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|
/**
* Copyright Amazon.com, Inc. or its affiliates. All Rights Reserved.
* SPDX-License-Identifier: Apache-2.0.
*/
#include <aws/io/tls_channel_handler.h>
#include <aws/common/clock.h>
#include <aws/common/mutex.h>
#include <aws/io/channel.h>
#include <aws/io/event_loop.h>
#include <aws/io/file_utils.h>
#include <aws/io/logging.h>
#include <aws/io/private/pki_utils.h>
#include <aws/io/private/tls_channel_handler_shared.h>
#include <aws/io/statistics.h>
#include <aws/common/encoding.h>
#include <aws/common/string.h>
#include <aws/common/task_scheduler.h>
#include <aws/common/thread.h>
#include <errno.h>
#include <inttypes.h>
#include <math.h>
#include <s2n.h>
#include <stdio.h>
#include <stdlib.h>
#define EST_TLS_RECORD_OVERHEAD 53 /* 5 byte header + 32 + 16 bytes for padding */
#define KB_1 1024
#define MAX_RECORD_SIZE (KB_1 * 16)
#define EST_HANDSHAKE_SIZE (7 * KB_1)
static const char *s_default_ca_dir = NULL;
static const char *s_default_ca_file = NULL;
struct s2n_delayed_shutdown_task {
struct aws_channel_task task;
struct aws_channel_slot *slot;
int error;
};
struct s2n_handler {
struct aws_channel_handler handler;
struct aws_tls_channel_handler_shared shared_state;
struct s2n_connection *connection;
struct s2n_ctx *s2n_ctx;
struct aws_channel_slot *slot;
struct aws_linked_list input_queue;
struct aws_byte_buf protocol;
struct aws_byte_buf server_name;
aws_channel_on_message_write_completed_fn *latest_message_on_completion;
struct aws_channel_task sequential_tasks;
void *latest_message_completion_user_data;
aws_tls_on_negotiation_result_fn *on_negotiation_result;
aws_tls_on_data_read_fn *on_data_read;
aws_tls_on_error_fn *on_error;
void *user_data;
bool advertise_alpn_message;
enum {
NEGOTIATION_ONGOING,
NEGOTIATION_FAILED,
NEGOTIATION_SUCCEEDED,
} state;
struct s2n_delayed_shutdown_task delayed_shutdown_task;
};
struct s2n_ctx {
struct aws_tls_ctx ctx;
struct s2n_config *s2n_config;
/* Only used in special circumstances (ex: have cert but no key, because key is in PKCS#11) */
struct s2n_cert_chain_and_key *custom_cert_chain_and_key;
/**
* Custom key operations to perform when a private key operation is required in the TLS handshake.
* Only will be used if non-NULL, otherwise this is ignored and the standard private key operations
* are performed instead.
* NOTE: PKCS11 also is done via this custom_key_handler.
*
* See aws_custom_key_op_handler in tls_channel_handler.h for more details.
*/
struct aws_custom_key_op_handler *custom_key_handler;
};
struct aws_tls_key_operation {
struct aws_allocator *alloc;
struct s2n_async_pkey_op *s2n_op;
struct s2n_handler *s2n_handler;
enum aws_tls_key_operation_type operation_type;
enum aws_tls_signature_algorithm signature_algorithm;
enum aws_tls_hash_algorithm digest_algorithm;
struct aws_byte_buf input_data;
struct aws_channel_task completion_task;
int completion_error_code;
struct aws_atomic_var complete_count;
};
AWS_STATIC_STRING_FROM_LITERAL(s_debian_path, "/etc/ssl/certs");
AWS_STATIC_STRING_FROM_LITERAL(s_rhel_path, "/etc/pki/tls/certs");
AWS_STATIC_STRING_FROM_LITERAL(s_android_path, "/system/etc/security/cacerts");
AWS_STATIC_STRING_FROM_LITERAL(s_free_bsd_path, "/usr/local/share/certs");
AWS_STATIC_STRING_FROM_LITERAL(s_net_bsd_path, "/etc/openssl/certs");
AWS_IO_API const char *aws_determine_default_pki_dir(void) {
/* debian variants; OpenBSD (although the directory doesn't exist by default) */
if (aws_path_exists(s_debian_path)) {
return aws_string_c_str(s_debian_path);
}
/* RHEL variants */
if (aws_path_exists(s_rhel_path)) {
return aws_string_c_str(s_rhel_path);
}
/* android */
if (aws_path_exists(s_android_path)) {
return aws_string_c_str(s_android_path);
}
/* FreeBSD */
if (aws_path_exists(s_free_bsd_path)) {
return aws_string_c_str(s_free_bsd_path);
}
/* NetBSD */
if (aws_path_exists(s_net_bsd_path)) {
return aws_string_c_str(s_net_bsd_path);
}
return NULL;
}
AWS_STATIC_STRING_FROM_LITERAL(s_debian_ca_file_path, "/etc/ssl/certs/ca-certificates.crt");
AWS_STATIC_STRING_FROM_LITERAL(s_old_rhel_ca_file_path, "/etc/pki/tls/certs/ca-bundle.crt");
AWS_STATIC_STRING_FROM_LITERAL(s_open_suse_ca_file_path, "/etc/ssl/ca-bundle.pem");
AWS_STATIC_STRING_FROM_LITERAL(s_open_elec_ca_file_path, "/etc/pki/tls/cacert.pem");
AWS_STATIC_STRING_FROM_LITERAL(s_modern_rhel_ca_file_path, "/etc/pki/ca-trust/extracted/pem/tls-ca-bundle.pem");
AWS_STATIC_STRING_FROM_LITERAL(s_openbsd_ca_file_path, "/etc/ssl/cert.pem");
AWS_IO_API const char *aws_determine_default_pki_ca_file(void) {
/* debian variants */
if (aws_path_exists(s_debian_ca_file_path)) {
return aws_string_c_str(s_debian_ca_file_path);
}
/* Old RHEL variants */
if (aws_path_exists(s_old_rhel_ca_file_path)) {
return aws_string_c_str(s_old_rhel_ca_file_path);
}
/* Open SUSE */
if (aws_path_exists(s_open_suse_ca_file_path)) {
return aws_string_c_str(s_open_suse_ca_file_path);
}
/* Open ELEC */
if (aws_path_exists(s_open_elec_ca_file_path)) {
return aws_string_c_str(s_open_elec_ca_file_path);
}
/* Modern RHEL variants */
if (aws_path_exists(s_modern_rhel_ca_file_path)) {
return aws_string_c_str(s_modern_rhel_ca_file_path);
}
/* OpenBSD */
if (aws_path_exists(s_openbsd_ca_file_path)) {
return aws_string_c_str(s_openbsd_ca_file_path);
}
return NULL;
}
/* If s2n is already initialized, then we don't call s2n_init() or s2n_cleanup() ourselves */
static bool s_s2n_initialized_externally = false;
void aws_tls_init_static_state(struct aws_allocator *alloc) {
(void)alloc;
AWS_LOGF_INFO(AWS_LS_IO_TLS, "static: Initializing TLS using s2n.");
/* Disable atexit behavior, so that s2n_cleanup() fully cleans things up.
*
* By default, s2n uses an ataexit handler and doesn't fully clean up until the program exits.
* This can cause a crash if s2n is compiled into a shared library and
* that library is unloaded before the appexit handler runs. */
if (s2n_disable_atexit() != S2N_SUCCESS) {
/* If this call fails, then s2n is already initialized
* https://github.com/aws/s2n-tls/blob/2ad65c11a96368591fe809cd27fd1e390b2c8ce3/api/s2n.h#L211-L212 */
AWS_LOGF_DEBUG(AWS_LS_IO_TLS, "static: s2n is already initialized");
s_s2n_initialized_externally = true;
} else {
s_s2n_initialized_externally = false;
}
if (!s_s2n_initialized_externally) {
setenv("S2N_DONT_MLOCK", "1", 1);
if (s2n_init() != S2N_SUCCESS) {
fprintf(stderr, "s2n_init() failed: %d (%s)\n", s2n_errno, s2n_strerror(s2n_errno, "EN"));
AWS_FATAL_ASSERT(0 && "s2n_init() failed");
}
}
s_default_ca_dir = aws_determine_default_pki_dir();
s_default_ca_file = aws_determine_default_pki_ca_file();
if (s_default_ca_dir || s_default_ca_file) {
AWS_LOGF_DEBUG(
AWS_LS_IO_TLS,
"ctx: Based on OS, we detected the default PKI path as %s, and ca file as %s",
s_default_ca_dir,
s_default_ca_file);
} else {
AWS_LOGF_WARN(
AWS_LS_IO_TLS,
"Default TLS trust store not found on this system."
