[keccak-asm] rho & pi in asm

[avr-crypto-lib.git] / keccak / keccak-stub.c

/* keecak.c */
/*
    This file is part of the AVR-Crypto-Lib.
    Copyright (C) 2010 Daniel Otte (daniel.otte@rub.de)

    This program is free software: you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <avr/pgmspace.h>
#include "memxor.h"
#include "rotate64.h"
#include "keccak.h"
#include "stdio.h"

#ifdef DEBUG
#  undef DEBUG
#endif

#define DEBUG 0

#if DEBUG
#include "cli.h"

void keccak_dump_state(uint64_t a[5][5]){
        uint8_t i,j;
        for(i=0; i<5; ++i){
                cli_putstr_P(PSTR("\r\n"));
                cli_putc('0'+i);
                cli_putstr_P(PSTR(": "));
                for(j=0; j<5; ++j){
                        cli_hexdump_rev(&(a[i][j]), 8);
                        cli_putc(' ');
                }
        }
}

void keccak_dump_ctx(keccak_ctx_t* ctx){
        keccak_dump_state(ctx->a);
        cli_putstr_P(PSTR("\r\nDBG: r: "));
        cli_hexdump_rev(&(ctx->r), 2);
        cli_putstr_P(PSTR("\t c: "));
        cli_hexdump_rev(&(ctx->c), 2);
        cli_putstr_P(PSTR("\t d: "));
        cli_hexdump(&(ctx->d), 1);
        cli_putstr_P(PSTR("\t bs: "));
        cli_hexdump(&(ctx->bs), 1);
}

#endif

/*
const uint64_t rc[] PROGMEM = {
       0x0000000000000001LL, 0x0000000000008082LL,
       0x800000000000808ALL, 0x8000000080008000LL,
       0x000000000000808BLL, 0x0000000080000001LL,
       0x8000000080008081LL, 0x8000000000008009LL,
       0x000000000000008ALL, 0x0000000000000088LL,
       0x0000000080008009LL, 0x000000008000000ALL,
       0x000000008000808BLL, 0x800000000000008BLL,
       0x8000000000008089LL, 0x8000000000008003LL,
       0x8000000000008002LL, 0x8000000000000080LL,
       0x000000000000800ALL, 0x800000008000000ALL,
       0x8000000080008081LL, 0x8000000000008080LL,
       0x0000000080000001LL, 0x8000000080008008LL
};
*/

const static uint8_t rc_comp[] PROGMEM = {
                0x01, 0x92, 0xda, 0x70,
                0x9b, 0x21, 0xf1, 0x59,
                0x8a, 0x88, 0x39, 0x2a,
                0xbb, 0xcb, 0xd9, 0x53,
                0x52, 0xc0, 0x1a, 0x6a,
                0xf1, 0xd0, 0x21, 0x78,
};
/*
const uint8_t keccak_rotate_codes[5][5] PROGMEM = {
                { ROT_CODE( 0), ROT_CODE(36), ROT_CODE( 3), ROT_CODE(41), ROT_CODE(18) },
                { ROT_CODE( 1), ROT_CODE(44), ROT_CODE(10), ROT_CODE(45), ROT_CODE( 2) },
                { ROT_CODE(62), ROT_CODE( 6), ROT_CODE(43), ROT_CODE(15), ROT_CODE(61) },
                { ROT_CODE(28), ROT_CODE(55), ROT_CODE(25), ROT_CODE(21), ROT_CODE(56) },
                { ROT_CODE(27), ROT_CODE(20), ROT_CODE(39), ROT_CODE( 8), ROT_CODE(14) }
};
*/
const uint8_t keccak_rotate_codes[5][5] PROGMEM = {
        { ROT_CODE( 0), ROT_CODE( 1), ROT_CODE(62), ROT_CODE(28), ROT_CODE(27) },
        { ROT_CODE(36), ROT_CODE(44), ROT_CODE( 6), ROT_CODE(55), ROT_CODE(20) },
        { ROT_CODE( 3), ROT_CODE(10), ROT_CODE(43), ROT_CODE(25), ROT_CODE(39) },
        { ROT_CODE(41), ROT_CODE(45), ROT_CODE(15), ROT_CODE(21), ROT_CODE( 8) },
        { ROT_CODE(18), ROT_CODE( 2), ROT_CODE(61), ROT_CODE(56), ROT_CODE(14) }
};

