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404 lines
11 KiB
C
404 lines
11 KiB
C
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/* Jitter RNG: SHA-3 Implementation
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*
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* Copyright (C) 2021 - 2022, Stephan Mueller <smueller@chronox.de>
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*
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* License: see LICENSE file in root directory
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*
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* THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED
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* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
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* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE, ALL OF
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* WHICH ARE HEREBY DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE
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* LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT
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* OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
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* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
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* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE
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* USE OF THIS SOFTWARE, EVEN IF NOT ADVISED OF THE POSSIBILITY OF SUCH
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* DAMAGE.
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*/
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#include "jitterentropy-sha3.h"
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#include "jitterentropy.h"
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/***************************************************************************
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* Message Digest Implementation
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***************************************************************************/
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/*
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* Conversion of Little-Endian representations in byte streams - the data
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* representation in the integer values is the host representation.
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*/
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static inline uint32_t ptr_to_le32(const uint8_t *p)
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{
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return (uint32_t)p[0] | (uint32_t)p[1] << 8 |
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(uint32_t)p[2] << 16 | (uint32_t)p[3] << 24;
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}
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static inline uint64_t ptr_to_le64(const uint8_t *p)
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{
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return (uint64_t)ptr_to_le32(p) | (uint64_t)ptr_to_le32(p + 4) << 32;
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}
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static inline void le32_to_ptr(uint8_t *p, const uint32_t value)
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{
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p[0] = (uint8_t)(value);
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p[1] = (uint8_t)(value >> 8);
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p[2] = (uint8_t)(value >> 16);
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p[3] = (uint8_t)(value >> 24);
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}
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static inline void le64_to_ptr(uint8_t *p, const uint64_t value)
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{
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le32_to_ptr(p + 4, (uint32_t)(value >> 32));
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le32_to_ptr(p, (uint32_t)(value));
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}
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/*********************************** Keccak ***********************************/
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/* state[x + y*5] */
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#define A(x, y) (x + 5 * y)
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static inline void keccakp_theta(uint64_t s[25])
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{
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uint64_t C[5], D[5];
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/* Step 1 */
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C[0] = s[A(0, 0)] ^ s[A(0, 1)] ^ s[A(0, 2)] ^ s[A(0, 3)] ^ s[A(0, 4)];
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C[1] = s[A(1, 0)] ^ s[A(1, 1)] ^ s[A(1, 2)] ^ s[A(1, 3)] ^ s[A(1, 4)];
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C[2] = s[A(2, 0)] ^ s[A(2, 1)] ^ s[A(2, 2)] ^ s[A(2, 3)] ^ s[A(2, 4)];
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C[3] = s[A(3, 0)] ^ s[A(3, 1)] ^ s[A(3, 2)] ^ s[A(3, 3)] ^ s[A(3, 4)];
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C[4] = s[A(4, 0)] ^ s[A(4, 1)] ^ s[A(4, 2)] ^ s[A(4, 3)] ^ s[A(4, 4)];
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/* Step 2 */
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D[0] = C[4] ^ rol64(C[1], 1);
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D[1] = C[0] ^ rol64(C[2], 1);
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D[2] = C[1] ^ rol64(C[3], 1);
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D[3] = C[2] ^ rol64(C[4], 1);
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D[4] = C[3] ^ rol64(C[0], 1);
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/* Step 3 */
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s[A(0, 0)] ^= D[0];
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s[A(1, 0)] ^= D[1];
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s[A(2, 0)] ^= D[2];
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s[A(3, 0)] ^= D[3];
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s[A(4, 0)] ^= D[4];
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s[A(0, 1)] ^= D[0];
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s[A(1, 1)] ^= D[1];
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s[A(2, 1)] ^= D[2];
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s[A(3, 1)] ^= D[3];
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s[A(4, 1)] ^= D[4];
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s[A(0, 2)] ^= D[0];
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s[A(1, 2)] ^= D[1];
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s[A(2, 2)] ^= D[2];
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s[A(3, 2)] ^= D[3];
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s[A(4, 2)] ^= D[4];
