popov/cpuminer-opt-gpu
1
0
Fork 0
mirror of https://github.com/JayDDee/cpuminer-opt.git synced 2025-09-17 23:44:27 +00:00
Code Issues Packages Projects Releases Wiki Activity

v3.8.1

Browse Source
This commit is contained in:
Jay D Dee
2018-02-07 16:38:45 -05:00
parent 54b8fd7362
commit a28daca3ce
83 changed files with 5153 additions and 3924 deletions
Download Patch File Download Diff File Expand all files Collapse all files

977
algo/hamsi/hamsi-hash-4way.c
View File

File diff suppressed because it is too large Load Diff

14
algo/hamsi/hamsi-hash-4way.h
View File

@@ -48,20 +48,20 @@ extern "C"{
#define SPH_SIZE_hamsi512 512
// Partial is only scalar but needs pointer ref for hamsi-helper
// deprecate partial_len
typedef struct {
__m128i h[16];
__m128i partial[2];
__m256i h[8];
__m256i buf[1];
size_t partial_len;
sph_u32 count_high, count_low;
} hamsi_4way_big_context;
typedef hamsi_4way_big_context hamsi512_4way_context;
void hamsi512_4way_init(void *cc);
void hamsi512_4way(void *cc, const void *data, size_t len);
void hamsi512_4way_close(void *cc, void *dst);
void hamsi512_4way_init( hamsi512_4way_context *sc );
void hamsi512_4way( hamsi512_4way_context *sc, const void *data, size_t len );
void hamsi512_4way_close( hamsi512_4way_context *sc, void *dst );
#ifdef __cplusplus
}

482
algo/hamsi/hamsi-helper-4way.c
View File

@@ -1,482 +0,0 @@
/* $Id: hamsi_helper.c 202 2010-05-31 15:46:48Z tp $ */
/*
* Helper code for Hamsi (input block expansion). This code is
* automatically generated and includes precomputed tables for
* expansion code which handles 2 to 8 bits at a time.
*
* This file is included from hamsi.c, and is not meant to be compiled
* independently.
*
* ==========================(LICENSE BEGIN)============================
*
* Copyright (c) 2007-2010 Projet RNRT SAPHIR
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
* ===========================(LICENSE END)=============================
*
* @author Thomas Pornin <thomas.pornin@cryptolog.com>
*/
#ifdef __cplusplus
extern "C"{
#endif
/* Note: this table lists bits within each byte from least
siginificant to most significant. */
static const sph_u32 T512[64][16] = {
{ SPH_C32(0xef0b0270), SPH_C32(0x3afd0000), SPH_C32(0x5dae0000),
SPH_C32(0x69490000), SPH_C32(0x9b0f3c06), SPH_C32(0x4405b5f9),
SPH_C32(0x66140a51), SPH_C32(0x924f5d0a), SPH_C32(0xc96b0030),
SPH_C32(0xe7250000), SPH_C32(0x2f840000), SPH_C32(0x264f0000),
SPH_C32(0x08695bf9), SPH_C32(0x6dfcf137), SPH_C32(0x509f6984),
SPH_C32(0x9e69af68) },
{ SPH_C32(0xc96b0030), SPH_C32(0xe7250000), SPH_C32(0x2f840000),
SPH_C32(0x264f0000), SPH_C32(0x08695bf9), SPH_C32(0x6dfcf137),
SPH_C32(0x509f6984), SPH_C32(0x9e69af68), SPH_C32(0x26600240),
SPH_C32(0xddd80000), SPH_C32(0x722a0000), SPH_C32(0x4f060000),
SPH_C32(0x936667ff), SPH_C32(0x29f944ce), SPH_C32(0x368b63d5),
SPH_C32(0x0c26f262) },
{ SPH_C32(0x145a3c00), SPH_C32(0xb9e90000), SPH_C32(0x61270000),
SPH_C32(0xf1610000), SPH_C32(0xce613d6c), SPH_C32(0xb0493d78),
SPH_C32(0x47a96720), SPH_C32(0xe18e24c5), SPH_C32(0x23671400),
SPH_C32(0xc8b90000), SPH_C32(0xf4c70000), SPH_C32(0xfb750000),
SPH_C32(0x73cd2465), SPH_C32(0xf8a6a549), SPH_C32(0x02c40a3f),
SPH_C32(0xdc24e61f) },
{ SPH_C32(0x23671400), SPH_C32(0xc8b90000), SPH_C32(0xf4c70000),
SPH_C32(0xfb750000), SPH_C32(0x73cd2465), SPH_C32(0xf8a6a549),
SPH_C32(0x02c40a3f), SPH_C32(0xdc24e61f), SPH_C32(0x373d2800),
SPH_C32(0x71500000), SPH_C32(0x95e00000), SPH_C32(0x0a140000),
SPH_C32(0xbdac1909), SPH_C32(0x48ef9831), SPH_C32(0x456d6d1f),
SPH_C32(0x3daac2da) },
{ SPH_C32(0x54285c00), SPH_C32(0xeaed0000), SPH_C32(0xc5d60000),
SPH_C32(0xa1c50000), SPH_C32(0xb3a26770), SPH_C32(0x94a5c4e1),
SPH_C32(0x6bb0419d), SPH_C32(0x551b3782), SPH_C32(0x9cbb1800),
SPH_C32(0xb0d30000), SPH_C32(0x92510000), SPH_C32(0xed930000),
SPH_C32(0x593a4345), SPH_C32(0xe114d5f4), SPH_C32(0x430633da),
SPH_C32(0x78cace29) },
{ SPH_C32(0x9cbb1800), SPH_C32(0xb0d30000), SPH_C32(0x92510000),
SPH_C32(0xed930000), SPH_C32(0x593a4345), SPH_C32(0xe114d5f4),
SPH_C32(0x430633da), SPH_C32(0x78cace29), SPH_C32(0xc8934400),
SPH_C32(0x5a3e0000), SPH_C32(0x57870000), SPH_C32(0x4c560000),
SPH_C32(0xea982435), SPH_C32(0x75b11115), SPH_C32(0x28b67247),
SPH_C32(0x2dd1f9ab) },
{ SPH_C32(0x29449c00), SPH_C32(0x64e70000), SPH_C32(0xf24b0000),
SPH_C32(0xc2f30000), SPH_C32(0x0ede4e8f), SPH_C32(0x56c23745),
SPH_C32(0xf3e04259), SPH_C32(0x8d0d9ec4), SPH_C32(0x466d0c00),
SPH_C32(0x08620000), SPH_C32(0xdd5d0000), SPH_C32(0xbadd0000),
SPH_C32(0x6a927942), SPH_C32(0x441f2b93), SPH_C32(0x218ace6f),
SPH_C32(0xbf2c0be2) },
{ SPH_C32(0x466d0c00), SPH_C32(0x08620000), SPH_C32(0xdd5d0000),
SPH_C32(0xbadd0000), SPH_C32(0x6a927942), SPH_C32(0x441f2b93),
SPH_C32(0x218ace6f), SPH_C32(0xbf2c0be2), SPH_C32(0x6f299000),
SPH_C32(0x6c850000), SPH_C32(0x2f160000), SPH_C32(0x782e0000),
SPH_C32(0x644c37cd), SPH_C32(0x12dd1cd6), SPH_C32(0xd26a8c36),
SPH_C32(0x32219526) },
{ SPH_C32(0xf6800005), SPH_C32(0x3443c000), SPH_C32(0x24070000),
SPH_C32(0x8f3d0000), SPH_C32(0x21373bfb), SPH_C32(0x0ab8d5ae),
SPH_C32(0xcdc58b19), SPH_C32(0xd795ba31), SPH_C32(0xa67f0001),
SPH_C32(0x71378000), SPH_C32(0x19fc0000), SPH_C32(0x96db0000),
SPH_C32(0x3a8b6dfd), SPH_C32(0xebcaaef3), SPH_C32(0x2c6d478f),
SPH_C32(0xac8e6c88) },
{ SPH_C32(0xa67f0001), SPH_C32(0x71378000), SPH_C32(0x19fc0000),
SPH_C32(0x96db0000), SPH_C32(0x3a8b6dfd), SPH_C32(0xebcaaef3),
SPH_C32(0x2c6d478f), SPH_C32(0xac8e6c88), SPH_C32(0x50ff0004),
SPH_C32(0x45744000), SPH_C32(0x3dfb0000), SPH_C32(0x19e60000),
SPH_C32(0x1bbc5606), SPH_C32(0xe1727b5d), SPH_C32(0xe1a8cc96),
SPH_C32(0x7b1bd6b9) },
{ SPH_C32(0xf7750009), SPH_C32(0xcf3cc000), SPH_C32(0xc3d60000),
SPH_C32(0x04920000), SPH_C32(0x029519a9), SPH_C32(0xf8e836ba),
SPH_C32(0x7a87f14e), SPH_C32(0x9e16981a), SPH_C32(0xd46a0000),
SPH_C32(0x8dc8c000), SPH_C32(0xa5af0000), SPH_C32(0x4a290000),
SPH_C32(0xfc4e427a), SPH_C32(0xc9b4866c), SPH_C32(0x98369604),
