/* * Copyright Supranational LLC * Licensed under the Apache License, Version 2.0, see LICENSE for details. * SPDX-License-Identifier: Apache-2.0 */ #ifndef __BLST_H__ #define __BLST_H__ #ifdef __SIZE_TYPE__ typedef __SIZE_TYPE__ size_t; #else #include #endif #if defined(__UINT8_TYPE__) && defined(__UINT32_TYPE__) \ && defined(__UINT64_TYPE__) typedef __UINT8_TYPE__ uint8_t; typedef __UINT32_TYPE__ uint32_t; typedef __UINT64_TYPE__ uint64_t; #else #include #endif #ifdef __cplusplus extern "C" { #elif defined(__BLST_CGO__) typedef _Bool bool; /* it's assumed that cgo calls modern enough compiler */ #elif !defined(bool) # if defined(__STDC_VERSION__) && __STDC_VERSION__>=199901 # define bool _Bool # else # define bool int # endif # define __blst_h_bool__ #endif #ifdef SWIG # define DEFNULL =NULL #elif defined __cplusplus # define DEFNULL =0 #else # define DEFNULL #endif typedef enum { BLST_SUCCESS = 0, BLST_BAD_ENCODING, BLST_POINT_NOT_ON_CURVE, BLST_POINT_NOT_IN_GROUP, BLST_AGGR_TYPE_MISMATCH, BLST_VERIFY_FAIL, BLST_PK_IS_INFINITY, BLST_BAD_SCALAR, } BLST_ERROR; typedef uint8_t byte; typedef uint64_t limb_t; typedef struct { byte b[256/8]; } blst_scalar; typedef struct { limb_t l[256/8/sizeof(limb_t)]; } blst_fr; typedef struct { limb_t l[384/8/sizeof(limb_t)]; } blst_fp; /* 0 is "real" part, 1 is "imaginary" */ typedef struct { blst_fp fp[2]; } blst_fp2; typedef struct { blst_fp2 fp2[3]; } blst_fp6; typedef struct { blst_fp6 fp6[2]; } blst_fp12; void blst_scalar_from_uint32(blst_scalar *out, const uint32_t a[8]); void blst_uint32_from_scalar(uint32_t out[8], const blst_scalar *a); void blst_scalar_from_uint64(blst_scalar *out, const uint64_t a[4]); void blst_uint64_from_scalar(uint64_t out[4], const blst_scalar *a); void blst_scalar_from_bendian(blst_scalar *out, const byte a[32]); void blst_bendian_from_scalar(byte out[32], const blst_scalar *a); void blst_scalar_from_lendian(blst_scalar *out, const byte a[32]); void blst_lendian_from_scalar(byte out[32], const blst_scalar *a); bool blst_scalar_fr_check(const blst_scalar *a); bool blst_sk_check(const blst_scalar *a); bool blst_sk_add_n_check(blst_scalar *out, const blst_scalar *a, const blst_scalar *b); bool blst_sk_sub_n_check(blst_scalar *out, const blst_scalar *a, const blst_scalar *b); bool blst_sk_mul_n_check(blst_scalar *out, const blst_scalar *a, const blst_scalar *b); void blst_sk_inverse(blst_scalar *out, const blst_scalar *a); bool blst_scalar_from_le_bytes(blst_scalar *out, const byte *in, size_t len); bool blst_scalar_from_be_bytes(blst_scalar *out, const byte *in, size_t len); #ifndef SWIG /* * BLS12-381-specific Fr operations. */ void blst_fr_add(blst_fr *ret, const blst_fr *a, const blst_fr *b); void blst_fr_sub(blst_fr *ret, const blst_fr *a, const blst_fr *b); void blst_fr_mul_by_3(blst_fr *ret, const blst_fr *a); void blst_fr_lshift(blst_fr *ret, const blst_fr *a, size_t count); void blst_fr_rshift(blst_fr *ret, const blst_fr *a, size_t count); void blst_fr_mul(blst_fr *ret, const blst_fr *a, const blst_fr *b); void blst_fr_sqr(blst_fr *ret, const blst_fr *a); void blst_fr_cneg(blst_fr *ret, const blst_fr *a, bool flag); void blst_fr_eucl_inverse(blst_fr *ret, const blst_fr *a); void blst_fr_inverse(blst_fr *ret, const blst_fr *a); void blst_fr_from_uint64(blst_fr *ret, const uint64_t a[4]); void blst_uint64_from_fr(uint64_t ret[4], const blst_fr *a); void blst_fr_from_scalar(blst_fr *ret, const blst_scalar *a); void blst_scalar_from_fr(blst_scalar *ret, const blst_fr *a); /* * BLS12-381-specific Fp operations. */ void blst_fp_add(blst_fp *ret, const