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-rw-r--r--digest.c594
1 files changed, 594 insertions, 0 deletions
diff --git a/digest.c b/digest.c
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+/* See LICENSE file for copyright and license details. */
+#include "../common.h"
+
+
+/**
+ * X-macro-enabled listing of all intergers in [0, 4]
+ */
+#define LIST_5 X(0) X(1) X(2) X(3) X(4)
+
+/**
+ * X-macro-enabled listing of all intergers in [0, 7]
+ */
+#define LIST_8 LIST_5 X(5) X(6) X(7)
+
+/**
+ * X-macro-enabled listing of all intergers in [0, 23]
+ */
+#define LIST_24 LIST_8 X(8) X(9) X(10) X(11) X(12) X(13) X(14) X(15)\
+ X(16) X(17) X(18) X(19) X(20) X(21) X(22) X(23)
+
+/**
+ * X-macro-enabled listing of all intergers in [0, 24]
+ */
+#define LIST_25 LIST_24 X(24)
+
+
+
+#define X(N) (N % 5) * 5 + N / 5,
+/**
+ * The order the lanes should be read when absorbing or squeezing,
+ * it transposes the lanes in the sponge
+ */
+static const long int LANE_TRANSPOSE_MAP[] = { LIST_25 };
+#undef X
+
+
+
+/**
+ * Keccak-f round constants
+ */
+static const uint_fast64_t RC[] = {
+ 0x0000000000000001ULL, 0x0000000000008082ULL, 0x800000000000808AULL, 0x8000000080008000ULL,
+ 0x000000000000808BULL, 0x0000000080000001ULL, 0x8000000080008081ULL, 0x8000000000008009ULL,
+ 0x000000000000008AULL, 0x0000000000000088ULL, 0x0000000080008009ULL, 0x000000008000000AULL,
+ 0x000000008000808BULL, 0x800000000000008BULL, 0x8000000000008089ULL, 0x8000000000008003ULL,
+ 0x8000000000008002ULL, 0x8000000000000080ULL, 0x000000000000800AULL, 0x800000008000000AULL,
+ 0x8000000080008081ULL, 0x8000000000008080ULL, 0x0000000080000001ULL, 0x8000000080008008ULL
+};
+
+
+/**
+ * Rotate a word
+ *
+ * @param x:int_fast64_t The value to rotate
+ * @param n:long Rotation steps, may be zero mod `w`
+ * @param w:long `state->w`
+ * @param wmod:int_fast64_t `state->wmod`
+ * @return :int_fast64_t The value rotated
+ */
+#define rotate(x, n, w, wmod) ((((x) >> ((w) - ((n) % (w)))) | ((x) << ((n) % (w)))) & (wmod))
+
+
+/**
+ * Rotate a 64-bit word
+ *
+ * @param x:int_fast64_t The value to rotate
+ * @param n:long Rotation steps, may not be zero
+ * @return :int_fast64_t The value rotated
+ */
+#define rotate64(x, n) ((int_fast64_t)(((uint64_t)(x) >> (64L - (n))) | ((uint64_t)(x) << (n))))
+
+
+/**
+ * Perform one round of computation
+ *
+ * @param state The hashing state
+ * @param rc The round contant for this round
+ */
+LIBKECCAK_GCC_ONLY(__attribute__((__nonnull__, __nothrow__, __hot__)))
+static void
+libkeccak_f_round(register libkeccak_state_t *restrict state, register int_fast64_t rc)
+{
+ int_fast64_t *restrict A = state->S;
+ int_fast64_t B[25];
+ int_fast64_t C[5];
+ int_fast64_t da, db, dc, dd, de;
+ int_fast64_t wmod = state->wmod;
+ long int w = state->w;
+
+ /* θ step (step 1 of 3). */
+#define X(N) C[N] = A[N * 5] ^ A[N * 5 + 1] ^ A[N * 5 + 2] ^ A[N * 5 + 3] ^ A[N * 5 + 4];
+ LIST_5;
+#undef X
+
+ /* θ step (step 2 of 3). */
