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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 "tls/s2n_tls13_secrets.h"
#include "tls/s2n_connection.h"
#include "tls/s2n_key_log.h"
#include "tls/s2n_tls13_handshake.h"
#include "utils/s2n_bitmap.h"
#define S2N_MAX_HASHLEN SHA384_DIGEST_LENGTH
#define CONN_HMAC_ALG(conn) ((conn)->secure->cipher_suite->prf_alg)
#define CONN_SECRETS(conn) ((conn)->secrets.version.tls13)
#define CONN_HASHES(conn) ((conn)->handshake.hashes)
#define CONN_SECRET(conn, secret) ( \
(struct s2n_blob){ .data = CONN_SECRETS(conn).secret, .size = s2n_get_hash_len(CONN_HMAC_ALG(conn)) })
#define CONN_HASH(conn, hash) ( \
(struct s2n_blob){ .data = CONN_HASHES(conn)->hash, .size = s2n_get_hash_len(CONN_HMAC_ALG(conn)) })
#define CONN_FINISHED(conn, mode) ( \
(struct s2n_blob){ .data = (conn)->handshake.mode##_finished, .size = s2n_get_hash_len(CONN_HMAC_ALG(conn)) })
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# If a given secret is not available, then the 0-value consisting of a
*# string of Hash.length bytes set to zeros is used.
*/
static uint8_t zero_value_bytes[S2N_MAX_HASHLEN] = { 0 };
#define ZERO_VALUE(hmac_alg) ( \
(const struct s2n_blob){ .data = zero_value_bytes, .size = s2n_get_hash_len(hmac_alg) })
/**
* When an operation doesn't need an actual transcript hash,
* it uses an empty transcript hash as an input instead.
*
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# Note that in some cases a zero-
*# length Context (indicated by "") is passed to HKDF-Expand-Label
*/
#define EMPTY_CONTEXT(hmac_alg) ( \
(const struct s2n_blob){ .data = s2n_get_empty_context(hmac_alg), .size = s2n_get_hash_len(hmac_alg) })
static uint8_t s2n_get_hash_len(s2n_hmac_algorithm hmac_alg)
{
uint8_t hash_size = 0;
if (s2n_hmac_digest_size(hmac_alg, &hash_size) != S2N_SUCCESS) {
return 0;
}
return hash_size;
}
static uint8_t *s2n_get_empty_context(s2n_hmac_algorithm hmac_alg)
{
static uint8_t sha256_empty_digest[S2N_MAX_HASHLEN] = { 0 };
static uint8_t sha384_empty_digest[S2N_MAX_HASHLEN] = { 0 };
switch (hmac_alg) {
case S2N_HMAC_SHA256:
return sha256_empty_digest;
case S2N_HMAC_SHA384:
return sha384_empty_digest;
default:
return NULL;
}
}
static s2n_hmac_algorithm supported_hmacs[] = {
S2N_HMAC_SHA256,
S2N_HMAC_SHA384
};
S2N_RESULT s2n_tls13_empty_transcripts_init()
{
DEFER_CLEANUP(struct s2n_hash_state hash = { 0 }, s2n_hash_free);
RESULT_GUARD_POSIX(s2n_hash_new(&hash));
s2n_hash_algorithm hash_alg = S2N_HASH_NONE;
for (size_t i = 0; i < s2n_array_len(supported_hmacs); i++) {
s2n_hmac_algorithm hmac_alg = supported_hmacs[i];
struct s2n_blob digest = EMPTY_CONTEXT(hmac_alg);
RESULT_GUARD_POSIX(s2n_hmac_hash_alg(hmac_alg, &hash_alg));
RESULT_GUARD_POSIX(s2n_hash_init(&hash, hash_alg));
RESULT_GUARD_POSIX(s2n_hash_digest(&hash, digest.data, digest.size));
}
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_calculate_transcript_digest(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(conn->handshake.hashes);
s2n_hash_algorithm hash_algorithm = S2N_HASH_NONE;
RESULT_GUARD_POSIX(s2n_hmac_hash_alg(CONN_HMAC_ALG(conn), &hash_algorithm));
uint8_t digest_size = 0;
RESULT_GUARD_POSIX(s2n_hash_digest_size(hash_algorithm, &digest_size));
struct s2n_blob digest = { 0 };
RESULT_GUARD_POSIX(s2n_blob_init(&digest, CONN_HASHES(conn)->transcript_hash_digest, digest_size));
struct s2n_hash_state *hash_state = &conn->handshake.hashes->hash_workspace;
RESULT_GUARD(s2n_handshake_copy_hash_state(conn, hash_algorithm, hash_state));
RESULT_GUARD_POSIX(s2n_hash_digest(hash_state, digest.data, digest.size));
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_extract_secret(s2n_hmac_algorithm hmac_alg,
const struct s2n_blob *previous_secret_material, const struct s2n_blob *new_secret_material,
struct s2n_blob *output)
{
/*
* TODO: We should be able to reuse the prf_work_space rather
* than allocating a new HMAC every time.
