1 /* $OpenBSD: xmss_fast.c,v 1.3 2018/03/22 07:06:11 markus Exp $ */ 2 /* 3 xmss_fast.c version 20160722 4 Andreas Hülsing 5 Joost Rijneveld 6 Public domain. 7 */ 8 9 #include "includes.h" 10 #ifdef WITH_XMSS 11 12 #include <stdlib.h> 13 #include <string.h> 14 #ifdef HAVE_STDINT_H 15 #include <stdint.h> 16 #endif 17 18 #include "xmss_fast.h" 19 #include "crypto_api.h" 20 #include "xmss_wots.h" 21 #include "xmss_hash.h" 22 23 #include "xmss_commons.h" 24 #include "xmss_hash_address.h" 25 // For testing 26 #include "stdio.h" 27 28 29 30 /** 31 * Used for pseudorandom keygeneration, 32 * generates the seed for the WOTS keypair at address addr 33 * 34 * takes n byte sk_seed and returns n byte seed using 32 byte address addr. 35 */ 36 static void get_seed(unsigned char *seed, const unsigned char *sk_seed, int n, uint32_t addr[8]) 37 { 38 unsigned char bytes[32]; 39 // Make sure that chain addr, hash addr, and key bit are 0! 40 setChainADRS(addr,0); 41 setHashADRS(addr,0); 42 setKeyAndMask(addr,0); 43 // Generate pseudorandom value 44 addr_to_byte(bytes, addr); 45 prf(seed, bytes, sk_seed, n); 46 } 47 48 /** 49 * Initialize xmss params struct 50 * parameter names are the same as in the draft 51 * parameter k is K as used in the BDS algorithm 52 */ 53 int xmss_set_params(xmss_params *params, int n, int h, int w, int k) 54 { 55 if (k >= h || k < 2 || (h - k) % 2) { 56 fprintf(stderr, "For BDS traversal, H - K must be even, with H > K >= 2!\n"); 57 return 1; 58 } 59 params->h = h; 60 params->n = n; 61 params->k = k; 62 wots_params wots_par; 63 wots_set_params(&wots_par, n, w); 64 params->wots_par = wots_par; 65 return 0; 66 } 67 68 /** 69 * Initialize BDS state struct 70 * parameter names are the same as used in the description of the BDS traversal 71 */ 72 void xmss_set_bds_state(bds_state *state, unsigned char *stack, int stackoffset, unsigned char *stacklevels, unsigned char *auth, unsigned char *keep, treehash_inst *treehash, unsigned char *retain, int next_leaf) 73 { 74 state->stack = stack; 75 state->stackoffset = stackoffset; 76 state->stacklevels = stacklevels; 77 state->auth = auth; 78 state->keep = keep; 79 state->treehash = treehash; 80 state->retain = retain; 81 state->next_leaf = next_leaf; 82 } 83 84 /** 85 * Initialize xmssmt_params struct 86 * parameter names are the same as in the draft 87 * 88 * Especially h is the total tree height, i.e. the XMSS trees have height h/d 89 */ 90 int xmssmt_set_params(xmssmt_params *params, int n, int h, int d, int w, int k) 91 { 92 if (h % d) { 93 fprintf(stderr, "d must divide h without remainder!\n"); 94 return 1; 95 } 96 params->h = h; 97 params->d = d; 98 params->n = n; 99 params->index_len = (h + 7) / 8; 100 xmss_params xmss_par; 101 if (xmss_set_params(&xmss_par, n, (h/d), w, k)) { 102 return 1; 103 } 104 params->xmss_par = xmss_par; 105 return 0; 106 } 107 108 /** 109 * Computes a leaf from a WOTS public key using an L-tree. 110 */ 111 static void l_tree(unsigned char *leaf, unsigned char *wots_pk, const xmss_params *params, const unsigned char *pub_seed, uint32_t addr[8]) 112 { 113 unsigned int l = params->wots_par.len; 114 unsigned int n = params->n; 115 uint32_t i = 0; 116 uint32_t height = 0; 117 uint32_t bound; 118 119 //ADRS.setTreeHeight(0); 120 setTreeHeight(addr, height); 121 122 while (l > 1) { 123 bound = l >> 1; //floor(l / 2); 124 for (i = 0; i < bound; i++) { 125 //ADRS.setTreeIndex(i); 126 setTreeIndex(addr, i); 127 //wots_pk[i] = RAND_HASH(pk[2i], pk[2i + 1], SEED, ADRS); 128 hash_h(wots_pk+i*n, wots_pk+i*2*n, pub_seed, addr, n); 129 } 130 //if ( l % 2 == 1 ) { 131 if (l & 1) { 132 //pk[floor(l / 2) + 1] = pk[l]; 133 memcpy(wots_pk+(l>>1)*n, wots_pk+(l-1)*n, n); 134 //l = ceil(l / 2); 135 l=(l>>1)+1; 136 } 137 else { 138 //l = ceil(l / 2); 139 l=(l>>1); 140 } 141 //ADRS.setTreeHeight(ADRS.getTreeHeight() + 1); 142 height++; 143 setTreeHeight(addr, height); 144 } 145 //return pk[0]; 146 memcpy(leaf, wots_pk, n); 147 } 148 149 /** 150 * Computes the leaf at a given address. First generates the WOTS key pair, then computes leaf using l_tree. As this happens position independent, we only require that addr encodes the right ltree-address. 