/* test_asn.c * * Copyright (C) 2006-2026 wolfSSL Inc. * * This file is part of wolfSSL. * * wolfSSL is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * wolfSSL is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335, USA */ #include #include #include #include #include #include #include #ifdef HAVE_ED25519 #include #endif #ifdef HAVE_ED448 #include #endif #ifdef HAVE_DILITHIUM #include #endif #if defined(WC_ENABLE_ASYM_KEY_EXPORT) && defined(HAVE_ED25519) static int test_SetAsymKeyDer_once(byte* privKey, word32 privKeySz, byte* pubKey, word32 pubKeySz, byte* trueDer, word32 trueDerSz) { EXPECT_DECLS; byte* calcDer = NULL; word32 calcDerSz = 0; ExpectIntEQ(calcDerSz = SetAsymKeyDer(privKey, privKeySz, pubKey, pubKeySz, NULL, 0, ED25519k), trueDerSz); ExpectNotNull(calcDer = (byte*)XMALLOC(calcDerSz, NULL, DYNAMIC_TYPE_TMP_BUFFER)); ExpectIntEQ(calcDerSz = SetAsymKeyDer(privKey, privKeySz, pubKey, pubKeySz, calcDer, calcDerSz, ED25519k), trueDerSz); ExpectIntEQ(XMEMCMP(calcDer, trueDer, trueDerSz), 0); XFREE(calcDer, NULL, DYNAMIC_TYPE_TMP_BUFFER); return EXPECT_RESULT(); } #endif /* WC_ENABLE_ASYM_KEY_EXPORT && HAVE_ED25519 */ int test_SetAsymKeyDer(void) { EXPECT_DECLS; #if defined(WC_ENABLE_ASYM_KEY_EXPORT) && defined(HAVE_ED25519) /* We can't access the keyEd25519Oid variable, so declare it instead */ byte algId[] = {43, 101, 112}; /* RFC 5958: version is v1 (0) for private only, v2 (1) when public key * bundled. Conditions 1-5 are private only, 6-8 include pub key and * mutate version[0] = 0x1 before building trueDer. */ byte version[] = {0x0}; byte keyPat = 0xcc; byte* privKey = NULL; word32 privKeySz = 0; byte* pubKey = NULL; word32 pubKeySz = 0; byte trueDer[310]; /* The largest size is 310 bytes on Condition 8 */ word32 trueDerSz = 0; /* * Condition 1: * PKEY data = 34 (1 to 127) * PKEY_CURVEPKEY data = 32 (1 to 127) * PUBKEY data = 0 (Empty) * SEQ data = 46 (1 to 127) */ privKeySz = 32; pubKeySz = 0; trueDerSz = 48; /* SEQ */ trueDer[0] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[1] = trueDerSz - 2; /* VER */ trueDer[2] = ASN_INTEGER; trueDer[3] = sizeof(version); trueDer[4] = version[0]; /* PKEYALGO_SEQ */ trueDer[5] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[6] = sizeof(algId) + 2; trueDer[7] = ASN_OBJECT_ID; trueDer[8] = sizeof(algId); trueDer[9] = algId[0]; trueDer[10] = algId[1]; trueDer[11] = algId[2]; /* PKEY */ trueDer[12] = ASN_OCTET_STRING; trueDer[13] = privKeySz + 2; trueDer[14] = ASN_OCTET_STRING; trueDer[15] = privKeySz; privKey = &trueDer[16]; XMEMSET(privKey, keyPat, privKeySz); /* trueDer[16] to trueDer[47] */ /* PUBKEY */ pubKey = NULL; /* Empty */ EXPECT_TEST(test_SetAsymKeyDer_once(privKey, privKeySz, pubKey, pubKeySz, trueDer, trueDerSz)); /* * Condition 2: * PKEY data = 129 (128 to 255) * PKEY_CURVEKEY data = 127 (0 to 127) * PUBKEY data = 0 (Empty) * SEQ data = 142 (128 to 255) */ privKeySz = 127; pubKeySz = 0; trueDerSz = 145; /* SEQ */ trueDer[0] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[1] = 0x81; trueDer[2] = trueDerSz - 3; /* VER */ trueDer[3] = ASN_INTEGER; trueDer[4] = sizeof(version); trueDer[5] = version[0]; /* PKEYALGO_SEQ */ trueDer[6] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[7] = sizeof(algId) + 2; trueDer[8] = ASN_OBJECT_ID; trueDer[9] = sizeof(algId); trueDer[10] = algId[0]; trueDer[11] = algId[1]; trueDer[12] = algId[2]; /* PKEY */ trueDer[13] = ASN_OCTET_STRING; trueDer[14] = 0x81; trueDer[15] = privKeySz + 2; trueDer[16] = ASN_OCTET_STRING; trueDer[17] = privKeySz; privKey = &trueDer[18]; XMEMSET(privKey, keyPat, privKeySz); /* trueDer[18] to trueDer[144] */ /* PUBKEY */ pubKey = NULL; /* Empty */ EXPECT_TEST(test_SetAsymKeyDer_once(privKey, privKeySz, pubKey, pubKeySz, trueDer, trueDerSz)); /* * Condition 3: * PKEY data = 131 (128 to 255) * PKEY_CURVEKEY = 128 (128 to 255) * PUBKEY data = 0 (Empty) * SEQ data =144 (128 to 255) */ privKeySz = 128; pubKeySz = 0; trueDerSz = 147; /* SEQ */ trueDer[0] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[1] = 0x81; trueDer[2] = trueDerSz - 3; /* VER */ trueDer[3] = ASN_INTEGER; trueDer[4] = sizeof(version); trueDer[5] = version[0]; /* PKEYALGO_SEQ */ trueDer[6] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[7] = sizeof(algId) + 2; trueDer[8] = ASN_OBJECT_ID; trueDer[9] = sizeof(algId); trueDer[10] = algId[0]; trueDer[11] = algId[1]; trueDer[12] = algId[2]; /* PKEY */ trueDer[13] = ASN_OCTET_STRING; trueDer[14] = 0x81; trueDer[15] = privKeySz + 3; trueDer[16] = ASN_OCTET_STRING; trueDer[17] = 0x81; trueDer[18] = privKeySz; privKey = &trueDer[19]; XMEMSET(privKey, keyPat, privKeySz); /* trueDer[19] to trueDer[146] */ /* PUBKEY */ pubKey = NULL; /* Empty */ EXPECT_TEST(test_SetAsymKeyDer_once(privKey, privKeySz, pubKey, pubKeySz, trueDer, trueDerSz)); /* * Condition 4: * PKEY data = 258 (256 to 65535) * PKEY_CURVEPKEY data = 255 (128 to 255) * PUBKEY data = 0 (Empty) * SEQ data = 272 (256 to 65536) */ privKeySz = 255; pubKeySz = 0; trueDerSz = 276; /* SEQ */ trueDer[0] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[1] = 0x82; trueDer[2] = ((trueDerSz - 4) >> 8) & 0xff; trueDer[3] = (trueDerSz - 4) & 0xff; /* VER */ trueDer[4] = ASN_INTEGER; trueDer[5] = sizeof(version); trueDer[6] = version[0]; /* PKEYALGO_SEQ */ trueDer[7] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[8] = sizeof(algId) + 2; trueDer[9] = ASN_OBJECT_ID; trueDer[10] = sizeof(algId); trueDer[11] = algId[0]; trueDer[12] = algId[1]; trueDer[13] = algId[2]; /* PKEY */ trueDer[14] = ASN_OCTET_STRING; trueDer[15] = 0x82; trueDer[16] = ((privKeySz + 3) >> 8) & 0xff; trueDer[17] = (privKeySz + 3) & 0xff; trueDer[18] = ASN_OCTET_STRING; trueDer[19] = 0x81; trueDer[20] = privKeySz; privKey = &trueDer[21]; XMEMSET(privKey, keyPat, privKeySz); /* trueDer[21] to trueDer[275] */ /* PUBKEY */ pubKey = NULL; /* Empty */ EXPECT_TEST(test_SetAsymKeyDer_once(privKey, privKeySz, pubKey, pubKeySz, trueDer, trueDerSz)); /* * Condition 5: * PKEY data = 260 (256 to 65535) * PKEY_CURVEPKEY data = 256 (256 to 65535) * PUBKEY data = 0 (Empty) * SEQ data = 274 (256 to 65535) */ privKeySz = 256; pubKeySz = 0; trueDerSz = 278; /* SEQ */ trueDer[0] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[1] = 0x82; trueDer[2] = ((trueDerSz - 4) >> 8) & 0xff; trueDer[3] = (trueDerSz - 4) & 0xff; /* VER */ trueDer[4] = ASN_INTEGER; trueDer[5] = sizeof(version); trueDer[6] = version[0]; /* PKEYALGO_SEQ */ trueDer[7] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[8] = sizeof(algId) + 2; trueDer[9] = ASN_OBJECT_ID; trueDer[10] = sizeof(algId); trueDer[11] = algId[0]; trueDer[12] = algId[1]; trueDer[13] = algId[2]; /* PKEY */ trueDer[14] = ASN_OCTET_STRING; trueDer[15] = 0x82; trueDer[16] = ((privKeySz + 4) >> 8) & 0xff; trueDer[17] = (privKeySz + 4) & 0xff; trueDer[18] = ASN_OCTET_STRING; trueDer[19] = 0x82; trueDer[20] = (privKeySz >> 8) & 0xff; trueDer[21] = privKeySz & 0xff; privKey = &trueDer[22]; XMEMSET(privKey, keyPat, privKeySz); /* trueDer[22] to trueDer[277] */ /* PUBKEY */ pubKey = NULL; /* Empty */ EXPECT_TEST(test_SetAsymKeyDer_once(privKey, privKeySz, pubKey, pubKeySz, trueDer, trueDerSz)); /* * Condition 6: * PKEY data = 34 (1 to 127) * PKEY_CURVEPKEY data = 32 (1 to 127) * PUBKEY data = 32 (1 to 127) * SEQ data = 80 (1 to 127) */ privKeySz = 32; pubKeySz = 32; trueDerSz = 82; version[0] = 0x1; /* publicKey present (v2) */ /* SEQ */ trueDer[0] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[1] = trueDerSz - 2; /* VER */ trueDer[2] = ASN_INTEGER; trueDer[3] = sizeof(version); trueDer[4] = version[0]; /* PKEYALGO_SEQ */ trueDer[5] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[6] = sizeof(algId) + 2; trueDer[7] = ASN_OBJECT_ID; trueDer[8] = sizeof(algId); trueDer[9] = algId[0]; trueDer[10] = algId[1]; trueDer[11] = algId[2]; /* PKEY */ trueDer[12] = ASN_OCTET_STRING; trueDer[13] = privKeySz + 2; trueDer[14] = ASN_OCTET_STRING; trueDer[15] = privKeySz; privKey = &trueDer[16]; XMEMSET(privKey, keyPat, privKeySz); /* trueDer[16] to trueDer[47] */ /* PUBKEY */ trueDer[48] = ASN_CONTEXT_SPECIFIC | ASN_ASYMKEY_PUBKEY; trueDer[49] = pubKeySz; pubKey = &trueDer[50]; XMEMSET(pubKey, keyPat, pubKeySz); /* trueDer[50] to trueDer[81] */ EXPECT_TEST(test_SetAsymKeyDer_once(privKey, privKeySz, pubKey, pubKeySz, trueDer, trueDerSz)); /* * Condition 7: * PKEY data = 34 (1 to 127) * PKEY_CURVEPKEY data = 32 (1 to 127) * PUBKEY data = 128 (128 to 255) * SEQ data = 180 (128 to 255) */ privKeySz = 32; pubKeySz = 128; trueDerSz = 180; version[0] = 0x1; /* publicKey present (v2) */ /* SEQ */ trueDer[0] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[1] = 0x81; trueDer[2] = trueDerSz - 3; /* VER */ trueDer[3] = ASN_INTEGER; trueDer[4] = sizeof(version); trueDer[5] = version[0]; /* PKEYALGO_SEQ */ trueDer[6] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[7] = sizeof(algId) + 2; trueDer[8] = ASN_OBJECT_ID; trueDer[9] = sizeof(algId); trueDer[10] = algId[0]; trueDer[11] = algId[1]; trueDer[12] = algId[2]; /* PKEY */ trueDer[13] = ASN_OCTET_STRING; trueDer[14] = privKeySz + 2; trueDer[15] = ASN_OCTET_STRING; trueDer[16] = privKeySz; privKey = &trueDer[17]; XMEMSET(privKey, keyPat, privKeySz); /* trueDer[17] to trueDer[48] */ /* PUBKEY */ trueDer[49] = ASN_CONTEXT_SPECIFIC | ASN_ASYMKEY_PUBKEY; trueDer[50] = 0x81; trueDer[51] = pubKeySz; pubKey = &trueDer[52]; XMEMSET(pubKey, keyPat, pubKeySz); /* trueDer[52] to trueDer[179] */ EXPECT_TEST(test_SetAsymKeyDer_once(privKey, privKeySz, pubKey, pubKeySz, trueDer, trueDerSz)); /* * Condition 8: * PKEY data = 34 (1 to 127) * PKEY_CURVEPKEY data = 32 (1 to 127) * PUBKEY data = 256 (256 to 65535) * SEQ data = 306 (256 to 65535) */ privKeySz = 32; pubKeySz = 256; trueDerSz = 310; version[0] = 0x1; /* publicKey present (v2) */ /* SEQ */ trueDer[0] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[1] = 0x82; trueDer[2] = ((trueDerSz - 4) >> 8) & 0xff; trueDer[3] = (trueDerSz - 4) & 0xff; /* VER */ trueDer[4] = ASN_INTEGER; trueDer[5] = sizeof(version); trueDer[6] = version[0]; /* PKEYALGO_SEQ */ trueDer[7] = ASN_SEQUENCE | ASN_CONSTRUCTED; trueDer[8] = sizeof(algId) + 2; trueDer[9] = ASN_OBJECT_ID; trueDer[10] = sizeof(algId); trueDer[11] = algId[0]; trueDer[12] = algId[1]; trueDer[13] = algId[2]; /* PKEY */ trueDer[14] = ASN_OCTET_STRING; trueDer[15] = privKeySz + 2; trueDer[16] = ASN_OCTET_STRING; trueDer[17] = privKeySz; privKey = &trueDer[18]; XMEMSET(privKey, keyPat, privKeySz); /* trueDer[18] to trueDer[49] */ /* PUBKEY */ trueDer[50] = ASN_CONTEXT_SPECIFIC | ASN_ASYMKEY_PUBKEY; trueDer[51] = 0x82; trueDer[52] = (pubKeySz >> 8) & 0xff; trueDer[53] = pubKeySz & 0xff; pubKey = &trueDer[54]; XMEMSET(pubKey, keyPat, pubKeySz); /* trueDer[54] to trueDer[309] */ EXPECT_TEST(test_SetAsymKeyDer_once(privKey, privKeySz, pubKey, pubKeySz, trueDer, trueDerSz)); #endif /* WC_ENABLE_ASYM_KEY_EXPORT && HAVE_ED25519 */ return EXPECT_RESULT(); } /* RFC 5958 leniency: parser must accept all four variants: * {v=0,v=1} x {publicKey absent, present}. */ int test_DecodeAsymKey_lenient_versions(void) { EXPECT_DECLS; #if defined(HAVE_ED25519) && defined(HAVE_ED25519_KEY_EXPORT) && \ defined(HAVE_ED25519_KEY_IMPORT) && defined(WOLFSSL_KEY_GEN) ed25519_key key; ed25519_key parsed; WC_RNG rng; byte bundled[256]; /* v=1 + publicKey */ byte privOnly[256]; /* v=0, no publicKey */ byte tmp[256]; int bundledSz = 0; int privOnlySz = 0; word32 idx; XMEMSET(&key, 0, sizeof(key)); XMEMSET(&parsed, 0, sizeof(parsed)); XMEMSET(&rng, 0, sizeof(rng)); ExpectIntEQ(wc_InitRng(&rng), 0); ExpectIntEQ(wc_ed25519_init(&key), 0); ExpectIntEQ(wc_ed25519_make_key(&rng, ED25519_KEY_SIZE, &key), 0); ExpectIntGT(bundledSz = wc_Ed25519KeyToDer(&key, bundled, (word32)sizeof(bundled)), 0); ExpectIntGT(privOnlySz = wc_Ed25519PrivateKeyToDer(&key, privOnly, (word32)sizeof(privOnly)), 0); if (EXPECT_SUCCESS() && ((bundledSz > 0) && ((size_t)bundledSz <= sizeof(bundled)) && (privOnlySz > 0) && ((size_t)privOnlySz <= sizeof(privOnly)))) { /* v=1 + publicKey */ XMEMCPY(tmp, bundled, (size_t)bundledSz); XMEMSET(&parsed, 0, sizeof(parsed)); ExpectIntEQ(wc_ed25519_init(&parsed), 0); idx = 0; ExpectIntEQ(wc_Ed25519PrivateKeyDecode(tmp, &idx, &parsed, (word32)bundledSz), 0); wc_ed25519_free(&parsed); /* v=0 + publicKey: patch version byte, [1] publicKey field present. */ XMEMCPY(tmp, bundled, (size_t)bundledSz); ExpectIntGT(test_pkcs8_patch_version_byte(tmp, (word32)bundledSz, 0), 0); XMEMSET(&parsed, 0, sizeof(parsed)); ExpectIntEQ(wc_ed25519_init(&parsed), 0); idx = 0; ExpectIntEQ(wc_Ed25519PrivateKeyDecode(tmp, &idx, &parsed, (word32)bundledSz), 0); wc_ed25519_free(&parsed); /* v=0, no publicKey */ XMEMCPY(tmp, privOnly, (size_t)privOnlySz); XMEMSET(&parsed, 0, sizeof(parsed)); ExpectIntEQ(wc_ed25519_init(&parsed), 0); idx = 0; ExpectIntEQ(wc_Ed25519PrivateKeyDecode(tmp, &idx, &parsed, (word32)privOnlySz), 0); wc_ed25519_free(&parsed); /* v=1, no publicKey */ XMEMCPY(tmp, privOnly, (size_t)privOnlySz); ExpectIntGT(test_pkcs8_patch_version_byte(tmp, (word32)privOnlySz, 1), 0); XMEMSET(&parsed, 0, sizeof(parsed)); ExpectIntEQ(wc_ed25519_init(&parsed), 0); idx = 0; ExpectIntEQ(wc_Ed25519PrivateKeyDecode(tmp, &idx, &parsed, (word32)privOnlySz), 0); wc_ed25519_free(&parsed); } wc_ed25519_free(&key); wc_FreeRng(&rng); #endif return EXPECT_RESULT(); } int test_DecodeAsymKey_negative(void) { EXPECT_DECLS; #if defined(HAVE_ED25519) && defined(HAVE_ED25519_KEY_EXPORT) && \ defined(HAVE_ED25519_KEY_IMPORT) && defined(WOLFSSL_KEY_GEN) ed25519_key key; ed25519_key parsed; WC_RNG rng; byte good[256]; byte tmp[256]; int goodSz = 0; word32 idx; XMEMSET(&key, 0, sizeof(key)); XMEMSET(&parsed, 0, sizeof(parsed)); XMEMSET(&rng, 0, sizeof(rng)); ExpectIntEQ(wc_InitRng(&rng), 0); ExpectIntEQ(wc_ed25519_init(&key), 0); ExpectIntEQ(wc_ed25519_make_key(&rng, ED25519_KEY_SIZE, &key), 0); ExpectIntGT(goodSz = wc_Ed25519KeyToDer(&key, good, (word32)sizeof(good)), 0); if (EXPECT_SUCCESS() && (goodSz > 0 && (size_t)goodSz <= sizeof(good))) { /* Truncated buffer */ XMEMCPY(tmp, good, (size_t)goodSz); ExpectIntEQ(wc_ed25519_init(&parsed), 0); idx = 0; ExpectIntLT(wc_Ed25519PrivateKeyDecode(tmp, &idx, &parsed, (word32)(goodSz - 1)), 0); wc_ed25519_free(&parsed); /* Outer length too big. Patch low-order length byte (long form: bump * the last byte of the multi-byte length encoding). */ XMEMCPY(tmp, good, (size_t)goodSz); if ((good[1] & 0x80) == 0) { tmp[1] = (byte)(good[1] + 1); } else { word32 nBytes = (word32)(good[1] & 0x7F); tmp[1 + nBytes] = (byte)(good[1 + nBytes] + 1); } XMEMSET(&parsed, 0, sizeof(parsed)); ExpectIntEQ(wc_ed25519_init(&parsed), 0); idx = 0; ExpectIntLT(wc_Ed25519PrivateKeyDecode(tmp, &idx, &parsed, (word32)goodSz), 0); wc_ed25519_free(&parsed); /* Outer tag not SEQUENCE */ XMEMCPY(tmp, good, (size_t)goodSz); tmp[0] = 0x02; XMEMSET(&parsed, 0, sizeof(parsed)); ExpectIntEQ(wc_ed25519_init(&parsed), 0); idx = 0; ExpectIntLT(wc_Ed25519PrivateKeyDecode(tmp, &idx, &parsed, (word32)goodSz), 0); wc_ed25519_free(&parsed); } wc_ed25519_free(&key); wc_FreeRng(&rng); #endif return EXPECT_RESULT(); } #ifndef NO_ASN static int test_GetSetShortInt_once(word32 val, byte* valDer, word32 valDerSz) { EXPECT_DECLS; #ifndef NO_PWDBASED #if !defined(WOLFSSL_ASN_TEMPLATE) || defined(HAVE_PKCS8) || \ defined(HAVE_PKCS12) byte outDer[MAX_SHORT_SZ]; word32 outDerSz = 0; word32 inOutIdx = 0; word32 maxIdx = MAX_SHORT_SZ; int value; ExpectIntLE(2 + valDerSz, MAX_SHORT_SZ); ExpectIntEQ(outDerSz = SetShortInt(outDer, &inOutIdx, val, maxIdx), 2 + valDerSz); ExpectIntEQ(outDer[0], ASN_INTEGER); ExpectIntEQ(outDer[1], valDerSz); ExpectIntEQ(XMEMCMP(outDer + 2, valDer, valDerSz), 0); if (val < 0x80000000) { /* GetShortInt only supports positive values. */ inOutIdx = 0; ExpectIntEQ(val, GetShortInt(outDer, &inOutIdx, &value, maxIdx)); } #endif /* !WOLFSSL_ASN_TEMPLATE || HAVE_PKCS8 || HAVE_PKCS12 */ #endif /* !NO_PWDBASED */ (void)val; (void)valDer; (void)valDerSz; return EXPECT_RESULT(); } #endif int test_GetSetShortInt(void) { EXPECT_DECLS; #ifndef NO_ASN byte valDer[MAX_SHORT_SZ] = {0}; /* Corner tests for input size */ { /* Input 1 byte min */ valDer[0] = 0x00; EXPECT_TEST(test_GetSetShortInt_once(0x00, valDer, 