/* * Implementation of the Skein hash function. * Source code author: Doug Whiting, 2008. * This algorithm and source code is released to the public domain. */ /* Copyright 2013 Doug Whiting. This code is released to the public domain. */ #include #include #include /* get the Skein API definitions */ #include "skein_impl.h" /* get internal definitions */ /* 256-bit Skein */ /* init the context for a straight hashing operation */ int Skein_256_Init(Skein_256_Ctxt_t *ctx, size_t hashBitLen) { union { uint8_t b[SKEIN_256_STATE_BYTES]; uint64_t w[SKEIN_256_STATE_WORDS]; } cfg; /* config block */ Skein_Assert(hashBitLen > 0, SKEIN_BAD_HASHLEN); ctx->h.hashBitLen = hashBitLen; /* output hash bit count */ switch (hashBitLen) { /* use pre-computed values, where available */ #ifndef SKEIN_NO_PRECOMP case 256: memcpy(ctx->X, SKEIN_256_IV_256, sizeof (ctx->X)); break; case 224: memcpy(ctx->X, SKEIN_256_IV_224, sizeof (ctx->X)); break; case 160: memcpy(ctx->X, SKEIN_256_IV_160, sizeof (ctx->X)); break; case 128: memcpy(ctx->X, SKEIN_256_IV_128, sizeof (ctx->X)); break; #endif default: /* here if there is no precomputed IV value available */ /* * build/process the config block, type == CONFIG (could be * precomputed) */ /* set tweaks: T0=0; T1=CFG | FINAL */ Skein_Start_New_Type(ctx, CFG_FINAL); /* set the schema, version */ cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); /* hash result length in bits */ cfg.w[1] = Skein_Swap64(hashBitLen); cfg.w[2] = Skein_Swap64(SKEIN_CFG_TREE_INFO_SEQUENTIAL); /* zero pad config block */ memset(&cfg.w[3], 0, sizeof (cfg) - 3 * sizeof (cfg.w[0])); /* compute the initial chaining values from config block */ /* zero the chaining variables */ memset(ctx->X, 0, sizeof (ctx->X)); Skein_256_Process_Block(ctx, cfg.b, 1, SKEIN_CFG_STR_LEN); break; } /* * The chaining vars ctx->X are now initialized for the given * hashBitLen. * Set up to process the data message portion of the hash (default) */ Skein_Start_New_Type(ctx, MSG); /* T0=0, T1= MSG type */ return (SKEIN_SUCCESS); } /* init the context for a MAC and/or tree hash operation */ /* * [identical to Skein_256_Init() when keyBytes == 0 && * treeInfo == SKEIN_CFG_TREE_INFO_SEQUENTIAL] */ int Skein_256_InitExt(Skein_256_Ctxt_t *ctx, size_t hashBitLen, uint64_t treeInfo, const uint8_t *key, size_t keyBytes) { union { uint8_t b[SKEIN_256_STATE_BYTES]; uint64_t w[SKEIN_256_STATE_WORDS]; } cfg; /* config block */ Skein_Assert(hashBitLen > 0, SKEIN_BAD_HASHLEN); Skein_Assert(keyBytes == 0 || key != NULL, SKEIN_FAIL); /* compute the initial chaining values ctx->X[], based on key */ if (keyBytes == 0) { /* is there a key? */ /* no key: use all zeroes as key for config block */ memset(ctx->X, 0, sizeof (ctx->X)); } else { /* here to pre-process a key */ Skein_assert(sizeof (cfg.b) >= sizeof (ctx->X)); /* do a mini-Init right here */ /* set output hash bit count = state size */ ctx->h.hashBitLen = 8 * sizeof (ctx->X); /* set tweaks: T0 = 0; T1 = KEY type */ Skein_Start_New_Type(ctx, KEY); /* zero the initial chaining variables */ memset(ctx->X, 0, sizeof (ctx->X)); /* hash the key */ (void) Skein_256_Update(ctx, key, keyBytes); /* put result into cfg.b[] */ (void) Skein_256_Final_Pad(ctx, cfg.b); /* copy over into ctx->X[] */ memcpy(ctx->X, cfg.b, sizeof (cfg.b)); #if SKEIN_NEED_SWAP { uint_t i; /* convert key bytes to context