151 */ 152 static void gen_leaf_wots(unsigned char *leaf, const unsigned char *sk_seed, const xmss_params *params, const unsigned char *pub_seed, uint32_t ltree_addr[8], uint32_t ots_addr[8]) 153 { 154 unsigned char seed[params->n]; 155 unsigned char pk[params->wots_par.keysize]; 156 157 get_seed(seed, sk_seed, params->n, ots_addr); 158 wots_pkgen(pk, seed, &(params->wots_par), pub_seed, ots_addr); 159 160 l_tree(leaf, pk, params, pub_seed, ltree_addr); 161 } 162 163 static int treehash_minheight_on_stack(bds_state* state, const xmss_params *params, const treehash_inst *treehash) { 164 unsigned int r = params->h, i; 165 for (i = 0; i < treehash->stackusage; i++) { 166 if (state->stacklevels[state->stackoffset - i - 1] < r) { 167 r = state->stacklevels[state->stackoffset - i - 1]; 168 } 169 } 170 return r; 171 } 172 173 /** 174 * Merkle's TreeHash algorithm. The address only needs to initialize the first 78 bits of addr. Everything else will be set by treehash. 175 * Currently only used for key generation. 176 * 177 */ 178 static void treehash_setup(unsigned char *node, int height, int index, bds_state *state, const unsigned char *sk_seed, const xmss_params *params, const unsigned char *pub_seed, const uint32_t addr[8]) 179 { 180 unsigned int idx = index; 181 unsigned int n = params->n; 182 unsigned int h = params->h; 183 unsigned int k = params->k; 184 // use three different addresses because at this point we use all three formats in parallel 185 uint32_t ots_addr[8]; 186 uint32_t ltree_addr[8]; 187 uint32_t node_addr[8]; 188 // only copy layer and tree address parts 189 memcpy(ots_addr, addr, 12); 190 // type = ots 191 setType(ots_addr, 0); 192 memcpy(ltree_addr, addr, 12); 193 setType(ltree_addr, 1); 194 memcpy(node_addr, addr, 12); 195 setType(node_addr, 2); 196 197 uint32_t lastnode, i; 198 unsigned char stack[(height+1)*n]; 199 unsigned int stacklevels[height+1]; 200 unsigned int stackoffset=0; 201 unsigned int nodeh; 202 203 lastnode = idx+(1<<height); 204 205 for (i = 0; i < h-k; i++) { 206 state->treehash[i].h = i; 207 state->treehash[i].completed = 1; 208 state->treehash[i].stackusage = 0; 209 } 210 211 i = 0; 212 for (; idx < lastnode; idx++) { 213 setLtreeADRS(ltree_addr, idx); 214 setOTSADRS(ots_addr, idx); 215 gen_leaf_wots(stack+stackoffset*n, sk_seed, params, pub_seed, ltree_addr, ots_addr); 216 stacklevels[stackoffset] = 0; 217 stackoffset++; 218 if (h - k > 0 && i == 3) { 219 memcpy(state->treehash[0].node, stack+stackoffset*n, n); 220 } 221 while (stackoffset>1 && stacklevels[stackoffset-1] == stacklevels[stackoffset-2]) 222 { 223 nodeh = stacklevels[stackoffset-1]; 224 if (i >> nodeh == 1) { 225 memcpy(state->auth + nodeh*n, stack+(stackoffset-1)*n, n); 226 } 227 else { 228 if (nodeh < h - k && i >> nodeh == 3) { 229 memcpy(state->treehash[nodeh].node, stack+(stackoffset-1)*n, n); 230 } 231 else if (nodeh >= h - k) { 232 memcpy(state->retain + ((1 << (h - 1 - nodeh)) + nodeh - h + (((i >> nodeh) - 3) >> 1)) * n, stack+(stackoffset-1)*n, n); 233 } 234 } 235 setTreeHeight(node_addr, stacklevels[stackoffset-1]); 236 setTreeIndex(node_addr, (idx >> (stacklevels[stackoffset-1]+1))); 237 hash_h(stack+(stackoffset-2)*n, stack+(stackoffset-2)*n, pub_seed, 238 node_addr, n); 239 stacklevels[stackoffset-2]++; 240 stackoffset--; 241 } 242 i++; 243 } 244 245 for (i = 0; i < n; i++) 246 node[i] = stack[i]; 247 } 248 249 static void treehash_update(treehash_inst *treehash, bds_state *state, const unsigned char *sk_seed, const xmss_params *params, const unsigned char *pub_seed, const uint32_t addr[8]) { 250 int n = params->n; 251 252 uint32_t ots_addr[8]; 253 uint32_t ltree_addr[8]; 254 uint32_t node_addr[8]; 255 // only copy layer and tree address parts 256 memcpy(ots_addr, addr, 12); 257 // type = ots 258 setType(ots_addr, 0); 259 memcpy(ltree_addr, addr, 12); 260 setType(ltree_addr, 1); 261 memcpy(node_addr, addr, 12); 262 setType(node_addr, 2); 263 264 setLtreeADRS(ltree_addr, treehash->next_idx); 265 setOTSADRS(ots_addr, treehash->next_idx); 266 267 unsigned char nodebuffer[2 * n]; 268 unsigned int nodeheight = 0; 269 gen_leaf_wots(nodebuffer, sk_seed, params, pub_seed, ltree_addr, ots_addr); 270 while (treehash->stackusage > 0 && state->stacklevels[state->stackoffset-1] == nodeheight) { 271 memcpy(nodebuffer + n, nodebuffer, n); 272 memcpy(nodebuffer, state->stack + (state->stackoffset-1)*n, n); 273 setTreeHeight(node_addr, nodeheight); 274 setTreeIndex(node_addr, (treehash->next_idx >> (nodeheight+1))); 275 hash_h(nodebuffer, nodebuffer, pub_seed, node_addr, n); 