void keccak_theta(uint64_t *a, uint64_t *b);
extern const uint8_t rho_pi_idx_table[25] PROGMEM;

static inline
void keccak_round(uint64_t a[5][5], uint8_t rci){
        uint64_t b[5][5];
        uint8_t i; // j;
        union {
                        uint64_t v64;
                        uint8_t v8[8];
                } t;
        /* theta */
        keccak_theta((uint64_t*)a, (uint64_t*)b);
#if DEBUG
        cli_putstr_P(PSTR("\r\nAfter theta:"));
        keccak_dump_state(a);
#endif
        /* rho & pi */
/*
        const uint8_t* rot_code = (const uint8_t*)keccak_rotate_codes;
    const uint8_t* idx_idx = (const uint8_t*)rho_pi_idx_table;
    uint64_t *a_tmp = (uint64_t*)a;
        for(i = 0; i < 25; ++i){
                    *((uint64_t*)(((uint8_t*)b) + pgm_read_byte(idx_idx++))) =
                rotate64left_code(*a_tmp++, pgm_read_byte(rot_code++));

        }
*/
#if DEBUG & 0
        cli_putstr_P(PSTR("\r\n--- after rho & pi ---"));
        keccak_dump_state(a);
#endif
        /* chi */
        memcpy(a, b, 5 * 5 * 8);
        for(i = 0; i < 5; ++i){
/*
                for(j = 0; j < 5; ++j){
                        a[i][j] =  b[i][j] ^ ((~(b[i][(j + 1) % 5])) & (b[i][(j + 2) % 5]));
                }
*/
            a[i][0] ^= ((~(b[i][1])) & (b[i][2]));
        a[i][1] ^= ((~(b[i][2])) & (b[i][3]));
        a[i][2] ^= ((~(b[i][3])) & (b[i][4]));
        a[i][3] ^= ((~(b[i][4])) & (b[i][0]));
        a[i][4] ^= ((~(b[i][0])) & (b[i][1]));

        }
#if DEBUG & 0
        cli_putstr_P(PSTR("\r\nAfter chi:"));
        keccak_dump_state(a);
#endif
        /* iota */

//      memcpy_P(&t, &(rc_comp[rci]), 8);
        t.v64 = 0;
        t.v8[0] = pgm_read_byte(&(rc_comp[rci]));
        if(t.v8[0] & 0x40){
                t.v8[7] = 0x80;
        }
        if(t.v8[0] & 0x20){
                t.v8[3] = 0x80;
        }
        if(t.v8[0] & 0x10){
                t.v8[1] = 0x80;
        }
        t.v8[0] &= 0x8F;

        a[0][0] ^= t.v64;
#if DEBUG & 0
        cli_putstr_P(PSTR("\r\nAfter iota:"));
        keccak_dump_state(a);
#endif
}

void keccak_f1600(uint64_t a[5][5]){
        uint8_t i = 0;
        do {
#if DEBUG
                cli_putstr_P(PSTR("\r\n\r\n--- Round "));
                cli_hexdump(&i, 1);
                cli_putstr_P(PSTR(" ---"));
#endif
                keccak_round(a, i);
        } while (++i < 24);
}

void keccak_nextBlock(keccak_ctx_t* ctx, const void* block){
        memxor(ctx->a, block, ctx->bs);
        keccak_f1600(ctx->a);
}

