *secret, uint16_t secret_size)
{
POSIX_ENSURE_REF(psk);
POSIX_ENSURE_REF(secret);
POSIX_ENSURE(secret_size != 0, S2N_ERR_INVALID_ARGUMENT);
POSIX_GUARD(s2n_realloc(&psk->secret, secret_size));
POSIX_CHECKED_MEMCPY(psk->secret.data, secret, secret_size);
return S2N_SUCCESS;
}
S2N_RESULT s2n_psk_clone(struct s2n_psk *new_psk, struct s2n_psk *original_psk)
{
if (original_psk == NULL) {
return S2N_RESULT_OK;
}
RESULT_ENSURE_REF(new_psk);
struct s2n_psk psk_copy = *new_psk;
/* Copy all fields from the old_config EXCEPT the blobs, which we need to reallocate. */
*new_psk = *original_psk;
new_psk->identity = psk_copy.identity;
new_psk->secret = psk_copy.secret;
new_psk->early_secret = psk_copy.early_secret;
new_psk->early_data_config = psk_copy.early_data_config;
/* Clone / realloc blobs */
RESULT_GUARD_POSIX(s2n_psk_set_identity(new_psk, original_psk->identity.data, original_psk->identity.size));
RESULT_GUARD_POSIX(s2n_psk_set_secret(new_psk, original_psk->secret.data, original_psk->secret.size));
RESULT_GUARD_POSIX(s2n_realloc(&new_psk->early_secret, original_psk->early_secret.size));
RESULT_CHECKED_MEMCPY(new_psk->early_secret.data, original_psk->early_secret.data, original_psk->early_secret.size);
RESULT_GUARD(s2n_early_data_config_clone(new_psk, &original_psk->early_data_config));
return S2N_RESULT_OK;
}
S2N_CLEANUP_RESULT s2n_psk_wipe(struct s2n_psk *psk)
{
if (psk == NULL) {
return S2N_RESULT_OK;
}
RESULT_GUARD_POSIX(s2n_free(&psk->early_secret));
RESULT_GUARD_POSIX(s2n_free(&psk->identity));
RESULT_GUARD_POSIX(s2n_free(&psk->secret));
RESULT_GUARD(s2n_early_data_config_free(&psk->early_data_config));
return S2N_RESULT_OK;
}
int s2n_psk_free(struct s2n_psk **psk)
{
if (psk == NULL) {
return S2N_SUCCESS;
}
POSIX_GUARD_RESULT(s2n_psk_wipe(*psk));
return s2n_free_object((uint8_t **) psk, sizeof(struct s2n_psk));
}
S2N_RESULT s2n_psk_parameters_init(struct s2n_psk_parameters *params)
{
RESULT_ENSURE_REF(params);
RESULT_CHECKED_MEMSET(params, 0, sizeof(struct s2n_psk_parameters));
RESULT_GUARD(s2n_array_init(¶ms->psk_list, sizeof(struct s2n_psk)));
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_psk_offered_psk_size(struct s2n_psk *psk, uint32_t *size)
{
*size = sizeof(uint16_t) /* identity size */
+ sizeof(uint32_t) /* obfuscated ticket age */
+ sizeof(uint8_t); /* binder size */
RESULT_GUARD_POSIX(s2n_add_overflow(*size, psk->identity.size, size));
uint8_t binder_size = 0;
RESULT_GUARD_POSIX(s2n_hmac_digest_size(psk->hmac_alg, &binder_size));
RESULT_GUARD_POSIX(s2n_add_overflow(*size, binder_size, size));
return S2N_RESULT_OK;
}
S2N_RESULT s2n_psk_parameters_offered_psks_size(struct s2n_psk_parameters *params, uint32_t *size)
{
RESULT_ENSURE_REF(params);
RESULT_ENSURE_REF(size);
*size = sizeof(uint16_t) /* identity list size */
+ sizeof(uint16_t) /* binder list size */;
for (uint32_t i = 0; i < params->psk_list.len; i++) {
struct s2n_psk *psk = NULL;
RESULT_GUARD(s2n_array_get(¶ms->psk_list, i, (void **) &psk));