* https://github.com/aws/s2n-tls/issues/3206
*/
DEFER_CLEANUP(struct s2n_hmac_state hmac_state = { 0 }, s2n_hmac_free);
RESULT_GUARD_POSIX(s2n_hmac_new(&hmac_state));
RESULT_GUARD_POSIX(s2n_hkdf_extract(&hmac_state, hmac_alg,
previous_secret_material, new_secret_material, output));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# Derive-Secret(Secret, Label, Messages) =
*# HKDF-Expand-Label(Secret, Label,
*# Transcript-Hash(Messages), Hash.length)
*/
static S2N_RESULT s2n_derive_secret(s2n_hmac_algorithm hmac_alg,
const struct s2n_blob *previous_secret_material, const struct s2n_blob *label, const struct s2n_blob *context,
struct s2n_blob *output)
{
/*
* TODO: We should be able to reuse the prf_work_space rather
* than allocating a new HMAC every time.
* https://github.com/aws/s2n-tls/issues/3206
*/
DEFER_CLEANUP(struct s2n_hmac_state hmac_state = { 0 }, s2n_hmac_free);
RESULT_GUARD_POSIX(s2n_hmac_new(&hmac_state));
output->size = s2n_get_hash_len(hmac_alg);
RESULT_GUARD_POSIX(s2n_hkdf_expand_label(&hmac_state, hmac_alg,
previous_secret_material, label, context, output));
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_derive_secret_with_context(struct s2n_connection *conn,
s2n_extract_secret_type_t input_secret_type, const struct s2n_blob *label, message_type_t transcript_end_msg,
struct s2n_blob *output)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(label);
RESULT_ENSURE_REF(output);
RESULT_ENSURE(conn->secrets.extract_secret_type == input_secret_type, S2N_ERR_SECRET_SCHEDULE_STATE);
RESULT_ENSURE(s2n_conn_get_current_message_type(conn) == transcript_end_msg, S2N_ERR_SECRET_SCHEDULE_STATE);
RESULT_GUARD(s2n_derive_secret(CONN_HMAC_ALG(conn), &CONN_SECRET(conn, extract_secret),
label, &CONN_HASH(conn, transcript_hash_digest), output));
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_derive_secret_without_context(struct s2n_connection *conn,
s2n_extract_secret_type_t input_secret_type, struct s2n_blob *output)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(output);
RESULT_ENSURE(conn->secrets.extract_secret_type == input_secret_type, S2N_ERR_SECRET_SCHEDULE_STATE);
RESULT_GUARD(s2n_derive_secret(CONN_HMAC_ALG(conn), &CONN_SECRET(conn, extract_secret),
&s2n_tls13_label_derived_secret, &EMPTY_CONTEXT(CONN_HMAC_ALG(conn)), output));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-4.4.4
*# The key used to compute the Finished message is computed from the
*# Base Key defined in Section 4.4 using HKDF (see Section 7.1).