" TLS connections will fail unless trusted CA certificates are installed,"
" or \"override default trust store\" is used while creating the TLS context.");
}
}
void aws_tls_clean_up_static_state(void) {
/* only clean up s2n if we were the ones that initialized it */
if (!s_s2n_initialized_externally) {
s2n_cleanup();
}
}
bool aws_tls_is_alpn_available(void) {
return true;
}
bool aws_tls_is_cipher_pref_supported(enum aws_tls_cipher_pref cipher_pref) {
switch (cipher_pref) {
case AWS_IO_TLS_CIPHER_PREF_SYSTEM_DEFAULT:
return true;
/* PQ Crypto no-ops on android for now */
#ifndef ANDROID
case AWS_IO_TLS_CIPHER_PREF_PQ_TLSv1_0_2021_05:
return true;
#endif
default:
return false;
}
}
static int s_generic_read(struct s2n_handler *handler, struct aws_byte_buf *buf) {
size_t written = 0;
while (!aws_linked_list_empty(&handler->input_queue) && written < buf->len) {
struct aws_linked_list_node *node = aws_linked_list_pop_front(&handler->input_queue);
struct aws_io_message *message = AWS_CONTAINER_OF(node, struct aws_io_message, queueing_handle);
size_t remaining_message_len = message->message_data.len - message->copy_mark;
size_t remaining_buf_len = buf->len - written;
size_t to_write = remaining_message_len < remaining_buf_len ? remaining_message_len : remaining_buf_len;
struct aws_byte_cursor message_cursor = aws_byte_cursor_from_buf(&message->message_data);
aws_byte_cursor_advance(&message_cursor, message->copy_mark);
aws_byte_cursor_read(&message_cursor, buf->buffer + written, to_write);
written += to_write;
message->copy_mark += to_write;
if (message->copy_mark == message->message_data.len) {
aws_mem_release(message->allocator, message);
} else {
aws_linked_list_push_front(&handler->input_queue, &message->queueing_handle);
}
}
if (written) {
return (int)written;
}
errno = EAGAIN;
return -1;
}
static int s_s2n_handler_recv(void *io_context, uint8_t *buf, uint32_t len) {
struct s2n_handler *handler = (struct s2n_handler *)io_context;
struct aws_byte_buf read_buffer = aws_byte_buf_from_array(buf, len);
return s_generic_read(handler, &read_buffer);
}
static int s_generic_send(struct s2n_handler *handler, struct aws_byte_buf *buf) {
struct aws_byte_cursor buffer_cursor = aws_byte_cursor_from_buf(buf);
size_t processed = 0;
while (processed < buf->len) {
const size_t overhead = aws_channel_slot_upstream_message_overhead(handler->slot);
const size_t message_size_hint = (buf->len - processed) + overhead;
struct aws_io_message *message = aws_channel_acquire_message_from_pool(
handler->slot->channel, AWS_IO_MESSAGE_APPLICATION_DATA, message_size_hint);
if (!message || message->message_data.capacity <= overhead) {
errno = ENOMEM;
return -1;
}
const size_t available_msg_write_capacity = message->message_data.capacity - overhead;
const size_t to_write =
available_msg_write_capacity >= buffer_cursor.len ? buffer_cursor.len : available_msg_write_capacity;
struct aws_byte_cursor chunk = aws_byte_cursor_advance(&buffer_cursor, to_write);
if (aws_byte_buf_append(&message->message_data, &chunk)) {
aws_mem_release(message->allocator, message);
return -1;
}
processed += message->message_data.len;
if (processed == buf->len) {
message->on_completion = handler->latest_message_on_completion;
message->user_data = handler->latest_message_completion_user_data;
handler->latest_message_on_completion = NULL;
handler->latest_message_completion_user_data = NULL;
}
if (aws_channel_slot_send_message(handler->slot, message, AWS_CHANNEL_DIR_WRITE)) {
aws_mem_release(message->allocator, message);
errno = EPIPE;
return -1;
}
}
if (processed) {
return (int)processed;
}
errno = EAGAIN;
return -1;
}
static int s_s2n_handler_send(void *io_context, const uint8_t *buf, uint32_t len) {
struct s2n_handler *handler = (struct s2n_handler *)io_context;
struct aws_byte_buf send_buf = aws_byte_buf_from_array(buf, len);
return s_generic_send(handler, &send_buf);
}
static void s_s2n_handler_destroy(struct aws_channel_handler *handler) {
if (handler) {
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
aws_tls_channel_handler_shared_clean_up(&s2n_handler->shared_state);
if (s2n_handler->connection) {
s2n_connection_free(s2n_handler->connection);
}
if (s2n_handler->s2n_ctx) {
aws_tls_ctx_release(&s2n_handler->s2n_ctx->ctx);
}
aws_mem_release(handler->alloc, (void *)s2n_handler);
}
}
static void s_on_negotiation_result(
struct aws_channel_handler *handler,
struct aws_channel_slot *slot,
int error_code,
void *user_data) {
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
aws_on_tls_negotiation_completed(&s2n_handler->shared_state, error_code);
if (s2n_handler->on_negotiation_result) {
s2n_handler->on_negotiation_result(handler, slot, error_code, user_data);
}
}
static int s_drive_negotiation(struct aws_channel_handler *handler) {
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
AWS_ASSERT(s2n_handler->state == NEGOTIATION_ONGOING);
aws_on_drive_tls_negotiation(&s2n_handler->shared_state);
s2n_blocked_status blocked = S2N_NOT_BLOCKED;
do {
int negotiation_code = s2n_negotiate(s2n_handler->connection, &blocked);
int s2n_error = s2n_errno;
if (negotiation_code == S2N_ERR_T_OK) {
s2n_handler->state = NEGOTIATION_SUCCEEDED;
const char *protocol = s2n_get_application_protocol(s2n_handler->connection);
if (protocol) {
AWS_LOGF_DEBUG(AWS_LS_IO_TLS, "id=%p: Alpn protocol negotiated as %s", (void *)handler, protocol);
s2n_handler->protocol = aws_byte_buf_from_c_str(protocol);
}
const char *server_name = s2n_get_server_name(s2n_handler->connection);
if (server_name) {
AWS_LOGF_DEBUG(AWS_LS_IO_TLS, "id=%p: Remote server name is %s", (void *)handler, server_name);
s2n_handler->server_name = aws_byte_buf_from_c_str(server_name);
}
if (s2n_handler->slot->adj_right && s2n_handler->advertise_alpn_message && protocol) {
struct aws_io_message *message = aws_channel_acquire_message_from_pool(
s2n_handler->slot->channel,
AWS_IO_MESSAGE_APPLICATION_DATA,
sizeof(struct aws_tls_negotiated_protocol_message));
message->message_tag = AWS_TLS_NEGOTIATED_PROTOCOL_MESSAGE;
struct aws_tls_negotiated_protocol_message *protocol_message =
(struct aws_tls_negotiated_protocol_message *)message->message_data.buffer;
protocol_message->protocol = s2n_handler->protocol;
message->message_data.len = sizeof(struct aws_tls_negotiated_protocol_message);
if (aws_channel_slot_send_message(s2n_handler->slot, message, AWS_CHANNEL_DIR_READ)) {
aws_mem_release(message->allocator, message);
aws_channel_shutdown(s2n_handler->slot->channel, aws_last_error());
return AWS_OP_SUCCESS;
}
}
s_on_negotiation_result(handler, s2n_handler->slot, AWS_OP_SUCCESS, s2n_handler->user_data);
break;
}
if (s2n_error_get_type(s2n_error) != S2N_ERR_T_BLOCKED) {
AWS_LOGF_WARN(
AWS_LS_IO_TLS,
"id=%p: negotiation failed with error %s (%s)",
(void *)handler,
s2n_strerror(s2n_error, "EN"),
s2n_strerror_debug(s2n_error, "EN"));
if (s2n_error_get_type(s2n_error) == S2N_ERR_T_ALERT) {
AWS_LOGF_DEBUG(
AWS_LS_IO_TLS,
"id=%p: Alert code %d",
(void *)handler,
s2n_connection_get_alert(s2n_handler->connection));
}