1)); /* Input 1 byte max */ valDer[0] = 0x00; valDer[1] = 0xff; EXPECT_TEST(test_GetSetShortInt_once(0xff, valDer, 2)); /* Input 2 bytes min */ valDer[0] = 0x01; valDer[1] = 0x00; EXPECT_TEST(test_GetSetShortInt_once(0x0100, valDer, 2)); /* Input 2 bytes max */ valDer[0] = 0x00; valDer[1] = 0xff; valDer[2] = 0xff; EXPECT_TEST(test_GetSetShortInt_once(0xffff, valDer, 3)); /* Input 3 bytes min */ valDer[0] = 0x01; valDer[1] = 0x00; valDer[2] = 0x00; EXPECT_TEST(test_GetSetShortInt_once(0x010000, valDer, 3)); /* Input 3 bytes max */ valDer[0] = 0x00; valDer[1] = 0xff; valDer[2] = 0xff; valDer[3] = 0xff; EXPECT_TEST(test_GetSetShortInt_once(0xffffff, valDer, 4)); /* Input 4 bytes min */ valDer[0] = 0x01; valDer[1] = 0x00; valDer[2] = 0x00; valDer[3] = 0x00; EXPECT_TEST(test_GetSetShortInt_once(0x01000000, valDer, 4)); /* Input 4 bytes max */ valDer[0] = 0x00; valDer[1] = 0xff; valDer[2] = 0xff; valDer[3] = 0xff; valDer[4] = 0xff; EXPECT_TEST(test_GetSetShortInt_once(0xffffffff, valDer, 5)); } /* Corner tests for output size */ { /* Skip "Output 1 byte min" because of same as "Input 1 byte min" */ /* Output 1 byte max */ valDer[0] = 0x7f; EXPECT_TEST(test_GetSetShortInt_once(0x7f, valDer, 1)); /* Output 2 bytes min */ valDer[0] = 0x00; valDer[1] = 0x80; EXPECT_TEST(test_GetSetShortInt_once(0x80, valDer, 2)); /* Output 2 bytes max */ valDer[0] = 0x7f; valDer[1] = 0xff; EXPECT_TEST(test_GetSetShortInt_once(0x7fff, valDer, 2)); /* Output 3 bytes min */ valDer[0] = 0x00; valDer[1] = 0x80; valDer[2] = 0x00; EXPECT_TEST(test_GetSetShortInt_once(0x8000, valDer, 3)); /* Output 3 bytes max */ valDer[0] = 0x7f; valDer[1] = 0xff; valDer[2] = 0xff; EXPECT_TEST(test_GetSetShortInt_once(0x7fffff, valDer, 3)); /* Output 4 bytes min */ valDer[0] = 0x00; valDer[1] = 0x80; valDer[2] = 0x00; valDer[3] = 0x00; EXPECT_TEST(test_GetSetShortInt_once(0x800000, valDer, 4)); /* Output 4 bytes max */ valDer[0] = 0x7f; valDer[1] = 0xff; valDer[2] = 0xff; valDer[3] = 0xff; EXPECT_TEST(test_GetSetShortInt_once(0x7fffffff, valDer, 4)); /* Output 5 bytes min */ valDer[0] = 0x00; valDer[1] = 0x80; valDer[2] = 0x00; valDer[3] = 0x00; valDer[4] = 0x00; EXPECT_TEST(test_GetSetShortInt_once(0x80000000, valDer, 5)); /* Skip "Output 5 bytes max" because of same as "Input 4 bytes max" */ } /* Extra tests */ { valDer[0] = 0x01; EXPECT_TEST(test_GetSetShortInt_once(0x01, valDer, 1)); } #if !defined(NO_PWDBASED) || defined(WOLFSSL_ASN_EXTRA) /* Negative INTEGER values. */ { word32 idx = 0; int value; valDer[0] = ASN_INTEGER; valDer[1] = 1; valDer[2] = 0x80; ExpectIntEQ(GetShortInt(valDer, &idx, &value, 3), WC_NO_ERR_TRACE(ASN_EXPECT_0_E)); idx = 0; valDer[0] = ASN_INTEGER; valDer[1] = 4; valDer[2] = 0xFF; valDer[3] = 0xFF; valDer[4] = 0xFF; valDer[5] = 0xFF; ExpectIntEQ(GetShortInt(valDer, &idx, &value, 6), WC_NO_ERR_TRACE(ASN_EXPECT_0_E)); } #if (!defined(HAVE_SELFTEST) && !defined(HAVE_FIPS)) || \ (defined(HAVE_FIPS_VERSION) && (HAVE_FIPS_VERSION > 2)) /* zero length value. should return ASN_PARSE_E */ { word32 idx = 0; int value = 0; valDer[0] = ASN_INTEGER; valDer[1] = 0x00; ExpectIntEQ(GetShortInt(valDer, &idx, &value, 2), WC_NO_ERR_TRACE(ASN_PARSE_E)); } #endif /* */ #endif /* !NO_PWDBASED || WOLFSSL_ASN_EXTRA */ #endif return EXPECT_RESULT(); } int test_wc_IndexSequenceOf(void) { EXPECT_DECLS; #ifndef NO_ASN const byte int_seq[] = { 0x30, 0x0A, 0x02, 0x01, 0x0A, 0x02, 0x02, 0x00, 0xF0, 0x02, 0x01, 0x7F, }; const byte bad_seq[] = { 0xA0, 0x01, 0x01, }; const byte empty_seq[] = { 0x30, 0x00, }; const byte * element; word32 elementSz; ExpectIntEQ(wc_IndexSequenceOf(int_seq, sizeof(int_seq), 0U, &element, &elementSz), 0); ExpectPtrEq(element, &int_seq[2]); ExpectIntEQ(elementSz, 3); ExpectIntEQ(wc_IndexSequenceOf(int_seq, sizeof(int_seq), 1U, &element, &elementSz), 0); ExpectPtrEq(element, &int_seq[5]); ExpectIntEQ(elementSz, 4); ExpectIntEQ(wc_IndexSequenceOf(int_seq, sizeof(int_seq), 2U, &element, &elementSz), 0); ExpectPtrEq(element, &int_seq[9]); ExpectIntEQ(elementSz, 3); ExpectIntEQ(wc_IndexSequenceOf(int_seq, sizeof(int_seq), 3U, &element, &elementSz), WC_NO_ERR_TRACE(BAD_INDEX_E)); ExpectIntEQ(wc_IndexSequenceOf(bad_seq, sizeof(bad_seq), 0U, &element, &elementSz), WC_NO_ERR_TRACE(ASN_PARSE_E)); ExpectIntEQ(wc_IndexSequenceOf(empty_seq, sizeof(empty_seq), 0U, &element, &elementSz), WC_NO_ERR_TRACE(BAD_INDEX_E)); #endif return EXPECT_RESULT(); } int test_wolfssl_local_MatchBaseName(void) { EXPECT_DECLS; #if !defined(NO_CERTS) && !defined(NO_ASN) && !defined(IGNORE_NAME_CONSTRAINTS) /* * Tests for DNS type (ASN_DNS_TYPE = 0x02) */ /* Positive tests - should match */ /* Exact match */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "domain.com", 10, "domain.com", 10), 1); /* Case insensitive match */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "DOMAIN.COM", 10, "domain.com", 10), 1); /* Subdomain match (RFC 5280: adding labels to the left) */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "sub.domain.com", 14, "domain.com", 10), 1); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "a.b.domain.com", 14, "domain.com", 10), 1); /* Leading dot constraint with subdomain (not RFC 5280 compliant for DNS, * but kept for backwards compatibility) */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "sub.domain.com", 14, ".domain.com", 11), 1); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "a.b.domain.com", 14, ".domain.com", 11), 1); /* Trailing-dot normalization: absolute DNS form is equivalent. */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "domain.com.", (int)XSTRLEN("domain.com."), "domain.com", (int)XSTRLEN("domain.com")), 1); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "domain.com", (int)XSTRLEN("domain.com"), "domain.com.", (int)XSTRLEN("domain.com.")), 1); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "domain.com.", (int)XSTRLEN("domain.com."), "domain.com.", (int)XSTRLEN("domain.com.")), 1); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "sub.domain.com.", (int)XSTRLEN("sub.domain.com."), ".domain.com.", (int)XSTRLEN(".domain.com.")), 1); /* Negative tests - should NOT match */ /* Bug #3: fakedomain.com should NOT match domain.com (no dot boundary) */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "fakedomain.com", 14, "domain.com", 10), 0); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "notdomain.com", 13, "domain.com", 10), 0); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "xexample.com", 12, "example.com", 11), 0); /* Bug #3: fakedomain.com should NOT match .domain.com */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "fakedomain.com", 14, ".domain.com", 11), 0); /* domain.com should NOT match .domain.com (leading dot requires subdomain) */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "domain.com", 10, ".domain.com", 11), 0); /* Different domain */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "other.com", 9, "domain.com", 10), 0); /* Name starting with dot */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, ".domain.com", 11, "domain.com", 10), 0); /* More than one trailing dot leaves an empty label after normalization. */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "domain.com..", (int)XSTRLEN("domain.com.."), "domain.com", (int)XSTRLEN("domain.com")), 0); /* * Tests for email type (ASN_RFC822_TYPE = 0x01) */ /* Positive tests - should match */ /* Exact email match */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@domain.com", 15, "user@domain.com", 15), 1); /* Email with domain constraint (leading dot) - subdomain present */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@sub.domain.com", 19, ".domain.com", 11), 1); /* Email with domain constraint (no leading dot) - exact domain */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@domain.com", 15, "domain.com", 10), 1); /* Negative tests - should NOT match */ /* user@domain.com should NOT match .domain.com (subdomain required) */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@domain.com", 15, ".domain.com", 11), 0); /* user@sub.domain.com should NOT match domain.com (exact domain