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|
/*
* Copyright (c) 2019 Cisco and/or its affiliates.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License 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 <vnet/crypto/crypto.h>
#include <vppinfra/lock.h>
#include <quic/quic.h>
#include <quic/quic_crypto.h>
#include <quicly.h>
#include <picotls/openssl.h>
#define QUICLY_EPOCH_1RTT 3
extern quic_main_t quic_main;
extern quic_ctx_t *quic_get_conn_ctx (quicly_conn_t * conn);
typedef void (*quicly_do_transform_fn) (ptls_cipher_context_t *, void *,
const void *, size_t);
struct cipher_context_t
{
ptls_cipher_context_t super;
vnet_crypto_op_t op;
u32 key_index;
};
struct aead_crypto_context_t
{
ptls_aead_context_t super;
vnet_crypto_op_t op;
u32 key_index;
};
static size_t
quic_crypto_offload_aead_decrypt (quic_ctx_t * qctx,
ptls_aead_context_t * _ctx, void *_output,
const void *input, size_t inlen,
uint64_t decrypted_pn, const void *aad,
size_t aadlen);
vnet_crypto_main_t *cm = &crypto_main;
void
quic_crypto_batch_tx_packets (quic_crypto_batch_ctx_t * batch_ctx)
{
vlib_main_t *vm = vlib_get_main ();
if (batch_ctx->nb_tx_packets <= 0)
return;
clib_rwlock_reader_lock (&quic_main.crypto_keys_quic_rw_lock);
vnet_crypto_process_ops (vm, batch_ctx->aead_crypto_tx_packets_ops,
batch_ctx->nb_tx_packets);
clib_rwlock_reader_unlock (&quic_main.crypto_keys_quic_rw_lock);
for (int i = 0; i < batch_ctx->nb_tx_packets; i++)
clib_mem_free (batch_ctx->aead_crypto_tx_packets_ops[i].iv);
batch_ctx->nb_tx_packets = 0;
}
void
quic_crypto_batch_rx_packets (quic_crypto_batch_ctx_t * batch_ctx)
{
vlib_main_t *vm = vlib_get_main ();
if (batch_ctx->nb_rx_packets <= 0)
return;
clib_rwlock_reader_lock (&quic_main.crypto_keys_quic_rw_lock);
vnet_crypto_process_ops (vm, batch_ctx->aead_crypto_rx_packets_ops,
batch_ctx->nb_rx_packets);
clib_rwlock_reader_unlock (&quic_main.crypto_keys_quic_rw_lock);
for (int i = 0; i < batch_ctx->nb_rx_packets; i++)
clib_mem_free (batch_ctx->aead_crypto_rx_packets_ops[i].iv);
batch_ctx->nb_rx_packets = 0;
}
void
build_iv (ptls_aead_context_t * ctx, uint8_t * iv, uint64_t seq)
{
size_t iv_size = ctx->algo->iv_size, i;
const uint8_t *s = ctx->static_iv;
uint8_t *d = iv;
/* build iv */
for (i = iv_size - 8; i != 0; --i)
*d++ = *s++;
i = 64;
do
{
i -= 8;
*d++ = *s++ ^ (uint8_t) (seq >> i);
}
while (i != 0);
}
static void
do_finalize_send_packet (ptls_cipher_context_t * hp,
quicly_datagram_t * packet,
size_t first_byte_at, size_t payload_from)
{
uint8_t hpmask[1 + QUICLY_SEND_PN_SIZE] = {
0
};
size_t i;
ptls_cipher_init (hp,
packet->data.base + payload_from - QUICLY_SEND_PN_SIZE +
QUICLY_MAX_PN_SIZE);