RESULT_ENSURE_REF(psk);
uint32_t psk_size = 0;
RESULT_GUARD(s2n_psk_offered_psk_size(psk, &psk_size));
RESULT_GUARD_POSIX(s2n_add_overflow(*size, psk_size, size));
}
return S2N_RESULT_OK;
}
S2N_CLEANUP_RESULT s2n_psk_parameters_wipe(struct s2n_psk_parameters *params)
{
RESULT_ENSURE_REF(params);
for (size_t i = 0; i < params->psk_list.len; i++) {
struct s2n_psk *psk = NULL;
RESULT_GUARD(s2n_array_get(¶ms->psk_list, i, (void **) &psk));
RESULT_GUARD(s2n_psk_wipe(psk));
}
RESULT_GUARD_POSIX(s2n_free(¶ms->psk_list.mem));
RESULT_GUARD(s2n_psk_parameters_init(params));
return S2N_RESULT_OK;
}
S2N_CLEANUP_RESULT s2n_psk_parameters_wipe_secrets(struct s2n_psk_parameters *params)
{
RESULT_ENSURE_REF(params);
for (size_t i = 0; i < params->psk_list.len; i++) {
struct s2n_psk *psk = NULL;
RESULT_GUARD(s2n_array_get(¶ms->psk_list, i, (void **) &psk));
RESULT_ENSURE_REF(psk);
RESULT_GUARD_POSIX(s2n_free(&psk->early_secret));
RESULT_GUARD_POSIX(s2n_free(&psk->secret));
}
return S2N_RESULT_OK;
}
bool s2n_offered_psk_list_has_next(struct s2n_offered_psk_list *psk_list)
{
return psk_list != NULL && s2n_stuffer_data_available(&psk_list->wire_data) > 0;
}
S2N_RESULT s2n_offered_psk_list_read_next(struct s2n_offered_psk_list *psk_list, struct s2n_offered_psk *psk)
{
RESULT_ENSURE_REF(psk_list);
RESULT_ENSURE_REF(psk_list->conn);
RESULT_ENSURE_MUT(psk);
uint16_t identity_size = 0;
RESULT_GUARD_POSIX(s2n_stuffer_read_uint16(&psk_list->wire_data, &identity_size));
RESULT_ENSURE_GT(identity_size, 0);
uint8_t *identity_data = NULL;
identity_data = s2n_stuffer_raw_read(&psk_list->wire_data, identity_size);
RESULT_ENSURE_REF(identity_data);
/**
*= https://tools.ietf.org/rfc/rfc8446#section-4.2.11
*# For identities established externally, an obfuscated_ticket_age of 0 SHOULD be
*# used, and servers MUST ignore the value.
*/
if (psk_list->conn->psk_params.type == S2N_PSK_TYPE_EXTERNAL) {
RESULT_GUARD_POSIX(s2n_stuffer_skip_read(&psk_list->wire_data, sizeof(uint32_t)));
} else {
RESULT_GUARD_POSIX(s2n_stuffer_read_uint32(&psk_list->wire_data, &psk->obfuscated_ticket_age));
}
RESULT_GUARD_POSIX(s2n_blob_init(&psk->identity, identity_data, identity_size));
psk->wire_index = psk_list->wire_index;
RESULT_ENSURE(psk_list->wire_index < UINT16_MAX, S2N_ERR_INTEGER_OVERFLOW);
psk_list->wire_index++;
return S2N_RESULT_OK;
}
int s2n_offered_psk_list_next(struct s2n_offered_psk_list *psk_list, struct s2n_offered_psk *psk)
{
POSIX_ENSURE_REF(psk_list);
POSIX_ENSURE_REF(psk);
*psk = (struct s2n_offered_psk){ 0 };
POSIX_ENSURE(s2n_offered_psk_list_has_next(psk_list), S2N_ERR_STUFFER_OUT_OF_DATA);
POSIX_ENSURE(s2n_result_is_ok(s2n_offered_psk_list_read_next(psk_list, psk)), S2N_ERR_BAD_MESSAGE);
return S2N_SUCCESS;
}
int s2n_offered_psk_list_reread(struct s2n_offered_psk_list *psk_list)
{
POSIX_ENSURE_REF(psk_list);
psk_list->wire_index = 0;
return s2n_stuffer_reread(&psk_list->wire_data);
}
/* Match a PSK identity received from the client against the server's known PSK identities.