const char *err_str = s2n_strerror_debug(s2n_error, NULL);
(void)err_str;
s2n_handler->state = NEGOTIATION_FAILED;
aws_raise_error(AWS_IO_TLS_ERROR_NEGOTIATION_FAILURE);
s_on_negotiation_result(
handler, s2n_handler->slot, AWS_IO_TLS_ERROR_NEGOTIATION_FAILURE, s2n_handler->user_data);
return AWS_OP_ERR;
}
} while (blocked == S2N_NOT_BLOCKED);
return AWS_OP_SUCCESS;
}
static void s_negotiation_task(struct aws_channel_task *task, void *arg, aws_task_status status) {
task->task_fn = NULL;
task->arg = NULL;
if (status == AWS_TASK_STATUS_RUN_READY) {
struct aws_channel_handler *handler = arg;
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
if (s2n_handler->state == NEGOTIATION_ONGOING) {
s_drive_negotiation(handler);
}
}
}
int aws_tls_client_handler_start_negotiation(struct aws_channel_handler *handler) {
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
AWS_LOGF_TRACE(AWS_LS_IO_TLS, "id=%p: Kicking off TLS negotiation.", (void *)handler);
if (aws_channel_thread_is_callers_thread(s2n_handler->slot->channel)) {
if (s2n_handler->state == NEGOTIATION_ONGOING) {
s_drive_negotiation(handler);
}
return AWS_OP_SUCCESS;
}
aws_channel_task_init(
&s2n_handler->sequential_tasks, s_negotiation_task, handler, "s2n_channel_handler_negotiation");
aws_channel_schedule_task_now(s2n_handler->slot->channel, &s2n_handler->sequential_tasks);
return AWS_OP_SUCCESS;
}
static int s_s2n_handler_process_read_message(
struct aws_channel_handler *handler,
struct aws_channel_slot *slot,
struct aws_io_message *message) {
struct s2n_handler *s2n_handler = handler->impl;
if (AWS_UNLIKELY(s2n_handler->state == NEGOTIATION_FAILED)) {
return aws_raise_error(AWS_IO_TLS_ERROR_NEGOTIATION_FAILURE);
}
if (message) {
aws_linked_list_push_back(&s2n_handler->input_queue, &message->queueing_handle);
if (s2n_handler->state == NEGOTIATION_ONGOING) {
size_t message_len = message->message_data.len;
if (!s_drive_negotiation(handler)) {
aws_channel_slot_increment_read_window(slot, message_len);
} else {
aws_channel_shutdown(s2n_handler->slot->channel, AWS_IO_TLS_ERROR_NEGOTIATION_FAILURE);
}
return AWS_OP_SUCCESS;
}
}
s2n_blocked_status blocked = S2N_NOT_BLOCKED;
size_t downstream_window = SIZE_MAX;
if (slot->adj_right) {
downstream_window = aws_channel_slot_downstream_read_window(slot);
}
size_t processed = 0;
AWS_LOGF_TRACE(
AWS_LS_IO_TLS, "id=%p: Downstream window %llu", (void *)handler, (unsigned long long)downstream_window);
while (processed < downstream_window && blocked == S2N_NOT_BLOCKED) {
struct aws_io_message *outgoing_read_message = aws_channel_acquire_message_from_pool(
slot->channel, AWS_IO_MESSAGE_APPLICATION_DATA, downstream_window - processed);
if (!outgoing_read_message) {
return AWS_OP_ERR;
}
ssize_t read = s2n_recv(
s2n_handler->connection,
outgoing_read_message->message_data.buffer,
outgoing_read_message->message_data.capacity,
&blocked);
AWS_LOGF_TRACE(AWS_LS_IO_TLS, "id=%p: Bytes read %lld", (void *)handler, (long long)read);
/* weird race where we received an alert from the peer, but s2n doesn't tell us about it.....
* if this happens, it's a graceful shutdown, so kick it off here.
*
* In other words, s2n, upon graceful shutdown, follows the unix EOF idiom. So just shutdown with
* SUCCESS.
*/
if (read == 0) {
AWS_LOGF_DEBUG(
AWS_LS_IO_TLS,
"id=%p: Alert code %d",
(void *)handler,
s2n_connection_get_alert(s2n_handler->connection));
aws_mem_release(outgoing_read_message->allocator, outgoing_read_message);
aws_channel_shutdown(slot->channel, AWS_OP_SUCCESS);
return AWS_OP_SUCCESS;
}
if (read < 0) {
aws_mem_release(outgoing_read_message->allocator, outgoing_read_message);
continue;
};
processed += read;
outgoing_read_message->message_data.len = (size_t)read;
if (s2n_handler->on_data_read) {
s2n_handler->on_data_read(handler, slot, &outgoing_read_message->message_data, s2n_handler->user_data);
}
if (slot->adj_right) {
aws_channel_slot_send_message(slot, outgoing_read_message, AWS_CHANNEL_DIR_READ);
} else {
aws_mem_release(outgoing_read_message->allocator, outgoing_read_message);
}
}
AWS_LOGF_TRACE(
AWS_LS_IO_TLS,
"id=%p: Remaining window for this event-loop tick: %llu",
(void *)handler,
(unsigned long long)downstream_window - processed);
return AWS_OP_SUCCESS;
}
static int s_s2n_handler_process_write_message(
struct aws_channel_handler *handler,
struct aws_channel_slot *slot,
struct aws_io_message *message) {
(void)slot;
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
if (AWS_UNLIKELY(s2n_handler->state != NEGOTIATION_SUCCEEDED)) {
return aws_raise_error(AWS_IO_TLS_ERROR_NOT_NEGOTIATED);
}
s2n_handler->latest_message_on_completion = message->on_completion;
s2n_handler->latest_message_completion_user_data = message->user_data;
s2n_blocked_status blocked;
ssize_t write_code =
s2n_send(s2n_handler->connection, message->message_data.buffer, (ssize_t)message->message_data.len, &blocked);
AWS_LOGF_TRACE(AWS_LS_IO_TLS, "id=%p: Bytes written: %llu", (void *)handler, (unsigned long long)write_code);
ssize_t message_len = (ssize_t)message->message_data.len;
if (write_code < message_len) {
return aws_raise_error(AWS_IO_TLS_ERROR_WRITE_FAILURE);
}
aws_mem_release(message->allocator, message);
return AWS_OP_SUCCESS;
}
static void s_delayed_shutdown_task_fn(struct aws_channel_task *channel_task, void *arg, enum aws_task_status status) {
(void)channel_task;
struct aws_channel_handler *handler = arg;
struct s2n_handler *s2n_handler = handler->impl;
if (status == AWS_TASK_STATUS_RUN_READY) {
AWS_LOGF_DEBUG(AWS_LS_IO_TLS, "id=%p: Delayed shut down in write direction", (void *)handler);
s2n_blocked_status blocked;
/* make a best effort, but the channel is going away after this run, so.... you only get one shot anyways */
s2n_shutdown(s2n_handler->connection, &blocked);
}
aws_channel_slot_on_handler_shutdown_complete(
s2n_handler->delayed_shutdown_task.slot,
AWS_CHANNEL_DIR_WRITE,
s2n_handler->delayed_shutdown_task.error,
false);
}
static enum aws_tls_signature_algorithm s_s2n_to_aws_signature_algorithm(s2n_tls_signature_algorithm s2n_alg) {
switch (s2n_alg) {
case S2N_TLS_SIGNATURE_RSA:
return AWS_TLS_SIGNATURE_RSA;
case S2N_TLS_SIGNATURE_ECDSA:
return AWS_TLS_SIGNATURE_ECDSA;
default:
return AWS_TLS_SIGNATURE_UNKNOWN;
}
}
static enum aws_tls_hash_algorithm s_s2n_to_aws_hash_algorithm(s2n_tls_hash_algorithm s2n_alg) {
switch (s2n_alg) {
case (S2N_TLS_HASH_SHA1):
return AWS_TLS_HASH_SHA1;
case (S2N_TLS_HASH_SHA224):
return AWS_TLS_HASH_SHA224;
case (S2N_TLS_HASH_SHA256):
return AWS_TLS_HASH_SHA256;
case (S2N_TLS_HASH_SHA384):
return AWS_TLS_HASH_SHA384;
case (S2N_TLS_HASH_SHA512):
return AWS_TLS_HASH_SHA512;
default:
return AWS_TLS_HASH_UNKNOWN;
}
}
static void s_tls_key_operation_destroy(struct aws_tls_key_operation *operation) {
if (operation->s2n_op) {
s2n_async_pkey_op_free(operation->s2n_op);
}
if (operation->s2n_handler) {
aws_channel_release_hold(operation->s2n_handler->slot->channel);
}
aws_byte_buf_clean_up(&operation->input_data);
aws_mem_release(operation->alloc, operation);
}
/* This task finishes a private key operation on the event-loop thread.