SPH_C32(0xf746c320) },
{ SPH_C32(0xd46a0000), SPH_C32(0x8dc8c000), SPH_C32(0xa5af0000),
SPH_C32(0x4a290000), SPH_C32(0xfc4e427a), SPH_C32(0xc9b4866c),
SPH_C32(0x98369604), SPH_C32(0xf746c320), SPH_C32(0x231f0009),
SPH_C32(0x42f40000), SPH_C32(0x66790000), SPH_C32(0x4ebb0000),
SPH_C32(0xfedb5bd3), SPH_C32(0x315cb0d6), SPH_C32(0xe2b1674a),
SPH_C32(0x69505b3a) },
{ SPH_C32(0x774400f0), SPH_C32(0xf15a0000), SPH_C32(0xf5b20000),
SPH_C32(0x34140000), SPH_C32(0x89377e8c), SPH_C32(0x5a8bec25),
SPH_C32(0x0bc3cd1e), SPH_C32(0xcf3775cb), SPH_C32(0xf46c0050),
SPH_C32(0x96180000), SPH_C32(0x14a50000), SPH_C32(0x031f0000),
SPH_C32(0x42947eb8), SPH_C32(0x66bf7e19), SPH_C32(0x9ca470d2),
SPH_C32(0x8a341574) },
{ SPH_C32(0xf46c0050), SPH_C32(0x96180000), SPH_C32(0x14a50000),
SPH_C32(0x031f0000), SPH_C32(0x42947eb8), SPH_C32(0x66bf7e19),
SPH_C32(0x9ca470d2), SPH_C32(0x8a341574), SPH_C32(0x832800a0),
SPH_C32(0x67420000), SPH_C32(0xe1170000), SPH_C32(0x370b0000),
SPH_C32(0xcba30034), SPH_C32(0x3c34923c), SPH_C32(0x9767bdcc),
SPH_C32(0x450360bf) },
{ SPH_C32(0xe8870170), SPH_C32(0x9d720000), SPH_C32(0x12db0000),
SPH_C32(0xd4220000), SPH_C32(0xf2886b27), SPH_C32(0xa921e543),
SPH_C32(0x4ef8b518), SPH_C32(0x618813b1), SPH_C32(0xb4370060),
SPH_C32(0x0c4c0000), SPH_C32(0x56c20000), SPH_C32(0x5cae0000),
SPH_C32(0x94541f3f), SPH_C32(0x3b3ef825), SPH_C32(0x1b365f3d),
SPH_C32(0xf3d45758) },
{ SPH_C32(0xb4370060), SPH_C32(0x0c4c0000), SPH_C32(0x56c20000),
SPH_C32(0x5cae0000), SPH_C32(0x94541f3f), SPH_C32(0x3b3ef825),
SPH_C32(0x1b365f3d), SPH_C32(0xf3d45758), SPH_C32(0x5cb00110),
SPH_C32(0x913e0000), SPH_C32(0x44190000), SPH_C32(0x888c0000),
SPH_C32(0x66dc7418), SPH_C32(0x921f1d66), SPH_C32(0x55ceea25),
SPH_C32(0x925c44e9) },
{ SPH_C32(0x0c720000), SPH_C32(0x49e50f00), SPH_C32(0x42790000),
SPH_C32(0x5cea0000), SPH_C32(0x33aa301a), SPH_C32(0x15822514),
SPH_C32(0x95a34b7b), SPH_C32(0xb44b0090), SPH_C32(0xfe220000),
SPH_C32(0xa7580500), SPH_C32(0x25d10000), SPH_C32(0xf7600000),
SPH_C32(0x893178da), SPH_C32(0x1fd4f860), SPH_C32(0x4ed0a315),
SPH_C32(0xa123ff9f) },
{ SPH_C32(0xfe220000), SPH_C32(0xa7580500), SPH_C32(0x25d10000),
SPH_C32(0xf7600000), SPH_C32(0x893178da), SPH_C32(0x1fd4f860),
SPH_C32(0x4ed0a315), SPH_C32(0xa123ff9f), SPH_C32(0xf2500000),
SPH_C32(0xeebd0a00), SPH_C32(0x67a80000), SPH_C32(0xab8a0000),
SPH_C32(0xba9b48c0), SPH_C32(0x0a56dd74), SPH_C32(0xdb73e86e),
SPH_C32(0x1568ff0f) },
{ SPH_C32(0x45180000), SPH_C32(0xa5b51700), SPH_C32(0xf96a0000),
SPH_C32(0x3b480000), SPH_C32(0x1ecc142c), SPH_C32(0x231395d6),
SPH_C32(0x16bca6b0), SPH_C32(0xdf33f4df), SPH_C32(0xb83d0000),
SPH_C32(0x16710600), SPH_C32(0x379a0000), SPH_C32(0xf5b10000),
SPH_C32(0x228161ac), SPH_C32(0xae48f145), SPH_C32(0x66241616),
SPH_C32(0xc5c1eb3e) },
{ SPH_C32(0xb83d0000), SPH_C32(0x16710600), SPH_C32(0x379a0000),
SPH_C32(0xf5b10000), SPH_C32(0x228161ac), SPH_C32(0xae48f145),
SPH_C32(0x66241616), SPH_C32(0xc5c1eb3e), SPH_C32(0xfd250000),
SPH_C32(0xb3c41100), SPH_C32(0xcef00000), SPH_C32(0xcef90000),
SPH_C32(0x3c4d7580), SPH_C32(0x8d5b6493), SPH_C32(0x7098b0a6),
SPH_C32(0x1af21fe1) },
{ SPH_C32(0x75a40000), SPH_C32(0xc28b2700), SPH_C32(0x94a40000),
SPH_C32(0x90f50000), SPH_C32(0xfb7857e0), SPH_C32(0x49ce0bae),
SPH_C32(0x1767c483), SPH_C32(0xaedf667e), SPH_C32(0xd1660000),
SPH_C32(0x1bbc0300), SPH_C32(0x9eec0000), SPH_C32(0xf6940000),
SPH_C32(0x03024527), SPH_C32(0xcf70fcf2), SPH_C32(0xb4431b17),
SPH_C32(0x857f3c2b) },
{ SPH_C32(0xd1660000), SPH_C32(0x1bbc0300), SPH_C32(0x9eec0000),
SPH_C32(0xf6940000), SPH_C32(0x03024527), SPH_C32(0xcf70fcf2),
SPH_C32(0xb4431b17), SPH_C32(0x857f3c2b), SPH_C32(0xa4c20000),
SPH_C32(0xd9372400), SPH_C32(0x0a480000), SPH_C32(0x66610000),
SPH_C32(0xf87a12c7), SPH_C32(0x86bef75c), SPH_C32(0xa324df94),
SPH_C32(0x2ba05a55) },
{ SPH_C32(0x75c90003), SPH_C32(0x0e10c000), SPH_C32(0xd1200000),
SPH_C32(0xbaea0000), SPH_C32(0x8bc42f3e), SPH_C32(0x8758b757),
SPH_C32(0xbb28761d), SPH_C32(0x00b72e2b), SPH_C32(0xeecf0001),
SPH_C32(0x6f564000), SPH_C32(0xf33e0000), SPH_C32(0xa79e0000),
SPH_C32(0xbdb57219), SPH_C32(0xb711ebc5), SPH_C32(0x4a3b40ba),
SPH_C32(0xfeabf254) },
{ SPH_C32(0xeecf0001), SPH_C32(0x6f564000), SPH_C32(0xf33e0000),
SPH_C32(0xa79e0000), SPH_C32(0xbdb57219), SPH_C32(0xb711ebc5),
SPH_C32(0x4a3b40ba), SPH_C32(0xfeabf254), SPH_C32(0x9b060002),
SPH_C32(0x61468000), SPH_C32(0x221e0000), SPH_C32(0x1d740000),
SPH_C32(0x36715d27), SPH_C32(0x30495c92), SPH_C32(0xf11336a7),
SPH_C32(0xfe1cdc7f) },
{ SPH_C32(0x86790000), SPH_C32(0x3f390002), SPH_C32(0xe19ae000),
SPH_C32(0x98560000), SPH_C32(0x9565670e), SPH_C32(0x4e88c8ea),
SPH_C32(0xd3dd4944), SPH_C32(0x161ddab9), SPH_C32(0x30b70000),
SPH_C32(0xe5d00000), SPH_C32(0xf4f46000), SPH_C32(0x42c40000),
SPH_C32(0x63b83d6a), SPH_C32(0x78ba9460), SPH_C32(0x21afa1ea),
SPH_C32(0xb0a51834) },
{ SPH_C32(0x30b70000), SPH_C32(0xe5d00000), SPH_C32(0xf4f46000),
SPH_C32(0x42c40000), SPH_C32(0x63b83d6a), SPH_C32(0x78ba9460),
SPH_C32(0x21afa1ea), SPH_C32(0xb0a51834), SPH_C32(0xb6ce0000),
SPH_C32(0xdae90002), SPH_C32(0x156e8000), SPH_C32(0xda920000),
SPH_C32(0xf6dd5a64), SPH_C32(0x36325c8a), SPH_C32(0xf272e8ae),
SPH_C32(0xa6b8c28d) },
{ SPH_C32(0x14190000), SPH_C32(0x23ca003c), SPH_C32(0x50df0000),
SPH_C32(0x44b60000), SPH_C32(0x1b6c67b0), SPH_C32(0x3cf3ac75),
SPH_C32(0x61e610b0), SPH_C32(0xdbcadb80), SPH_C32(0xe3430000),
SPH_C32(0x3a4e0014), SPH_C32(0xf2c60000), SPH_C32(0xaa4e0000),
SPH_C32(0xdb1e42a6), SPH_C32(0x256bbe15), SPH_C32(0x123db156),
SPH_C32(0x3a4e99d7) },
{ SPH_C32(0xe3430000), SPH_C32(0x3a4e0014), SPH_C32(0xf2c60000),
SPH_C32(0xaa4e0000), SPH_C32(0xdb1e42a6), SPH_C32(0x256bbe15),
SPH_C32(0x123db156), SPH_C32(0x3a4e99d7), SPH_C32(0xf75a0000),
SPH_C32(0x19840028), SPH_C32(0xa2190000), SPH_C32(0xeef80000),
SPH_C32(0xc0722516), SPH_C32(0x19981260), SPH_C32(0x73dba1e6),
SPH_C32(0xe1844257) },
{ SPH_C32(0x54500000), SPH_C32(0x0671005c), SPH_C32(0x25ae0000),