276 nodeheight++; 277 treehash->stackusage--; 278 state->stackoffset--; 279 } 280 if (nodeheight == treehash->h) { // this also implies stackusage == 0 281 memcpy(treehash->node, nodebuffer, n); 282 treehash->completed = 1; 283 } 284 else { 285 memcpy(state->stack + state->stackoffset*n, nodebuffer, n); 286 treehash->stackusage++; 287 state->stacklevels[state->stackoffset] = nodeheight; 288 state->stackoffset++; 289 treehash->next_idx++; 290 } 291 } 292 293 /** 294 * Computes a root node given a leaf and an authapth 295 */ 296 static void validate_authpath(unsigned char *root, const unsigned char *leaf, unsigned long leafidx, const unsigned char *authpath, const xmss_params *params, const unsigned char *pub_seed, uint32_t addr[8]) 297 { 298 unsigned int n = params->n; 299 300 uint32_t i, j; 301 unsigned char buffer[2*n]; 302 303 // If leafidx is odd (last bit = 1), current path element is a right child and authpath has to go to the left. 304 // Otherwise, it is the other way around 305 if (leafidx & 1) { 306 for (j = 0; j < n; j++) 307 buffer[n+j] = leaf[j]; 308 for (j = 0; j < n; j++) 309 buffer[j] = authpath[j]; 310 } 311 else { 312 for (j = 0; j < n; j++) 313 buffer[j] = leaf[j]; 314 for (j = 0; j < n; j++) 315 buffer[n+j] = authpath[j]; 316 } 317 authpath += n; 318 319 for (i=0; i < params->h-1; i++) { 320 setTreeHeight(addr, i); 321 leafidx >>= 1; 322 setTreeIndex(addr, leafidx); 323 if (leafidx&1) { 324 hash_h(buffer+n, buffer, pub_seed, addr, n); 325 for (j = 0; j < n; j++) 326 buffer[j] = authpath[j]; 327 } 328 else { 329 hash_h(buffer, buffer, pub_seed, addr, n); 330 for (j = 0; j < n; j++) 331 buffer[j+n] = authpath[j]; 332 } 333 authpath += n; 334 } 335 setTreeHeight(addr, (params->h-1)); 336 leafidx >>= 1; 337 setTreeIndex(addr, leafidx); 338 hash_h(root, buffer, pub_seed, addr, n); 339 } 340 341 /** 342 * Performs one treehash update on the instance that needs it the most. 343 * Returns 1 if such an instance was not found 344 **/ 345 static char bds_treehash_update(bds_state *state, unsigned int updates, const unsigned char *sk_seed, const xmss_params *params, unsigned char *pub_seed, const uint32_t addr[8]) { 346 uint32_t i, j; 347 unsigned int level, l_min, low; 348 unsigned int h = params->h; 349 unsigned int k = params->k; 350 unsigned int used = 0; 351 352 for (j = 0; j < updates; j++) { 353 l_min = h; 354 level = h - k; 355 for (i = 0; i < h - k; i++) { 356 if (state->treehash[i].completed) { 357 low = h; 358 } 359 else if (state->treehash[i].stackusage == 0) { 360 low = i; 361 } 362 else { 363 low = treehash_minheight_on_stack(state, params, &(state->treehash[i])); 364 } 365 if (low < l_min) { 366 level = i; 367 l_min = low; 368 } 369 } 370 if (level == h - k) { 371 break; 372 } 373 treehash_update(&(state->treehash[level]), state, sk_seed, params, pub_seed, addr); 374 used++; 375 } 376 return updates - used; 377 } 378 379 /** 380 * Updates the state (typically NEXT_i) by adding a leaf and updating the stack 381 * Returns 1 if all leaf nodes have already been processed 382 **/ 383 static char bds_state_update(bds_state *state, const unsigned char *sk_seed, const xmss_params *params, unsigned char *pub_seed, const uint32_t addr[8]) { 384 uint32_t ltree_addr[8]; 385 uint32_t node_addr[8]; 386 uint32_t ots_addr[8]; 387 388 int n = params->n; 389 int h = params->h; 390 int k = params->k; 391 392 int nodeh; 393 int idx = state->next_leaf; 394 if (idx == 1 << h) { 395 return 1; 396 } 397 398 // only copy layer and tree address parts 399 memcpy(ots_addr, addr, 12); 400 // type = ots 401 setType(ots_addr, 0); 402 memcpy(ltree_addr, addr, 12); 403 setType(ltree_addr, 1); 404 memcpy(node_addr, addr, 12); 405 setType(node_addr, 2); 406 407 setOTSADRS(ots_addr, idx); 408 setLtreeADRS(ltree_addr, idx); 409 410 gen_leaf_wots(state->stack+state->stackoffset*n, sk_seed, params, pub_seed, ltree_addr, ots_addr); 411 412 state->stacklevels[state->stackoffset] = 0; 413 state->stackoffset++; 414 if (h - k > 0 && idx == 3) { 415 memcpy(state->treehash[0].node, state->stack+state->stackoffset*n, n); 416 } 417 while (state->stackoffset>1 && state->stacklevels[state->stackoffset-1] == state->stacklevels[state->stackoffset-2]) { 418 nodeh = state->stacklevels[state->stackoffset-1]; 419 if (idx >> nodeh == 1) { 420 memcpy(state->auth + nodeh*n, state->stack+(state->stackoffset-1)*n, n); 