blst_fp *a, const blst_fp *b); void blst_fp_sub(blst_fp *ret, const blst_fp *a, const blst_fp *b); void blst_fp_mul_by_3(blst_fp *ret, const blst_fp *a); void blst_fp_mul_by_8(blst_fp *ret, const blst_fp *a); void blst_fp_lshift(blst_fp *ret, const blst_fp *a, size_t count); void blst_fp_mul(blst_fp *ret, const blst_fp *a, const blst_fp *b); void blst_fp_sqr(blst_fp *ret, const blst_fp *a); void blst_fp_cneg(blst_fp *ret, const blst_fp *a, bool flag); void blst_fp_eucl_inverse(blst_fp *ret, const blst_fp *a); void blst_fp_inverse(blst_fp *ret, const blst_fp *a); bool blst_fp_sqrt(blst_fp *ret, const blst_fp *a); void blst_fp_from_uint32(blst_fp *ret, const uint32_t a[12]); void blst_uint32_from_fp(uint32_t ret[12], const blst_fp *a); void blst_fp_from_uint64(blst_fp *ret, const uint64_t a[6]); void blst_uint64_from_fp(uint64_t ret[6], const blst_fp *a); void blst_fp_from_bendian(blst_fp *ret, const byte a[48]); void blst_bendian_from_fp(byte ret[48], const blst_fp *a); void blst_fp_from_lendian(blst_fp *ret, const byte a[48]); void blst_lendian_from_fp(byte ret[48], const blst_fp *a); /* * BLS12-381-specific Fp2 operations. */ void blst_fp2_add(blst_fp2 *ret, const blst_fp2 *a, const blst_fp2 *b); void blst_fp2_sub(blst_fp2 *ret, const blst_fp2 *a, const blst_fp2 *b); void blst_fp2_mul_by_3(blst_fp2 *ret, const blst_fp2 *a); void blst_fp2_mul_by_8(blst_fp2 *ret, const blst_fp2 *a); void blst_fp2_lshift(blst_fp2 *ret, const blst_fp2 *a, size_t count); void blst_fp2_mul(blst_fp2 *ret, const blst_fp2 *a, const blst_fp2 *b); void blst_fp2_sqr(blst_fp2 *ret, const blst_fp2 *a); void blst_fp2_cneg(blst_fp2 *ret, const blst_fp2 *a, bool flag); void blst_fp2_eucl_inverse(blst_fp2 *ret, const blst_fp2 *a); void blst_fp2_inverse(blst_fp2 *ret, const blst_fp2 *a); bool blst_fp2_sqrt(blst_fp2 *ret, const blst_fp2 *a); /* * BLS12-381-specific Fp12 operations. */ void blst_fp12_sqr(blst_fp12 *ret, const blst_fp12 *a); void blst_fp12_cyclotomic_sqr(blst_fp12 *ret, const blst_fp12 *a); void blst_fp12_mul(blst_fp12 *ret, const blst_fp12 *a, const blst_fp12 *b); void blst_fp12_mul_by_xy00z0(blst_fp12 *ret, const blst_fp12 *a, const blst_fp6 *xy00z0); void blst_fp12_conjugate(blst_fp12 *a); void blst_fp12_inverse(blst_fp12 *ret, const blst_fp12 *a); /* caveat lector! |n| has to be non-zero and not more than 3! */ void blst_fp12_frobenius_map(blst_fp12 *ret, const blst_fp12 *a, size_t n); bool blst_fp12_is_equal(const blst_fp12 *a, const blst_fp12 *b); bool blst_fp12_is_one(const blst_fp12 *a); bool blst_fp12_in_group(const blst_fp12 *a); const blst_fp12 *blst_fp12_one(void); #endif // SWIG /* * BLS12-381-specific point operations. */ typedef struct { blst_fp x, y, z; } blst_p1; typedef struct { blst_fp x, y; } blst_p1_affine; void blst_p1_add(blst_p1 *out, const blst_p1 *a, const blst_p1 *b); void blst_p1_add_or_double(blst_p1 *out, const blst_p1 *a, const blst_p1 *b); void blst_p1_add_affine(blst_p1 *out, const blst_p1 *a, const blst_p1_affine *b); void blst_p1_add_or_double_affine(blst_p1 *out, const blst_p1 *a, const blst_p1_affine *b); void blst_p1_double(blst_p1 *out, const blst_p1 *a); void blst_p1_mult(blst_p1 *out, const blst_p1 *p, const byte *scalar, size_t nbits); void blst_p1_cneg(blst_p1 *p, bool cbit); void blst_p1_to_affine(blst_p1_affine *out, const blst_p1 *in); void blst_p1_from_affine(blst_p1 *out, const blst_p1_affine *in); bool blst_p1_on_curve(const blst_p1 *p); bool blst_p1_in_g1(const blst_p1 *p); bool blst_p1_is_equal(const blst_p1 *a, const blst_p1 *b); bool blst_p1_is_inf(const blst_p1 *a); const blst_p1 *blst_p1_generator(void); bool blst_p1_affine_on_curve(const blst_p1_affine *p); bool blst_p1_affine_in_g1(const blst_p1_affine *p); bool blst_p1_affine_is_equal(const blst_p1_affine *a, const blst_p1_affine *b); bool blst_p1_affine_is_inf(const blst_p1_affine *a); const blst_p1_affine *blst_p1_affine_generator(void); typedef struct { blst_fp2 x, y, z; } blst_p2; typedef struct { blst_fp2 x, y; } blst_p2_affine; void blst_p2_add(blst_p2 *out, const blst_p2 *a, const blst_p2 *b); void blst_p2_add_or_double(blst_p2 *out, const blst_p2 *a, const blst_p2 *b); void blst_p2_add_affine(blst_p2 *out, const blst_p2 *a, const blst_p2_affine *b); void blst_p2_add_or_double_affine(blst_p2 *out, const blst_p2 *a, const blst_p2_affine *b); void blst_p2_double(blst_p2 *out, const blst_p2 *a); void blst_p2_mult(blst_p2 *out, const blst_p2 *p, const byte *scalar, size_t nbits); void blst_p2_cneg(blst_p2 *p, bool cbit); void blst_p2_to_affine(blst_p2_affine *out, const blst_p2 *in); void blst_p2_from_affine(blst_p2 *out, const blst_p2_affine *in); bool blst_p2_on_curve(const blst_p2 *p); bool blst_p2_in_g2(const blst_p2 *p); bool blst_p2_is_equal(const blst_p2 *a, const blst_p2 *b); bool blst_p2_is_inf(const blst_p2 *a); const blst_p2 *blst_p2_generator(void); bool blst_p2_affine_on_curve(const blst_p2_affine *p); bool blst_p2_affine_in_g2(const blst_p2_affine *p); bool blst_p2_affine_is_equal(const blst_p2_affine *a, const blst_p2_affine *b); bool blst_p2_affine_is_inf(const blst_p2_affine *a); const blst_p2_affine *blst_p2_affine_generator(void); /* * Multi-scalar multiplications and other multi-point operations. */ void blst_p1s_to_affine(blst_p1_affine dst[], const blst_p1 *const points[], size_t npoints); void blst_p1s_add(blst_p1 *ret, const blst_p1_affine *const points[], size_t npoints); size_t blst_p1s_mult_wbits_precompute_sizeof(size_t wbits, size_t npoints); void blst_p1s_mult_wbits_precompute(blst_p1_affine table[], size_t wbits, const blst_p1_affine *const points[], size_t npoints); size_t blst_p1s_mult_wbits_scratch_sizeof(size_t npoints); void blst_p1s_mult_wbits(blst_p1 *ret, const blst_p1_affine table[], size_t wbits, size_t npoints, const byte *const scalars[], size_t nbits, limb_t *scratch); size_t blst_p1s_mult_pippenger_scratch_sizeof(size_t npoints); void blst_p1s_mult_pippenger(blst_p1 *ret, const blst_p1_affine *const points[], size_t npoints, const byte *const scalars[], size_t nbits, limb_t *scratch); void blst_p1s_tile_pippenger(blst_p1 *ret, const blst_p1_affine *const points[], size_t npoints, const byte *const scalars[], size_t nbits, limb_t *scratch, size_t bit0, size_t window); void blst_p2s_to_affine(blst_p2_affine dst[], const blst_p2 *const points[], size_t npoints); void blst_p2s_add(blst_p2 *ret, const blst_p2_affine *const points[], size_t npoints); size_t blst_p2s_mult_wbits_precompute_sizeof(size_t wbits, size_t npoints); void blst_p2s_mult_wbits_precompute(blst_p2_affine table[], size_t wbits, const blst_p2_affine *const points[], size_t npoints); size_t blst_p2s_mult_wbits_scratch_sizeof(size_t npoints); void blst_p2s_mult_wbits(blst_p2 *ret, const blst_p2_affine table[], size_t wbits, size_t npoints, const byte *const scalars[], size_t nbits, limb_t *scratch); size_t blst_p2s_mult_pippenger_scratch_sizeof(size_t npoints); void blst_p2s_mult_pippenger(blst_p2 *ret, const blst_p2_affine *const points[], size_t npoints, const byte *const scalars[], size_t nbits, limb_t *scratch); void blst_p2s_tile_pippenger(blst_p2 *ret, const blst_p2_affine *const points[], size_t npoints, const byte *const