SPH_C32(0x6a1e0000), SPH_C32(0x2ea54edf), SPH_C32(0x664e8512),
SPH_C32(0xbfba18c3), SPH_C32(0x7e715d17), SPH_C32(0xbc8d0000),
SPH_C32(0xfc3b0018), SPH_C32(0x19830000), SPH_C32(0xd10b0000),
SPH_C32(0xae1878c4), SPH_C32(0x42a69856), SPH_C32(0x0012da37),
SPH_C32(0x2c3b504e) },
{ SPH_C32(0xbc8d0000), SPH_C32(0xfc3b0018), SPH_C32(0x19830000),
SPH_C32(0xd10b0000), SPH_C32(0xae1878c4), SPH_C32(0x42a69856),
SPH_C32(0x0012da37), SPH_C32(0x2c3b504e), SPH_C32(0xe8dd0000),
SPH_C32(0xfa4a0044), SPH_C32(0x3c2d0000), SPH_C32(0xbb150000),
SPH_C32(0x80bd361b), SPH_C32(0x24e81d44), SPH_C32(0xbfa8c2f4),
SPH_C32(0x524a0d59) },
{ SPH_C32(0x69510000), SPH_C32(0xd4e1009c), SPH_C32(0xc3230000),
SPH_C32(0xac2f0000), SPH_C32(0xe4950bae), SPH_C32(0xcea415dc),
SPH_C32(0x87ec287c), SPH_C32(0xbce1a3ce), SPH_C32(0xc6730000),
SPH_C32(0xaf8d000c), SPH_C32(0xa4c10000), SPH_C32(0x218d0000),
SPH_C32(0x23111587), SPH_C32(0x7913512f), SPH_C32(0x1d28ac88),
SPH_C32(0x378dd173) },
{ SPH_C32(0xc6730000), SPH_C32(0xaf8d000c), SPH_C32(0xa4c10000),
SPH_C32(0x218d0000), SPH_C32(0x23111587), SPH_C32(0x7913512f),
SPH_C32(0x1d28ac88), SPH_C32(0x378dd173), SPH_C32(0xaf220000),
SPH_C32(0x7b6c0090), SPH_C32(0x67e20000), SPH_C32(0x8da20000),
SPH_C32(0xc7841e29), SPH_C32(0xb7b744f3), SPH_C32(0x9ac484f4),
SPH_C32(0x8b6c72bd) },
{ SPH_C32(0xcc140000), SPH_C32(0xa5630000), SPH_C32(0x5ab90780),
SPH_C32(0x3b500000), SPH_C32(0x4bd013ff), SPH_C32(0x879b3418),
SPH_C32(0x694348c1), SPH_C32(0xca5a87fe), SPH_C32(0x819e0000),
SPH_C32(0xec570000), SPH_C32(0x66320280), SPH_C32(0x95f30000),
SPH_C32(0x5da92802), SPH_C32(0x48f43cbc), SPH_C32(0xe65aa22d),
SPH_C32(0x8e67b7fa) },
{ SPH_C32(0x819e0000), SPH_C32(0xec570000), SPH_C32(0x66320280),
SPH_C32(0x95f30000), SPH_C32(0x5da92802), SPH_C32(0x48f43cbc),
SPH_C32(0xe65aa22d), SPH_C32(0x8e67b7fa), SPH_C32(0x4d8a0000),
SPH_C32(0x49340000), SPH_C32(0x3c8b0500), SPH_C32(0xaea30000),
SPH_C32(0x16793bfd), SPH_C32(0xcf6f08a4), SPH_C32(0x8f19eaec),
SPH_C32(0x443d3004) },
{ SPH_C32(0x78230000), SPH_C32(0x12fc0000), SPH_C32(0xa93a0b80),
SPH_C32(0x90a50000), SPH_C32(0x713e2879), SPH_C32(0x7ee98924),
SPH_C32(0xf08ca062), SPH_C32(0x636f8bab), SPH_C32(0x02af0000),
SPH_C32(0xb7280000), SPH_C32(0xba1c0300), SPH_C32(0x56980000),
SPH_C32(0xba8d45d3), SPH_C32(0x8048c667), SPH_C32(0xa95c149a),
SPH_C32(0xf4f6ea7b) },
{ SPH_C32(0x02af0000), SPH_C32(0xb7280000), SPH_C32(0xba1c0300),
SPH_C32(0x56980000), SPH_C32(0xba8d45d3), SPH_C32(0x8048c667),
SPH_C32(0xa95c149a), SPH_C32(0xf4f6ea7b), SPH_C32(0x7a8c0000),
SPH_C32(0xa5d40000), SPH_C32(0x13260880), SPH_C32(0xc63d0000),
SPH_C32(0xcbb36daa), SPH_C32(0xfea14f43), SPH_C32(0x59d0b4f8),
SPH_C32(0x979961d0) },
{ SPH_C32(0xac480000), SPH_C32(0x1ba60000), SPH_C32(0x45fb1380),
SPH_C32(0x03430000), SPH_C32(0x5a85316a), SPH_C32(0x1fb250b6),
SPH_C32(0xfe72c7fe), SPH_C32(0x91e478f6), SPH_C32(0x1e4e0000),
SPH_C32(0xdecf0000), SPH_C32(0x6df80180), SPH_C32(0x77240000),
SPH_C32(0xec47079e), SPH_C32(0xf4a0694e), SPH_C32(0xcda31812),
SPH_C32(0x98aa496e) },
{ SPH_C32(0x1e4e0000), SPH_C32(0xdecf0000), SPH_C32(0x6df80180),
SPH_C32(0x77240000), SPH_C32(0xec47079e), SPH_C32(0xf4a0694e),
SPH_C32(0xcda31812), SPH_C32(0x98aa496e), SPH_C32(0xb2060000),
SPH_C32(0xc5690000), SPH_C32(0x28031200), SPH_C32(0x74670000),
SPH_C32(0xb6c236f4), SPH_C32(0xeb1239f8), SPH_C32(0x33d1dfec),
SPH_C32(0x094e3198) },
{ SPH_C32(0xaec30000), SPH_C32(0x9c4f0001), SPH_C32(0x79d1e000),
SPH_C32(0x2c150000), SPH_C32(0x45cc75b3), SPH_C32(0x6650b736),
SPH_C32(0xab92f78f), SPH_C32(0xa312567b), SPH_C32(0xdb250000),
SPH_C32(0x09290000), SPH_C32(0x49aac000), SPH_C32(0x81e10000),
SPH_C32(0xcafe6b59), SPH_C32(0x42793431), SPH_C32(0x43566b76),
SPH_C32(0xe86cba2e) },
{ SPH_C32(0xdb250000), SPH_C32(0x09290000), SPH_C32(0x49aac000),
SPH_C32(0x81e10000), SPH_C32(0xcafe6b59), SPH_C32(0x42793431),
SPH_C32(0x43566b76), SPH_C32(0xe86cba2e), SPH_C32(0x75e60000),
SPH_C32(0x95660001), SPH_C32(0x307b2000), SPH_C32(0xadf40000),
SPH_C32(0x8f321eea), SPH_C32(0x24298307), SPH_C32(0xe8c49cf9),
SPH_C32(0x4b7eec55) },
{ SPH_C32(0x58430000), SPH_C32(0x807e0000), SPH_C32(0x78330001),
SPH_C32(0xc66b3800), SPH_C32(0xe7375cdc), SPH_C32(0x79ad3fdd),
SPH_C32(0xac73fe6f), SPH_C32(0x3a4479b1), SPH_C32(0x1d5a0000),
SPH_C32(0x2b720000), SPH_C32(0x488d0000), SPH_C32(0xaf611800),
SPH_C32(0x25cb2ec5), SPH_C32(0xc879bfd0), SPH_C32(0x81a20429),
SPH_C32(0x1e7536a6) },
{ SPH_C32(0x1d5a0000), SPH_C32(0x2b720000), SPH_C32(0x488d0000),
SPH_C32(0xaf611800), SPH_C32(0x25cb2ec5), SPH_C32(0xc879bfd0),
SPH_C32(0x81a20429), SPH_C32(0x1e7536a6), SPH_C32(0x45190000),
SPH_C32(0xab0c0000), SPH_C32(0x30be0001), SPH_C32(0x690a2000),
SPH_C32(0xc2fc7219), SPH_C32(0xb1d4800d), SPH_C32(0x2dd1fa46),
SPH_C32(0x24314f17) },
{ SPH_C32(0xa53b0000), SPH_C32(0x14260000), SPH_C32(0x4e30001e),
SPH_C32(0x7cae0000), SPH_C32(0x8f9e0dd5), SPH_C32(0x78dfaa3d),
SPH_C32(0xf73168d8), SPH_C32(0x0b1b4946), SPH_C32(0x07ed0000),
SPH_C32(0xb2500000), SPH_C32(0x8774000a), SPH_C32(0x970d0000),
SPH_C32(0x437223ae), SPH_C32(0x48c76ea4), SPH_C32(0xf4786222),
SPH_C32(0x9075b1ce) },
{ SPH_C32(0x07ed0000), SPH_C32(0xb2500000), SPH_C32(0x8774000a),
SPH_C32(0x970d0000), SPH_C32(0x437223ae), SPH_C32(0x48c76ea4),
SPH_C32(0xf4786222), SPH_C32(0x9075b1ce), SPH_C32(0xa2d60000),
SPH_C32(0xa6760000), SPH_C32(0xc9440014), SPH_C32(0xeba30000),
SPH_C32(0xccec2e7b), SPH_C32(0x3018c499), SPH_C32(0x03490afa),
SPH_C32(0x9b6ef888) },
{ SPH_C32(0x88980000), SPH_C32(0x1f940000), SPH_C32(0x7fcf002e),
SPH_C32(0xfb4e0000), SPH_C32(0xf158079a), SPH_C32(0x61ae9167),
SPH_C32(0xa895706c), SPH_C32(0xe6107494), SPH_C32(0x0bc20000),
SPH_C32(0xdb630000), SPH_C32(0x7e88000c), SPH_C32(0x15860000),
SPH_C32(0x91fd48f3), SPH_C32(0x7581bb43), SPH_C32(0xf460449e),
SPH_C32(0xd8b61463) },
{ SPH_C32(0x0bc20000), SPH_C32(0xdb630000), SPH_C32(0x7e88000c),
SPH_C32(0x15860000), SPH_C32(0x91fd48f3), SPH_C32(0x7581bb43),
SPH_C32(0xf460449e), SPH_C32(0xd8b61463), SPH_C32(0x835a0000),