421 } 422 else { 423 if (nodeh < h - k && idx >> nodeh == 3) { 424 memcpy(state->treehash[nodeh].node, state->stack+(state->stackoffset-1)*n, n); 425 } 426 else if (nodeh >= h - k) { 427 memcpy(state->retain + ((1 << (h - 1 - nodeh)) + nodeh - h + (((idx >> nodeh) - 3) >> 1)) * n, state->stack+(state->stackoffset-1)*n, n); 428 } 429 } 430 setTreeHeight(node_addr, state->stacklevels[state->stackoffset-1]); 431 setTreeIndex(node_addr, (idx >> (state->stacklevels[state->stackoffset-1]+1))); 432 hash_h(state->stack+(state->stackoffset-2)*n, state->stack+(state->stackoffset-2)*n, pub_seed, node_addr, n); 433 434 state->stacklevels[state->stackoffset-2]++; 435 state->stackoffset--; 436 } 437 state->next_leaf++; 438 return 0; 439 } 440 441 /** 442 * Returns the auth path for node leaf_idx and computes the auth path for the 443 * next leaf node, using the algorithm described by Buchmann, Dahmen and Szydlo 444 * in "Post Quantum Cryptography", Springer 2009. 445 */ 446 static void bds_round(bds_state *state, const unsigned long leaf_idx, const unsigned char *sk_seed, const xmss_params *params, unsigned char *pub_seed, uint32_t addr[8]) 447 { 448 unsigned int i; 449 unsigned int n = params->n; 450 unsigned int h = params->h; 451 unsigned int k = params->k; 452 453 unsigned int tau = h; 454 unsigned int startidx; 455 unsigned int offset, rowidx; 456 unsigned char buf[2 * n]; 457 458 uint32_t ots_addr[8]; 459 uint32_t ltree_addr[8]; 460 uint32_t node_addr[8]; 461 // only copy layer and tree address parts 462 memcpy(ots_addr, addr, 12); 463 // type = ots 464 setType(ots_addr, 0); 465 memcpy(ltree_addr, addr, 12); 466 setType(ltree_addr, 1); 467 memcpy(node_addr, addr, 12); 468 setType(node_addr, 2); 469 470 for (i = 0; i < h; i++) { 471 if (! ((leaf_idx >> i) & 1)) { 472 tau = i; 473 break; 474 } 475 } 476 477 if (tau > 0) { 478 memcpy(buf, state->auth + (tau-1) * n, n); 479 // we need to do this before refreshing state->keep to prevent overwriting 480 memcpy(buf + n, state->keep + ((tau-1) >> 1) * n, n); 481 } 482 if (!((leaf_idx >> (tau + 1)) & 1) && (tau < h - 1)) { 483 memcpy(state->keep + (tau >> 1)*n, state->auth + tau*n, n); 484 } 485 if (tau == 0) { 486 setLtreeADRS(ltree_addr, leaf_idx); 487 setOTSADRS(ots_addr, leaf_idx); 488 gen_leaf_wots(state->auth, sk_seed, params, pub_seed, ltree_addr, ots_addr); 489 } 490 else { 491 setTreeHeight(node_addr, (tau-1)); 492 setTreeIndex(node_addr, leaf_idx >> tau); 493 hash_h(state->auth + tau * n, buf, pub_seed, node_addr, n); 494 for (i = 0; i < tau; i++) { 495 if (i < h - k) { 496 memcpy(state->auth + i * n, state->treehash[i].node, n); 497 } 498 else { 499 offset = (1 << (h - 1 - i)) + i - h; 500 rowidx = ((leaf_idx >> i) - 1) >> 1; 501 memcpy(state->auth + i * n, state->retain + (offset + rowidx) * n, n); 502 } 503 } 504 505 for (i = 0; i < ((tau < h - k) ? tau : (h - k)); i++) { 506 startidx = leaf_idx + 1 + 3 * (1 << i); 507 if (startidx < 1U << h) { 508 state->treehash[i].h = i; 509 state->treehash[i].next_idx = startidx; 510 state->treehash[i].completed = 0; 511 state->treehash[i].stackusage = 0; 512 } 513 } 514 } 515 } 516 517 /* 518 * Generates a XMSS key pair for a given parameter set. 519 * Format sk: [(32bit) idx || SK_SEED || SK_PRF || PUB_SEED || root] 520 * Format pk: [root || PUB_SEED] omitting algo oid. 521 */ 522 int xmss_keypair(unsigned char *pk, unsigned char *sk, bds_state *state, xmss_params *params) 523 { 524 unsigned int n = params->n; 525 // Set idx = 0 526 sk[0] = 0; 527 sk[1] = 0; 528 sk[2] = 0; 529 sk[3] = 0; 530 // Init SK_SEED (n byte), SK_PRF (n byte), and PUB_SEED (n byte) 531 randombytes(sk+4, 3*n); 532 // Copy PUB_SEED to public key 533 memcpy(pk+n, sk+4+2*n, n); 534 535 uint32_t addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 536 537 // Compute root 538 treehash_setup(pk, params->h, 0, state, sk+4, params, sk+4+2*n, addr); 539 // copy root to sk 540 memcpy(sk+4+3*n, pk, n); 541 return 0; 542 } 543 544 /** 545 * Signs a message. 