1 /* 2 * Copyright 2023-2024 The OpenSSL Project Authors. All Rights Reserved. 3 * 4 * Licensed under the Apache License 2.0 (the "License"). You may not use 5 * this file except in compliance with the License. You can obtain a copy 6 * in the file LICENSE in the source distribution or at 7 * https://www.openssl.org/source/license.html 8 */ 9 10 #include "internal/quic_srtm.h" 11 #include "internal/common.h" 12 #include <openssl/lhash.h> 13 #include <openssl/core_names.h> 14 #include <openssl/rand.h> 15 16 /* 17 * QUIC Stateless Reset Token Manager 18 * ================================== 19 */ 20 typedef struct srtm_item_st SRTM_ITEM; 21 22 #define BLINDED_SRT_LEN 16 23 24 DEFINE_LHASH_OF_EX(SRTM_ITEM); 25 26 /* 27 * The SRTM is implemented using two LHASH instances, one matching opaque pointers to 28 * an item structure, and another matching a SRT-derived value to an item 29 * structure. Multiple items with different seq_num values under a given opaque, 30 * and duplicate SRTs, are handled using sorted singly-linked lists. 31 * 32 * The O(n) insert and lookup performance is tolerated on the basis that the 33 * total number of entries for a given opaque (total number of extant CIDs for a 34 * connection) should be quite small, and the QUIC protocol allows us to place a 35 * hard limit on this via the active_connection_id_limit TPARAM. Thus there is 36 * no risk of a large number of SRTs needing to be registered under a given 37 * opaque. 38 * 39 * It is expected one SRTM will exist per QUIC_PORT and track all SRTs across 40 * all connections for that QUIC_PORT. 41 */ 42 struct srtm_item_st { 43 SRTM_ITEM *next_by_srt_blinded; /* SORT BY opaque DESC */ 44 SRTM_ITEM *next_by_seq_num; /* SORT BY seq_num DESC */ 45 void *opaque; /* \__ unique identity for item */ 46 uint64_t seq_num; /* / */ 47 QUIC_STATELESS_RESET_TOKEN srt; 48 unsigned char srt_blinded[BLINDED_SRT_LEN]; /* H(srt) */ 49 50 #ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION 51 uint32_t debug_token; 52 #endif 53 }; 54 55 struct quic_srtm_st { 56 /* Crypto context used to calculate blinded SRTs H(srt). */ 57 EVP_CIPHER_CTX *blind_ctx; /* kept with key */ 58 59 LHASH_OF(SRTM_ITEM) *items_fwd; /* (opaque) -> SRTM_ITEM */ 60 LHASH_OF(SRTM_ITEM) *items_rev; /* (H(srt)) -> SRTM_ITEM */ 61 62 /* 63 * Monotonically transitions to 1 in event of allocation failure. The only 64 * valid operation on such an object is to free it. 65 */ 66 unsigned int alloc_failed : 1; 67 }; 68 69 static unsigned long items_fwd_hash(const SRTM_ITEM *item) 70 { 71 return (unsigned long)(uintptr_t)item->opaque; 72 } 73 74 static int items_fwd_cmp(const SRTM_ITEM *a, const SRTM_ITEM *b) 75 { 76 return a->opaque != b->opaque; 77 } 78 79 static unsigned long items_rev_hash(const SRTM_ITEM *item) 80 { 81 /* 82 * srt_blinded has already been through a crypto-grade hash function, so we 83 * can just use bits from that. 84 */ 85 unsigned long l; 86 87 memcpy(&l, item->srt_blinded, sizeof(l)); 88 return l; 89 } 90 91 static int items_rev_cmp(const SRTM_ITEM *a, const SRTM_ITEM *b) 92 { 93 /* 94 * We don't need to use CRYPTO_memcmp here as the relationship of 95 * srt_blinded to srt is already cryptographically obfuscated. 