*# Specifically:
*#
*# finished_key =
*# HKDF-Expand-Label(BaseKey, "finished", "", Hash.length)
**/
static S2N_RESULT s2n_tls13_compute_finished_key(struct s2n_connection *conn,
const struct s2n_blob *base_key, struct s2n_blob *output)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(base_key);
RESULT_ENSURE_REF(output);
RESULT_GUARD(s2n_handshake_set_finished_len(conn, output->size));
/*
* TODO: We should be able to reuse the prf_work_space rather
* than allocating a new HMAC every time.
*/
DEFER_CLEANUP(struct s2n_hmac_state hmac_state = { 0 }, s2n_hmac_free);
RESULT_GUARD_POSIX(s2n_hmac_new(&hmac_state));
RESULT_GUARD_POSIX(s2n_hkdf_expand_label(&hmac_state, CONN_HMAC_ALG(conn),
base_key, &s2n_tls13_label_finished, &(struct s2n_blob){ 0 }, output));
return S2N_RESULT_OK;
}
static S2N_RESULT s2n_trigger_secret_callbacks(struct s2n_connection *conn,
const struct s2n_blob *secret, s2n_extract_secret_type_t secret_type, s2n_mode mode)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(secret);
static const s2n_secret_type_t conversions[][2] = {
[S2N_EARLY_SECRET] = { S2N_CLIENT_EARLY_TRAFFIC_SECRET, S2N_CLIENT_EARLY_TRAFFIC_SECRET },
[S2N_HANDSHAKE_SECRET] = { S2N_SERVER_HANDSHAKE_TRAFFIC_SECRET, S2N_CLIENT_HANDSHAKE_TRAFFIC_SECRET },
[S2N_MASTER_SECRET] = { S2N_SERVER_APPLICATION_TRAFFIC_SECRET, S2N_CLIENT_APPLICATION_TRAFFIC_SECRET },
};
s2n_secret_type_t callback_secret_type = conversions[secret_type][mode];
if (conn->secret_cb && (s2n_connection_is_quic_enabled(conn) || s2n_in_unit_test())) {
RESULT_GUARD_POSIX(conn->secret_cb(conn->secret_cb_context, conn, callback_secret_type,
secret->data, secret->size));
}
s2n_result_ignore(s2n_key_log_tls13_secret(conn, secret, callback_secret_type));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# 0
*# |
*# v
*# PSK -> HKDF-Extract = Early Secret
*
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# There are multiple potential Early Secret values, depending on which
*# PSK the server ultimately selects. The client will need to compute
*# one for each potential PSK
*/
S2N_RESULT s2n_extract_early_secret(struct s2n_psk *psk)
{
RESULT_ENSURE_REF(psk);
RESULT_GUARD_POSIX(s2n_realloc(&psk->early_secret, s2n_get_hash_len(psk->hmac_alg)));
RESULT_GUARD(s2n_extract_secret(psk->hmac_alg,
&ZERO_VALUE(psk->hmac_alg),
&psk->secret,
&psk->early_secret));
return S2N_RESULT_OK;
}
/*
* When we require an early secret to derive other secrets,
* either retrieve the early secret stored on the chosen / early data PSK
* or calculate one using a "zero" PSK.
*/
static S2N_RESULT s2n_extract_early_secret_for_schedule(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
struct s2n_psk *psk = conn->psk_params.chosen_psk;
s2n_hmac_algorithm hmac_alg = CONN_HMAC_ALG(conn);
/*
* If the client is sending early data, then the PSK is always assumed
* to be the first PSK offered.