* This method compares a single client identity to all server identities.
*
* While both the client's offered identities and whether a match was found are public, we should make an attempt
* to keep the server's known identities a secret. We will make comparisons to the server's identities constant
* time (to hide partial matches) and not end the search early when a match is found (to hide the ordering).
*
* Keeping these comparisons constant time is not high priority. There's no known attack using these timings,
* and an attacker could probably guess the server's known identities just by observing the public identities
* sent by clients.
*/
static S2N_RESULT s2n_match_psk_identity(struct s2n_array *known_psks, const struct s2n_blob *wire_identity,
struct s2n_psk **match)
{
RESULT_ENSURE_REF(match);
RESULT_ENSURE_REF(wire_identity);
RESULT_ENSURE_REF(known_psks);
*match = NULL;
for (size_t i = 0; i < known_psks->len; i++) {
struct s2n_psk *psk = NULL;
RESULT_GUARD(s2n_array_get(known_psks, i, (void **) &psk));
RESULT_ENSURE_REF(psk);
RESULT_ENSURE_REF(psk->identity.data);
RESULT_ENSURE_REF(wire_identity->data);
uint32_t compare_size = MIN(wire_identity->size, psk->identity.size);
if (s2n_constant_time_equals(psk->identity.data, wire_identity->data, compare_size)
& (psk->identity.size == wire_identity->size) & (!*match)) {
*match = psk;
}
}
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-4.2.10
*# For PSKs provisioned via NewSessionTicket, a server MUST validate
*# that the ticket age for the selected PSK identity (computed by
*# subtracting ticket_age_add from PskIdentity.obfuscated_ticket_age
*# modulo 2^32) is within a small tolerance of the time since the ticket
*# was issued (see Section 8).
**/
static S2N_RESULT s2n_validate_ticket_lifetime(struct s2n_connection *conn, uint32_t obfuscated_ticket_age, uint32_t ticket_age_add)
{
RESULT_ENSURE_REF(conn);
if (conn->psk_params.type == S2N_PSK_TYPE_EXTERNAL) {
return S2N_RESULT_OK;
}
/* Subtract the ticket_age_add value from the ticket age in milliseconds. The resulting uint32_t value
* may wrap, resulting in the modulo 2^32 operation. */
uint32_t ticket_age_in_millis = obfuscated_ticket_age - ticket_age_add;
uint32_t session_lifetime_in_millis = conn->config->session_state_lifetime_in_nanos / ONE_MILLISEC_IN_NANOS;
RESULT_ENSURE(ticket_age_in_millis < session_lifetime_in_millis, S2N_ERR_INVALID_SESSION_TICKET);
return S2N_RESULT_OK;
}
int s2n_offered_psk_list_choose_psk(struct s2n_offered_psk_list *psk_list, struct s2n_offered_psk *psk)
{
POSIX_ENSURE_REF(psk_list);
POSIX_ENSURE_REF(psk_list->conn);
struct s2n_psk_parameters *psk_params = &psk_list->conn->psk_params;
struct s2n_stuffer ticket_stuffer = { 0 };
if (!psk) {
psk_params->chosen_psk = NULL;
return S2N_SUCCESS;
}
if (psk_params->type == S2N_PSK_TYPE_RESUMPTION && psk_list->conn->config->use_tickets) {
POSIX_GUARD(s2n_stuffer_init(&ticket_stuffer, &psk->identity));
POSIX_GUARD(s2n_stuffer_skip_write(&ticket_stuffer, psk->identity.size));
/* s2n_decrypt_session_ticket appends a new PSK with the decrypted values. */
POSIX_GUARD(s2n_decrypt_session_ticket(psk_list->conn, &ticket_stuffer));
}
struct s2n_psk *chosen_psk = NULL;
