/* Copyright (c) 2016, The Tor Project, Inc. */ /* See LICENSE for licensing information */ /** * \file test_hs_descriptor.c * \brief Test hidden service descriptor encoding and decoding. */ #define HS_DESCRIPTOR_PRIVATE #include "crypto_ed25519.h" #include "ed25519_cert.h" #include "or.h" #include "hs_descriptor.h" #include "test.h" #include "torcert.h" static hs_desc_intro_point_t * helper_build_intro_point(const ed25519_keypair_t *blinded_kp, time_t now, const char *addr, int legacy) { int ret; ed25519_keypair_t auth_kp; hs_desc_intro_point_t *intro_point = NULL; hs_desc_intro_point_t *ip = tor_malloc_zero(sizeof(*ip)); ip->link_specifiers = smartlist_new(); { hs_desc_link_specifier_t *ls = tor_malloc_zero(sizeof(*ls)); if (legacy) { ls->type = LS_LEGACY_ID; memcpy(ls->u.legacy_id, "0299F268FCA9D55CD157976D39AE92B4B455B3A8", DIGEST_LEN); } else { ls->u.ap.port = 9001; int family = tor_addr_parse(&ls->u.ap.addr, addr); switch (family) { case AF_INET: ls->type = LS_IPV4; break; case AF_INET6: ls->type = LS_IPV6; break; default: /* Stop the test, not suppose to have an error. */ tt_int_op(family, OP_EQ, AF_INET); } } smartlist_add(ip->link_specifiers, ls); } ret = ed25519_keypair_generate(&auth_kp, 0); tt_int_op(ret, ==, 0); ip->auth_key_cert = tor_cert_create(blinded_kp, CERT_TYPE_AUTH_HS_IP_KEY, &auth_kp.pubkey, now, HS_DESC_CERT_LIFETIME, CERT_FLAG_INCLUDE_SIGNING_KEY); tt_assert(ip->auth_key_cert); if (legacy) { ip->enc_key.legacy = crypto_pk_new(); ip->enc_key_type = HS_DESC_KEY_TYPE_LEGACY; tt_assert(ip->enc_key.legacy); ret = crypto_pk_generate_key(ip->enc_key.legacy); tt_int_op(ret, ==, 0); } else { ret = curve25519_keypair_generate(&ip->enc_key.curve25519, 0); tt_int_op(ret, ==, 0); ip->enc_key_type = HS_DESC_KEY_TYPE_CURVE25519; } intro_point = ip; done: return intro_point; } /* Return a valid hs_descriptor_t object. If no_ip is set, no introduction * points are added. */ static hs_descriptor_t * helper_build_hs_desc(unsigned int no_ip) { int ret; time_t now = time(NULL); hs_descriptor_t *descp = NULL, *desc = tor_malloc_zero(sizeof(*desc)); desc->plaintext_data.version = HS_DESC_SUPPORTED_FORMAT_VERSION_MAX; ret = ed25519_keypair_generate(&desc->plaintext_data.signing_kp, 0); tt_int_op(ret, ==, 0); ret = ed25519_keypair_generate(&desc->plaintext_data.blinded_kp, 0); tt_int_op(ret, ==, 0); desc->plaintext_data.signing_key_cert = tor_cert_create(&desc->plaintext_data.blinded_kp, CERT_TYPE_SIGNING_HS_DESC, &desc->plaintext_data.signing_kp.pubkey, now, 3600, CERT_FLAG_INCLUDE_SIGNING_KEY); tt_assert(desc->plaintext_data.signing_key_cert); desc->plaintext_data.revision_counter = 42; desc->plaintext_data.lifetime_sec = 3 * 60 * 60; /* Setup encrypted data section. */ desc->encrypted_data.create2_ntor = 1; desc->encrypted_data.auth_types = smartlist_new(); desc->encrypted_data.single_onion_service = 1; smartlist_add(desc->encrypted_data.auth_types, tor_strdup("ed25519")); desc->encrypted_data.intro_points = smartlist_new(); if (!no_ip) { /* Add four intro points. */ smartlist_add(desc->encrypted_data.intro_points, helper_build_intro_point(&desc->plaintext_data.blinded_kp, now, "1.2.3.4", 0)); smartlist_add(desc->encrypted_data.intro_points, helper_build_intro_point(&desc->plaintext_data.blinded_kp, now, "[2600::1]", 0)); smartlist_add(desc->encrypted_data.intro_points, helper_build_intro_point(&desc->plaintext_data.blinded_kp, now, "3.2.1.4", 1)); smartlist_add(desc->encrypted_data.intro_points, helper_build_intro_point(&desc->plaintext_data.blinded_kp, now, "", 1)); } descp = desc; done: return descp; } static void helper_compare_hs_desc(const hs_descriptor_t *desc1, const hs_descriptor_t *desc2) { char *addr1 = NULL, *addr2 = NULL; /* Plaintext data section. */ tt_int_op(desc1->plaintext_data.version, OP_EQ, desc2->plaintext_data.version); tt_uint_op(desc1->plaintext_data.lifetime_sec, OP_EQ, desc2->plaintext_data.lifetime_sec); tt_assert(tor_cert_eq(desc1->plaintext_data.signing_key_cert, desc2->plaintext_data.signing_key_cert)); tt_mem_op(desc1->plaintext_data.signing_kp.pubkey.pubkey, OP_EQ, desc2->plaintext_data.signing_kp.pubkey.pubkey, ED25519_PUBKEY_LEN); tt_mem_op(desc1->plaintext_data.blinded_kp.pubkey.pubkey, OP_EQ, desc2->plaintext_data.blinded_kp.pubkey.pubkey, ED25519_PUBKEY_LEN); tt_u64_op(desc1->plaintext_data.revision_counter, ==, desc2->plaintext_data.revision_counter); /* NOTE: We can't compare the encrypted blob because when encoding the * descriptor, the object is immutable thus we don't update it with the * encrypted blob. As contrast to the decoding process where we populate a * descriptor object. */ /* Encrypted data section. */ tt_uint_op(desc1->encrypted_data.create2_ntor, ==, desc2->encrypted_data.create2_ntor); /* Authentication type. */ tt_int_op(!!desc1->encrypted_data.auth_types, ==, !!desc2->encrypted_data.auth_types); if (desc1->encrypted_data.auth_types && desc2->encrypted_data.auth_types) { tt_int_op(smartlist_len(desc1->encrypted_data.auth_types), ==, smartlist_len(desc2->encrypted_data.auth_types)); for (int i = 0; i < smartlist_len(desc1->encrypted_data.auth_types); i++) { tt_str_op(smartlist_get(desc1->encrypted_data.auth_types, i), OP_EQ, smartlist_get(desc2->encrypted_data.auth_types, i)); } } /* Introduction points. */ { tt_assert(desc1->encrypted_data.intro_points); tt_assert(desc2->encrypted_data.intro_points); tt_int_op(smartlist_len(desc1->encrypted_data.intro_points), ==, smartlist_len(desc2->encrypted_data.intro_points)); for (int i=0; i < smartlist_len(desc1->encrypted_data.intro_points); i++) { hs_desc_intro_point_t *ip1 = smartlist_get(desc1->encrypted_data .intro_points, i), *ip2 = smartlist_get(desc2->encrypted_data .intro_points, i); tt_assert(tor_cert_eq(ip1->auth_key_cert, ip2->auth_key_cert)); tt_int_op(ip1->enc_key_type, OP_EQ, ip2->enc_key_type); tt_assert(ip1->enc_key_type == HS_DESC_KEY_TYPE_LEGACY || ip1->enc_key_type == HS_DESC_KEY_TYPE_CURVE25519); switch (ip1->enc_key_type) { case HS_DESC_KEY_TYPE_LEGACY: tt_int_op(crypto_pk_cmp_keys(ip1->enc_key.legacy, ip2->enc_key.legacy), OP_EQ, 0); break; case HS_DESC_KEY_TYPE_CURVE25519: tt_mem_op(ip1->enc_key.curve25519.pubkey.public_key, OP_EQ, ip2->enc_key.curve25519.pubkey.public_key, CURVE25519_PUBKEY_LEN); break; } tt_int_op(smartlist_len(ip1->link_specifiers), ==, smartlist_len(ip2->link_specifiers)); for (int j = 0; j < smartlist_len(ip1->link_specifiers); j++) { hs_desc_link_specifier_t *ls1 = smartlist_get(ip1->link_specifiers, j), *ls2 = smartlist_get(ip2->link_specifiers, j); tt_int_op(ls1->type, ==, ls2->type); switch (ls1->type) { case LS_IPV4: case LS_IPV6: { addr1 = tor_addr_to_str_dup(&ls1->u.ap.addr); addr2 = tor_addr_to_str_dup(&ls2->u.ap.addr); tt_str_op(addr1, OP_EQ, addr2); tor_free(addr1); tor_free(addr2); tt_int_op(ls1->u.ap.port, ==, ls2->u.ap.port); } break; case LS_LEGACY_ID: tt_mem_op(ls1->u.legacy_id, OP_EQ, ls2->u.legacy_id, sizeof(ls1->u.legacy_id)); break; default: /* Unknown type, caught it and print its value. */ tt_int_op(ls1->type, OP_EQ, -1); } } } } done: tor_free(addr1); tor_free(addr2); } /* Test certificate encoding put in a descriptor. */ static void test_cert_encoding(void *arg) { int ret; char *encoded = NULL; time_t now = time(NULL); ed25519_keypair_t kp; ed25519_public_key_t signed_key; ed25519_secret_key_t secret_key; tor_cert_t *cert = NULL; (void) arg; ret = ed25519_keypair_generate(&kp, 0); tt_int_op(ret, == , 0); ret = ed25519_secret_key_generate(&secret_key, 0); tt_int_op(ret, == , 0); ret = ed25519_public_key_generate(&signed_key, &secret_key); tt_int_op(ret, == , 0); cert = tor_cert_create(&kp, CERT_TYPE_SIGNING_AUTH, &signed_key, now, 3600 * 2, CERT_FLAG_INCLUDE_SIGNING_KEY); tt_assert(cert); /* Test the certificate encoding function. */ ret = tor_cert_encode_ed22519(cert, &encoded); tt_int_op(ret, ==, 0); /* Validated the certificate string. */ { char *end, *pos = encoded; char *b64_cert, buf[256]; size_t b64_cert_len; tor_cert_t *parsed_cert; tt_int_op(strcmpstart(pos, "-----BEGIN ED25519 CERT-----\n"), ==, 0); pos += strlen("-----BEGIN ED25519 CERT-----\n"); /* Isolate the base64 encoded certificate and try to decode it. */ end = strstr(pos, "-----END ED25519 CERT-----"); tt_assert(end); b64_cert = pos; b64_cert_len = end - pos; ret = base64_decode(buf, sizeof(buf), b64_cert, b64_cert_len); tt_int_op(ret, >, 0); /* Parseable? */ parsed_cert = tor_cert_parse((uint8_t *) buf, ret); tt_assert(parsed_cert); /* Signature is valid? */ ret = tor_cert_checksig(parsed_cert, &kp.pubkey, now + 10); tt_int_op(ret, ==, 0); ret = tor_cert_eq(cert, parsed_cert); tt_int_op(ret, ==, 1); /* The cert did have the signing key? */ ret= ed25519_pubkey_eq(&parsed_cert->signing_key, &kp.pubkey); tt_int_op(ret, ==, 1); tor_cert_free(parsed_cert); /* Get to the end part of the certificate. */ pos += b64_cert_len; tt_int_op(strcmpstart(pos, "-----END ED25519 CERT-----"), ==, 0); pos += strlen("-----END ED25519 CERT-----"); } done: tor_cert_free(cert); tor_free(encoded); } /* Test the descriptor padding. */ static void test_descriptor_padding(void *arg) { char *plaintext; size_t plaintext_len, padded_len; uint8_t *padded_plaintext = NULL; /* Example: if l = 129, the ceiled division gives 2 and then multiplied by 128 * to give 256. With l = 127, ceiled division gives 1 then times 128. */ #define PADDING_EXPECTED_LEN(l) \ CEIL_DIV(l, HS_DESC_PLAINTEXT_PADDING_MULTIPLE) * \ HS_DESC_PLAINTEXT_PADDING_MULTIPLE (void) arg; { /* test #1: no padding */ plaintext_len = HS_DESC_PLAINTEXT_PADDING_MULTIPLE; plaintext = tor_malloc(plaintext_len); padded_len = build_plaintext_padding(plaintext, plaintext_len, &padded_plaintext); tt_assert(padded_plaintext); tor_free(plaintext); /* Make sure our padding has been zeroed. */ tt_int_op(tor_mem_is_zero((char *) padded_plaintext + plaintext_len, padded_len - plaintext_len), OP_EQ, 1); tor_free(padded_plaintext); /* Never never have a padded length smaller than the plaintext. */ tt_int_op(padded_len, OP_GE, plaintext_len); tt_int_op(padded_len, OP_EQ, PADDING_EXPECTED_LEN(plaintext_len)); } { /* test #2: one byte padding? */ plaintext_len = HS_DESC_PLAINTEXT_PADDING_MULTIPLE - 1; plaintext = tor_malloc(plaintext_len); padded_plaintext = NULL; padded_len = build_plaintext_padding(plaintext, plaintext_len, &padded_plaintext); tt_assert(padded_plaintext); tor_free(plaintext); /* Make sure our padding has been zeroed. */ tt_int_op(tor_mem_is_zero((char *) padded_plaintext + plaintext_len, padded_len - plaintext_len), OP_EQ, 1); tor_free(padded_plaintext); /* Never never have a padded length smaller than the plaintext. */ tt_int_op(padded_len, OP_GE, plaintext_len); tt_int_op(padded_len, OP_EQ, PADDING_EXPECTED_LEN(plaintext_len)); } { /* test #3: Lots more bytes of padding? */ plaintext_len = HS_DESC_PLAINTEXT_PADDING_MULTIPLE + 1; plaintext = tor_malloc(plaintext_len); padded_plaintext = NULL; padded_len = build_plaintext_padding(plaintext, plaintext_len, &padded_plaintext); tt_assert(padded_plaintext); tor_free(plaintext); /* Make