546 * Returns 547 * 1. an array containing the signature followed by the message AND 548 * 2. an updated secret key! 549 * 550 */ 551 int xmss_sign(unsigned char *sk, bds_state *state, unsigned char *sig_msg, unsigned long long *sig_msg_len, const unsigned char *msg, unsigned long long msglen, const xmss_params *params) 552 { 553 unsigned int h = params->h; 554 unsigned int n = params->n; 555 unsigned int k = params->k; 556 uint16_t i = 0; 557 558 // Extract SK 559 unsigned long idx = ((unsigned long)sk[0] << 24) | ((unsigned long)sk[1] << 16) | ((unsigned long)sk[2] << 8) | sk[3]; 560 unsigned char sk_seed[n]; 561 memcpy(sk_seed, sk+4, n); 562 unsigned char sk_prf[n]; 563 memcpy(sk_prf, sk+4+n, n); 564 unsigned char pub_seed[n]; 565 memcpy(pub_seed, sk+4+2*n, n); 566 567 // index as 32 bytes string 568 unsigned char idx_bytes_32[32]; 569 to_byte(idx_bytes_32, idx, 32); 570 571 unsigned char hash_key[3*n]; 572 573 // Update SK 574 sk[0] = ((idx + 1) >> 24) & 255; 575 sk[1] = ((idx + 1) >> 16) & 255; 576 sk[2] = ((idx + 1) >> 8) & 255; 577 sk[3] = (idx + 1) & 255; 578 // -- Secret key for this non-forward-secure version is now updated. 579 // -- A productive implementation should use a file handle instead and write the updated secret key at this point! 580 581 // Init working params 582 unsigned char R[n]; 583 unsigned char msg_h[n]; 584 unsigned char ots_seed[n]; 585 uint32_t ots_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 586 587 // --------------------------------- 588 // Message Hashing 589 // --------------------------------- 590 591 // Message Hash: 592 // First compute pseudorandom value 593 prf(R, idx_bytes_32, sk_prf, n); 594 // Generate hash key (R || root || idx) 595 memcpy(hash_key, R, n); 596 memcpy(hash_key+n, sk+4+3*n, n); 597 to_byte(hash_key+2*n, idx, n); 598 // Then use it for message digest 599 h_msg(msg_h, msg, msglen, hash_key, 3*n, n); 600 601 // Start collecting signature 602 *sig_msg_len = 0; 603 604 // Copy index to signature 605 sig_msg[0] = (idx >> 24) & 255; 606 sig_msg[1] = (idx >> 16) & 255; 607 sig_msg[2] = (idx >> 8) & 255; 608 sig_msg[3] = idx & 255; 609 610 sig_msg += 4; 611 *sig_msg_len += 4; 612 613 // Copy R to signature 614 for (i = 0; i < n; i++) 615 sig_msg[i] = R[i]; 616 617 sig_msg += n; 618 *sig_msg_len += n; 619 620 // ---------------------------------- 621 // Now we start to "really sign" 622 // ---------------------------------- 623 624 // Prepare Address 625 setType(ots_addr, 0); 626 setOTSADRS(ots_addr, idx); 627 628 // Compute seed for OTS key pair 629 get_seed(ots_seed, sk_seed, n, ots_addr); 630 631 // Compute WOTS signature 632 wots_sign(sig_msg, msg_h, ots_seed, &(params->wots_par), pub_seed, ots_addr); 633 634 sig_msg += params->wots_par.keysize; 635 *sig_msg_len += params->wots_par.keysize; 636 637 // the auth path was already computed during the previous round 638 memcpy(sig_msg, state->auth, h*n); 639 640 if (idx < (1U << h) - 1) { 641 bds_round(state, idx, sk_seed, params, pub_seed, ots_addr); 642 bds_treehash_update(state, (h - k) >> 1, sk_seed, params, pub_seed, ots_addr); 643 } 644 645 /* TODO: save key/bds state here! */ 646 647 sig_msg += params->h*n; 648 *sig_msg_len += params->h*n; 649 650 //Whipe secret elements? 651 //zerobytes(tsk, CRYPTO_SECRETKEYBYTES); 652 653 654 memcpy(sig_msg, msg, msglen); 655 *sig_msg_len += msglen; 656 657 return 0; 658 } 659 660 /** 661 * Verifies a given message signature pair under a given public key. 662 */ 663 int xmss_sign_open(unsigned char *msg, unsigned long long *msglen, const unsigned char *sig_msg, unsigned long long sig_msg_len, const unsigned char *pk, const xmss_params *params) 664 { 665 unsigned int n = params->n; 666 667 unsigned long long i, m_len; 668 unsigned long idx=0; 669 unsigned char wots_pk[params->wots_par.keysize]; 670 unsigned char pkhash[n]; 671 unsigned char root[n]; 672 unsigned char msg_h[n]; 673 unsigned char hash_key[3*n]; 674 675 unsigned char pub_seed[n]; 676 memcpy(pub_seed, pk+n, n); 677 678 // Init addresses 679 uint32_t ots_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 680 uint32_t ltree_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 681 uint32_t node_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 682 683 setType(ots_addr, 0); 684 setType(ltree_addr, 1); 685 setType(node_addr, 2); 686 687 // Extract index 688 idx = ((unsigned long)sig_msg[0] << 24) | ((unsigned long)sig_msg[1] << 16) | ((unsigned long)sig_msg[2] << 8) | sig_msg[3]; 689 printf("verify:: idx = %lu\n", idx); 690 691 // Generate hash key (R || root || idx) 692 memcpy(hash_key, sig_msg+4,n); 693 memcpy(hash_key+n, pk, n); 694 to_byte(hash_key+2*n, idx, n); 695 696 sig_msg += (n+4); 697 sig_msg_len -= (n+4); 698 