POSIX_GUARD_RESULT(s2n_match_psk_identity(&psk_params->psk_list, &psk->identity, &chosen_psk));
POSIX_ENSURE_REF(chosen_psk);
POSIX_GUARD_RESULT(s2n_validate_ticket_lifetime(psk_list->conn, psk->obfuscated_ticket_age, chosen_psk->ticket_age_add));
psk_params->chosen_psk = chosen_psk;
psk_params->chosen_psk_wire_index = psk->wire_index;
return S2N_SUCCESS;
}
struct s2n_offered_psk *s2n_offered_psk_new()
{
DEFER_CLEANUP(struct s2n_blob mem = { 0 }, s2n_free);
PTR_GUARD_POSIX(s2n_alloc(&mem, sizeof(struct s2n_offered_psk)));
PTR_GUARD_POSIX(s2n_blob_zero(&mem));
struct s2n_offered_psk *psk = (struct s2n_offered_psk *) (void *) mem.data;
ZERO_TO_DISABLE_DEFER_CLEANUP(mem);
return psk;
}
int s2n_offered_psk_free(struct s2n_offered_psk **psk)
{
if (psk == NULL) {
return S2N_SUCCESS;
}
return s2n_free_object((uint8_t **) psk, sizeof(struct s2n_offered_psk));
}
int s2n_offered_psk_get_identity(struct s2n_offered_psk *psk, uint8_t **identity, uint16_t *size)
{
POSIX_ENSURE_REF(psk);
POSIX_ENSURE_REF(identity);
POSIX_ENSURE_REF(size);
*identity = psk->identity.data;
*size = psk->identity.size;
return S2N_SUCCESS;
}
/* The binder hash is computed by hashing the concatenation of the current transcript
* and a partial ClientHello that does not include the binders themselves.
*/
int s2n_psk_calculate_binder_hash(struct s2n_connection *conn, s2n_hmac_algorithm hmac_alg,
const struct s2n_blob *partial_client_hello, struct s2n_blob *output_binder_hash)
{
POSIX_ENSURE_REF(conn);
POSIX_ENSURE_REF(partial_client_hello);
POSIX_ENSURE_REF(output_binder_hash);
struct s2n_handshake_hashes *hashes = conn->handshake.hashes;
POSIX_ENSURE_REF(hashes);
/* Retrieve the current transcript.
* The current transcript will be empty unless this handshake included a HelloRetryRequest. */
s2n_hash_algorithm hash_alg = S2N_HASH_NONE;
struct s2n_hash_state *hash_state = &hashes->hash_workspace;
POSIX_GUARD(s2n_hmac_hash_alg(hmac_alg, &hash_alg));
POSIX_GUARD_RESULT(s2n_handshake_copy_hash_state(conn, hash_alg, hash_state));
/* Add the partial client hello to the transcript. */
POSIX_GUARD(s2n_hash_update(hash_state, partial_client_hello->data, partial_client_hello->size));
/* Get the transcript digest */
POSIX_GUARD(s2n_hash_digest(hash_state, output_binder_hash->data, output_binder_hash->size));
return S2N_SUCCESS;
}
/* The binder is computed in the same way as the Finished message
* (https://tools.ietf.org/html/rfc8446#section-4.4.4) but with the BaseKey being the binder_key
* derived via the key schedule from the corresponding PSK which is being offered
* (https://tools.ietf.org/html/rfc8446#section-7.1)
*/
int s2n_psk_calculate_binder(struct s2n_psk *psk, const struct s2n_blob *binder_hash,
struct s2n_blob *output_binder)
{
POSIX_ENSURE_REF(psk);
POSIX_ENSURE_REF(binder_hash);
POSIX_ENSURE_REF(output_binder);
DEFER_CLEANUP(struct s2n_tls13_keys psk_keys, s2n_tls13_keys_free);
POSIX_GUARD(s2n_tls13_keys_init(&psk_keys, psk->hmac_alg));
POSIX_ENSURE_EQ(binder_hash->size, psk_keys.size);
POSIX_ENSURE_EQ(output_binder->size, psk_keys.size);
/* Derive the binder key */
POSIX_GUARD_RESULT(s2n_derive_binder_key(psk, &psk_keys.derive_secret));
POSIX_GUARD(s2n_blob_init(&psk_keys.extract_secret, psk->early_secret.data, psk_keys.size));