only) */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@sub.domain.com", 19, "domain.com", 10), 0); /* @ at start is invalid */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "@domain.com", 11, ".domain.com", 11), 0); /* @ at end is invalid */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@", 5, ".domain.com", 11), 0); /* double @ is invalid */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@@domain.com", 16, ".domain.com", 11), 0); /* multiple @ is invalid */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@domain@extra.com", 21, ".domain.com", 11), 0); /* No @ in email name */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "userdomain.com", 14, ".domain.com", 11), 0); /* Email domain doesn't match constraint */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@other.com", 14, ".domain.com", 11), 0); /* Email suffix without dot boundary (fakedomain) */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@fakedomain.com", 19, ".domain.com", 11), 0); /* Base constraint with invalid @ position */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@domain.com", 15, "@domain.com", 11), 0); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_RFC822_TYPE, "user@domain.com", 15, "user@", 5), 0); /* * Tests for directory type (ASN_DIR_TYPE = 0x04) */ /* Positive tests - should match */ /* Exact match */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DIR_TYPE, "CN=test", 7, "CN=test", 7), 1); /* Prefix match (name longer than base) */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DIR_TYPE, "CN=test,O=org", 13, "CN=test", 7), 1); /* Negative tests - should NOT match */ /* Different content */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DIR_TYPE, "CN=other", 8, "CN=test", 7), 0); /* Case sensitive for directory */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DIR_TYPE, "CN=TEST", 7, "CN=test", 7), 0); /* * Edge cases and error handling */ /* NULL pointers */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, NULL, 10, "domain.com", 10), 0); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "domain.com", 10, NULL, 10), 0); /* Empty/zero size */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "", 0, "domain.com", 10), 0); ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "domain.com", 10, "", 0), 0); /* Invalid type */ ExpectIntEQ(wolfssl_local_MatchBaseName(0xFF, "domain.com", 10, "domain.com", 10), 0); /* Name starting with dot */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, ".", 1, ".", 1), 0); /* Name shorter than base */ ExpectIntEQ(wolfssl_local_MatchBaseName(ASN_DNS_TYPE, "a.com", 5, "domain.com", 10), 0); #endif /* !NO_CERTS && !NO_ASN && !IGNORE_NAME_CONSTRAINTS */ return EXPECT_RESULT(); } #if !defined(NO_CERTS) && !defined(NO_ASN) && !defined(IGNORE_NAME_CONSTRAINTS) /* Convenience wrappers so the cases below read as (name, base) pairs and the * string lengths can't drift out of sync with the literals. */ static int dnsWildPermitted(const char* name, const char* base) { return wolfssl_local_MatchDnsConstraintWildcard(name, (int)XSTRLEN(name), base, (int)XSTRLEN(base), 1); } static int dnsWildExcluded(const char* name, const char* base) { return wolfssl_local_MatchDnsConstraintWildcard(name, (int)XSTRLEN(name), base, (int)XSTRLEN(base), 0); } static int uriNC(const char* uri, const char* base) { return wolfssl_local_MatchUriNameConstraint(uri, (int)XSTRLEN(uri), base, (int)XSTRLEN(base)); } #endif /* * Tests label-aware matching of a wildcard DNS SAN against a name-constraint * subtree. The permitted variant must prove containment (every expansion of * the wildcard stays inside the subtree); the excluded variant must detect * intersection (some expansion falls inside the subtree). A '*' never crosses * a label boundary, so the comparison is by label from the right. */ int test_wolfssl_local_MatchDnsConstraintWildcard(void) { EXPECT_DECLS; #if !defined(NO_CERTS) && !defined(NO_ASN) && !defined(IGNORE_NAME_CONSTRAINTS) /* * PERMITTED subtree -- containment. Accept only when EVERY expansion of * the wildcard is inside the base subtree. */ /* Wildcard is an extra label to the left of the base: always contained. */ ExpectIntEQ(dnsWildPermitted("*.example.com", "example.com"), 1); ExpectIntEQ(dnsWildPermitted("*.sub.example.com", "example.com"), 1); ExpectIntEQ(dnsWildPermitted("foo*.example.com", "example.com"), 1); ExpectIntEQ(dnsWildPermitted("a*b.example.com", "example.com"), 1); /* Case-insensitive on the literal tail labels. */ ExpectIntEQ(dnsWildPermitted("*.EXAMPLE.CoM", "example.com"), 1); /* Single-label base; the matched tail "com" is literal. */ ExpectIntEQ(dnsWildPermitted("*.example.com", "com"), 1); /* Leading-dot base requires at least one label before it -- the wildcard * label satisfies that. */ ExpectIntEQ(dnsWildPermitted("*.example.com", ".example.com"), 1); ExpectIntEQ(dnsWildPermitted("*.sub.example.com", ".example.com"), 1); /* Trailing-dot normalization: absolute DNS form is equivalent. */ ExpectIntEQ(dnsWildPermitted("*.example.com.", "example.com"), 1); ExpectIntEQ(dnsWildPermitted("*.example.com", "example.com."), 1); ExpectIntEQ(dnsWildPermitted("*.example.com.", "example.com."), 1); ExpectIntEQ(dnsWildPermitted("*.example.com.", ".example.com."), 1); /* Wildcard lands on a label that must equal the base: NOT provably * contained, because the label can expand to something else. */ ExpectIntEQ(dnsWildPermitted("*.example.com", "foo.example.com"), 0); ExpectIntEQ(dnsWildPermitted("*.example.com.", "foo.example.com"), 0); ExpectIntEQ(dnsWildPermitted("*.example.com", "foo.example.com."), 0); ExpectIntEQ(dnsWildPermitted("ex*.com", "example.com"), 0); ExpectIntEQ(dnsWildPermitted("foo.exa*ple.com", "example.com"), 0); /* Tail labels do not match the base at all. */ ExpectIntEQ(dnsWildPermitted("*.example.com", "example.org"), 0); ExpectIntEQ(dnsWildPermitted("*.evil.com", "example.com"), 0); /* Leading-dot base, but wildcard would have to equal an interior base * label. */ ExpectIntEQ(dnsWildPermitted("*.example.com", ".sub.example.com"), 0); /* A bare '*' cannot be proven inside any multi-label-or-single subtree. */ ExpectIntEQ(dnsWildPermitted("*", "com"), 0); /* * EXCLUDED subtree -- intersection. Reject when SOME expansion of the * wildcard falls inside the base subtree. A wildcard label is * conservatively treated as able to match any single base label. */ ExpectIntEQ(dnsWildExcluded("*.example.com", "foo.example.com"), 1); ExpectIntEQ(dnsWildExcluded("*.example.com.", "foo.example.com"), 1); ExpectIntEQ(dnsWildExcluded("*.example.com", "foo.example.com."), 1); ExpectIntEQ(dnsWildExcluded("*.example.com.", "foo.example.com."), 1); /* Wildcard adds a label on top of the excluded subtree. */ ExpectIntEQ(dnsWildExcluded("*.example.com", "example.com"), 1); ExpectIntEQ(dnsWildExcluded("*.example.com", "com"), 1); ExpectIntEQ(dnsWildExcluded("*.example.com", ".example.com"), 1); /* Wildcard in a non-left label still intersects. */ ExpectIntEQ(dnsWildExcluded("foo.