*/
if (conn->mode == S2N_CLIENT && conn->early_data_state == S2N_EARLY_DATA_REQUESTED) {
RESULT_GUARD(s2n_array_get(&conn->psk_params.psk_list, 0, (void **) &psk));
RESULT_ENSURE_REF(psk);
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# if no PSK is selected, it will then need
*# to compute the Early Secret corresponding to the zero PSK.
*/
if (psk == NULL) {
RESULT_GUARD(s2n_extract_secret(hmac_alg,
&ZERO_VALUE(hmac_alg),
&ZERO_VALUE(hmac_alg),
&CONN_SECRET(conn, extract_secret)));
return S2N_RESULT_OK;
}
/*
* The early secret is required to generate or verify a PSK's binder,
* so must have already been calculated if a valid PSK exists.
* Use the early secret stored on the PSK.
*/
RESULT_ENSURE_EQ(hmac_alg, psk->hmac_alg);
RESULT_CHECKED_MEMCPY(CONN_SECRETS(conn).extract_secret, psk->early_secret.data, psk->early_secret.size);
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# |
*# +-----> Derive-Secret(., "ext binder" | "res binder", "")
*# | = binder_key
*/
S2N_RESULT s2n_derive_binder_key(struct s2n_psk *psk, struct s2n_blob *output)
{
RESULT_ENSURE_REF(psk);
RESULT_ENSURE_REF(output);
const struct s2n_blob *label = &s2n_tls13_label_resumption_psk_binder_key;
if (psk->type == S2N_PSK_TYPE_EXTERNAL) {
label = &s2n_tls13_label_external_psk_binder_key;
}
RESULT_GUARD(s2n_extract_early_secret(psk));
RESULT_GUARD(s2n_derive_secret(psk->hmac_alg,
&psk->early_secret,
label,
&EMPTY_CONTEXT(psk->hmac_alg),
output));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# |
*# +-----> Derive-Secret(., "c e traffic", ClientHello)
*# | = client_early_traffic_secret
*/
static S2N_RESULT s2n_derive_client_early_traffic_secret(struct s2n_connection *conn, struct s2n_blob *output)
{
RESULT_GUARD(s2n_derive_secret_with_context(conn,
S2N_EARLY_SECRET,
&s2n_tls13_label_client_early_traffic_secret,
CLIENT_HELLO,
output));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# |
*# v
*# Derive-Secret(., "derived", "")
*# |
*# v
*# (EC)DHE -> HKDF-Extract = Handshake Secret
*/
static S2N_RESULT s2n_extract_handshake_secret(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
struct s2n_blob derived_secret = { 0 };
uint8_t derived_secret_bytes[S2N_TLS13_SECRET_MAX_LEN] = { 0 };
RESULT_GUARD_POSIX(s2n_blob_init(&derived_secret, derived_secret_bytes, S2N_TLS13_SECRET_MAX_LEN));
RESULT_GUARD(s2n_derive_secret_without_context(conn, S2N_EARLY_SECRET, &derived_secret));
DEFER_CLEANUP(struct s2n_blob shared_secret = { 0 }, s2n_free_or_wipe);
RESULT_GUARD_POSIX(s2n_tls13_compute_shared_secret(conn, &shared_secret));
RESULT_GUARD(s2n_extract_secret(CONN_HMAC_ALG(conn),
&derived_secret,
&shared_secret,
&CONN_SECRET(conn, extract_secret)));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# |
*# +-----> Derive-Secret(., "c hs traffic",
*# | ClientHello...ServerHello)
*# | = client_handshake_traffic_secret
*/
static S2N_RESULT s2n_derive_client_handshake_traffic_secret(struct s2n_connection *conn, struct s2n_blob *output)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(output);
RESULT_GUARD(s2n_derive_secret_with_context(conn,
S2N_HANDSHAKE_SECRET,
&s2n_tls13_label_client_handshake_traffic_secret,
SERVER_HELLO,
output));
/*
* The client finished key needs to be calculated using the
* same connection state as the client handshake secret.