sure our padding has been zeroed. */ tt_int_op(tor_mem_is_zero((char *) padded_plaintext + plaintext_len, padded_len - plaintext_len), OP_EQ, 1); tor_free(padded_plaintext); /* Never never have a padded length smaller than the plaintext. */ tt_int_op(padded_len, OP_GE, plaintext_len); tt_int_op(padded_len, OP_EQ, PADDING_EXPECTED_LEN(plaintext_len)); } done: return; } static void test_link_specifier(void *arg) { ssize_t ret; hs_desc_link_specifier_t spec; smartlist_t *link_specifiers = smartlist_new(); (void) arg; /* Always this port. */ spec.u.ap.port = 42; smartlist_add(link_specifiers, &spec); /* Test IPv4 for starter. */ { char *b64, buf[256]; uint32_t ipv4; link_specifier_t *ls; spec.type = LS_IPV4; ret = tor_addr_parse(&spec.u.ap.addr, "1.2.3.4"); tt_int_op(ret, ==, AF_INET); b64 = encode_link_specifiers(link_specifiers); tt_assert(b64); /* Decode it and validate the format. */ ret = base64_decode(buf, sizeof(buf), b64, strlen(b64)); tt_int_op(ret, >, 0); /* First byte is the number of link specifier. */ tt_int_op(get_uint8(buf), ==, 1); ret = link_specifier_parse(&ls, (uint8_t *) buf + 1, ret - 1); tt_int_op(ret, ==, 8); /* Should be 2 bytes for port and 4 bytes for IPv4. */ tt_int_op(link_specifier_get_ls_len(ls), ==, 6); ipv4 = link_specifier_get_un_ipv4_addr(ls); tt_int_op(tor_addr_to_ipv4h(&spec.u.ap.addr), ==, ipv4); tt_int_op(link_specifier_get_un_ipv4_port(ls), ==, spec.u.ap.port); link_specifier_free(ls); tor_free(b64); } /* Test IPv6. */ { char *b64, buf[256]; uint8_t ipv6[16]; link_specifier_t *ls; spec.type = LS_IPV6; ret = tor_addr_parse(&spec.u.ap.addr, "[1:2:3:4::]"); tt_int_op(ret, ==, AF_INET6); b64 = encode_link_specifiers(link_specifiers); tt_assert(b64); /* Decode it and validate the format. */ ret = base64_decode(buf, sizeof(buf), b64, strlen(b64)); tt_int_op(ret, >, 0); /* First byte is the number of link specifier. */ tt_int_op(get_uint8(buf), ==, 1); ret = link_specifier_parse(&ls, (uint8_t *) buf + 1, ret - 1); tt_int_op(ret, ==, 20); /* Should be 2 bytes for port and 16 bytes for IPv6. */ tt_int_op(link_specifier_get_ls_len(ls), ==, 18); for (unsigned int i = 0; i < sizeof(ipv6); i++) { ipv6[i] = link_specifier_get_un_ipv6_addr(ls, i); } tt_mem_op(tor_addr_to_in6_addr8(&spec.u.ap.addr), ==, ipv6, sizeof(ipv6)); tt_int_op(link_specifier_get_un_ipv6_port(ls), ==, spec.u.ap.port); link_specifier_free(ls); tor_free(b64); } /* Test legacy. */ { char *b64, buf[256]; uint8_t *id; link_specifier_t *ls; spec.type = LS_LEGACY_ID; memset(spec.u.legacy_id, 'Y', sizeof(spec.u.legacy_id)); b64 = encode_link_specifiers(link_specifiers); tt_assert(b64); /* Decode it and validate the format. */ ret = base64_decode(buf, sizeof(buf), b64, strlen(b64)); tt_int_op(ret, >, 0); /* First byte is the number of link specifier. */ tt_int_op(get_uint8(buf), ==, 1); ret = link_specifier_parse(&ls, (uint8_t *) buf + 1, ret - 1); /* 20 bytes digest + 1 byte type + 1 byte len. */ tt_int_op(ret, ==, 22); tt_int_op(link_specifier_getlen_un_legacy_id(ls), OP_EQ, DIGEST_LEN); /* Digest length is 20 bytes. */ tt_int_op(link_specifier_get_ls_len(ls), OP_EQ, DIGEST_LEN); id = link_specifier_getarray_un_legacy_id(ls); tt_mem_op(spec.u.legacy_id, OP_EQ, id, DIGEST_LEN); link_specifier_free(ls); tor_free(b64); } done: smartlist_free(link_specifiers); } static void test_encode_descriptor(void *arg) { int ret; char *encoded = NULL; hs_descriptor_t *desc = helper_build_hs_desc(0); (void) arg; ret = hs_desc_encode_descriptor(desc, &encoded); tt_int_op(ret, ==, 0); tt_assert(encoded); done: hs_descriptor_free(desc); tor_free(encoded); } static void test_decode_descriptor(void *arg) { int ret; char *encoded = NULL; hs_descriptor_t *desc = helper_build_hs_desc(0); hs_descriptor_t *decoded = NULL; hs_descriptor_t *desc_no_ip = NULL; (void) arg; /* Give some bad stuff to the decoding function. */ ret = hs_desc_decode_descriptor("hladfjlkjadf", NULL, &decoded); tt_int_op(ret, OP_EQ, -1); ret = hs_desc_encode_descriptor(desc, &encoded); tt_int_op(ret, ==, 0); tt_assert(encoded); ret = hs_desc_decode_descriptor(encoded, NULL, &decoded); tt_int_op(ret, ==, 0); tt_assert(decoded); helper_compare_hs_desc(desc, decoded); /* Decode a descriptor with _no_ introduction points. */ { desc_no_ip = helper_build_hs_desc(1); tt_assert(desc_no_ip); tor_free(encoded); ret = hs_desc_encode_descriptor(desc_no_ip, &encoded); tt_int_op(ret, ==, 0); tt_assert(encoded); hs_descriptor_free(decoded); ret = hs_desc_decode_descriptor(encoded, NULL, &decoded); tt_int_op(ret, ==, 0); tt_assert(decoded); } done: hs_descriptor_free(desc); hs_descriptor_free(desc_no_ip); hs_descriptor_free(decoded); tor_free(encoded); } static void test_supported_version(void *arg) { int ret; (void) arg; /* Unsupported. */ ret = hs_desc_is_supported_version(42); tt_int_op(ret, OP_EQ, 0); /* To early. */ ret = hs_desc_is_supported_version(HS_DESC_SUPPORTED_FORMAT_VERSION_MIN - 1); tt_int_op(ret, OP_EQ, 0); /* One too new. */ ret = hs_desc_is_supported_version(HS_DESC_SUPPORTED_FORMAT_VERSION_MAX + 1); tt_int_op(ret, OP_EQ, 0); /* Valid version. */ ret = hs_desc_is_supported_version(3); tt_int_op(ret, OP_EQ, 1); done: ; } static void test_encrypted_data_len(void *arg) { int ret; size_t value; (void) arg; /* No length, error. */ ret = encrypted_data_length_is_valid(0); tt_int_op(ret, OP_EQ, 0); /* Not a multiple of our encryption algorithm (thus no padding). It's * suppose to be aligned on HS_DESC_PLAINTEXT_PADDING_MULTIPLE. */ value = HS_DESC_PLAINTEXT_PADDING_MULTIPLE * 10 - 1; ret = encrypted_data_length_is_valid(value); tt_int_op(ret, OP_EQ, 0); /* Valid value. */ value = HS_DESC_PADDED_PLAINTEXT_MAX_LEN + HS_DESC_ENCRYPTED_SALT_LEN + DIGEST256_LEN; ret = encrypted_data_length_is_valid(value); tt_int_op(ret, OP_EQ, 1); /* XXX: Test maximum possible size. */ done: ; } static void test_decode_intro_point(void *arg) { int ret; char *encoded_ip = NULL; size_t len_out; hs_desc_intro_point_t *ip = NULL; hs_descriptor_t *desc = NULL; (void) arg; /* The following certificate expires in 2036. After that, one of the test * will fail because of the expiry time. */ /* Seperate pieces of a valid encoded introduction point. */ const char *intro_point = "introduction-point AQIUMDI5OUYyNjhGQ0E5RDU1Q0QxNTc="; const char *auth_key = "auth-key\n" "-----BEGIN ED25519 CERT-----\n" "AQkACOhAAQW8ltYZMIWpyrfyE/b4Iyi8CNybCwYs6ADk7XfBaxsFAQAgBAD3/BE4\n" "XojGE/N2bW/wgnS9r2qlrkydGyuCKIGayYx3haZ39LD4ZTmSMRxwmplMAqzG/XNP\n" "0Kkpg4p2/VnLFJRdU1SMFo1lgQ4P0bqw7Tgx200fulZ4KUM5z5V7m+a/mgY=\n" "-----END ED25519 CERT-----"; const char *enc_key = "enc-key ntor bpZKLsuhxP6woDQ3yVyjm5gUKSk7RjfAijT2qrzbQk0="; const char *enc_key_legacy = "enc-key legacy\n" "-----BEGIN RSA PUBLIC KEY-----\n" "MIGJAoGBAO4bATcW8kW4h6RQQAKEgg+aXCpF4JwbcO6vGZtzXTDB+HdPVQzwqkbh\n" "XzFM6VGArhYw4m31wcP1Z7IwULir7UMnAFd7Zi62aYfU6l+Y1yAoZ1wzu1XBaAMK\n" "ejpwQinW9nzJn7c2f69fVke3pkhxpNdUZ+vplSA/l9iY+y+v+415AgMBAAE=\n" "-----END RSA PUBLIC KEY-----"; const char *enc_key_cert = "enc-key-certification\n" "-----BEGIN ED25519 CERT-----\n" "AQsACOhZAUpNvCZ1aJaaR49lS6MCdsVkhVGVrRqoj0Y2T4SzroAtAQAgBABFOcGg\n" "lbTt1DF5nKTE/gU3Fr8ZtlCIOhu1A+F5LM7fqCUupfesg0KTHwyIZOYQbJuM5/he\n" "/jDNyLy9woPJdjkxywaY2RPUxGjLYtMQV0E8PUxWyICV+7y52fTCYaKpYQw=\n" "-----END ED25519 CERT-----"; const