ptls_cipher_encrypt (hp, hpmask, hpmask, sizeof (hpmask));
packet->data.base[first_byte_at] ^=
hpmask[0] &
(QUICLY_PACKET_IS_LONG_HEADER (packet->data.base[first_byte_at]) ? 0xf :
0x1f);
for (i = 0; i != QUICLY_SEND_PN_SIZE; ++i)
packet->data.base[payload_from + i - QUICLY_SEND_PN_SIZE] ^=
hpmask[i + 1];
}
void
quic_crypto_finalize_send_packet (quicly_datagram_t * packet)
{
quic_encrypt_cb_ctx *encrypt_cb_ctx =
(quic_encrypt_cb_ctx *) ((uint8_t *) packet + sizeof (*packet));
for (int i = 0; i < encrypt_cb_ctx->snd_ctx_count; i++)
{
do_finalize_send_packet (encrypt_cb_ctx->snd_ctx[i].hp,
packet,
encrypt_cb_ctx->snd_ctx[i].first_byte_at,
encrypt_cb_ctx->snd_ctx[i].payload_from);
}
encrypt_cb_ctx->snd_ctx_count = 0;
}
static int
quic_crypto_setup_cipher (quicly_crypto_engine_t * engine,
quicly_conn_t * conn, size_t epoch, int is_enc,
ptls_cipher_context_t ** hp_ctx,
ptls_aead_context_t ** aead_ctx,
ptls_aead_algorithm_t * aead,
ptls_hash_algorithm_t * hash, const void *secret)
{
uint8_t hpkey[PTLS_MAX_SECRET_SIZE];
int ret;
if (hp_ctx != NULL)
*hp_ctx = NULL;
*aead_ctx = NULL;
/* generate new header protection key */
if (hp_ctx != NULL)
{
if ((ret =
ptls_hkdf_expand_label (hash, hpkey, aead->ctr_cipher->key_size,
ptls_iovec_init (secret,
hash->digest_size),
"quic hp", ptls_iovec_init (NULL, 0),
NULL)) != 0)
goto Exit;
if ((*hp_ctx =
ptls_cipher_new (aead->ctr_cipher, is_enc, hpkey)) == NULL)
{
ret = PTLS_ERROR_NO_MEMORY;
goto Exit;
}
}
/* generate new AEAD context */
if ((*aead_ctx =
ptls_aead_new (aead, hash, is_enc, secret,
QUICLY_AEAD_BASE_LABEL)) == NULL)
{
ret = PTLS_ERROR_NO_MEMORY;
goto Exit;
}
if (epoch == QUICLY_EPOCH_1RTT && !is_enc)
{
quic_ctx_t *qctx = quic_get_conn_ctx (conn);
if (qctx->ingress_keys.aead_ctx != NULL)
{
qctx->key_phase_ingress++;
}
qctx->ingress_keys.aead_ctx = *aead_ctx;
if (hp_ctx != NULL)
qctx->ingress_keys.hp_ctx = *hp_ctx;
}
ret = 0;
Exit:
if (ret != 0)
{
if (*aead_ctx != NULL)
{
ptls_aead_free (*aead_ctx);
*aead_ctx = NULL;
}
if (*hp_ctx != NULL)
{
ptls_cipher_free (*hp_ctx);
*hp_ctx = NULL;
}
}
ptls_clear_memory (hpkey, sizeof (hpkey));
return ret;
}
void
quic_crypto_finalize_send_packet_cb (struct st_quicly_crypto_engine_t
*engine, quicly_conn_t * conn,
ptls_cipher_context_t * hp,
ptls_aead_context_t * aead,
quicly_datagram_t * packet,
size_t first_byte_at,
size_t payload_from, int coalesced)
{
quic_encrypt_cb_ctx *encrypt_cb_ctx =
(quic_encrypt_cb_ctx *) ((uint8_t *) packet + sizeof (*packet));
encrypt_cb_ctx->snd_ctx[encrypt_cb_ctx->snd_ctx_count].hp = hp;
encrypt_cb_ctx->snd_ctx[encrypt_cb_ctx->snd_ctx_count].first_byte_at =
first_byte_at;
encrypt_cb_ctx->snd_ctx[encrypt_cb_ctx->snd_ctx_count].payload_from =
payload_from;