* If the operation was successful, TLS negotiation is resumed.
* If the operation failed, the channel is shut down */
static void s_tls_key_operation_completion_task(
struct aws_channel_task *channel_task,
void *arg,
enum aws_task_status status) {
(void)channel_task;
struct aws_tls_key_operation *operation = arg;
struct s2n_handler *s2n_handler = operation->s2n_handler;
struct aws_channel_handler *handler = &s2n_handler->handler;
/* if things started failing since this task was scheduled, just clean up and bail out */
if (status != AWS_TASK_STATUS_RUN_READY || s2n_handler->state != NEGOTIATION_ONGOING) {
goto clean_up;
}
if (operation->completion_error_code == 0) {
if (s2n_async_pkey_op_apply(operation->s2n_op, s2n_handler->connection)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "id=%p: Failed applying s2n async pkey op", (void *)handler);
operation->completion_error_code = AWS_ERROR_INVALID_STATE;
}
}
if (operation->completion_error_code == 0) {
s_drive_negotiation(handler);
} else {
aws_channel_shutdown(s2n_handler->slot->channel, operation->completion_error_code);
}
clean_up:
s_tls_key_operation_destroy(operation);
}
/* Common implementation for aws_tls_key_operation_complete() and aws_tls_key_operation_complete_with_error()
* This is called exactly once. Schedules a task to actually finish things up on the event-loop thread. */
static void s_tls_key_operation_complete_common(
struct aws_tls_key_operation *operation,
int error_code,
const struct aws_byte_cursor *output) {
AWS_ASSERT((error_code != 0) ^ (output != NULL)); /* error_code XOR output must be set */
/* Ensure this can only be called once and exactly once. */
size_t complete_count = aws_atomic_fetch_add(&operation->complete_count, 1);
AWS_FATAL_ASSERT(complete_count == 0 && "TLS key operation marked complete multiple times");
struct s2n_handler *s2n_handler = operation->s2n_handler;
struct aws_channel_handler *handler = &s2n_handler->handler;
if (output != NULL) {
/* Immediately pass output through to s2n_op. */
if (s2n_async_pkey_op_set_output(operation->s2n_op, output->ptr, output->len)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "id=%p: Failed setting output on s2n async pkey op", (void *)handler);
error_code = AWS_ERROR_INVALID_STATE;
goto done;
}
}
done:
operation->completion_error_code = error_code;
/* Schedule a task to finish the operation.
* We schedule a task because the user might
* have completed the operation asynchronously,
* but we need to be on the event-loop thread to
* resume TLS negotiation. */
aws_channel_task_init(
&operation->completion_task,
s_tls_key_operation_completion_task,
operation,
"tls_key_operation_completion_task");
aws_channel_schedule_task_now(s2n_handler->slot->channel, &operation->completion_task);
}
void aws_tls_key_operation_complete(struct aws_tls_key_operation *operation, struct aws_byte_cursor output) {
if (operation == NULL) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "Operation complete: operation is null and therefore cannot be set to complete!");
return;
}
AWS_LOGF_DEBUG(
AWS_LS_IO_TLS,
"id=%p: TLS key operation complete with %zu bytes of output data",
(void *)operation->s2n_handler,
output.len);
s_tls_key_operation_complete_common(operation, 0, &output);
}
void aws_tls_key_operation_complete_with_error(struct aws_tls_key_operation *operation, int error_code) {
if (operation == NULL) {
AWS_LOGF_ERROR(
AWS_LS_IO_TLS, "Operation complete with error: operation is null and therefore cannot be set to complete!");
return;
}
if (error_code == 0) {
error_code = AWS_ERROR_UNKNOWN;
AWS_LOGF_ERROR(
AWS_LS_IO_TLS,
"id=%p: TLS key operation completed with error, but no error-code set. Using %s",
(void *)operation->s2n_handler,
aws_error_name(error_code));
}
AWS_LOGF_ERROR(
AWS_LS_IO_TLS,
"id=%p: TLS key operation complete with error %s",
(void *)operation->s2n_handler,
aws_error_name(error_code));
s_tls_key_operation_complete_common(operation, error_code, NULL);
}
static struct aws_tls_key_operation *s_tls_key_operation_new(
struct aws_channel_handler *handler,
struct s2n_async_pkey_op *s2n_op) {
struct s2n_handler *s2n_handler = handler->impl;
struct aws_tls_key_operation *operation = aws_mem_calloc(handler->alloc, 1, sizeof(struct aws_tls_key_operation));
operation->alloc = handler->alloc;
/* Copy input data */
uint32_t input_size = 0;
if (s2n_async_pkey_op_get_input_size(s2n_op, &input_size)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "id=%p: Failed querying s2n async pkey op size", (void *)handler);
aws_raise_error(AWS_ERROR_INVALID_STATE);
goto error;
}
aws_byte_buf_init(&operation->input_data, operation->alloc, input_size); /* cannot fail */
if (s2n_async_pkey_op_get_input(s2n_op, operation->input_data.buffer, input_size)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "id=%p: Failed querying s2n async pkey input", (void *)handler);
aws_raise_error(AWS_ERROR_INVALID_STATE);
goto error;
}
operation->input_data.len = input_size;
/* Get operation type */
s2n_async_pkey_op_type s2n_op_type = 0;
if (s2n_async_pkey_op_get_op_type(s2n_op, &s2n_op_type)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "id=%p: Failed querying s2n async pkey op type", (void *)handler);
aws_raise_error(AWS_ERROR_INVALID_STATE);
goto error;
}
if (s2n_op_type == S2N_ASYNC_SIGN) {
operation->operation_type = AWS_TLS_KEY_OPERATION_SIGN;
/* Gather additional information if this is a SIGN operation */
s2n_tls_signature_algorithm s2n_sign_alg = 0;
if (s2n_connection_get_selected_client_cert_signature_algorithm(s2n_handler->connection, &s2n_sign_alg)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "id=%p: Failed getting s2n client cert signature algorithm", (void *)handler);
aws_raise_error(AWS_ERROR_INVALID_STATE);
goto error;
}
operation->signature_algorithm = s_s2n_to_aws_signature_algorithm(s2n_sign_alg);
if (operation->signature_algorithm == AWS_TLS_SIGNATURE_UNKNOWN) {
AWS_LOGF_ERROR(
AWS_LS_IO_TLS,
"id=%p: Cannot sign with s2n_tls_signature_algorithm=%d. Algorithm currently unsupported",
(void *)handler,
s2n_sign_alg);
aws_raise_error(AWS_IO_TLS_SIGNATURE_ALGORITHM_UNSUPPORTED);
goto error;
}
s2n_tls_hash_algorithm s2n_digest_alg = 0;
if (s2n_connection_get_selected_client_cert_digest_algorithm(s2n_handler->connection, &s2n_digest_alg)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "id=%p: Failed getting s2n client cert digest algorithm", (void *)handler);
aws_raise_error(AWS_ERROR_INVALID_STATE);
goto error;
}
