#include "../features.c" #include "../memleak.c" #include #include #include #include #include #include /* AUTOGENERATED MOCKS START */ /* Generated stub for amount_asset_extract_value */ u8 *amount_asset_extract_value(const tal_t *ctx UNNEEDED, struct amount_asset *asset UNNEEDED) { fprintf(stderr, "amount_asset_extract_value called!\n"); abort(); } /* Generated stub for amount_asset_is_main */ bool amount_asset_is_main(struct amount_asset *asset UNNEEDED) { fprintf(stderr, "amount_asset_is_main called!\n"); abort(); } /* Generated stub for amount_asset_to_sat */ struct amount_sat amount_asset_to_sat(struct amount_asset *asset UNNEEDED) { fprintf(stderr, "amount_asset_to_sat called!\n"); abort(); } /* Generated stub for amount_sat_add */ bool amount_sat_add(struct amount_sat *val UNNEEDED, struct amount_sat a UNNEEDED, struct amount_sat b UNNEEDED) { fprintf(stderr, "amount_sat_add called!\n"); abort(); } /* Generated stub for amount_sat_eq */ bool amount_sat_eq(struct amount_sat a UNNEEDED, struct amount_sat b UNNEEDED) { fprintf(stderr, "amount_sat_eq called!\n"); abort(); } /* Generated stub for amount_sat_greater_eq */ bool amount_sat_greater_eq(struct amount_sat a UNNEEDED, struct amount_sat b UNNEEDED) { fprintf(stderr, "amount_sat_greater_eq called!\n"); abort(); } /* Generated stub for amount_sat_sub */ bool amount_sat_sub(struct amount_sat *val UNNEEDED, struct amount_sat a UNNEEDED, struct amount_sat b UNNEEDED) { fprintf(stderr, "amount_sat_sub called!\n"); abort(); } /* Generated stub for amount_sat_to_asset */ struct amount_asset amount_sat_to_asset(struct amount_sat *sat UNNEEDED, const u8 *asset UNNEEDED) { fprintf(stderr, "amount_sat_to_asset called!\n"); abort(); } /* Generated stub for amount_tx_fee */ struct amount_sat amount_tx_fee(u32 fee_per_kw UNNEEDED, size_t weight UNNEEDED) { fprintf(stderr, "amount_tx_fee called!\n"); abort(); } /* Generated stub for fromwire */ const u8 *fromwire(const u8 **cursor UNNEEDED, size_t *max UNNEEDED, void *copy UNNEEDED, size_t n UNNEEDED) { fprintf(stderr, "fromwire called!\n"); abort(); } /* Generated stub for fromwire_amount_sat */ struct amount_sat fromwire_amount_sat(const u8 **cursor UNNEEDED, size_t *max UNNEEDED) { fprintf(stderr, "fromwire_amount_sat called!\n"); abort(); } /* Generated stub for fromwire_bool */ bool fromwire_bool(const u8 **cursor UNNEEDED, size_t *max UNNEEDED) { fprintf(stderr, "fromwire_bool called!\n"); abort(); } /* Generated stub for fromwire_fail */ void *fromwire_fail(const u8 **cursor UNNEEDED, size_t *max UNNEEDED) { fprintf(stderr, "fromwire_fail called!\n"); abort(); } /* Generated stub for fromwire_secp256k1_ecdsa_signature */ void fromwire_secp256k1_ecdsa_signature(const u8 **cursor UNNEEDED, size_t *max UNNEEDED, secp256k1_ecdsa_signature *signature UNNEEDED) { fprintf(stderr, "fromwire_secp256k1_ecdsa_signature called!\n"); abort(); } /* Generated stub for fromwire_sha256 */ void fromwire_sha256(const u8 **cursor UNNEEDED, size_t *max UNNEEDED, struct sha256 *sha256 UNNEEDED) { fprintf(stderr, "fromwire_sha256 called!\n"); abort(); } /* Generated stub for fromwire_tal_arrn */ u8 *fromwire_tal_arrn(const tal_t *ctx UNNEEDED, const u8 **cursor UNNEEDED, size_t *max UNNEEDED, size_t num UNNEEDED) { fprintf(stderr, "fromwire_tal_arrn called!