encrypt_cb_ctx->snd_ctx_count++;
}
void
quic_crypto_decrypt_packet (quic_ctx_t * qctx, quic_rx_packet_ctx_t * pctx)
{
ptls_cipher_context_t *header_protection = NULL;
ptls_aead_context_t *aead = NULL;
int pn;
/* Long Header packets are not decrypted by vpp */
if (QUICLY_PACKET_IS_LONG_HEADER (pctx->packet.octets.base[0]))
return;
uint64_t next_expected_packet_number =
quicly_get_next_expected_packet_number (qctx->conn);
if (next_expected_packet_number == UINT64_MAX)
return;
aead = qctx->ingress_keys.aead_ctx;
header_protection = qctx->ingress_keys.hp_ctx;
if (!aead || !header_protection)
return;
size_t encrypted_len = pctx->packet.octets.len - pctx->packet.encrypted_off;
uint8_t hpmask[5] = { 0 };
uint32_t pnbits = 0;
size_t pnlen, ptlen, i;
/* decipher the header protection, as well as obtaining pnbits, pnlen */
if (encrypted_len < header_protection->algo->iv_size + QUICLY_MAX_PN_SIZE)
return;
ptls_cipher_init (header_protection,
pctx->packet.octets.base + pctx->packet.encrypted_off +
QUICLY_MAX_PN_SIZE);
ptls_cipher_encrypt (header_protection, hpmask, hpmask, sizeof (hpmask));
pctx->packet.octets.base[0] ^=
hpmask[0] & (QUICLY_PACKET_IS_LONG_HEADER (pctx->packet.octets.base[0]) ?
0xf : 0x1f);
pnlen = (pctx->packet.octets.base[0] & 0x3) + 1;
for (i = 0; i != pnlen; ++i)
{
pctx->packet.octets.base[pctx->packet.encrypted_off + i] ^=
hpmask[i + 1];
pnbits =
(pnbits << 8) | pctx->packet.octets.base[pctx->packet.encrypted_off +
i];
}
size_t aead_off = pctx->packet.encrypted_off + pnlen;
pn =
quicly_determine_packet_number (pnbits, pnlen * 8,
next_expected_packet_number);
int key_phase_bit =
(pctx->packet.octets.base[0] & QUICLY_KEY_PHASE_BIT) != 0;
if (key_phase_bit != (qctx->key_phase_ingress & 1))
{
pctx->packet.octets.base[0] ^=
hpmask[0] &
(QUICLY_PACKET_IS_LONG_HEADER (pctx->packet.octets.base[0]) ? 0xf :
0x1f);
for (i = 0; i != pnlen; ++i)
{
pctx->packet.octets.base[pctx->packet.encrypted_off + i] ^=
hpmask[i + 1];
}
return;
}
if ((ptlen =
quic_crypto_offload_aead_decrypt (qctx, aead,
pctx->packet.octets.base + aead_off,
pctx->packet.octets.base + aead_off,
pctx->packet.octets.len - aead_off,
pn, pctx->packet.octets.base,
aead_off)) == SIZE_MAX)
{
fprintf (stderr,
"%s: aead decryption failure (pn: %d)\n", __FUNCTION__, pn);
return;
}
pctx->packet.encrypted_off = aead_off;
pctx->packet.octets.len = ptlen + aead_off;
pctx->packet.decrypted.pn = pn;
pctx->packet.decrypted.key_phase = qctx->key_phase_ingress;
}
#ifdef QUIC_HP_CRYPTO
static void
quic_crypto_cipher_do_init (ptls_cipher_context_t * _ctx, const void *iv)
{
struct cipher_context_t *ctx = (struct cipher_context_t *) _ctx;
vnet_crypto_op_id_t id;