void keccak_lastBlock(keccak_ctx_t* ctx, const void* block, uint16_t length_b){
        while(length_b>=ctx->r){
                keccak_nextBlock(ctx, block);
                block = (uint8_t*)block + ctx->bs;
                length_b -=  ctx->r;
        }
        uint8_t tmp[ctx->bs];
        uint8_t pad[3];
        memset(tmp, 0x00, ctx->bs);
        memcpy(tmp, block, (length_b+7)/8);
        /* appand 1 */
        if(length_b & 7){
                /* we have some single bits */
                uint8_t t;
                t = tmp[length_b / 8] >> (8 - (length_b & 7));
                t |= 0x01 << (length_b & 7);
                tmp[length_b / 8] = t;
        }else{
                tmp[length_b / 8] = 0x01;
        }
        pad[0] = ctx->d;
        pad[1] = ctx->bs;
        pad[2] = 0x01;
        if(length_b / 8 + 1 + 3 <= ctx->bs){
                memcpy(tmp + length_b / 8 + 1, pad, 3);
        }else{
                if(length_b / 8 + 1 + 2 <= ctx->bs){
                        memcpy(tmp+length_b/8+1, pad, 2);
                        keccak_nextBlock(ctx, tmp);
                        memset(tmp, 0x00, ctx->bs);
                        tmp[0] = 0x01;
                }else{
                        if(length_b/8+1+1 <= ctx->bs){
                                memcpy(tmp + length_b / 8 + 1, pad, 1);
                                keccak_nextBlock(ctx, tmp);
                                memset(tmp, 0x00, ctx->bs);
                                tmp[0] = ctx->bs;
                                tmp[1] = 0x01;
                        }else{
                                keccak_nextBlock(ctx, tmp);
                                memset(tmp, 0x00, ctx->bs);
                                tmp[0] = ctx->d;
                                tmp[1] = ctx->bs;
                                tmp[2] = 0x01;
                        }
                }
        }
        keccak_nextBlock(ctx, tmp);
}

void keccak_ctx2hash(void* dest, uint16_t length_b, keccak_ctx_t* ctx){
        while(length_b>=ctx->r){
                memcpy(dest, ctx->a, ctx->bs);
                dest = (uint8_t*)dest + ctx->bs;
                length_b -= ctx->r;
                keccak_f1600(ctx->a);
        }
        memcpy(dest, ctx->a, (length_b+7)/8);
}

void keccak224_ctx2hash(void* dest, keccak_ctx_t* ctx){
        keccak_ctx2hash(dest, 224, ctx);
}

void keccak256_ctx2hash(void* dest, keccak_ctx_t* ctx){
        keccak_ctx2hash(dest, 256, ctx);
}

void keccak384_ctx2hash(void* dest, keccak_ctx_t* ctx){
        keccak_ctx2hash(dest, 384, ctx);
}

void keccak512_ctx2hash(void* dest, keccak_ctx_t* ctx){
        keccak_ctx2hash(dest, 512, ctx);
}

/*
  1. SHA3-224: ⌊Keccak[r = 1152, c =  448, d = 28]⌋224
  2. SHA3-256: ⌊Keccak[r = 1088, c =  512, d = 32]⌋256
  3. SHA3-384: ⌊Keccak[r =  832, c =  768, d = 48]⌋384
  4. SHA3-512: ⌊Keccak[r =  576, c = 1024, d = 64]⌋512
*/
void keccak_init(uint16_t r, uint16_t c, uint8_t d, keccak_ctx_t* ctx){
        memset(ctx->a, 0x00, 5 * 5 * 8);
        ctx->r = r;
        ctx->c = c;
        ctx->d = d;
        ctx->bs = (uint8_t)(r / 8);
}

void keccak224_init(keccak_ctx_t* ctx){
        keccak_init(1152, 448, 28, ctx);
}

void keccak256_init(keccak_ctx_t* ctx){
        keccak_init(1088, 512, 32, ctx);
}

void keccak384_init(keccak_ctx_t* ctx){
        keccak_init( 832, 768, 48, ctx);
}

void keccak512_init(keccak_ctx_t* ctx){
        keccak_init( 576, 1024, 64, ctx);
}