699 // hash message 700 unsigned long long tmp_sig_len = params->wots_par.keysize+params->h*n; 701 m_len = sig_msg_len - tmp_sig_len; 702 h_msg(msg_h, sig_msg + tmp_sig_len, m_len, hash_key, 3*n, n); 703 704 //----------------------- 705 // Verify signature 706 //----------------------- 707 708 // Prepare Address 709 setOTSADRS(ots_addr, idx); 710 // Check WOTS signature 711 wots_pkFromSig(wots_pk, sig_msg, msg_h, &(params->wots_par), pub_seed, ots_addr); 712 713 sig_msg += params->wots_par.keysize; 714 sig_msg_len -= params->wots_par.keysize; 715 716 // Compute Ltree 717 setLtreeADRS(ltree_addr, idx); 718 l_tree(pkhash, wots_pk, params, pub_seed, ltree_addr); 719 720 // Compute root 721 validate_authpath(root, pkhash, idx, sig_msg, params, pub_seed, node_addr); 722 723 sig_msg += params->h*n; 724 sig_msg_len -= params->h*n; 725 726 for (i = 0; i < n; i++) 727 if (root[i] != pk[i]) 728 goto fail; 729 730 *msglen = sig_msg_len; 731 for (i = 0; i < *msglen; i++) 732 msg[i] = sig_msg[i]; 733 734 return 0; 735 736 737 fail: 738 *msglen = sig_msg_len; 739 for (i = 0; i < *msglen; i++) 740 msg[i] = 0; 741 *msglen = -1; 742 return -1; 743 } 744 745 /* 746 * Generates a XMSSMT key pair for a given parameter set. 747 * Format sk: [(ceil(h/8) bit) idx || SK_SEED || SK_PRF || PUB_SEED || root] 748 * Format pk: [root || PUB_SEED] omitting algo oid. 749 */ 750 int xmssmt_keypair(unsigned char *pk, unsigned char *sk, bds_state *states, unsigned char *wots_sigs, xmssmt_params *params) 751 { 752 unsigned int n = params->n; 753 unsigned int i; 754 unsigned char ots_seed[params->n]; 755 // Set idx = 0 756 for (i = 0; i < params->index_len; i++) { 757 sk[i] = 0; 758 } 759 // Init SK_SEED (n byte), SK_PRF (n byte), and PUB_SEED (n byte) 760 randombytes(sk+params->index_len, 3*n); 761 // Copy PUB_SEED to public key 762 memcpy(pk+n, sk+params->index_len+2*n, n); 763 764 // Set address to point on the single tree on layer d-1 765 uint32_t addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 766 setLayerADRS(addr, (params->d-1)); 767 // Set up state and compute wots signatures for all but topmost tree root 768 for (i = 0; i < params->d - 1; i++) { 769 // Compute seed for OTS key pair 770 treehash_setup(pk, params->xmss_par.h, 0, states + i, sk+params->index_len, &(params->xmss_par), pk+n, addr); 771 setLayerADRS(addr, (i+1)); 772 get_seed(ots_seed, sk+params->index_len, n, addr); 773 wots_sign(wots_sigs + i*params->xmss_par.wots_par.keysize, pk, ots_seed, &(params->xmss_par.wots_par), pk+n, addr); 774 } 775 treehash_setup(pk, params->xmss_par.h, 0, states + i, sk+params->index_len, &(params->xmss_par), pk+n, addr); 776 memcpy(sk+params->index_len+3*n, pk, n); 777 return 0; 778 } 779 780 /** 781 * Signs a message. 782 * Returns 783 * 1. an array containing the signature followed by the message AND 784 * 2. an updated secret key! 785 * 786 */ 787 int xmssmt_sign(unsigned char *sk, bds_state *states, unsigned char *wots_sigs, unsigned char *sig_msg, unsigned long long *sig_msg_len, const unsigned char *msg, unsigned long long msglen, const xmssmt_params *params) 788 { 789 unsigned int n = params->n; 790 791 unsigned int tree_h = params->xmss_par.h; 792 unsigned int h = params->h; 793 unsigned int k = params->xmss_par.k; 794 unsigned int idx_len = params->index_len; 795 uint64_t idx_tree; 796 uint32_t idx_leaf; 797 uint64_t i, j; 798 int needswap_upto = -1; 799 unsigned int updates; 800 801 unsigned char sk_seed[n]; 802 unsigned char sk_prf[n]; 803 unsigned char pub_seed[n]; 804 // Init working params 805 unsigned char R[n]; 806 unsigned char msg_h[n]; 807 unsigned char hash_key[3*n]; 808 unsigned char ots_seed[n]; 809 uint32_t addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 810 uint32_t ots_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 811 unsigned char idx_bytes_32[32]; 812 bds_state tmp; 813 814 // Extract SK 815 unsigned long long idx = 0; 816 for (i = 0; i < idx_len; i++) { 817 idx |= ((unsigned long long)sk[i]) << 8*(idx_len - 1 - i); 818 } 819 820 memcpy(sk_seed, sk+idx_len, n); 821 memcpy(sk_prf, sk+idx_len+n, n); 822 memcpy(pub_seed, sk+idx_len+2*n, n); 823 824 // Update SK 825 for (i = 0; i < idx_len; i++) { 826 sk[i] = ((idx + 1) >> 8*(idx_len - 1 - i)) & 255; 827 } 828 // -- Secret key for this non-forward-secure version is now updated. 