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openssl/ssl/quic/quic_srtm.c
Richard Levitte b646179229 Copyright year updates 
Reviewed-by: Neil Horman <nhorman@openssl.org>
Release: yes
(cherry picked from commit 0ce7d1f355)

Reviewed-by: Hugo Landau <hlandau@openssl.org>
Reviewed-by: Tomas Mraz <tomas@openssl.org>
(Merged from https://github.com/openssl/openssl/pull/24034)
2024-04-09 13:43:26 +02:00

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/*
* Copyright 2023-2024 The OpenSSL Project Authors. All Rights Reserved.
*
* Licensed under the Apache License 2.0 (the "License"). You may not use
* this file except in compliance with the License. You can obtain a copy
* in the file LICENSE in the source distribution or at
* https://www.openssl.org/source/license.html
*/
#include "internal/quic_srtm.h"
#include "internal/common.h"
#include <openssl/lhash.h>
#include <openssl/core_names.h>
#include <openssl/rand.h>
/*
* QUIC Stateless Reset Token Manager
* ==================================
*/
typedef struct srtm_item_st SRTM_ITEM;
#define BLINDED_SRT_LEN 16
DEFINE_LHASH_OF_EX(SRTM_ITEM);
/*
* The SRTM is implemented using two LHASH instances, one matching opaque pointers to
* an item structure, and another matching a SRT-derived value to an item
* structure. Multiple items with different seq_num values under a given opaque,
* and duplicate SRTs, are handled using sorted singly-linked lists.
*
* The O(n) insert and lookup performance is tolerated on the basis that the
* total number of entries for a given opaque (total number of extant CIDs for a
* connection) should be quite small, and the QUIC protocol allows us to place a
* hard limit on this via the active_connection_id_limit TPARAM. Thus there is
* no risk of a large number of SRTs needing to be registered under a given
* opaque.
*
* It is expected one SRTM will exist per QUIC_PORT and track all SRTs across
* all connections for that QUIC_PORT.
*/
struct srtm_item_st {
SRTM_ITEM *next_by_srt_blinded; /* SORT BY opaque DESC */
SRTM_ITEM *next_by_seq_num; /* SORT BY seq_num DESC */
void *opaque; /* \__ unique identity for item */
uint64_t seq_num; /* / */
QUIC_STATELESS_RESET_TOKEN srt;
unsigned char srt_blinded[BLINDED_SRT_LEN]; /* H(srt) */
#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
uint32_t debug_token;
#endif
};
struct quic_srtm_st {
/* Crypto context used to calculate blinded SRTs H(srt). */
EVP_CIPHER_CTX *blind_ctx; /* kept with key */
LHASH_OF(SRTM_ITEM) *items_fwd; /* (opaque) -> SRTM_ITEM */
LHASH_OF(SRTM_ITEM) *items_rev; /* (H(srt)) -> SRTM_ITEM */
/*
* Monotonically transitions to 1 in event of allocation failure. The only
* valid operation on such an object is to free it.
*/
unsigned int alloc_failed : 1;
};
static unsigned long items_fwd_hash(const SRTM_ITEM *item)
{
return (unsigned long)(uintptr_t)item->opaque;
}
static int items_fwd_cmp(const SRTM_ITEM *a, const SRTM_ITEM *b)
{
return a->opaque != b->opaque;
}
static unsigned long items_rev_hash(const SRTM_ITEM *item)
{
/*
* srt_blinded has already been through a crypto-grade hash function, so we
* can just use bits from that.
*/
unsigned long l;
memcpy(&l, item->srt_blinded, sizeof(l));
return l;
}
static int items_rev_cmp(const SRTM_ITEM *a, const SRTM_ITEM *b)
{
/*
* We don't need to use CRYPTO_memcmp here as the relationship of
* srt_blinded to srt is already cryptographically obfuscated.
