/* Copyright (c) 2001-2004, Roger Dingledine. * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson. * Copyright (c) 2007-2008, The Tor Project, Inc. */ /* See LICENSE for licensing information */ /* Ordinarily defined in tor_main.c; this bit is just here to provide one * since we're not linking to tor_main.c */ const char tor_svn_revision[] = ""; /** * \file test.c * \brief Unit tests for many pieces of the lower level Tor modules. **/ #include "orconfig.h" #include #ifdef HAVE_FCNTL_H #include #endif #ifdef MS_WINDOWS /* For mkdir() */ #include #else #include #endif /* These macros pull in declarations for some functions and structures that * are typically file-private. */ #define BUFFERS_PRIVATE #define CONFIG_PRIVATE #define CONTROL_PRIVATE #define CRYPTO_PRIVATE #define DIRSERV_PRIVATE #define DIRVOTE_PRIVATE #define GEOIP_PRIVATE #define MEMPOOL_PRIVATE #define ROUTER_PRIVATE #include "or.h" #include "test.h" #include "torgzip.h" #include "mempool.h" #include "memarea.h" #ifdef USE_DMALLOC #include #include #endif /** Set to true if any unit test has failed. Mostly, this is set by the macros * in test.h */ int have_failed = 0; /** Temporary directory (set up by setup_directory) under which we store all * our files during testing. */ static char temp_dir[256]; /** Select and create the temporary directory we'll use to run our unit tests. * Store it in temp_dir. Exit immediately if we can't create it. * idempotent. */ static void setup_directory(void) { static int is_setup = 0; int r; if (is_setup) return; #ifdef MS_WINDOWS // XXXX tor_snprintf(temp_dir, sizeof(temp_dir), "c:\\windows\\temp\\tor_test_%d", (int)getpid()); r = mkdir(temp_dir); #else tor_snprintf(temp_dir, sizeof(temp_dir), "/tmp/tor_test_%d", (int) getpid()); r = mkdir(temp_dir, 0700); #endif if (r) { fprintf(stderr, "Can't create directory %s:", temp_dir); perror(""); exit(1); } is_setup = 1; } /** Return a filename relative to our testing temporary directory */ static const char * get_fname(const char *name) { static char buf[1024]; setup_directory(); tor_snprintf(buf,sizeof(buf),"%s/%s",temp_dir,name); return buf; } /** Remove all files stored under the temporary directory, and the directory * itself. */ static void remove_directory(void) { smartlist_t *elements = tor_listdir(temp_dir); if (elements) { SMARTLIST_FOREACH(elements, const char *, cp, { size_t len = strlen(cp)+strlen(temp_dir)+16; char *tmp = tor_malloc(len); tor_snprintf(tmp, len, "%s"PATH_SEPARATOR"%s", temp_dir, cp); unlink(tmp); tor_free(tmp); }); SMARTLIST_FOREACH(elements, char *, cp, tor_free(cp)); smartlist_free(elements); } rmdir(temp_dir); } /** Define this if unit tests spend too much time generating public keys*/ #undef CACHE_GENERATED_KEYS static crypto_pk_env_t *pregen_keys[5] = {NULL, NULL, NULL, NULL, NULL}; #define N_PREGEN_KEYS ((int)(sizeof(pregen_keys)/sizeof(pregen_keys[0]))) /** Generate and return a new keypair for use in unit tests. If we're using * the key cache optimization, we might reuse keys: we only guarantee that * keys made with distinct values for idx are different. The value of * idx must be at least 0, and less than N_PREGEN_KEYS. */ static crypto_pk_env_t * pk_generate(int idx) { #ifdef CACHE_GENERATED_KEYS tor_assert(idx < N_PREGEN_KEYS); if (! pregen_keys[idx]) { pregen_keys[idx] = crypto_new_pk_env(); tor_assert(!crypto_pk_generate_key(pregen_keys[idx])); } return crypto_pk_dup_key(pregen_keys[idx]); #else crypto_pk_env_t *result; (void) idx; result = crypto_new_pk_env(); tor_assert(!crypto_pk_generate_key(result)); return result; #endif } /** Free all storage used for the cached key optimization. */ static void free_pregenerated_keys(void) { unsigned idx; for (idx = 0; idx < N_PREGEN_KEYS; ++idx) { if (pregen_keys[idx]) { crypto_free_pk_env(pregen_keys[idx]); pregen_keys[idx] = NULL; } } } /** Run unit tests for buffers.c */ static void test_buffers(void) { char str[256]; char str2[256]; buf_t *buf = NULL, *buf2 = NULL; const char *cp; int j; size_t r; /**** * buf_new ****/ if (!(buf = buf_new())) test_fail(); //test_eq(buf_capacity(buf), 4096); test_eq(buf_datalen(buf), 0); /**** * General pointer frobbing */ for (j=0;j<256;++j) { str[j] = (char)j; } write_to_buf(str, 256, buf); write_to_buf(str, 256, buf); test_eq(buf_datalen(buf), 512); fetch_from_buf(str2, 200, buf); test_memeq(str, str2, 200); test_eq(buf_datalen(buf), 312); memset(str2, 0, sizeof(str2)); fetch_from_buf(str2, 256, buf); test_memeq(str+200, str2, 56); test_memeq(str, str2+56, 200); test_eq(buf_datalen(buf), 56); memset(str2, 0, sizeof(str2)); /* Okay, now we should be 512 bytes into the 4096-byte buffer. If we add * another 3584 bytes, we hit the end. */ for (j=0;j<15;++j) { write_to_buf(str, 256, buf); } assert_buf_ok(buf); test_eq(buf_datalen(buf), 3896); fetch_from_buf(str2, 56, buf); test_eq(buf_datalen(buf), 3840); test_memeq(str+200, str2, 56); for (j=0;j<15;++j) { memset(str2, 0, sizeof(str2)); fetch_from_buf(str2, 256, buf); test_memeq(str, str2, 256); } test_eq(buf_datalen(buf), 0); buf_free(buf); buf = NULL; /* Okay, now make sure growing can work. */ buf = buf_new_with_capacity(16); //test_eq(buf_capacity(buf), 16); write_to_buf(str+1, 255, buf); //test_eq(buf_capacity(buf), 256); fetch_from_buf(str2, 254, buf); test_memeq(str+1, str2, 254); //test_eq(buf_capacity(buf), 256); assert_buf_ok(buf); write_to_buf(str, 32, buf); //test_eq(buf_capacity(buf), 256); assert_buf_ok(buf); write_to_buf(str, 256, buf); assert_buf_ok(buf); //test_eq(buf_capacity(buf), 512); test_eq(buf_datalen(buf), 33+256); fetch_from_buf(str2, 33, buf); test_eq(*str2, str[255]); test_memeq(str2+1, str, 32); //test_eq(buf_capacity(buf), 512); test_eq(buf_datalen(buf), 256); fetch_from_buf(str2, 256, buf); test_memeq(str, str2, 256); /* now try shrinking: case 1. */ buf_free(buf); buf = buf_new_with_capacity(33668); for (j=0;j<67;++j) { write_to_buf(str,255, buf); } //test_eq(buf_capacity(buf), 33668); test_eq(buf_datalen(buf), 17085); for (j=0; j < 40; ++j) { fetch_from_buf(str2, 255,buf); test_memeq(str2, str, 255); } /* now try shrinking: case 2. */ buf_free(buf); buf = buf_new_with_capacity(33668); for (j=0;j<67;++j) { write_to_buf(str,255, buf); } for (j=0; j < 20; ++j) { fetch_from_buf(str2, 255,buf); test_memeq(str2, str, 255); } for (j=0;j<80;++j) { write_to_buf(str,255, buf); } //test_eq(buf_capacity(buf),33668); for (j=0; j < 120; ++j) { fetch_from_buf(str2, 255,buf); test_memeq(str2, str, 255); } /* Move from buf to buf. */ buf_free(buf); buf = buf_new_with_capacity(4096); buf2 = buf_new_with_capacity(4096); for (j=0;j<100;++j) write_to_buf(str, 255, buf); test_eq(buf_datalen(buf), 25500); for (j=0;j<100;++j) { r = 10; move_buf_to_buf(buf2, buf, &r); test_eq(r, 0); } test_eq(buf_datalen(buf), 24500); test_eq(buf_datalen(buf2), 1000); for (j=0;j<3;++j) { fetch_from_buf(str2, 255, buf2); test_memeq(str2, str, 255); } r = 8192; /*big move*/ move_buf_to_buf(buf2, buf, &r); test_eq(r, 0); r = 30000; /* incomplete move */ move_buf_to_buf(buf2, buf, &r); test_eq(r, 13692); for (j=0;j<97;++j) { fetch_from_buf(str2, 255, buf2); test_memeq(str2, str, 255); } buf_free(buf); buf_free(buf2); buf = buf2 = NULL; buf = buf_new_with_capacity(5); cp = "Testing. This is a moderately long Testing string."; for (j = 0; cp[j]; j++) write_to_buf(cp+j, 1, buf); test_eq(0, buf_find_string_offset(buf, "Testing", 7)); test_eq(1, buf_find_string_offset(buf, "esting", 6)); test_eq(1, buf_find_string_offset(buf, "est", 3)); test_eq(39, buf_find_string_offset(buf, "ing str", 7)); test_eq(35, buf_find_string_offset(buf, "Testing str", 11)); test_eq(32, buf_find_string_offset(buf, "ng ", 3)); test_eq(43, buf_find_string_offset(buf, "string.", 7)); test_eq(-1, buf_find_string_offset(buf, "shrdlu", 6)); test_eq(-1, buf_find_string_offset(buf, "Testing thing", 13)); test_eq(-1, buf_find_string_offset(buf, "ngx", 3)); buf_free(buf); buf = NULL; #if 0 { int s; int eof; int i; buf_t *buf2; /**** * read_to_buf ****/ s = open(get_fname("data"), O_WRONLY|O_CREAT|O_TRUNC, 0600); write(s, str, 256); close(s); s = open(get_fname("data"), O_RDONLY, 0); eof = 0; errno = 0; /* XXXX */ i = read_to_buf(s, 10, buf, &eof); printf("%s\n", strerror(errno)); test_eq(i, 10); test_eq(eof, 0); //test_eq(buf_capacity(buf), 4096); test_eq(buf_datalen(buf), 10); test_memeq(str, (char*)_buf_peek_raw_buffer(buf), 10); /* Test reading 0 bytes. */ i = read_to_buf(s, 0, buf, &eof); //test_eq(buf_capacity(buf), 512*1024); test_eq(buf_datalen(buf), 10); test_eq(eof, 0); test_eq(i, 0); /* Now test when buffer is filled exactly. */ buf2 = buf_new_with_capacity(6); i = read_to_buf(s, 6, buf2, &eof); //test_eq(buf_capacity(buf2), 6); test_eq(buf_datalen(buf2), 6); test_eq(eof, 0); test_eq(i, 6); test_memeq(str+10, (char*)_buf_peek_raw_buffer(buf2), 6); buf_free(buf2); buf2 = NULL; /* Now test when buffer is filled with more data to read. */ buf2 = buf_new_with_capacity(32); i = read_to_buf(s, 128, buf2, &eof); //test_eq(buf_capacity(buf2), 128); test_eq(buf_datalen(buf2), 32); test_eq(eof, 0); test_eq(i, 32); buf_free(buf2); buf2 = NULL; /* Now read to eof. */ test_assert(buf_capacity(buf) > 256); i = read_to_buf(s, 1024, buf, &eof); test_eq(i, (256-32-10-6)); test_eq(buf_capacity(buf), MAX_BUF_SIZE); test_eq(buf_datalen(buf), 256-6-32); test_memeq(str, (char*)_buf_peek_raw_buffer(buf), 10); /* XXX Check rest. */ test_eq(eof, 0); i = read_to_buf(s, 1024, buf, &eof); test_eq(i, 0); test_eq(buf_capacity(buf), MAX_BUF_SIZE); test_eq(buf_datalen(buf), 256-6-32); test_eq(eof, 1); } #endif done: if (buf) buf_free(buf); if (buf2) buf_free(buf2); } /** Run unit tests for Diffie-Hellman functionality. */ static void test_crypto_dh(void) { crypto_dh_env_t *dh1 = crypto_dh_new(); crypto_dh_env_t *dh2 = crypto_dh_new(); char p1[DH_BYTES]; char p2[DH_BYTES]; char s1[DH_BYTES]; char s2[DH_BYTES]; int s1len, s2len; test_eq(crypto_dh_get_bytes(dh1), DH_BYTES); test_eq(crypto_dh_get_bytes(dh2), DH_BYTES); memset(p1, 0, DH_BYTES); memset(p2, 0, DH_BYTES); test_memeq(p1, p2, DH_BYTES); test_assert(! crypto_dh_get_public(dh1, p1, DH_BYTES)); test_memneq(p1, p2, DH_BYTES); test_assert(! crypto_dh_get_public(dh2, p2, DH_BYTES)); test_memneq(p1, p2, DH_BYTES); memset(s1, 0, DH_BYTES); memset(s2, 0xFF, DH_BYTES); s1len = crypto_dh_compute_secret(dh1, p2, DH_BYTES, s1, 50); s2len = crypto_dh_compute_secret(dh2, p1, DH_BYTES, s2, 50); test_assert(s1len > 0); test_eq(s1len, s2len); test_memeq(s1, s2, s1len); { /* XXXX Now fabricate