struct s2n_blob *binder_key = &psk_keys.derive_secret;
/* Expand the binder key into the finished key */
s2n_tls13_key_blob(finished_key, psk_keys.size);
POSIX_GUARD(s2n_tls13_derive_finished_key(&psk_keys, binder_key, &finished_key));
/* HMAC the binder hash with the binder finished key */
POSIX_GUARD(s2n_hkdf_extract(&psk_keys.hmac, psk_keys.hmac_algorithm, &finished_key, binder_hash, output_binder));
return S2N_SUCCESS;
}
int s2n_psk_verify_binder(struct s2n_connection *conn, struct s2n_psk *psk,
const struct s2n_blob *partial_client_hello, struct s2n_blob *binder_to_verify)
{
POSIX_ENSURE_REF(psk);
POSIX_ENSURE_REF(binder_to_verify);
DEFER_CLEANUP(struct s2n_tls13_keys psk_keys, s2n_tls13_keys_free);
POSIX_GUARD(s2n_tls13_keys_init(&psk_keys, psk->hmac_alg));
POSIX_ENSURE_EQ(binder_to_verify->size, psk_keys.size);
/* Calculate the binder hash from the transcript */
s2n_tls13_key_blob(binder_hash, psk_keys.size);
POSIX_GUARD(s2n_psk_calculate_binder_hash(conn, psk->hmac_alg, partial_client_hello, &binder_hash));
/* Calculate the expected binder from the binder hash */
s2n_tls13_key_blob(expected_binder, psk_keys.size);
POSIX_GUARD(s2n_psk_calculate_binder(psk, &binder_hash, &expected_binder));
/* Verify the expected binder matches the given binder.
* This operation must be constant time. */
POSIX_GUARD(s2n_tls13_mac_verify(&psk_keys, &expected_binder, binder_to_verify));
return S2N_SUCCESS;
}
static S2N_RESULT s2n_psk_write_binder(struct s2n_connection *conn, struct s2n_psk *psk,
const struct s2n_blob *binder_hash, struct s2n_stuffer *out)
{
RESULT_ENSURE_REF(binder_hash);
struct s2n_blob binder = { 0 };
uint8_t binder_data[S2N_TLS13_SECRET_MAX_LEN] = { 0 };
RESULT_GUARD_POSIX(s2n_blob_init(&binder, binder_data, binder_hash->size));
RESULT_GUARD_POSIX(s2n_psk_calculate_binder(psk, binder_hash, &binder));
RESULT_GUARD_POSIX(s2n_stuffer_write_uint8(out, binder.size));
RESULT_GUARD_POSIX(s2n_stuffer_write(out, &binder));
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_psk_write_binder_list(struct s2n_connection *conn, const struct s2n_blob *partial_client_hello,
struct s2n_stuffer *out)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(partial_client_hello);
RESULT_ENSURE_REF(conn->secure);
struct s2n_psk_parameters *psk_params = &conn->psk_params;
struct s2n_array *psk_list = &psk_params->psk_list;
/* Setup memory to hold the binder hashes. We potentially need one for
* every hash algorithm. */
uint8_t binder_hashes_data[S2N_HASH_ALG_COUNT][S2N_TLS13_SECRET_MAX_LEN] = { 0 };
struct s2n_blob binder_hashes[S2N_HASH_ALG_COUNT] = { 0 };
struct s2n_stuffer_reservation binder_list_size = { 0 };
RESULT_GUARD_POSIX(s2n_stuffer_reserve_uint16(out, &binder_list_size));
/* Write binder for every psk */
for (size_t i = 0; i < psk_list->len; i++) {
struct s2n_psk *psk = NULL;
RESULT_GUARD(s2n_array_get(psk_list, i, (void **) &psk));
RESULT_ENSURE_REF(psk);
/**
*= https://tools.ietf.org/rfc/rfc8446#section-4.1.4
*# In addition, in its updated ClientHello, the client SHOULD NOT offer
*# any pre-shared keys associated with a hash other than that of the
*# selected cipher suite. This allows the client to avoid having to
*# compute partial hash transcripts for multiple hashes in the second
*# ClientHello.