*/
return memcmp(a->srt_blinded, b->srt_blinded, sizeof(a->srt_blinded));
}
static int srtm_check_lh(QUIC_SRTM *srtm, LHASH_OF(SRTM_ITEM) *lh)
{
if (lh_SRTM_ITEM_error(lh)) {
srtm->alloc_failed = 1;
return 0;
}
return 1;
}
QUIC_SRTM *ossl_quic_srtm_new(OSSL_LIB_CTX *libctx, const char *propq)
{
QUIC_SRTM *srtm = NULL;
unsigned char key[16];
EVP_CIPHER *ecb = NULL;
if (RAND_priv_bytes_ex(libctx, key, sizeof(key), sizeof(key) * 8) != 1)
goto err;
if ((srtm = OPENSSL_zalloc(sizeof(*srtm))) == NULL)
return NULL;
/* Use AES-128-ECB as a permutation over 128-bit SRTs. */
if ((ecb = EVP_CIPHER_fetch(libctx, "AES-128-ECB", propq)) == NULL)
goto err;
if ((srtm->blind_ctx = EVP_CIPHER_CTX_new()) == NULL)
goto err;
if (!EVP_EncryptInit_ex2(srtm->blind_ctx, ecb, key, NULL, NULL))
goto err;
EVP_CIPHER_free(ecb);
ecb = NULL;
/* Create mappings. */
if ((srtm->items_fwd = lh_SRTM_ITEM_new(items_fwd_hash, items_fwd_cmp)) == NULL
|| (srtm->items_rev = lh_SRTM_ITEM_new(items_rev_hash, items_rev_cmp)) == NULL)
goto err;
return srtm;
err:
/*
* No cleansing of key needed as blinding exists only for side channel
* mitigation.
*/
ossl_quic_srtm_free(srtm);
EVP_CIPHER_free(ecb);
return NULL;
}
static void srtm_free_each(SRTM_ITEM *ihead)
{
SRTM_ITEM *inext, *item = ihead;
for (item = item->next_by_seq_num; item != NULL; item = inext) {
inext = item->next_by_seq_num;
OPENSSL_free(item);
}
OPENSSL_free(ihead);
}
void ossl_quic_srtm_free(QUIC_SRTM *srtm)
{
if (srtm == NULL)
return;
lh_SRTM_ITEM_free(srtm->items_rev);
if (srtm->items_fwd != NULL) {
lh_SRTM_ITEM_doall(srtm->items_fwd, srtm_free_each);
lh_SRTM_ITEM_free(srtm->items_fwd);
}
EVP_CIPHER_CTX_free(srtm->blind_ctx);
OPENSSL_free(srtm);
}
/*
* Find a SRTM_ITEM by (opaque, seq_num). Returns NULL if no match.
* If head is non-NULL, writes the head of the relevant opaque list to *head if
* there is one.
* If prev is non-NULL, writes the previous node to *prev or NULL if it is
* the first item.
*/
static SRTM_ITEM *srtm_find(QUIC_SRTM *srtm, void *opaque, uint64_t seq_num,
SRTM_ITEM **head_p, SRTM_ITEM **prev_p)
{
SRTM_ITEM key, *item = NULL, *prev = NULL;
key.opaque = opaque;
item = lh_SRTM_ITEM_retrieve(srtm->items_fwd, &key);
if (head_p != NULL)
*head_p = item;
for (; item != NULL; prev = item, item = item->next_by_seq_num)
if (item->seq_num == seq_num) {
break;
} else if (item->seq_num < seq_num) {
/*
* List is sorted in descending order so there can't be any match
* after this.
*/
item = NULL;
break;
}
if (prev_p != NULL)
*prev_p = prev;
return item;
}
/*
* Inserts a SRTM_ITEM into the singly-linked by-sequence-number linked list.
* The new head pointer is written to *new_head (which may or may not be
* unchanged).
*/
static void sorted_insert_seq_num(SRTM_ITEM *head, SRTM_ITEM *item, SRTM_ITEM **new_head)
{
uint64_t seq_num = item->seq_num;
SRTM_ITEM *cur = head, **fixup = new_head;
*new_head = head;
while (cur != NULL && cur->seq_num > seq_num) {
fixup = &cur->next_by_seq_num;
cur = cur->next_by_seq_num;
}
item->next_by_seq_num = *fixup;
*fixup = item;
}
/*
* Inserts a SRTM_ITEM into the singly-linked by-SRT list.
* The new head pointer is written to *new_head (which may or may not be
* unchanged).
*/
static void sorted_insert_srt(SRTM_ITEM *head, SRTM_ITEM *item, SRTM_ITEM **new_head)
{
uintptr_t opaque = (uintptr_t)item->opaque;
SRTM_ITEM *cur = head, **fixup = new_head;
*new_head = head;
while (cur != NULL && (uintptr_t)cur->opaque > opaque) {
fixup = &cur->next_by_srt_blinded;
cur = cur->next_by_srt_blinded;
}
item->next_by_srt_blinded = *fixup;
*fixup = item;
}
/*
* Computes the blinded SRT value used for internal lookup for side channel
* mitigation purposes. We compute this once as a cached value when an SRTM_ITEM
* is formed.