SPH_C32(0xc4f70000), SPH_C32(0x01470022), SPH_C32(0xeec80000),
SPH_C32(0x60a54f69), SPH_C32(0x142f2a24), SPH_C32(0x5cf534f2),
SPH_C32(0x3ea660f7) },
{ SPH_C32(0x52500000), SPH_C32(0x29540000), SPH_C32(0x6a61004e),
SPH_C32(0xf0ff0000), SPH_C32(0x9a317eec), SPH_C32(0x452341ce),
SPH_C32(0xcf568fe5), SPH_C32(0x5303130f), SPH_C32(0x538d0000),
SPH_C32(0xa9fc0000), SPH_C32(0x9ef70006), SPH_C32(0x56ff0000),
SPH_C32(0x0ae4004e), SPH_C32(0x92c5cdf9), SPH_C32(0xa9444018),
SPH_C32(0x7f975691) },
{ SPH_C32(0x538d0000), SPH_C32(0xa9fc0000), SPH_C32(0x9ef70006),
SPH_C32(0x56ff0000), SPH_C32(0x0ae4004e), SPH_C32(0x92c5cdf9),
SPH_C32(0xa9444018), SPH_C32(0x7f975691), SPH_C32(0x01dd0000),
SPH_C32(0x80a80000), SPH_C32(0xf4960048), SPH_C32(0xa6000000),
SPH_C32(0x90d57ea2), SPH_C32(0xd7e68c37), SPH_C32(0x6612cffd),
SPH_C32(0x2c94459e) },
{ SPH_C32(0xe6280000), SPH_C32(0x4c4b0000), SPH_C32(0xa8550000),
SPH_C32(0xd3d002e0), SPH_C32(0xd86130b8), SPH_C32(0x98a7b0da),
SPH_C32(0x289506b4), SPH_C32(0xd75a4897), SPH_C32(0xf0c50000),
SPH_C32(0x59230000), SPH_C32(0x45820000), SPH_C32(0xe18d00c0),
SPH_C32(0x3b6d0631), SPH_C32(0xc2ed5699), SPH_C32(0xcbe0fe1c),
SPH_C32(0x56a7b19f) },
{ SPH_C32(0xf0c50000), SPH_C32(0x59230000), SPH_C32(0x45820000),
SPH_C32(0xe18d00c0), SPH_C32(0x3b6d0631), SPH_C32(0xc2ed5699),
SPH_C32(0xcbe0fe1c), SPH_C32(0x56a7b19f), SPH_C32(0x16ed0000),
SPH_C32(0x15680000), SPH_C32(0xedd70000), SPH_C32(0x325d0220),
SPH_C32(0xe30c3689), SPH_C32(0x5a4ae643), SPH_C32(0xe375f8a8),
SPH_C32(0x81fdf908) },
{ SPH_C32(0xb4310000), SPH_C32(0x77330000), SPH_C32(0xb15d0000),
SPH_C32(0x7fd004e0), SPH_C32(0x78a26138), SPH_C32(0xd116c35d),
SPH_C32(0xd256d489), SPH_C32(0x4e6f74de), SPH_C32(0xe3060000),
SPH_C32(0xbdc10000), SPH_C32(0x87130000), SPH_C32(0xbff20060),
SPH_C32(0x2eba0a1a), SPH_C32(0x8db53751), SPH_C32(0x73c5ab06),
SPH_C32(0x5bd61539) },
{ SPH_C32(0xe3060000), SPH_C32(0xbdc10000), SPH_C32(0x87130000),
SPH_C32(0xbff20060), SPH_C32(0x2eba0a1a), SPH_C32(0x8db53751),
SPH_C32(0x73c5ab06), SPH_C32(0x5bd61539), SPH_C32(0x57370000),
SPH_C32(0xcaf20000), SPH_C32(0x364e0000), SPH_C32(0xc0220480),
SPH_C32(0x56186b22), SPH_C32(0x5ca3f40c), SPH_C32(0xa1937f8f),
SPH_C32(0x15b961e7) },
{ SPH_C32(0x02f20000), SPH_C32(0xa2810000), SPH_C32(0x873f0000),
SPH_C32(0xe36c7800), SPH_C32(0x1e1d74ef), SPH_C32(0x073d2bd6),
SPH_C32(0xc4c23237), SPH_C32(0x7f32259e), SPH_C32(0xbadd0000),
SPH_C32(0x13ad0000), SPH_C32(0xb7e70000), SPH_C32(0xf7282800),
SPH_C32(0xdf45144d), SPH_C32(0x361ac33a), SPH_C32(0xea5a8d14),
SPH_C32(0x2a2c18f0) },
{ SPH_C32(0xbadd0000), SPH_C32(0x13ad0000), SPH_C32(0xb7e70000),
SPH_C32(0xf7282800), SPH_C32(0xdf45144d), SPH_C32(0x361ac33a),
SPH_C32(0xea5a8d14), SPH_C32(0x2a2c18f0), SPH_C32(0xb82f0000),
SPH_C32(0xb12c0000), SPH_C32(0x30d80000), SPH_C32(0x14445000),
SPH_C32(0xc15860a2), SPH_C32(0x3127e8ec), SPH_C32(0x2e98bf23),
SPH_C32(0x551e3d6e) },
{ SPH_C32(0x1e6c0000), SPH_C32(0xc4420000), SPH_C32(0x8a2e0000),
SPH_C32(0xbcb6b800), SPH_C32(0x2c4413b6), SPH_C32(0x8bfdd3da),
SPH_C32(0x6a0c1bc8), SPH_C32(0xb99dc2eb), SPH_C32(0x92560000),
SPH_C32(0x1eda0000), SPH_C32(0xea510000), SPH_C32(0xe8b13000),
SPH_C32(0xa93556a5), SPH_C32(0xebfb6199), SPH_C32(0xb15c2254),
SPH_C32(0x33c5244f) },
{ SPH_C32(0x92560000), SPH_C32(0x1eda0000), SPH_C32(0xea510000),
SPH_C32(0xe8b13000), SPH_C32(0xa93556a5), SPH_C32(0xebfb6199),
SPH_C32(0xb15c2254), SPH_C32(0x33c5244f), SPH_C32(0x8c3a0000),
SPH_C32(0xda980000), SPH_C32(0x607f0000), SPH_C32(0x54078800),
SPH_C32(0x85714513), SPH_C32(0x6006b243), SPH_C32(0xdb50399c),
SPH_C32(0x8a58e6a4) },
{ SPH_C32(0x033d0000), SPH_C32(0x08b30000), SPH_C32(0xf33a0000),
SPH_C32(0x3ac20007), SPH_C32(0x51298a50), SPH_C32(0x6b6e661f),
SPH_C32(0x0ea5cfe3), SPH_C32(0xe6da7ffe), SPH_C32(0xa8da0000),
SPH_C32(0x96be0000), SPH_C32(0x5c1d0000), SPH_C32(0x07da0002),
SPH_C32(0x7d669583), SPH_C32(0x1f98708a), SPH_C32(0xbb668808),
SPH_C32(0xda878000) },
{ SPH_C32(0xa8da0000), SPH_C32(0x96be0000), SPH_C32(0x5c1d0000),
SPH_C32(0x07da0002), SPH_C32(0x7d669583), SPH_C32(0x1f98708a),
SPH_C32(0xbb668808), SPH_C32(0xda878000), SPH_C32(0xabe70000),
SPH_C32(0x9e0d0000), SPH_C32(0xaf270000), SPH_C32(0x3d180005),
SPH_C32(0x2c4f1fd3), SPH_C32(0x74f61695), SPH_C32(0xb5c347eb),
SPH_C32(0x3c5dfffe) },
{ SPH_C32(0x01930000), SPH_C32(0xe7820000), SPH_C32(0xedfb0000),
SPH_C32(0xcf0c000b), SPH_C32(0x8dd08d58), SPH_C32(0xbca3b42e),
SPH_C32(0x063661e1), SPH_C32(0x536f9e7b), SPH_C32(0x92280000),
SPH_C32(0xdc850000), SPH_C32(0x57fa0000), SPH_C32(0x56dc0003),
SPH_C32(0xbae92316), SPH_C32(0x5aefa30c), SPH_C32(0x90cef752),
SPH_C32(0x7b1675d7) },
{ SPH_C32(0x92280000), SPH_C32(0xdc850000), SPH_C32(0x57fa0000),
SPH_C32(0x56dc0003), SPH_C32(0xbae92316), SPH_C32(0x5aefa30c),
SPH_C32(0x90cef752), SPH_C32(0x7b1675d7), SPH_C32(0x93bb0000),
SPH_C32(0x3b070000), SPH_C32(0xba010000), SPH_C32(0x99d00008),
SPH_C32(0x3739ae4e), SPH_C32(0xe64c1722), SPH_C32(0x96f896b3),
SPH_C32(0x2879ebac) },
{ SPH_C32(0x5fa80000), SPH_C32(0x56030000), SPH_C32(0x43ae0000),
SPH_C32(0x64f30013), SPH_C32(0x257e86bf), SPH_C32(0x1311944e),
SPH_C32(0x541e95bf), SPH_C32(0x8ea4db69), SPH_C32(0x00440000),
SPH_C32(0x7f480000), SPH_C32(0xda7c0000), SPH_C32(0x2a230001),
SPH_C32(0x3badc9cc), SPH_C32(0xa9b69c87), SPH_C32(0x030a9e60),
SPH_C32(0xbe0a679e) },
{ SPH_C32(0x00440000), SPH_C32(0x7f480000), SPH_C32(0xda7c0000),
SPH_C32(0x2a230001), SPH_C32(0x3badc9cc), SPH_C32(0xa9b69c87),
SPH_C32(0x030a9e60), SPH_C32(0xbe0a679e), SPH_C32(0x5fec0000),
SPH_C32(0x294b0000), SPH_C32(0x99d20000), SPH_C32(0x4ed00012),
SPH_C32(0x1ed34f73), SPH_C32(0xbaa708c9), SPH_C32(0x57140bdf),
SPH_C32(0x30aebcf7) },
{ SPH_C32(0xee930000), SPH_C32(0xd6070000), SPH_C32(0x92c10000),
SPH_C32(0x2b9801e0), SPH_C32(0x9451287c), SPH_C32(0x3b6cfb57),
SPH_C32(0x45312374), SPH_C32(0x201f6a64), SPH_C32(0x7b280000),
SPH_C32(0x57420000), SPH_C32(0xa9e50000), SPH_C32(0x634300a0),
SPH_C32(0x9edb442f), SPH_C32(0x6d9995bb), SPH_C32(0x27f83b03),