*
*= https://tools.ietf.org/rfc/rfc8446#section-4.4.4
*# The key used to compute the Finished message is computed from the
*# Base Key defined in Section 4.4 using HKDF (see Section 7.1).
*/
RESULT_GUARD(s2n_tls13_compute_finished_key(conn,
output, &CONN_FINISHED(conn, client)));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# |
*# +-----> Derive-Secret(., "s hs traffic",
*# | ClientHello...ServerHello)
*# | = server_handshake_traffic_secret
*/
static S2N_RESULT s2n_derive_server_handshake_traffic_secret(struct s2n_connection *conn, struct s2n_blob *output)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(output);
RESULT_GUARD(s2n_derive_secret_with_context(conn,
S2N_HANDSHAKE_SECRET,
&s2n_tls13_label_server_handshake_traffic_secret,
SERVER_HELLO,
output));
/*
* The server finished key needs to be calculated using the
* same connection state as the server handshake secret.
*
*= https://tools.ietf.org/rfc/rfc8446#section-4.4.4
*# The key used to compute the Finished message is computed from the
*# Base Key defined in Section 4.4 using HKDF (see Section 7.1).
*/
RESULT_GUARD(s2n_tls13_compute_finished_key(conn,
output, &CONN_FINISHED(conn, server)));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# v
*# Derive-Secret(., "derived", "")
*# |
*# v
*# 0 -> HKDF-Extract = Master Secret
*/
static S2N_RESULT s2n_extract_master_secret(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
struct s2n_blob derived_secret = { 0 };
uint8_t derived_secret_bytes[S2N_TLS13_SECRET_MAX_LEN] = { 0 };
RESULT_GUARD_POSIX(s2n_blob_init(&derived_secret, derived_secret_bytes, S2N_TLS13_SECRET_MAX_LEN));
RESULT_GUARD(s2n_derive_secret_without_context(conn, S2N_HANDSHAKE_SECRET, &derived_secret));
RESULT_GUARD(s2n_extract_secret(CONN_HMAC_ALG(conn),
&derived_secret,
&ZERO_VALUE(CONN_HMAC_ALG(conn)),
&CONN_SECRET(conn, extract_secret)));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# |
*# +-----> Derive-Secret(., "c ap traffic",
*# | ClientHello...server Finished)
*# | = client_application_traffic_secret_0
*/
static S2N_RESULT s2n_derive_client_application_traffic_secret(struct s2n_connection *conn, struct s2n_blob *output)
{
RESULT_GUARD(s2n_derive_secret_with_context(conn,
S2N_MASTER_SECRET,
&s2n_tls13_label_client_application_traffic_secret,
SERVER_FINISHED,
output));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# |
*# +-----> Derive-Secret(., "s ap traffic",
*# | ClientHello...server Finished)
*# | = server_application_traffic_secret_0
*/
static S2N_RESULT s2n_derive_server_application_traffic_secret(struct s2n_connection *conn, struct s2n_blob *output)
{
RESULT_GUARD(s2n_derive_secret_with_context(conn,
S2N_MASTER_SECRET,
&s2n_tls13_label_server_application_traffic_secret,
SERVER_FINISHED,
output));
return S2N_RESULT_OK;
}
/**
*= https://tools.ietf.org/rfc/rfc8446#section-7.1
*# |
*# +-----> Derive-Secret(., "res master",
*# ClientHello...client Finished)
*# = resumption_master_secret
*/
S2N_RESULT s2n_derive_resumption_master_secret(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
