#include "bitcoin/locktime.h" #include "bitcoin/pubkey.h" #include "bitcoin/signature.h" #include "protobuf_convert.h" #include Signature *signature_to_proto(const tal_t *ctx, secp256k1_context *secpctx, const struct signature *sig) { u8 compact[64]; Signature *pb = tal(ctx, Signature); signature__init(pb); assert(sig_valid(secpctx, sig)); secp256k1_ecdsa_signature_serialize_compact(secpctx, compact, &sig->sig); /* Kill me now... */ memcpy(&pb->r1, compact, 8); memcpy(&pb->r2, compact + 8, 8); memcpy(&pb->r3, compact + 16, 8); memcpy(&pb->r4, compact + 24, 8); memcpy(&pb->s1, compact + 32, 8); memcpy(&pb->s2, compact + 40, 8); memcpy(&pb->s3, compact + 48, 8); memcpy(&pb->s4, compact + 56, 8); return pb; } bool proto_to_signature(secp256k1_context *secpctx, const Signature *pb, struct signature *sig) { u8 compact[64]; /* Kill me again. */ memcpy(compact, &pb->r1, 8); memcpy(compact + 8, &pb->r2, 8); memcpy(compact + 16, &pb->r3, 8); memcpy(compact + 24, &pb->r4, 8); memcpy(compact + 32, &pb->s1, 8); memcpy(compact + 40, &pb->s2, 8); memcpy(compact + 48, &pb->s3, 8); memcpy(compact + 56, &pb->s4, 8); if (secp256k1_ecdsa_signature_parse_compact(secpctx, &sig->sig, compact) != 1) return false; return sig_valid(secpctx, sig); } BitcoinPubkey *pubkey_to_proto(const tal_t *ctx, secp256k1_context *secpctx, const struct pubkey *key) { BitcoinPubkey *p = tal(ctx, BitcoinPubkey); bitcoin_pubkey__init(p); p->key.len = PUBKEY_DER_LEN; p->key.data = tal_arr(p, u8, p->key.len); pubkey_to_der(secpctx, p->key.data, key); return p; } bool proto_to_pubkey(secp256k1_context *secpctx, const BitcoinPubkey *pb, struct pubkey *key) { return pubkey_from_der(secpctx, pb->key.data, pb->key.len, key); } Sha256Hash *sha256_to_proto(const tal_t *ctx, const struct sha256 *hash) { Sha256Hash *h = tal(ctx, Sha256Hash); sha256_hash__init(h); /* Kill me now... */ memcpy(&h->a, hash->u.u8, 8); memcpy(&h->b, hash->u.u8 + 8, 8); memcpy(&h->c, hash->u.u8 + 16, 8); memcpy(&h->d, hash->u.u8 + 24, 8); return h; } void proto_to_sha256(const Sha256Hash *pb, struct sha256 *hash) { /* Kill me again. */ memcpy(hash->u.u8, &pb->a, 8); memcpy(hash->u.u8 + 8, &pb->b, 8); memcpy(hash->u.u8 + 16, &pb->c, 8); memcpy(hash->u.u8 + 24, &pb->d, 8); } Rval *rval_to_proto(const tal_t *ctx, const struct rval *r) { Rval *pb = tal(ctx, Rval); rval__init(pb); /* Kill me now... */ memcpy(&pb->a, r->r, 8); memcpy(&pb->b, r->r + 8, 8); memcpy(&pb->c, r->r + 16, 8); memcpy(&pb->d, r->r + 24, 8); return pb; } void proto_to_rval(const Rval *pb, struct rval *r) { /* Kill me again. */ memcpy(r->r, &pb->a, 8); memcpy(r->r + 8, &pb->b, 8); memcpy(r->r + 16, &pb->c, 8); memcpy(r->r + 24, &pb->d, 8); } bool proto_to_rel_locktime(const Locktime *l, struct rel_locktime *locktime) { switch (l->locktime_case) { case LOCKTIME__LOCKTIME_SECONDS: return seconds_to_rel_locktime(l->seconds, locktime); case LOCKTIME__LOCKTIME_BLOCKS: return blocks_to_rel_locktime(l->blocks, locktime); default: return false; } } bool proto_to_abs_locktime(const Locktime *l, struct abs_locktime *locktime) { switch (l->locktime_case) { case LOCKTIME__LOCKTIME_SECONDS: return seconds_to_abs_locktime(l->seconds, locktime); case LOCKTIME__LOCKTIME_BLOCKS: return blocks_to_abs_locktime(l->blocks, locktime); default: return false; } } Locktime *rel_locktime_to_proto(const tal_t *ctx, const struct rel_locktime *locktime) { Locktime *l = tal(ctx, Locktime); locktime__init(l); if (rel_locktime_is_seconds(locktime)) { l->locktime_case = LOCKTIME__LOCKTIME_SECONDS; l->seconds = rel_locktime_to_seconds(locktime); } else { l->locktime_case = LOCKTIME__LOCKTIME_BLOCKS; l->blocks = rel_locktime_to_blocks(locktime); } return l; } Locktime *abs_locktime_to_proto(const tal_t *ctx, const struct abs_locktime *locktime) { Locktime *l = tal(ctx, Locktime); locktime__init(l); if (abs_locktime_is_seconds(locktime)) { l->locktime_case = LOCKTIME__LOCKTIME_SECONDS; l->seconds = abs_locktime_to_seconds(locktime); } else { l->locktime_case = LOCKTIME__LOCKTIME_BLOCKS; l->blocks = abs_locktime_to_blocks(locktime); } return l; }