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s[A(0, 3)] ^= D[0];
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s[A(1, 3)] ^= D[1];
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s[A(2, 3)] ^= D[2];
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s[A(3, 3)] ^= D[3];
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s[A(4, 3)] ^= D[4];
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s[A(0, 4)] ^= D[0];
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s[A(1, 4)] ^= D[1];
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s[A(2, 4)] ^= D[2];
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s[A(3, 4)] ^= D[3];
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s[A(4, 4)] ^= D[4];
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}
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static inline void keccakp_rho(uint64_t s[25])
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{
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/* Step 1 */
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/* s[A(0, 0)] = s[A(0, 0)]; */
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#define RHO_ROL(t) (((t + 1) * (t + 2) / 2) % 64)
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/* Step 3 */
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s[A(1, 0)] = rol64(s[A(1, 0)], RHO_ROL(0));
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s[A(0, 2)] = rol64(s[A(0, 2)], RHO_ROL(1));
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s[A(2, 1)] = rol64(s[A(2, 1)], RHO_ROL(2));
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s[A(1, 2)] = rol64(s[A(1, 2)], RHO_ROL(3));
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s[A(2, 3)] = rol64(s[A(2, 3)], RHO_ROL(4));
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s[A(3, 3)] = rol64(s[A(3, 3)], RHO_ROL(5));
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s[A(3, 0)] = rol64(s[A(3, 0)], RHO_ROL(6));
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s[A(0, 1)] = rol64(s[A(0, 1)], RHO_ROL(7));
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s[A(1, 3)] = rol64(s[A(1, 3)], RHO_ROL(8));
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s[A(3, 1)] = rol64(s[A(3, 1)], RHO_ROL(9));
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s[A(1, 4)] = rol64(s[A(1, 4)], RHO_ROL(10));
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s[A(4, 4)] = rol64(s[A(4, 4)], RHO_ROL(11));
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s[A(4, 0)] = rol64(s[A(4, 0)], RHO_ROL(12));
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s[A(0, 3)] = rol64(s[A(0, 3)], RHO_ROL(13));
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s[A(3, 4)] = rol64(s[A(3, 4)], RHO_ROL(14));
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s[A(4, 3)] = rol64(s[A(4, 3)], RHO_ROL(15));
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s[A(3, 2)] = rol64(s[A(3, 2)], RHO_ROL(16));
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s[A(2, 2)] = rol64(s[A(2, 2)], RHO_ROL(17));
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s[A(2, 0)] = rol64(s[A(2, 0)], RHO_ROL(18));
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s[A(0, 4)] = rol64(s[A(0, 4)], RHO_ROL(19));
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s[A(4, 2)] = rol64(s[A(4, 2)], RHO_ROL(20));
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s[A(2, 4)] = rol64(s[A(2, 4)], RHO_ROL(21));
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s[A(4, 1)] = rol64(s[A(4, 1)], RHO_ROL(22));
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s[A(1, 1)] = rol64(s[A(1, 1)], RHO_ROL(23));
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}
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static inline void keccakp_pi(uint64_t s[25])
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{
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uint64_t t = s[A(4, 4)];
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/* Step 1 */
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/* s[A(0, 0)] = s[A(0, 0)]; */
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s[A(4, 4)] = s[A(1, 4)];
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s[A(1, 4)] = s[A(3, 1)];
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s[A(3, 1)] = s[A(1, 3)];
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s[A(1, 3)] = s[A(0, 1)];
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s[A(0, 1)] = s[A(3, 0)];
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s[A(3, 0)] = s[A(3, 3)];
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s[A(3, 3)] = s[A(2, 3)];
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s[A(2, 3)] = s[A(1, 2)];
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s[A(1, 2)] = s[A(2, 1)];
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s[A(2, 1)] = s[A(0, 2)];
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s[A(0, 2)] = s[A(1, 0)];
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s[A(1, 0)] = s[A(1, 1)];
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s[A(1, 1)] = s[A(4, 1)];
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s[A(4, 1)] = s[A(2, 4)];
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s[A(2, 4)] = s[A(4, 2)];
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s[A(4, 2)] = s[A(0, 4)];
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s[A(0, 4)] = s[A(2, 0)];
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s[A(2, 0)] = s[A(2, 2)];
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s[A(2, 2)] = s[A(3, 2)];
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s[A(3, 2)] = s[A(4, 3)];
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s[A(4, 3)] = s[A(3, 4)];
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s[A(3, 4)] = s[A(0, 3)];
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s[A(0, 3)] = s[A(4, 0)];
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s[A(4, 0)] = t;
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}
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static inline void keccakp_chi(uint64_t s[25])
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{
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uint64_t t0[5], t1[5];
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t0[0] = s[A(0, 0)];
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t0[1] = s[A(0, 1)];
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t0[2] = s[A(0, 2)];
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t0[3] = s[A(0, 3)];
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t0[4] = s[A(0, 4)];
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t1[0] = s[A(1, 0)];
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t1[1] = s[A(1, 1)];
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t1[2] = s[A(1, 2)];
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t1[3] = s[A(1, 3)];
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t1[4] = s[A(1, 4)];
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s[A(0, 0)] ^= ~s[A(1, 0)] & s[A(2, 0)];
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s[A(0, 1)] ^= ~s[A(1, 1)] & s[A(2, 1)];