char *enc_key_cert_legacy = "enc-key-certification\n" "-----BEGIN CROSSCERT-----\n" "Sk28JnVolppHj2VLowJ2xWSFUZWtGqiPRjZPhLOugC0ACOhZgFPA5egeRDUXMM1U\n" "Fn3c7Je0gJS6mVma5FzwlgwggeriF13UZcaT71vEAN/ZJXbxOfQVGMZ0rXuFpjUq\n" "C8CvqmZIwEUaPE1nDFtmnTcucvNS1YQl9nsjH3ejbxc+4yqps/cXh46FmXsm5yz7\n" "NZjBM9U1fbJhlNtOvrkf70K8bLk6\n" "-----END CROSSCERT-----"; (void) enc_key_legacy; (void) enc_key_cert_legacy; /* Start by testing the "decode all intro points" function. */ { char *line; desc = helper_build_hs_desc(0); tt_assert(desc); /* Only try to decode an incomplete introduction point section. */ tor_asprintf(&line, "\n%s", intro_point); ret = decode_intro_points(desc, &desc->encrypted_data, line); tor_free(line); tt_int_op(ret, ==, -1); /* Decode one complete intro point. */ smartlist_t *lines = smartlist_new(); smartlist_add(lines, (char *) intro_point); smartlist_add(lines, (char *) auth_key); smartlist_add(lines, (char *) enc_key); smartlist_add(lines, (char *) enc_key_cert); encoded_ip = smartlist_join_strings(lines, "\n", 0, &len_out); tt_assert(encoded_ip); tor_asprintf(&line, "\n%s", encoded_ip); tor_free(encoded_ip); ret = decode_intro_points(desc, &desc->encrypted_data, line); tor_free(line); smartlist_free(lines); tt_int_op(ret, ==, 0); } /* Try to decode a junk string. */ { hs_descriptor_free(desc); desc = helper_build_hs_desc(0); const char *junk = "this is not a descriptor"; ip = decode_introduction_point(desc, junk); tt_assert(!ip); desc_intro_point_free(ip); ip = NULL; } /* Invalid link specifiers. */ { smartlist_t *lines = smartlist_new(); const char *bad_line = "introduction-point blah"; smartlist_add(lines, (char *) bad_line); smartlist_add(lines, (char *) auth_key); smartlist_add(lines, (char *) enc_key); smartlist_add(lines, (char *) enc_key_cert); encoded_ip = smartlist_join_strings(lines, "\n", 0, &len_out); tt_assert(encoded_ip); ip = decode_introduction_point(desc, encoded_ip); tt_assert(!ip); tor_free(encoded_ip); smartlist_free(lines); desc_intro_point_free(ip); ip = NULL; } /* Invalid auth key type. */ { smartlist_t *lines = smartlist_new(); /* Try to put a valid object that our tokenize function will be able to * parse but that has nothing to do with the auth_key. */ const char *bad_line = "auth-key\n" "-----BEGIN UNICORN CERT-----\n" "MIGJAoGBAO4bATcW8kW4h6RQQAKEgg+aXCpF4JwbcO6vGZtzXTDB+HdPVQzwqkbh\n" "XzFM6VGArhYw4m31wcP1Z7IwULir7UMnAFd7Zi62aYfU6l+Y1yAoZ1wzu1XBaAMK\n" "ejpwQinW9nzJn7c2f69fVke3pkhxpNdUZ+vplSA/l9iY+y+v+415AgMBAAE=\n" "-----END UNICORN CERT-----"; /* Build intro point text. */ smartlist_add(lines, (char *) intro_point); smartlist_add(lines, (char *) bad_line); smartlist_add(lines, (char *) enc_key); smartlist_add(lines, (char *) enc_key_cert); encoded_ip = smartlist_join_strings(lines, "\n", 0, &len_out); tt_assert(encoded_ip); ip = decode_introduction_point(desc, encoded_ip); tt_assert(!ip); tor_free(encoded_ip); smartlist_free(lines); } /* Invalid enc-key. */ { smartlist_t *lines = smartlist_new(); const char *bad_line = "enc-key unicorn bpZKLsuhxP6woDQ3yVyjm5gUKSk7RjfAijT2qrzbQk0="; /* Build intro point text. */ smartlist_add(lines, (char *) intro_point); smartlist_add(lines, (char *) auth_key); smartlist_add(lines, (char *) bad_line); smartlist_add(lines, (char *) enc_key_cert); encoded_ip = smartlist_join_strings(lines, "\n", 0, &len_out); tt_assert(encoded_ip); ip = decode_introduction_point(desc, encoded_ip); tt_assert(!ip); tor_free(encoded_ip); smartlist_free(lines); } /* Invalid enc-key object. */ { smartlist_t *lines = smartlist_new(); const char *bad_line = "enc-key ntor"; /* Build intro point text. */ smartlist_add(lines, (char *) intro_point); smartlist_add(lines, (char *) auth_key); smartlist_add(lines, (char *) bad_line); smartlist_add(lines, (char *) enc_key_cert); encoded_ip = smartlist_join_strings(lines, "\n", 0, &len_out); tt_assert(encoded_ip); ip = decode_introduction_point(desc, encoded_ip); tt_assert(!ip); tor_free(encoded_ip); smartlist_free(lines); } /* Invalid enc-key base64 curv25519 key. */ { smartlist_t *lines = smartlist_new(); const char *bad_line = "enc-key ntor blah==="; /* Build intro point text. */ smartlist_add(lines, (char *) intro_point); smartlist_add(lines, (char *) auth_key); smartlist_add(lines, (char *) bad_line); smartlist_add(lines, (char *) enc_key_cert); encoded_ip = smartlist_join_strings(lines, "\n", 0, &len_out); tt_assert(encoded_ip); ip = decode_introduction_point(desc, encoded_ip); tt_assert(!ip); tor_free(encoded_ip); smartlist_free(lines); } /* Invalid enc-key invalid legacy. */ { smartlist_t *lines = smartlist_new(); const char *bad_line = "enc-key legacy blah==="; /* Build intro point text. */ smartlist_add(lines, (char *) intro_point); smartlist_add(lines, (char *) auth_key); smartlist_add(lines, (char *) bad_line); smartlist_add(lines, (char *) enc_key_cert); encoded_ip = smartlist_join_strings(lines, "\n", 0, &len_out); tt_assert(encoded_ip); ip = decode_introduction_point(desc, encoded_ip); tt_assert(!ip); tor_free(encoded_ip); smartlist_free(lines); } /* Valid object. */ { smartlist_t *lines = smartlist_new(); /* Build intro point text. */ smartlist_add(lines, (char *) intro_point); smartlist_add(lines, (char *) auth_key); smartlist_add(lines, (char *) enc_key); smartlist_add(lines, (char *) enc_key_cert); encoded_ip = smartlist_join_strings(lines, "\n", 0, &len_out); tt_assert(encoded_ip); ip = decode_introduction_point(desc, encoded_ip); tt_assert(ip); tor_free(encoded_ip); smartlist_free(lines); } done: hs_descriptor_free(desc); desc_intro_point_free(ip); } static void test_decode_plaintext(void *arg) { int ret; hs_desc_plaintext_data_t desc_plaintext; const char *bad_value = "unicorn"; (void) arg; #define template \ "hs-descriptor %s\n" \ "descriptor-lifetime %s\n" \ "descriptor-signing-key-cert\n" \ "-----BEGIN ED25519 CERT-----\n" \ "AQgABjvPAQaG3g+dc6oV/oJV4ODAtkvx56uBnPtBT9mYVuHVOhn7AQAgBABUg3mQ\n" \ "myBr4bu5LCr53wUEbW2EXui01CbUgU7pfo9LvJG3AcXRojj6HlfsUs9BkzYzYdjF\n" \ "A69Apikgu0ewHYkFFASt7Il+gB3w6J8YstQJZT7dtbtl+doM7ug8B68Qdg8=\n" \ "-----END ED25519 CERT-----\n" \ "revision-counter %s\n" \ "encrypted\n" \ "-----BEGIN %s-----\n" \ "UNICORN\n" \ "-----END MESSAGE-----\n" \ "signature m20WJH5agqvwhq7QeuEZ1mYyPWQDO+eJOZUjLhAiKu8DbL17DsDfJE6kXbWy" \ "HimbNj2we0enV3cCOOAsmPOaAw\n" /* Invalid version. */ { char *plaintext; tor_asprintf(&plaintext, template, bad_value, "180", "42", "MESSAGE"); ret = hs_desc_decode_plaintext(plaintext, &desc_plaintext); tor_free(plaintext); tt_int_op(ret, OP_EQ, -1); } /* Missing fields. */ { const char *plaintext = "hs-descriptor 3\n"; ret = hs_desc_decode_plaintext(plaintext, &desc_plaintext); tt_int_op(ret, OP_EQ, -1); } /* Max length. */ { size_t big = 64000; /* Must always be bigger than HS_DESC_MAX_LEN. */ tt_int_op(HS_DESC_MAX_LEN, <, big); char *plaintext = tor_malloc_zero(big); memset(plaintext, 'a', big); plaintext[big - 1] = '\0'; ret = hs_desc_decode_plaintext(plaintext, &desc_plaintext); tor_free(plaintext); tt_int_op(ret, OP_EQ, -1); } /* Bad lifetime value. */ { char *plaintext; tor_asprintf(&plaintext, template, "3", bad_value, "42", "MESSAGE"); ret = hs_desc_decode_plaintext(plaintext, &desc_plaintext); tor_free(plaintext); tt_int_op(ret, OP_EQ, -1); } /* Huge lifetime value. */ { char *plaintext; tor_asprintf(&plaintext, template, "3", "7181615", "42", "MESSAGE"); ret = hs_desc_decode_plaintext(plaintext, &desc_plaintext); tor_free(plaintext); tt_int_op(ret, OP_EQ, -1); } /* Invalid encrypted section. */ { char *plaintext; tor_asprintf(&plaintext, template, "3", "180", "42", bad_value); ret = hs_desc_decode_plaintext(plaintext, &desc_plaintext); tor_free(plaintext); tt_int_op(ret, OP_EQ, -1); } /* Invalid revision counter. */ { char *plaintext; tor_asprintf(&plaintext, template, "3", "180", bad_value, "MESSAGE"); ret = hs_desc_decode_plaintext(plaintext, &desc_plaintext); tor_free(plaintext); tt_int_op(ret, OP_EQ, -1); } done: ; } static void test_validate_cert(void *arg) { int ret; time_t now = time(NULL); ed25519_keypair_t kp; tor_cert_t *cert = NULL; (void) arg; ret = ed25519_keypair_generate(&kp, 0); tt_int_op(ret, ==, 0); /* Cert of type CERT_TYPE_AUTH_HS_IP_KEY. */ cert = tor_cert_create(&kp, CERT_TYPE_AUTH_HS_IP_KEY, &kp.pubkey, now, 3600, CERT_FLAG_INCLUDE_SIGNING_KEY); tt_assert(cert); /* Test with empty certificate. */ ret = cert_is_valid(NULL, CERT_TYPE_AUTH_HS_IP_KEY, "unicorn"); tt_int_op(ret, OP_EQ, 0); /* Test with a bad type. */ ret = cert_is_valid(cert, CERT_TYPE_SIGNING_HS_DESC, "unicorn"); tt_int_op(ret, OP_EQ, 0); /* Normal validation. */ ret = cert_is_valid(cert, CERT_TYPE_AUTH_HS_IP_KEY, "unicorn"); tt_int_op(ret, OP_EQ, 1); /* Break signing key so signature verification will fails. */ memset(&cert->signing_key, 0, sizeof(cert->signing_key)); ret = cert_is_valid(cert, CERT_TYPE_AUTH_HS_IP_KEY, "unicorn"); tt_int_op(ret, OP_EQ, 0); tor_cert_free(cert); /* Try a cert without including the signing key. */ cert = tor_cert_create(&kp, CERT_TYPE_AUTH_HS_IP_KEY, &kp.pubkey, now, 3600, 0); tt_assert(cert); /* Test with a bad type. */ ret = cert_is_valid(cert, CERT_TYPE_AUTH_HS_IP_KEY, "unicorn"); tt_int_op(ret, OP_EQ, 0); done: tor_cert_free(cert); } static void test_desc_signature(void *arg) { int ret; char *data = NULL, *desc = NULL; char sig_b64[ED25519_SIG_BASE64_LEN + 1]; ed25519_keypair_t kp; ed25519_signature_t sig; (void) arg; ed25519_keypair_generate(&kp, 0); /* Setup a phoony descriptor but with a valid signature token that is the * signature is verifiable. */ tor_asprintf(&data, "This is a signed descriptor\n"); ret = ed25519_sign_prefixed(&sig, (const uint8_t *) data, strlen(data), "Tor onion service descriptor sig v3", &kp); tt_int_op(ret, ==, 0); ret = ed25519_signature_to_base64(sig_b64, &sig); tt_int_op(ret, ==, 0); /* Build the descriptor that should be valid. */ tor_asprintf(&desc, "%ssignature %s\n", data, sig_b64); ret = desc_sig_is_valid(sig_b64, &kp, desc, strlen(desc)); tt_int_op(ret, ==, 1); /* Junk signature. */ ret = desc_sig_is_valid("JUNK", &kp, desc, strlen(desc)); tt_int_op(ret, ==, 0); done: tor_free(desc); tor_free(data); } struct testcase_t hs_descriptor[] = { /* Encoding tests. */ { "cert_encoding", test_cert_encoding, TT_FORK, NULL, NULL }, { "link_specifier", test_link_specifier, TT_FORK, NULL, NULL }, { "encode_descriptor", test_encode_descriptor, TT_FORK, NULL, NULL }, { "descriptor_padding", test_descriptor_padding, TT_FORK, NULL, NULL }, /* Decoding tests. */ { "decode_descriptor", test_decode_descriptor, TT_FORK, NULL, NULL }, { "encrypted_data_len", test_encrypted_data_len, TT_FORK, NULL, NULL }, { "decode_intro_point", test_decode_intro_point, TT_FORK, NULL, NULL }, { "decode_plaintext", test_decode_plaintext, TT_FORK, NULL, NULL }, /* Misc. */ { "version", test_supported_version, TT_FORK, NULL, NULL }, { "validate_cert", test_validate_cert, TT_FORK, NULL, NULL }, { "desc_signature", test_desc_signature, TT_FORK, NULL, NULL }, END_OF_TESTCASES };