diff options
Diffstat (limited to 'ecdsa.c')
-rw-r--r-- | ecdsa.c | 141 |
1 files changed, 141 insertions, 0 deletions
@@ -89,6 +89,18 @@ #endif /* + * Whether to use the Verilog point multipliers. + */ + +#ifndef HAL_ECDSA_VERILOG_ECDSA256_MULTIPLIER +#define HAL_ECDSA_VERILOG_ECDSA256_MULTIPLIER 1 +#endif + +#ifndef HAL_ECDSA_VERILOG_ECDSA384_MULTIPLIER +#define HAL_ECDSA_VERILOG_ECDSA384_MULTIPLIER 1 +#endif + +/* * Whether we want debug output. */ @@ -124,6 +136,7 @@ typedef struct { fp_digit rho; /* Montgomery reduction value */ const uint8_t *oid; /* OBJECT IDENTIFIER */ size_t oid_len; /* Length of OBJECT IDENTIFIER */ + hal_curve_name_t curve; /* Curve name */ } ecdsa_curve_t; /* @@ -206,6 +219,7 @@ static const ecdsa_curve_t * const get_curve(const hal_curve_name_t curve) fp_montgomery_calc_normalization(curve_p256.mu, curve_p256.q); curve_p256.oid = p256_oid; curve_p256.oid_len = sizeof(p256_oid); + curve_p256.curve = HAL_CURVE_P256; fp_read_unsigned_bin(curve_p384.q, unconst_uint8_t(p384_q), sizeof(p384_q)); fp_read_unsigned_bin(curve_p384.b, unconst_uint8_t(p384_b), sizeof(p384_b)); @@ -218,6 +232,7 @@ static const ecdsa_curve_t * const get_curve(const hal_curve_name_t curve) fp_montgomery_calc_normalization(curve_p384.mu, curve_p384.q); curve_p384.oid = p384_oid; curve_p384.oid_len = sizeof(p384_oid); + curve_p384.curve = HAL_CURVE_P384; fp_read_unsigned_bin(curve_p521.q, unconst_uint8_t(p521_q), sizeof(p521_q)); fp_read_unsigned_bin(curve_p521.b, unconst_uint8_t(p521_b), sizeof(p521_b)); @@ -230,6 +245,7 @@ static const ecdsa_curve_t * const get_curve(const hal_curve_name_t curve) fp_montgomery_calc_normalization(curve_p521.mu, curve_p521.q); curve_p521.oid = p521_oid; curve_p521.oid_len = sizeof(p521_oid); + curve_p521.curve = HAL_CURVE_P521; initialized = 1; } @@ -749,6 +765,113 @@ static inline hal_error_t get_random(void *buffer, const size_t length) #endif /* HAL_ECDSA_DEBUG_ONLY_STATIC_TEST_VECTOR_RANDOM */ /* + * Use experimental Verilog base point multiplier cores to calculate + * public key given a private key. point_pick_random() has already + * selected a suitable private key for us, we just need to calculate + * the corresponding public key. + */ + +#if HAL_ECDSA_VERILOG_ECDSA256_MULTIPLIER || HAL_ECDSA_VERILOG_ECDSA384_MULTIPLIER + +typedef struct { + size_t bytes; + const char *name; + hal_addr_t k_addr; + hal_addr_t x_addr; + hal_addr_t y_addr; +} verilog_ecdsa_driver_t; + +static hal_error_t verilog_point_pick_random(const verilog_ecdsa_driver_t * const driver, + fp_int *k, + ec_point_t *P) +{ + assert(k != NULL && P != NULL); + + const size_t len = fp_unsigned_bin_size(k); + uint8_t b[driver->bytes]; + const uint8_t zero[4] = {0, 0, 0, 0}; + hal_core_t *core = NULL; + hal_error_t err; + + if (len > sizeof(b)) + return HAL_ERROR_RESULT_TOO_LONG; + + if ((err = hal_core_alloc(driver->name, &core)) != HAL_OK) + goto fail; + +#define check(_x_) do { if ((err = (_x_)) != HAL_OK) goto fail; } while (0) + + memset(b, 0, sizeof(b)); + fp_to_unsigned_bin(k, b + sizeof(b) - len); + + for (int i = 0; i < sizeof(b); i += 4) + check(hal_io_write(core, driver->k_addr + i/4, &b[sizeof(b) - 4 - i], 4)); + + check(hal_io_write(core, ADDR_CTRL, zero, sizeof(zero))); + check(hal_io_next(core)); + check(hal_io_wait_valid(core)); + + for (int i = 0; i < sizeof(b); i += 4) + check(hal_io_read(core, driver->x_addr + i/4, &b[sizeof(b) - 4 - i], 4)); + fp_read_unsigned_bin(P->x, b, sizeof(b)); + + for (int i = 0; i < sizeof(b); i += 4) + check(hal_io_read(core, driver->y_addr + i/4, &b[sizeof(b) - 4 - i], 4)); + fp_read_unsigned_bin(P->y, b, sizeof(b)); + + fp_set(P->z, 1); + +#undef check + + err = HAL_OK; + + fail: + hal_core_free(core); + memset(b, 0, sizeof(b)); + return err; +} + +#endif + +static inline hal_error_t verilog_p256_point_pick_random(fp_int *k, ec_point_t *P) +{ +#if HAL_ECDSA_VERILOG_ECDSA256_MULTIPLIER + + static const verilog_ecdsa_driver_t p256_driver = { + .name = ECDSA256_NAME, + .bytes = ECDSA256_OPERAND_BITS / 8, + .k_addr = ECDSA256_ADDR_K, + .x_addr = ECDSA256_ADDR_X, + .y_addr = ECDSA256_ADDR_Y + }; + + return verilog_point_pick_random(&p256_driver, k, P); + +#endif + + return HAL_ERROR_CORE_NOT_FOUND; +} + +static inline hal_error_t verilog_p384_point_pick_random(fp_int *k, ec_point_t *P) +{ +#if HAL_ECDSA_VERILOG_ECDSA384_MULTIPLIER + + static const verilog_ecdsa_driver_t p384_driver = { + .name = ECDSA384_NAME, + .bytes = ECDSA384_OPERAND_BITS / 8, + .k_addr = ECDSA384_ADDR_K, + .x_addr = ECDSA384_ADDR_X, + .y_addr = ECDSA384_ADDR_Y + }; + + return verilog_point_pick_random(&p384_driver, k, P); + +#endif + + return HAL_ERROR_CORE_NOT_FOUND; +} + +/* * Pick a random point on the curve, return random scalar and * resulting point. */ @@ -792,6 +915,24 @@ static hal_error_t point_pick_random(const ecdsa_curve_t * const curve, memset(k_buf, 0, sizeof(k_buf)); +#if HAL_ECDSA_VERILOG_ECDSA256_MULTIPLIER || HAL_ECDSA_VERILOG_ECDSA384_MULTIPLIER + switch (curve->curve) { + + case HAL_CURVE_P256: + if ((err = verilog_p256_point_pick_random(k, P)) != HAL_ERROR_CORE_NOT_FOUND) + return err; + break; + + case HAL_CURVE_P384: + if ((err = verilog_p384_point_pick_random(k, P)) != HAL_ERROR_CORE_NOT_FOUND) + return err; + break; + + default: + break; + } +#endif + /* * Calculate P = kG and return. */ |