829 // -- A productive implementation should use a file handle instead and write the updated secret key at this point! 830 831 832 // --------------------------------- 833 // Message Hashing 834 // --------------------------------- 835 836 // Message Hash: 837 // First compute pseudorandom value 838 to_byte(idx_bytes_32, idx, 32); 839 prf(R, idx_bytes_32, sk_prf, n); 840 // Generate hash key (R || root || idx) 841 memcpy(hash_key, R, n); 842 memcpy(hash_key+n, sk+idx_len+3*n, n); 843 to_byte(hash_key+2*n, idx, n); 844 845 // Then use it for message digest 846 h_msg(msg_h, msg, msglen, hash_key, 3*n, n); 847 848 // Start collecting signature 849 *sig_msg_len = 0; 850 851 // Copy index to signature 852 for (i = 0; i < idx_len; i++) { 853 sig_msg[i] = (idx >> 8*(idx_len - 1 - i)) & 255; 854 } 855 856 sig_msg += idx_len; 857 *sig_msg_len += idx_len; 858 859 // Copy R to signature 860 for (i = 0; i < n; i++) 861 sig_msg[i] = R[i]; 862 863 sig_msg += n; 864 *sig_msg_len += n; 865 866 // ---------------------------------- 867 // Now we start to "really sign" 868 // ---------------------------------- 869 870 // Handle lowest layer separately as it is slightly different... 871 872 // Prepare Address 873 setType(ots_addr, 0); 874 idx_tree = idx >> tree_h; 875 idx_leaf = (idx & ((1 << tree_h)-1)); 876 setLayerADRS(ots_addr, 0); 877 setTreeADRS(ots_addr, idx_tree); 878 setOTSADRS(ots_addr, idx_leaf); 879 880 // Compute seed for OTS key pair 881 get_seed(ots_seed, sk_seed, n, ots_addr); 882 883 // Compute WOTS signature 884 wots_sign(sig_msg, msg_h, ots_seed, &(params->xmss_par.wots_par), pub_seed, ots_addr); 885 886 sig_msg += params->xmss_par.wots_par.keysize; 887 *sig_msg_len += params->xmss_par.wots_par.keysize; 888 889 memcpy(sig_msg, states[0].auth, tree_h*n); 890 sig_msg += tree_h*n; 891 *sig_msg_len += tree_h*n; 892 893 // prepare signature of remaining layers 894 for (i = 1; i < params->d; i++) { 895 // put WOTS signature in place 896 memcpy(sig_msg, wots_sigs + (i-1)*params->xmss_par.wots_par.keysize, params->xmss_par.wots_par.keysize); 897 898 sig_msg += params->xmss_par.wots_par.keysize; 899 *sig_msg_len += params->xmss_par.wots_par.keysize; 900 901 // put AUTH nodes in place 902 memcpy(sig_msg, states[i].auth, tree_h*n); 903 sig_msg += tree_h*n; 904 *sig_msg_len += tree_h*n; 905 } 906 907 updates = (tree_h - k) >> 1; 908 909 setTreeADRS(addr, (idx_tree + 1)); 910 // mandatory update for NEXT_0 (does not count towards h-k/2) if NEXT_0 exists 911 if ((1 + idx_tree) * (1 << tree_h) + idx_leaf < (1ULL << h)) { 912 bds_state_update(&states[params->d], sk_seed, &(params->xmss_par), pub_seed, addr); 913 } 914 915 for (i = 0; i < params->d; i++) { 916 // check if we're not at the end of a tree 917 if (! (((idx + 1) & ((1ULL << ((i+1)*tree_h)) - 1)) == 0)) { 918 idx_leaf = (idx >> (tree_h * i)) & ((1 << tree_h)-1); 919 idx_tree = (idx >> (tree_h * (i+1))); 920 setLayerADRS(addr, i); 921 setTreeADRS(addr, idx_tree); 922 if (i == (unsigned int) (needswap_upto + 1)) { 923 bds_round(&states[i], idx_leaf, sk_seed, &(params->xmss_par), pub_seed, addr); 924 } 925 updates = bds_treehash_update(&states[i], updates, sk_seed, &(params->xmss_par), pub_seed, addr); 926 setTreeADRS(addr, (idx_tree + 1)); 927 // if a NEXT-tree exists for this level; 928 if ((1 + idx_tree) * (1 << tree_h) + idx_leaf < (1ULL << (h - tree_h * i))) { 929 if (i > 0 && updates > 0 && states[params->d + i].next_leaf < (1ULL << h)) { 930 bds_state_update(&states[params->d + i], sk_seed, &(params->xmss_par), pub_seed, addr); 931 updates--; 932 } 933 } 934 } 935 else if (idx < (1ULL << h) - 1) { 936 memcpy(&tmp, states+params->d + i, sizeof(bds_state)); 937 memcpy(states+params->d + i, states + i, sizeof(bds_state)); 938 memcpy(states + i, &tmp, sizeof(bds_state)); 939 940 setLayerADRS(ots_addr, (i+1)); 941 setTreeADRS(ots_addr, ((idx + 1) >> ((i+2) * tree_h))); 942 setOTSADRS(ots_addr, (((idx >> ((i+1) * tree_h)) + 1) & ((1 << tree_h)-1))); 943 944 get_seed(ots_seed, sk+params->index_len, n, ots_addr); 945 wots_sign(wots_sigs + i*params->xmss_par.wots_par.keysize, states[i].stack, ots_seed, &(params->xmss_par.wots_par), pub_seed, ots_addr); 946 947 states[params->d + i].stackoffset = 0; 948 states[params->d + i].next_leaf = 0; 949 950 updates--; // WOTS-signing counts as one update 951 needswap_upto = i; 952 for (j = 0; j < tree_h-k; j++) { 953 states[i].treehash[j].completed = 1; 954 } 955 } 956 } 957 958 //Whipe secret elements? 