+ da = C[4] ^ rotate(C[1], 1, w, wmod);
+ dd = C[2] ^ rotate(C[4], 1, w, wmod);
+ db = C[0] ^ rotate(C[2], 1, w, wmod);
+ de = C[3] ^ rotate(C[0], 1, w, wmod);
+ dc = C[1] ^ rotate(C[3], 1, w, wmod);
+
+ /* ρ and π steps, with last two part of θ. */
+#define X(bi, ai, dv, r) B[bi] = rotate(A[ai] ^ dv, r, w, wmod)
+ B[0] = A[0] ^ da; X( 1, 15, dd, 28); X( 2, 5, db, 1); X( 3, 20, de, 27); X( 4, 10, dc, 62);
+ X( 5, 6, db, 44); X( 6, 21, de, 20); X( 7, 11, dc, 6); X( 8, 1, da, 36); X( 9, 16, dd, 55);
+ X(10, 12, dc, 43); X(11, 2, da, 3); X(12, 17, dd, 25); X(13, 7, db, 10); X(14, 22, de, 39);
+ X(15, 18, dd, 21); X(16, 8, db, 45); X(17, 23, de, 8); X(18, 13, dc, 15); X(19, 3, da, 41);
+ X(20, 24, de, 14); X(21, 14, dc, 61); X(22, 4, da, 18); X(23, 19, dd, 56); X(24, 9, db, 2);
+#undef X
+
+ /* ξ step. */
+#define X(N) A[N] = B[N] ^ ((~(B[(N + 5) % 25])) & B[(N + 10) % 25]);
+ LIST_25;
+#undef X
+
+ /* ι step. */
+ A[0] ^= rc;
+}
+
+
+/**
+ * 64-bit word version of `libkeccak_f_round`
+ *
+ * @param state The hashing state
+ * @param rc The round contant for this round
+ */
+LIBKECCAK_GCC_ONLY(__attribute__((__nonnull__, __nothrow__, __hot__)))
+static void
+libkeccak_f_round64(register libkeccak_state_t *restrict state, register int_fast64_t rc)
+{
+ int_fast64_t *restrict A = state->S;
+ int_fast64_t B[25];
+ int_fast64_t C[5];
+ int_fast64_t da, db, dc, dd, de;
+
+ /* θ step (step 1 of 3). */
+#define X(N) C[N] = A[N * 5] ^ A[N * 5 + 1] ^ A[N * 5 + 2] ^ A[N * 5 + 3] ^ A[N * 5 + 4];
+ LIST_5;
+#undef X
+
+ /* θ step (step 2 of 3). */
+ da = C[4] ^ rotate64(C[1], 1);
+ dd = C[2] ^ rotate64(C[4], 1);
+ db = C[0] ^ rotate64(C[2], 1);
+ de = C[3] ^ rotate64(C[0], 1);
+ dc = C[1] ^ rotate64(C[3], 1);
+
+ /* ρ and π steps, with last two part of θ. */
+#define X(bi, ai, dv, r) B[bi] = rotate64(A[ai] ^ dv, r)
+ B[0] = A[0] ^ da; X( 1, 15, dd, 28); X( 2, 5, db, 1); X( 3, 20, de, 27); X( 4, 10, dc, 62);
+ X( 5, 6, db, 44); X( 6, 21, de, 20); X( 7, 11, dc, 6); X( 8, 1, da, 36); X( 9, 16, dd, 55);
+ X(10, 12, dc, 43); X(11, 2, da, 3); X(12, 17, dd, 25); X(13, 7, db, 10); X(14, 22, de, 39);
+ X(15, 18, dd, 21); X(16, 8, db, 45); X(17, 23, de, 8); X(18, 13, dc, 15); X(19, 3, da, 41);
+ X(20, 24, de, 14); X(21, 14, dc, 61); X(22, 4, da, 18); X(23, 19, dd, 56); X(24, 9, db, 2);
+#undef X
+
+ /* ξ step. */
+#define X(N) A[N] = B[N] ^ ((~(B[(N + 5) % 25])) & B[(N + 10) % 25]);
+ LIST_25;
+#undef X
+
+ /* ι step. */
+ A[0] ^= rc;
+}
+
+
+/**
+ * Convert a chunk of bytes to a lane
+ *
+ * @param state The hashing state
+ */
+LIBKECCAK_GCC_ONLY(__attribute__((__nonnull__, __nothrow__, __gnu_inline__)))
+static inline void
+libkeccak_f(register libkeccak_state_t *restrict state)
+{
+ register long int i = 0;
+ register long int nr = state->nr;
+ register long int wmod = state->wmod;
+ if (nr == 24) {
+ for (; i < nr; i++)
+ libkeccak_f_round64(state, (int_fast64_t)(RC[i]));
+ } else {
+ for (; i < nr; i++)