SPH_C32(0xc7ff60f0) },
{ SPH_C32(0x7b280000), SPH_C32(0x57420000), SPH_C32(0xa9e50000),
SPH_C32(0x634300a0), SPH_C32(0x9edb442f), SPH_C32(0x6d9995bb),
SPH_C32(0x27f83b03), SPH_C32(0xc7ff60f0), SPH_C32(0x95bb0000),
SPH_C32(0x81450000), SPH_C32(0x3b240000), SPH_C32(0x48db0140),
SPH_C32(0x0a8a6c53), SPH_C32(0x56f56eec), SPH_C32(0x62c91877),
SPH_C32(0xe7e00a94) }
};
#define U_BIG( n ) \
do { \
__m128i db = buf[n]; \
for ( int u = 0; u < 32; u++ ) \
{ \
__m128i dm = mm_negate_32( _mm_and_si128( db, mm_one_32 ) ); \
m0 = _mm_xor_si128( m0, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m1 = _mm_xor_si128( m1, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m2 = _mm_xor_si128( m2, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m3 = _mm_xor_si128( m3, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m4 = _mm_xor_si128( m4, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m5 = _mm_xor_si128( m5, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m6 = _mm_xor_si128( m6, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m7 = _mm_xor_si128( m7, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m8 = _mm_xor_si128( m8, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
m9 = _mm_xor_si128( m9, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
mA = _mm_xor_si128( mA, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
mB = _mm_xor_si128( mB, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
mC = _mm_xor_si128( mC, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
mD = _mm_xor_si128( mD, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
mE = _mm_xor_si128( mE, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
mF = _mm_xor_si128( mF, _mm_and_si128( dm, _mm_set1_epi32( *tp++ ) ) ); \
db = _mm_srli_epi32( db, 1 ); \
} \
} while (0);
#define INPUT_BIG \
do { \
const sph_u32 *tp = &T512[0][0]; \
m0 = mm_zero; \
m1 = mm_zero; \
m2 = mm_zero; \
m3 = mm_zero; \
m4 = mm_zero; \
m5 = mm_zero; \
m6 = mm_zero; \
m7 = mm_zero; \
m8 = mm_zero; \
m9 = mm_zero; \
mA = mm_zero; \
mB = mm_zero; \
mC = mm_zero; \
mD = mm_zero; \
mE = mm_zero; \
mF = mm_zero; \
U_BIG( 0 ); \
U_BIG( 1 ); \
} while (0)
#ifdef __cplusplus
}
#endif

940
algo/hamsi/sph_hamsi.c.test Normal file
View File

@@ -0,0 +1,940 @@
/* $Id: hamsi.c 251 2010-10-19 14:31:51Z tp $ */
/*
* Hamsi implementation.
*
* ==========================(LICENSE BEGIN)============================
*
* Copyright (c) 2007-2010 Projet RNRT SAPHIR
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
* ===========================(LICENSE END)=============================
*
* @author Thomas Pornin <thomas.pornin@cryptolog.com>
*/
#include <stddef.h>
#include <string.h>
#include "sph_hamsi.h"
#ifdef __cplusplus
extern "C"{
#endif
#if SPH_SMALL_FOOTPRINT && !defined SPH_SMALL_FOOTPRINT_HAMSI
#define SPH_SMALL_FOOTPRINT_HAMSI 1
#endif
/*
* The SPH_HAMSI_EXPAND_* define how many input bits we handle in one
* table lookup during message expansion (1 to 8, inclusive). If we note
* w the number of bits per message word (w=32 for Hamsi-224/256, w=64
* for Hamsi-384/512), r the size of a "row" in 32-bit words (r=8 for
* Hamsi-224/256, r=16 for Hamsi-384/512), and n the expansion level,
* then we will get t tables (where t=ceil(w/n)) of individual size
* 2^n*r*4 (in bytes). The last table may be shorter (e.g. with w=32 and
* n=5, there are 7 tables, but the last one uses only two bits on
* input, not five).
*
* Also, we read t rows of r words from RAM. Words in a given row are
* concatenated in RAM in that order, so most of the cost is about
* reading the first row word; comparatively, cache misses are thus
* less expensive with Hamsi-512 (r=16) than with Hamsi-256 (r=8).
*
* When n=1, tables are "special" in that we omit the first entry of
* each table (which always contains 0), so that total table size is
* halved.
*
* We thus have the following (size1 is the cumulative table size of
* Hamsi-224/256; size2 is for Hamsi-384/512; similarly, t1 and t2
* are for Hamsi-224/256 and Hamsi-384/512, respectively).
*
* n size1 size2 t1 t2
* ---------------------------------------
* 1 1024 4096 32 64
* 2 2048 8192 16 32
* 3 2688 10880 11 22
* 4 4096 16384 8 16
* 5 6272 25600 7 13
* 6 10368 41984 6 11
* 7 16896 73856 5 10
* 8 32768 131072 4 8
*
* So there is a trade-off: a lower n makes the tables fit better in
* L1 cache, but increases the number of memory accesses. The optimal
* value depends on the amount of available L1 cache and the relative
* impact of a cache miss.
*
* Experimentally, in ideal benchmark conditions (which are not necessarily
* realistic with regards to L1 cache contention), it seems that n=8 is
* the best value on "big" architectures (those with 32 kB or more of L1
* cache), while n=4 is better on "small" architectures. This was tested
* on an Intel Core2 Q6600 (both 32-bit and 64-bit mode), a PowerPC G3
* (32 kB L1 cache, hence "big"), and a MIPS-compatible Broadcom BCM3302
* (8 kB L1 cache).
*
* Note: with n=1, the 32 tables (actually implemented as one big table)
* are read entirely and sequentially, regardless of the input data,
* thus avoiding any data-dependent table access pattern.
*/
#if !defined SPH_HAMSI_EXPAND_SMALL
#if SPH_SMALL_FOOTPRINT_HAMSI
#define SPH_HAMSI_EXPAND_SMALL 4
#else
#define SPH_HAMSI_EXPAND_SMALL 8
#endif
#endif
#if !defined SPH_HAMSI_EXPAND_BIG
#define SPH_HAMSI_EXPAND_BIG 8
#endif
#ifdef _MSC_VER
#pragma warning (disable: 4146)
#endif
#include "sph_hamsi_helper.c"
static const sph_u32 IV224[] = {
SPH_C32(0xc3967a67), SPH_C32(0xc3bc6c20), SPH_C32(0x4bc3bcc3),
SPH_C32(0xa7c3bc6b), SPH_C32(0x2c204b61), SPH_C32(0x74686f6c),
SPH_C32(0x69656b65), SPH_C32(0x20556e69)
};
/*
* This version is the one used in the Hamsi submission package for
* round 2 of the SHA-3 competition; the UTF-8 encoding is wrong and
* shall soon be corrected in the official Hamsi specification.