operation->digest_algorithm = s_s2n_to_aws_hash_algorithm(s2n_digest_alg);
if (operation->digest_algorithm == AWS_TLS_HASH_UNKNOWN) {
AWS_LOGF_ERROR(
AWS_LS_IO_TLS,
"id=%p: Cannot sign digest created with s2n_tls_hash_algorithm=%d. Algorithm currently unsupported",
(void *)handler,
s2n_digest_alg);
aws_raise_error(AWS_IO_TLS_DIGEST_ALGORITHM_UNSUPPORTED);
goto error;
}
} else if (s2n_op_type == S2N_ASYNC_DECRYPT) {
operation->operation_type = AWS_TLS_KEY_OPERATION_DECRYPT;
} else {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "id=%p: Unknown s2n async pkey op type:%d", (void *)handler, (int)s2n_op_type);
aws_raise_error(AWS_ERROR_INVALID_STATE);
goto error;
}
/* Keep channel alive until operation completes */
operation->s2n_handler = s2n_handler;
aws_channel_acquire_hold(s2n_handler->slot->channel);
/* Set this to zero so we can track how many times complete has been called */
aws_atomic_init_int(&operation->complete_count, 0);
/* Set this last. We don't want to take ownership of s2n_op until we know setup was 100% successful */
operation->s2n_op = s2n_op;
return operation;
error:
s_tls_key_operation_destroy(operation);
return NULL;
}
struct aws_byte_cursor aws_tls_key_operation_get_input(const struct aws_tls_key_operation *operation) {
return aws_byte_cursor_from_buf(&operation->input_data);
}
enum aws_tls_key_operation_type aws_tls_key_operation_get_type(const struct aws_tls_key_operation *operation) {
return operation->operation_type;
}
enum aws_tls_signature_algorithm aws_tls_key_operation_get_signature_algorithm(
const struct aws_tls_key_operation *operation) {
return operation->signature_algorithm;
}
enum aws_tls_hash_algorithm aws_tls_key_operation_get_digest_algorithm(const struct aws_tls_key_operation *operation) {
return operation->digest_algorithm;
}
static int s_s2n_async_pkey_callback(struct s2n_connection *conn, struct s2n_async_pkey_op *s2n_op) {
struct s2n_handler *s2n_handler = s2n_connection_get_ctx(conn);
struct aws_channel_handler *handler = &s2n_handler->handler;
AWS_ASSERT(conn == s2n_handler->connection);
(void)conn;
AWS_LOGF_TRACE(AWS_LS_IO_TLS, "id=%p: s2n async pkey callback received", (void *)handler);
/* Create the AWS wrapper around s2n_async_pkey_op */
struct aws_tls_key_operation *operation = s_tls_key_operation_new(handler, s2n_op);
if (operation == NULL) {
s2n_async_pkey_op_free(s2n_op);
return S2N_FAILURE;
}
AWS_LOGF_DEBUG(
AWS_LS_IO_TLS,
"id=%p: Begin TLS key operation. type=%s input_data.len=%zu signature=%s digest=%s",
(void *)operation,
aws_tls_key_operation_type_str(operation->operation_type),
operation->input_data.len,
aws_tls_signature_algorithm_str(operation->signature_algorithm),
aws_tls_hash_algorithm_str(operation->digest_algorithm));
aws_custom_key_op_handler_perform_operation(s2n_handler->s2n_ctx->custom_key_handler, operation);
return S2N_SUCCESS;
}
static int s_s2n_do_delayed_shutdown(
struct aws_channel_handler *handler,
struct aws_channel_slot *slot,
int error_code) {
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
s2n_handler->delayed_shutdown_task.slot = slot;
s2n_handler->delayed_shutdown_task.error = error_code;
uint64_t shutdown_delay = s2n_connection_get_delay(s2n_handler->connection);
uint64_t now = 0;
if (aws_channel_current_clock_time(slot->channel, &now)) {
return AWS_OP_ERR;
}
uint64_t shutdown_time = aws_add_u64_saturating(shutdown_delay, now);
aws_channel_schedule_task_future(slot->channel, &s2n_handler->delayed_shutdown_task.task, shutdown_time);
return AWS_OP_SUCCESS;
}
static int s_s2n_handler_shutdown(
struct aws_channel_handler *handler,
struct aws_channel_slot *slot,
enum aws_channel_direction dir,
int error_code,
bool abort_immediately) {
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
if (dir == AWS_CHANNEL_DIR_WRITE) {
if (!abort_immediately && error_code != AWS_IO_SOCKET_CLOSED) {
AWS_LOGF_DEBUG(AWS_LS_IO_TLS, "id=%p: Scheduling delayed write direction shutdown", (void *)handler);
if (s_s2n_do_delayed_shutdown(handler, slot, error_code) == AWS_OP_SUCCESS) {
return AWS_OP_SUCCESS;
}
}
} else {
AWS_LOGF_DEBUG(
AWS_LS_IO_TLS, "id=%p: Shutting down read direction with error code %d", (void *)handler, error_code);
/* If negotiation hasn't succeeded yet, it's certainly not going to succeed now */
if (s2n_handler->state == NEGOTIATION_ONGOING) {
s2n_handler->state = NEGOTIATION_FAILED;
}
while (!aws_linked_list_empty(&s2n_handler->input_queue)) {
struct aws_linked_list_node *node = aws_linked_list_pop_front(&s2n_handler->input_queue);
struct aws_io_message *message = AWS_CONTAINER_OF(node, struct aws_io_message, queueing_handle);
aws_mem_release(message->allocator, message);
}
}
return aws_channel_slot_on_handler_shutdown_complete(slot, dir, error_code, abort_immediately);
}
static void s_run_read(struct aws_channel_task *task, void *arg, aws_task_status status) {
task->task_fn = NULL;
task->arg = NULL;
if (status == AWS_TASK_STATUS_RUN_READY) {
struct aws_channel_handler *handler = (struct aws_channel_handler *)arg;
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
s_s2n_handler_process_read_message(handler, s2n_handler->slot, NULL);
}
}
static int s_s2n_handler_increment_read_window(
struct aws_channel_handler *handler,
struct aws_channel_slot *slot,
size_t size) {
(void)size;
struct s2n_handler *s2n_handler = handler->impl;
size_t downstream_size = aws_channel_slot_downstream_read_window(slot);
size_t current_window_size = slot->window_size;
AWS_LOGF_TRACE(
AWS_LS_IO_TLS, "id=%p: Increment read window message received %llu", (void *)handler, (unsigned long long)size);
size_t likely_records_count = (size_t)ceil((double)(downstream_size) / (double)(MAX_RECORD_SIZE));
size_t offset_size = aws_mul_size_saturating(likely_records_count, EST_TLS_RECORD_OVERHEAD);
size_t total_desired_size = aws_add_size_saturating(offset_size, downstream_size);
if (total_desired_size > current_window_size) {
size_t window_update_size = total_desired_size - current_window_size;
AWS_LOGF_TRACE(
AWS_LS_IO_TLS,
"id=%p: Propagating read window increment of size %llu",
(void *)handler,
(unsigned long long)window_update_size);
aws_channel_slot_increment_read_window(slot, window_update_size);
}
if (s2n_handler->state == NEGOTIATION_SUCCEEDED && !s2n_handler->sequential_tasks.node.next) {
/* TLS requires full records before it can decrypt anything. As a result we need to check everything we've
* buffered instead of just waiting on a read from the socket, or we'll hit a deadlock.