+ libkeccak_f_round(state, (int_fast64_t)(RC[i] & (uint_fast64_t)wmod));
+ }
+}
+
+
+/**
+ * Convert a chunk of bytes to a lane
+ *
+ * @param message The message
+ * @param msglen The length of the message
+ * @param rr Bitrate in bytes
+ * @param ww Word size in bytes
+ * @param off The offset in the message
+ * @return The lane
+ */
+LIBKECCAK_GCC_ONLY(__attribute__((__nonnull__, __nothrow__, __pure__, __warn_unused_result__, __gnu_inline__)))
+static inline int_fast64_t
+libkeccak_to_lane(register const char *restrict message, register size_t msglen,
+ register long int rr, register long int ww, size_t off)
+{
+ register long int n = (long)((msglen < (size_t)rr ? msglen : (size_t)rr) - off);
+ int_fast64_t rc = 0;
+ message += off;
+ while (ww--) {
+ rc <<= 8;
+ rc |= __builtin_expect(ww < n, 1) ? (int_fast64_t)(unsigned char)(message[ww]) : 0L;
+ }
+ return rc;
+}
+
+
+/**
+ * 64-bit lane version of `libkeccak_to_lane`
+ *
+ * @param message The message
+ * @param msglen The length of the message
+ * @param rr Bitrate in bytes
+ * @param off The offset in the message
+ * @return The lane
+ */
+LIBKECCAK_GCC_ONLY(__attribute__((__nonnull__, __nothrow__, __pure__, __hot__, __warn_unused_result__, __gnu_inline__)))
+static inline int_fast64_t
+libkeccak_to_lane64(register const char *restrict message, register size_t msglen, register long int rr, size_t off)
+{
+ register long int n = (long)((msglen < (size_t)rr ? msglen : (size_t)rr) - off);
+ int_fast64_t rc = 0;
+ message += off;
+#define X(N) if (__builtin_expect(N < n, 1)) rc |= (int_fast64_t)(unsigned char)(message[N]) << (N * 8);\
+ else return rc;
+ LIST_8;
+#undef X
+ return rc;
+}
+
+
+/**
+ * pad 10*1
+ *
+ * @param state The hashing state, `state->M` and `state->mptr` will be updated,
+ * `state->M` should have `state->r / 8` bytes left over at the end
+ * @param bits The number of bits in the end of the message that does not make a whole byte
+ */
+LIBKECCAK_GCC_ONLY(__attribute__((__nonnull__, __nothrow__, __gnu_inline__)))
+static inline void
+libkeccak_pad10star1(register libkeccak_state_t *restrict state, register size_t bits)
+{
+ register size_t r = (size_t)(state->r);
+ register size_t nrf = state->mptr - !!bits;
+ register size_t len = (nrf << 3) | bits;
+ register size_t ll = len % r;
+ register char b = (char)(bits ? (state->M[nrf] | (1 << bits)) : 1);
+
+ if (r - 8 <= ll && ll <= r - 2) {
+ state->M[nrf] = (char)(b ^ 0x80);
+ state->mptr = nrf + 1;
+ } else {
+ len = ++nrf << 3;
+ len = (len - (len % r) + (r - 8)) >> 3;
+ state->mptr = len + 1;
+
+ state->M[nrf - 1] = b;
+ __builtin_memset(state->M + nrf, 0, (len - nrf) * sizeof(char));
+ state->M[len] = (char)0x80;
+ }
+}
+
+
+/**
+ * Perform the absorption phase
+ *
+ * @param state The hashing state
+ * @param len The number of bytes from `state->M` to absorb
+ */
+LIBKECCAK_GCC_ONLY(__attribute__((__nonnull__, __nothrow__)))
+static void
+libkeccak_absorption_phase(register libkeccak_state_t *restrict state, register size_t len)