\n"); abort(); } /* Generated stub for fromwire_u16 */ u16 fromwire_u16(const u8 **cursor UNNEEDED, size_t *max UNNEEDED) { fprintf(stderr, "fromwire_u16 called!\n"); abort(); } /* Generated stub for fromwire_u32 */ u32 fromwire_u32(const u8 **cursor UNNEEDED, size_t *max UNNEEDED) { fprintf(stderr, "fromwire_u32 called!\n"); abort(); } /* Generated stub for fromwire_u64 */ u64 fromwire_u64(const u8 **cursor UNNEEDED, size_t *max UNNEEDED) { fprintf(stderr, "fromwire_u64 called!\n"); abort(); } /* Generated stub for fromwire_u8 */ u8 fromwire_u8(const u8 **cursor UNNEEDED, size_t *max UNNEEDED) { fprintf(stderr, "fromwire_u8 called!\n"); abort(); } /* Generated stub for towire */ void towire(u8 **pptr UNNEEDED, const void *data UNNEEDED, size_t len UNNEEDED) { fprintf(stderr, "towire called!\n"); abort(); } /* Generated stub for towire_amount_sat */ void towire_amount_sat(u8 **pptr UNNEEDED, const struct amount_sat sat UNNEEDED) { fprintf(stderr, "towire_amount_sat called!\n"); abort(); } /* Generated stub for towire_bool */ void towire_bool(u8 **pptr UNNEEDED, bool v UNNEEDED) { fprintf(stderr, "towire_bool called!\n"); abort(); } /* Generated stub for towire_secp256k1_ecdsa_signature */ void towire_secp256k1_ecdsa_signature(u8 **pptr UNNEEDED, const secp256k1_ecdsa_signature *signature UNNEEDED) { fprintf(stderr, "towire_secp256k1_ecdsa_signature called!\n"); abort(); } /* Generated stub for towire_sha256 */ void towire_sha256(u8 **pptr UNNEEDED, const struct sha256 *sha256 UNNEEDED) { fprintf(stderr, "towire_sha256 called!\n"); abort(); } /* Generated stub for towire_u16 */ void towire_u16(u8 **pptr UNNEEDED, u16 v UNNEEDED) { fprintf(stderr, "towire_u16 called!\n"); abort(); } /* Generated stub for towire_u32 */ void towire_u32(u8 **pptr UNNEEDED, u32 v UNNEEDED) { fprintf(stderr, "towire_u32 called!\n"); abort(); } /* Generated stub for towire_u64 */ void towire_u64(u8 **pptr UNNEEDED, u64 v UNNEEDED) { fprintf(stderr, "towire_u64 called!\n"); abort(); } /* Generated stub for towire_u8 */ void towire_u8(u8 **pptr UNNEEDED, u8 v UNNEEDED) { fprintf(stderr, "towire_u8 called!\n"); abort(); } /* Generated stub for towire_u8_array */ void towire_u8_array(u8 **pptr UNNEEDED, const u8 *arr UNNEEDED, size_t num UNNEEDED) { fprintf(stderr, "towire_u8_array called!\n"); abort(); } /* AUTOGENERATED MOCKS END */ static void test_featurebits_or(void) { u8 *f1 = tal_arr(tmpctx, u8, 0); u8 *f2 = tal_arr(tmpctx, u8, 0); u8 *control = tal_arr(tmpctx, u8, 0); for (size_t i = 0; i < 100; i += 3) { set_feature_bit(&f1, i); set_feature_bit(&control, i); } for (size_t i = 0; i < 10; i += 2) { set_feature_bit(&f2, i); set_feature_bit(&control, i); } u8 *result = featurebits_or(tmpctx, take(f1), f2); assert( memeq(result, tal_bytelen(result), control, tal_bytelen(control))); } static bool feature_set_eq(const struct feature_set *f1, const struct feature_set *f2) { /* We assume minimal sizing */ for (size_t i = 0; i < ARRAY_SIZE(f1->bits); i++) { if (!memeq(f1->bits[i], tal_bytelen(f1->bits[i]), f2->bits[i], tal_bytelen(f2->bits[i]))) return false; } return true; } static void test_feature_set_or(void) { struct feature_set *f1, *f2, *control; /* cppcheck-suppress uninitvar - false positive on f1->bits */ for (size_t i = 0; i < ARRAY_SIZE(f1->bits); i++) { f1 = talz(tmpctx, struct feature_set); f2 = talz(tmpctx, struct