*
static const sph_u32 IV224[] = {
SPH_C32(0x3c967a67), SPH_C32(0x3cbc6c20), SPH_C32(0xb4c343c3),
SPH_C32(0xa73cbc6b), SPH_C32(0x2c204b61), SPH_C32(0x74686f6c),
SPH_C32(0x69656b65), SPH_C32(0x20556e69)
};
*/
static const sph_u32 IV256[] = {
SPH_C32(0x76657273), SPH_C32(0x69746569), SPH_C32(0x74204c65),
SPH_C32(0x7576656e), SPH_C32(0x2c204465), SPH_C32(0x70617274),
SPH_C32(0x656d656e), SPH_C32(0x7420456c)
};
static const sph_u32 IV384[] = {
SPH_C32(0x656b7472), SPH_C32(0x6f746563), SPH_C32(0x686e6965),
SPH_C32(0x6b2c2043), SPH_C32(0x6f6d7075), SPH_C32(0x74657220),
SPH_C32(0x53656375), SPH_C32(0x72697479), SPH_C32(0x20616e64),
SPH_C32(0x20496e64), SPH_C32(0x75737472), SPH_C32(0x69616c20),
SPH_C32(0x43727970), SPH_C32(0x746f6772), SPH_C32(0x61706879),
SPH_C32(0x2c204b61)
};
static const sph_u32 IV512[] = {
SPH_C32(0x73746565), SPH_C32(0x6c706172), SPH_C32(0x6b204172),
SPH_C32(0x656e6265), SPH_C32(0x72672031), SPH_C32(0x302c2062),
SPH_C32(0x75732032), SPH_C32(0x3434362c), SPH_C32(0x20422d33),
SPH_C32(0x30303120), SPH_C32(0x4c657576), SPH_C32(0x656e2d48),
SPH_C32(0x65766572), SPH_C32(0x6c65652c), SPH_C32(0x2042656c),
SPH_C32(0x6769756d)
};
static const sph_u32 alpha_n[] = {
SPH_C32(0xff00f0f0), SPH_C32(0xccccaaaa), SPH_C32(0xf0f0cccc),
SPH_C32(0xff00aaaa), SPH_C32(0xccccaaaa), SPH_C32(0xf0f0ff00),
SPH_C32(0xaaaacccc), SPH_C32(0xf0f0ff00), SPH_C32(0xf0f0cccc),
SPH_C32(0xaaaaff00), SPH_C32(0xccccff00), SPH_C32(0xaaaaf0f0),
SPH_C32(0xaaaaf0f0), SPH_C32(0xff00cccc), SPH_C32(0xccccf0f0),
SPH_C32(0xff00aaaa), SPH_C32(0xccccaaaa), SPH_C32(0xff00f0f0),
SPH_C32(0xff00aaaa), SPH_C32(0xf0f0cccc), SPH_C32(0xf0f0ff00),
SPH_C32(0xccccaaaa), SPH_C32(0xf0f0ff00), SPH_C32(0xaaaacccc),
SPH_C32(0xaaaaff00), SPH_C32(0xf0f0cccc), SPH_C32(0xaaaaf0f0),
SPH_C32(0xccccff00), SPH_C32(0xff00cccc), SPH_C32(0xaaaaf0f0),
SPH_C32(0xff00aaaa), SPH_C32(0xccccf0f0)
};
static const sph_u32 alpha_f[] = {
SPH_C32(0xcaf9639c), SPH_C32(0x0ff0f9c0), SPH_C32(0x639c0ff0),
SPH_C32(0xcaf9f9c0), SPH_C32(0x0ff0f9c0), SPH_C32(0x639ccaf9),
SPH_C32(0xf9c00ff0), SPH_C32(0x639ccaf9), SPH_C32(0x639c0ff0),
SPH_C32(0xf9c0caf9), SPH_C32(0x0ff0caf9), SPH_C32(0xf9c0639c),
SPH_C32(0xf9c0639c), SPH_C32(0xcaf90ff0), SPH_C32(0x0ff0639c),
SPH_C32(0xcaf9f9c0), SPH_C32(0x0ff0f9c0), SPH_C32(0xcaf9639c),
SPH_C32(0xcaf9f9c0), SPH_C32(0x639c0ff0), SPH_C32(0x639ccaf9),
SPH_C32(0x0ff0f9c0), SPH_C32(0x639ccaf9), SPH_C32(0xf9c00ff0),
SPH_C32(0xf9c0caf9), SPH_C32(0x639c0ff0), SPH_C32(0xf9c0639c),
SPH_C32(0x0ff0caf9), SPH_C32(0xcaf90ff0), SPH_C32(0xf9c0639c),
SPH_C32(0xcaf9f9c0), SPH_C32(0x0ff0639c)
};
#define DECL_STATE_SMALL \
sph_u32 c0, c1, c2, c3, c4, c5, c6, c7;
#define READ_STATE_SMALL(sc) do { \
c0 = sc->h[0x0]; \
c1 = sc->h[0x1]; \
c2 = sc->h[0x2]; \
c3 = sc->h[0x3]; \
c4 = sc->h[0x4]; \
c5 = sc->h[0x5]; \
c6 = sc->h[0x6]; \
c7 = sc->h[0x7]; \
} while (0)
#define WRITE_STATE_SMALL(sc) do { \
sc->h[0x0] = c0; \
sc->h[0x1] = c1; \
sc->h[0x2] = c2; \
sc->h[0x3] = c3; \
sc->h[0x4] = c4; \
sc->h[0x5] = c5; \
sc->h[0x6] = c6; \
sc->h[0x7] = c7; \
} while (0)
#define s0 m0
#define s1 m1
#define s2 c0
#define s3 c1
#define s4 c2
#define s5 c3
#define s6 m2
#define s7 m3
#define s8 m4
#define s9 m5
#define sA c4
#define sB c5
#define sC c6
#define sD c7
#define sE m6
#define sF m7
#define SBOX(a, b, c, d) do { \
sph_u32 t; \
t = (a); \
(a) &= (c); \
(a) ^= (d); \
(c) ^= (b); \
(c) ^= (a); \
(d) |= t; \
(d) ^= (b); \
t ^= (c); \
(b) = (d); \
(d) |= t; \
(d) ^= (a); \
(a) &= (b); \
t ^= (a); \
(b) ^= (d); \
(b) ^= t; \
(a) = (c); \
(c) = (b); \
(b) = (d); \
(d) = SPH_T32(~t); \
} while (0)
#define L(a, b, c, d) do { \
(a) = SPH_ROTL32(a, 13); \
(c) = SPH_ROTL32(c, 3); \
(b) ^= (a) ^ (c); \
(d) ^= (c) ^ SPH_T32((a) << 3); \
(b) = SPH_ROTL32(b, 1); \
(d) = SPH_ROTL32(d, 7); \
(a) ^= (b) ^ (d); \
(c) ^= (d) ^ SPH_T32((b) << 7); \
(a) = SPH_ROTL32(a, 5); \
(c) = SPH_ROTL32(c, 22); \
} while (0)
#define ROUND_SMALL(rc, alpha) do { \
s0 ^= alpha[0x00]; \
s1 ^= alpha[0x01] ^ (sph_u32)(rc); \
s2 ^= alpha[0x02]; \
s3 ^= alpha[0x03]; \
s4 ^= alpha[0x08]; \
s5 ^= alpha[0x09]; \
s6 ^= alpha[0x0A]; \
s7 ^= alpha[0x0B]; \
s8 ^= alpha[0x10]; \
s9 ^= alpha[0x11]; \
sA ^= alpha[0x12]; \
sB ^= alpha[0x13]; \
sC ^= alpha[0x18]; \
sD ^= alpha[0x19]; \
sE ^= alpha[0x1A]; \
sF ^= alpha[0x1B]; \
SBOX(s0, s4, s8, sC); \
SBOX(s1, s5, s9, sD); \
SBOX(s2, s6, sA, sE); \
SBOX(s3, s7, sB, sF); \
L(s0, s5, sA, sF); \
L(s1, s6, sB, sC); \
L(s2, s7, s8, sD); \
L(s3, s4, s9, sE); \
} while (0)
#define P_SMALL do { \
ROUND_SMALL(0, alpha_n); \
ROUND_SMALL(1, alpha_n); \
ROUND_SMALL(2, alpha_n); \
} while (0)
#define PF_SMALL do { \
ROUND_SMALL(0, alpha_f); \
ROUND_SMALL(1, alpha_f); \
ROUND_SMALL(2, alpha_f); \
ROUND_SMALL(3, alpha_f); \
ROUND_SMALL(4, alpha_f); \
ROUND_SMALL(5, alpha_f); \
} while (0)
#define T_SMALL do { \
/* order is important */ \
c7 = (sc->h[7] ^= sB); \
c6 = (sc->h[6] ^= sA); \
c5 = (sc->h[5] ^= s9); \
c4 = (sc->h[4] ^= s8); \
c3 = (sc->h[3] ^= s3); \
c2 = (sc->h[2] ^= s2); \
c1 = (sc->h[1] ^= s1); \
c0 = (sc->h[0] ^= s0); \
} while (0)
static void
hamsi_small(sph_hamsi_small_context *sc, const unsigned char *buf, size_t num)
{
DECL_STATE_SMALL
#if !SPH_64
sph_u32 tmp;
#endif
#if SPH_64
sc->count += (sph_u64)num << 5;
#else
tmp = SPH_T32((sph_u32)num << 5);
sc->count_low = SPH_T32(sc->count_low + tmp);
sc->count_high += (sph_u32)((num >> 13) >> 14);
if (sc->count_low < tmp)
sc->count_high ++;
#endif
READ_STATE_SMALL(sc);
while (num -- > 0) {
sph_u32 m0, m1, m2, m3, m4, m5, m6, m7;
INPUT_SMALL;
P_SMALL;
T_SMALL;
buf += 4;
}
WRITE_STATE_SMALL(sc);
}
static void
hamsi_small_final(sph_hamsi_small_context *sc, const unsigned char *buf)
{
sph_u32 m0, m1, m2, m3, m4, m5, m6, m7;
DECL_STATE_SMALL
READ_STATE_SMALL(sc);
INPUT_SMALL;
PF_SMALL;
T_SMALL;
WRITE_STATE_SMALL(sc);
}
static void
hamsi_small_init(sph_hamsi_small_context *sc, const sph_u32 *iv)
{
sc->partial_len = 0;
memcpy(sc->h, iv, sizeof sc->h);
#if SPH_64
sc->count = 0;
#else
sc->count_high = sc->count_low = 0;
#endif
}
static void
