}
}
-void keccak_dump_ctx(keccak_ctx_t* ctx){
+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);
0xf1, 0xd0, 0x21, 0x78,
};
-const static uint8_t r[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) }
+#define RP_IDX(i, j) ((((2 * j + 3 * i) % 5) * 5 + i) * 8)
+
+uint8_t const rho_pi_idx_table[5][5] PROGMEM = {
+ { RP_IDX(0, 0), RP_IDX(0, 1), RP_IDX(0, 2), RP_IDX(0, 3), RP_IDX(0, 4) },
+ { RP_IDX(1, 0), RP_IDX(1, 1), RP_IDX(1, 2), RP_IDX(1, 3), RP_IDX(1, 4) },
+ { RP_IDX(2, 0), RP_IDX(2, 1), RP_IDX(2, 2), RP_IDX(2, 3), RP_IDX(2, 4) },
+ { RP_IDX(3, 0), RP_IDX(3, 1), RP_IDX(3, 2), RP_IDX(3, 3), RP_IDX(3, 4) },
+ { RP_IDX(4, 0), RP_IDX(4, 1), RP_IDX(4, 2), RP_IDX(4, 3), RP_IDX(4, 4) }
+};
+
+#define ROT_BIT(a) (( (a) <= 4) ? ((a) << 1) : (0x01 | ((8 - (a)) << 1)))
+#define ROT_CODE(a) ((((a) / 8 + ((((a) % 8) > 4) ? 1 : 0)) << 4) | ROT_BIT(((a) % 8)))
+
+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) }
};
+
static inline
void keccak_round(uint64_t *a, uint8_t rci){
uint64_t b[5][5];
uint64_t v64;
uint8_t v8[8];
} t;
+ 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;
/* theta */
for(i = 0; i < 5; ++i){
b[i][0] = a[i] ^ a[5 + i] ^ a[10 + i] ^ a[15 + i] ^ a[20 + i];
}
- for(i = 0; i < 5; ++i){
+ for(i = 0; i < 5; ++i){
t.v64 = b[(4 + i) % 5][0] ^ rotate64_1bit_left(b[(i + 1) % 5][0]);
for(j = 0; j < 5; ++j){
a[j * 5 + i] ^= t.v64;
keccak_dump_state(a);
#endif
/* rho & pi */
- for(i = 0; i < 5; ++i){
- for(j = 0; j < 5; ++j){
- b[(2 * i + 3 * j) % 5][j] = rotate64left_code(a[j * 5 +i], pgm_read_byte(&(r[i][j])));
- }
- }
+ 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
cli_putstr_P(PSTR("\r\n--- after rho & pi ---"));
keccak_dump_state(a);
a[j * 5 + i] = b[j][i] ^ ((~(b[j][(i + 1) % 5])) & (b[j][(i + 2) % 5]));
}
}
+
#if DEBUG
cli_putstr_P(PSTR("\r\nAfter chi:"));
keccak_dump_state(a);
#endif
}
-void keccak_f1600(void* a){
+void keccak_f1600(void *a){
uint8_t i = 0;
do {
#if DEBUG
} while (++i < 24);
}
-void keccak_nextBlock(keccak_ctx_t* ctx, const void* block){
+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){
+void keccak_lastBlock(keccak_ctx_t *ctx, const void *block, uint16_t length_b){
uint8_t length_B;
uint8_t t;
while(length_b >= ctx->r){
}else{
t = 0x01;
}
- ctx->a[length_B] ^= t
+ ctx->a[length_B] ^= t;
if(length_b == ctx->r - 1){
keccak_f1600(ctx->a);
}
keccak_f1600(ctx->a);
}
-void keccak_ctx2hash(void* dest, uint16_t length_b, keccak_ctx_t* ctx){
+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;
memcpy(dest, ctx->a, (length_b+7)/8);
}
-void keccak224_ctx2hash(void* dest, keccak_ctx_t* ctx){
+void keccak224_ctx2hash(void *dest, keccak_ctx_t *ctx){
keccak_ctx2hash(dest, 224, ctx);
}
-void keccak256_ctx2hash(void* dest, keccak_ctx_t* ctx){
+void keccak256_ctx2hash(void *dest, keccak_ctx_t *ctx){
keccak_ctx2hash(dest, 256, ctx);
}
-void keccak384_ctx2hash(void* dest, keccak_ctx_t* ctx){
+void keccak384_ctx2hash(void *dest, keccak_ctx_t *ctx){
keccak_ctx2hash(dest, 384, ctx);
}
-void keccak512_ctx2hash(void* dest, keccak_ctx_t* ctx){
+void keccak512_ctx2hash(void *dest, keccak_ctx_t *ctx){
keccak_ctx2hash(dest, 512, ctx);
}
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, keccak_ctx_t* ctx){
+void keccak_init(uint16_t r, keccak_ctx_t *ctx){
memset(ctx->a, 0x00, 5 * 5 * 8);
ctx->r = r;
ctx->bs = (uint8_t)(r / 8);
}
-void keccak224_init(keccak_ctx_t* ctx){
+void keccak224_init(keccak_ctx_t *ctx){
keccak_init(1152, ctx);
}
-void keccak256_init(keccak_ctx_t* ctx){
+void keccak256_init(keccak_ctx_t *ctx){
keccak_init(1088, ctx);
}
-void keccak384_init(keccak_ctx_t* ctx){
+void keccak384_init(keccak_ctx_t *ctx){
keccak_init( 832, ctx);
}
-void keccak512_init(keccak_ctx_t* ctx){
+void keccak512_init(keccak_ctx_t *ctx){
keccak_init( 576, ctx);
}