/* Secret derivation requires these fields to be non-null. */
RESULT_ENSURE_REF(conn->secure);
RESULT_ENSURE_REF(conn->secure->cipher_suite);
RESULT_GUARD(s2n_derive_secret_with_context(conn,
S2N_MASTER_SECRET,
&s2n_tls13_label_resumption_master_secret,
CLIENT_FINISHED,
&CONN_SECRET(conn, resumption_master_secret)));
return S2N_RESULT_OK;
}
static s2n_result (*extract_methods[])(struct s2n_connection *conn) = {
[S2N_EARLY_SECRET] = &s2n_extract_early_secret_for_schedule,
[S2N_HANDSHAKE_SECRET] = &s2n_extract_handshake_secret,
[S2N_MASTER_SECRET] = &s2n_extract_master_secret,
};
S2N_RESULT s2n_tls13_extract_secret(struct s2n_connection *conn, s2n_extract_secret_type_t secret_type)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(conn->secure);
RESULT_ENSURE_REF(conn->secure->cipher_suite);
RESULT_ENSURE_REF(conn->handshake.hashes);
RESULT_ENSURE_NE(secret_type, S2N_NONE_SECRET);
RESULT_ENSURE_GTE(secret_type, 0);
RESULT_ENSURE_LT(secret_type, s2n_array_len(extract_methods));
s2n_extract_secret_type_t next_secret_type = conn->secrets.extract_secret_type + 1;
for (s2n_extract_secret_type_t i = next_secret_type; i <= secret_type; i++) {
RESULT_ENSURE_REF(extract_methods[i]);
RESULT_GUARD(extract_methods[i](conn));
conn->secrets.extract_secret_type = i;
}
return S2N_RESULT_OK;
}
static s2n_result (*derive_methods[][2])(struct s2n_connection *conn, struct s2n_blob *secret) = {
[S2N_EARLY_SECRET] = { &s2n_derive_client_early_traffic_secret, &s2n_derive_client_early_traffic_secret },
[S2N_HANDSHAKE_SECRET] = { &s2n_derive_server_handshake_traffic_secret, &s2n_derive_client_handshake_traffic_secret },
[S2N_MASTER_SECRET] = { &s2n_derive_server_application_traffic_secret, &s2n_derive_client_application_traffic_secret },
};
S2N_RESULT s2n_tls13_derive_secret(struct s2n_connection *conn, s2n_extract_secret_type_t secret_type,
s2n_mode mode, struct s2n_blob *secret)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(secret);
RESULT_ENSURE_REF(conn->secure);
RESULT_ENSURE_REF(conn->secure->cipher_suite);
RESULT_ENSURE_REF(conn->handshake.hashes);
RESULT_ENSURE_NE(secret_type, S2N_NONE_SECRET);
RESULT_GUARD(s2n_tls13_extract_secret(conn, secret_type));
RESULT_ENSURE_GTE(secret_type, 0);
RESULT_ENSURE_LT(secret_type, s2n_array_len(derive_methods));
RESULT_ENSURE_REF(derive_methods[secret_type][mode]);
RESULT_GUARD(derive_methods[secret_type][mode](conn, secret));
RESULT_GUARD(s2n_trigger_secret_callbacks(conn, secret, secret_type, mode));
return S2N_RESULT_OK;
}
S2N_RESULT s2n_tls13_secrets_clean(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
/* Secret clean requires these fields to be non-null. */
RESULT_ENSURE_REF(conn->secure);
RESULT_ENSURE_REF(conn->secure->cipher_suite);
if (conn->actual_protocol_version < S2N_TLS13) {
return S2N_RESULT_OK;
}
/*
* Wipe base secrets.
* Not strictly necessary, but probably safer than leaving them.
* A compromised secret additionally compromises all secrets derived from it,
* so these are the most sensitive secrets.
