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360 lines
11 KiB
C
360 lines
11 KiB
C
/* hash.c April 2012
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* Groestl ANSI C code optimised for 32-bit machines
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* Author: Thomas Krinninger
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*
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* This work is based on the implementation of
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* Soeren S. Thomsen and Krystian Matusiewicz
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*
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*
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*/
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#include <stddef.h>
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#include "groestl.h"
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#include "groestl_tables.h"
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#define P_TYPE 0
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#define Q_TYPE 1
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const uint8_t shift_Values[2][8] = {{0,1,2,3,4,5,6,7},{1,3,5,7,0,2,4,6}};
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const uint8_t indices_cyclic[15] = {0,1,2,3,4,5,6,7,0,1,2,3,4,5,6};
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#define ROTATE_COLUMN_DOWN(v1, v2, amount_bytes, temp_var) {temp_var = (v1<<(8*amount_bytes))|(v2>>(8*(4-amount_bytes))); \
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v2 = (v2<<(8*amount_bytes))|(v1>>(8*(4-amount_bytes))); \
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v1 = temp_var;}
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#define COLUMN(x,y,i,c0,c1,c2,c3,c4,c5,c6,c7,tv1,tv2,tu,tl,t) \
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tu = T[2*(uint32_t)x[4*c0+0]]; \
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tl = T[2*(uint32_t)x[4*c0+0]+1]; \
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tv1 = T[2*(uint32_t)x[4*c1+1]]; \
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tv2 = T[2*(uint32_t)x[4*c1+1]+1]; \
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ROTATE_COLUMN_DOWN(tv1,tv2,1,t) \
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tu ^= tv1; \
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tl ^= tv2; \
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tv1 = T[2*(uint32_t)x[4*c2+2]]; \
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tv2 = T[2*(uint32_t)x[4*c2+2]+1]; \
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ROTATE_COLUMN_DOWN(tv1,tv2,2,t) \
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tu ^= tv1; \
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tl ^= tv2; \
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tv1 = T[2*(uint32_t)x[4*c3+3]]; \
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tv2 = T[2*(uint32_t)x[4*c3+3]+1]; \
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ROTATE_COLUMN_DOWN(tv1,tv2,3,t) \
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tu ^= tv1; \
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tl ^= tv2; \
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tl ^= T[2*(uint32_t)x[4*c4+0]]; \
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tu ^= T[2*(uint32_t)x[4*c4+0]+1]; \
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tv1 = T[2*(uint32_t)x[4*c5+1]]; \
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tv2 = T[2*(uint32_t)x[4*c5+1]+1]; \
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ROTATE_COLUMN_DOWN(tv1,tv2,1,t) \
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tl ^= tv1; \
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tu ^= tv2; \
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tv1 = T[2*(uint32_t)x[4*c6+2]]; \
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tv2 = T[2*(uint32_t)x[4*c6+2]+1]; \
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ROTATE_COLUMN_DOWN(tv1,tv2,2,t) \
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tl ^= tv1; \
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tu ^= tv2; \
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tv1 = T[2*(uint32_t)x[4*c7+3]]; \
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tv2 = T[2*(uint32_t)x[4*c7+3]+1]; \
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ROTATE_COLUMN_DOWN(tv1,tv2,3,t) \
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tl ^= tv1; \
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tu ^= tv2; \
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y[i] = tu; \
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y[i+1] = tl;
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/* compute one round of P (short variants) */
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static void RND512P(uint8_t *x, uint32_t *y, uint32_t r) {
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uint32_t temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp;
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uint32_t* x32 = (uint32_t*)x;
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x32[ 0] ^= 0x00000000^r;
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x32[ 2] ^= 0x00000010^r;
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x32[ 4] ^= 0x00000020^r;
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x32[ 6] ^= 0x00000030^r;
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x32[ 8] ^= 0x00000040^r;
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x32[10] ^= 0x00000050^r;
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x32[12] ^= 0x00000060^r;
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x32[14] ^= 0x00000070^r;
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COLUMN(x,y, 0, 0, 2, 4, 6, 9, 11, 13, 15, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y, 2, 2, 4, 6, 8, 11, 13, 15, 1, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y, 4, 4, 6, 8, 10, 13, 15, 1, 3, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y, 6, 6, 8, 10, 12, 15, 1, 3, 5, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y, 8, 8, 10, 12, 14, 1, 3, 5, 7, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y,10, 10, 12, 14, 0, 3, 5, 7, 9, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y,12, 12, 14, 0, 2, 5, 7, 9, 11, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y,14, 14, 0, 2, 4, 7, 9, 11, 13, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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}
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/* compute one round of Q (short variants) */
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static void RND512Q(uint8_t *x, uint32_t *y, uint32_t r) {
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uint32_t temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp;
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uint32_t* x32 = (uint32_t*)x;
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x32[ 0] = ~x32[ 0];
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x32[ 1] ^= 0xffffffff^r;
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x32[ 2] = ~x32[ 2];
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x32[ 3] ^= 0xefffffff^r;
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x32[ 4] = ~x32[ 4];
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x32[ 5] ^= 0xdfffffff^r;
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x32[ 6] = ~x32[ 6];
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x32[ 7] ^= 0xcfffffff^r;
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x32[ 8] = ~x32[ 8];
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x32[ 9] ^= 0xbfffffff^r;
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x32[10] = ~x32[10];
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x32[11] ^= 0xafffffff^r;
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x32[12] = ~x32[12];
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x32[13] ^= 0x9fffffff^r;
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x32[14] = ~x32[14];
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x32[15] ^= 0x8fffffff^r;
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COLUMN(x,y, 0, 2, 6, 10, 14, 1, 5, 9, 13, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y, 2, 4, 8, 12, 0, 3, 7, 11, 15, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y, 4, 6, 10, 14, 2, 5, 9, 13, 1, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y, 6, 8, 12, 0, 4, 7, 11, 15, 3, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y, 8, 10, 14, 2, 6, 9, 13, 1, 5, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y,10, 12, 0, 4, 8, 11, 15, 3, 7, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y,12, 14, 2, 6, 10, 13, 1, 5, 9, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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COLUMN(x,y,14, 0, 4, 8, 12, 15, 3, 7, 11, temp_v1, temp_v2, temp_upper_value, temp_lower_value, temp);