*
* We have messages in a queue and they need to be run after the socket has popped (even if it didn't have data
* to read). Alternatively, s2n reads entire records at a time, so we'll need to grab whatever we can and we
* have no idea what's going on inside there. So we need to attempt another read.*/
aws_channel_task_init(
&s2n_handler->sequential_tasks, s_run_read, handler, "s2n_channel_handler_read_on_window_increment");
aws_channel_schedule_task_now(slot->channel, &s2n_handler->sequential_tasks);
}
return AWS_OP_SUCCESS;
}
static size_t s_s2n_handler_message_overhead(struct aws_channel_handler *handler) {
(void)handler;
return EST_TLS_RECORD_OVERHEAD;
}
static size_t s_s2n_handler_initial_window_size(struct aws_channel_handler *handler) {
(void)handler;
return EST_HANDSHAKE_SIZE;
}
static void s_s2n_handler_reset_statistics(struct aws_channel_handler *handler) {
struct s2n_handler *s2n_handler = handler->impl;
aws_crt_statistics_tls_reset(&s2n_handler->shared_state.stats);
}
static void s_s2n_handler_gather_statistics(struct aws_channel_handler *handler, struct aws_array_list *stats) {
struct s2n_handler *s2n_handler = handler->impl;
void *stats_base = &s2n_handler->shared_state.stats;
aws_array_list_push_back(stats, &stats_base);
}
struct aws_byte_buf aws_tls_handler_protocol(struct aws_channel_handler *handler) {
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
return s2n_handler->protocol;
}
struct aws_byte_buf aws_tls_handler_server_name(struct aws_channel_handler *handler) {
struct s2n_handler *s2n_handler = (struct s2n_handler *)handler->impl;
return s2n_handler->server_name;
}
static struct aws_channel_handler_vtable s_handler_vtable = {
.destroy = s_s2n_handler_destroy,
.process_read_message = s_s2n_handler_process_read_message,
.process_write_message = s_s2n_handler_process_write_message,
.shutdown = s_s2n_handler_shutdown,
.increment_read_window = s_s2n_handler_increment_read_window,
.initial_window_size = s_s2n_handler_initial_window_size,
.message_overhead = s_s2n_handler_message_overhead,
.reset_statistics = s_s2n_handler_reset_statistics,
.gather_statistics = s_s2n_handler_gather_statistics,
};
static int s_parse_protocol_preferences(
struct aws_string *alpn_list_str,
const char protocol_output[4][128],
size_t *protocol_count) {
size_t max_count = *protocol_count;
*protocol_count = 0;
struct aws_byte_cursor alpn_list_buffer[4];
AWS_ZERO_ARRAY(alpn_list_buffer);
struct aws_array_list alpn_list;
struct aws_byte_cursor user_alpn_str = aws_byte_cursor_from_string(alpn_list_str);
aws_array_list_init_static(&alpn_list, alpn_list_buffer, 4, sizeof(struct aws_byte_cursor));
if (aws_byte_cursor_split_on_char(&user_alpn_str, ';', &alpn_list)) {
aws_raise_error(AWS_IO_TLS_CTX_ERROR);
return AWS_OP_ERR;
}
size_t protocols_list_len = aws_array_list_length(&alpn_list);
if (protocols_list_len < 1) {
aws_raise_error(AWS_IO_TLS_CTX_ERROR);
return AWS_OP_ERR;
}
for (size_t i = 0; i < protocols_list_len && i < max_count; ++i) {
struct aws_byte_cursor cursor;
AWS_ZERO_STRUCT(cursor);
if (aws_array_list_get_at(&alpn_list, (void *)&cursor, (size_t)i)) {
aws_raise_error(AWS_IO_TLS_CTX_ERROR);
return AWS_OP_ERR;
}
AWS_FATAL_ASSERT(cursor.ptr && cursor.len > 0);
memcpy((void *)protocol_output[i], cursor.ptr, cursor.len);
*protocol_count += 1;
}
return AWS_OP_SUCCESS;
}
static size_t s_tl_cleanup_key = 0; /* Address of variable serves as key in hash table */
/*
* This local object is added to the table of every event loop that has a (s2n) tls connection
* added to it at some point in time
*/
static struct aws_event_loop_local_object s_tl_cleanup_object = {
.key = &s_tl_cleanup_key,
.object = NULL,
.on_object_removed = NULL,
};
static void s_aws_cleanup_s2n_thread_local_state(void *user_data) {
(void)user_data;
s2n_cleanup();
}
/* s2n allocates thread-local data structures. We need to clean these up when the event loop's thread exits. */
static int s_s2n_tls_channel_handler_schedule_thread_local_cleanup(struct aws_channel_slot *slot) {
struct aws_channel *channel = slot->channel;
struct aws_event_loop_local_object existing_marker;
AWS_ZERO_STRUCT(existing_marker);
/*
* Check whether another s2n_tls_channel_handler has already scheduled the cleanup task.
*/
if (aws_channel_fetch_local_object(channel, &s_tl_cleanup_key, &existing_marker)) {
/* Doesn't exist in event loop table: add it and add the at-exit cleanup callback */
if (aws_channel_put_local_object(channel, &s_tl_cleanup_key, &s_tl_cleanup_object)) {
return AWS_OP_ERR;
}
aws_thread_current_at_exit(s_aws_cleanup_s2n_thread_local_state, NULL);
}
return AWS_OP_SUCCESS;
}
static struct aws_channel_handler *s_new_tls_handler(
struct aws_allocator *allocator,
struct aws_tls_connection_options *options,
struct aws_channel_slot *slot,
s2n_mode mode) {
AWS_ASSERT(options->ctx);
struct s2n_handler *s2n_handler = aws_mem_calloc(allocator, 1, sizeof(struct s2n_handler));
s2n_handler->handler.impl = s2n_handler;
s2n_handler->handler.alloc = allocator;
s2n_handler->handler.vtable = &s_handler_vtable;
s2n_handler->handler.slot = slot;
aws_tls_ctx_acquire(options->ctx);
s2n_handler->s2n_ctx = options->ctx->impl;
s2n_handler->connection = s2n_connection_new(mode);
if (!s2n_handler->connection) {
goto cleanup_conn;
}
aws_tls_channel_handler_shared_init(&s2n_handler->shared_state, &s2n_handler->handler, options);
s2n_handler->user_data = options->user_data;
s2n_handler->on_data_read = options->on_data_read;
s2n_handler->on_error = options->on_error;
s2n_handler->on_negotiation_result = options->on_negotiation_result;
s2n_handler->advertise_alpn_message = options->advertise_alpn_message;
s2n_handler->latest_message_completion_user_data = NULL;
s2n_handler->latest_message_on_completion = NULL;
s2n_handler->slot = slot;
aws_linked_list_init(&s2n_handler->input_queue);
s2n_handler->protocol = aws_byte_buf_from_array(NULL, 0);
if (options->server_name) {
if (s2n_set_server_name(s2n_handler->connection, aws_string_c_str(options->server_name))) {
aws_raise_error(AWS_IO_TLS_CTX_ERROR);
goto cleanup_conn;
}
}
s2n_handler->state = NEGOTIATION_ONGOING;
s2n_connection_set_recv_cb(s2n_handler->connection, s_s2n_handler_recv);
s2n_connection_set_recv_ctx(s2n_handler->connection, s2n_handler);
s2n_connection_set_send_cb(s2n_handler->connection, s_s2n_handler_send);
s2n_connection_set_send_ctx(s2n_handler->connection, s2n_handler);
s2n_connection_set_ctx(s2n_handler->connection, s2n_handler);
s2n_connection_set_blinding(s2n_handler->connection, S2N_SELF_SERVICE_BLINDING);
if (options->alpn_list) {
AWS_LOGF_DEBUG(
AWS_LS_IO_TLS,
"id=%p: Setting ALPN list %s",
(void *)&s2n_handler->handler,
aws_string_c_str(options->alpn_list));
const char protocols_cpy[4][128];
AWS_ZERO_ARRAY(protocols_cpy);
size_t protocols_size = 4;
if (s_parse_protocol_preferences(options->alpn_list, protocols_cpy, &protocols_size)) {
aws_raise_error(AWS_IO_TLS_CTX_ERROR);
goto cleanup_conn;
}
const char *protocols[4];
AWS_ZERO_ARRAY(protocols);
for (size_t i = 0; i < protocols_size; ++i) {
protocols[i] = protocols_cpy[i];
}
if (s2n_connection_set_protocol_preferences(
s2n_handler->connection, (const char *const *)protocols, (int)protocols_size)) {
aws_raise_error(AWS_IO_TLS_CTX_ERROR);
goto cleanup_conn;
}
}
if (s2n_connection_set_config(s2n_handler->connection, s2n_handler->s2n_ctx->s2n_config)) {
AWS_LOGF_WARN(
AWS_LS_IO_TLS,