*/
RESULT_GUARD_POSIX(s2n_blob_zero(&CONN_SECRET(conn, extract_secret)));
conn->secrets.extract_secret_type = S2N_NONE_SECRET;
/* Wipe other secrets no longer needed */
RESULT_GUARD_POSIX(s2n_blob_zero(&CONN_SECRET(conn, client_early_secret)));
RESULT_GUARD_POSIX(s2n_blob_zero(&CONN_SECRET(conn, client_handshake_secret)));
RESULT_GUARD_POSIX(s2n_blob_zero(&CONN_SECRET(conn, server_handshake_secret)));
return S2N_RESULT_OK;
}
S2N_RESULT s2n_tls13_secrets_update(struct s2n_connection *conn)
{
RESULT_ENSURE_REF(conn);
if (s2n_connection_get_protocol_version(conn) < S2N_TLS13) {
return S2N_RESULT_OK;
}
/* Secret update requires these fields to be non-null. */
RESULT_ENSURE_REF(conn->secure);
RESULT_ENSURE_REF(conn->secure->cipher_suite);
message_type_t message_type = s2n_conn_get_current_message_type(conn);
switch (message_type) {
case CLIENT_HELLO:
if (conn->early_data_state == S2N_EARLY_DATA_REQUESTED
|| conn->early_data_state == S2N_EARLY_DATA_ACCEPTED) {
RESULT_GUARD(s2n_calculate_transcript_digest(conn));
RESULT_GUARD(s2n_tls13_derive_secret(conn, S2N_EARLY_SECRET,
S2N_CLIENT, &CONN_SECRET(conn, client_early_secret)));
}
break;
case SERVER_HELLO:
RESULT_GUARD(s2n_calculate_transcript_digest(conn));
RESULT_GUARD(s2n_tls13_derive_secret(conn, S2N_HANDSHAKE_SECRET,
S2N_CLIENT, &CONN_SECRET(conn, client_handshake_secret)));
RESULT_GUARD(s2n_tls13_derive_secret(conn, S2N_HANDSHAKE_SECRET,
S2N_SERVER, &CONN_SECRET(conn, server_handshake_secret)));
break;
case SERVER_FINISHED:
RESULT_GUARD(s2n_calculate_transcript_digest(conn));
RESULT_GUARD(s2n_tls13_derive_secret(conn, S2N_MASTER_SECRET,
S2N_CLIENT, &CONN_SECRET(conn, client_app_secret)));
RESULT_GUARD(s2n_tls13_derive_secret(conn, S2N_MASTER_SECRET,
S2N_SERVER, &CONN_SECRET(conn, server_app_secret)));
break;
case CLIENT_FINISHED:
RESULT_GUARD(s2n_calculate_transcript_digest(conn));
RESULT_GUARD(s2n_derive_resumption_master_secret(conn));
break;
default:
break;
}
return S2N_RESULT_OK;
}
S2N_RESULT s2n_tls13_secrets_get(struct s2n_connection *conn, s2n_extract_secret_type_t secret_type,
s2n_mode mode, struct s2n_blob *secret)
{
RESULT_ENSURE_REF(conn);
RESULT_ENSURE_REF(secret);
/* Getting secrets requires these fields to be non-null. */
RESULT_ENSURE_REF(conn->secure);
RESULT_ENSURE_REF(conn->secure->cipher_suite);
uint8_t *secrets[][2] = {
[S2N_EARLY_SECRET] = { NULL, CONN_SECRETS(conn).client_early_secret },
[S2N_HANDSHAKE_SECRET] = { CONN_SECRETS(conn).server_handshake_secret, CONN_SECRETS(conn).client_handshake_secret },
[S2N_MASTER_SECRET] = { CONN_SECRETS(conn).server_app_secret, CONN_SECRETS(conn).client_app_secret },
};
RESULT_ENSURE_GT(secret_type, S2N_NONE_SECRET);
RESULT_ENSURE_LT(secret_type, s2n_array_len(secrets));
RESULT_ENSURE_LTE(secret_type, conn->secrets.extract_secret_type);
RESULT_ENSURE_REF(secrets[secret_type][mode]);
secret->size = s2n_get_hash_len(CONN_HMAC_ALG(conn));
RESULT_CHECKED_MEMCPY(secret->data, secrets[secret_type][mode], secret->size);
RESULT_ENSURE_GT(secret->size, 0);
return S2N_RESULT_OK;
}
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