some bad values and make sure they get caught, * Check 0, 1, N-1, >= N, etc. */ } done: crypto_dh_free(dh1); crypto_dh_free(dh2); } /** Run unit tests for our random number generation function and its wrappers. */ static void test_crypto_rng(void) { int i, j, allok; char data1[100], data2[100]; /* Try out RNG. */ test_assert(! crypto_seed_rng(0)); crypto_rand(data1, 100); crypto_rand(data2, 100); test_memneq(data1,data2,100); allok = 1; for (i = 0; i < 100; ++i) { uint64_t big; char *host; j = crypto_rand_int(100); if (i < 0 || i >= 100) allok = 0; big = crypto_rand_uint64(U64_LITERAL(1)<<40); if (big >= (U64_LITERAL(1)<<40)) allok = 0; big = crypto_rand_uint64(U64_LITERAL(5)); if (big >= 5) allok = 0; host = crypto_random_hostname(3,8,"www.",".onion"); if (strcmpstart(host,"www.") || strcmpend(host,".onion") || strlen(host) < 13 || strlen(host) > 18) allok = 0; tor_free(host); } test_assert(allok); done: ; } /** Run unit tests for our AES functionality */ static void test_crypto_aes(void) { char *data1 = NULL, *data2 = NULL, *data3 = NULL; crypto_cipher_env_t *env1 = NULL, *env2 = NULL; int i, j; data1 = tor_malloc(1024); data2 = tor_malloc(1024); data3 = tor_malloc(1024); /* Now, test encryption and decryption with stream cipher. */ data1[0]='\0'; for (i = 1023; i>0; i -= 35) strncat(data1, "Now is the time for all good onions", i); memset(data2, 0, 1024); memset(data3, 0, 1024); env1 = crypto_new_cipher_env(); test_neq(env1, 0); env2 = crypto_new_cipher_env(); test_neq(env2, 0); j = crypto_cipher_generate_key(env1); crypto_cipher_set_key(env2, crypto_cipher_get_key(env1)); crypto_cipher_encrypt_init_cipher(env1); crypto_cipher_decrypt_init_cipher(env2); /* Try encrypting 512 chars. */ crypto_cipher_encrypt(env1, data2, data1, 512); crypto_cipher_decrypt(env2, data3, data2, 512); test_memeq(data1, data3, 512); test_memneq(data1, data2, 512); /* Now encrypt 1 at a time, and get 1 at a time. */ for (j = 512; j < 560; ++j) { crypto_cipher_encrypt(env1, data2+j, data1+j, 1); } for (j = 512; j < 560; ++j) { crypto_cipher_decrypt(env2, data3+j, data2+j, 1); } test_memeq(data1, data3, 560); /* Now encrypt 3 at a time, and get 5 at a time. */ for (j = 560; j < 1024-5; j += 3) { crypto_cipher_encrypt(env1, data2+j, data1+j, 3); } for (j = 560; j < 1024-5; j += 5) { crypto_cipher_decrypt(env2, data3+j, data2+j, 5); } test_memeq(data1, data3, 1024-5); /* Now make sure that when we encrypt with different chunk sizes, we get the same results. */ crypto_free_cipher_env(env2); env2 = NULL; memset(data3, 0, 1024); env2 = crypto_new_cipher_env(); test_neq(env2, 0); crypto_cipher_set_key(env2, crypto_cipher_get_key(env1)); crypto_cipher_encrypt_init_cipher(env2); for (j = 0; j < 1024-16; j += 17) { crypto_cipher_encrypt(env2, data3+j, data1+j, 17); } for (j= 0; j < 1024-16; ++j) { if (data2[j] != data3[j]) { printf("%d: %d\t%d\n", j, (int) data2[j], (int) data3[j]); } } test_memeq(data2, data3, 1024-16); crypto_free_cipher_env(env1); env1 = NULL; crypto_free_cipher_env(env2); env2 = NULL; /* NIST test vector for aes. */ env1 = crypto_new_cipher_env(); /* IV starts at 0 */ crypto_cipher_set_key(env1, "\x80\x00\x00\x00\x00\x00\x00\x00" "\x00\x00\x00\x00\x00\x00\x00\x00"); crypto_cipher_encrypt_init_cipher(env1); crypto_cipher_encrypt(env1, data1, "\x00\x00\x00\x00\x00\x00\x00\x00" "\x00\x00\x00\x00\x00\x00\x00\x00", 16); test_memeq_hex(data1, "0EDD33D3C621E546455BD8BA1418BEC8"); /* Now test rollover. All these values are originally from a python * script. */ crypto_cipher_set_iv(env1, "\x00\x00\x00\x00\x00\x00\x00\x00" "\xff\xff\xff\xff\xff\xff\xff\xff"); memset(data2, 0, 1024); crypto_cipher_encrypt(env1, data1, data2, 32); test_memeq_hex(data1, "335fe6da56f843199066c14a00a40231" "cdd0b917dbc7186908a6bfb5ffd574d3"); crypto_cipher_set_iv(env1, "\x00\x00\x00\x00\xff\xff\xff\xff" "\xff\xff\xff\xff\xff\xff\xff\xff"); memset(data2, 0, 1024); crypto_cipher_encrypt(env1, data1, data2, 32); test_memeq_hex(data1, "e627c6423fa2d77832a02b2794094b73" "3e63c721df790d2c6469cc1953a3ffac"); crypto_cipher_set_iv(env1, "\xff\xff\xff\xff\xff\xff\xff\xff" "\xff\xff\xff\xff\xff\xff\xff\xff"); memset(data2, 0, 1024); crypto_cipher_encrypt(env1, data1, data2, 32); test_memeq_hex(data1, "2aed2bff0de54f9328efd070bf48f70a" "0EDD33D3C621E546455BD8BA1418BEC8"); /* Now check rollover on inplace cipher. */ crypto_cipher_set_iv(env1, "\xff\xff\xff\xff\xff\xff\xff\xff" "\xff\xff\xff\xff\xff\xff\xff\xff"); crypto_cipher_crypt_inplace(env1, data2, 64); test_memeq_hex(data2, "2aed2bff0de54f9328efd070bf48f70a" "0EDD33D3C621E546455BD8BA1418BEC8" "93e2c5243d6839eac58503919192f7ae" "1908e67cafa08d508816659c2e693191"); crypto_cipher_set_iv(env1, "\xff\xff\xff\xff\xff\xff\xff\xff" "\xff\xff\xff\xff\xff\xff\xff\xff"); crypto_cipher_crypt_inplace(env1, data2, 64); test_assert(tor_mem_is_zero(data2, 64)); done: if (env1) crypto_free_cipher_env(env1); if (env2) crypto_free_cipher_env(env2); tor_free(data1); tor_free(data2); tor_free(data3); } /** Run unit tests for our SHA-1 functionality */ static void test_crypto_sha(void) { crypto_digest_env_t *d1 = NULL, *d2 = NULL; int i; char key[80]; char digest[20]; char data[50]; char d_out1[DIGEST_LEN], d_out2[DIGEST_LEN]; /* Test SHA-1 with a test vector from the specification. */ i = crypto_digest(data, "abc", 3); test_memeq_hex(data, "A9993E364706816ABA3E25717850C26C9CD0D89D"); /* Test HMAC-SHA-1 with test cases from RFC2202. */ /* Case 1. */ memset(key, 0x0b, 20); crypto_hmac_sha1(digest, key, 20, "Hi There", 8); test_streq(hex_str(digest, 20), "B617318655057264E28BC0B6FB378C8EF146BE00"); /* Case 2. */ crypto_hmac_sha1(digest, "Jefe", 4, "what do ya want for nothing?", 28); test_streq(hex_str(digest, 20), "EFFCDF6AE5EB2FA2D27416D5F184DF9C259A7C79"); /* Case 4. */ base16_decode(key, 25, "0102030405060708090a0b0c0d0e0f10111213141516171819", 50); memset(data, 0xcd, 50); crypto_hmac_sha1(digest, key, 25, data, 50); test_streq(hex_str(digest, 20), "4C9007F4026250C6BC8414F9BF50C86C2D7235DA"); /* Case . */ memset(key, 0xaa, 80); crypto_hmac_sha1(digest, key, 80, "Test Using Larger Than Block-Size Key - Hash Key First", 54); test_streq(hex_str(digest, 20), "AA4AE5E15272D00E95705637CE8A3B55ED402112"); /* Incremental digest code. */ d1 = crypto_new_digest_env(); test_assert(d1); crypto_digest_add_bytes(d1, "abcdef", 6); d2 = crypto_digest_dup(d1); test_assert(d2); crypto_digest_add_bytes(d2, "ghijkl", 6); crypto_digest_get_digest(d2, d_out1, sizeof(d_out1)); crypto_digest(d_out2, "abcdefghijkl", 12); test_memeq(d_out1, d_out2, DIGEST_LEN); crypto_digest_assign(d2, d1); crypto_digest_add_bytes(d2, "mno", 3); crypto_digest_get_digest(d2, d_out1, sizeof(d_out1)); crypto_digest(d_out2, "abcdefmno", 9); test_memeq(d_out1, d_out2, DIGEST_LEN); crypto_digest_get_digest(d1, d_out1, sizeof(d_out1)); crypto_digest(d_out2, "abcdef", 6); test_memeq(d_out1, d_out2, DIGEST_LEN); done: if (d1) crypto_free_digest_env(d1); if (d2) crypto_free_digest_env(d2); } /** Run unit tests for our public key crypto functions */ static void test_crypto_pk(void) { crypto_pk_env_t *pk1 = NULL, *pk2 = NULL; char *encoded = NULL; char data1[1024], data2[1024], data3[1024]; size_t size; int i, j, p, len; /* Public-key ciphers */ pk1 = pk_generate(0); pk2 = crypto_new_pk_env(); test_assert(pk1 && pk2); test_assert(! crypto_pk_write_public_key_to_string(pk1, &encoded, &size)); test_assert(! crypto_pk_read_public_key_from_string(pk2, encoded, size)); test_eq(0, crypto_pk_cmp_keys(pk1, pk2)); test_eq(128, crypto_pk_keysize(pk1)); test_eq(128, crypto_pk_keysize(pk2)); test_eq(128, crypto_pk_public_encrypt(pk2, data1, "Hello whirled.", 15, PK_PKCS1_OAEP_PADDING)); test_eq(128, crypto_pk_public_encrypt(pk1, data2, "Hello whirled.", 15, PK_PKCS1_OAEP_PADDING)); /* oaep padding should make encryption not match */ test_memneq(data1, data2, 128); test_eq(15, crypto_pk_private_decrypt(pk1, data3, data1, 128, PK_PKCS1_OAEP_PADDING,1)); test_streq(data3, "Hello whirled."); memset(data3, 0, 1024); test_eq(15, crypto_pk_private_decrypt(pk1, data3, data2, 128, PK_PKCS1_OAEP_PADDING,1)); test_streq(data3, "Hello whirled."); /* Can't decrypt with public key. */ test_eq(-1, crypto_pk_private_decrypt(pk2, data3, data2, 128, PK_PKCS1_OAEP_PADDING,1)); /* Try again with bad padding */ memcpy(data2+1, "XYZZY", 5); /* This has fails ~ once-in-2^40 */ test_eq(-1, crypto_pk_private_decrypt(pk1, data3, data2, 128, PK_PKCS1_OAEP_PADDING,1)); /* File operations: save and load private key */ test_assert(! crypto_pk_write_private_key_to_filename(pk1, get_fname("pkey1"))); /* failing case for read: can't read. */ test_assert(crypto_pk_read_private_key_from_filename(pk2, get_fname("xyzzy")) < 0); write_str_to_file(get_fname("xyzzy"), "foobar", 6); /* Failing case for read: no key. */ test_assert(crypto_pk_read_private_key_from_filename(pk2, get_fname("xyzzy")) < 0); test_assert(! crypto_pk_read_private_key_from_filename(pk2, get_fname("pkey1"))); test_eq(15, crypto_pk_private_decrypt(pk2, data3, data1, 128, PK_PKCS1_OAEP_PADDING,1)); /* Now try signing. */ strlcpy(data1, "Ossifrage", 1024); test_eq(128, crypto_pk_private_sign(pk1, data2, data1, 10)); test_eq(10, crypto_pk_public_checksig(pk1, data3, data2, 128)); test_streq(data3, "Ossifrage"); /* Try signing digests. */ test_eq(128, crypto_pk_private_sign_digest(pk1, data2, data1, 10)); test_eq(20, crypto_pk_public_checksig(pk1, data3, data2, 128)); test_eq(0, crypto_pk_public_checksig_digest(pk1, data1, 10, data2, 128)); test_eq(-1, crypto_pk_public_checksig_digest(pk1, data1, 11, data2, 128)); /*XXXX test failed signing*/ /* Try encoding */ crypto_free_pk_env(pk2); pk2 = NULL; i = crypto_pk_asn1_encode(pk1, data1, 1024); test_assert(i>0); pk2 = crypto_pk_asn1_decode(data1, i); test_assert(crypto_pk_cmp_keys(pk1,pk2) == 0); /* Try with hybrid encryption wrappers. */ crypto_rand(data1, 1024); for (i = 0; i < 3; ++i) { for (j = 85; j < 140; ++j) { memset(data2,0,1024); memset(data3,0,1024); if (i == 0 && j < 129) continue; p = (i==0)?PK_NO_PADDING: (i==1)?PK_PKCS1_PADDING:PK_PKCS1_OAEP_PADDING; len = crypto_pk_public_hybrid_encrypt(pk1,data2,data1,j,p,0); test_assert(len>=0); len = crypto_pk_private_hybrid_decrypt(pk1,data3,data2,len,p,1); test_eq(len,j); test_memeq(data1,data3,j); } } /* Try copy_full */ crypto_free_pk_env(pk2); pk2 = crypto_pk_copy_full(pk1); test_assert(pk2 != NULL); test_neq_ptr(pk1, pk2); test_assert(crypto_pk_cmp_keys(pk1,pk2) == 0); done: if (pk1) crypto_free_pk_env(pk1); if (pk2) crypto_free_pk_env(pk2); tor_free(encoded); } /** Run unit tests for misc crypto functionality. */ static void test_crypto(void) { char *data1 = NULL, *data2 = NULL, *data3 = NULL; int i, j, idx; data1 = tor_malloc(1024); data2 = tor_malloc(1024); data3 = tor_malloc(1024); test_assert(data1 && data2 && data3); /* Base64 tests */ memset(data1, 6, 1024); for (idx = 0; idx < 10; ++idx) { i = base64_encode(data2, 1024, data1, idx); test_assert(i >= 0); j = base64_decode(data3, 1024, data2, i); test_eq(j,idx); test_memeq(data3, data1, idx); } strlcpy(data1, "Test string that contains 35 chars.", 1024); strlcat(data1, " 2nd string that contains 35 chars.", 1024); i = base64_encode(data2, 1024, data1, 71); j = base64_decode(data3, 1024, data2, i); test_eq(j, 71); test_streq(data3, data1); test_assert(data2[i] == '\0'); crypto_rand(data1, DIGEST_LEN); memset(data2, 100, 1024); digest_to_base64(data2, data1); test_eq(BASE64_DIGEST_LEN, strlen(data2)); test_eq(100, data2[BASE64_DIGEST_LEN+2]); memset(data3, 99, 1024); test_eq(digest_from_base64(data3, data2), 0); test_memeq(data1, data3, DIGEST_LEN); test_eq(99, data3[DIGEST_LEN+1]); test_assert(digest_from_base64(data3, "###") < 0); /* Base32 tests */ strlcpy(data1, "5chrs", 1024); /* bit pattern is: [35 63 68 72 73] -> * [00110101 01100011 01101000 01110010 01110011] * By 5s: [00110 10101 10001 10110 10000 11100 10011 10011] */ base32_encode(data2, 9, data1, 5); test_streq(data2, "gvrwq4tt"); strlcpy(data1, "\xFF\xF5\x6D\x44\xAE\x0D\x5C\xC9\x62\xC4", 1024); base32_encode(data2, 30, data1, 10); test_streq(data2, "772w2rfobvomsywe"); /* Base16 tests */ strlcpy(data1, "6chrs\xff", 1024); base16_encode(data2, 13, data1, 6); test_streq(data2, "3663687273FF"); strlcpy(data1, "f0d678affc000100", 1024); i = base16_decode(data2, 8, data1, 16); test_eq(i,0); test_memeq(data2, "\xf0\xd6\x78\xaf\xfc\x00\x01\x00",8); /* now try some failing base16 decodes */ test_eq(-1, base16_decode(data2, 8, data1, 15)); /* odd input len */ test_eq(-1, base16_decode(data2, 7, data1, 16)); /* dest too short */ strlcpy(data1, "f0dz!8affc000100", 1024); test_eq(-1, base16_decode(data2, 8, data1, 16)); tor_free(data1); tor_free(data2); tor_free(data3); /* Add spaces to fingerprint */ { data1 = tor_strdup("ABCD1234ABCD56780000ABCD1234ABCD56780000"); test_eq(strlen(data1), 40); data2 = tor_malloc(FINGERPRINT_LEN+1); add_spaces_to_fp(data2, FINGERPRINT_LEN+1, data1); test_streq(data2, "ABCD 1234 ABCD 5678 0000 ABCD 1234 ABCD 5678 0000"); tor_free(data1); tor_free(data2); } /* Check fingerprint */ { test_assert(crypto_pk_check_fingerprint_syntax( "ABCD 1234 ABCD 5678 0000 ABCD 1234 ABCD 5678 0000")); test_assert(!crypto_pk_check_fingerprint_syntax( "ABCD 1234 ABCD 5678 0000 ABCD 1234 ABCD 5678 000")); test_assert(!crypto_pk_check_fingerprint_syntax( "ABCD 1234 ABCD 5678 0000 ABCD 1234 ABCD 5678 00000")); test_assert(!crypto_pk_check_fingerprint_syntax( "ABCD 1234 ABCD 5678 0000 ABCD1234 ABCD 5678 0000")); test_assert(!crypto_pk_check_fingerprint_syntax( "ABCD 1234 ABCD 5678 0000 ABCD1234 ABCD 5678 00000")); test_assert(!crypto_pk_check_fingerprint_syntax( "ACD 1234 ABCD 5678 0000 ABCD 1234 ABCD 5678 00000")); } done: tor_free(data1); tor_free(data2); tor_free(data3); } /** Run unit tests for our secret-to-key passphrase hashing functionality. */ static void test_crypto_s2k(void) { char buf[29]; char buf2[29]; char *buf3 = NULL; int i; memset(buf, 0, sizeof(buf)); memset(buf2, 0, sizeof(buf2)); buf3 = tor_malloc(65536); memset(buf3, 0, 65536); secret_to_key(buf+9, 20, "", 0, buf); crypto_digest(buf2+9, buf3, 1024); test_memeq(buf, buf2, 29); memcpy(buf,"vrbacrda",8); memcpy(buf2,"vrbacrda",8); buf[8] = 96; buf2[8] = 96; secret_to_key(buf+9, 20, "12345678", 8, buf); for (i = 0; i < 65536; i += 16) { memcpy(buf3+i, "vrbacrda12345678", 16); } crypto_digest(buf2+9, buf3, 65536); test_memeq(buf, buf2, 29); done: tor_free(buf3); } /** Helper: return a tristate based on comparing the strings in *a and * *b. */ static int _compare_strs(const void **a, const void **b) { const char *s1 = *a, *s2 = *b; return strcmp(s1, s2); } /** Helper: return a tristate based on comparing the strings in *a and * *b, excluding a's first character, and ignoring case. */ static int _compare_without_first_ch(const void *a, const void **b) { const char *s1 = a, *s2 = *b; return strcasecmp(s1+1, s2); } /** Test basic utility functionality. */ static void test_util(void) { struct timeval start, end; struct tm a_time; char timestr[RFC1123_TIME_LEN+1]; char buf[1024]; time_t t_res; int i; uint32_t u32; uint16_t u16; char *cp, *k, *v; const char *str; start.tv_sec = 5; start.tv_usec = 5000; end.tv_sec = 5; end.tv_usec = 5000; test_eq(0L, tv_udiff(&start, &end)); end.tv_usec = 7000; test_eq(2000L, tv_udiff(&start, &end)); end.tv_sec = 6; test_eq(1002000L, tv_udiff(&start, &end)); end.tv_usec = 0; test_eq(995000L, tv_udiff(&start, &end)); end.tv_sec = 4; test_eq(-1005000L, tv_udiff(&start, &end)); end.tv_usec = 999990; start.tv_sec = 1; start.tv_usec = 500; /* The test values here are confirmed to be correct on a platform * with a working timegm. */ a_time.tm_year = 2003-1900; a_time.tm_mon = 7; a_time.tm_mday = 30; a_time.tm_hour = 6; a_time.tm_min = 14; a_time.tm_sec = 55; test_eq((time_t) 1062224095UL, tor_timegm(&a_time)); a_time.tm_year = 2004-1900; /* Try a leap year, after feb. */ test_eq((time_t) 1093846495UL, tor_timegm(&a_time)); a_time.tm_mon = 1; /* Try a leap year, in feb. */ a_time.tm_mday = 10; test_eq((time_t) 1076393695UL, tor_timegm(&a_time)); format_rfc1123_time(timestr, 0); test_streq("Thu, 01 Jan 1970 00:00:00 GMT", timestr); format_rfc1123_time(timestr, (time_t)1091580502UL); test_streq("Wed, 04 Aug 2004 00:48:22 GMT", timestr); t_res = 0; i = parse_rfc1123_time(timestr, &t_res); test_eq(i,0); test_eq(t_res, (time_t)1091580502UL); test_eq(-1, parse_rfc1123_time("Wed, zz Aug 2004 99-99x99 GMT", &t_res)); tor_gettimeofday(&start); /* Tests for corner cases of strl operations */ test_eq(5, strlcpy(buf, "Hello", 0)); strlcpy(buf, "Hello", sizeof(buf)); test_eq(10, strlcat(buf, "Hello", 5)); /* Test tor_strstrip() */ strlcpy(buf, "Testing 1 2 3", sizeof(buf)); tor_strstrip(buf, ",!"); test_streq(buf, "Testing 1 2 3"); strlcpy(buf, "!Testing 1 2 3?", sizeof(buf)); tor_strstrip(buf, "!? "); test_streq(buf, "Testing123"); /* Test parse_addr_port */ cp = NULL; u32 = 3; u16 = 3; test_assert(!parse_addr_port(LOG_WARN, "1.2.3.4", &cp, &u32, &u16)); test_streq(cp, "1.2.3.4"); test_eq(u32, 0x01020304u); test_eq(u16, 0); tor_free(cp); test_assert(!parse_addr_port(LOG_WARN, "4.3.2.1:99", &cp, &u32, &u16)); test_streq(cp, "4.3.2.1"); test_eq(u32, 0x04030201u); test_eq(u16, 99); tor_free(cp); test_assert(!parse_addr_port(LOG_WARN, "nonexistent.address:4040", &cp, NULL, &u16)); test_streq(cp, "nonexistent.address"); test_eq(u16, 4040); tor_free(cp); test_assert(!parse_addr_port(LOG_WARN, "localhost:9999", &cp, &u32, &u16)); test_streq(cp, "localhost"); test_eq(u32, 0x7f000001u); test_eq(u16, 9999); tor_free(cp); u32 = 3; test_assert(!parse_addr_port(LOG_WARN, "localhost", NULL, &u32, &u16)); test_eq(cp, NULL); test_eq(u32, 0x7f000001u); test_eq(u16, 0); tor_free(cp); test_eq(0, addr_mask_get_bits(0x0u)); test_eq(32, addr_mask_get_bits(0xFFFFFFFFu)); test_eq(16, addr_mask_get_bits(0xFFFF0000u)); test_eq(31, addr_mask_get_bits(0xFFFFFFFEu)); test_eq(1, addr_mask_get_bits(0x80000000u)); /* Test tor_parse_long. */ test_eq(10L, tor_parse_long("10",10,0,100,NULL,NULL)); test_eq(0L, tor_parse_long("10",10,50,100,NULL,NULL)); test_eq(-50L, tor_parse_long("-50",10,-100,100,NULL,NULL)); /* Test tor_parse_ulong */ test_eq(10UL, tor_parse_ulong("10",10,0,100,NULL,NULL)); test_eq(0UL, tor_parse_ulong("10",10,50,100,NULL,NULL)); /* Test tor_parse_uint64. */ test_assert(U64_LITERAL(10) == tor_parse_uint64("10 x",10,0,100, &i, &cp)); test_assert(i == 1); test_streq(cp, " x"); test_assert(U64_LITERAL(12345678901) == tor_parse_uint64("12345678901",10,0,UINT64_MAX, &i, &cp)); test_assert(i == 1); test_streq(cp, ""); test_assert(U64_LITERAL(0) == tor_parse_uint64("12345678901",10,500,INT32_MAX, &i, &cp)); test_assert(i == 0); /* Test failing snprintf cases */ test_eq(-1, tor_snprintf(buf, 0, "Foo")); test_eq(-1, tor_snprintf(buf, 2, "Foo")); /* Test printf with uint64 */ tor_snprintf(buf, sizeof(buf), "x!"U64_FORMAT"!x", U64_PRINTF_ARG(U64_LITERAL(12345678901))); test_streq(buf, "x!12345678901!x"); /* Test parse_config_line_from_str */ strlcpy(buf, "k v\n" " key value with spaces \n" "keykey val\n" "k2\n" "k3 \n" "\n" " \n" "#comment\n" "k4#a\n" "k5#abc\n" "k6 val #with comment\n" "kseven \"a quoted 'string\"\n" "k8 \"a \\x71uoted\\n\\\"str\\\\ing\\t\\001\\01\\1\\\"\"\n" , sizeof(buf)); str = buf; str = parse_config_line_from_str(str, &k, &v); test_streq(k, "k"); test_streq(v, "v"); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "key value with")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "key"); test_streq(v, "value with spaces"); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "keykey")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "keykey"); test_streq(v, "val"); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "k2\n")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "k2"); test_streq(v, ""); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "k3 \n")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "k3"); test_streq(v, ""); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "#comment")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "k4"); test_streq(v, ""); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "k5#abc")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "k5"); test_streq(v, ""); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "k6")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "k6"); test_streq(v, "val"); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "kseven")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "kseven"); test_streq(v, "a quoted \'string"); tor_free(k); tor_free(v); test_assert(!strcmpstart(str, "k8 ")); str = parse_config_line_from_str(str, &k, &v); test_streq(k, "k8"); test_streq(v, "a quoted\n\"str\\ing\t\x01\x01\x01\""); tor_free(k); tor_free(v); test_streq(str, ""); /* Test for strcmpstart and strcmpend. */ test_assert(strcmpstart("abcdef", "abcdef")==0); test_assert(strcmpstart("abcdef", "abc")==0); test_assert(strcmpstart("abcdef", "abd")<0); test_assert(strcmpstart("abcdef", "abb")>0); test_assert(strcmpstart("ab", "abb")<0); test_assert(strcmpend("abcdef", "abcdef")==0); test_assert(strcmpend("abcdef", "def")==0); test_assert(strcmpend("abcdef", "deg")<0); test_assert(strcmpend("abcdef", "dee")>0); test_assert(strcmpend("ab", "abb")<0); test_assert(strcasecmpend("AbcDEF", "abcdef")==0); test_assert(strcasecmpend("abcdef", "dEF")==0); test_assert(strcasecmpend("abcDEf", "deg")<0); test_assert(strcasecmpend("abcdef", "DEE")>0); test_assert(strcasecmpend("ab", "abB")<0); /* Test mem_is_zero */ memset(buf,0,128); buf[128] = 'x'; test_assert(tor_digest_is_zero(buf)); test_assert(tor_mem_is_zero(buf, 10)); test_assert(tor_mem_is_zero(buf, 20)); test_assert(tor_mem_is_zero(buf, 128)); test_assert(!tor_mem_is_zero(buf, 129)); buf[60] = (char)255; test_assert(!tor_mem_is_zero(buf, 128)); buf[0] = (char)1; test_assert(!tor_mem_is_zero(buf, 10)); /* Test inet_ntop */ { char tmpbuf[TOR_ADDR_BUF_LEN]; const char *ip = "176.192.208.224"; struct in_addr in; tor_inet_pton(AF_INET, ip, &in); tor_inet_ntop(AF_INET, &in, tmpbuf, sizeof(tmpbuf)); test_streq(tmpbuf, ip); } /* Test 'escaped' */ test_streq("\"\"", escaped("")); test_streq("\"abcd\"", escaped("abcd")); test_streq("\"\\\\\\n\\r\\t\\\"\\'\"", escaped("\\\n\r\t\"\'")); test_streq("\"z\\001abc\\277d\"", escaped("z\001abc\277d")); test_assert(NULL == escaped(NULL)); /* Test strndup and memdup */ { const char *s = "abcdefghijklmnopqrstuvwxyz"; cp = tor_strndup(s, 30); test_streq(cp, s); /* same string, */ test_neq(cp, s); /* but different pointers. */ tor_free(cp); cp = tor_strndup(s, 5); test_streq(cp, "abcde"); tor_free(cp); s = "a\0b\0c\0d\0e\0"; cp = tor_memdup(s,10); test_memeq(cp, s, 10); /* same ram, */ test_neq(cp, s); /* but different pointers. */ tor_free(cp); } /* Test str-foo functions */ cp = tor_strdup("abcdef"); test_assert(tor_strisnonupper(cp)); cp[3] = 'D'; test_assert(!tor_strisnonupper(cp)); tor_strupper(cp); test_streq(cp, "ABCDEF"); test_assert(tor_strisprint(cp)); cp[3] = 3; test_assert(!tor_strisprint(cp)); tor_free(cp); /* Test eat_whitespace. */ { const char *s = " \n a"; test_eq_ptr(eat_whitespace(s), s+4); s = "abcd"; test_eq_ptr(eat_whitespace(s), s); s = "#xyz\nab"; test_eq_ptr(eat_whitespace(s), s+5); } /* Test memmem and memstr */ { const char *haystack = "abcde"; tor_assert(!tor_memmem(haystack, 5, "ef", 2)); test_eq_ptr(tor_memmem(haystack, 5, "cd", 2), haystack + 2); test_eq_ptr(tor_memmem(haystack, 5, "cde", 3), haystack + 2); haystack = "ababcad"; test_eq_ptr(tor_memmem(haystack, 7, "abc", 3), haystack + 2); test_eq_ptr(tor_memstr(haystack, 7, "abc"), haystack + 2); test_assert(!tor_memstr(haystack, 7, "fe")); test_assert(!tor_memstr(haystack, 7, "longerthantheoriginal")); } /* Test wrap_string */ { smartlist_t *sl = smartlist_create(); wrap_string(sl, "This is a test of string wrapping functionality: woot.", 10, "", ""); cp = smartlist_join_strings(sl, "", 0, NULL); test_streq(cp, "This is a\ntest of\nstring\nwrapping\nfunctional\nity: woot.\n"); tor_free(cp); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_clear(sl); wrap_string(sl, "This is a test of string wrapping functionality: woot.", 16, "### ", "# "); cp = smartlist_join_strings(sl, "", 0, NULL); test_streq(cp, "### This is a\n# test of string\n# wrapping\n# functionality:\n" "# woot.\n"); tor_free(cp); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_free(sl); } /* now make sure time works. */ tor_gettimeofday(&end); /* We might've timewarped a little. */ test_assert(tv_udiff(&start, &end) >= -5000); /* Test tor_log2(). */ test_eq(tor_log2(64), 6); test_eq(tor_log2(65), 6); test_eq(tor_log2(63), 5); test_eq(tor_log2(1), 0); test_eq(tor_log2(2), 1); test_eq(tor_log2(3), 1); test_eq(tor_log2(4), 2); test_eq(tor_log2(5), 2); test_eq(tor_log2(U64_LITERAL(40000000000000000)), 55); test_eq(tor_log2(UINT64_MAX), 63); /* Test round_to_power_of_2 */ test_eq(round_to_power_of_2(120), 128); test_eq(round_to_power_of_2(128), 128); test_eq(round_to_power_of_2(130), 128); test_eq(round_to_power_of_2(U64_LITERAL(40000000000000000)), U64_LITERAL(1)<<55); test_eq(round_to_power_of_2(0), 2); done: ; } /** Helper: assert that IPv6 addresses a and b are the same. On * failure, reports an error, describing the addresses as e1 and * e2, and reporting the line number as line. */ static void _test_eq_ip6(struct in6_addr *a, struct in6_addr *b, const char *e1, const char *e2, int line) { int i; int ok = 1; for (i = 0; i < 16; ++i) { if (a->s6_addr[i] != b->s6_addr[i]) { ok = 0; break; } } if (ok) { printf("."); fflush(stdout); } else { char buf1[128], *cp1; char buf2[128], *cp2; have_failed = 1; cp1 = buf1; cp2 = buf2; for (i=0; i<16; ++i) { tor_snprintf(cp1, sizeof(buf1)-(cp1-buf1), "%02x", a->s6_addr[i]); tor_snprintf(cp2, sizeof(buf2)-(cp2-buf2), "%02x", b->s6_addr[i]); cp1 += 2; cp2 += 2; if ((i%2)==1 && i != 15) { *cp1++ = ':'; *cp2++ = ':'; } } *cp1 = *cp2 = '\0'; printf("Line %d: assertion failed: (%s == %s)\n" " %s != %s\n", line, e1, e2, buf1, buf2); fflush(stdout); } } /** Helper: Assert that two strings both decode as IPv6 addresses with * tor_inet_pton(), and both decode to the same address. */ #define test_pton6_same(a,b) STMT_BEGIN \ test_eq(tor_inet_pton(AF_INET6, a, &a1), 1); \ test_eq(tor_inet_pton(AF_INET6, b, &a2), 1); \ _test_eq_ip6(&a1,&a2,#a,#b,__LINE__); \ STMT_END /** Helper: Assert that a is recognized as a bad IPv6 address by * tor_inet_pton(). */ #define test_pton6_bad(a) \ test_eq(0, tor_inet_pton(AF_INET6, a, &a1)) /** Helper: assert that a, when parsed by tor_inet_pton() and displayed * with tor_inet_ntop(), yields b. Also assert that b parses to * the same value as a. */ #define test_ntop6_reduces(a,b) STMT_BEGIN \ test_eq(tor_inet_pton(AF_INET6, a, &a1), 1); \ test_streq(tor_inet_ntop(AF_INET6, &a1, buf, sizeof(buf)), b); \ test_eq(tor_inet_pton(AF_INET6, b, &a2), 1); \ _test_eq_ip6(&a1, &a2, a, b, __LINE__); \ STMT_END /** Helper: assert that a parses by tor_inet_pton() into a address that * passes tor_addr_is_internal() with for_listening. */ #define test_internal_ip(a,for_listening) STMT_BEGIN \ test_eq(tor_inet_pton(AF_INET6, a, &t1.addr.in6_addr), 1); \ t1.family = AF_INET6; \ if (!tor_addr_is_internal(&t1, for_listening)) \ test_fail_msg( a "was not internal."); \ STMT_END /** Helper: assert that a parses by tor_inet_pton() into a address that * does not pass tor_addr_is_internal() with for_listening. */ #define test_external_ip(a,for_listening) STMT_BEGIN \ test_eq(tor_inet_pton(AF_INET6, a, &t1.addr.in6_addr), 1); \ t1.family = AF_INET6; \ if (tor_addr_is_internal(&t1, for_listening)) \ test_fail_msg(a "was not external."); \ STMT_END /** Helper: Assert that a and b, when parsed by * tor_inet_pton(), give addresses that compare in the order defined by * op with tor_addr_compare(). */ #define test_addr_compare(a, op, b) STMT_BEGIN \ test_eq(tor_inet_pton(AF_INET6, a, &t1.addr.in6_addr), 1); \ test_eq(tor_inet_pton(AF_INET6, b, &t2.addr.in6_addr), 1); \ t1.family = t2.family = AF_INET6; \ r = tor_addr_compare(&t1,&t2,CMP_SEMANTIC); \ if (!(r op 0)) \ test_fail_msg("failed: tor_addr_compare("a","b") "#op" 0"); \ STMT_END /** Helper: Assert that a and b, when parsed by * tor_inet_pton(), give addresses that compare in the order defined by * op with tor_addr_compare_masked() with m masked. */ #define test_addr_compare_masked(a, op, b, m) STMT_BEGIN \ test_eq(tor_inet_pton(AF_INET6, a, &t1.addr.in6_addr), 1); \ test_eq(tor_inet_pton(AF_INET6, b, &t2.addr.in6_addr), 1); \ t1.family = t2.family = AF_INET6; \ r = tor_addr_compare_masked(&t1,&t2,m,CMP_SEMANTIC); \ if (!(r op 0)) \ test_fail_msg("failed: tor_addr_compare_masked("a","b","#m") "#op" 0"); \ STMT_END /** Helper: assert that xx is parseable as a masked IPv6 address with * ports by tor_parse_mask_addr_ports(), with family f, IP address * as 4 32-bit words ip1...ip4, mask bits as mm, and port range * as pt1..pt2. */ #define test_addr_mask_ports_parse(xx, f, ip1, ip2, ip3, ip4, mm, pt1, pt2) \ STMT_BEGIN \ test_eq(tor_addr_parse_mask_ports(xx, &t1, &mask, &port1, &port2), f); \ p1=tor_inet_ntop(AF_INET6, &t1.addr.in6_addr, bug, sizeof(bug)); \ test_eq(htonl(ip1), tor_addr_to_in6_addr32(&t1)[0]); \ test_eq(htonl(ip2), tor_addr_to_in6_addr32(&t1)[1]); \ test_eq(htonl(ip3), tor_addr_to_in6_addr32(&t1)[2]); \ test_eq(htonl(ip4), tor_addr_to_in6_addr32(&t1)[3]); \ test_eq(mask, mm); \ test_eq(port1, pt1); \ test_eq(port2, pt2); \ STMT_END /** Run unit tests for IPv6 encoding/decoding/manipulation functions. */ static void test_util_ip6_helpers(void) { char buf[TOR_ADDR_BUF_LEN], bug[TOR_ADDR_BUF_LEN]; struct in6_addr a1, a2; tor_addr_t t1, t2; int r, i; uint16_t port1, port2; maskbits_t mask; const char *p1; struct sockaddr_storage sa_storage; struct sockaddr_in *sin; struct sockaddr_in6 *sin6; // struct in_addr b1, b2; /* Test tor_inet_ntop and tor_inet_pton: IPv6 */ /* ==== Converting to and from sockaddr_t. */ sin = (struct sockaddr_in *)&sa_storage; sin->sin_family = AF_INET; sin->sin_port = 9090; sin->sin_addr.s_addr = htonl(0x7f7f0102); /*127.127.1.2*/ tor_addr_from_sockaddr(&t1, (struct sockaddr *)sin, NULL); test_eq(tor_addr_family(&t1), AF_INET); test_eq(tor_addr_to_ipv4h(&t1), 0x7f7f0102); memset(&sa_storage, 0, sizeof(sa_storage)); test_eq(sizeof(struct sockaddr_in), tor_addr_to_sockaddr(&t1, 1234, (struct sockaddr *)&sa_storage, sizeof(sa_storage))); test_eq(1234, ntohs(sin->sin_port)); test_eq(0x7f7f0102, ntohl(sin->sin_addr.s_addr)); memset(&sa_storage, 0, sizeof(sa_storage)); sin6 = (struct sockaddr_in6 *)&sa_storage; sin6->sin6_family = AF_INET6; sin6->sin6_port = htons(7070); sin6->sin6_addr.s6_addr[0] = 128; tor_addr_from_sockaddr(&t1, (struct sockaddr *)sin6, NULL); test_eq(tor_addr_family(&t1), AF_INET6); p1 = tor_addr_to_str(buf, &t1, sizeof(buf), 0); test_streq(p1, "8000::"); memset(&sa_storage, 0, sizeof(sa_storage)); test_eq(sizeof(struct sockaddr_in6), tor_addr_to_sockaddr(&t1, 9999, (struct sockaddr *)&sa_storage, sizeof(sa_storage))); test_eq(AF_INET6, sin6->sin6_family); test_eq(9999, ntohs(sin6->sin6_port)); test_eq(0x80000000, ntohl(S6_ADDR32(sin6->sin6_addr)[0])); /* ==== tor_addr_lookup: static cases. (Can't test dns without knowing we * have a good resolver. */ test_eq(0, tor_addr_lookup("127.128.129.130", AF_UNSPEC, &t1)); test_eq(AF_INET, tor_addr_family(&t1)); test_eq(tor_addr_to_ipv4h(&t1), 0x7f808182); test_eq(0, tor_addr_lookup("9000::5", AF_UNSPEC, &t1)); test_eq(AF_INET6, tor_addr_family(&t1)); test_eq(0x90, tor_addr_to_in6_addr8(&t1)[0]); test_assert(tor_mem_is_zero((char*)tor_addr_to_in6_addr8(&t1)+1, 