96 */ 97 return memcmp(a->srt_blinded, b->srt_blinded, sizeof(a->srt_blinded)); 98 } 99 100 static int srtm_check_lh(QUIC_SRTM *srtm, LHASH_OF(SRTM_ITEM) *lh) 101 { 102 if (lh_SRTM_ITEM_error(lh)) { 103 srtm->alloc_failed = 1; 104 return 0; 105 } 106 107 return 1; 108 } 109 110 QUIC_SRTM *ossl_quic_srtm_new(OSSL_LIB_CTX *libctx, const char *propq) 111 { 112 QUIC_SRTM *srtm = NULL; 113 unsigned char key[16]; 114 EVP_CIPHER *ecb = NULL; 115 116 if (RAND_priv_bytes_ex(libctx, key, sizeof(key), sizeof(key) * 8) != 1) 117 goto err; 118 119 if ((srtm = OPENSSL_zalloc(sizeof(*srtm))) == NULL) 120 return NULL; 121 122 /* Use AES-128-ECB as a permutation over 128-bit SRTs. */ 123 if ((ecb = EVP_CIPHER_fetch(libctx, "AES-128-ECB", propq)) == NULL) 124 goto err; 125 126 if ((srtm->blind_ctx = EVP_CIPHER_CTX_new()) == NULL) 127 goto err; 128 129 if (!EVP_EncryptInit_ex2(srtm->blind_ctx, ecb, key, NULL, NULL)) 130 goto err; 131 132 EVP_CIPHER_free(ecb); 133 ecb = NULL; 134 135 /* Create mappings. */ 136 if ((srtm->items_fwd = lh_SRTM_ITEM_new(items_fwd_hash, items_fwd_cmp)) == NULL 137 || (srtm->items_rev = lh_SRTM_ITEM_new(items_rev_hash, items_rev_cmp)) == NULL) 138 goto err; 139 140 return srtm; 141 142 err: 143 /* 144 * No cleansing of key needed as blinding exists only for side channel 145 * mitigation. 146 */ 147 ossl_quic_srtm_free(srtm); 148 EVP_CIPHER_free(ecb); 149 return NULL; 150 } 151 152 static void srtm_free_each(SRTM_ITEM *ihead) 153 { 154 SRTM_ITEM *inext, *item = ihead; 155 156 for (item = item->next_by_seq_num; item != NULL; item = inext) { 157 inext = item->next_by_seq_num; 158 OPENSSL_free(item); 159 } 160 161 OPENSSL_free(ihead); 162 } 163 164 void ossl_quic_srtm_free(QUIC_SRTM *srtm) 165 { 166 if (srtm == NULL) 167 return; 168 169 lh_SRTM_ITEM_free(srtm->items_rev); 170 if (srtm->items_fwd != NULL) { 171 lh_SRTM_ITEM_doall(srtm->items_fwd, srtm_free_each); 172 lh_SRTM_ITEM_free(srtm->items_fwd); 173 } 174 175 EVP_CIPHER_CTX_free(srtm->blind_ctx); 176 OPENSSL_free(srtm); 177 } 178 179 /* 180 * Find a SRTM_ITEM by (opaque, seq_num). Returns NULL if no match. 181 * If head is non-NULL, writes the head of the relevant opaque list to *head if 182 * there is one. 183 * If prev is non-NULL, writes the previous node to *prev or NULL if it is 184 * the first item. 185 */ 186 static SRTM_ITEM *srtm_find(QUIC_SRTM *srtm, void *opaque, uint64_t seq_num, 187 SRTM_ITEM **head_p, SRTM_ITEM **prev_p) 188 { 189 SRTM_ITEM key, *item = NULL, *prev = NULL; 190 191 key.opaque = opaque; 192 193 item = lh_SRTM_ITEM_retrieve(srtm->items_fwd, &key); 194 if (head_p != NULL) 195 *head_p = item; 196 197 for (; item != NULL; prev = item, item = item->next_by_seq_num) 198 if (item->seq_num == seq_num) { 199 break; 200 } else if (item->seq_num < seq_num) { 201 /* 202 * List is sorted in descending order so there can't be any match 203 * after this. 204 */ 205 item = NULL; 206 break; 207 } 208 209 if (prev_p != NULL) 210 *prev_p = prev; 211 212 return item; 213 } 214 215 /* 216 * Inserts a SRTM_ITEM into the singly-linked by-sequence-number linked list. 217 * The new head pointer is written to *new_head (which may or may not be 218 * unchanged). 