if (!strcmp (ctx->super.algo->name, "AES128-CTR"))
{
id = VNET_CRYPTO_OP_AES_128_CTR_ENC;
}
else if (!strcmp (ctx->super.algo->name, "AES256-CTR"))
{
id = VNET_CRYPTO_OP_AES_256_CTR_ENC;
}
else
{
QUIC_DBG (1, "%s, Invalid crypto cipher : ", __FUNCTION__,
_ctx->algo->name);
assert (0);
}
vnet_crypto_op_init (&ctx->op, id);
ctx->op.iv = (u8 *) iv;
ctx->op.key_index = ctx->key_index;
}
static void
quic_crypto_cipher_dispose (ptls_cipher_context_t * _ctx)
{
/* Do nothing */
}
static void
quic_crypto_cipher_encrypt (ptls_cipher_context_t * _ctx, void *output,
const void *input, size_t _len)
{
vlib_main_t *vm = vlib_get_main ();
struct cipher_context_t *ctx = (struct cipher_context_t *) _ctx;
ctx->op.src = (u8 *) input;
ctx->op.dst = output;
ctx->op.len = _len;
vnet_crypto_process_ops (vm, &ctx->op, 1);
}
static int
quic_crypto_cipher_setup_crypto (ptls_cipher_context_t * _ctx, int is_enc,
const void *key, const EVP_CIPHER * cipher,
quicly_do_transform_fn do_transform)
{
struct cipher_context_t *ctx = (struct cipher_context_t *) _ctx;
ctx->super.do_dispose = quic_crypto_cipher_dispose;
ctx->super.do_init = quic_crypto_cipher_do_init;
ctx->super.do_transform = do_transform;
vlib_main_t *vm = vlib_get_main ();
vnet_crypto_alg_t algo;
if (!strcmp (ctx->super.algo->name, "AES128-CTR"))
{
algo = VNET_CRYPTO_ALG_AES_128_CTR;
}
else if (!strcmp (ctx->super.algo->name, "AES256-CTR"))
{
algo = VNET_CRYPTO_ALG_AES_256_CTR;
}
else
{
QUIC_DBG (1, "%s, Invalid crypto cipher : ", __FUNCTION__,
_ctx->algo->name);
assert (0);
}
ctx->key_index = vnet_crypto_key_add (vm, algo,
(u8 *) key, _ctx->algo->key_size);
return 0;
}
static int
quic_crypto_aes128ctr_setup_crypto (ptls_cipher_context_t * ctx, int is_enc,
const void *key)
{
return quic_crypto_cipher_setup_crypto (ctx, 1, key, EVP_aes_128_ctr (),
quic_crypto_cipher_encrypt);
}
static int
quic_crypto_aes256ctr_setup_crypto (ptls_cipher_context_t * ctx, int is_enc,
const void *key)
{
return quic_crypto_cipher_setup_crypto (ctx, 1, key, EVP_aes_256_ctr (),
quic_crypto_cipher_encrypt);
}
#endif // QUIC_HP_CRYPTO
void
quic_crypto_aead_encrypt_init (ptls_aead_context_t * _ctx, const void *iv,
const void *aad, size_t aadlen)
{
quic_main_t *qm = &quic_main;
u32 thread_index = vlib_get_thread_index ();
struct aead_crypto_context_t *ctx = (struct aead_crypto_context_t *) _ctx;
vnet_crypto_op_id_t id;
if (!strcmp (ctx->super.algo->name, "AES128-GCM"))
{
id = VNET_CRYPTO_OP_AES_128_GCM_ENC;
}
else if (!strcmp (ctx->super.algo->name, "AES256-GCM"))
{
id = VNET_CRYPTO_OP_AES_256_GCM_ENC;
}
else
{
assert (0);
}
quic_crypto_batch_ctx_t *quic_crypto_batch_ctx =
&qm->wrk_ctx[thread_index].crypto_context_batch;
vnet_crypto_op_t *vnet_op =