14)); test_eq(0x05, tor_addr_to_in6_addr8(&t1)[15]); /* === Test pton: valid af_inet6 */ /* Simple, valid parsing. */ r = tor_inet_pton(AF_INET6, "0102:0304:0506:0708:090A:0B0C:0D0E:0F10", &a1); test_assert(r==1); for (i=0;i<16;++i) { test_eq(i+1, (int)a1.s6_addr[i]); } /* ipv4 ending. */ test_pton6_same("0102:0304:0506:0708:090A:0B0C:0D0E:0F10", "0102:0304:0506:0708:090A:0B0C:13.14.15.16"); /* shortened words. */ test_pton6_same("0001:0099:BEEF:0000:0123:FFFF:0001:0001", "1:99:BEEF:0:0123:FFFF:1:1"); /* zeros at the beginning */ test_pton6_same("0000:0000:0000:0000:0009:C0A8:0001:0001", "::9:c0a8:1:1"); test_pton6_same("0000:0000:0000:0000:0009:C0A8:0001:0001", "::9:c0a8:0.1.0.1"); /* zeros in the middle. */ test_pton6_same("fe80:0000:0000:0000:0202:1111:0001:0001", "fe80::202:1111:1:1"); /* zeros at the end. */ test_pton6_same("1000:0001:0000:0007:0000:0000:0000:0000", "1000:1:0:7::"); /* === Test ntop: af_inet6 */ test_ntop6_reduces("0:0:0:0:0:0:0:0", "::"); test_ntop6_reduces("0001:0099:BEEF:0006:0123:FFFF:0001:0001", "1:99:beef:6:123:ffff:1:1"); //test_ntop6_reduces("0:0:0:0:0:0:c0a8:0101", "::192.168.1.1"); test_ntop6_reduces("0:0:0:0:0:ffff:c0a8:0101", "::ffff:192.168.1.1"); test_ntop6_reduces("002:0:0000:0:3::4", "2::3:0:0:4"); test_ntop6_reduces("0:0::1:0:3", "::1:0:3"); test_ntop6_reduces("008:0::0", "8::"); test_ntop6_reduces("0:0:0:0:0:ffff::1", "::ffff:0.0.0.1"); test_ntop6_reduces("abcd:0:0:0:0:0:7f00::", "abcd::7f00:0"); test_ntop6_reduces("0000:0000:0000:0000:0009:C0A8:0001:0001", "::9:c0a8:1:1"); test_ntop6_reduces("fe80:0000:0000:0000:0202:1111:0001:0001", "fe80::202:1111:1:1"); test_ntop6_reduces("1000:0001:0000:0007:0000:0000:0000:0000", "1000:1:0:7::"); /* === Test pton: invalid in6. */ test_pton6_bad("foobar."); test_pton6_bad("55555::"); test_pton6_bad("9:-60::"); test_pton6_bad("1:2:33333:4:0002:3::"); //test_pton6_bad("1:2:3333:4:00002:3::");// BAD, but glibc doesn't say so. test_pton6_bad("1:2:3333:4:fish:3::"); test_pton6_bad("1:2:3:4:5:6:7:8:9"); test_pton6_bad("1:2:3:4:5:6:7"); test_pton6_bad("1:2:3:4:5:6:1.2.3.4.5"); test_pton6_bad("1:2:3:4:5:6:1.2.3"); test_pton6_bad("::1.2.3"); test_pton6_bad("::1.2.3.4.5"); test_pton6_bad("99"); test_pton6_bad(""); test_pton6_bad("1::2::3:4"); test_pton6_bad("a:::b:c"); test_pton6_bad(":::a:b:c"); test_pton6_bad("a:b:c:::"); /* test internal checking */ test_external_ip("fbff:ffff::2:7", 0); test_internal_ip("fc01::2:7", 0); test_internal_ip("fdff:ffff::f:f", 0); test_external_ip("fe00::3:f", 0); test_external_ip("fe7f:ffff::2:7", 0); test_internal_ip("fe80::2:7", 0); test_internal_ip("febf:ffff::f:f", 0); test_internal_ip("fec0::2:7:7", 0); test_internal_ip("feff:ffff::e:7:7", 0); test_external_ip("ff00::e:7:7", 0); test_internal_ip("::", 0); test_internal_ip("::1", 0); test_internal_ip("::1", 1); test_internal_ip("::", 0); test_external_ip("::", 1); test_external_ip("::2", 0); test_external_ip("2001::", 0); test_external_ip("ffff::", 0); test_external_ip("::ffff:0.0.0.0", 1); test_internal_ip("::ffff:0.0.0.0", 0); test_internal_ip("::ffff:0.255.255.255", 0); test_external_ip("::ffff:1.0.0.0", 0); test_external_ip("::ffff:9.255.255.255", 0); test_internal_ip("::ffff:10.0.0.0", 0); test_internal_ip("::ffff:10.255.255.255", 0); test_external_ip("::ffff:11.0.0.0", 0); test_external_ip("::ffff:126.255.255.255", 0); test_internal_ip("::ffff:127.0.0.0", 0); test_internal_ip("::ffff:127.255.255.255", 0); test_external_ip("::ffff:128.0.0.0", 0); test_external_ip("::ffff:172.15.255.255", 0); test_internal_ip("::ffff:172.16.0.0", 0); test_internal_ip("::ffff:172.31.255.255", 0); test_external_ip("::ffff:172.32.0.0", 0); test_external_ip("::ffff:192.167.255.255", 0); test_internal_ip("::ffff:192.168.0.0", 0); test_internal_ip("::ffff:192.168.255.255", 0); test_external_ip("::ffff:192.169.0.0", 0); test_external_ip("::ffff:169.253.255.255", 0); test_internal_ip("::ffff:169.254.0.0", 0); test_internal_ip("::ffff:169.254.255.255", 0); test_external_ip("::ffff:169.255.0.0", 0); test_assert(is_internal_IP(0x7f000001, 0)); /* tor_addr_compare(tor_addr_t x2) */ test_addr_compare("ffff::", ==, "ffff::0"); test_addr_compare("0::3:2:1", <, "0::ffff:0.3.2.1"); test_addr_compare("0::2:2:1", <, "0::ffff:0.3.2.1"); test_addr_compare("0::ffff:0.3.2.1", >, "0::0:0:0"); test_addr_compare("0::ffff:5.2.2.1", <, "::ffff:6.0.0.0"); /* XXXX wrong. */ tor_addr_parse_mask_ports("[::ffff:2.3.4.5]", &t1, NULL, NULL, NULL); tor_addr_parse_mask_ports("2.3.4.5", &t2, NULL, NULL, NULL); test_assert(tor_addr_compare(&t1, &t2, CMP_SEMANTIC) == 0); tor_addr_parse_mask_ports("[::ffff:2.3.4.4]", &t1, NULL, NULL, NULL); tor_addr_parse_mask_ports("2.3.4.5", &t2, NULL, NULL, NULL); test_assert(tor_addr_compare(&t1, &t2, CMP_SEMANTIC) < 0); /* test compare_masked */ test_addr_compare_masked("ffff::", ==, "ffff::0", 128); test_addr_compare_masked("ffff::", ==, "ffff::0", 64); test_addr_compare_masked("0::2:2:1", <, "0::8000:2:1", 81); test_addr_compare_masked("0::2:2:1", ==, "0::8000:2:1", 80); /* Test decorated addr_to_string. */ test_eq(AF_INET6, tor_addr_from_str(&t1, "[123:45:6789::5005:11]")); p1 = tor_addr_to_str(buf, &t1, sizeof(buf), 1); test_streq(p1, "[123:45:6789::5005:11]"); test_eq(AF_INET, tor_addr_from_str(&t1, "18.0.0.1")); p1 = tor_addr_to_str(buf, &t1, sizeof(buf), 1); test_streq(p1, "18.0.0.1"); /* Test tor_addr_parse_reverse_lookup_name */ i = tor_addr_parse_reverse_lookup_name(&t1, "Foobar.baz", AF_UNSPEC, 0); test_eq(0, i); i = tor_addr_parse_reverse_lookup_name(&t1, "Foobar.baz", AF_UNSPEC, 1); test_eq(0, i); i = tor_addr_parse_reverse_lookup_name(&t1, "1.0.168.192.in-addr.arpa", AF_UNSPEC, 1); test_eq(1, i); test_eq(tor_addr_family(&t1), AF_INET); p1 = tor_addr_to_str(buf, &t1, sizeof(buf), 1); test_streq(p1, "192.168.0.1"); i = tor_addr_parse_reverse_lookup_name(&t1, "192.168.0.99", AF_UNSPEC, 0); test_eq(0, i); i = tor_addr_parse_reverse_lookup_name(&t1, "192.168.0.99", AF_UNSPEC, 1); test_eq(1, i); p1 = tor_addr_to_str(buf, &t1, sizeof(buf), 1); test_streq(p1, "192.168.0.99"); memset(&t1, 0, sizeof(t1)); i = tor_addr_parse_reverse_lookup_name(&t1, "0.1.2.3.4.5.6.7.8.9.a.b.c.d.e.f." "f.e.e.b.1.e.b.e.e.f.f.e.e.e.d.9." "ip6.ARPA", AF_UNSPEC, 0); test_eq(1, i); p1 = tor_addr_to_str(buf, &t1, sizeof(buf), 1); test_streq(p1, "[9dee:effe:ebe1:beef:fedc:ba98:7654:3210]"); /* Failing cases. */ i = tor_addr_parse_reverse_lookup_name(&t1, "6.7.8.9.a.b.c.d.e.f." "f.e.e.b.1.e.b.e.e.f.f.e.e.e.d.9." "ip6.ARPA", AF_UNSPEC, 0); test_eq(i, -1); i = tor_addr_parse_reverse_lookup_name(&t1, "6.7.8.9.a.b.c.d.e.f.a.b.c.d.e.f.0." "f.e.e.b.1.e.b.e.e.f.f.e.e.e.d.9." "ip6.ARPA", AF_UNSPEC, 0); test_eq(i, -1); i = tor_addr_parse_reverse_lookup_name(&t1, "6.7.8.9.a.b.c.d.e.f.X.0.0.0.0.9." "f.e.e.b.1.e.b.e.e.f.f.e.e.e.d.9." "ip6.ARPA", AF_UNSPEC, 0); test_eq(i, -1); i = tor_addr_parse_reverse_lookup_name(&t1, "32.1.1.in-addr.arpa", AF_UNSPEC, 0); test_eq(i, -1); i = tor_addr_parse_reverse_lookup_name(&t1, ".in-addr.arpa", AF_UNSPEC, 0); test_eq(i, -1); i = tor_addr_parse_reverse_lookup_name(&t1, "1.2.3.4.5.in-addr.arpa", AF_UNSPEC, 0); test_eq(i, -1); i = tor_addr_parse_reverse_lookup_name(&t1, "1.2.3.4.5.in-addr.arpa", AF_INET6, 0); test_eq(i, -1); i = tor_addr_parse_reverse_lookup_name(&t1, "6.7.8.9.a.b.c.d.e.f.a.b.c.d.e.0." "f.e.e.b.1.e.b.e.e.f.f.e.e.e.d.9." "ip6.ARPA", AF_INET, 0); test_eq(i, -1); /* test tor_addr_parse_mask_ports */ test_addr_mask_ports_parse("[::f]/17:47-95", AF_INET6, 0, 0, 0, 0x0000000f, 17, 47, 95); //test_addr_parse("[::fefe:4.1.1.7/120]:999-1000"); //test_addr_parse_check("::fefe:401:107", 120, 999, 1000); test_addr_mask_ports_parse("[::ffff:4.1.1.7]/120:443", AF_INET6, 0, 0, 0x0000ffff, 0x04010107, 120, 443, 443); test_addr_mask_ports_parse("[abcd:2::44a:0]:2-65000", AF_INET6, 0xabcd0002, 0, 0, 0x044a0000, 128, 2, 65000); r=tor_addr_parse_mask_ports("[fefef::]/112", &t1, NULL, NULL, NULL); test_assert(r == -1); r=tor_addr_parse_mask_ports("efef::/112", &t1, NULL, NULL, NULL); test_assert(r == -1); r=tor_addr_parse_mask_ports("[f:f:f:f:f:f:f:f::]", &t1, NULL, NULL, NULL); test_assert(r == -1); r=tor_addr_parse_mask_ports("[::f:f:f:f:f:f:f:f]", &t1, NULL, NULL, NULL); test_assert(r == -1); r=tor_addr_parse_mask_ports("[f:f:f:f:f:f:f:f:f]", &t1, NULL, NULL, NULL); test_assert(r == -1); /* Test for V4-mapped address with mask < 96. (arguably not valid) */ r=tor_addr_parse_mask_ports("[::ffff:1.1.2.2/33]", &t1, &mask, NULL, NULL); test_assert(r == -1); r=tor_addr_parse_mask_ports("1.1.2.2/33", &t1, &mask, NULL, NULL); test_assert(r == -1); r=tor_addr_parse_mask_ports("1.1.2.2/31", &t1, &mask, NULL, NULL); test_assert(r == AF_INET); r=tor_addr_parse_mask_ports("[efef::]/112", &t1, &mask, &port1, &port2); test_assert(r == AF_INET6); test_assert(port1 == 1); test_assert(port2 == 65535); /* make sure inet address lengths >= max */ test_assert(INET_NTOA_BUF_LEN >= sizeof("255.255.255.255")); test_assert(TOR_ADDR_BUF_LEN >= sizeof("ffff:ffff:ffff:ffff:ffff:ffff:255.255.255.255")); test_assert(sizeof(tor_addr_t) >= sizeof(struct in6_addr)); /* get interface addresses */ r = get_interface_address6(LOG_DEBUG, AF_INET, &t1); i = get_interface_address6(LOG_DEBUG, AF_INET6, &t2); #if 0 tor_inet_ntop(AF_INET, &t1.sa.sin_addr, buf, sizeof(buf)); printf("\nv4 address: %s (family=%i)", buf, IN_FAMILY(&t1)); tor_inet_ntop(AF_INET6, &t2.sa6.sin6_addr, buf, sizeof(buf)); printf("\nv6 address: %s (family=%i)", buf, IN_FAMILY(&t2)); #endif done: ; } /** Run unit tests for basic dynamic-sized array functionality. */ static void test_util_smartlist_basic(void) { smartlist_t *sl; /* XXXX test sort_digests, uniq_strings, uniq_digests */ /* Test smartlist add, del_keeporder, insert, get. */ sl = smartlist_create(); smartlist_add(sl, (void*)1); smartlist_add(sl, (void*)2); smartlist_add(sl, (void*)3); smartlist_add(sl, (void*)4); smartlist_del_keeporder(sl, 1); smartlist_insert(sl, 1, (void*)22); smartlist_insert(sl, 0, (void*)0); smartlist_insert(sl, 5, (void*)555); test_eq_ptr((void*)0, smartlist_get(sl,0)); test_eq_ptr((void*)1, smartlist_get(sl,1)); test_eq_ptr((void*)22, smartlist_get(sl,2)); test_eq_ptr((void*)3, smartlist_get(sl,3)); test_eq_ptr((void*)4, smartlist_get(sl,4)); test_eq_ptr((void*)555, smartlist_get(sl,5)); /* Try deleting in the middle. */ smartlist_del(sl, 1); test_eq_ptr((void*)555, smartlist_get(sl, 1)); /* Try deleting at the end. */ smartlist_del(sl, 