*.example.com", "bar.example.com"), 1); /* Partial-label wildcard: conservatively excluded even though "ex*" * cannot actually expand to "foo" (over-rejection, safe). */ ExpectIntEQ(dnsWildExcluded("ex*.example.com", "foo.example.com"), 1); /* A bare '*' can expand to the apex label of a single-label subtree. */ ExpectIntEQ(dnsWildExcluded("*", "com"), 1); /* No intersection: literal tail labels differ from the base. */ ExpectIntEQ(dnsWildExcluded("*.example.com", "foo.other.com"), 0); ExpectIntEQ(dnsWildExcluded("*.other.com", "example.com"), 0); ExpectIntEQ(dnsWildExcluded("*.example.com", "example.org"), 0); /* Leading-dot excluded base needs a label before it; the wildcard SAN has * no room for one, so no expansion reaches the proper subtree. */ ExpectIntEQ(dnsWildExcluded("*.example.com", ".foo.example.com"), 0); /* Same arity: '*' can expand to the apex label of the base, so the * wildcard intersects (*.com can be example.com, which is excluded). */ ExpectIntEQ(dnsWildExcluded("*.com", "example.com"), 1); /* But a base with MORE labels than the name cannot be reached. */ ExpectIntEQ(dnsWildExcluded("*.com", "a.example.com"), 0); /* * Error / degenerate inputs (both flags reject). */ ExpectIntEQ(wolfssl_local_MatchDnsConstraintWildcard(NULL, 5, "com", 3, 1), 0); ExpectIntEQ(wolfssl_local_MatchDnsConstraintWildcard("*.com", 5, NULL, 3, 1), 0); ExpectIntEQ(wolfssl_local_MatchDnsConstraintWildcard("*.com", 0, "com", 3, 1), 0); ExpectIntEQ(wolfssl_local_MatchDnsConstraintWildcard("*.com", 5, "com", 0, 1), 0); /* Name beginning with a dot is invalid. */ ExpectIntEQ(dnsWildPermitted(".x.com", "com"), 0); ExpectIntEQ(dnsWildExcluded(".x.com", "com"), 0); /* Base that is only dots collapses to nothing. */ ExpectIntEQ(dnsWildExcluded("*.example.com", "."), 0); ExpectIntEQ(dnsWildExcluded("*.example.com", ".."), 0); /* SAN has an empty interior label ("*..com"), but only the right-most * "com" label overlaps the base "com" -- the empty label sits outside the * compared suffix, and '*' can expand to any label, so the matcher * conservatively reports intersection. */ ExpectIntEQ(dnsWildExcluded("*..com", "com"), 1); #endif /* !NO_CERTS && !NO_ASN && !IGNORE_NAME_CONSTRAINTS */ return EXPECT_RESULT(); } /* * Tests URI name-constraint matching (RFC 5280 4.2.1.10): the constraint * applies to the host portion of the URI. A constraint that does NOT begin * with a dot is an exact host match; one that begins with a dot matches any * host with one or more additional leading labels (the bare host is excluded). */ int test_wolfssl_local_MatchUriNameConstraint(void) { EXPECT_DECLS; #if !defined(NO_CERTS) && !defined(NO_ASN) && !defined(IGNORE_NAME_CONSTRAINTS) /* * Exact host match (no leading dot in the constraint). */ ExpectIntEQ(uriNC("https://host.com/path", "host.com"), 1); ExpectIntEQ(uriNC("https://host.com", "host.com"), 1); ExpectIntEQ(uriNC("https://host.com:8443/x", "host.com"), 1); ExpectIntEQ(uriNC("ftp://user@host.com/x", "host.com"), 1); ExpectIntEQ(uriNC("https://HOST.COM", "host.com"), 1); ExpectIntEQ(uriNC("https://host.com?q=1", "host.com"), 1); ExpectIntEQ(uriNC("https://host.com#frag", "host.com"), 1); /* The bug this fix closes: an exact-host constraint must NOT subtree-match * a sub-host. */ ExpectIntEQ(uriNC("https://www.host.com/", "host.com"), 0); ExpectIntEQ(uriNC("https://a.b.host.com", "host.com"), 0); /* Suffix that does not respect a label boundary. */ ExpectIntEQ(uriNC("https://xhost.com", "host.com"), 0); /* host.com is a prefix of the URI host but not the whole host. */ ExpectIntEQ(uriNC("https://host.com.evil.com", "host.com"), 0); ExpectIntEQ(uriNC("https://other.com", "host.com"), 0); /* * Leading-dot constraint: proper subtree of hosts (apex excluded). */ ExpectIntEQ(uriNC("https://www.host.com/", ".host.com"), 1); ExpectIntEQ(uriNC("https://a.b.host.com", ".host.com"), 1); ExpectIntEQ(uriNC("https://www.host.com:443", ".host.com"), 1); /* The bare host is NOT in the leading-dot subtree. */ ExpectIntEQ(uriNC("https://host.com", ".host.com"), 0); ExpectIntEQ(uriNC("https://evilhost.com", ".host.com"), 0); /* * IPv6 literal host extraction ([..]) then exact match. */ ExpectIntEQ(uriNC("https://[2001:db8::1]:443/x", "2001:db8::1"), 1); ExpectIntEQ(uriNC("https://[2001:db8::1]", "2001:db8::2"), 0); /* * Malformed / degenerate URIs and inputs (reject). */ ExpectIntEQ(uriNC("no-scheme-host.com", "host.com"), 0); ExpectIntEQ(uriNC("https://", "host.com"), 0); /* double literal to abide source-check thinking it's a c++ comment */ ExpectIntEQ(uriNC("https://" "/path", "host.com"), 0); ExpectIntEQ(wolfssl_local_MatchUriNameConstraint(NULL, 10, "host.com", 8), 0); ExpectIntEQ(wolfssl_local_MatchUriNameConstraint("https://host.com", 16, NULL, 8), 0); ExpectIntEQ(wolfssl_local_MatchUriNameConstraint("https://host.com", 0, "host.com", 8), 0); ExpectIntEQ(wolfssl_local_MatchUriNameConstraint("https://host.com", 16, "host.com", 0), 0); #endif /* !NO_CERTS && !NO_ASN && !IGNORE_NAME_CONSTRAINTS */ return EXPECT_RESULT(); } /* * Testing wc_DecodeRsaPssParams with known DER byte arrays. * Exercises both WOLFSSL_ASN_TEMPLATE and non-template paths. */ int test_wc_DecodeRsaPssParams(void) { EXPECT_DECLS; #if defined(WC_RSA_PSS) && !defined(NO_RSA) && !defined(NO_ASN) enum wc_HashType hash; int mgf; int saltLen; /* SHA-256 / MGF1-SHA-256 / saltLen=32 */ static const byte pssParamsSha256[] = { 0x30, 0x34, 0xA0, 0x0F, 0x30, 0x0D, 0x06, 0x09, 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x01, 0x05, 0x00, 0xA1, 0x1C, 0x30, 0x1A, 0x06, 0x09, 0x2A, 0x86, 0x48, 0x86, 0xF7, 0x0D, 0x01, 0x01, 0x08, 0x30, 0x0D, 0x06, 0x09, 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x01, 0x05, 0x00, 0xA2, 0x03, 0x02, 0x01, 0x20, }; /* Hash-only: SHA-256 hash, defaults for MGF and salt */ static const byte pssParamsHashOnly[] = { 0x30, 0x11, 0xA0, 0x0F, 0x30, 0x0D, 0x06, 0x09, 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x01, 0x05, 0x00, }; /* Salt-only: default hash/mgf, saltLen=48 */ static const byte pssParamsSaltOnly[] = { 0x30, 0x05, 0xA2, 0x03, 0x02, 0x01, 0x30, }; /* NULL tag (05 00) means all defaults */ static const byte pssParamsNull[] = { 0x05, 0x00 }; /* Empty SEQUENCE means all non-default fields omitted => defaults */ static const byte pssParamsEmptySeq[] = { 0x30, 0x00 }; /* --- Test 1: sz=0 => all defaults --- */ hash = WC_HASH_TYPE_NONE; mgf = 0; saltLen = 0; ExpectIntEQ(wc_DecodeRsaPssParams((const byte*)"", 0, &hash, &mgf, &saltLen), 0); ExpectIntEQ((int)hash, (int)WC_HASH_TYPE_SHA); ExpectIntEQ(mgf, WC_MGF1SHA1); ExpectIntEQ(saltLen, 20); /* --- Test 2: NULL tag => all defaults --- */ hash = WC_HASH_TYPE_NONE; mgf = 0; saltLen = 0; ExpectIntEQ(wc_DecodeRsaPssParams(pssParamsNull, (word32)sizeof(pssParamsNull), &hash, &mgf, &saltLen), 0); ExpectIntEQ((int)hash, (int)WC_HASH_TYPE_SHA); ExpectIntEQ(mgf, WC_MGF1SHA1); ExpectIntEQ(saltLen, 20); /* --- Test 3: Empty SEQUENCE => all defaults --- */ hash = WC_HASH_TYPE_NONE; mgf = 0; saltLen = 0; ExpectIntEQ(wc_DecodeRsaPssParams(pssParamsEmptySeq, (word32)sizeof(pssParamsEmptySeq), &hash, &mgf, &saltLen), 0); ExpectIntEQ((int)hash, (int)WC_HASH_TYPE_SHA); ExpectIntEQ(mgf, WC_MGF1SHA1); ExpectIntEQ(saltLen, 20); #ifndef NO_SHA256 /* --- Test 4: SHA-256 / MGF1-SHA-256 / salt=32 --- */ hash = WC_HASH_TYPE_NONE; mgf = 0; saltLen = 0; ExpectIntEQ(wc_DecodeRsaPssParams(pssParamsSha256, (word32)sizeof(pssParamsSha256), &hash, &mgf, &saltLen), 0); ExpectIntEQ((int)hash, (int)WC_HASH_TYPE_SHA256); ExpectIntEQ(mgf, WC_MGF1SHA256); ExpectIntEQ(saltLen, 32); /* --- Test 5: Hash only => SHA-256, default MGF/salt --- */ hash = WC_HASH_TYPE_NONE; mgf = 0; saltLen = 0; ExpectIntEQ(wc_DecodeRsaPssParams(pssParamsHashOnly, (word32)sizeof(pssParamsHashOnly), &hash, &mgf, &saltLen), 0); ExpectIntEQ((int)hash, (int)WC_HASH_TYPE_SHA256); ExpectIntEQ(mgf, WC_MGF1SHA1); ExpectIntEQ(saltLen, 20); #endif /* --- Test 6: Salt only => default hash/MGF, salt=48 --- */ hash = WC_HASH_TYPE_NONE; mgf = 0; saltLen = 0; ExpectIntEQ(wc_DecodeRsaPssParams(pssParamsSaltOnly, (word32)sizeof(pssParamsSaltOnly), &hash, &mgf, &saltLen), 0); ExpectIntEQ((int)hash, (int)WC_HASH_TYPE_SHA); ExpectIntEQ(mgf, WC_MGF1SHA1); ExpectIntEQ(saltLen, 48); /* --- Test 7: NULL pointer -> BAD_FUNC_ARG --- */ ExpectIntEQ(wc_DecodeRsaPssParams(NULL, 10, &hash, &mgf, &saltLen), WC_NO_ERR_TRACE(BAD_FUNC_ARG)); /* --- Test 8: Bad leading tag => ASN_PARSE_E --- */ { static const byte badTag[] = { 0x01, 0x00 }; ExpectIntEQ(wc_DecodeRsaPssParams(badTag, (word32)sizeof(badTag), &hash, &mgf, &saltLen), WC_NO_ERR_TRACE(ASN_PARSE_E)); } #endif /* WC_RSA_PSS && !NO_RSA && !NO_ASN */ return EXPECT_RESULT(); } /* Test that DecodeAltNames rejects a SAN entry whose length exceeds the * remaining SEQUENCE length (integer underflow on the length tracker). */ int test_DecodeAltNames_length_underflow(void) { EXPECT_DECLS; #if !defined(NO_CERTS) && !defined(NO_RSA) && !defined(NO_ASN) /* Self-signed DER certificate with a well-formed SAN extension. * Byte at offset 418 is the SAN SEQUENCE length (0x06). The negative * test below copies this cert and shrinks that byte to 0x03 so the * DNS entry length exceeds the SEQUENCE bounds. */ static const unsigned char good_san_cert[] = { 0x30, 0x82, 0x02, 0xf9, 0x30, 0x82, 0x01, 0xe1, 0xa0, 0x03, 0x02, 0x01, 0x02, 0x02, 0x02, 0x10, 0x21, 0x30, 0x0d, 0x06, 0x09, 0x2a, 0x86, 0x48, 0x86, 0xf7, 0x0d, 0x01, 0x01, 0x0b, 0x05, 0x00, 0x30, 0x0f, 0x31, 0x0d, 0x30, 0x0b, 0x06, 0x03, 0x55, 0x04, 0x03, 0x13, 0x04, 0x61, 0x61, 0x31, 0x31, 0x30, 0x1e, 0x17, 0x0d, 0x31, 0x36, 0x30, 0x32, 0x30, 0x37, 0x31, 0x37, 0x32, 0x34, 0x30, 0x30, 0x5a, 0x17, 0x0d, 0x33, 0x34, 0x30, 0x32, 0x31, 0x34, 0x30, 0x36, 0x32, 0x36, 0x35, 0x33, 0x5a, 0x30, 0x0f, 0x31, 0x0d, 0x30, 0x0b, 0x06, 0x03, 0x55, 0x04, 0x03, 0x13, 0x04, 0x61, 0x61, 0x61, 0x61, 0x30, 0x82, 0x01, 0x20, 0x30, 0x0d, 0x06, 0x09, 0x2a, 0x86, 0x48, 0x86, 0xf7, 0x0d, 0x01, 0x01, 0x01, 0x05, 0x00, 0x03, 0x82, 0x01, 0x0d, 0x00, 0x30, 0x82, 0x01, 0x08, 0x02, 0x82, 0x01, 0x01, 0x00, 0xa8, 0x8a, 0x5e, 0x26, 0x23, 0x1b, 0x31, 0xd3, 0x37, 0x1a, 0x70, 0xb2, 0xec, 0x3f, 0x74, 0xd4, 0xb4, 0x44, 0xe3, 0x7a, 0xa5, 0xc0, 0xf5, 0xaa, 0x97, 0x26, 0x9a, 0x04, 0xff, 0xda, 0xbe, 0xe5, 0x09, 0x03, 0x98, 0x3d, 0xb5, 0xbf, 0x01, 0x2c, 0x9a, 0x0a, 0x3a, 0xfb, 0xbc, 0x3c, 0xe7, 0xbe, 0x83, 0x5c, 0xb3, 0x70, 0xe8, 0x5c, 0xe3, 0xd1, 0x83, 0xc3, 0x94, 0x08, 0xcd, 0x1a, 0x87, 0xe5, 0xe0, 0x5b, 0x9c, 0x5c, 0x6e, 0xb0, 0x7d, 0xe2, 0x58, 0x6c, 0xc3, 0xb5, 0xc8, 0x9d, 0x11, 0xf1, 0x5d, 0x96, 0x0d, 0x66, 0x1e, 0x56, 0x7f, 0x8f, 0x59, 0xa7, 0xa5, 0xe1, 0xc5, 0xe7, 0x81, 0x4c, 0x09, 0x9d, 0x5e, 0x96, 0xf0, 0x9a, 0xc2, 0x8b, 0x70, 0xd5, 0xab, 0x79, 0x58, 0x5d, 0xb7, 0x58, 0xaa, 0xfd, 0x75, 0x52, 0xaa, 0x4b, 0xa7, 0x25, 0x68, 0x76, 0x59, 0x00, 0xee, 0x78, 0x2b, 0x91, 0xc6, 0x59, 0x91, 0x99, 0x38, 0x3e, 0xa1, 0x76, 0xc3, 0xf5, 0x23, 0x6b, 0xe6, 0x07, 0xea, 0x63, 0x1c, 0x97, 0x49, 0xef, 0xa0, 0xfe, 0xfd, 0x13, 0xc9, 0xa9, 0x9f, 0xc2, 0x0b, 0xe6, 0x87, 0x92, 0x5b, 0xcc, 0xf5, 0x42, 0x95, 0x4a, 0xa4, 0x6d, 0x64, 0xba, 0x7d, 0xce, 0xcb, 0x04, 0xd0, 0xf8, 0xe7, 0xe3, 0xda, 0x75, 0x60, 0xd3, 0x8b, 0x6a, 0x64, 0xfc, 0x78, 0x56, 0x21, 0x69, 0x5a, 0xe8, 0xa7, 0x8f, 0xfb, 0x8f, 0x82, 0xe3, 0xae, 0x36, 0xa2, 0x93, 0x66, 0x92, 0xcb, 0x82, 0xa3, 0xbe, 0x84, 0x00, 0x86, 0xdc, 0x7e, 0x6d, 0x53, 0x77, 0x84, 0x17, 0xb9, 0x55, 0x43, 0x0d, 0xf1, 0x16, 0x1f, 0xd5, 0x43, 0x75, 0x99, 0x66, 0x19, 0x52, 0xd0, 0xac, 0x5f, 0x74, 0xad, 0xb2, 0x90, 0x15, 0x50, 0x04, 0x74, 0x43, 0xdf, 0x6c, 0x35, 0xd0, 0xfd, 0x32, 0x37, 0xb3, 0x8d, 0xf5, 0xe5, 0x09, 0x02, 0x01, 0x03, 0xa3, 0x61, 0x30, 0x5f, 0x30, 0x0c, 0x06, 0x03, 0x55, 0x1d, 0x13, 0x01, 0x01, 0xff, 0x04, 0x02, 0x30, 0x00, /* SAN extension: correct SEQUENCE length 0x06 */ 0x30, 0x0f, 0x06, 0x03, 0x55, 0x1d, 0x11, 0x04, 0x08, 0x30, 0x06, 0x82, 0x04, 0x61, 0x2a, 0x62, 0x2a, 0x30, 0x1d, 0x06, 0x03, 0x55, 0x1d, 0x0e, 0x04, 0x16, 0x04, 0x14, 0x92, 0x6a, 0x1e, 0x52, 0x3a, 0x1a, 0x57, 0x9f, 0xc9, 0x82, 0x9a, 0xce, 0xc8, 0xc0, 0xa9, 0x51, 0x9d, 0x2f, 0xc7, 0x72, 0x30, 0x1f, 0x06, 0x03, 0x55, 0x1d, 0x23, 0x04, 0x18, 0x30, 0x16, 0x80, 0x14, 0x6b, 0xf9, 0xa4, 0x2d, 0xa5, 0xe9, 0x39, 0x89, 0xa8, 0x24, 0x58, 0x79, 0x87, 0x11, 0xfc, 0x6f, 0x07, 0x91, 0xef, 0xa6, 0x30, 0x0d, 0x06, 0x09, 0x2a, 0x86, 0x48, 0x86, 0xf7, 0x0d, 0x01, 0x01, 0x0b, 0x05, 0x00, 0x03, 0x82, 0x01, 0x01, 0x00, 0x3f, 0xd5, 0x37, 0x2f, 0xc7, 0xf8, 0x8b, 0x39, 0x1c, 0xe3, 0xdf, 0x77, 0xee, 0xc6, 0x4b, 0x5f, 0x84, 0xcf, 0xfa, 0x33, 0x2c, 0xb2, 0xb5, 0x4b, 0x09, 0xee, 0x56, 0xc0, 0xf2, 0xf0, 0xeb, 0xad, 0x1c, 0x02, 0xef, 0xae, 0x09, 0x53, 0xc0, 0x06, 0xad, 0x4e, 0xfd, 0x3e, 0x8c, 0x13, 0xb3, 0xbf, 0x80, 0x05, 0x36, 0xb5, 0x3f, 0x2b, 0xc7, 0x60, 0x53, 0x14, 0xbf, 0x33, 0x63, 0x47, 0xc3, 0xc6, 0x28, 0xda, 0x10, 0x12, 0xe2, 0xc4, 0xeb, 0xc5, 0x64, 0x66, 0xc0, 0xcc, 0x6b, 0x84, 0xda, 0x0c, 0xe9, 0xf6, 0xe3, 0xf8, 0x8e, 0x3d, 0x95, 0x5f, 0xba, 0x9f, 0xe1, 0xc7, 0xed, 0x6e, 0x97, 0xcc, 0xbd, 0x7d, 0xe5, 0x4e, 0xab, 0xbc, 0x1b, 0xf1, 0x3a, 0x09, 0x33, 0x09, 0xe1, 0xcc, 0xec, 0x21, 0x16, 0x8e, 0xb1, 0x74, 0x9e, 0xc8, 0x13, 0x7c, 0xdf, 0x07, 0xaa, 0xeb, 0x70, 0xd7, 0x91, 0x5c, 0xc4, 0xef, 0x83, 0x88, 0xc3, 0xe4, 0x97, 0xfa, 0xe4, 0xdf, 0xd7, 0x0d, 0xff, 0xba, 0x78, 0x22, 0xfc, 0x3f, 0xdc, 0xd8, 0x02, 0x8d, 0x93, 0x57, 0xf9, 0x9e, 0x39, 0x3a, 0x77, 0x00, 0xd9, 0x19, 0xaa, 0x68, 0xa1, 0xe6, 0x9e, 0x13, 0xeb, 0x37, 0x16, 0xf5, 0x77, 0xa4, 0x0b, 0x40, 0x04, 0xd3, 0xa5, 0x49, 0x78, 0x35, 0xfa, 0x3b, 0xf6, 0x02, 0xab, 0x85, 0xee, 0xcb, 0x9b, 0x62, 0xda, 0x05, 0x00, 0x22, 0x2f, 0xf8, 0xbd, 0x0b, 0xe5, 0x2c, 0xb2, 0x53, 0x78, 0x0a, 0xcb, 0x69, 0xc0, 0xb6, 0x9f, 0x96, 0xff, 0x58, 0x22, 0x70, 0x9c, 0x01, 0x2e, 0x56, 0x60, 0x5d, 0x37, 0xe3, 0x40, 0x25, 0xc9, 0x90, 0xc8, 0x0f, 0x41, 0x68, 0xb4, 0xfd, 0x10, 0xe2, 0x09, 0x99, 0x08, 0x5d, 0x7b, 0xc9, 0xe3, 0x29, 0xd4, 0x5a, 0xcf, 0xc9, 0x34, 0x55, 0xa1, 0x40, 0x44, 0xd6, 0x88, 0x16, 0xbb, 0xdd }; /* Offset of the SAN SEQUENCE length byte inside good_san_cert. */ #define SAN_SEQ_LEN_OFFSET 418 DecodedCert cert; unsigned char bad_san_cert[sizeof(good_san_cert)]; /* Control: the original cert with correct SAN SEQUENCE length should * parse successfully (signature won't verify, but NO_VERIFY skips that). */ wc_InitDecodedCert(&cert, good_san_cert, (word32)sizeof(good_san_cert), NULL); ExpectIntEQ(wc_ParseCert(&cert, CERT_TYPE, NO_VERIFY, NULL), 0); wc_FreeDecodedCert(&cert); /* Build a malformed variant: shrink the SAN SEQUENCE length from 6 to 3 * so the DNS entry length (4) exceeds the SEQUENCE bounds. Without a * bounds check DecodeAltNames would underflow the length tracker. */ XMEMCPY(bad_san_cert, good_san_cert, sizeof(good_san_cert)); bad_san_cert[SAN_SEQ_LEN_OFFSET] = 0x03; wc_InitDecodedCert(&cert, bad_san_cert, (word32)sizeof(bad_san_cert), NULL); ExpectIntEQ(wc_ParseCert(&cert, CERT_TYPE, NO_VERIFY, NULL), WC_NO_ERR_TRACE(ASN_PARSE_E)); wc_FreeDecodedCert(&cert); /* NUL in dNSName SAN must be rejected per RFC 5280 4.2.1.6. */ XMEMCPY(bad_san_cert, good_san_cert, sizeof(good_san_cert)); bad_san_cert[SAN_SEQ_LEN_OFFSET + 5] = 0x00; wc_InitDecodedCert(&cert, bad_san_cert, (word32)sizeof(bad_san_cert), NULL); ExpectIntEQ(wc_ParseCert(&cert, CERT_TYPE, NO_VERIFY, NULL), WC_NO_ERR_TRACE(ASN_PARSE_E)); wc_FreeDecodedCert(&cert); #endif /* !NO_CERTS && !NO_RSA && !NO_ASN */ return EXPECT_RESULT(); } int test_SerialNumber0_RootCA(void) { EXPECT_DECLS; #if !defined(NO_CERTS) && !defined(NO_FILESYSTEM) && !defined(NO_RSA) && \ !defined(WOLFSSL_NO_PEM) && defined(WOLFSSL_PEM_TO_DER) /* Test that root CA certificates with serial number 0 are accepted, * while non-root certificates with serial 0 are rejected (issue #8615) */ #if !defined(WOLFSSL_NO_ASN_STRICT) && !defined(WOLFSSL_PYTHON) && \ !defined(WOLFSSL_ASN_ALLOW_0_SERIAL) && \ !defined(WOLFSSL_TEST_APPLE_NATIVE_CERT_VALIDATION) WOLFSSL_CERT_MANAGER* cm = NULL; const char* rootSerial0File = "./certs/test-serial0/root_serial0.pem"; const char* selfSignedNonCASerial0File = "./certs/test-serial0/selfsigned_nonca_serial0.pem"; /* Test 1: Root CA with serial 0 should load successfully */ ExpectNotNull(cm = wolfSSL_CertManagerNew()); ExpectIntEQ(wolfSSL_CertManagerLoadCA(cm, rootSerial0File, NULL), WOLFSSL_SUCCESS); #if (!defined(NO_WOLFSSL_CLIENT) || !defined(WOLFSSL_NO_CLIENT_AUTH)) || \ defined(OPENSSL_EXTRA) { const char* eeSerial0File = "./certs/test-serial0/ee_serial0.pem"; const char* eeNormalFile = "./certs/test-serial0/ee_normal.pem"; /* Test 2: End-entity cert with serial 0 should be rejected during * verify */ ExpectIntEQ(wolfSSL_CertManagerVerify(cm, eeSerial0File, WOLFSSL_FILETYPE_PEM), WC_NO_ERR_TRACE(ASN_PARSE_E)); /* Test 3: Normal end-entity cert signed by root CA with serial 0 * should verify successfully */ ExpectIntEQ(wolfSSL_CertManagerVerify(cm, eeNormalFile, WOLFSSL_FILETYPE_PEM), WOLFSSL_SUCCESS); } #endif if (cm != NULL) { wolfSSL_CertManagerFree(cm); cm = NULL; } /* Test 4: Self-signed non-CA certificate with serial 0 should be rejected */ ExpectNotNull(cm = wolfSSL_CertManagerNew()); ExpectIntNE(wolfSSL_CertManagerLoadCA(cm, selfSignedNonCASerial0File, NULL), WOLFSSL_SUCCESS); if (cm != NULL) { wolfSSL_CertManagerFree(cm); cm = NULL; } /* Test 5: Intermediate CA (CA:TRUE but issuer != subject) with serial 0 * must be rejected when loaded as CA_TYPE. Exercises