"id=%p: configuration error %s (%s)",
(void *)&s2n_handler->handler,
s2n_strerror(s2n_errno, "EN"),
s2n_strerror_debug(s2n_errno, "EN"));
aws_raise_error(AWS_IO_TLS_CTX_ERROR);
goto cleanup_conn;
}
aws_channel_task_init(
&s2n_handler->delayed_shutdown_task.task,
s_delayed_shutdown_task_fn,
&s2n_handler->handler,
"s2n_delayed_shutdown");
if (s_s2n_tls_channel_handler_schedule_thread_local_cleanup(slot)) {
goto cleanup_conn;
}
return &s2n_handler->handler;
cleanup_conn:
s_s2n_handler_destroy(&s2n_handler->handler);
return NULL;
}
struct aws_channel_handler *aws_tls_client_handler_new(
struct aws_allocator *allocator,
struct aws_tls_connection_options *options,
struct aws_channel_slot *slot) {
return s_new_tls_handler(allocator, options, slot, S2N_CLIENT);
}
struct aws_channel_handler *aws_tls_server_handler_new(
struct aws_allocator *allocator,
struct aws_tls_connection_options *options,
struct aws_channel_slot *slot) {
return s_new_tls_handler(allocator, options, slot, S2N_SERVER);
}
static void s_s2n_ctx_destroy(struct s2n_ctx *s2n_ctx) {
if (s2n_ctx != NULL) {
s2n_config_free(s2n_ctx->s2n_config);
if (s2n_ctx->custom_cert_chain_and_key) {
s2n_cert_chain_and_key_free(s2n_ctx->custom_cert_chain_and_key);
}
s2n_ctx->custom_key_handler = aws_custom_key_op_handler_release(s2n_ctx->custom_key_handler);
aws_mem_release(s2n_ctx->ctx.alloc, s2n_ctx);
}
}
static int s2n_wall_clock_time_nanoseconds(void *context, uint64_t *time_in_ns) {
(void)context;
if (aws_sys_clock_get_ticks(time_in_ns)) {
*time_in_ns = 0;
return -1;
}
return 0;
}
static int s2n_monotonic_clock_time_nanoseconds(void *context, uint64_t *time_in_ns) {
(void)context;
if (aws_high_res_clock_get_ticks(time_in_ns)) {
*time_in_ns = 0;
return -1;
}
return 0;
}
static void s_log_and_raise_s2n_errno(const char *msg) {
AWS_LOGF_ERROR(
AWS_LS_IO_TLS, "%s: %s (%s)", msg, s2n_strerror(s2n_errno, "EN"), s2n_strerror_debug(s2n_errno, "EN"));
aws_raise_error(AWS_IO_TLS_CTX_ERROR);
}
static struct aws_tls_ctx *s_tls_ctx_new(
struct aws_allocator *alloc,
const struct aws_tls_ctx_options *options,
s2n_mode mode) {
struct s2n_ctx *s2n_ctx = aws_mem_calloc(alloc, 1, sizeof(struct s2n_ctx));
if (!s2n_ctx) {
return NULL;
}
if (!aws_tls_is_cipher_pref_supported(options->cipher_pref)) {
aws_raise_error(AWS_IO_TLS_CIPHER_PREF_UNSUPPORTED);
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "static: TLS Cipher Preference is not supported: %d.", options->cipher_pref);
return NULL;
}
s2n_ctx->ctx.alloc = alloc;
s2n_ctx->ctx.impl = s2n_ctx;
aws_ref_count_init(&s2n_ctx->ctx.ref_count, s2n_ctx, (aws_simple_completion_callback *)s_s2n_ctx_destroy);
s2n_ctx->s2n_config = s2n_config_new();
if (!s2n_ctx->s2n_config) {
s_log_and_raise_s2n_errno("ctx: creation failed");
goto cleanup_s2n_config;
}
int set_clock_result = s2n_config_set_wall_clock(s2n_ctx->s2n_config, s2n_wall_clock_time_nanoseconds, NULL);
if (set_clock_result != S2N_ERR_T_OK) {
s_log_and_raise_s2n_errno("ctx: failed to set wall clock");
goto cleanup_s2n_config;
}
set_clock_result = s2n_config_set_monotonic_clock(s2n_ctx->s2n_config, s2n_monotonic_clock_time_nanoseconds, NULL);
if (set_clock_result != S2N_ERR_T_OK) {
s_log_and_raise_s2n_errno("ctx: failed to set monotonic clock");
goto cleanup_s2n_config;
}
if (options->custom_key_op_handler != NULL) {
/* PKCS#11 integration hasn't been tested with TLS 1.3, so don't use cipher preferences that allow 1.3 */
switch (options->minimum_tls_version) {
case AWS_IO_SSLv3:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "CloudFront-SSL-v-3");
break;
case AWS_IO_TLSv1:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "CloudFront-TLS-1-0-2014");
break;
case AWS_IO_TLSv1_1:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "ELBSecurityPolicy-TLS-1-1-2017-01");
break;
case AWS_IO_TLSv1_2:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "ELBSecurityPolicy-TLS-1-2-Ext-2018-06");
break;
case AWS_IO_TLSv1_3:
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "TLS 1.3 with PKCS#11 is not supported yet.");
aws_raise_error(AWS_IO_TLS_VERSION_UNSUPPORTED);
goto cleanup_s2n_config;
case AWS_IO_TLS_VER_SYS_DEFAULTS:
default:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "ELBSecurityPolicy-TLS-1-1-2017-01");
}
} else {
switch (options->minimum_tls_version) {
case AWS_IO_SSLv3:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "AWS-CRT-SDK-SSLv3.0");
break;
case AWS_IO_TLSv1:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "AWS-CRT-SDK-TLSv1.0");
break;
case AWS_IO_TLSv1_1:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "AWS-CRT-SDK-TLSv1.1");
break;
case AWS_IO_TLSv1_2:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "AWS-CRT-SDK-TLSv1.2");
break;
case AWS_IO_TLSv1_3:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "AWS-CRT-SDK-TLSv1.3");
break;
case AWS_IO_TLS_VER_SYS_DEFAULTS:
default:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "AWS-CRT-SDK-TLSv1.0");
}
}
switch (options->cipher_pref) {
case AWS_IO_TLS_CIPHER_PREF_SYSTEM_DEFAULT:
/* No-Op, if the user configured a minimum_tls_version then a version-specific Cipher Preference was set */
break;
case AWS_IO_TLS_CIPHER_PREF_PQ_TLSv1_0_2021_05:
s2n_config_set_cipher_preferences(s2n_ctx->s2n_config, "PQ-TLS-1-0-2021-05-26");
break;
default:
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "Unrecognized TLS Cipher Preference: %d", options->cipher_pref);
aws_raise_error(AWS_IO_TLS_CIPHER_PREF_UNSUPPORTED);
goto cleanup_s2n_config;
}
if (aws_tls_options_buf_is_set(&options->certificate) && aws_tls_options_buf_is_set(&options->private_key)) {
AWS_LOGF_DEBUG(AWS_LS_IO_TLS, "ctx: Certificate and key have been set, setting them up now.");
if (!aws_text_is_utf8(options->certificate.buffer, options->certificate.len)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "static: failed to import certificate, must be ASCII/UTF-8 encoded");
aws_raise_error(AWS_IO_FILE_VALIDATION_FAILURE);
goto cleanup_s2n_config;
}
if (!aws_text_is_utf8(options->private_key.buffer, options->private_key.len)) {
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "static: failed to import private key, must be ASCII/UTF-8 encoded");
aws_raise_error(AWS_IO_FILE_VALIDATION_FAILURE);
goto cleanup_s2n_config;
}
/* Ensure that what we pass to s2n is zero-terminated */
struct aws_string *certificate_string = aws_string_new_from_buf(alloc, &options->certificate);
struct aws_string *private_key_string = aws_string_new_from_buf(alloc, &options->private_key);
int err_code = s2n_config_add_cert_chain_and_key(
s2n_ctx->s2n_config, (const char *)certificate_string->bytes, (const char *)private_key_string->bytes);
aws_string_destroy(certificate_string);
aws_string_destroy_secure(private_key_string);
if (mode == S2N_CLIENT) {
s2n_config_set_client_auth_type(s2n_ctx->s2n_config, S2N_CERT_AUTH_REQUIRED);
}
if (err_code != S2N_ERR_T_OK) {
s_log_and_raise_s2n_errno("ctx: Failed to add certificate and private key");
goto cleanup_s2n_config;
}
} else if (options->custom_key_op_handler != NULL) {
s2n_ctx->custom_key_handler = aws_custom_key_op_handler_acquire(options->custom_key_op_handler);
/* set callback so that we can do custom private key operations */
if (s2n_config_set_async_pkey_callback(s2n_ctx->s2n_config, s_s2n_async_pkey_callback)) {
s_log_and_raise_s2n_errno("ctx: failed to set private key callback");
goto cleanup_s2n_config;
}
/* set certificate.