4); test_eq(4, smartlist_len(sl)); /* test isin. */ test_assert(smartlist_isin(sl, (void*)3)); test_assert(!smartlist_isin(sl, (void*)99)); done: smartlist_free(sl); } /** Run unit tests for smartlist-of-strings functionality. */ static void test_util_smartlist_strings(void) { smartlist_t *sl = smartlist_create(); char *cp=NULL, *cp_alloc=NULL; size_t sz; /* Test split and join */ test_eq(0, smartlist_len(sl)); smartlist_split_string(sl, "abc", ":", 0, 0); test_eq(1, smartlist_len(sl)); test_streq("abc", smartlist_get(sl, 0)); smartlist_split_string(sl, "a::bc::", "::", 0, 0); test_eq(4, smartlist_len(sl)); test_streq("a", smartlist_get(sl, 1)); test_streq("bc", smartlist_get(sl, 2)); test_streq("", smartlist_get(sl, 3)); cp_alloc = smartlist_join_strings(sl, "", 0, NULL); test_streq(cp_alloc, "abcabc"); tor_free(cp_alloc); cp_alloc = smartlist_join_strings(sl, "!", 0, NULL); test_streq(cp_alloc, "abc!a!bc!"); tor_free(cp_alloc); cp_alloc = smartlist_join_strings(sl, "XY", 0, NULL); test_streq(cp_alloc, "abcXYaXYbcXY"); tor_free(cp_alloc); cp_alloc = smartlist_join_strings(sl, "XY", 1, NULL); test_streq(cp_alloc, "abcXYaXYbcXYXY"); tor_free(cp_alloc); cp_alloc = smartlist_join_strings(sl, "", 1, NULL); test_streq(cp_alloc, "abcabc"); tor_free(cp_alloc); smartlist_split_string(sl, "/def/ /ghijk", "/", 0, 0); test_eq(8, smartlist_len(sl)); test_streq("", smartlist_get(sl, 4)); test_streq("def", smartlist_get(sl, 5)); test_streq(" ", smartlist_get(sl, 6)); test_streq("ghijk", smartlist_get(sl, 7)); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_clear(sl); smartlist_split_string(sl, "a,bbd,cdef", ",", SPLIT_SKIP_SPACE, 0); test_eq(3, smartlist_len(sl)); test_streq("a", smartlist_get(sl,0)); test_streq("bbd", smartlist_get(sl,1)); test_streq("cdef", smartlist_get(sl,2)); smartlist_split_string(sl, " z <> zhasd <> <> bnud<> ", "<>", SPLIT_SKIP_SPACE, 0); test_eq(8, smartlist_len(sl)); test_streq("z", smartlist_get(sl,3)); test_streq("zhasd", smartlist_get(sl,4)); test_streq("", smartlist_get(sl,5)); test_streq("bnud", smartlist_get(sl,6)); test_streq("", smartlist_get(sl,7)); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_clear(sl); smartlist_split_string(sl, " ab\tc \td ef ", NULL, SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); test_eq(4, smartlist_len(sl)); test_streq("ab", smartlist_get(sl,0)); test_streq("c", smartlist_get(sl,1)); test_streq("d", smartlist_get(sl,2)); test_streq("ef", smartlist_get(sl,3)); smartlist_split_string(sl, "ghi\tj", NULL, SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); test_eq(6, smartlist_len(sl)); test_streq("ghi", smartlist_get(sl,4)); test_streq("j", smartlist_get(sl,5)); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_clear(sl); cp_alloc = smartlist_join_strings(sl, "XY", 0, NULL); test_streq(cp_alloc, ""); tor_free(cp_alloc); cp_alloc = smartlist_join_strings(sl, "XY", 1, NULL); test_streq(cp_alloc, "XY"); tor_free(cp_alloc); smartlist_split_string(sl, " z <> zhasd <> <> bnud<> ", "<>", SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); test_eq(3, smartlist_len(sl)); test_streq("z", smartlist_get(sl, 0)); test_streq("zhasd", smartlist_get(sl, 1)); test_streq("bnud", smartlist_get(sl, 2)); smartlist_split_string(sl, " z <> zhasd <> <> bnud<> ", "<>", SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 2); test_eq(5, smartlist_len(sl)); test_streq("z", smartlist_get(sl, 3)); test_streq("zhasd <> <> bnud<>", smartlist_get(sl, 4)); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_clear(sl); smartlist_split_string(sl, "abcd\n", "\n", SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); test_eq(1, smartlist_len(sl)); test_streq("abcd", smartlist_get(sl, 0)); smartlist_split_string(sl, "efgh", "\n", SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); test_eq(2, smartlist_len(sl)); test_streq("efgh", smartlist_get(sl, 1)); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_clear(sl); /* Test swapping, shuffling, and sorting. */ smartlist_split_string(sl, "the,onion,router,by,arma,and,nickm", ",", 0, 0); test_eq(7, smartlist_len(sl)); smartlist_sort(sl, _compare_strs); cp_alloc = smartlist_join_strings(sl, ",", 0, NULL); test_streq(cp_alloc,"and,arma,by,nickm,onion,router,the"); tor_free(cp_alloc); smartlist_swap(sl, 1, 5); cp_alloc = smartlist_join_strings(sl, ",", 0, NULL); test_streq(cp_alloc,"and,router,by,nickm,onion,arma,the"); tor_free(cp_alloc); smartlist_shuffle(sl); test_eq(7, smartlist_len(sl)); test_assert(smartlist_string_isin(sl, "and")); test_assert(smartlist_string_isin(sl, "router")); test_assert(smartlist_string_isin(sl, "by")); test_assert(smartlist_string_isin(sl, "nickm")); test_assert(smartlist_string_isin(sl, "onion")); test_assert(smartlist_string_isin(sl, "arma")); test_assert(smartlist_string_isin(sl, "the")); /* Test bsearch. */ smartlist_sort(sl, _compare_strs); test_streq("nickm", smartlist_bsearch(sl, "zNicKM", _compare_without_first_ch)); test_streq("and", smartlist_bsearch(sl, " AND", _compare_without_first_ch)); test_eq_ptr(NULL, smartlist_bsearch(sl, " ANz", _compare_without_first_ch)); /* Test bsearch_idx */ { int f; test_eq(0, smartlist_bsearch_idx(sl," aaa",_compare_without_first_ch,&f)); test_eq(f, 0); test_eq(0, smartlist_bsearch_idx(sl," and",_compare_without_first_ch,&f)); test_eq(f, 1); test_eq(1, smartlist_bsearch_idx(sl," arm",_compare_without_first_ch,&f)); test_eq(f, 0); test_eq(1, smartlist_bsearch_idx(sl," arma",_compare_without_first_ch,&f)); test_eq(f, 1); test_eq(2, smartlist_bsearch_idx(sl," armb",_compare_without_first_ch,&f)); test_eq(f, 0); test_eq(7, smartlist_bsearch_idx(sl," zzzz",_compare_without_first_ch,&f)); test_eq(f, 0); } /* Test reverse() and pop_last() */ smartlist_reverse(sl); cp_alloc = smartlist_join_strings(sl, ",", 0, NULL); test_streq(cp_alloc,"the,router,onion,nickm,by,arma,and"); tor_free(cp_alloc); cp_alloc = smartlist_pop_last(sl); test_streq(cp_alloc, "and"); tor_free(cp_alloc); test_eq(smartlist_len(sl), 6); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_clear(sl); cp_alloc = smartlist_pop_last(sl); test_eq(cp_alloc, NULL); /* Test uniq() */ smartlist_split_string(sl, "50,noon,radar,a,man,a,plan,a,canal,panama,radar,noon,50", ",", 0, 0); smartlist_sort(sl, _compare_strs); smartlist_uniq(sl, _compare_strs, _tor_free); cp_alloc = smartlist_join_strings(sl, ",", 0, NULL); test_streq(cp_alloc, "50,a,canal,man,noon,panama,plan,radar"); tor_free(cp_alloc); /* Test string_isin and isin_case and num_isin */ test_assert(smartlist_string_isin(sl, "noon")); test_assert(!smartlist_string_isin(sl, "noonoon")); test_assert(smartlist_string_isin_case(sl, "nOOn")); test_assert(!smartlist_string_isin_case(sl, "nooNooN")); test_assert(smartlist_string_num_isin(sl, 50)); test_assert(!smartlist_string_num_isin(sl, 60)); /* Test smartlist_choose */ { int i; int allsame = 1; int allin = 1; void *first = smartlist_choose(sl); test_assert(smartlist_isin(sl, first)); for (i = 0; i < 100; ++i) { void *second = smartlist_choose(sl); if (second != first) allsame = 0; if (!smartlist_isin(sl, second)) allin = 0; } test_assert(!allsame); test_assert(allin); } SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_clear(sl); /* Test string_remove and remove and join_strings2 */ smartlist_split_string(sl, "Some say the Earth will end in ice and some in fire", " ", 0, 0); cp = smartlist_get(sl, 4); test_streq(cp, "will"); smartlist_add(sl, cp); smartlist_remove(sl, cp); tor_free(cp); cp_alloc = smartlist_join_strings(sl, ",", 0, NULL); test_streq(cp_alloc, "Some,say,the,Earth,fire,end,in,ice,and,some,in"); tor_free(cp_alloc); smartlist_string_remove(sl, "in"); cp_alloc = smartlist_join_strings2(sl, "+XX", 1, 0, &sz); test_streq(cp_alloc, "Some+say+the+Earth+fire+end+some+ice+and"); test_eq((int)sz, 40); done: SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_free(sl); tor_free(cp_alloc); } /** Run unit tests for smartlist set manipulation functions. */ static void test_util_smartlist_overlap(void) { smartlist_t *sl = smartlist_create(); smartlist_t *ints = smartlist_create(); smartlist_t *odds = smartlist_create(); smartlist_t *evens = smartlist_create(); smartlist_t *primes = smartlist_create(); int i; for (i=1; i < 10; i += 2) smartlist_add(odds, (void*)(uintptr_t)i); for (i=0; i < 10; i += 2) smartlist_add(evens, (void*)(uintptr_t)i); /* add_all */ smartlist_add_all(ints, odds); smartlist_add_all(ints, evens); test_eq(smartlist_len(ints), 10); smartlist_add(primes, (void*)2); smartlist_add(primes, (void*)3); smartlist_add(primes, (void*)5); smartlist_add(primes, (void*)7); /* overlap */ test_assert(smartlist_overlap(ints, odds)); test_assert(smartlist_overlap(odds, primes)); test_assert(smartlist_overlap(evens, primes)); test_assert(!smartlist_overlap(odds, evens)); /* intersect */ smartlist_add_all(sl, odds); smartlist_intersect(sl, primes); test_eq(smartlist_len(sl), 3); test_assert(smartlist_isin(sl, (void*)3)); test_assert(smartlist_isin(sl, (void*)5)); test_assert(smartlist_isin(sl, (void*)7)); /* subtract */ smartlist_add_all(sl, primes); smartlist_subtract(sl, odds); test_eq(smartlist_len(sl), 1); test_assert(smartlist_isin(sl, (void*)2)); done: smartlist_free(odds); smartlist_free(evens); smartlist_free(ints); smartlist_free(primes); smartlist_free(sl); } /** Run unit tests for smartlist-of-digests functions. */ static void test_util_smartlist_digests(void) { smartlist_t *sl = smartlist_create(); /* digest_isin. */ smartlist_add(sl, tor_memdup("AAAAAAAAAAAAAAAAAAAA", DIGEST_LEN)); smartlist_add(sl, tor_memdup("\00090AAB2AAAAaasdAAAAA", DIGEST_LEN)); smartlist_add(sl, tor_memdup("\00090AAB2AAAAaasdAAAAA", DIGEST_LEN)); test_eq(0, smartlist_digest_isin(NULL, "AAAAAAAAAAAAAAAAAAAA")); test_assert(smartlist_digest_isin(sl, "AAAAAAAAAAAAAAAAAAAA")); test_assert(smartlist_digest_isin(sl, "\00090AAB2AAAAaasdAAAAA")); test_eq(0, smartlist_digest_isin(sl, "\00090AAB2AAABaasdAAAAA")); /* sort digests */ smartlist_sort_digests(sl); test_memeq(smartlist_get(sl, 0), "\00090AAB2AAAAaasdAAAAA", DIGEST_LEN); test_memeq(smartlist_get(sl, 1), "\00090AAB2AAAAaasdAAAAA", DIGEST_LEN); test_memeq(smartlist_get(sl, 2), "AAAAAAAAAAAAAAAAAAAA", DIGEST_LEN); test_eq(3, smartlist_len(sl)); /* uniq_digests */ smartlist_uniq_digests(sl); test_eq(2, smartlist_len(sl)); test_memeq(smartlist_get(sl, 0), "\00090AAB2AAAAaasdAAAAA", DIGEST_LEN); test_memeq(smartlist_get(sl, 1), "AAAAAAAAAAAAAAAAAAAA", DIGEST_LEN); done: SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_free(sl); } /** Run