&quic_crypto_batch_ctx->aead_crypto_tx_packets_ops
[quic_crypto_batch_ctx->nb_tx_packets];
vnet_crypto_op_init (vnet_op, id);
vnet_op->aad = (u8 *) aad;
vnet_op->aad_len = aadlen;
vnet_op->iv = clib_mem_alloc (PTLS_MAX_IV_SIZE);
clib_memcpy (vnet_op->iv, iv, PTLS_MAX_IV_SIZE);
vnet_op->key_index = ctx->key_index;
}
size_t
quic_crypto_aead_encrypt_update (ptls_aead_context_t * _ctx, void *output,
const void *input, size_t inlen)
{
struct aead_crypto_context_t *ctx = (struct aead_crypto_context_t *) _ctx;
quic_main_t *qm = &quic_main;
u32 thread_index = vlib_get_thread_index ();
quic_crypto_batch_ctx_t *quic_crypto_batch_ctx =
&qm->wrk_ctx[thread_index].crypto_context_batch;
vnet_crypto_op_t *vnet_op =
&quic_crypto_batch_ctx->aead_crypto_tx_packets_ops
[quic_crypto_batch_ctx->nb_tx_packets];
vnet_op->src = (u8 *) input;
vnet_op->dst = output;
vnet_op->len = inlen;
vnet_op->tag_len = ctx->super.algo->tag_size;
vnet_op->tag = vnet_op->src + inlen;
return 0;
}
size_t
quic_crypto_aead_encrypt_final (ptls_aead_context_t * _ctx, void *output)
{
quic_main_t *qm = &quic_main;
u32 thread_index = vlib_get_thread_index ();
quic_crypto_batch_ctx_t *quic_crypto_batch_ctx =
&qm->wrk_ctx[thread_index].crypto_context_batch;
vnet_crypto_op_t *vnet_op =
&quic_crypto_batch_ctx->
aead_crypto_tx_packets_ops[quic_crypto_batch_ctx->nb_tx_packets];
quic_crypto_batch_ctx->nb_tx_packets++;
return vnet_op->len + vnet_op->tag_len;
}
size_t
quic_crypto_aead_decrypt (ptls_aead_context_t * _ctx, void *_output,
const void *input, size_t inlen, const void *iv,
const void *aad, size_t aadlen)
{
vlib_main_t *vm = vlib_get_main ();
struct aead_crypto_context_t *ctx = (struct aead_crypto_context_t *) _ctx;
vnet_crypto_op_id_t id;
if (!strcmp (ctx->super.algo->name, "AES128-GCM"))
{
id = VNET_CRYPTO_OP_AES_128_GCM_DEC;
}
else if (!strcmp (ctx->super.algo->name, "AES256-GCM"))
{
id = VNET_CRYPTO_OP_AES_256_GCM_DEC;
}
else
{
assert (0);
}
vnet_crypto_op_init (&ctx->op, id);
ctx->op.aad = (u8 *) aad;
ctx->op.aad_len = aadlen;
ctx->op.iv = (u8 *) iv;
ctx->op.src = (u8 *) input;
ctx->op.dst = _output;
ctx->op.key_index = ctx->key_index;
ctx->op.len = inlen - ctx->super.algo->tag_size;
ctx->op.tag_len = ctx->super.algo->tag_size;
ctx->op.tag = ctx->op.src + ctx->op.len;
vnet_crypto_process_ops (vm, &ctx->op, 1);
if (ctx->op.status != VNET_CRYPTO_OP_STATUS_COMPLETED)
return SIZE_MAX;
return ctx->op.len;
}
static size_t
quic_crypto_offload_aead_decrypt (quic_ctx_t * qctx,
ptls_aead_context_t * _ctx, void *_output,
const void *input, size_t inlen,
uint64_t decrypted_pn, const void *aad,
size_t aadlen)
{
struct aead_crypto_context_t *ctx = (struct aead_crypto_context_t *) _ctx;