+{
+ register long int rr = state->r >> 3;
+ register long int ww = state->w >> 3;
+ register long int n = (long)len / rr;
+ register const char* restrict message = state->M;
+ if (__builtin_expect(ww >= 8, 1)) { /* ww > 8 is impossible, it is just for optimisation possibilities. */
+ while (n--) {
+#define X(N) state->S[N] ^= libkeccak_to_lane64(message, len, rr, (size_t)(LANE_TRANSPOSE_MAP[N] * 8));
+ LIST_25;
+#undef X
+ libkeccak_f(state);
+ message += (size_t)rr;
+ len -= (size_t)rr;
+ }
+ } else {
+ while (n--) {
+#define X(N) state->S[N] ^= libkeccak_to_lane(message, len, rr, ww, (size_t)(LANE_TRANSPOSE_MAP[N] * ww));
+ LIST_25;
+#undef X
+ libkeccak_f(state);
+ message += (size_t)rr;
+ len -= (size_t)rr;
+ }
+ }
+}
+
+
+/**
+ * Perform the squeezing phase
+ *
+ * @param state The hashing state
+ * @param rr The bitrate in bytes
+ * @param nn The output size in bytes, rounded up to whole bytes
+ * @param ww The word size in bytes
+ * @param hashsum Output parameter for the hashsum
+ */
+LIBKECCAK_GCC_ONLY(__attribute__((__nonnull__, __nothrow__, __hot__)))
+static void
+libkeccak_squeezing_phase(register libkeccak_state_t *restrict state, long int rr,
+ long int nn, long int ww, register unsigned char *restrict hashsum)
+{
+ register int_fast64_t v;
+ register long int ni = rr / ww;
+ auto long int olen = state->n;
+ auto long int i, j = 0;
+ register long int k;
+ while (olen > 0) {
+ for (i = 0; i < ni && j < nn; i++) {
+ v = state->S[LANE_TRANSPOSE_MAP[i]];
+ for (k = 0; k++ < ww && j++ < nn; v >>= 8)
+ *hashsum++ = (unsigned char)v;
+ }
+ if (olen -= state->r, olen > 0)
+ libkeccak_f(state);
+ }
+ if (state->n & 7)
+ hashsum[-1] &= (unsigned char)((1 << (state->n & 7)) - 1);
+}
+
+
+/**
+ * Absorb more of the message to the Keccak sponge
+ * without wiping sensitive data when possible
+ *
+ * @param state The hashing state
+ * @param msg The partial message
+ * @param msglen The length of the partial message
+ * @return Zero on success, -1 on error
+ */
+int
+libkeccak_fast_update(libkeccak_state_t *restrict state, const void *restrict msg, size_t msglen)
+{
+ size_t len;
+ auto char *restrict new;
+
+ if (__builtin_expect(state->mptr + msglen > state->mlen, 0)) {
+ state->mlen += msglen;
+ new = realloc(state->M, state->mlen * sizeof(char));
+ if (!new)
+ return state->mlen -= msglen, -1;
+ state->M = new;
+ }
+
+ __builtin_memcpy(state->M + state->mptr, msg, msglen * sizeof(char));
+ state->mptr += msglen;
+ len = state->mptr;
+ len -= state->mptr % (size_t)((state->r * state->b) >> 3);
+ state->mptr -= len;
+
+ libkeccak_absorption_phase(state, len);
+ __builtin_memmove(state->M, state->M + len, state->mptr * sizeof(char));
+
+ return 0;
+}
+
+
+/**
+ * Absorb more of the message to the Keccak sponge
+ * and wipe sensitive data when possible
+ *
+ * @param state The hashing state
+ * @param msg The partial message
+ * @param msglen The length of the partial message