*/
if (s2n_is_hello_retry_handshake(conn) && conn->secure->cipher_suite->prf_alg != psk->hmac_alg) {
continue;
}
/* Retrieve or calculate the binder hash. */
struct s2n_blob *binder_hash = &binder_hashes[psk->hmac_alg];
if (binder_hash->size == 0) {
uint8_t hash_size = 0;
RESULT_GUARD_POSIX(s2n_hmac_digest_size(psk->hmac_alg, &hash_size));
RESULT_GUARD_POSIX(s2n_blob_init(binder_hash, binder_hashes_data[psk->hmac_alg], hash_size));
RESULT_GUARD_POSIX(s2n_psk_calculate_binder_hash(conn, psk->hmac_alg, partial_client_hello, binder_hash));
}
RESULT_GUARD(s2n_psk_write_binder(conn, psk, binder_hash, out));
}
RESULT_GUARD_POSIX(s2n_stuffer_write_vector_size(&binder_list_size));
return S2N_RESULT_OK;
}
S2N_RESULT s2n_finish_psk_extension(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
if (!conn->psk_params.binder_list_size) {
return S2N_RESULT_OK;
}
struct s2n_stuffer *client_hello = &conn->handshake.io;
struct s2n_psk_parameters *psk_params = &conn->psk_params;
/* Fill in the correct message size. */
RESULT_GUARD_POSIX(s2n_handshake_finish_header(client_hello));
/* Remove the empty space allocated for the binder list.
* It was originally added to ensure the extension / extension list / message sizes
* were properly calculated. */
RESULT_GUARD_POSIX(s2n_stuffer_wipe_n(client_hello, psk_params->binder_list_size));
/* Store the partial client hello for use in calculating the binder hash. */
struct s2n_blob partial_client_hello = { 0 };
RESULT_GUARD_POSIX(s2n_blob_init(&partial_client_hello, client_hello->blob.data,
s2n_stuffer_data_available(client_hello)));
RESULT_GUARD(s2n_psk_write_binder_list(conn, &partial_client_hello, client_hello));
/* Reset binder list size.
* This is important because the psk extension can be removed during a retry.
*/
conn->psk_params.binder_list_size = 0;
return S2N_RESULT_OK;
}
int s2n_psk_set_hmac(struct s2n_psk *psk, s2n_psk_hmac hmac)
{
POSIX_ENSURE_REF(psk);
switch (hmac) {
case S2N_PSK_HMAC_SHA256:
psk->hmac_alg = S2N_HMAC_SHA256;
break;
case S2N_PSK_HMAC_SHA384:
psk->hmac_alg = S2N_HMAC_SHA384;
break;
default:
POSIX_BAIL(S2N_ERR_HMAC_INVALID_ALGORITHM);
}
return S2N_SUCCESS;
}
S2N_RESULT s2n_connection_set_psk_type(struct s2n_connection *conn, s2n_psk_type type)
{
RESULT_ENSURE_REF(conn);
if (conn->psk_params.psk_list.len != 0) {
RESULT_ENSURE(conn->psk_params.type == type, S2N_ERR_PSK_MODE);
}
conn->psk_params.type = type;
return S2N_RESULT_OK;
}
int s2n_connection_append_psk(struct s2n_connection *conn, struct s2n_psk *input_psk)
{
POSIX_ENSURE_REF(conn);
POSIX_ENSURE_REF(input_psk);
POSIX_GUARD_RESULT(s2n_connection_set_psk_type(conn, input_psk->type));
struct s2n_array *psk_list = &conn->psk_params.psk_list;
/* Check for duplicate identities */
for (uint32_t j = 0; j < psk_list->len; j++) {
struct s2n_psk *existing_psk = NULL;
POSIX_GUARD_RESULT(s2n_array_get(psk_list, j, (void **) &existing_psk));
POSIX_ENSURE_REF(existing_psk);
bool duplicate = existing_psk->identity.size == input_psk->identity.size