959 //zerobytes(tsk, CRYPTO_SECRETKEYBYTES); 960 961 memcpy(sig_msg, msg, msglen); 962 *sig_msg_len += msglen; 963 964 return 0; 965 } 966 967 /** 968 * Verifies a given message signature pair under a given public key. 969 */ 970 int xmssmt_sign_open(unsigned char *msg, unsigned long long *msglen, const unsigned char *sig_msg, unsigned long long sig_msg_len, const unsigned char *pk, const xmssmt_params *params) 971 { 972 unsigned int n = params->n; 973 974 unsigned int tree_h = params->xmss_par.h; 975 unsigned int idx_len = params->index_len; 976 uint64_t idx_tree; 977 uint32_t idx_leaf; 978 979 unsigned long long i, m_len; 980 unsigned long long idx=0; 981 unsigned char wots_pk[params->xmss_par.wots_par.keysize]; 982 unsigned char pkhash[n]; 983 unsigned char root[n]; 984 unsigned char msg_h[n]; 985 unsigned char hash_key[3*n]; 986 987 unsigned char pub_seed[n]; 988 memcpy(pub_seed, pk+n, n); 989 990 // Init addresses 991 uint32_t ots_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 992 uint32_t ltree_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 993 uint32_t node_addr[8] = {0, 0, 0, 0, 0, 0, 0, 0}; 994 995 // Extract index 996 for (i = 0; i < idx_len; i++) { 997 idx |= ((unsigned long long)sig_msg[i]) << (8*(idx_len - 1 - i)); 998 } 999 printf("verify:: idx = %llu\n", idx); 1000 sig_msg += idx_len; 1001 sig_msg_len -= idx_len; 1002 1003 // Generate hash key (R || root || idx) 1004 memcpy(hash_key, sig_msg,n); 1005 memcpy(hash_key+n, pk, n); 1006 to_byte(hash_key+2*n, idx, n); 1007 1008 sig_msg += n; 1009 sig_msg_len -= n; 1010 1011 1012 // hash message (recall, R is now on pole position at sig_msg 1013 unsigned long long tmp_sig_len = (params->d * params->xmss_par.wots_par.keysize) + (params->h * n); 1014 m_len = sig_msg_len - tmp_sig_len; 1015 h_msg(msg_h, sig_msg + tmp_sig_len, m_len, hash_key, 3*n, n); 1016 1017 1018 //----------------------- 1019 // Verify signature 1020 //----------------------- 1021 1022 // Prepare Address 1023 idx_tree = idx >> tree_h; 1024 idx_leaf = (idx & ((1 << tree_h)-1)); 1025 setLayerADRS(ots_addr, 0); 1026 setTreeADRS(ots_addr, idx_tree); 1027 setType(ots_addr, 0); 1028 1029 memcpy(ltree_addr, ots_addr, 12); 1030 setType(ltree_addr, 1); 1031 1032 memcpy(node_addr, ltree_addr, 12); 1033 setType(node_addr, 2); 1034 1035 setOTSADRS(ots_addr, idx_leaf); 1036 1037 // Check WOTS signature 1038 wots_pkFromSig(wots_pk, sig_msg, msg_h, &(params->xmss_par.wots_par), pub_seed, ots_addr); 1039 1040 sig_msg += params->xmss_par.wots_par.keysize; 1041 sig_msg_len -= params->xmss_par.wots_par.keysize; 1042 1043 // Compute Ltree 1044 setLtreeADRS(ltree_addr, idx_leaf); 1045 l_tree(pkhash, wots_pk, &(params->xmss_par), pub_seed, ltree_addr); 1046 1047 // Compute root 1048 validate_authpath(root, pkhash, idx_leaf, sig_msg, &(params->xmss_par), pub_seed, node_addr); 1049 1050 sig_msg += tree_h*n; 1051 sig_msg_len -= tree_h*n; 1052 1053 for (i = 1; i < params->d; i++) { 1054 // Prepare Address 1055 idx_leaf = (idx_tree & ((1 << tree_h)-1)); 1056 idx_tree = idx_tree >> tree_h; 1057 1058 setLayerADRS(ots_addr, i); 1059 setTreeADRS(ots_addr, idx_tree); 1060 setType(ots_addr, 0); 1061 1062 memcpy(ltree_addr, ots_addr, 12); 1063 setType(ltree_addr, 1); 1064 1065 memcpy(node_addr, ltree_addr, 12); 1066 setType(node_addr, 2); 1067 1068 setOTSADRS(ots_addr, idx_leaf); 1069 1070 // Check WOTS signature 1071 wots_pkFromSig(wots_pk, sig_msg, root, &(params->xmss_par.wots_par), pub_seed, ots_addr); 1072 1073 sig_msg += params->xmss_par.wots_par.keysize; 1074 sig_msg_len -= params->xmss_par.wots_par.keysize; 1075 1076 // Compute Ltree 1077 setLtreeADRS(ltree_addr, idx_leaf); 1078 l_tree(pkhash, wots_pk, &(params->xmss_par), pub_seed, ltree_addr); 1079 1080 // Compute root 1081 validate_authpath(root, pkhash, idx_leaf, sig_msg, &(params->xmss_par), pub_seed, node_addr); 1082 1083 sig_msg += tree_h*n; 1084 sig_msg_len -= tree_h*n; 1085 1086 } 1087 1088 for (i = 0; i < n; i++) 1089 if (root[i] != pk[i]) 1090 goto fail; 1091 1092 *msglen = sig_msg_len; 1093 for (i = 0; i < *msglen; i++) 1094 msg[i] = sig_msg[i]; 1095 1096 return 0; 1097 1098 1099 fail: 1100 *msglen = sig_msg_len; 1101 for (i = 0; i < *msglen; i++) 1102 msg[i] = 0; 1103 *msglen = -1; 1104 return -1; 1105 } 1106 #endif /* WITH_XMSS */ 1107