*/
static int srtm_compute_blinded(QUIC_SRTM *srtm, SRTM_ITEM *item,
const QUIC_STATELESS_RESET_TOKEN *token)
{
int outl = 0;
/*
* We use AES-128-ECB as a permutation using a random key to facilitate
* blinding for side-channel purposes. Encrypt the token as a single AES
* block.
*/
if (!EVP_EncryptUpdate(srtm->blind_ctx, item->srt_blinded, &outl,
(const unsigned char *)token, sizeof(*token)))
return 0;
if (!ossl_assert(outl == sizeof(*token)))
return 0;
return 1;
}
int ossl_quic_srtm_add(QUIC_SRTM *srtm, void *opaque, uint64_t seq_num,
const QUIC_STATELESS_RESET_TOKEN *token)
{
SRTM_ITEM *item = NULL, *head = NULL, *new_head, *r_item;
if (srtm->alloc_failed)
return 0;
/* (opaque, seq_num) duplicates not allowed */
if ((item = srtm_find(srtm, opaque, seq_num, &head, NULL)) != NULL)
return 0;
if ((item = OPENSSL_zalloc(sizeof(*item))) == NULL)
return 0;
item->opaque = opaque;
item->seq_num = seq_num;
item->srt = *token;
if (!srtm_compute_blinded(srtm, item, &item->srt)) {
OPENSSL_free(item);
return 0;
}
/* Add to forward mapping. */
if (head == NULL) {
/* First item under this opaque */
lh_SRTM_ITEM_insert(srtm->items_fwd, item);
if (!srtm_check_lh(srtm, srtm->items_fwd)) {
OPENSSL_free(item);
return 0;
}
} else {
sorted_insert_seq_num(head, item, &new_head);
if (new_head != head) { /* head changed, update in lhash */
lh_SRTM_ITEM_insert(srtm->items_fwd, new_head);
if (!srtm_check_lh(srtm, srtm->items_fwd)) {
OPENSSL_free(item);
return 0;
}
}
}
/* Add to reverse mapping. */
r_item = lh_SRTM_ITEM_retrieve(srtm->items_rev, item);
if (r_item == NULL) {
/* First item under this blinded SRT */
lh_SRTM_ITEM_insert(srtm->items_rev, item);
if (!srtm_check_lh(srtm, srtm->items_rev))
/*
* Can't free the item now as we would have to undo the insertion
* into the forward mapping which would require an insert operation
* to restore the previous value. which might also fail. However,
* the item will be freed OK when we free the entire SRTM.
*/
return 0;
} else {
sorted_insert_srt(r_item, item, &new_head);
if (new_head != r_item) { /* head changed, update in lhash */
lh_SRTM_ITEM_insert(srtm->items_rev, new_head);
if (!srtm_check_lh(srtm, srtm->items_rev))
/* As above. */
return 0;
}
}
return 1;
}
/* Remove item from reverse mapping. */
static int srtm_remove_from_rev(QUIC_SRTM *srtm, SRTM_ITEM *item)
{
SRTM_ITEM *rh_item;
rh_item = lh_SRTM_ITEM_retrieve(srtm->items_rev, item);
assert(rh_item != NULL);
if (rh_item == item) {
/*
* Change lhash to point to item after this one, or remove the entry if
* this is the last one.
*/
if (item->next_by_srt_blinded != NULL) {
lh_SRTM_ITEM_insert(srtm->items_rev, item->next_by_srt_blinded);
if (!srtm_check_lh(srtm, srtm->items_rev))
return 0;
} else {
lh_SRTM_ITEM_delete(srtm->items_rev, item);
}
} else {
/* Find our entry in the SRT list */
for (; rh_item->next_by_srt_blinded != item;
rh_item = rh_item->next_by_srt_blinded);
rh_item->next_by_srt_blinded = item->next_by_srt_blinded;
}
return 1;
}
int ossl_quic_srtm_remove(QUIC_SRTM *srtm, void *opaque, uint64_t seq_num)
{
SRTM_ITEM *item, *prev = NULL;
if (srtm->alloc_failed)
return 0;
if ((item = srtm_find(srtm, opaque, seq_num, NULL, &prev)) == NULL)
/* No match */
return 0;
/* Remove from forward mapping. */
if (prev == NULL) {
/*
* Change lhash to point to item after this one, or remove the entry if
* this is the last one.