219 */ 220 static void sorted_insert_seq_num(SRTM_ITEM *head, SRTM_ITEM *item, SRTM_ITEM **new_head) 221 { 222 uint64_t seq_num = item->seq_num; 223 SRTM_ITEM *cur = head, **fixup = new_head; 224 225 *new_head = head; 226 227 while (cur != NULL && cur->seq_num > seq_num) { 228 fixup = &cur->next_by_seq_num; 229 cur = cur->next_by_seq_num; 230 } 231 232 item->next_by_seq_num = *fixup; 233 *fixup = item; 234 } 235 236 /* 237 * Inserts a SRTM_ITEM into the singly-linked by-SRT list. 238 * The new head pointer is written to *new_head (which may or may not be 239 * unchanged). 240 */ 241 static void sorted_insert_srt(SRTM_ITEM *head, SRTM_ITEM *item, SRTM_ITEM **new_head) 242 { 243 uintptr_t opaque = (uintptr_t)item->opaque; 244 SRTM_ITEM *cur = head, **fixup = new_head; 245 246 *new_head = head; 247 248 while (cur != NULL && (uintptr_t)cur->opaque > opaque) { 249 fixup = &cur->next_by_srt_blinded; 250 cur = cur->next_by_srt_blinded; 251 } 252 253 item->next_by_srt_blinded = *fixup; 254 *fixup = item; 255 } 256 257 /* 258 * Computes the blinded SRT value used for internal lookup for side channel 259 * mitigation purposes. We compute this once as a cached value when an SRTM_ITEM 260 * is formed. 261 */ 262 static int srtm_compute_blinded(QUIC_SRTM *srtm, SRTM_ITEM *item, 263 const QUIC_STATELESS_RESET_TOKEN *token) 264 { 265 int outl = 0; 266 267 /* 268 * We use AES-128-ECB as a permutation using a random key to facilitate 269 * blinding for side-channel purposes. Encrypt the token as a single AES 270 * block. 271 */ 272 if (!EVP_EncryptUpdate(srtm->blind_ctx, item->srt_blinded, &outl, 273 (const unsigned char *)token, sizeof(*token))) 274 return 0; 275 276 if (!ossl_assert(outl == sizeof(*token))) 277 return 0; 278 279 return 1; 280 } 281 282 int ossl_quic_srtm_add(QUIC_SRTM *srtm, void *opaque, uint64_t seq_num, 283 const QUIC_STATELESS_RESET_TOKEN *token) 284 { 285 SRTM_ITEM *item = NULL, *head = NULL, *new_head, *r_item; 286 287 if (srtm->alloc_failed) 288 return 0; 289 290 /* (opaque, seq_num) duplicates not allowed */ 291 if ((item = srtm_find(srtm, opaque, seq_num, &head, NULL)) != NULL) 292 return 0; 293 294 if ((item = OPENSSL_zalloc(sizeof(*item))) == NULL) 295 return 0; 296 297 item->opaque = opaque; 298 item->seq_num = seq_num; 299 item->srt = *token; 300 if (!srtm_compute_blinded(srtm, item, &item->srt)) { 301 OPENSSL_free(item); 302 return 0; 303 } 304 305 /* Add to forward mapping. */ 306 if (head == NULL) { 307 /* First item under this opaque */ 308 lh_SRTM_ITEM_insert(srtm->items_fwd, item); 309 if (!srtm_check_lh(srtm, srtm->items_fwd)) { 310 OPENSSL_free(item); 311 return 0; 312 } 313 } else { 314 sorted_insert_seq_num(head, item, &new_head); 315 if (new_head != head) { /* head changed, update in lhash */ 316 lh_SRTM_ITEM_insert(srtm->items_fwd, new_head); 317 if (!srtm_check_lh(srtm, srtm->items_fwd)) { 318 OPENSSL_free(item); 319 return 0; 320 } 321 } 322 } 323 324 /* Add to reverse mapping. */ 325 r_item = lh_SRTM_ITEM_retrieve(srtm->items_rev, item); 326 if (r_item == NULL) { 327 /* First item under this blinded SRT */ 328 lh_SRTM_ITEM_insert(srtm->items_rev, item); 329 if (!srtm_check_lh(srtm, srtm->items_rev)) 330 /* 331 * Can't free the item now as we would have to undo the insertion 332 * into the forward mapping which would require an insert operation 333 * to restore the previous value. which might also fail. However, 334 * the item will be freed OK when we free the entire SRTM. 335 */ 336 return 0; 337 } else { 338 sorted_insert_srt(r_item, item, &new_head); 339 if (new_head != r_item) { /* head changed, update in lhash */ 340 lh_SRTM_ITEM_insert(srtm->items_rev, new_head); 341 if (!srtm_check_lh(srtm, srtm->items_rev)) 342 /* As above. */ 343 return 0; 344 } 345 } 346 347 return 1; 348 } 349 350 /* Remove item from reverse mapping. */ 351 static int srtm_remove_from_rev(QUIC_SRTM *srtm, SRTM_ITEM *item) 352 { 353 SRTM_ITEM *rh_item; 354 355 rh_item = lh_SRTM_ITEM_retrieve(srtm->items_rev, item); 356 assert(rh_item != NULL); 357 if (rh_item == item) { 358 /* 359 * Change lhash to point to item after this one, or remove the entry if 360 * this is the last one. 361 */ 362 if (item->next_by_srt_blinded != NULL) { 363 lh_SRTM_ITEM_insert(srtm->items_rev, item->next_by_srt_blinded); 364 if (!srtm_check_lh(srtm, srtm->items_rev)) 365 return 0; 366 } else { 367 lh_SRTM_ITEM_delete(srtm->items_rev, item); 368 } 369 } else { 370 /* Find our entry in the SRT list */ 371 for (; rh_item->next_by_srt_blinded != item; 372 rh_item = rh_item->next_by_srt_blinded); 373 rh_item->next_by_srt_blinded = item->next_by_srt_blinded; 374 } 375 376 return 1; 377 } 378 379 int ossl_quic_srtm_remove(QUIC_SRTM *srtm, void *opaque, uint64_t seq_num) 380 { 381 SRTM_ITEM *item, *prev = NULL; 382 383 if (srtm->alloc_failed) 384 return 0; 385 386 if ((item = srtm_find(srtm, opaque, seq_num, NULL, &prev)) == NULL) 387 /* No match */ 388 return 0; 389 390 /* Remove from forward mapping. */ 391 if (prev == NULL) { 392 /* 393 * Change lhash to point to item after this one, or remove the entry if 394 * this is the last one. 395 */ 396 if (item->next_by_seq_num != NULL) { 397 lh_SRTM_ITEM_insert(srtm->items_fwd, item->next_by_seq_num); 398 if (!srtm_check_lh(srtm, srtm->items_fwd)) 399 return 0; 400 } else { 401 lh_SRTM_ITEM_delete(srtm->items_fwd, item); 402 } 403 } else { 404 prev->next_by_seq_num = item->next_by_seq_num; 405 } 406 407 /* Remove from reverse mapping. */ 408 if (!srtm_remove_from_rev(srtm, item)) 409 return 0; 410 411 OPENSSL_free(item); 412 return 1; 413 } 414 415 int ossl_quic_srtm_cull(QUIC_SRTM *srtm, void *opaque) 416 { 417 SRTM_ITEM key, *item = NULL, *inext, *ihead; 418 419 key.opaque = opaque; 420 421 if (srtm->alloc_failed) 422 return 0; 423 424 if ((ihead = lh_SRTM_ITEM_retrieve(srtm->items_fwd, &key)) == NULL) 425 return 1; /* nothing removed is a success condition */ 426 427 for (item = ihead; item != NULL; item = inext) { 428 inext = item->next_by_seq_num; 429 if (item != ihead) { 430 srtm_remove_from_rev(srtm, item); 431 OPENSSL_free(item); 432 } 433 } 434 435 lh_SRTM_ITEM_delete(srtm->items_fwd, ihead); 