scalars[], size_t nbits, limb_t *scratch, size_t bit0, size_t window); /* * Hash-to-curve operations. */ #ifndef SWIG void blst_map_to_g1(blst_p1 *out, const blst_fp *u, const blst_fp *v DEFNULL); void blst_map_to_g2(blst_p2 *out, const blst_fp2 *u, const blst_fp2 *v DEFNULL); #endif void blst_encode_to_g1(blst_p1 *out, const byte *msg, size_t msg_len, const byte *DST DEFNULL, size_t DST_len DEFNULL, const byte *aug DEFNULL, size_t aug_len DEFNULL); void blst_hash_to_g1(blst_p1 *out, const byte *msg, size_t msg_len, const byte *DST DEFNULL, size_t DST_len DEFNULL, const byte *aug DEFNULL, size_t aug_len DEFNULL); void blst_encode_to_g2(blst_p2 *out, const byte *msg, size_t msg_len, const byte *DST DEFNULL, size_t DST_len DEFNULL, const byte *aug DEFNULL, size_t aug_len DEFNULL); void blst_hash_to_g2(blst_p2 *out, const byte *msg, size_t msg_len, const byte *DST DEFNULL, size_t DST_len DEFNULL, const byte *aug DEFNULL, size_t aug_len DEFNULL); /* * Zcash-compatible serialization/deserialization. */ void blst_p1_serialize(byte out[96], const blst_p1 *in); void blst_p1_compress(byte out[48], const blst_p1 *in); void blst_p1_affine_serialize(byte out[96], const blst_p1_affine *in); void blst_p1_affine_compress(byte out[48], const blst_p1_affine *in); BLST_ERROR blst_p1_uncompress(blst_p1_affine *out, const byte in[48]); BLST_ERROR blst_p1_deserialize(blst_p1_affine *out, const byte in[96]); void blst_p2_serialize(byte out[192], const blst_p2 *in); void blst_p2_compress(byte out[96], const blst_p2 *in); void blst_p2_affine_serialize(byte out[192], const blst_p2_affine *in); void blst_p2_affine_compress(byte out[96], const blst_p2_affine *in); BLST_ERROR blst_p2_uncompress(blst_p2_affine *out, const byte in[96]); BLST_ERROR blst_p2_deserialize(blst_p2_affine *out, const byte in[192]); /* * Specification defines two variants, 'minimal-signature-size' and * 'minimal-pubkey-size'. To unify appearance we choose to distinguish * them by suffix referring to the public key type, more specifically * _pk_in_g1 corresponds to 'minimal-pubkey-size' and _pk_in_g2 - to * 'minimal-signature-size'. It might appear a bit counterintuitive * in sign call, but no matter how you twist it, something is bound to * turn a little odd. */ /* * Secret-key operations. */ void blst_keygen(blst_scalar *out_SK, const byte *IKM, size_t IKM_len, const byte *info DEFNULL, size_t info_len DEFNULL); void blst_sk_to_pk_in_g1(blst_p1 *out_pk, const blst_scalar *SK); void blst_sign_pk_in_g1(blst_p2 *out_sig, const blst_p2 *hash, const blst_scalar *SK); void blst_sk_to_pk_in_g2(blst_p2 *out_pk, const blst_scalar *SK); void blst_sign_pk_in_g2(blst_p1 *out_sig, const blst_p1 *hash, const blst_scalar *SK); /* * Pairing interface. */ #ifndef SWIG void blst_miller_loop(blst_fp12 *ret, const blst_p2_affine *Q, const blst_p1_affine *P); void blst_miller_loop_n(blst_fp12 *ret, const blst_p2_affine *const Qs[], const blst_p1_affine *const Ps[], size_t n); void blst_final_exp(blst_fp12 *ret, const blst_fp12 *f); void blst_precompute_lines(blst_fp6 Qlines[68], const blst_p2_affine *Q); void blst_miller_loop_lines(blst_fp12 *ret, const blst_fp6 Qlines[68], const blst_p1_affine *P); bool blst_fp12_finalverify(const blst_fp12 *gt1, const blst_fp12 *gt2); #endif #ifdef __BLST_CGO__ typedef limb_t blst_pairing; #elif defined(__BLST_RUST_BINDGEN__) typedef struct {} blst_pairing; #else typedef struct blst_opaque blst_pairing; #endif size_t blst_pairing_sizeof(void); void blst_pairing_init(blst_pairing *new_ctx, bool hash_or_encode, const byte *DST DEFNULL, size_t DST_len