*/
if (item->next_by_seq_num != NULL) {
lh_SRTM_ITEM_insert(srtm->items_fwd, item->next_by_seq_num);
if (!srtm_check_lh(srtm, srtm->items_fwd))
return 0;
} else {
lh_SRTM_ITEM_delete(srtm->items_fwd, item);
}
} else {
prev->next_by_seq_num = item->next_by_seq_num;
}
/* Remove from reverse mapping. */
if (!srtm_remove_from_rev(srtm, item))
return 0;
OPENSSL_free(item);
return 1;
}
int ossl_quic_srtm_cull(QUIC_SRTM *srtm, void *opaque)
{
SRTM_ITEM key, *item = NULL, *inext, *ihead;
key.opaque = opaque;
if (srtm->alloc_failed)
return 0;
if ((ihead = lh_SRTM_ITEM_retrieve(srtm->items_fwd, &key)) == NULL)
return 1; /* nothing removed is a success condition */
for (item = ihead; item != NULL; item = inext) {
inext = item->next_by_seq_num;
if (item != ihead) {
srtm_remove_from_rev(srtm, item);
OPENSSL_free(item);
}
}
lh_SRTM_ITEM_delete(srtm->items_fwd, ihead);
srtm_remove_from_rev(srtm, ihead);
OPENSSL_free(ihead);
return 1;
}
int ossl_quic_srtm_lookup(QUIC_SRTM *srtm,
const QUIC_STATELESS_RESET_TOKEN *token,
size_t idx,
void **opaque, uint64_t *seq_num)
{
SRTM_ITEM key, *item;
if (srtm->alloc_failed)
return 0;
if (!srtm_compute_blinded(srtm, &key, token))
return 0;
item = lh_SRTM_ITEM_retrieve(srtm->items_rev, &key);
for (; idx > 0 && item != NULL; --idx, item = item->next_by_srt_blinded);
if (item == NULL)
return 0;
if (opaque != NULL)
*opaque = item->opaque;
if (seq_num != NULL)
*seq_num = item->seq_num;
return 1;
}
#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
static uint32_t token_next = 0x5eadbeef;
static size_t tokens_seen;
struct check_args {
uint32_t token;
int mode;
};
static void check_mark(SRTM_ITEM *item, void *arg)
{
struct check_args *arg_ = arg;
uint32_t token = arg_->token;
uint64_t prev_seq_num = 0;
void *prev_opaque = NULL;
int have_prev = 0;
assert(item != NULL);
while (item != NULL) {
if (have_prev) {
assert(!(item->opaque == prev_opaque && item->seq_num == prev_seq_num));
if (!arg_->mode)
assert(item->opaque != prev_opaque || item->seq_num < prev_seq_num);
}
++tokens_seen;
item->debug_token = token;
prev_opaque = item->opaque;
prev_seq_num = item->seq_num;
have_prev = 1;
if (arg_->mode)
item = item->next_by_srt_blinded;
else
item = item->next_by_seq_num;
}
}
static void check_count(SRTM_ITEM *item, void *arg)
{
struct check_args *arg_ = arg;
uint32_t token = arg_->token;
assert(item != NULL);
while (item != NULL) {
++tokens_seen;
assert(item->debug_token == token);
if (arg_->mode)
item = item->next_by_seq_num;
else
item = item->next_by_srt_blinded;
}
}
#endif
void ossl_quic_srtm_check(const QUIC_SRTM *srtm)
{
#ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION
struct check_args args = {0};
size_t tokens_expected, tokens_expected_old;
args.token = token_next;
++token_next;
assert(srtm != NULL);
assert(srtm->blind_ctx != NULL);
assert(srtm->items_fwd != NULL);
assert(srtm->items_rev != NULL);
tokens_seen = 0;
lh_SRTM_ITEM_doall_arg(srtm->items_fwd, check_mark, &args);
tokens_expected = tokens_seen;
tokens_seen = 0;
lh_SRTM_ITEM_doall_arg(srtm->items_rev, check_count, &args);
assert(tokens_seen == tokens_expected);
tokens_expected_old = tokens_expected;
args.token = token_next;
++token_next;
args.mode = 1;
tokens_seen = 0;
lh_SRTM_ITEM_doall_arg(srtm->items_rev, check_mark, &args);
tokens_expected = tokens_seen;
tokens_seen = 0;
lh_SRTM_ITEM_doall_arg(srtm->items_fwd, check_count, &args);
assert(tokens_seen == tokens_expected);
assert(tokens_seen == tokens_expected_old);
#endif
}
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