hamsi_small_core(sph_hamsi_small_context *sc, const void *data, size_t len)
{
if (sc->partial_len != 0) {
size_t mlen;
mlen = 4 - sc->partial_len;
if (len < mlen) {
memcpy(sc->partial + sc->partial_len, data, len);
sc->partial_len += len;
return;
} else {
memcpy(sc->partial + sc->partial_len, data, mlen);
len -= mlen;
data = (const unsigned char *)data + mlen;
hamsi_small(sc, sc->partial, 1);
sc->partial_len = 0;
}
}
hamsi_small(sc, data, (len >> 2));
data = (const unsigned char *)data + (len & ~(size_t)3);
len &= (size_t)3;
memcpy(sc->partial, data, len);
sc->partial_len = len;
}
static void
hamsi_small_close(sph_hamsi_small_context *sc,
unsigned ub, unsigned n, void *dst, size_t out_size_w32)
{
unsigned char pad[12];
size_t ptr, u;
unsigned z;
unsigned char *out;
ptr = sc->partial_len;
memcpy(pad, sc->partial, ptr);
#if SPH_64
sph_enc64be(pad + 4, sc->count + (ptr << 3) + n);
#else
sph_enc32be(pad + 4, sc->count_high);
sph_enc32be(pad + 8, sc->count_low + (ptr << 3) + n);
#endif
z = 0x80 >> n;
pad[ptr ++] = ((ub & -z) | z) & 0xFF;
while (ptr < 4)
pad[ptr ++] = 0;
hamsi_small(sc, pad, 2);
hamsi_small_final(sc, pad + 8);
out = dst;
for (u = 0; u < out_size_w32; u ++)
sph_enc32be(out + (u << 2), sc->h[u]);
}
#define DECL_STATE_BIG \
sph_u32 c0, c1, c2, c3, c4, c5, c6, c7; \
sph_u32 c8, c9, cA, cB, cC, cD, cE, cF;
#define READ_STATE_BIG(sc) do { \
c0 = sc->h[0x0]; \
c1 = sc->h[0x1]; \
c2 = sc->h[0x2]; \
c3 = sc->h[0x3]; \
c4 = sc->h[0x4]; \
c5 = sc->h[0x5]; \
c6 = sc->h[0x6]; \
c7 = sc->h[0x7]; \
c8 = sc->h[0x8]; \
c9 = sc->h[0x9]; \
cA = sc->h[0xA]; \
cB = sc->h[0xB]; \
cC = sc->h[0xC]; \
cD = sc->h[0xD]; \
cE = sc->h[0xE]; \
cF = sc->h[0xF]; \
} while (0)
#define WRITE_STATE_BIG(sc) do { \
sc->h[0x0] = c0; \
sc->h[0x1] = c1; \
sc->h[0x2] = c2; \
sc->h[0x3] = c3; \
sc->h[0x4] = c4; \
sc->h[0x5] = c5; \
sc->h[0x6] = c6; \
sc->h[0x7] = c7; \
sc->h[0x8] = c8; \
sc->h[0x9] = c9; \
sc->h[0xA] = cA; \
sc->h[0xB] = cB; \
sc->h[0xC] = cC; \
sc->h[0xD] = cD; \
sc->h[0xE] = cE; \
sc->h[0xF] = cF; \
} while (0)
#define s00 m0
#define s01 m1
#define s02 c0
#define s03 c1
#define s04 m2
#define s05 m3
#define s06 c2
#define s07 c3
#define s08 c4
#define s09 c5
#define s0A m4
#define s0B m5
#define s0C c6
#define s0D c7
#define s0E m6
#define s0F m7
#define s10 m8
#define s11 m9
#define s12 c8
#define s13 c9
#define s14 mA
#define s15 mB
#define s16 cA
#define s17 cB
#define s18 cC
#define s19 cD
#define s1A mC
#define s1B mD
#define s1C cE
#define s1D cF
#define s1E mE
#define s1F mF
#define ROUND_BIG(rc, alpha) do { \
s00 ^= alpha[0x00]; \
s01 ^= alpha[0x01] ^ (sph_u32)(rc); \
s02 ^= alpha[0x02]; \
s03 ^= alpha[0x03]; \
s04 ^= alpha[0x04]; \
s05 ^= alpha[0x05]; \
s06 ^= alpha[0x06]; \
s07 ^= alpha[0x07]; \
s08 ^= alpha[0x08]; \
s09 ^= alpha[0x09]; \
s0A ^= alpha[0x0A]; \
s0B ^= alpha[0x0B]; \
s0C ^= alpha[0x0C]; \
s0D ^= alpha[0x0D]; \
s0E ^= alpha[0x0E]; \
s0F ^= alpha[0x0F]; \
s10 ^= alpha[0x10]; \
s11 ^= alpha[0x11]; \
s12 ^= alpha[0x12]; \
s13 ^= alpha[0x13]; \
s14 ^= alpha[0x14]; \
s15 ^= alpha[0x15]; \
s16 ^= alpha[0x16]; \
s17 ^= alpha[0x17]; \
s18 ^= alpha[0x18]; \
s19 ^= alpha[0x19]; \
s1A ^= alpha[0x1A]; \
s1B ^= alpha[0x1B]; \
s1C ^= alpha[0x1C]; \
s1D ^= alpha[0x1D]; \
s1E ^= alpha[0x1E]; \
s1F ^= alpha[0x1F]; \
SBOX(s00, s08, s10, s18); \
SBOX(s01, s09, s11, s19); \
SBOX(s02, s0A, s12, s1A); \
SBOX(s03, s0B, s13, s1B); \
SBOX(s04, s0C, s14, s1C); \
SBOX(s05, s0D, s15, s1D); \
SBOX(s06, s0E, s16, s1E); \
SBOX(s07, s0F, s17, s1F); \
L(s00, s09, s12, s1B); \
L(s01, s0A, s13, s1C); \
L(s02, s0B, s14, s1D); \
L(s03, s0C, s15, s1E); \
L(s04, s0D, s16, s1F); \
L(s05, s0E, s17, s18); \
L(s06, s0F, s10, s19); \
L(s07, s08, s11, s1A); \
/*if (rc == 0 ) { \
printf("S L5 post s10 %08lx s11 %08lx s12 %08lx s13 %08lx\n",s10,s11,s12,s13); \
}*/ \
L(s00, s02, s05, s07); \
L(s10, s13, s15, s16); \
/*if (rc == 0 ) { \
printf("S L5 post s10 %08lx s11 %08lx s12 %08lx s13 %08lx\n",s10,s11,s12,s13); \
}*/ \
L(s09, s0B, s0C, s0E); \
L(s19, s1A, s1C, s1F); \
} while (0)
#if SPH_SMALL_FOOTPRINT_HAMSI
#define P_BIG do { \
unsigned r; \
for (r = 0; r < 6; r ++) \
ROUND_BIG(r, alpha_n); \
} while (0)
#define PF_BIG do { \
unsigned r; \
for (r = 0; r < 12; r ++) \
ROUND_BIG(r, alpha_f); \
} while (0)
#else
#define P_BIG do { \
ROUND_BIG(0, alpha_n); \
/*printf("S R0 s00 %08lx s01 %08lx s02 %08lx s03 %08lx\n",s00,s01,s02,s03); \
printf("S R0 s04 %08lx s05 %08lx s06 %08lx s07 %08lx\n",s04,s05,s06,s07); \
printf("S R0 s08 %08lx s09 %08lx s0A %08lx s0B %08lx\n",s08,s09,s0A,s0B); \
printf("S R0 s0C %08lx s0D %08lx s0E %08lx s0F %08lx\n",s0C,s0D,s0E,s0F); \
printf("S R0 s10 %08lx s11 %08lx s12 %08lx s13 %08lx\n",s10,s11,s12,s13); \
printf("S R0 s14 %08lx s15 %08lx s16 %08lx s17 %08lx\n",s14,s15,s16,s17); \
printf("S R0 s18 %08lx s19 %08lx s1A %08lx s1B %08lx\n",s18,s19,s1A,s1B); \
printf("S R0 s1C %08lx s1D %08lx s1E %08lx s1F %08lx\n",s1C,s1D,s1E,s1F); \
*/\
ROUND_BIG(1, alpha_n); \
ROUND_BIG(2, alpha_n); \
ROUND_BIG(3, alpha_n); \
ROUND_BIG(4, alpha_n); \
ROUND_BIG(5, alpha_n); \
} while (0)
#define PF_BIG do { \
ROUND_BIG(0, alpha_f); \
ROUND_BIG(1, alpha_f); \
ROUND_BIG(2, alpha_f); \
ROUND_BIG(3, alpha_f); \
ROUND_BIG(4, alpha_f); \
ROUND_BIG(5, alpha_f); \
ROUND_BIG(6, alpha_f); \
ROUND_BIG(7, alpha_f); \
ROUND_BIG(8, alpha_f); \
ROUND_BIG(9, alpha_f); \
ROUND_BIG(10, alpha_f); \
ROUND_BIG(11, alpha_f); \
} while (0)
#endif
#define T_BIG do { \
/* order is important */ \
cF = (sc->h[0xF] ^= s17); \
cE = (sc->h[0xE] ^= s16); \
cD = (sc->h[0xD] ^= s15); \
cC = (sc->h[0xC] ^= s14); \
cB = (sc->h[0xB] ^= s13); \
cA = (sc->h[0xA] ^= s12); \
c9 = (sc->h[0x9] ^= s11); \
c8 = (sc->h[0x8] ^= s10); \
c7 = (sc->h[0x7] ^= s07); \
c6 = (sc->h[0x6] ^= s06); \
c5 = (sc->h[0x5] ^= s05); \
c4 = (sc->h[0x4] ^= s04); \
c3 = (sc->h[0x3] ^= s03); \
c2 = (sc->h[0x2] ^= s02); \
c1 = (sc->h[0x1] ^= s01); \
c0 = (sc->h[0x0] ^= s00); \
} while (0)
static void
hamsi_big(sph_hamsi_big_context *sc, const unsigned char *buf, size_t num)
{
DECL_STATE_BIG
#if !SPH_64
sph_u32 tmp;
#endif
#if SPH_64
sc->count += (sph_u64)num << 6;