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s[A(0, 2)] ^= ~s[A(1, 2)] & s[A(2, 2)];
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s[A(0, 3)] ^= ~s[A(1, 3)] & s[A(2, 3)];
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s[A(0, 4)] ^= ~s[A(1, 4)] & s[A(2, 4)];
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s[A(1, 0)] ^= ~s[A(2, 0)] & s[A(3, 0)];
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s[A(1, 1)] ^= ~s[A(2, 1)] & s[A(3, 1)];
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s[A(1, 2)] ^= ~s[A(2, 2)] & s[A(3, 2)];
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s[A(1, 3)] ^= ~s[A(2, 3)] & s[A(3, 3)];
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s[A(1, 4)] ^= ~s[A(2, 4)] & s[A(3, 4)];
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s[A(2, 0)] ^= ~s[A(3, 0)] & s[A(4, 0)];
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s[A(2, 1)] ^= ~s[A(3, 1)] & s[A(4, 1)];
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s[A(2, 2)] ^= ~s[A(3, 2)] & s[A(4, 2)];
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s[A(2, 3)] ^= ~s[A(3, 3)] & s[A(4, 3)];
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s[A(2, 4)] ^= ~s[A(3, 4)] & s[A(4, 4)];
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s[A(3, 0)] ^= ~s[A(4, 0)] & t0[0];
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s[A(3, 1)] ^= ~s[A(4, 1)] & t0[1];
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s[A(3, 2)] ^= ~s[A(4, 2)] & t0[2];
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s[A(3, 3)] ^= ~s[A(4, 3)] & t0[3];
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s[A(3, 4)] ^= ~s[A(4, 4)] & t0[4];
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s[A(4, 0)] ^= ~t0[0] & t1[0];
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s[A(4, 1)] ^= ~t0[1] & t1[1];
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s[A(4, 2)] ^= ~t0[2] & t1[2];
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s[A(4, 3)] ^= ~t0[3] & t1[3];
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s[A(4, 4)] ^= ~t0[4] & t1[4];
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}
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static const uint64_t keccakp_iota_vals[] = {
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0x0000000000000001ULL, 0x0000000000008082ULL, 0x800000000000808aULL,
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0x8000000080008000ULL, 0x000000000000808bULL, 0x0000000080000001ULL,
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0x8000000080008081ULL, 0x8000000000008009ULL, 0x000000000000008aULL,
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0x0000000000000088ULL, 0x0000000080008009ULL, 0x000000008000000aULL,
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0x000000008000808bULL, 0x800000000000008bULL, 0x8000000000008089ULL,
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0x8000000000008003ULL, 0x8000000000008002ULL, 0x8000000000000080ULL,
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0x000000000000800aULL, 0x800000008000000aULL, 0x8000000080008081ULL,
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0x8000000000008080ULL, 0x0000000080000001ULL, 0x8000000080008008ULL
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};
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static inline void keccakp_iota(uint64_t s[25], unsigned int round)
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{
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s[0] ^= keccakp_iota_vals[round];
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}
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static inline void keccakp_1600(uint64_t s[25])
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{
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unsigned int round;
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for (round = 0; round < 24; round++) {
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keccakp_theta(s);
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keccakp_rho(s);
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keccakp_pi(s);
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keccakp_chi(s);
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keccakp_iota(s, round);
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}
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}
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/*********************************** SHA-3 ************************************/
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static inline void sha3_init(struct sha_ctx *ctx)
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{
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unsigned int i;
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for (i = 0; i < 25; i++)
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ctx->state[i] = 0;
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ctx->msg_len = 0;
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}
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void sha3_256_init(struct sha_ctx *ctx)
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{
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sha3_init(ctx);
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ctx->r = SHA3_256_SIZE_BLOCK;
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ctx->rword = SHA3_256_SIZE_BLOCK / sizeof(uint64_t);
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ctx->digestsize = SHA3_256_SIZE_DIGEST;
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}
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static inline void sha3_fill_state(struct sha_ctx *ctx, const uint8_t *in)
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{
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unsigned int i;
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for (i = 0; i < ctx->rword; i++) {
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ctx->state[i] ^= ptr_to_le64(in);
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in += 8;
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}
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}
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void sha3_update(struct sha_ctx *ctx, const uint8_t *in, size_t inlen)
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{
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size_t partial = ctx->msg_len % ctx->r;
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ctx->msg_len += inlen;
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/* Sponge absorbing phase */
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/* Check if we have a partial block stored */
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if (partial) {
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size_t todo = ctx->r - partial;
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/*
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* If the provided data is small enough to fit in the partial
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* buffer, copy it and leave it unprocessed.