feature_set); control = talz(tmpctx, struct feature_set); f1->bits[i] = tal_arr(f1, u8, 0); f2->bits[i] = tal_arr(f2, u8, 0); control->bits[i] = tal_arr(control, u8, 0); /* or with nothing is a nop */ set_feature_bit(&f1->bits[i], 0); set_feature_bit(&control->bits[i], 0); assert(feature_set_or(f1, f2)); assert(feature_set_eq(f1, control)); /* or compulsory with either compulsory or optional is a fail */ set_feature_bit(&f2->bits[i], 0); assert(!feature_set_or(f1, f2)); assert(feature_set_eq(f1, control)); assert(!feature_set_or(f2, f1)); clear_feature_bit(f2->bits[i], 0); set_feature_bit(&f2->bits[i], 1); assert(!feature_set_or(f1, f2)); assert(feature_set_eq(f1, control)); assert(!feature_set_or(f2, f1)); clear_feature_bit(f2->bits[i], 1); set_feature_bit(&f2->bits[i], 10); set_feature_bit(&control->bits[i], 10); assert(feature_set_or(f1, f2)); assert(feature_set_eq(f1, control)); } } int main(void) { u8 *bits; struct feature_set *fset; setup_locale(); wally_init(0); secp256k1_ctx = wally_get_secp_context(); setup_tmpctx(); /* Just some bits to set. */ fset = feature_set_for_feature(tmpctx, OPTIONAL_FEATURE(OPT_DATA_LOSS_PROTECT)); bits = tal_arr(tmpctx, u8, 0); for (size_t i = 0; i < 100; i += 3) set_feature_bit(&bits, i); for (size_t i = 0; i < 100; i++) assert(test_bit(bits, i / 8, i % 8) == ((i % 3) == 0)); for (size_t i = 0; i < 100; i++) assert(feature_is_set(bits, i) == ((i % 3) == 0)); /* Simple test: single byte */ bits = tal_arr(tmpctx, u8, 1); /* Compulsory feature */ bits[0] = (1 << 0); assert(feature_offered(bits, 0)); assert(!feature_offered(bits, 2)); assert(!feature_offered(bits, 8)); assert(!feature_offered(bits, 16)); /* Optional feature */ bits[0] = (1 << 1); assert(feature_offered(bits, 0)); assert(!feature_offered(bits, 2)); assert(!feature_offered(bits, 8)); assert(!feature_offered(bits, 16)); /* Endian-sensitive test: big-endian means we frob last byte here */ bits = tal_arrz(tmpctx, u8, 2); bits[1] = (1 << 0); assert(feature_offered(bits, 0)); assert(!feature_offered(bits, 2)); assert(!feature_offered(bits, 8)); assert(!feature_offered(bits, 16)); /* Optional feature */ bits[1] = (1 << 1); assert(feature_offered(bits, 0)); assert(!feature_offered(bits, 2)); assert(!feature_offered(bits, 8)); assert(!feature_offered(bits, 16)); /* We always support no features. */ memset(bits, 0, tal_count(bits)); assert(features_unsupported(fset, bits, INIT_FEATURE) == -1); /* We must support our own features. */ assert(features_unsupported(fset, fset->bits[INIT_FEATURE], INIT_FEATURE) == -1); /* We can add random odd features, no problem. */ for (size_t i = 1; i < 16; i += 2) { bits = tal_dup_talarr(tmpctx, u8, fset->bits[INIT_FEATURE]); set_feature_bit(&bits, i); assert(features_unsupported(fset, bits, INIT_FEATURE) == -1); } /* We can't add random even features. */ for (size_t i = 0; i < 16; i += 2) { bits = tal_dup_talarr(tmpctx, u8, fset->bits[INIT_FEATURE]); set_feature_bit(&bits, i); /* Special case for missing compulsory feature */ if (i == 2) { assert(features_unsupported(fset, bits, INIT_FEATURE) == i); } else { assert((features_unsupported(fset, bits, INIT_FEATURE) == -1) == feature_offered(fset->bits[INIT_FEATURE], i)); } } test_featurebits_or(); test_feature_set_or(); wally_cleanup(0); tal_free(tmpctx); take_cleanup(); return 0; }