unit tests for concatenate-a-smartlist-of-strings functions. */ static void test_util_smartlist_join(void) { smartlist_t *sl = smartlist_create(); smartlist_t *sl2 = smartlist_create(), *sl3 = smartlist_create(), *sl4 = smartlist_create(); char *joined=NULL; /* unique, sorted. */ smartlist_split_string(sl, "Abashments Ambush Anchorman Bacon Banks Borscht " "Bunks Inhumane Insurance Knish Know Manners " "Maraschinos Stamina Sunbonnets Unicorns Wombats", " ", 0, 0); /* non-unique, sorted. */ smartlist_split_string(sl2, "Ambush Anchorman Anchorman Anemias Anemias Bacon " "Crossbowmen Inhumane Insurance Knish Know Manners " "Manners Maraschinos Wombats Wombats Work", " ", 0, 0); SMARTLIST_FOREACH_JOIN(sl, char *, cp1, sl2, char *, cp2, strcmp(cp1,cp2), smartlist_add(sl3, cp2)) { test_streq(cp1, cp2); smartlist_add(sl4, cp1); } SMARTLIST_FOREACH_JOIN_END(cp1, cp2); SMARTLIST_FOREACH(sl3, const char *, cp, test_assert(smartlist_isin(sl2, cp) && !smartlist_string_isin(sl, cp))); SMARTLIST_FOREACH(sl4, const char *, cp, test_assert(smartlist_isin(sl, cp) && smartlist_string_isin(sl2, cp))); joined = smartlist_join_strings(sl3, ",", 0, NULL); test_streq(joined, "Anemias,Anemias,Crossbowmen,Work"); tor_free(joined); joined = smartlist_join_strings(sl4, ",", 0, NULL); test_streq(joined, "Ambush,Anchorman,Anchorman,Bacon,Inhumane,Insurance," "Knish,Know,Manners,Manners,Maraschinos,Wombats,Wombats"); tor_free(joined); done: smartlist_free(sl4); smartlist_free(sl3); SMARTLIST_FOREACH(sl2, char *, cp, tor_free(cp)); smartlist_free(sl2); SMARTLIST_FOREACH(sl, char *, cp, tor_free(cp)); smartlist_free(sl); tor_free(joined); } /** Run unit tests for bitarray code */ static void test_util_bitarray(void) { bitarray_t *ba = NULL; int i, j, ok=1; ba = bitarray_init_zero(1); test_assert(ba); test_assert(! bitarray_is_set(ba, 0)); bitarray_set(ba, 0); test_assert(bitarray_is_set(ba, 0)); bitarray_clear(ba, 0); test_assert(! bitarray_is_set(ba, 0)); bitarray_free(ba); ba = bitarray_init_zero(1023); for (i = 1; i < 64; ) { for (j = 0; j < 1023; ++j) { if (j % i) bitarray_set(ba, j); else bitarray_clear(ba, j); } for (j = 0; j < 1023; ++j) { if (!bool_eq(bitarray_is_set(ba, j), j%i)) ok = 0; } test_assert(ok); if (i < 7) ++i; else if (i == 28) i = 32; else i += 7; } done: if (ba) bitarray_free(ba); } /** Run unit tests for digest set code (implemented as a hashtable or as a * bloom filter) */ static void test_util_digestset(void) { smartlist_t *included = smartlist_create(); char d[DIGEST_LEN]; int i; int ok = 1; int false_positives = 0; digestset_t *set = NULL; for (i = 0; i < 1000; ++i) { crypto_rand(d, DIGEST_LEN); smartlist_add(included, tor_memdup(d, DIGEST_LEN)); } set = digestset_new(1000); SMARTLIST_FOREACH(included, const char *, cp, if (digestset_isin(set, cp)) ok = 0); test_assert(ok); SMARTLIST_FOREACH(included, const char *, cp, digestset_add(set, cp)); SMARTLIST_FOREACH(included, const char *, cp, if (!digestset_isin(set, cp)) ok = 0); test_assert(ok); for (i = 0; i < 1000; ++i) { crypto_rand(d, DIGEST_LEN); if (digestset_isin(set, d)) ++false_positives; } test_assert(false_positives < 50); /* Should be far lower. */ done: if (set) digestset_free(set); SMARTLIST_FOREACH(included, char *, cp, tor_free(cp)); smartlist_free(included); } /** mutex for thread test to stop the threads hitting data at the same time. */ static tor_mutex_t *_thread_test_mutex = NULL; /** mutexes for the thread test to make sure that the threads have to * interleave somewhat. */ static tor_mutex_t *_thread_test_start1 = NULL, *_thread_test_start2 = NULL; /** Shared strmap for the thread test. */ static strmap_t *_thread_test_strmap = NULL; /** The name of thread1 for the thread test */ static char *_thread1_name = NULL; /** The name of thread2 for the thread test */ static char *_thread2_name = NULL; static void _thread_test_func(void* _s) ATTR_NORETURN; /** How many iterations have the threads in the unit test run? */ static int t1_count = 0, t2_count = 0; /** Helper function for threading unit tests: This function runs in a * subthread. It grabs its own mutex (start1 or start2) to make sure that it * should start, then it repeatedly alters _test_thread_strmap protected by * _thread_test_mutex. */ static void _thread_test_func(void* _s) { char *s = _s; int i, *count; tor_mutex_t *m; char buf[64]; char **cp; if (!strcmp(s, "thread 1")) { m = _thread_test_start1; cp = &_thread1_name; count = &t1_count; } else { m = _thread_test_start2; cp = &_thread2_name; count = &t2_count; } tor_mutex_acquire(m); tor_snprintf(buf, sizeof(buf), "%lu", tor_get_thread_id()); *cp = tor_strdup(buf); for (i=0; i<10000; ++i) { tor_mutex_acquire(_thread_test_mutex); strmap_set(_thread_test_strmap, "last to run", *cp); ++*count; tor_mutex_release(_thread_test_mutex); } tor_mutex_acquire(_thread_test_mutex); strmap_set(_thread_test_strmap, s, *cp); tor_mutex_release(_thread_test_mutex); tor_mutex_release(m); spawn_exit(); } /** Run unit tests for threading logic. */ static void test_util_threads(void) { char *s1 = NULL, *s2 = NULL; int done = 0, timedout = 0; time_t started; #ifndef TOR_IS_MULTITHREADED /* Skip this test if we aren't threading. We should be threading most * everywhere by now. */ if (1) return; #endif _thread_test_mutex = tor_mutex_new(); _thread_test_start1 = tor_mutex_new(); _thread_test_start2 = tor_mutex_new(); _thread_test_strmap = strmap_new(); s1 = tor_strdup("thread 1"); s2 = tor_strdup("thread 2"); tor_mutex_acquire(_thread_test_start1); tor_mutex_acquire(_thread_test_start2); spawn_func(_thread_test_func, s1); spawn_func(_thread_test_func, s2); tor_mutex_release(_thread_test_start2); tor_mutex_release(_thread_test_start1); started = time(NULL); while (!done) { tor_mutex_acquire(_thread_test_mutex); strmap_assert_ok(_thread_test_strmap); if (strmap_get(_thread_test_strmap, "thread 1") && strmap_get(_thread_test_strmap, "thread 2")) { done = 1; } else if (time(NULL) > started + 25) { timedout = done = 1; } tor_mutex_release(_thread_test_mutex); } tor_mutex_free(_thread_test_mutex); tor_mutex_acquire(_thread_test_start1); tor_mutex_release(_thread_test_start1); tor_mutex_acquire(_thread_test_start2); tor_mutex_release(_thread_test_start2); if (timedout) { printf("\nTimed out: %d %d", t1_count, t2_count); test_assert(strmap_get(_thread_test_strmap, "thread 1")); test_assert(strmap_get(_thread_test_strmap, "thread 2")); test_assert(!timedout); } /* different thread IDs. */ test_assert(strcmp(strmap_get(_thread_test_strmap, "thread 1"), strmap_get(_thread_test_strmap, "thread 2"))); test_assert(!strcmp(strmap_get(_thread_test_strmap, "thread 1"), strmap_get(_thread_test_strmap, "last to run")) || !strcmp(strmap_get(_thread_test_strmap, "thread 2"), strmap_get(_thread_test_strmap, "last to run"))); done: tor_free(s1); tor_free(s2); tor_free(_thread1_name); tor_free(_thread2_name); if (_thread_test_strmap) strmap_free(_thread_test_strmap, NULL); if (_thread_test_start1) tor_mutex_free(_thread_test_start1); if (_thread_test_start2) tor_mutex_free(_thread_test_start2); } /** Helper: return a tristate based on comparing two strings. */ static int _compare_strings_for_pqueue(const void *s1, const void *s2) { return strcmp((const char*)s1, (const char*)s2); } /** Run unit tests for heap-based priority queue functions. */ static void test_util_pqueue(void) { smartlist_t *sl = NULL; int (*cmp)(const void *, const void*); #define OK() smartlist_pqueue_assert_ok(sl, cmp) cmp = _compare_strings_for_pqueue; sl = smartlist_create(); smartlist_pqueue_add(sl, cmp, (char*)"cows"); smartlist_pqueue_add(sl, cmp, (char*)"zebras"); smartlist_pqueue_add(sl, cmp, (char*)"fish"); smartlist_pqueue_add(sl, cmp, (char*)"frogs"); smartlist_pqueue_add(sl, cmp, (char*)"apples"); smartlist_pqueue_add(sl, cmp, (char*)"squid"); smartlist_pqueue_add(sl, cmp, (char*)"daschunds"); smartlist_pqueue_add(sl, cmp, (char*)"eggplants"); smartlist_pqueue_add(sl, cmp, (char*)"weissbier"); smartlist_pqueue_add(sl, cmp, (char*)"lobsters"); smartlist_pqueue_add(sl, cmp, (char*)"roquefort"); OK(); test_eq(smartlist_len(sl), 11); test_streq(smartlist_get(sl, 0), "apples"); test_streq(smartlist_pqueue_pop(sl, cmp), "apples"); test_eq(smartlist_len(sl), 10); OK(); test_streq(smartlist_pqueue_pop(sl, cmp), "cows"); test_streq(smartlist_pqueue_pop(sl, cmp), "daschunds"); smartlist_pqueue_add(sl, cmp, (char*)"chinchillas"); OK(); smartlist_pqueue_add(sl, cmp, (char*)"fireflies"); OK(); test_streq(smartlist_pqueue_pop(sl, cmp), "chinchillas"); test_streq(smartlist_pqueue_pop(sl, cmp), "eggplants"); test_streq(smartlist_pqueue_pop(sl, cmp), "fireflies"); OK(); test_streq(smartlist_pqueue_pop(sl, cmp), "fish"); test_streq(smartlist_pqueue_pop(sl, cmp), "frogs"); test_streq(smartlist_pqueue_pop(sl, cmp), "lobsters"); test_streq(smartlist_pqueue_pop(sl, cmp), "roquefort"); OK(); test_eq(smartlist_len(sl), 3); test_streq(smartlist_pqueue_pop(sl, cmp), "squid"); test_streq(smartlist_pqueue_pop(sl, cmp), "weissbier"); test_streq(smartlist_pqueue_pop(sl, cmp), "zebras"); test_eq(smartlist_len(sl), 0); OK(); #undef OK done: if (sl) smartlist_free(sl); } /** Run unit tests for compression functions */ static void test_util_gzip(void) { char *buf1=NULL, *buf2=NULL, *buf3=NULL, *cp1, *cp2; const char *ccp2; size_t len1, len2; tor_zlib_state_t *state = NULL; buf1 = tor_strdup("AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAZAAAAAAAAAAAAAAAAAAAZ"); test_assert(detect_compression_method(buf1, strlen(buf1)) == UNKNOWN_METHOD); if (is_gzip_supported()) { test_assert(!tor_gzip_compress(&buf2, &len1, buf1, strlen(buf1)+1, GZIP_METHOD)); test_assert(buf2); test_assert(!memcmp(buf2, "\037\213", 2)); /* Gzip magic. */ test_assert(detect_compression_method(buf2, len1) == GZIP_METHOD); test_assert(!tor_gzip_uncompress(&buf3, &len2, buf2, len1, GZIP_METHOD, 1, LOG_INFO)); test_assert(buf3); test_streq(buf1,buf3); tor_free(buf2); tor_free(buf3); } test_assert(!tor_gzip_compress(&buf2, &len1, buf1, strlen(buf1)+1, ZLIB_METHOD)); test_assert(buf2); test_assert(!memcmp(buf2, "\x78\xDA", 2)); /* deflate magic. */ test_assert(detect_compression_method(buf2, len1) == ZLIB_METHOD); test_assert(!tor_gzip_uncompress(&buf3, &len2, buf2, len1, ZLIB_METHOD, 1, LOG_INFO)); test_assert(buf3); test_streq(buf1,buf3); /* Check whether we can uncompress concatenated, compresed strings. */ tor_free(buf3); buf2 = tor_realloc(buf2, len1*2); memcpy(buf2+len1, buf2, len1); test_assert(!tor_gzip_uncompress(&buf3, &len2, buf2, len1*2, ZLIB_METHOD, 1, LOG_INFO)); test_eq(len2, (strlen(buf1)+1)*2); test_memeq(buf3, "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAZAAAAAAAAAAAAAAAAAAAZ\0" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAZAAAAAAAAAAAAAAAAAAAZ\0", (strlen(buf1)+1)*2); tor_free(buf1); tor_free(buf2); tor_free(buf3); /* Check whether we can uncompress partial strings. */ buf1 = tor_strdup("String with low redundancy that won't be compressed much."); test_assert(!tor_gzip_compress(&buf2, &len1, buf1, strlen(buf1)+1, ZLIB_METHOD)); tor_assert(len1>16); /* when we allow an uncomplete string, we should succeed.