+ * @return Zero on success, -1 on error
+ */
+int
+libkeccak_update(libkeccak_state_t *restrict state, const void *restrict msg, size_t msglen)
+{
+ size_t len;
+ auto char *restrict new;
+
+ if (__builtin_expect(state->mptr + msglen > state->mlen, 0)) {
+ state->mlen += msglen;
+ new = malloc(state->mlen * sizeof(char));
+ if (new == NULL)
+ return state->mlen -= msglen, -1;
+ libkeccak_state_wipe_message(state);
+ free(state->M);
+ state->M = new;
+ }
+
+ __builtin_memcpy(state->M + state->mptr, msg, msglen * sizeof(char));
+ state->mptr += msglen;
+ len = state->mptr;
+ len -= state->mptr % (size_t)((state->r * state->b) >> 3);
+ state->mptr -= len;
+
+ libkeccak_absorption_phase(state, len);
+ __builtin_memmove(state->M, state->M + len, state->mptr * sizeof(char));
+
+ return 0;
+}
+
+
+/**
+ * Absorb the last part of the message and squeeze the Keccak sponge
+ * without wiping sensitive data when possible
+ *
+ * @param state The hashing state
+ * @param msg The rest of the message, may be `NULL`
+ * @param msglen The length of the partial message
+ * @param bits The number of bits at the end of the message not covered by `msglen`
+ * @param suffix The suffix concatenate to the message, only '1':s and '0':s, and NUL-termination
+ * @param hashsum Output parameter for the hashsum, may be `NULL`
+ * @return Zero on success, -1 on error
+ */
+int
+libkeccak_fast_digest(libkeccak_state_t *restrict state, const void *restrict msg_, size_t msglen,
+ size_t bits, const char *restrict suffix, void *restrict hashsum)
+{
+ const char *restrict msg = msg_;
+ auto char *restrict new;
+ register long int rr = state->r >> 3;
+ auto size_t suffix_len = suffix ? __builtin_strlen(suffix) : 0;
+ register size_t ext;
+ register long int i;
+
+ if (!msg)
+ msglen = bits = 0;
+ else
+ msglen += bits >> 3, bits &= 7;
+
+ ext = msglen + ((bits + suffix_len + 7) >> 3) + (size_t)rr;
+ if (__builtin_expect(state->mptr + ext > state->mlen, 0)) {
+ state->mlen += ext;
+ new = realloc(state->M, state->mlen * sizeof(char));
+ if (!new)
+ return state->mlen -= ext, -1;
+ state->M = new;
+ }
+
+ if (msglen)
+ __builtin_memcpy(state->M + state->mptr, msg, msglen * sizeof(char));
+ state->mptr += msglen;
+
+ if (bits)
+ state->M[state->mptr] = msg[msglen] & (char)((1 << bits) - 1);
+ if (__builtin_expect(!!suffix_len, 1)) {
+ if (bits == 0)
+ state->M[state->mptr] = 0;
+ while (suffix_len--) {
+ state->M[state->mptr] |= (char)((*suffix++ & 1) << bits++);
+ if (bits == 8)
+ bits = 0, state->M[++(state->mptr)] = 0;
+ }
+ }
+ if (bits)
+ state->mptr++;
+
+ libkeccak_pad10star1(state, bits);
+ libkeccak_absorption_phase(state, state->mptr);
+
+ if (hashsum) {
+ libkeccak_squeezing_phase(state, rr, (state->n + 7) >> 3, state->w >> 3, hashsum);
+ } else {
+ for (i = (state->n - 1) / state->r; i--;)
+ libkeccak_f(state);
+ }
+
+ return 0;
+}
+
+
+/**
+ * Absorb the last part of the message and squeeze the Keccak sponge
+ * and wipe sensitive data when possible