the selfSigned * half of the ParseCertRelative exemption predicate. */ { const char* intermediateSerial0File = "./certs/test-serial0/intermediate_serial0.pem"; ExpectNotNull(cm = wolfSSL_CertManagerNew()); ExpectIntNE(wolfSSL_CertManagerLoadCA(cm, intermediateSerial0File, NULL), WOLFSSL_SUCCESS); if (cm != NULL) { wolfSSL_CertManagerFree(cm); cm = NULL; } } #endif /* !WOLFSSL_NO_ASN_STRICT && !WOLFSSL_PYTHON && !WOLFSSL_ASN_ALLOW_0_SERIAL && !WOLFSSL_TEST_APPLE_NATIVE_CERT_VALIDATION */ #endif /* !NO_CERTS && !NO_FILESYSTEM && !NO_RSA && !WOLFSSL_NO_PEM */ return EXPECT_RESULT(); } int test_wc_DecodeObjectId(void) { EXPECT_DECLS; #if !defined(NO_ASN) && \ (defined(HAVE_OID_DECODING) || defined(WOLFSSL_ASN_PRINT)) { /* OID 1.2.840.113549.1.1.11 (sha256WithRSAEncryption) * DER encoding: 2a 86 48 86 f7 0d 01 01 0b * First byte 0x2a = 42 => arc0 = 42/40 = 1, arc1 = 42%40 = 2 * Remaining arcs: 840, 113549, 1, 1, 11 */ static const byte oid_sha256rsa[] = { 0x2a, 0x86, 0x48, 0x86, 0xf7, 0x0d, 0x01, 0x01, 0x0b }; word16 out[MAX_OID_SZ]; word32 outSz; /* Test 1: Normal decode */ outSz = MAX_OID_SZ; ExpectIntEQ(DecodeObjectId(oid_sha256rsa, sizeof(oid_sha256rsa), out, &outSz), 0); ExpectIntEQ((int)outSz, 7); ExpectIntEQ(out[0], 1); ExpectIntEQ(out[1], 2); ExpectIntEQ(out[2], 840); ExpectIntEQ(out[3], (word16)113549); /* truncated to word16 */ ExpectIntEQ(out[4], 1); ExpectIntEQ(out[5], 1); ExpectIntEQ(out[6], 11); /* Test 2: NULL args */ outSz = MAX_OID_SZ; ExpectIntEQ(DecodeObjectId(NULL, sizeof(oid_sha256rsa), out, &outSz), WC_NO_ERR_TRACE(BAD_FUNC_ARG)); ExpectIntEQ(DecodeObjectId(oid_sha256rsa, sizeof(oid_sha256rsa), out, NULL), WC_NO_ERR_TRACE(BAD_FUNC_ARG)); /* Test 3 (Bug 1): outSz=1 must return BUFFER_E, not OOB write. * The first OID byte decodes into two arcs, so outSz must be >= 2. */ outSz = 1; ExpectIntEQ(DecodeObjectId(oid_sha256rsa, sizeof(oid_sha256rsa), out, &outSz), WC_NO_ERR_TRACE(BUFFER_E)); /* Test 4: outSz=0 must also return BUFFER_E */ outSz = 0; ExpectIntEQ(DecodeObjectId(oid_sha256rsa, sizeof(oid_sha256rsa), out, &outSz), WC_NO_ERR_TRACE(BUFFER_E)); /* Test 5: outSz=2 is enough for a single-byte OID (two arcs) */ { static const byte oid_one_byte[] = { 0x2a }; /* 1.2 */ outSz = 2; ExpectIntEQ(DecodeObjectId(oid_one_byte, sizeof(oid_one_byte), out, &outSz), 0); ExpectIntEQ((int)outSz, 2); ExpectIntEQ(out[0], 1); ExpectIntEQ(out[1], 2); } /* Test 6: Buffer too small for later arcs */ outSz = 3; /* only room for 3 arcs, but OID has 7 */ ExpectIntEQ(DecodeObjectId(oid_sha256rsa, sizeof(oid_sha256rsa), out, &outSz), WC_NO_ERR_TRACE(BUFFER_E)); } #endif /* !NO_ASN && (HAVE_OID_DECODING || WOLFSSL_ASN_PRINT) */ return EXPECT_RESULT(); } #if defined(HAVE_PKCS8) && !defined(NO_ASN) && \ (defined(WOLFSSL_TEST_CERT) || defined(OPENSSL_EXTRA) || \ defined(OPENSSL_EXTRA_X509_SMALL) || defined(WOLFSSL_PUBLIC_ASN)) && \ (defined(HAVE_ED25519) || \ (defined(HAVE_ED448) && defined(HAVE_ED448_KEY_EXPORT) && \ defined(WOLFSSL_KEY_GEN)) || \ (defined(HAVE_DILITHIUM) && \ !defined(WOLFSSL_DILITHIUM_NO_MAKE_KEY) && \ !defined(WOLFSSL_DILITHIUM_NO_ASN1))) /* Run ToTraditional_ex() on a copy of der and assert the algId, returned * length, and the inner OCTET STRING tag/length at the start of the * (in-place rewritten) buffer. */ static int test_ToTraditional_ex_once(const byte* der, word32 derSz, word32 expectAlgId, word32 expectPrivKeySz) { EXPECT_DECLS; byte* copy = NULL; word32 algId = 0; int ret; copy = (byte*)XMALLOC(derSz, NULL, DYNAMIC_TYPE_TMP_BUFFER); ExpectNotNull(copy); if (copy != NULL) { XMEMCPY(copy, der, derSz); ret = ToTraditional_ex(copy, derSz, &algId); ExpectIntGT(ret, 0); ExpectIntEQ(algId, expectAlgId); if (ret > 0) { /* wolfSSL writes nested OCTET STRING, but accept raw bytes * too per RFC 5958. */ if (copy[0] == ASN_OCTET_STRING) { if (expectPrivKeySz < 0x80) { ExpectIntEQ(copy[1], (byte)expectPrivKeySz); } else if (expectPrivKeySz < 0x100) { ExpectIntEQ(copy[1], 0x81); ExpectIntEQ(copy[2], (byte)expectPrivKeySz); } else { ExpectIntEQ(copy[1], 0x82); ExpectIntEQ(((word32)copy[2] << 8) | copy[3], expectPrivKeySz); } } else { ExpectIntEQ(ret, (int)expectPrivKeySz); } } } XFREE(copy, NULL, DYNAMIC_TYPE_TMP_BUFFER); return EXPECT_RESULT(); } #endif /* Hand crafted PKCS#8 v0 and v1 Ed25519 buffers to test parser directly. */ int test_ToTraditional_ex_handcrafted(void) { EXPECT_DECLS; #if defined(HAVE_PKCS8) && defined(HAVE_ED25519) && \ (defined(WOLFSSL_TEST_CERT) || defined(OPENSSL_EXTRA) || \ defined(OPENSSL_EXTRA_X509_SMALL) || defined(WOLFSSL_PUBLIC_ASN)) /* Ed25519 algorithm OID body (1.3.101.112). */ static const byte algId[] = { 43, 101, 112 }; const word32 privKeySz = ED25519_KEY_SIZE; const word32 pubKeySz = ED25519_PUB_KEY_SIZE; byte der[128]; word32 sz; word32 outerLenIdx; /* Filler bytes for the dummy private/public key bodies */ const byte keyPat = 0xCC; const byte pubPat = 0xDD; /* v0: SEQ { INTEGER 0, SEQ { OID }, OCTET STRING { OCTET STRING priv } } */ sz = 0; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; outerLenIdx = sz; der[sz++] = 0; /* outer length, filled in below */ der[sz++] = ASN_INTEGER; der[sz++] = 1; der[sz++] = 0x00; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; der[sz++] = (byte)(sizeof(algId) + 2); der[sz++] = ASN_OBJECT_ID; der[sz++] = (byte)sizeof(algId); XMEMCPY(der + sz, algId, sizeof(algId)); sz += sizeof(algId); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)(privKeySz + 2); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)privKeySz; XMEMSET(der + sz, keyPat, privKeySz); sz += privKeySz; der[outerLenIdx] = (byte)(sz - outerLenIdx - 1); EXPECT_TEST(test_ToTraditional_ex_once(der, sz, ED25519k, privKeySz)); /* v1: same plus [1] publicKey trailer. */ sz = 0; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; outerLenIdx = sz; der[sz++] = 0; der[sz++] = ASN_INTEGER; der[sz++] = 1; der[sz++] = 0x01; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; der[sz++] = (byte)(sizeof(algId) + 2); der[sz++] = ASN_OBJECT_ID; der[sz++] = (byte)sizeof(algId); XMEMCPY(der + sz, algId, sizeof(algId)); sz += sizeof(algId); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)(privKeySz + 2); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)privKeySz; XMEMSET(der + sz, keyPat, privKeySz); sz += privKeySz; /* [1] publicKey trailer */ der[sz++] = ASN_CONTEXT_SPECIFIC | ASN_ASYMKEY_PUBKEY; der[sz++] = (byte)pubKeySz; XMEMSET(der + sz, pubPat, pubKeySz); sz += pubKeySz; der[outerLenIdx] = (byte)(sz - outerLenIdx - 1); EXPECT_TEST(test_ToTraditional_ex_once(der, sz, ED25519k, privKeySz)); /* v1 without publicKey: should still accept per RFC 5958. */ sz = 0; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; outerLenIdx = sz; der[sz++] = 0; der[sz++] = ASN_INTEGER; der[sz++] = 1; der[sz++] = 0x01; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; der[sz++] = (byte)(sizeof(algId) + 2); der[sz++] = ASN_OBJECT_ID; der[sz++] = (byte)sizeof(algId); XMEMCPY(der + sz, algId, sizeof(algId)); sz += sizeof(algId); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)(privKeySz + 2); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)privKeySz; XMEMSET(der + sz, keyPat, privKeySz); sz += privKeySz; der[outerLenIdx] = (byte)(sz - outerLenIdx - 1); EXPECT_TEST(test_ToTraditional_ex_once(der, sz, ED25519k, privKeySz)); #endif /* HAVE_PKCS8 && HAVE_ED25519 */ return EXPECT_RESULT(); } /* Encoder/parser round trip: ToTraditional_ex() must accept both forms created * by SetAsymKeyDer() (v0 with PrivateKeyToDer, v1 with KeyToDer). */ int test_ToTraditional_ex_roundtrip(void) { EXPECT_DECLS; #if defined(HAVE_PKCS8) && \ (defined(WOLFSSL_TEST_CERT) || defined(OPENSSL_EXTRA) || \ defined(OPENSSL_EXTRA_X509_SMALL) || defined(WOLFSSL_PUBLIC_ASN)) #if defined(HAVE_ED25519) && defined(HAVE_ED25519_KEY_EXPORT) && \ defined(WOLFSSL_KEY_GEN) { ed25519_key key; WC_RNG rng; byte der[256]; int derSz = 0; XMEMSET(&key, 0, sizeof(key)); XMEMSET(&rng, 0, sizeof(rng)); ExpectIntEQ(wc_InitRng(&rng), 0); ExpectIntEQ(wc_ed25519_init(&key), 0); ExpectIntEQ(wc_ed25519_make_key(&rng, ED25519_KEY_SIZE, &key), 