words */ for (i = 0; i < SKEIN_256_STATE_WORDS; i++) ctx->X[i] = Skein_Swap64(ctx->X[i]); } #endif } /* * build/process the config block, type == CONFIG (could be * precomputed for each key) */ ctx->h.hashBitLen = hashBitLen; /* output hash bit count */ Skein_Start_New_Type(ctx, CFG_FINAL); memset(&cfg.w, 0, sizeof (cfg.w)); /* pre-pad cfg.w[] with zeroes */ cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); cfg.w[1] = Skein_Swap64(hashBitLen); /* hash result length in bits */ /* tree hash config info (or SKEIN_CFG_TREE_INFO_SEQUENTIAL) */ cfg.w[2] = Skein_Swap64(treeInfo); Skein_Show_Key(256, &ctx->h, key, keyBytes); /* compute the initial chaining values from config block */ Skein_256_Process_Block(ctx, cfg.b, 1, SKEIN_CFG_STR_LEN); /* The chaining vars ctx->X are now initialized */ /* Set up to process the data message portion of the hash (default) */ ctx->h.bCnt = 0; /* buffer b[] starts out empty */ Skein_Start_New_Type(ctx, MSG); return (SKEIN_SUCCESS); } /* process the input bytes */ int Skein_256_Update(Skein_256_Ctxt_t *ctx, const uint8_t *msg, size_t msgByteCnt) { size_t n; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES, SKEIN_FAIL); /* process full blocks, if any */ if (msgByteCnt + ctx->h.bCnt > SKEIN_256_BLOCK_BYTES) { /* finish up any buffered message data */ if (ctx->h.bCnt) { /* # bytes free in buffer b[] */ n = SKEIN_256_BLOCK_BYTES - ctx->h.bCnt; if (n) { /* check on our logic here */ Skein_assert(n < msgByteCnt); memcpy(&ctx->b[ctx->h.bCnt], msg, n); msgByteCnt -= n; msg += n; ctx->h.bCnt += n; } Skein_assert(ctx->h.bCnt == SKEIN_256_BLOCK_BYTES); Skein_256_Process_Block(ctx, ctx->b, 1, SKEIN_256_BLOCK_BYTES); ctx->h.bCnt = 0; } /* * now process any remaining full blocks, directly from input * message data */ if (msgByteCnt > SKEIN_256_BLOCK_BYTES) { /* number of full blocks to process */ n = (msgByteCnt - 1) / SKEIN_256_BLOCK_BYTES; Skein_256_Process_Block(ctx, msg, n, SKEIN_256_BLOCK_BYTES); msgByteCnt -= n * SKEIN_256_BLOCK_BYTES; msg += n * SKEIN_256_BLOCK_BYTES; } Skein_assert(ctx->h.bCnt == 0); } /* copy any remaining source message data bytes into b[] */ if (msgByteCnt) { Skein_assert(msgByteCnt + ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES); memcpy(&ctx->b[ctx->h.bCnt], msg, msgByteCnt); ctx->h.bCnt += msgByteCnt; } return (SKEIN_SUCCESS); } /* finalize the hash computation and output the result */ int Skein_256_Final(Skein_256_Ctxt_t *ctx, uint8_t *hashVal) { size_t i, n, byteCnt; uint64_t X[SKEIN_256_STATE_WORDS]; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES, SKEIN_FAIL); ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */ /* zero pad b[] if necessary */ if (ctx->h.bCnt < SKEIN_256_BLOCK_BYTES) memset(&ctx->b[ctx->h.bCnt], 0, SKEIN_256_BLOCK_BYTES - ctx->h.bCnt); /* process the final block */ Skein_256_Process_Block(ctx, ctx->b, 1, ctx->h.bCnt); /* now output the result */ /* total number of output bytes */ byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* run Threefish in "counter mode" to generate output */ /* zero out b[], so it can hold the counter */ memset(ctx->b, 0, sizeof (ctx->b)); /* keep a local copy of counter mode "key" */ memcpy(X, ctx->X, sizeof (X)); for (i = 0; i * SKEIN_256_BLOCK_BYTES < byteCnt; i++) { /* build the counter block */ *(uint64_t *)ctx->b = Skein_Swap64((uint64_t)i); Skein_Start_New_Type(ctx, OUT_FINAL); /* run "counter mode" */ Skein_256_Process_Block(ctx, ctx->b, 1, sizeof (uint64_t)); /* number of output bytes left to go */ n = byteCnt - i * SKEIN_256_BLOCK_BYTES; if (n >= SKEIN_256_BLOCK_BYTES) n = SKEIN_256_BLOCK_BYTES; Skein_Put64_LSB_First(hashVal + i * SKEIN_256_BLOCK_BYTES, ctx->X, n); /* "output" the ctr mode bytes */ Skein_Show_Final(256, &ctx->h, n, hashVal + i * SKEIN_256_BLOCK_BYTES); /* restore the counter mode key for next time */ memcpy(ctx->X, X, sizeof (X)); } return (SKEIN_SUCCESS); } /* 512-bit Skein */ /* init the context for a straight hashing operation */ int Skein_512_Init(Skein_512_Ctxt_t *ctx, size_t hashBitLen) { union { uint8_t b[SKEIN_512_STATE_BYTES]; uint64_t w[SKEIN_512_STATE_WORDS]; } cfg; /* config block */ Skein_Assert(hashBitLen > 0, SKEIN_BAD_HASHLEN); ctx->h.hashBitLen = hashBitLen; /* output hash bit count */ switch (hashBitLen) { /* use pre-computed values, where available */ #ifndef SKEIN_NO_PRECOMP case 512: memcpy(ctx->X, SKEIN_512_IV_512, sizeof (ctx->X)); break; case 384: memcpy(ctx->X, SKEIN_512_IV_384, sizeof (ctx->X)); break; case 256: memcpy(ctx->X, SKEIN_512_IV_256, sizeof (ctx->X)); break; case 224: memcpy(ctx->X, SKEIN_512_IV_224, sizeof (ctx->X)); break; #endif default: /* * here if there is no precomputed IV value available * build/process the config block, type == CONFIG (could be * precomputed) */ /* set tweaks: T0=0; T1=CFG | FINAL */ Skein_Start_New_Type(ctx, CFG_FINAL); /* set the schema, version */ cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); /* hash result length in bits */ cfg.w[1] = Skein_Swap64(hashBitLen); cfg.w[2] = Skein_Swap64(SKEIN_CFG_TREE_INFO_SEQUENTIAL); /* zero pad config block */ memset(&cfg.w[3], 0, sizeof (cfg) - 3 * sizeof (cfg.w[0])); /* compute the initial chaining values from config block */ /* zero the chaining variables */ memset(ctx->X, 0, sizeof (ctx->X)); Skein_512_Process_Block(ctx, cfg.b, 1, SKEIN_CFG_STR_LEN); break; } /* * The chaining vars ctx->X are now initialized for the given * hashBitLen. Set up to process the data message portion of the * hash (default) */ Skein_Start_New_Type(ctx, MSG); /* T0=0, T1= MSG type */ return (SKEIN_SUCCESS); } /* init the context for a MAC and/or tree hash operation */ /* * [identical to Skein_512_Init() when keyBytes == 0 && * treeInfo == SKEIN_CFG_TREE_INFO_SEQUENTIAL] */ int Skein_512_InitExt(Skein_512_Ctxt_t *ctx, size_t hashBitLen, uint64_t treeInfo, const uint8_t *key, size_t keyBytes) { union { uint8_t b[SKEIN_512_STATE_BYTES]; uint64_t w[SKEIN_512_STATE_WORDS]; } cfg; /* config block */ Skein_Assert(hashBitLen > 0, SKEIN_BAD_HASHLEN); Skein_Assert(keyBytes == 0 || key != NULL, SKEIN_FAIL); /* compute the initial chaining values ctx->X[], based on key */ if (keyBytes == 0) { /* is there a key? */ /* no key: use all zeroes as key for config block */ memset(ctx->X, 0, sizeof (ctx->X)); } else { /* here to pre-process a key */ Skein_assert(sizeof (cfg.b) >= sizeof (ctx->X)); /* do a mini-Init right here */ /* set output hash bit count = state size */ ctx->h.hashBitLen = 8 * sizeof (ctx->X); /* set tweaks: T0 = 0; T1 = KEY type */ Skein_Start_New_Type(ctx, KEY); /* zero the initial chaining variables */ memset(ctx->X, 0, sizeof (ctx->X)); (void) Skein_512_Update(ctx, key, keyBytes); /* hash the key */ /* put result into cfg.b[] */ (void) Skein_512_Final_Pad(ctx, cfg.b); /* copy over into ctx->X[] */ memcpy(ctx->X, cfg.b, sizeof (cfg.b)); #if SKEIN_NEED_SWAP { uint_t i; /* convert key bytes to context words */ for (i = 0; i < SKEIN_512_STATE_WORDS; i++) ctx->X[i] = Skein_Swap64(ctx->X[i]); } #endif } /* * build/process the config block, type == CONFIG (could be * precomputed for each key) */ ctx->h.hashBitLen = hashBitLen; /* output hash bit count */ Skein_Start_New_Type(ctx, CFG_FINAL); memset(&cfg.w, 0, sizeof (cfg.w)); /* pre-pad cfg.w[] with zeroes */ cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); cfg.w[1] = Skein_Swap64(hashBitLen); /* hash result length in bits */ /* tree hash config info (or SKEIN_CFG_TREE_INFO_SEQUENTIAL) */ cfg.w[2] = Skein_Swap64(treeInfo); Skein_Show_Key(512, &ctx->h, key, keyBytes); /* compute the initial chaining values from config block */ Skein_512_Process_Block(ctx, cfg.b, 1, SKEIN_CFG_STR_LEN); /* The chaining vars ctx->X are now initialized */ /* Set up to process the data message portion of the hash (default) */ ctx->h.bCnt = 0; /* buffer b[] starts out empty */ Skein_Start_New_Type(ctx, MSG); return (SKEIN_SUCCESS); } /* process the input bytes */ int Skein_512_Update(Skein_512_Ctxt_t *ctx, const uint8_t *msg, size_t msgByteCnt) { size_t n; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES, SKEIN_FAIL); /* process full blocks, if any */ if (msgByteCnt + ctx->h.bCnt > SKEIN_512_BLOCK_BYTES) { /* finish up any buffered message data */ if (ctx->h.bCnt) { /* # bytes free in buffer b[] */ n = SKEIN_512_BLOCK_BYTES - ctx->h.bCnt; if (n) { /* check on our logic here */ Skein_assert(n < msgByteCnt); memcpy(&ctx->b[ctx->h.bCnt], msg, n); msgByteCnt -= n; msg += n; ctx->h.bCnt += n; } Skein_assert(ctx->h.bCnt == SKEIN_512_BLOCK_BYTES); Skein_512_Process_Block(ctx, ctx->b, 1, SKEIN_512_BLOCK_BYTES); ctx->h.bCnt = 0; } /* * now process any remaining full blocks, directly from input * message data */ if (msgByteCnt > SKEIN_512_BLOCK_BYTES) { /* number of full blocks to process */ n = (msgByteCnt - 1) / SKEIN_512_BLOCK_BYTES; Skein_512_Process_Block(ctx, msg, n, SKEIN_512_BLOCK_BYTES); msgByteCnt -= n * SKEIN_512_BLOCK_BYTES; msg += n * SKEIN_512_BLOCK_BYTES; } Skein_assert(ctx->h.bCnt == 0); } /* copy any remaining source message data bytes into b[] */ if (msgByteCnt) { Skein_assert(msgByteCnt + ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES); memcpy(&ctx->b[ctx->h.bCnt], msg, msgByteCnt); ctx->h.bCnt += msgByteCnt; } return (SKEIN_SUCCESS); } /* finalize the hash computation and output the result */ int Skein_512_Final(Skein_512_Ctxt_t *ctx, uint8_t *hashVal) { size_t i, n, byteCnt; uint64_t X[SKEIN_512_STATE_WORDS]; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES, SKEIN_FAIL); ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */ /* zero pad b[] if necessary */ if (ctx->h.bCnt < SKEIN_512_BLOCK_BYTES) memset(&ctx->b[ctx->h.bCnt], 0, SKEIN_512_BLOCK_BYTES - ctx->h.bCnt); /* process the final block */ Skein_512_Process_Block(ctx, ctx->b, 1, ctx->h.bCnt); /* now output the result */ /* total number of output bytes */ byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* run Threefish in "counter mode" to generate output */ /* zero out b[], so it can hold the counter */ memset(ctx->b, 0, sizeof (ctx->b)); /* keep a local copy of counter mode "key" */ memcpy(X, ctx->X, sizeof (X)); for (i = 0; i * SKEIN_512_BLOCK_BYTES < byteCnt; i++) { /* build the counter block */ *(uint64_t *)ctx->b = Skein_Swap64((uint64_t)i); Skein_Start_New_Type(ctx, OUT_FINAL); /* run "counter mode" */ Skein_512_Process_Block(ctx, ctx->b, 1, sizeof (uint64_t)); /* number of output bytes left to go */ n = byteCnt - i * SKEIN_512_BLOCK_BYTES; if (n >= SKEIN_512_BLOCK_BYTES) n = SKEIN_512_BLOCK_BYTES; Skein_Put64_LSB_First(hashVal + i * SKEIN_512_BLOCK_BYTES, ctx->X, n); /* "output" the ctr mode bytes */ Skein_Show_Final(512, &ctx->h, n, hashVal + i * SKEIN_512_BLOCK_BYTES); /* restore the counter mode key for next time */ memcpy(ctx->X, X, sizeof (X)); } return (SKEIN_SUCCESS); } /* 1024-bit Skein */ /* init the context for a straight hashing operation */ int Skein1024_Init(Skein1024_Ctxt_t *ctx, size_t hashBitLen) { union { uint8_t b[SKEIN1024_STATE_BYTES]; uint64_t w[SKEIN1024_STATE_WORDS]; } cfg; /* config block */ Skein_Assert(hashBitLen > 0, SKEIN_BAD_HASHLEN); ctx->h.hashBitLen = hashBitLen; /* output hash bit count */ switch (hashBitLen) { /* use pre-computed values, where available */ #ifndef SKEIN_NO_PRECOMP case 512: memcpy(ctx->X, SKEIN1024_IV_512, sizeof (ctx->X)); break; case 384: memcpy(ctx->X, SKEIN1024_IV_384, sizeof (ctx->X)); break; case 1024: memcpy(ctx->X, SKEIN1024_IV_1024, sizeof (ctx->X)); break; #endif default: /* here if there is no precomputed IV value available */ /* * build/process the config block, type == CONFIG (could be * precomputed) */ /* set tweaks: T0=0; T1=CFG | FINAL */ Skein_Start_New_Type(ctx, CFG_FINAL); /* set the schema, version */ cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); /* hash result length in bits */ cfg.w[1] = Skein_Swap64(hashBitLen); cfg.w[2] = Skein_Swap64(SKEIN_CFG_TREE_INFO_SEQUENTIAL); /* zero pad config block */ memset(&cfg.w[3], 0, sizeof (cfg) - 3 * sizeof (cfg.w[0])); /* compute the initial chaining values from config block */ /* zero the chaining variables */ memset(ctx->X, 0, sizeof (ctx->X)); Skein1024_Process_Block(ctx, cfg.b, 1, SKEIN_CFG_STR_LEN); break; } /* * The chaining vars ctx->X are now initialized for the given * hashBitLen. Set up to process the data message portion of the hash * (default) */ Skein_Start_New_Type(ctx, MSG); /* T0=0, T1= MSG type */ return (SKEIN_SUCCESS); } /* init the context for a MAC and/or tree hash operation */ /* * [identical to Skein1024_Init() when keyBytes == 0 && * treeInfo == SKEIN_CFG_TREE_INFO_SEQUENTIAL] */ int Skein1024_InitExt(Skein1024_Ctxt_t *ctx, size_t hashBitLen, uint64_t treeInfo, const uint8_t *key, size_t keyBytes) { union { uint8_t b[SKEIN1024_STATE_BYTES]; uint64_t w[SKEIN1024_STATE_WORDS]; } cfg; /* config block */ Skein_Assert(hashBitLen > 0, SKEIN_BAD_HASHLEN); Skein_Assert(keyBytes == 0 || key != NULL, SKEIN_FAIL); /* compute the initial chaining values ctx->X[], based on key */ if (keyBytes == 0) { /* is there a key? */ /* no key: use all zeroes as key for config block */ memset(ctx->X, 0, sizeof (ctx->X)); } else { /* here to pre-process a key */ Skein_assert(sizeof (cfg.b) >= sizeof (ctx->X)); /* do a mini-Init right here */ /* set output hash bit count = state size */ ctx->h.hashBitLen = 8 * sizeof (ctx->X); /* set tweaks: T0 = 0; T1 = KEY type */ Skein_Start_New_Type(ctx, KEY); /* zero the initial chaining variables */ memset(ctx->X, 0, sizeof (ctx->X)); (void) Skein1024_Update(ctx, key, keyBytes); /* hash the key */ /* put result into cfg.b[] */ (void) Skein1024_Final_Pad(ctx, cfg.b); /* copy over into ctx->X[] */ memcpy(ctx->X, cfg.b, sizeof (cfg.b)); #if SKEIN_NEED_SWAP { uint_t i; /* convert key bytes to context words */ for (i = 0; i < SKEIN1024_STATE_WORDS; i++) ctx->X[i] = Skein_Swap64(ctx->X[i]); } #endif } /* * build/process the config block, type == CONFIG (could be * precomputed for each key) */ ctx->h.hashBitLen = hashBitLen; /* output hash bit count */ Skein_Start_New_Type(ctx, CFG_FINAL); memset(&cfg.w, 0, sizeof (cfg.w)); /* pre-pad cfg.w[] with zeroes */ cfg.w[0] = Skein_Swap64(SKEIN_SCHEMA_VER); /* hash result length in bits */ cfg.w[1] = Skein_Swap64(hashBitLen); /* tree hash config info (or SKEIN_CFG_TREE_INFO_SEQUENTIAL) */ cfg.w[2] = Skein_Swap64(treeInfo); Skein_Show_Key(1024, &ctx->h, key, keyBytes); /* compute the initial chaining values from config block */ Skein1024_Process_Block(ctx, cfg.b, 1, SKEIN_CFG_STR_LEN); /* The chaining vars ctx->X are now initialized */ /* Set up to process the data message portion of the hash (default) */ ctx->h.bCnt = 0; /* buffer b[] starts out empty */ Skein_Start_New_Type(ctx, MSG); return (SKEIN_SUCCESS); } /* process the input bytes */ int Skein1024_Update(Skein1024_Ctxt_t *ctx, const uint8_t *msg, size_t msgByteCnt) { size_t n; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES, SKEIN_FAIL); /* process full blocks, if any */ if (msgByteCnt + ctx->h.bCnt > SKEIN1024_BLOCK_BYTES) { /* finish up any buffered message data */ if (ctx->h.bCnt) { /* # bytes free in buffer b[] */ n = SKEIN1024_BLOCK_BYTES - ctx->h.bCnt; if (n) { /* check on our logic here */ Skein_assert(n < msgByteCnt); memcpy(&ctx->b[ctx->h.bCnt], msg, n); msgByteCnt -= n; msg += n; ctx->h.bCnt += n; } Skein_assert(ctx->h.bCnt == SKEIN1024_BLOCK_BYTES); Skein1024_Process_Block(ctx, ctx->b, 1, SKEIN1024_BLOCK_BYTES); ctx->h.bCnt = 0; } /* * now process any remaining full blocks, directly from * input message data */ if (msgByteCnt > SKEIN1024_BLOCK_BYTES) { /* number of full blocks to process */ n = (msgByteCnt - 1) / SKEIN1024_BLOCK_BYTES; Skein1024_Process_Block(ctx, msg, n, SKEIN1024_BLOCK_BYTES); msgByteCnt -= n * SKEIN1024_BLOCK_BYTES; msg += n * SKEIN1024_BLOCK_BYTES; } Skein_assert(ctx->h.bCnt == 0); } /* copy any remaining source message data bytes into b[] */ if (msgByteCnt) { Skein_assert(msgByteCnt + ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES); memcpy(&ctx->b[ctx->h.bCnt], msg, msgByteCnt); ctx->h.bCnt += msgByteCnt; } return (SKEIN_SUCCESS); } /* finalize the hash computation and output the result */ int Skein1024_Final(Skein1024_Ctxt_t *ctx, uint8_t *hashVal) { size_t i, n, byteCnt; uint64_t X[SKEIN1024_STATE_WORDS]; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES, SKEIN_FAIL); ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */ /* zero pad b[] if necessary */ if (ctx->h.bCnt < SKEIN1024_BLOCK_BYTES) memset(&ctx->b[ctx->h.bCnt], 0, SKEIN1024_BLOCK_BYTES - ctx->h.bCnt); /* process the final block */ Skein1024_Process_Block(ctx, ctx->b, 1, ctx->h.bCnt); /* now output the result */ /* total number of output bytes */ byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* run Threefish in "counter mode" to generate output */ /* zero out b[], so it can hold the counter */ memset(ctx->b, 