vnet_crypto_op_id_t id;
if (!strcmp (ctx->super.algo->name, "AES128-GCM"))
{
id = VNET_CRYPTO_OP_AES_128_GCM_DEC;
}
else if (!strcmp (ctx->super.algo->name, "AES256-GCM"))
{
id = VNET_CRYPTO_OP_AES_256_GCM_DEC;
}
else
{
return SIZE_MAX;
}
quic_main_t *qm = &quic_main;
quic_crypto_batch_ctx_t *quic_crypto_batch_ctx =
&qm->wrk_ctx[qctx->c_thread_index].crypto_context_batch;
vnet_crypto_op_t *vnet_op =
&quic_crypto_batch_ctx->aead_crypto_rx_packets_ops
[quic_crypto_batch_ctx->nb_rx_packets];
vnet_crypto_op_init (vnet_op, id);
vnet_op->aad = (u8 *) aad;
vnet_op->aad_len = aadlen;
vnet_op->iv = clib_mem_alloc (PTLS_MAX_IV_SIZE);
build_iv (_ctx, vnet_op->iv, decrypted_pn);
vnet_op->src = (u8 *) input;
vnet_op->dst = _output;
vnet_op->key_index = ctx->key_index;
vnet_op->len = inlen - ctx->super.algo->tag_size;
vnet_op->tag_len = ctx->super.algo->tag_size;
vnet_op->tag = vnet_op->src + vnet_op->len;
quic_crypto_batch_ctx->nb_rx_packets++;
return vnet_op->len;
}
static void
quic_crypto_aead_dispose_crypto (ptls_aead_context_t * _ctx)
{
}
static int
quic_crypto_aead_setup_crypto (ptls_aead_context_t * _ctx, int is_enc,
const void *key, const EVP_CIPHER * cipher)
{
vlib_main_t *vm = vlib_get_main ();
struct aead_crypto_context_t *ctx = (struct aead_crypto_context_t *) _ctx;
vnet_crypto_alg_t algo;
if (!strcmp (ctx->super.algo->name, "AES128-GCM"))
{
algo = VNET_CRYPTO_ALG_AES_128_GCM;
}
else if (!strcmp (ctx->super.algo->name, "AES256-GCM"))
{
algo = VNET_CRYPTO_ALG_AES_256_GCM;
}
else
{
QUIC_DBG (1, "%s, invalied aead cipher %s", __FUNCTION__,
_ctx->algo->name);
assert (0);
}
ctx->super.do_decrypt = quic_crypto_aead_decrypt;
ctx->super.do_encrypt_init = quic_crypto_aead_encrypt_init;
ctx->super.do_encrypt_update = quic_crypto_aead_encrypt_update;
ctx->super.do_encrypt_final = quic_crypto_aead_encrypt_final;
ctx->super.dispose_crypto = quic_crypto_aead_dispose_crypto;
clib_rwlock_writer_lock (&quic_main.crypto_keys_quic_rw_lock);
ctx->key_index = vnet_crypto_key_add (vm, algo,
(u8 *) key, _ctx->algo->key_size);
clib_rwlock_writer_unlock (&quic_main.crypto_keys_quic_rw_lock);
return 0;
}
static int
quic_crypto_aead_aes128gcm_setup_crypto (ptls_aead_context_t * ctx,
int is_enc, const void *key)
{
return quic_crypto_aead_setup_crypto (ctx, is_enc, key, EVP_aes_128_gcm ());
}
static int
quic_crypto_aead_aes256gcm_setup_crypto (ptls_aead_context_t * ctx,
int is_enc, const void *key)
{
return quic_crypto_aead_setup_crypto (ctx, is_enc, key, EVP_aes_256_gcm ());
}
#ifdef QUIC_HP_CRYPTO
ptls_cipher_algorithm_t quic_crypto_aes128ctr = {
"AES128-CTR",
PTLS_AES128_KEY_SIZE,
1, PTLS_AES_IV_SIZE,
sizeof (struct cipher_context_t), aes128ctr_setup_crypto
};