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}
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/* compute compression function (short variants) */
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static void F512(uint32_t *h, const uint32_t *m) {
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int i;
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uint32_t Ptmp[2*COLS512];
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uint32_t Qtmp[2*COLS512];
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uint32_t y[2*COLS512];
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uint32_t z[2*COLS512];
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for (i = 0; i < 2*COLS512; i++) {
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z[i] = m[i];
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Ptmp[i] = h[i]^m[i];
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}
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/* compute Q(m) */
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RND512Q((uint8_t*)z, y, 0x00000000);
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RND512Q((uint8_t*)y, z, 0x01000000);
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RND512Q((uint8_t*)z, y, 0x02000000);
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RND512Q((uint8_t*)y, z, 0x03000000);
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RND512Q((uint8_t*)z, y, 0x04000000);
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RND512Q((uint8_t*)y, z, 0x05000000);
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RND512Q((uint8_t*)z, y, 0x06000000);
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RND512Q((uint8_t*)y, z, 0x07000000);
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RND512Q((uint8_t*)z, y, 0x08000000);
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RND512Q((uint8_t*)y, Qtmp, 0x09000000);
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/* compute P(h+m) */
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RND512P((uint8_t*)Ptmp, y, 0x00000000);
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RND512P((uint8_t*)y, z, 0x00000001);
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RND512P((uint8_t*)z, y, 0x00000002);
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RND512P((uint8_t*)y, z, 0x00000003);
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RND512P((uint8_t*)z, y, 0x00000004);
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RND512P((uint8_t*)y, z, 0x00000005);
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RND512P((uint8_t*)z, y, 0x00000006);
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RND512P((uint8_t*)y, z, 0x00000007);
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RND512P((uint8_t*)z, y, 0x00000008);
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RND512P((uint8_t*)y, Ptmp, 0x00000009);
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/* compute P(h+m) + Q(m) + h */
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for (i = 0; i < 2*COLS512; i++) {
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h[i] ^= Ptmp[i]^Qtmp[i];
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}
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}
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/* digest up to msglen bytes of input (full blocks only) */
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static void Transform(hashState *ctx,
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const uint8_t *input,
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int msglen) {
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/* digest message, one block at a time */
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for (; msglen >= SIZE512;
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msglen -= SIZE512, input += SIZE512) {
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F512(ctx->chaining,(uint32_t*)input);
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/* increment block counter */
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ctx->block_counter1++;
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if (ctx->block_counter1 == 0) ctx->block_counter2++;
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}
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}
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/* given state h, do h <- P(h)+h */
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static void OutputTransformation(hashState *ctx) {
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int j;
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uint32_t temp[2*COLS512];
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uint32_t y[2*COLS512];
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uint32_t z[2*COLS512];
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for (j = 0; j < 2*COLS512; j++) {
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temp[j] = ctx->chaining[j];
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}
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RND512P((uint8_t*)temp, y, 0x00000000);
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RND512P((uint8_t*)y, z, 0x00000001);
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RND512P((uint8_t*)z, y, 0x00000002);
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RND512P((uint8_t*)y, z, 0x00000003);
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RND512P((uint8_t*)z, y, 0x00000004);
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RND512P((uint8_t*)y, z, 0x00000005);
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RND512P((uint8_t*)z, y, 0x00000006);
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RND512P((uint8_t*)y, z, 0x00000007);
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RND512P((uint8_t*)z, y, 0x00000008);
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RND512P((uint8_t*)y, temp, 0x00000009);
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for (j = 0; j < 2*COLS512; j++) {
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ctx->chaining[j] ^= temp[j];
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}
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}
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/* initialise context */
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static void Init(hashState* ctx) {
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/* allocate memory for state and data buffer */
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for(size_t i = 0; i < (SIZE512/sizeof(uint32_t)); i++)
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{
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ctx->chaining[i] = 0;
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}
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/* set initial value */
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ctx->chaining[2*COLS512-1] = u32BIG((uint32_t)HASH_BIT_LEN);
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/* set other variables */
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ctx->buf_ptr = 0;
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ctx->block_counter1 = 0;
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ctx->block_counter2 = 0;
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ctx->bits_in_last_byte = 0;
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}
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/* update state with databitlen bits of input */
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static void Update(hashState* ctx,
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const BitSequence* input,
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DataLength databitlen) {
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int index = 0;
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int msglen = (int)(databitlen/8);
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int rem = (int)(databitlen%8);
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/* if the buffer contains data that has not yet been digested, first
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add data to buffer until full */
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if (ctx->buf_ptr) {