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*/
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if (inlen < todo) {
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memcpy(ctx->partial + partial, in, inlen);
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return;
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}
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/*
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* The input data is large enough to fill the entire partial
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* block buffer. Thus, we fill it and transform it.
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*/
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memcpy(ctx->partial + partial, in, todo);
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inlen -= todo;
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in += todo;
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sha3_fill_state(ctx, ctx->partial);
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keccakp_1600(ctx->state);
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}
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/* Perform a transformation of full block-size messages */
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for (; inlen >= ctx->r; inlen -= ctx->r, in += ctx->r) {
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sha3_fill_state(ctx, in);
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keccakp_1600(ctx->state);
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}
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/* If we have data left, copy it into the partial block buffer */
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memcpy(ctx->partial, in, inlen);
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}
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void sha3_final(struct sha_ctx *ctx, uint8_t *digest)
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{
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size_t partial = ctx->msg_len % ctx->r;
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unsigned int i;
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/* Final round in sponge absorbing phase */
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/* Fill the unused part of the partial buffer with zeros */
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memset(ctx->partial + partial, 0, ctx->r - partial);
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/*
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* Add the leading and trailing bit as well as the 01 bits for the
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* SHA-3 suffix.
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*/
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ctx->partial[partial] = 0x06;
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ctx->partial[ctx->r - 1] |= 0x80;
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/* Final transformation */
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sha3_fill_state(ctx, ctx->partial);
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keccakp_1600(ctx->state);
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/*
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* Sponge squeeze phase - the digest size is always smaller as the
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* state size r which implies we only have one squeeze round.
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*/
|
||
|
for (i = 0; i < ctx->digestsize / 8; i++, digest += 8)
|
||
|
le64_to_ptr(digest, ctx->state[i]);
|
||
|
|
||
|
/* Add remaining 4 bytes if we use SHA3-224 */
|
||
|
if (ctx->digestsize % 8)
|
||
|
le32_to_ptr(digest, (uint32_t)(ctx->state[i]));
|
||
|
|
||
|
memset(ctx->partial, 0, ctx->r);
|
||
|
sha3_init(ctx);
|
||
|
}
|
||
|
|
||
|
int sha3_tester(void)
|
||
|
{
|
||
|
HASH_CTX_ON_STACK(ctx);
|
||
|
static const uint8_t msg_256[] = { 0x5E, 0x5E, 0xD6 };
|
||
|
static const uint8_t exp_256[] = { 0xF1, 0x6E, 0x66, 0xC0, 0x43, 0x72,
|
||
|
0xB4, 0xA3, 0xE1, 0xE3, 0x2E, 0x07,
|
||
|
0xC4, 0x1C, 0x03, 0x40, 0x8A, 0xD5,
|
||
|
0x43, 0x86, 0x8C, 0xC4, 0x0E, 0xC5,
|
||
|
0x5E, 0x00, 0xBB, 0xBB, 0xBD, 0xF5,
|
||
|
0x91, 0x1E };
|
||
|
uint8_t act[SHA3_256_SIZE_DIGEST] = { 0 };
|
||
|
unsigned int i;
|
||
|
|
||
|
sha3_256_init(&ctx);
|
||
|
sha3_update(&ctx, msg_256, 3);
|
||
|
sha3_final(&ctx, act);
|
||
|
|
||
|
for (i = 0; i < SHA3_256_SIZE_DIGEST; i++) {
|
||
|
if (exp_256[i] != act[i])
|
||
|
return 1;
|
||
|
}
|
||
|
|
||
|
return 0;
|
||
|
}
|
||
|
|
||
|
int sha3_alloc(void **hash_state)
|
||
|
{
|
||
|
struct sha_ctx *tmp;
|
||
|
|
||
|
tmp = jent_zalloc(SHA_MAX_CTX_SIZE);
|
||
|
if (!tmp)
|
||
|
return 1;
|
||
|
|
||
|
*hash_state = tmp;
|
||
|
|
||
|
return 0;
|
||
|
}
|
||
|
|
||
|
void sha3_dealloc(void *hash_state)
|
||
|
{
|
||
|
struct sha_ctx *ctx = (struct sha_ctx *)hash_state;
|
||
|
|
||
|
jent_zfree(ctx, SHA_MAX_CTX_SIZE);
|
||
|
}
|