* we need to create a custom s2n_cert_chain_and_key that knows the cert but not the key */
s2n_ctx->custom_cert_chain_and_key = s2n_cert_chain_and_key_new();
if (!s2n_ctx->custom_cert_chain_and_key) {
s_log_and_raise_s2n_errno("ctx: creation failed");
goto cleanup_s2n_config;
}
if (s2n_cert_chain_and_key_load_public_pem_bytes(
s2n_ctx->custom_cert_chain_and_key, options->certificate.buffer, options->certificate.len)) {
s_log_and_raise_s2n_errno("ctx: failed to load certificate");
goto cleanup_s2n_config;
}
if (s2n_config_add_cert_chain_and_key_to_store(s2n_ctx->s2n_config, s2n_ctx->custom_cert_chain_and_key)) {
s_log_and_raise_s2n_errno("ctx: failed to add certificate to store");
goto cleanup_s2n_config;
}
if (mode == S2N_CLIENT) {
s2n_config_set_client_auth_type(s2n_ctx->s2n_config, S2N_CERT_AUTH_REQUIRED);
}
}
if (options->verify_peer) {
if (s2n_config_set_check_stapled_ocsp_response(s2n_ctx->s2n_config, 1) == S2N_SUCCESS) {
if (s2n_config_set_status_request_type(s2n_ctx->s2n_config, S2N_STATUS_REQUEST_OCSP) != S2N_SUCCESS) {
s_log_and_raise_s2n_errno("ctx: ocsp status request cannot be set");
goto cleanup_s2n_config;
}
} else {
if (s2n_error_get_type(s2n_errno) == S2N_ERR_T_USAGE) {
AWS_LOGF_INFO(AWS_LS_IO_TLS, "ctx: cannot enable ocsp stapling: %s", s2n_strerror(s2n_errno, "EN"));
} else {
s_log_and_raise_s2n_errno("ctx: cannot enable ocsp stapling");
goto cleanup_s2n_config;
}
}
if (options->ca_path || aws_tls_options_buf_is_set(&options->ca_file)) {
/* The user called an override_default_trust_store() function.
* Begin by wiping anything that s2n loaded by default */
if (s2n_config_wipe_trust_store(s2n_ctx->s2n_config)) {
s_log_and_raise_s2n_errno("ctx: failed to wipe default trust store");
goto cleanup_s2n_config;
}
if (options->ca_path) {
if (s2n_config_set_verification_ca_location(
s2n_ctx->s2n_config, NULL, aws_string_c_str(options->ca_path))) {
s_log_and_raise_s2n_errno("ctx: configuration error");
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "Failed to set ca_path %s\n", aws_string_c_str(options->ca_path));
goto cleanup_s2n_config;
}
}
if (aws_tls_options_buf_is_set(&options->ca_file)) {
/* Ensure that what we pass to s2n is zero-terminated */
struct aws_string *ca_file_string = aws_string_new_from_buf(alloc, &options->ca_file);
int set_ca_result =
s2n_config_add_pem_to_trust_store(s2n_ctx->s2n_config, (const char *)ca_file_string->bytes);
aws_string_destroy(ca_file_string);
if (set_ca_result) {
s_log_and_raise_s2n_errno("ctx: configuration error");
AWS_LOGF_ERROR(AWS_LS_IO_TLS, "Failed to set ca_file %s\n", (const char *)options->ca_file.buffer);
goto cleanup_s2n_config;
}
}
} else if (s_default_ca_file || s_default_ca_dir) {
/* User wants to use the system's default trust store.
*
* Note that s2n's trust store always starts with libcrypto's default locations.
* These paths are configured when libcrypto is built (--openssldir),
* but might not be right for the current machine (e.g. if libcrypto
* is statically linked into an application that is distributed
* to multiple flavors of Linux). Therefore, load the locations that
* were found at library startup. */
if (s2n_config_set_verification_ca_location(s2n_ctx->s2n_config, s_default_ca_file, s_default_ca_dir)) {
s_log_and_raise_s2n_errno("ctx: configuration error");
AWS_LOGF_ERROR(
AWS_LS_IO_TLS, "Failed to set ca_path: %s and ca_file %s\n", s_default_ca_dir, s_default_ca_file);
goto cleanup_s2n_config;
}
} else {
/* Cannot find system's trust store */
aws_raise_error(AWS_IO_TLS_ERROR_DEFAULT_TRUST_STORE_NOT_FOUND);
AWS_LOGF_ERROR(
AWS_LS_IO_TLS,
"Default TLS trust store not found on this system."
" Install CA certificates, or \"override default trust store\".");
goto cleanup_s2n_config;
}
if (mode == S2N_SERVER && s2n_config_set_client_auth_type(s2n_ctx->s2n_config, S2N_CERT_AUTH_REQUIRED)) {
s_log_and_raise_s2n_errno("ctx: failed to set client auth type");
goto cleanup_s2n_config;
}
} else if (mode != S2N_SERVER) {
AWS_LOGF_WARN(
AWS_LS_IO_TLS,
"ctx: X.509 validation has been disabled. "
"If this is not running in a test environment, this is likely a security vulnerability.");
if (s2n_config_disable_x509_verification(s2n_ctx->s2n_config)) {
s_log_and_raise_s2n_errno("ctx: failed to disable x509 verification");
goto cleanup_s2n_config;
}
}
if (options->alpn_list) {
AWS_LOGF_DEBUG(AWS_LS_IO_TLS, "ctx: Setting ALPN list %s", aws_string_c_str(options->alpn_list));
const char protocols_cpy[4][128];
AWS_ZERO_ARRAY(protocols_cpy);
size_t protocols_size = 4;
if (s_parse_protocol_preferences(options->alpn_list, protocols_cpy, &protocols_size)) {
s_log_and_raise_s2n_errno("ctx: Failed to parse ALPN list");
goto cleanup_s2n_config;
}
const char *protocols[4];
AWS_ZERO_ARRAY(protocols);
for (size_t i = 0; i < protocols_size; ++i) {
protocols[i] = protocols_cpy[i];
}
if (s2n_config_set_protocol_preferences(s2n_ctx->s2n_config, protocols, (int)protocols_size)) {
s_log_and_raise_s2n_errno("ctx: Failed to set protocol preferences");
goto cleanup_s2n_config;
}
}
if (options->max_fragment_size == 512) {
s2n_config_send_max_fragment_length(s2n_ctx->s2n_config, S2N_TLS_MAX_FRAG_LEN_512);
} else if (options->max_fragment_size == 1024) {
s2n_config_send_max_fragment_length(s2n_ctx->s2n_config, S2N_TLS_MAX_FRAG_LEN_1024);
} else if (options->max_fragment_size == 2048) {
s2n_config_send_max_fragment_length(s2n_ctx->s2n_config, S2N_TLS_MAX_FRAG_LEN_2048);
} else if (options->max_fragment_size == 4096) {
s2n_config_send_max_fragment_length(s2n_ctx->s2n_config, S2N_TLS_MAX_FRAG_LEN_4096);
}
return &s2n_ctx->ctx;
cleanup_s2n_config:
s_s2n_ctx_destroy(s2n_ctx);
return NULL;
}
struct aws_tls_ctx *aws_tls_server_ctx_new(struct aws_allocator *alloc, const struct aws_tls_ctx_options *options) {
aws_io_fatal_assert_library_initialized();
return s_tls_ctx_new(alloc, options, S2N_SERVER);
}
struct aws_tls_ctx *aws_tls_client_ctx_new(struct aws_allocator *alloc, const struct aws_tls_ctx_options *options) {
aws_io_fatal_assert_library_initialized();
return s_tls_ctx_new(alloc, options, S2N_CLIENT);
}
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