&& memcmp(existing_psk->identity.data, input_psk->identity.data, existing_psk->identity.size) == 0;
POSIX_ENSURE(!duplicate, S2N_ERR_DUPLICATE_PSK_IDENTITIES);
}
/* Verify the PSK list will fit in the ClientHello pre_shared_key extension */
if (conn->mode == S2N_CLIENT) {
uint32_t list_size = 0;
POSIX_GUARD_RESULT(s2n_psk_parameters_offered_psks_size(&conn->psk_params, &list_size));
uint32_t psk_size = 0;
POSIX_GUARD_RESULT(s2n_psk_offered_psk_size(input_psk, &psk_size));
POSIX_ENSURE(list_size + psk_size + S2N_EXTENSION_HEADER_LENGTH <= UINT16_MAX, S2N_ERR_OFFERED_PSKS_TOO_LONG);
}
DEFER_CLEANUP(struct s2n_psk new_psk = { 0 }, s2n_psk_wipe);
POSIX_ENSURE(s2n_result_is_ok(s2n_psk_clone(&new_psk, input_psk)), S2N_ERR_INVALID_ARGUMENT);
POSIX_GUARD_RESULT(s2n_array_insert_and_copy(psk_list, psk_list->len, &new_psk));
ZERO_TO_DISABLE_DEFER_CLEANUP(new_psk);
return S2N_SUCCESS;
}
int s2n_config_set_psk_mode(struct s2n_config *config, s2n_psk_mode mode)
{
POSIX_ENSURE_REF(config);
config->psk_mode = mode;
return S2N_SUCCESS;
}
int s2n_connection_set_psk_mode(struct s2n_connection *conn, s2n_psk_mode mode)
{
POSIX_ENSURE_REF(conn);
s2n_psk_type type = 0;
switch (mode) {
case S2N_PSK_MODE_RESUMPTION:
type = S2N_PSK_TYPE_RESUMPTION;
break;
case S2N_PSK_MODE_EXTERNAL:
type = S2N_PSK_TYPE_EXTERNAL;
break;
default:
POSIX_BAIL(S2N_ERR_INVALID_ARGUMENT);
break;
}
POSIX_GUARD_RESULT(s2n_connection_set_psk_type(conn, type));
conn->psk_mode_overridden = true;
return S2N_SUCCESS;
}
int s2n_connection_get_negotiated_psk_identity_length(struct s2n_connection *conn, uint16_t *identity_length)
{
POSIX_ENSURE_REF(conn);
POSIX_ENSURE_REF(identity_length);
struct s2n_psk *chosen_psk = conn->psk_params.chosen_psk;
if (chosen_psk == NULL) {
*identity_length = 0;
} else {
*identity_length = chosen_psk->identity.size;
}
return S2N_SUCCESS;
}
int s2n_connection_get_negotiated_psk_identity(struct s2n_connection *conn, uint8_t *identity,
uint16_t max_identity_length)
{
POSIX_ENSURE_REF(conn);
POSIX_ENSURE_REF(identity);
struct s2n_psk *chosen_psk = conn->psk_params.chosen_psk;
if (chosen_psk == NULL) {
return S2N_SUCCESS;
}
POSIX_ENSURE(chosen_psk->identity.size <= max_identity_length, S2N_ERR_INSUFFICIENT_MEM_SIZE);
POSIX_CHECKED_MEMCPY(identity, chosen_psk->identity.data, chosen_psk->identity.size);
return S2N_SUCCESS;
}
S2N_RESULT s2n_psk_validate_keying_material(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
struct s2n_psk *chosen_psk = conn->psk_params.chosen_psk;
if (!chosen_psk || chosen_psk->type != S2N_PSK_TYPE_RESUMPTION) {
return S2N_RESULT_OK;
}
/*
* The minimum ticket lifetime is 1s, because ticket_lifetime is given
* in seconds and 0 indicates that the ticket should be immediately discarded.
*/
uint32_t min_lifetime = ONE_SEC_IN_NANOS;
uint64_t current_time = 0;
RESULT_GUARD(s2n_config_wall_clock(conn->config, ¤t_time));
RESULT_ENSURE(chosen_psk->keying_material_expiration > current_time + min_lifetime, S2N_ERR_KEYING_MATERIAL_EXPIRED);
return S2N_RESULT_OK;
}
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