DEFNULL); const byte *blst_pairing_get_dst(const blst_pairing *ctx); void blst_pairing_commit(blst_pairing *ctx); BLST_ERROR blst_pairing_aggregate_pk_in_g2(blst_pairing *ctx, const blst_p2_affine *PK, const blst_p1_affine *signature, const byte *msg, size_t msg_len, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_pairing_chk_n_aggr_pk_in_g2(blst_pairing *ctx, const blst_p2_affine *PK, bool pk_grpchk, const blst_p1_affine *signature, bool sig_grpchk, const byte *msg, size_t msg_len, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_pairing_mul_n_aggregate_pk_in_g2(blst_pairing *ctx, const blst_p2_affine *PK, const blst_p1_affine *sig, const byte *scalar, size_t nbits, const byte *msg, size_t msg_len, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_pairing_chk_n_mul_n_aggr_pk_in_g2(blst_pairing *ctx, const blst_p2_affine *PK, bool pk_grpchk, const blst_p1_affine *sig, bool sig_grpchk, const byte *scalar, size_t nbits, const byte *msg, size_t msg_len, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_pairing_aggregate_pk_in_g1(blst_pairing *ctx, const blst_p1_affine *PK, const blst_p2_affine *signature, const byte *msg, size_t msg_len, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_pairing_chk_n_aggr_pk_in_g1(blst_pairing *ctx, const blst_p1_affine *PK, bool pk_grpchk, const blst_p2_affine *signature, bool sig_grpchk, const byte *msg, size_t msg_len, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_pairing_mul_n_aggregate_pk_in_g1(blst_pairing *ctx, const blst_p1_affine *PK, const blst_p2_affine *sig, const byte *scalar, size_t nbits, const byte *msg, size_t msg_len, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_pairing_chk_n_mul_n_aggr_pk_in_g1(blst_pairing *ctx, const blst_p1_affine *PK, bool pk_grpchk, const blst_p2_affine *sig, bool sig_grpchk, const byte *scalar, size_t nbits, const byte *msg, size_t msg_len, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_pairing_merge(blst_pairing *ctx, const blst_pairing *ctx1); bool blst_pairing_finalverify(const blst_pairing *ctx, const blst_fp12 *gtsig DEFNULL); /* * Customarily applications aggregate signatures separately. * In which case application would have to pass NULLs for |signature| * to blst_pairing_aggregate calls and pass aggregated signature * collected with these calls to blst_pairing_finalverify. Inputs are * Zcash-compatible "straight-from-wire" byte vectors, compressed or * not. */ BLST_ERROR blst_aggregate_in_g1(blst_p1 *out, const blst_p1 *in, const byte *zwire); BLST_ERROR blst_aggregate_in_g2(blst_p2 *out, const blst_p2 *in, const byte *zwire); void blst_aggregated_in_g1(blst_fp12 *out, const blst_p1_affine *signature); void blst_aggregated_in_g2(blst_fp12 *out, const blst_p2_affine *signature); /* * "One-shot" CoreVerify entry points. */ BLST_ERROR blst_core_verify_pk_in_g1(const blst_p1_affine *pk, const blst_p2_affine *signature, bool hash_or_encode, const byte *msg, size_t msg_len, const byte *DST DEFNULL, size_t DST_len DEFNULL, const byte *aug DEFNULL, size_t aug_len DEFNULL); BLST_ERROR blst_core_verify_pk_in_g2(const blst_p2_affine *pk, const blst_p1_affine *signature, bool hash_or_encode, const byte *msg, size_t msg_len, const byte *DST DEFNULL, size_t DST_len DEFNULL, const byte *aug DEFNULL, size_t aug_len DEFNULL); extern const blst_p1_affine BLS12_381_G1; extern const blst_p1_affine BLS12_381_NEG_G1; extern const blst_p2_affine BLS12_381_G2; extern const blst_p2_affine BLS12_381_NEG_G2; #include "blst_aux.h" #ifdef __cplusplus } #elif defined(__blst_h_bool__) # undef __blst_h_bool__ # undef bool #endif #endif