0); if (EXPECT_SUCCESS()) { ExpectIntGT(derSz = wc_Ed25519KeyToDer(&key, der, sizeof(der)), 0); EXPECT_TEST(test_ToTraditional_ex_once(der, (word32)derSz, ED25519k, ED25519_KEY_SIZE)); derSz = wc_Ed25519PrivateKeyToDer(&key, der, sizeof(der)); ExpectIntGT(derSz, 0); EXPECT_TEST(test_ToTraditional_ex_once(der, (word32)derSz, ED25519k, ED25519_KEY_SIZE)); } wc_ed25519_free(&key); wc_FreeRng(&rng); } #endif /* HAVE_ED25519 */ #if defined(HAVE_ED448) && defined(HAVE_ED448_KEY_EXPORT) && \ defined(WOLFSSL_KEY_GEN) { ed448_key key; WC_RNG rng; byte der[256]; int derSz = 0; XMEMSET(&key, 0, sizeof(key)); XMEMSET(&rng, 0, sizeof(rng)); ExpectIntEQ(wc_InitRng(&rng), 0); ExpectIntEQ(wc_ed448_init(&key), 0); ExpectIntEQ(wc_ed448_make_key(&rng, ED448_KEY_SIZE, &key), 0); if (EXPECT_SUCCESS()) { ExpectIntGT(derSz = wc_Ed448KeyToDer(&key, der, sizeof(der)), 0); EXPECT_TEST(test_ToTraditional_ex_once(der, (word32)derSz, ED448k, ED448_KEY_SIZE)); derSz = wc_Ed448PrivateKeyToDer(&key, der, sizeof(der)); ExpectIntGT(derSz, 0); EXPECT_TEST(test_ToTraditional_ex_once(der, (word32)derSz, ED448k, ED448_KEY_SIZE)); } wc_ed448_free(&key); wc_FreeRng(&rng); } #endif /* HAVE_ED448 */ #if defined(HAVE_DILITHIUM) && \ !defined(WOLFSSL_DILITHIUM_NO_MAKE_KEY) && \ !defined(WOLFSSL_DILITHIUM_NO_ASN1) && \ (!defined(WOLFSSL_NO_ML_DSA_44) || !defined(WOLFSSL_NO_ML_DSA_65) || \ !defined(WOLFSSL_NO_ML_DSA_87)) { static const struct { int wcLevel; word32 oidSum; word32 privKeySz; } variants[] = { #ifndef WOLFSSL_NO_ML_DSA_44 { WC_ML_DSA_44, ML_DSA_LEVEL2k, ML_DSA_LEVEL2_KEY_SIZE }, #endif #ifndef WOLFSSL_NO_ML_DSA_65 { WC_ML_DSA_65, ML_DSA_LEVEL3k, ML_DSA_LEVEL3_KEY_SIZE }, #endif #ifndef WOLFSSL_NO_ML_DSA_87 { WC_ML_DSA_87, ML_DSA_LEVEL5k, ML_DSA_LEVEL5_KEY_SIZE }, #endif }; const word32 derMaxSz = DILITHIUM_MAX_BOTH_KEY_DER_SIZE; byte* der = NULL; WC_RNG rng; size_t i; int derSz; XMEMSET(&rng, 0, sizeof(rng)); ExpectIntEQ(wc_InitRng(&rng), 0); ExpectNotNull(der = (byte*)XMALLOC(derMaxSz, NULL, DYNAMIC_TYPE_TMP_BUFFER)); for (i = 0; i < sizeof(variants) / sizeof(variants[0]); i++) { dilithium_key key; XMEMSET(&key, 0, sizeof(key)); ExpectIntEQ(wc_dilithium_init(&key), 0); ExpectIntEQ(wc_dilithium_set_level(&key, variants[i].wcLevel), 0); ExpectIntEQ(wc_dilithium_make_key(&key, &rng), 0); if (EXPECT_SUCCESS()) { ExpectIntGT(derSz = wc_Dilithium_KeyToDer(&key, der, derMaxSz), 0); EXPECT_TEST(test_ToTraditional_ex_once(der, (word32)derSz, variants[i].oidSum, variants[i].privKeySz)); derSz = wc_Dilithium_PrivateKeyToDer(&key, der, derMaxSz); ExpectIntGT(derSz, 0); EXPECT_TEST(test_ToTraditional_ex_once(der, (word32)derSz, variants[i].oidSum, variants[i].privKeySz)); } wc_dilithium_free(&key); } XFREE(der, NULL, DYNAMIC_TYPE_TMP_BUFFER); wc_FreeRng(&rng); } #endif /* HAVE_DILITHIUM */ #endif /* HAVE_PKCS8 */ return EXPECT_RESULT(); } /* Trailing garbage that is neither [0] attributes nor [1] publicKey must * still be rejected. */ int test_ToTraditional_ex_negative(void) { EXPECT_DECLS; #if defined(HAVE_PKCS8) && defined(HAVE_ED25519) && \ defined(HAVE_ED25519_KEY_EXPORT) && defined(WOLFSSL_KEY_GEN) && \ defined(WOLFSSL_ASN_TEMPLATE) && \ (defined(WOLFSSL_TEST_CERT) || defined(OPENSSL_EXTRA) || \ defined(OPENSSL_EXTRA_X509_SMALL) || defined(WOLFSSL_PUBLIC_ASN)) ed25519_key key; WC_RNG rng; byte der[256]; byte copy[256]; int derSz = 0; word32 algId; XMEMSET(&key, 0, sizeof(key)); XMEMSET(&rng, 0, sizeof(rng)); ExpectIntEQ(wc_InitRng(&rng), 0); ExpectIntEQ(wc_ed25519_init(&key), 0); ExpectIntEQ(wc_ed25519_make_key(&rng, ED25519_KEY_SIZE, &key), 0); ExpectIntGT(derSz = wc_Ed25519PrivateKeyToDer(&key, der, sizeof(der)), 0); if (EXPECT_SUCCESS() && (derSz > 0) && ((size_t)derSz + 1 <= sizeof(copy))) { /* Append one byte of trailing data, grow outer SEQ length to cover. * Ed25519 PKCS#8 outer SEQ is under 128 bytes, expect DER short form * so the negative path is always exercised. */ XMEMCPY(copy, der, (size_t)derSz); ExpectTrue(copy[1] < 0x80); if (EXPECT_SUCCESS() && copy[1] < 0x80) { copy[1] = (byte)(copy[1] + 1); copy[derSz] = 0x05; algId = 0; ExpectIntLT(ToTraditional_ex(copy, (word32)(derSz + 1), &algId), 0); } } /* publicKey trailer is permitted only when version == v1 */ if (EXPECT_SUCCESS() && (derSz > 0) && ((size_t)derSz + 2 + ED25519_PUB_KEY_SIZE <= sizeof(copy))) { word32 trailerSz = 2 + ED25519_PUB_KEY_SIZE; XMEMCPY(copy, der, (size_t)derSz); ExpectTrue(copy[1] < (byte)(0x80 - trailerSz)); if (EXPECT_SUCCESS() && copy[1] < (byte)(0x80 - trailerSz)) { copy[1] = (byte)(copy[1] + trailerSz); copy[derSz] = ASN_CONTEXT_SPECIFIC | ASN_ASYMKEY_PUBKEY; copy[derSz + 1] = ED25519_PUB_KEY_SIZE; XMEMSET(copy + derSz + 2, 0xDD, ED25519_PUB_KEY_SIZE); algId = 0; ExpectIntLT(ToTraditional_ex(copy, (word32)(derSz + (int)trailerSz), &algId), 0); } } /* v1 buffer (with publicKey) plus extra trailing garbage. */ ExpectIntGT(derSz = wc_Ed25519KeyToDer(&key, der, sizeof(der)), 0); if (EXPECT_SUCCESS() && (derSz > 0) && ((size_t)derSz + 1 <= sizeof(copy))) { XMEMCPY(copy, der, (size_t)derSz); ExpectTrue(copy[1] < 0x80); if (EXPECT_SUCCESS() && copy[1] < 0x80) { copy[1] = (byte)(copy[1] + 1); copy[derSz] = 0x05; algId = 0; ExpectIntLT(ToTraditional_ex(copy, (word32)(derSz + 1), &algId), 0); } } wc_ed25519_free(&key); wc_FreeRng(&rng); #endif return EXPECT_RESULT(); } /* ML-DSA AlgorithmIdentifier has no parameters per FIPS 204. Verify * ToTraditional_ex() rejects a PKCS#8 whose algoSeq carries trailing NULL * or OBJECT_ID parameters. Template parser only (legacy is lenient). */ int test_ToTraditional_ex_mldsa_bad_params(void) { EXPECT_DECLS; #if defined(HAVE_PKCS8) && defined(HAVE_DILITHIUM) && \ defined(WOLFSSL_ASN_TEMPLATE) && \ (defined(WOLFSSL_TEST_CERT) || defined(OPENSSL_EXTRA) || \ defined(OPENSSL_EXTRA_X509_SMALL) || defined(WOLFSSL_PUBLIC_ASN)) /* ML-DSA-65 OID body: 2.16.840.1.101.3.4.3.18 */ static const byte mldsaOid[] = { 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x03, 0x12 }; /* Single-arc OID body, used only to occupy the OBJECT_ID slot. */ static const byte extraOid[] = { 0x01 }; byte der[64]; byte copy[64]; word32 sz; word32 outerLenIdx; word32 algId; const word32 privKeySz = 4; const byte privBody = 0xAA; /* Bad case, algoSeq = { OID, NULL } */ sz = 0; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; outerLenIdx = sz; der[sz++] = 0; /* outer length, filled in below */ der[sz++] = ASN_INTEGER; der[sz++] = 1; der[sz++] = 0x00; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; der[sz++] = (byte)(sizeof(mldsaOid) + 2 + 2); der[sz++] = ASN_OBJECT_ID; der[sz++] = (byte)sizeof(mldsaOid); XMEMCPY(der + sz, mldsaOid, sizeof(mldsaOid)); sz += sizeof(mldsaOid); /* Disallowed, NULL parameter after the ML-DSA OID. */ der[sz++] = ASN_TAG_NULL; der[sz++] = 0; der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)(privKeySz + 2); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)privKeySz; XMEMSET(der + sz, privBody, privKeySz); sz += privKeySz; der[outerLenIdx] = (byte)(sz - outerLenIdx - 1); XMEMCPY(copy, der, sz); algId = 0; ExpectIntLT(ToTraditional_ex(copy, sz, &algId), 0); /* Bad case, algoSeq = { OID, OBJECT_ID } */ sz = 0; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; outerLenIdx = sz; der[sz++] = 0; der[sz++] = ASN_INTEGER; der[sz++] = 1; der[sz++] = 0x00; der[sz++] = ASN_SEQUENCE | ASN_CONSTRUCTED; der[sz++] = (byte)(sizeof(mldsaOid) + 2 + sizeof(extraOid) + 2); der[sz++] = ASN_OBJECT_ID; der[sz++] = (byte)sizeof(mldsaOid); XMEMCPY(der + sz, mldsaOid, sizeof(mldsaOid)); sz += sizeof(mldsaOid); /* Disallowed, OBJECT_ID parameter after the ML-DSA OID. */ der[sz++] = ASN_OBJECT_ID; der[sz++] = (byte)sizeof(extraOid); XMEMCPY(der + sz, extraOid, sizeof(extraOid)); sz += sizeof(extraOid); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)(privKeySz + 2); der[sz++] = ASN_OCTET_STRING; der[sz++] = (byte)privKeySz; XMEMSET(der + sz, privBody, privKeySz); sz += privKeySz; der[outerLenIdx] = (byte)(sz - outerLenIdx - 1); XMEMCPY(copy, der, sz); algId = 0; ExpectIntLT(ToTraditional_ex(copy, sz, &algId), 0); #endif return EXPECT_RESULT(); }