436 srtm_remove_from_rev(srtm, ihead); 437 OPENSSL_free(ihead); 438 return 1; 439 } 440 441 int ossl_quic_srtm_lookup(QUIC_SRTM *srtm, 442 const QUIC_STATELESS_RESET_TOKEN *token, 443 size_t idx, 444 void **opaque, uint64_t *seq_num) 445 { 446 SRTM_ITEM key, *item; 447 448 if (srtm->alloc_failed) 449 return 0; 450 451 if (!srtm_compute_blinded(srtm, &key, token)) 452 return 0; 453 454 item = lh_SRTM_ITEM_retrieve(srtm->items_rev, &key); 455 for (; idx > 0 && item != NULL; --idx, item = item->next_by_srt_blinded); 456 if (item == NULL) 457 return 0; 458 459 if (opaque != NULL) 460 *opaque = item->opaque; 461 if (seq_num != NULL) 462 *seq_num = item->seq_num; 463 464 return 1; 465 } 466 467 #ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION 468 469 static uint32_t token_next = 0x5eadbeef; 470 static size_t tokens_seen; 471 472 struct check_args { 473 uint32_t token; 474 int mode; 475 }; 476 477 static void check_mark(SRTM_ITEM *item, void *arg) 478 { 479 struct check_args *arg_ = arg; 480 uint32_t token = arg_->token; 481 uint64_t prev_seq_num = 0; 482 void *prev_opaque = NULL; 483 int have_prev = 0; 484 485 assert(item != NULL); 486 487 while (item != NULL) { 488 if (have_prev) { 489 assert(!(item->opaque == prev_opaque && item->seq_num == prev_seq_num)); 490 if (!arg_->mode) 491 assert(item->opaque != prev_opaque || item->seq_num < prev_seq_num); 492 } 493 494 ++tokens_seen; 495 item->debug_token = token; 496 prev_opaque = item->opaque; 497 prev_seq_num = item->seq_num; 498 have_prev = 1; 499 500 if (arg_->mode) 501 item = item->next_by_srt_blinded; 502 else 503 item = item->next_by_seq_num; 504 } 505 } 506 507 static void check_count(SRTM_ITEM *item, void *arg) 508 { 509 struct check_args *arg_ = arg; 510 uint32_t token = arg_->token; 511 512 assert(item != NULL); 513 514 while (item != NULL) { 515 ++tokens_seen; 516 assert(item->debug_token == token); 517 518 if (arg_->mode) 519 item = item->next_by_seq_num; 520 else 521 item = item->next_by_srt_blinded; 522 } 523 } 524 525 #endif 526 527 void ossl_quic_srtm_check(const QUIC_SRTM *srtm) 528 { 529 #ifdef FUZZING_BUILD_MODE_UNSAFE_FOR_PRODUCTION 530 struct check_args args = {0}; 531 size_t tokens_expected, tokens_expected_old; 532 533 args.token = token_next; 534 ++token_next; 535 536 assert(srtm != NULL); 537 assert(srtm->blind_ctx != NULL); 538 assert(srtm->items_fwd != NULL); 539 assert(srtm->items_rev != NULL); 540 541 tokens_seen = 0; 542 lh_SRTM_ITEM_doall_arg(srtm->items_fwd, check_mark, &args); 543 544 tokens_expected = tokens_seen; 545 tokens_seen = 0; 546 lh_SRTM_ITEM_doall_arg(srtm->items_rev, check_count, &args); 547 548 assert(tokens_seen == tokens_expected); 549 tokens_expected_old = tokens_expected; 550 551 args.token = token_next; 552 ++token_next; 553 554 args.mode = 1; 555 tokens_seen = 0; 556 lh_SRTM_ITEM_doall_arg(srtm->items_rev, check_mark, &args); 557 558 tokens_expected = tokens_seen; 559 tokens_seen = 0; 560 lh_SRTM_ITEM_doall_arg(srtm->items_fwd, check_count, &args); 561 562 assert(tokens_seen == tokens_expected); 563 assert(tokens_seen == tokens_expected_old); 564 #endif 565 } 566