0, sizeof (ctx->b)); /* keep a local copy of counter mode "key" */ memcpy(X, ctx->X, sizeof (X)); for (i = 0; i * SKEIN1024_BLOCK_BYTES < byteCnt; i++) { /* build the counter block */ *(uint64_t *)ctx->b = Skein_Swap64((uint64_t)i); Skein_Start_New_Type(ctx, OUT_FINAL); /* run "counter mode" */ Skein1024_Process_Block(ctx, ctx->b, 1, sizeof (uint64_t)); /* number of output bytes left to go */ n = byteCnt - i * SKEIN1024_BLOCK_BYTES; if (n >= SKEIN1024_BLOCK_BYTES) n = SKEIN1024_BLOCK_BYTES; Skein_Put64_LSB_First(hashVal + i * SKEIN1024_BLOCK_BYTES, ctx->X, n); /* "output" the ctr mode bytes */ Skein_Show_Final(1024, &ctx->h, n, hashVal + i * SKEIN1024_BLOCK_BYTES); /* restore the counter mode key for next time */ memcpy(ctx->X, X, sizeof (X)); } return (SKEIN_SUCCESS); } /* Functions to support MAC/tree hashing */ /* (this code is identical for Optimized and Reference versions) */ /* finalize the hash computation and output the block, no OUTPUT stage */ int Skein_256_Final_Pad(Skein_256_Ctxt_t *ctx, uint8_t *hashVal) { /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES, SKEIN_FAIL); ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */ /* zero pad b[] if necessary */ if (ctx->h.bCnt < SKEIN_256_BLOCK_BYTES) memset(&ctx->b[ctx->h.bCnt], 0, SKEIN_256_BLOCK_BYTES - ctx->h.bCnt); /* process the final block */ Skein_256_Process_Block(ctx, ctx->b, 1, ctx->h.bCnt); /* "output" the state bytes */ Skein_Put64_LSB_First(hashVal, ctx->X, SKEIN_256_BLOCK_BYTES); return (SKEIN_SUCCESS); } /* finalize the hash computation and output the block, no OUTPUT stage */ int Skein_512_Final_Pad(Skein_512_Ctxt_t *ctx, uint8_t *hashVal) { /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES, SKEIN_FAIL); ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* tag as the final block */ /* zero pad b[] if necessary */ if (ctx->h.bCnt < SKEIN_512_BLOCK_BYTES) memset(&ctx->b[ctx->h.bCnt], 0, SKEIN_512_BLOCK_BYTES - ctx->h.bCnt); /* process the final block */ Skein_512_Process_Block(ctx, ctx->b, 1, ctx->h.bCnt); /* "output" the state bytes */ Skein_Put64_LSB_First(hashVal, ctx->X, SKEIN_512_BLOCK_BYTES); return (SKEIN_SUCCESS); } /* finalize the hash computation and output the block, no OUTPUT stage */ int Skein1024_Final_Pad(Skein1024_Ctxt_t *ctx, uint8_t *hashVal) { /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES, SKEIN_FAIL); /* tag as the final block */ ctx->h.T[1] |= SKEIN_T1_FLAG_FINAL; /* zero pad b[] if necessary */ if (ctx->h.bCnt < SKEIN1024_BLOCK_BYTES) memset(&ctx->b[ctx->h.bCnt], 0, SKEIN1024_BLOCK_BYTES - ctx->h.bCnt); /* process the final block */ Skein1024_Process_Block(ctx, ctx->b, 1, ctx->h.bCnt); /* "output" the state bytes */ Skein_Put64_LSB_First(hashVal, ctx->X, SKEIN1024_BLOCK_BYTES); return (SKEIN_SUCCESS); } #if SKEIN_TREE_HASH /* just do the OUTPUT stage */ int Skein_256_Output(Skein_256_Ctxt_t *ctx, uint8_t *hashVal) { size_t i, n, byteCnt; uint64_t X[SKEIN_256_STATE_WORDS]; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN_256_BLOCK_BYTES, SKEIN_FAIL); /* now output the result */ /* total number of output bytes */ byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* run Threefish in "counter mode" to generate output */ /* zero out b[], so it can hold the counter */ memset(ctx->b, 0, sizeof (ctx->b)); /* keep a local copy of counter mode "key" */ memcpy(X, ctx->X, sizeof (X)); for (i = 0; i * SKEIN_256_BLOCK_BYTES < byteCnt; i++) { /* build the counter block */ *(uint64_t *)ctx->b = Skein_Swap64((uint64_t)i); Skein_Start_New_Type(ctx, OUT_FINAL); /* run "counter mode" */ Skein_256_Process_Block(ctx, ctx->b, 1, sizeof (uint64_t)); /* number of output bytes left to go */ n = byteCnt - i * SKEIN_256_BLOCK_BYTES; if (n >= SKEIN_256_BLOCK_BYTES) n = SKEIN_256_BLOCK_BYTES; Skein_Put64_LSB_First(hashVal + i * SKEIN_256_BLOCK_BYTES, ctx->X, n); /* "output" the ctr mode bytes */ Skein_Show_Final(256, &ctx->h, n, hashVal + i * SKEIN_256_BLOCK_BYTES); /* restore the counter mode key for next time */ memcpy(ctx->X, X, sizeof (X)); } return (SKEIN_SUCCESS); } /* just do the OUTPUT stage */ int Skein_512_Output(Skein_512_Ctxt_t *ctx, uint8_t *hashVal) { size_t i, n, byteCnt; uint64_t X[SKEIN_512_STATE_WORDS]; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN_512_BLOCK_BYTES, SKEIN_FAIL); /* now output the result */ /* total number of output bytes */ byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* run Threefish in "counter mode" to generate output */ /* zero out b[], so it can hold the counter */ memset(ctx->b, 0, sizeof (ctx->b)); /* keep a local copy of counter mode "key" */ memcpy(X, ctx->X, sizeof (X)); for (i = 0; i * SKEIN_512_BLOCK_BYTES < byteCnt; i++) { /* build the counter block */ *(uint64_t *)ctx->b = Skein_Swap64((uint64_t)i); Skein_Start_New_Type(ctx, OUT_FINAL); /* run "counter mode" */ Skein_512_Process_Block(ctx, ctx->b, 1, sizeof (uint64_t)); /* number of output bytes left to go */ n = byteCnt - i * SKEIN_512_BLOCK_BYTES; if (n >= SKEIN_512_BLOCK_BYTES) n = SKEIN_512_BLOCK_BYTES; Skein_Put64_LSB_First(hashVal + i * SKEIN_512_BLOCK_BYTES, ctx->X, n); /* "output" the ctr mode bytes */ Skein_Show_Final(256, &ctx->h, n, hashVal + i * SKEIN_512_BLOCK_BYTES); /* restore the counter mode key for next time */ memcpy(ctx->X, X, sizeof (X)); } return (SKEIN_SUCCESS); } /* just do the OUTPUT stage */ int Skein1024_Output(Skein1024_Ctxt_t *ctx, uint8_t *hashVal) { size_t i, n, byteCnt; uint64_t X[SKEIN1024_STATE_WORDS]; /* catch uninitialized context */ Skein_Assert(ctx->h.bCnt <= SKEIN1024_BLOCK_BYTES, SKEIN_FAIL); /* now output the result */ /* total number of output bytes */ byteCnt = (ctx->h.hashBitLen + 7) >> 3; /* run Threefish in "counter mode" to generate output */ /* zero out b[], so it can hold the counter */ memset(ctx->b, 0, sizeof (ctx->b)); /* keep a local copy of counter mode "key" */ memcpy(X, ctx->X, sizeof (X)); for (i = 0; i * SKEIN1024_BLOCK_BYTES < byteCnt; i++) { /* build the counter block */ *(uint64_t *)ctx->b = Skein_Swap64((uint64_t)i); Skein_Start_New_Type(ctx, OUT_FINAL); /* run "counter mode" */ Skein1024_Process_Block(ctx, ctx->b, 1, sizeof (uint64_t)); /* number of output bytes left to go */ n = byteCnt - i * SKEIN1024_BLOCK_BYTES; if (n >= SKEIN1024_BLOCK_BYTES) n = SKEIN1024_BLOCK_BYTES; Skein_Put64_LSB_First(hashVal + i * SKEIN1024_BLOCK_BYTES, ctx->X, n); /* "output" the ctr mode bytes */ Skein_Show_Final(256, &ctx->h, n, hashVal + i * SKEIN1024_BLOCK_BYTES); /* restore the counter mode key for next time */ memcpy(ctx->X, X, sizeof (X)); } return (SKEIN_SUCCESS); } #endif #ifdef _KERNEL EXPORT_SYMBOL(Skein_512_Init); EXPORT_SYMBOL(Skein_512_InitExt); EXPORT_SYMBOL(Skein_512_Update); EXPORT_SYMBOL(Skein_512_Final); #endif