#include #include #include #include #include #include #include #include "varint.h" #include "warnings.h" #include "crypto.h" #include "keccak.h" #include "hash-ops.h" #include "generic-ops.h" #include namespace crypto { using std::abort; using std::int32_t; using std::int64_t; using std::lock_guard; using std::mutex; using std::size_t; using std::uint32_t; using std::uint64_t; extern "C" { #include "crypto-ops.h" #include "random.h" } mutex random_lock; static inline unsigned char *operator &(ec_point &point) { return &reinterpret_cast(point); } static inline const unsigned char *operator &(const ec_point &point) { return &reinterpret_cast(point); } static inline unsigned char *operator &(ec_scalar &scalar) { return &reinterpret_cast(scalar); } static inline const unsigned char *operator &(const ec_scalar &scalar) { return &reinterpret_cast(scalar); } /* generate a random 32-byte (256-bit) integer and copy it to res */ static inline void random_scalar(ec_scalar &res) { unsigned char tmp[64]; generate_random_bytes(64, tmp); sc_reduce(tmp); memcpy(&res, tmp, 32); } static void hash_to_scalar(const void *data, size_t length, ec_scalar &res) { //was static inline void cn_fast_hashh(data, length, reinterpret_cast(res)); //this is the void one.. reinterp is trying to get it from ec_scalar to the correct thing... sc_reduce32(&res); } /* * generate public and secret keys from a random 256-bit integer * TODO: allow specifiying random value (for wallet recovery) * */ secret_key crypto_ops::generate_keys(public_key &pub, secret_key &sec, const secret_key& recovery_key, bool recover) { lock_guard lock(random_lock); ge_p3 point; secret_key rng; if (recover) { rng = recovery_key; } else { random_scalar(rng); } sec = rng; sc_reduce32(&sec); // reduce in case second round of keys (sendkeys) ge_scalarmult_base(&point, &sec); ge_p3_tobytes(&pub, &point); return rng; } bool crypto_ops::check_key(const public_key &key) { ge_p3 point; return ge_frombytes_vartime(&point, &key) == 0; } bool crypto_ops::secret_key_to_public_key(const secret_key &sec, public_key &pub) { ge_p3 point; if (sc_check(&sec) != 0) { return false; } ge_scalarmult_base(&point, &sec); ge_p3_tobytes(&pub, &point); return true; } bool crypto_ops::generate_key_derivation(const public_key &key1, const secret_key &key2, key_derivation &derivation) { ge_p3 point; ge_p2 point2; ge_p1p1 point3; assert(sc_check(&key2) == 0); if (ge_frombytes_vartime(&point, &key1) != 0) { return false; } ge_scalarmult(&point2, &key2, &point); ge_mul8(&point3, &point2); ge_p1p1_to_p2(&point2, &point3); ge_tobytes(&derivation, &point2); return true; } static void derivation_to_scalar(const key_derivation &derivation, size_t output_index, ec_scalar &res) { struct { key_derivation derivation; char output_index[(sizeof(size_t) * 8 + 6) / 7]; } buf; char *end = buf.output_index; buf.derivation = derivation; tools::write_varint(end, output_index); assert(end <= buf.output_index + sizeof buf.output_index); hash_to_scalar(&buf, end - reinterpret_cast(&buf), res); } bool crypto_ops::derive_public_key(const key_derivation &derivation, size_t output_index, const public_key &base, public_key &derived_key) { ec_scalar scalar; ge_p3 point1; ge_p3 point2; ge_cached point3; ge_p1p1 point4; ge_p2 point5; if (ge_frombytes_vartime(&point1, &base) != 0) { return false; } derivation_to_scalar(derivation, output_index, scalar); ge_scalarmult_base(&point2, &scalar); ge_p3_to_cached(&point3, &point2); ge_add(&point4, &point1, &point3); ge_p1p1_to_p2(&point5, &point4); ge_tobytes(&derived_key, &point5); return true; } void crypto_ops::derive_secret_key(const key_derivation &derivation, size_t output_index, const secret_key &base, secret_key &derived_key) { ec_scalar scalar; assert(sc_check(&base) == 0); derivation_to_scalar(derivation, output_index, scalar); sc_add(&derived_key, &base, &scalar); } struct s_comm { hash h; ec_point key; ec_point comm; }; void crypto_ops::generate_signature(const hash &prefix_hash, const public_key &pub, const secret_key &sec, signature &sig) { lock_guard lock(random_lock); ge_p3 tmp3; ec_scalar k; //ec_scalar k = {{0xbf, 0x4b, 0xa0, 0xc8, 0x81, 0xda, 0x40, 0xc9, 0x89, 0x29, 0x27, 0x75, 0x43, 0xe7, 0x38, 0x25, 0xb8, 0xcc, 0x5a, 0x73, 0x21, 0x8a, 0x12, 0x65, 0xa0, 0xf8, 0x33, 0x37, 0x60, 0x17, 0x92, 0x06}}; //uncomment for testing purposes s_comm buf; #if !defined(NDEBUG) { ge_p3 t; public_key t2; assert(sc_check(&sec) == 0); ge_scalarmult_base(&t, &sec); ge_p3_tobytes(&t2, &t); assert(pub == t2); } #endif buf.h = prefix_hash; buf.key = pub; random_scalar(k); //fix a scalar k for testing purposes ge_scalarmult_base(&tmp3, &k); ge_p3_tobytes(&buf.comm, &tmp3); //printv(buf.comm.data, "comm"); //testing hash_to_scalar(&buf, sizeof(s_comm), sig.c); //printf("here2\n"); sc_mulsub(&sig.r, &sig.c, &sec, &k); //k - c*sec mod l } bool crypto_ops::check_signature(const hash &prefix_hash, const public_key &pub, const signature &sig) { ge_p2 tmp2; ge_p3 tmp3; ec_scalar c; s_comm buf; assert(check_key(pub)); buf.h = prefix_hash; buf.key = pub; if (ge_frombytes_vartime(&tmp3, &pub) != 0) { abort(); } if (sc_check(&sig.c) != 0 || sc_check(&sig.r) != 0) { return false; } ge_double_scalarmult_base_vartime(&tmp2, &sig.c, &tmp3, &sig.r); //tmp2 = cP + rG ge_tobytes(&buf.comm, &tmp2); hash_to_scalar(&buf, sizeof(s_comm), c); sc_sub(&c, &c, &sig.c); return sc_isnonzero(&c) == 0; } static void hash_to_ec(const public_key &key, ge_p3 &res) { hash h; ge_p2 point; ge_p1p1 point2; cn_fast_hashh(std::addressof(key), sizeof(public_key), h); ge_fromfe_frombytes_vartime(&point, reinterpret_cast(&h)); ge_mul8(&point2, &point); ge_p1p1_to_p3(&res, &point2); } void crypto_ops::generate_key_image(const public_key &pub, const secret_key &sec, key_image &image) { ge_p3 point; ge_p2 point2; assert(sc_check(&sec) == 0); hash_to_ec(pub, point); ge_scalarmult(&point2, &sec, &point); ge_tobytes(&image, &point2); } struct rs_comm { hash h; struct { ec_point a, b; } ab[]; }; static inline size_t rs_comm_size(size_t pubs_count) { return sizeof(rs_comm) + pubs_count * sizeof(rs_comm().ab[0]); } void crypto_ops::generate_ring_signature(const hash &prefix_hash, const key_image &image, const public_key *const *pubs, size_t pubs_count, const secret_key &sec, size_t sec_index, signature *sig) { lock_guard lock(random_lock); size_t i; ge_p3 image_unp; ge_dsmp image_pre; ec_scalar sum, k, h; rs_comm *const buf = reinterpret_cast(alloca(rs_comm_size(pubs_count))); assert(sec_index < pubs_count); #if !defined(NDEBUG) { ge_p3 t; public_key t2; key_image t3; assert(sc_check(&sec) == 0); ge_scalarmult_base(&t, &sec); ge_p3_tobytes(&t2, &t); assert(*pubs[sec_index] == t2); generate_key_image(*pubs[sec_index], sec, t3); assert(image == t3); for (i = 0; i < pubs_count; i++) { assert(check_key(*pubs[i])); } } #endif if (ge_frombytes_vartime(&image_unp, &image) != 0) { abort(); } ge_dsm_precomp(image_pre, &image_unp); sc_0(&sum); buf->h = prefix_hash; for (i = 0; i < pubs_count; i++) { ge_p2 tmp2; ge_p3 tmp3; if (i == sec_index) { random_scalar(k); ge_scalarmult_base(&tmp3, &k); ge_p3_tobytes(&buf->ab[i].a, &tmp3); hash_to_ec(*pubs[i], tmp3); ge_scalarmult(&tmp2, &k, &tmp3); ge_tobytes(&buf->ab[i].b, &tmp2); } else { random_scalar(sig[i].c); random_scalar(sig[i].r); if (ge_frombytes_vartime(&tmp3, &*pubs[i]) != 0) { abort(); } ge_double_scalarmult_base_vartime(&tmp2, &sig[i].c, &tmp3, &sig[i].r); ge_tobytes(&buf->ab[i].a, &tmp2); hash_to_ec(*pubs[i], tmp3); ge_double_scalarmult_precomp_vartime(&tmp2, &sig[i].r, &tmp3, &sig[i].c, image_pre); ge_tobytes(&buf->ab[i].b, &tmp2); sc_add(&sum, &sum, &sig[i].c); } } hash_to_scalar(buf, rs_comm_size(pubs_count), h); sc_sub(&sig[sec_index].c, &h, &sum); sc_mulsub(&sig[sec_index].r, &sig[sec_index].c, &sec, &k); } bool crypto_ops::check_ring_signature(const hash &prefix_hash, const key_image &image, const public_key *const *pubs, size_t pubs_count, const signature *sig) { size_t i; ge_p3 image_unp; ge_dsmp image_pre; ec_scalar sum, h; rs_comm *const buf = reinterpret_cast(alloca(rs_comm_size(pubs_count))); #if !defined(NDEBUG) for (i = 0; i < pubs_count; i++) { assert(check_key(*pubs[i])); } #endif if (ge_frombytes_vartime(&image_unp, &image) != 0) { return false; } ge_dsm_precomp(image_pre, &image_unp); sc_0(&sum); buf->h = prefix_hash; for (i = 0; i < pubs_count; i++) { ge_p2 tmp2; ge_p3 tmp3; if (sc_check(&sig[i].c) != 0 || sc_check(&sig[i].r) != 0) { return false; } if (ge_frombytes_vartime(&tmp3, &*pubs[i]) != 0) { abort(); } ge_double_scalarmult_base_vartime(&tmp2, &sig[i].c, &tmp3, &sig[i].r); ge_tobytes(&buf->ab[i].a, &tmp2); hash_to_ec(*pubs[i], tmp3); ge_double_scalarmult_precomp_vartime(&tmp2, &sig[i].r, &tmp3, &sig[i].c, image_pre); ge_tobytes(&buf->ab[i].b, &tmp2); sc_add(&sum, &sum, &sig[i].c); } hash_to_scalar(buf, rs_comm_size(pubs_count), h); sc_sub(&h, &h, &sum); return sc_isnonzero(&h) == 0; } } CRYPTO_MAKE_HASHABLE(hash) //these are in generic-ops.h CRYPTO_MAKE_COMPARABLE(hash8)