ptls_cipher_algorithm_t quic_crypto_aes256ctr = {
"AES256-CTR", PTLS_AES256_KEY_SIZE, 1 /* block size */ ,
PTLS_AES_IV_SIZE, sizeof (struct cipher_context_t), aes256ctr_setup_crypto
};
#endif
ptls_aead_algorithm_t quic_crypto_aes128gcm = {
"AES128-GCM",
#ifdef QUIC_HP_CRYPTO
&quic_crypto_aes128ctr,
#else
&ptls_openssl_aes128ctr,
#endif
&ptls_openssl_aes128ecb,
PTLS_AES128_KEY_SIZE,
PTLS_AESGCM_IV_SIZE,
PTLS_AESGCM_TAG_SIZE,
sizeof (struct aead_crypto_context_t),
quic_crypto_aead_aes128gcm_setup_crypto
};
ptls_aead_algorithm_t quic_crypto_aes256gcm = {
"AES256-GCM",
#ifdef QUIC_HP_CRYPTO
&quic_crypto_aes256ctr,
#else
&ptls_openssl_aes256ctr,
#endif
&ptls_openssl_aes256ecb,
PTLS_AES256_KEY_SIZE,
PTLS_AESGCM_IV_SIZE,
PTLS_AESGCM_TAG_SIZE,
sizeof (struct aead_crypto_context_t),
quic_crypto_aead_aes256gcm_setup_crypto
};
ptls_cipher_suite_t quic_crypto_aes128gcmsha256 = {
PTLS_CIPHER_SUITE_AES_128_GCM_SHA256,
&quic_crypto_aes128gcm, &ptls_openssl_sha256
};
ptls_cipher_suite_t quic_crypto_aes256gcmsha384 = {
PTLS_CIPHER_SUITE_AES_256_GCM_SHA384,
&quic_crypto_aes256gcm, &ptls_openssl_sha384
};
ptls_cipher_suite_t *quic_crypto_cipher_suites[] = {
&quic_crypto_aes256gcmsha384, &quic_crypto_aes128gcmsha256, NULL
};
quicly_crypto_engine_t quic_crypto_engine = {
quic_crypto_setup_cipher, quic_crypto_finalize_send_packet_cb
};
int
quic_encrypt_ticket_cb (ptls_encrypt_ticket_t * _self, ptls_t * tls,
int is_encrypt, ptls_buffer_t * dst, ptls_iovec_t src)
{
quic_session_cache_t *self = (void *) _self;
int ret;
if (is_encrypt)
{
/* replace the cached entry along with a newly generated session id */
clib_mem_free (self->data.base);
if ((self->data.base = clib_mem_alloc (src.len)) == NULL)
return PTLS_ERROR_NO_MEMORY;
ptls_get_context (tls)->random_bytes (self->id, sizeof (self->id));
clib_memcpy (self->data.base, src.base, src.len);
self->data.len = src.len;
/* store the session id in buffer */
if ((ret = ptls_buffer_reserve (dst, sizeof (self->id))) != 0)
return ret;
clib_memcpy (dst->base + dst->off, self->id, sizeof (self->id));
dst->off += sizeof (self->id);
}
else
{
/* check if session id is the one stored in cache */
if (src.len != sizeof (self->id))
return PTLS_ERROR_SESSION_NOT_FOUND;
if (clib_memcmp (self->id, src.base, sizeof (self->id)) != 0)
return PTLS_ERROR_SESSION_NOT_FOUND;
/* return the cached value */
if ((ret = ptls_buffer_reserve (dst, self->data.len)) != 0)
return ret;
clib_memcpy (dst->base + dst->off, self->data.base, self->data.len);
dst->off += self->data.len;
}
return 0;
}
/*
* fd.io coding-style-patch-verification: ON
*
* Local Variables:
* eval: (c-set-style "gnu")
* End:
*/
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