+ *
+ * @param state The hashing state
+ * @param msg The rest of the message, may be `NULL`
+ * @param msglen The length of the partial message
+ * @param bits The number of bits at the end of the message not covered by `msglen`
+ * @param suffix The suffix concatenate to the message, only '1':s and '0':s, and NUL-termination
+ * @param hashsum Output parameter for the hashsum, may be `NULL`
+ * @return Zero on success, -1 on error
+ */
+int
+libkeccak_digest(libkeccak_state_t *restrict state, const void *restrict msg_, size_t msglen,
+ size_t bits, const char *restrict suffix, void *restrict hashsum)
+{
+ const char *restrict msg = msg_;
+ auto char *restrict new;
+ register long int rr = state->r >> 3;
+ auto size_t suffix_len = suffix ? __builtin_strlen(suffix) : 0;
+ register size_t ext;
+ register long int i;
+
+ if (!msg)
+ msglen = bits = 0;
+ else
+ msglen += bits >> 3, bits &= 7;
+
+ ext = msglen + ((bits + suffix_len + 7) >> 3) + (size_t)rr;
+ if (__builtin_expect(state->mptr + ext > state->mlen, 0)) {
+ state->mlen += ext;
+ new = malloc(state->mlen * sizeof(char));
+ if (!new)
+ return state->mlen -= ext, -1;
+ libkeccak_state_wipe_message(state);
+ free(state->M);
+ state->M = new;
+ }
+
+ if (msglen)
+ __builtin_memcpy(state->M + state->mptr, msg, msglen * sizeof(char));
+ state->mptr += msglen;
+
+ if (bits)
+ state->M[state->mptr] = msg[msglen] & (char)((1 << bits) - 1);
+ if (__builtin_expect(!!suffix_len, 1)) {
+ if (bits == 0)
+ state->M[state->mptr] = 0;
+ while (suffix_len--) {
+ state->M[state->mptr] |= (char)((*suffix++ & 1) << bits++);
+ if (bits == 8)
+ bits = 0, state->M[++(state->mptr)] = 0;
+ }
+ }
+ if (bits)
+ state->mptr++;
+
+ libkeccak_pad10star1(state, bits);
+ libkeccak_absorption_phase(state, state->mptr);
+
+ if (hashsum) {
+ libkeccak_squeezing_phase(state, rr, (state->n + 7) >> 3, state->w >> 3, hashsum);
+ } else {
+ for (i = (state->n - 1) / state->r; i--;)
+ libkeccak_f(state);
+ }
+
+ return 0;
+}
+
+
+/**
+ * Force some rounds of Keccak-f
+ *
+ * @param state The hashing state
+ * @param times The number of rounds
+ */
+void
+libkeccak_simple_squeeze(register libkeccak_state_t *restrict state, register long int times)
+{
+ while (times--)
+ libkeccak_f(state);
+}
+
+
+/**
+ * Squeeze as much as is needed to get a digest a number of times
+ *
+ * @param state The hashing state
+ * @param times The number of digests
+ */
+void
+libkeccak_fast_squeeze(register libkeccak_state_t *restrict state, register long int times)
+{
+ times *= (state->n - 1) / state->r + 1;
+ while (times--)
+ libkeccak_f(state);
+}
+
+
+/**
+ * Squeeze out another digest
+ *
+ * @param state The hashing state
+ * @param hashsum Output parameter for the hashsum
+ */
+void
+libkeccak_squeeze(register libkeccak_state_t *restrict state, register void *restrict hashsum)
+{
+ libkeccak_f(state);
+ libkeccak_squeezing_phase(state, state->r >> 3, (state->n + 7) >> 3, state->w >> 3, hashsum);
+}