#else
tmp = SPH_T32((sph_u32)num << 6);
sc->count_low = SPH_T32(sc->count_low + tmp);
sc->count_high += (sph_u32)((num >> 13) >> 13);
if (sc->count_low < tmp)
sc->count_high ++;
#endif
READ_STATE_BIG(sc);
/*
uint32_t* b = (uint32_t*)buf;
//printf("S s64: %016llx\n",*ss);
//printf("S buf: %08lx %08lx\n",b[0], b[1]);
int n1 = 1;
int n2 = 1;
*/
while (num -- > 0) {
sph_u32 m0, m1, m2, m3, m4, m5, m6, m7;
sph_u32 m8, m9, mA, mB, mC, mD, mE, mF;
INPUT_BIG;
/*if ( n1 )
{
n1 = 0;
printf("S INPUT m: %08lx %08lx %08lx %08lx\n",m0,m1,m2,m3 );
printf("S INPUT m: %08lx %08lx %08lx %08lx\n",m4,m5,m6,m7);
printf("S INPUT m: %08lx %08lx %08lx %08lx\n",m8,m9,mA,mB );
printf("S INPUT m: %08lx %08lx %08lx %08lx\n",mC,mD,mE,mF);
}
*/
P_BIG;
/*if ( n2 )
{
n2 = 0;
printf("S P_BIG s: %08lx %08lx %08lx %08lx\n",s00,s01,s02,s03 );
printf("S P_BIG s: %08lx %08lx %08lx %08lx\n",s04,s05,s07,s07);
printf("S P_BIG s: %08lx %08lx %08lx %08lx\n",s08,s09,s0A,s0B );
printf("S P_BIG s: %08lx %08lx %08lx %08lx\n",s0C,s0D,s0E,s0F);
}
*/
T_BIG;
buf += 8;
}
WRITE_STATE_BIG(sc);
}
static void
hamsi_big_final(sph_hamsi_big_context *sc, const unsigned char *buf)
{
sph_u32 m0, m1, m2, m3, m4, m5, m6, m7;
sph_u32 m8, m9, mA, mB, mC, mD, mE, mF;
DECL_STATE_BIG
READ_STATE_BIG(sc);
INPUT_BIG;
PF_BIG;
T_BIG;
WRITE_STATE_BIG(sc);
}
static void
hamsi_big_init(sph_hamsi_big_context *sc, const sph_u32 *iv)
{
sc->partial_len = 0;
memcpy(sc->h, iv, sizeof sc->h);
#if SPH_64
sc->count = 0;
#else
sc->count_high = sc->count_low = 0;
#endif
}
static void
hamsi_big_core(sph_hamsi_big_context *sc, const void *data, size_t len)
{
uint64_t* d = (uint64_t*)data;
uint64_t* h = (uint64_t*)sc->h;
/*
printf("S core1 len = %d\n",len);
printf("S data: %016llx %016llx %016llx %016llx\n",d[0],d[1],d[2],d[3]);
printf("S data: %016llx %016llx %016llx %016llx\n",d[4],d[5],d[6],d[7]);
printf("S H: %016llx %016llx %016llx %016llx\n",h[0],h[1],h[2],h[3]);
*/
if (sc->partial_len != 0) {
//printf("WARNING partial_len != 0\n");
size_t mlen;
mlen = 8 - sc->partial_len;
if (len < mlen) {
memcpy(sc->partial + sc->partial_len, data, len);
sc->partial_len += len;
return;
} else {
memcpy(sc->partial + sc->partial_len, data, mlen);
len -= mlen;
data = (const unsigned char *)data + mlen;
hamsi_big(sc, sc->partial, 1);
sc->partial_len = 0;
}
}
hamsi_big(sc, data, (len >> 3));
/*
printf("S core2\n");
printf("S H: %016llx %016llx %016llx %016llx\n",h[0],h[1],h[2],h[3]);
*/
data = (const unsigned char *)data + (len & ~(size_t)7);
len &= (size_t)7;
memcpy(sc->partial, data, len);
sc->partial_len = len;
}
static void
hamsi_big_close(sph_hamsi_big_context *sc,
unsigned ub, unsigned n, void *dst, size_t out_size_w32)
{
unsigned char pad[8];
size_t ptr, u;
unsigned z;
unsigned char *out;
//uint64_t* h = (uint64_t*)sc->h;
ptr = sc->partial_len;
#if SPH_64
sph_enc64be(pad, sc->count + (ptr << 3) + n);
#else
sph_enc32be(pad, sc->count_high);
sph_enc32be(pad + 4, sc->count_low + (ptr << 3) + n);
#endif
z = 0x80 >> n;
sc->partial[ptr ++] = ((ub & -z) | z) & 0xFF;
while (ptr < 8)
sc->partial[ptr ++] = 0;
//printf("S close1\n");
//printf("S H: %016llx %016llx %016llx %016llx\n",h[0],h[1],h[2],h[3]);
hamsi_big(sc, sc->partial, 1);
//printf("S close2\n");
//printf("S H: %016llx %016llx %016llx %016llx\n",h[0],h[1],h[2],h[3]);
hamsi_big_final(sc, pad);
//printf("S close3\n");
//printf("S H: %016llx %016llx %016llx %016llx\n",h[0],h[1],h[2],h[3]);
out = dst;
if (out_size_w32 == 12) {
sph_enc32be(out + 0, sc->h[ 0]);
sph_enc32be(out + 4, sc->h[ 1]);
sph_enc32be(out + 8, sc->h[ 3]);
sph_enc32be(out + 12, sc->h[ 4]);
sph_enc32be(out + 16, sc->h[ 5]);
sph_enc32be(out + 20, sc->h[ 6]);
sph_enc32be(out + 24, sc->h[ 8]);
sph_enc32be(out + 28, sc->h[ 9]);
sph_enc32be(out + 32, sc->h[10]);
sph_enc32be(out + 36, sc->h[12]);
sph_enc32be(out + 40, sc->h[13]);
sph_enc32be(out + 44, sc->h[15]);
} else {
for (u = 0; u < 16; u ++)
sph_enc32be(out + (u << 2), sc->h[u]);
}
}
/* see sph_hamsi.h */
void
sph_hamsi224_init(void *cc)
{
hamsi_small_init(cc, IV224);
}
/* see sph_hamsi.h */
void
sph_hamsi224(void *cc, const void *data, size_t len)
{
hamsi_small_core(cc, data, len);
}
/* see sph_hamsi.h */
void
sph_hamsi224_close(void *cc, void *dst)
{
hamsi_small_close(cc, 0, 0, dst, 7);
// hamsi_small_init(cc, IV224);
}
/* see sph_hamsi.h */
void
sph_hamsi224_addbits_and_close(void *cc, unsigned ub, unsigned n, void *dst)
{
hamsi_small_close(cc, ub, n, dst, 7);
// hamsi_small_init(cc, IV224);
}
/* see sph_hamsi.h */
void
sph_hamsi256_init(void *cc)
{
hamsi_small_init(cc, IV256);
}
/* see sph_hamsi.h */
void
sph_hamsi256(void *cc, const void *data, size_t len)
{
hamsi_small_core(cc, data, len);
}
/* see sph_hamsi.h */
void
sph_hamsi256_close(void *cc, void *dst)
{
hamsi_small_close(cc, 0, 0, dst, 8);
// hamsi_small_init(cc, IV256);
}
/* see sph_hamsi.h */
void
sph_hamsi256_addbits_and_close(void *cc, unsigned ub, unsigned n, void *dst)
{
hamsi_small_close(cc, ub, n, dst, 8);
// hamsi_small_init(cc, IV256);
}
/* see sph_hamsi.h */
void
sph_hamsi384_init(void *cc)
{
hamsi_big_init(cc, IV384);
}
/* see sph_hamsi.h */
void
sph_hamsi384(void *cc, const void *data, size_t len)
{
hamsi_big_core(cc, data, len);
}
/* see sph_hamsi.h */
void
sph_hamsi384_close(void *cc, void *dst)
{
hamsi_big_close(cc, 0, 0, dst, 12);
// hamsi_big_init(cc, IV384);
}
/* see sph_hamsi.h */
void
sph_hamsi384_addbits_and_close(void *cc, unsigned ub, unsigned n, void *dst)
{
hamsi_big_close(cc, ub, n, dst, 12);
// hamsi_big_init(cc, IV384);
}
/* see sph_hamsi.h */
void
sph_hamsi512_init(void *cc)
{
hamsi_big_init(cc, IV512);
}
/* see sph_hamsi.h */
void
sph_hamsi512(void *cc, const void *data, size_t len)
{
hamsi_big_core(cc, data, len);
}
/* see sph_hamsi.h */
void
sph_hamsi512_close(void *cc, void *dst)
{
hamsi_big_close(cc, 0, 0, dst, 16);
// hamsi_big_init(cc, IV512);
}
/* see sph_hamsi.h */
void
sph_hamsi512_addbits_and_close(void *cc, unsigned ub, unsigned n, void *dst)
{
hamsi_big_close(cc, ub, n, dst, 16);
// hamsi_big_init(cc, IV512);
}
#ifdef __cplusplus
}
#endif