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while (ctx->buf_ptr < SIZE512 && index < msglen) {
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ctx->buffer[(int)ctx->buf_ptr++] = input[index++];
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}
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if (ctx->buf_ptr < SIZE512) {
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/* buffer still not full, return */
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if (rem) {
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ctx->bits_in_last_byte = rem;
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ctx->buffer[(int)ctx->buf_ptr++] = input[index];
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}
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return;
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}
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/* digest buffer */
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ctx->buf_ptr = 0;
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Transform(ctx, ctx->buffer, SIZE512);
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}
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/* digest bulk of message */
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Transform(ctx, input+index, msglen-index);
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index += ((msglen-index)/SIZE512)*SIZE512;
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/* store remaining data in buffer */
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while (index < msglen) {
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ctx->buffer[(int)ctx->buf_ptr++] = input[index++];
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}
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/* if non-integral number of bytes have been supplied, store
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remaining bits in last byte, together with information about
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number of bits */
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if (rem) {
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ctx->bits_in_last_byte = rem;
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ctx->buffer[(int)ctx->buf_ptr++] = input[index];
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}
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}
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#define BILB ctx->bits_in_last_byte
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/* finalise: process remaining data (including padding), perform
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output transformation, and write hash result to 'output' */
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static void Final(hashState* ctx,
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BitSequence* output) {
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int i, j = 0, hashbytelen = HASH_BIT_LEN/8;
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uint8_t *s = (BitSequence*)ctx->chaining;
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/* pad with '1'-bit and first few '0'-bits */
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if (BILB) {
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ctx->buffer[(int)ctx->buf_ptr-1] &= ((1<<BILB)-1)<<(8-BILB);
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ctx->buffer[(int)ctx->buf_ptr-1] ^= 0x1<<(7-BILB);
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BILB = 0;
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}
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else ctx->buffer[(int)ctx->buf_ptr++] = 0x80;
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/* pad with '0'-bits */
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if (ctx->buf_ptr > SIZE512-LENGTHFIELDLEN) {
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/* padding requires two blocks */
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while (ctx->buf_ptr < SIZE512) {
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ctx->buffer[(int)ctx->buf_ptr++] = 0;
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}
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/* digest first padding block */
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Transform(ctx, ctx->buffer, SIZE512);
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ctx->buf_ptr = 0;
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}
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while (ctx->buf_ptr < SIZE512-LENGTHFIELDLEN) {
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ctx->buffer[(int)ctx->buf_ptr++] = 0;
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}
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/* length padding */
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ctx->block_counter1++;
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if (ctx->block_counter1 == 0) ctx->block_counter2++;
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ctx->buf_ptr = SIZE512;
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while (ctx->buf_ptr > SIZE512-(int)sizeof(uint32_t)) {
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ctx->buffer[(int)--ctx->buf_ptr] = (uint8_t)ctx->block_counter1;
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ctx->block_counter1 >>= 8;
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}
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while (ctx->buf_ptr > SIZE512-LENGTHFIELDLEN) {
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ctx->buffer[(int)--ctx->buf_ptr] = (uint8_t)ctx->block_counter2;
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ctx->block_counter2 >>= 8;
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}
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/* digest final padding block */
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Transform(ctx, ctx->buffer, SIZE512);
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/* perform output transformation */
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OutputTransformation(ctx);
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/* store hash result in output */
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for (i = SIZE512-hashbytelen; i < SIZE512; i++,j++) {
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output[j] = s[i];
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}
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/* zeroise relevant variables and deallocate memory */
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for (i = 0; i < COLS512; i++) {
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ctx->chaining[i] = 0;
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}
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for (i = 0; i < SIZE512; i++) {
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ctx->buffer[i] = 0;
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}
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}
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/* hash bit sequence */
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void groestl(const BitSequence* data,
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DataLength databitlen,
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BitSequence* hashval) {
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hashState context;
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/* initialise */
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Init(&context);
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/* process message */
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Update(&context, data, databitlen);
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/* finalise */
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Final(&context, hashval);
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}
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/*
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static int crypto_hash(unsigned char *out,
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const unsigned char *in,
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unsigned long long len)
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{
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groestl(in, 8*len, out);
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return 0;
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}
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*/
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