*/ tor_assert(!tor_gzip_uncompress(&buf3, &len2, buf2, len1-16, ZLIB_METHOD, 0, LOG_INFO)); buf3[len2]='\0'; tor_assert(len2 > 5); tor_assert(!strcmpstart(buf1, buf3)); /* when we demand a complete string, this must fail. */ tor_free(buf3); tor_assert(tor_gzip_uncompress(&buf3, &len2, buf2, len1-16, ZLIB_METHOD, 1, LOG_INFO)); tor_assert(!buf3); /* Now, try streaming compression. */ tor_free(buf1); tor_free(buf2); tor_free(buf3); state = tor_zlib_new(1, ZLIB_METHOD); tor_assert(state); cp1 = buf1 = tor_malloc(1024); len1 = 1024; ccp2 = "ABCDEFGHIJABCDEFGHIJ"; len2 = 21; test_assert(tor_zlib_process(state, &cp1, &len1, &ccp2, &len2, 0) == TOR_ZLIB_OK); test_eq(len2, 0); /* Make sure we compressed it all. */ test_assert(cp1 > buf1); len2 = 0; cp2 = cp1; test_assert(tor_zlib_process(state, &cp1, &len1, &ccp2, &len2, 1) == TOR_ZLIB_DONE); test_eq(len2, 0); test_assert(cp1 > cp2); /* Make sure we really added something. */ tor_assert(!tor_gzip_uncompress(&buf3, &len2, buf1, 1024-len1, ZLIB_METHOD, 1, LOG_WARN)); test_streq(buf3, "ABCDEFGHIJABCDEFGHIJ"); /*Make sure it compressed right.*/ done: if (state) tor_zlib_free(state); tor_free(buf2); tor_free(buf3); tor_free(buf1); } /** Run unit tests for string-to-void* map functions */ static void test_util_strmap(void) { strmap_t *map; strmap_iter_t *iter; const char *k; void *v; char *visited = NULL; smartlist_t *found_keys = NULL; map = strmap_new(); test_assert(map); test_eq(strmap_size(map), 0); test_assert(strmap_isempty(map)); v = strmap_set(map, "K1", (void*)99); test_eq(v, NULL); test_assert(!strmap_isempty(map)); v = strmap_set(map, "K2", (void*)101); test_eq(v, NULL); v = strmap_set(map, "K1", (void*)100); test_eq(v, (void*)99); test_eq_ptr(strmap_get(map,"K1"), (void*)100); test_eq_ptr(strmap_get(map,"K2"), (void*)101); test_eq_ptr(strmap_get(map,"K-not-there"), NULL); strmap_assert_ok(map); v = strmap_remove(map,"K2"); strmap_assert_ok(map); test_eq_ptr(v, (void*)101); test_eq_ptr(strmap_get(map,"K2"), NULL); test_eq_ptr(strmap_remove(map,"K2"), NULL); strmap_set(map, "K2", (void*)101); strmap_set(map, "K3", (void*)102); strmap_set(map, "K4", (void*)103); test_eq(strmap_size(map), 4); strmap_assert_ok(map); strmap_set(map, "K5", (void*)104); strmap_set(map, "K6", (void*)105); strmap_assert_ok(map); /* Test iterator. */ iter = strmap_iter_init(map); found_keys = smartlist_create(); while (!strmap_iter_done(iter)) { strmap_iter_get(iter,&k,&v); smartlist_add(found_keys, tor_strdup(k)); test_eq_ptr(v, strmap_get(map, k)); if (!strcmp(k, "K2")) { iter = strmap_iter_next_rmv(map,iter); } else { iter = strmap_iter_next(map,iter); } } /* Make sure we removed K2, but not the others. */ test_eq_ptr(strmap_get(map, "K2"), NULL); test_eq_ptr(strmap_get(map, "K5"), (void*)104); /* Make sure we visited everyone once */ smartlist_sort_strings(found_keys); visited = smartlist_join_strings(found_keys, ":", 0, NULL); test_streq(visited, "K1:K2:K3:K4:K5:K6"); strmap_assert_ok(map); /* Clean up after ourselves. */ strmap_free(map, NULL); map = NULL; /* Now try some lc functions. */ map = strmap_new(); strmap_set_lc(map,"Ab.C", (void*)1); test_eq_ptr(strmap_get(map,"ab.c"), (void*)1); strmap_assert_ok(map); test_eq_ptr(strmap_get_lc(map,"AB.C"), (void*)1); test_eq_ptr(strmap_get(map,"AB.C"), NULL); test_eq_ptr(strmap_remove_lc(map,"aB.C"), (void*)1); strmap_assert_ok(map); test_eq_ptr(strmap_get_lc(map,"AB.C"), NULL); done: if (map) strmap_free(map,NULL); if (found_keys) { SMARTLIST_FOREACH(found_keys, char *, cp, tor_free(cp)); smartlist_free(found_keys); } tor_free(visited); } /** Run unit tests for mmap() wrapper functionality. */ static void test_util_mmap(void) { char *fname1 = tor_strdup(get_fname("mapped_1")); char *fname2 = tor_strdup(get_fname("mapped_2")); char *fname3 = tor_strdup(get_fname("mapped_3")); const size_t buflen = 17000; char *buf = tor_malloc(17000); tor_mmap_t *mapping = NULL; crypto_rand(buf, buflen); mapping = tor_mmap_file(fname1); test_assert(! mapping); write_str_to_file(fname1, "Short file.", 1); write_bytes_to_file(fname2, buf, buflen, 1); write_bytes_to_file(fname3, buf, 16384, 1); mapping = tor_mmap_file(fname1); test_assert(mapping); test_eq(mapping->size, strlen("Short file.")); test_streq(mapping->data, "Short file."); #ifdef MS_WINDOWS tor_munmap_file(mapping); mapping = NULL; test_assert(unlink(fname1) == 0); #else /* make sure we can unlink. */ test_assert(unlink(fname1) == 0); test_streq(mapping->data, "Short file."); tor_munmap_file(mapping); mapping = NULL; #endif /* Now a zero-length file. */ write_str_to_file(fname1, "", 1); mapping = tor_mmap_file(fname1); test_eq(mapping, NULL); test_eq(ERANGE, errno); unlink(fname1); /* Make sure that we fail to map a no-longer-existent file. */ mapping = tor_mmap_file(fname1); test_assert(mapping == NULL); /* Now try a big file that stretches across a few pages and isn't aligned */ mapping = tor_mmap_file(fname2); test_assert(mapping); test_eq(mapping->size, buflen); test_memeq(mapping->data, buf, buflen); tor_munmap_file(mapping); mapping = NULL; /* Now try a big aligned file. */ mapping = tor_mmap_file(fname3); test_assert(mapping); test_eq(mapping->size, 16384); test_memeq(mapping->data, buf, 16384); tor_munmap_file(mapping); mapping = NULL; done: unlink(fname1); unlink(fname2); unlink(fname3); tor_free(fname1); tor_free(fname2); tor_free(fname3); tor_free(buf); if (mapping) tor_munmap_file(mapping); } /** Run unit tests for escaping/unescaping data for use by controllers. */ static void test_util_control_formats(void) { char *out = NULL; const char *inp = "..This is a test\r\nof the emergency \nbroadcast\r\n..system.\r\nZ.\r\n"; size_t sz; sz = read_escaped_data(inp, strlen(inp), &out); test_streq(out, ".This is a test\nof the emergency \nbroadcast\n.system.\nZ.\n"); test_eq(sz, strlen(out)); done: tor_free(out); } /** Run unit tests for the onion handshake code. */ static void test_onion_handshake(void) { /* client-side */ crypto_dh_env_t *c_dh = NULL; char c_buf[ONIONSKIN_CHALLENGE_LEN]; char c_keys[40]; /* server-side */ char s_buf[ONIONSKIN_REPLY_LEN]; char s_keys[40]; /* shared */ crypto_pk_env_t *pk = NULL; pk = pk_generate(0); /* client handshake 1. */ memset(c_buf, 0, ONIONSKIN_CHALLENGE_LEN); test_assert(! onion_skin_create(pk, &c_dh, c_buf)); /* server handshake */ memset(s_buf, 0, ONIONSKIN_REPLY_LEN); memset(s_keys, 0, 40); test_assert(! onion_skin_server_handshake(c_buf, pk, NULL, s_buf, s_keys, 40)); /* client handshake 2 */ memset(c_keys, 0, 40); test_assert(! onion_skin_client_handshake(c_dh, s_buf, c_keys, 40)); if (memcmp(c_keys, s_keys, 40)) { puts("Aiiiie"); exit(1); } test_memeq(c_keys, s_keys, 40); memset(s_buf, 0, 40); test_memneq(c_keys, s_buf, 40); done: if (c_dh) crypto_dh_free(c_dh); if (pk) crypto_free_pk_env(pk); } /** Run unit tests for router descriptor generation logic. */ static void test_dir_format(void) { char buf[8192], buf2[8192]; char platform[256]; char fingerprint[FINGERPRINT_LEN+1]; char *pk1_str = NULL, *pk2_str = NULL, *pk3_str = NULL, *cp; size_t pk1_str_len, pk2_str_len, pk3_str_len; routerinfo_t *r1=NULL, *r2=NULL; crypto_pk_env_t *pk1 = NULL, *pk2 = NULL, *pk3 = NULL; routerinfo_t *rp1 = NULL; addr_policy_t *ex1, *ex2; routerlist_t *dir1 = NULL, *dir2 = NULL; tor_version_t ver1; pk1 = pk_generate(0); pk2 = pk_generate(1); pk3 = pk_generate(2); test_assert( is_legal_nickname("a")); test_assert(!is_legal_nickname("")); test_assert(!is_legal_nickname("abcdefghijklmnopqrst")); /* 20 chars */ test_assert(!is_legal_nickname("hyphen-")); /* bad char */ test_assert( is_legal_nickname("abcdefghijklmnopqrs")); /* 19 chars */ test_assert(!is_legal_nickname("$AAAAAAAA01234AAAAAAAAAAAAAAAAAAAAAAAAAAA")); /* valid */ test_assert( is_legal_nickname_or_hexdigest( "$AAAAAAAA01234AAAAAAAAAAAAAAAAAAAAAAAAAAA")); test_assert( is_legal_nickname_or_hexdigest( "$AAAAAAAA01234AAAAAAAAAAAAAAAAAAAAAAAAAAA=fred")); test_assert( is_legal_nickname_or_hexdigest( "$AAAAAAAA01234AAAAAAAAAAAAAAAAAAAAAAAAAAA~fred")); /* too short */ test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA")); /* illegal char */ test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAzAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA")); /* hex part too long */ test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA")); test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA=fred")); /* Bad nickname */ test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA=")); test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA~")); test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA~hyphen-")); test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA~" "abcdefghijklmnoppqrst")); /* Bad extra char. */ test_assert(!is_legal_nickname_or_hexdigest( "$AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA!")); test_assert(is_legal_nickname_or_hexdigest("xyzzy")); test_assert(is_legal_nickname_or_hexdigest("abcdefghijklmnopqrs")); test_assert(!is_legal_nickname_or_hexdigest("abcdefghijklmnopqrst")); get_platform_str(platform, sizeof(platform)); r1 = tor_malloc_zero(sizeof(routerinfo_t)); r1->address = tor_strdup("18.244.0.1"); r1->addr = 0xc0a80001u; /* 192.168.0.1 */ r1->cache_info.published_on = 0; r1->or_port = 9000; r1->dir_port = 9003; r1->onion_pkey = crypto_pk_dup_key(pk1); r1->identity_pkey = crypto_pk_dup_key(pk2); r1->bandwidthrate = 1000; r1->bandwidthburst = 5000; r1->bandwidthcapacity = 10000; r1->exit_policy = NULL; r1->nickname = tor_strdup("Magri"); r1->platform = tor_strdup(platform); ex1 = tor_malloc_zero(sizeof(addr_policy_t)); ex2 = tor_malloc_zero(sizeof(addr_policy_t)); ex1->policy_type = ADDR_POLICY_ACCEPT; tor_addr_from_ipv4h(&ex1->addr, 0); ex1->maskbits = 0; ex1->prt_min = ex1->prt_max = 80; ex2->policy_type = ADDR_POLICY_REJECT; tor_addr_from_ipv4h(&ex2->addr, 18<<24); ex2->maskbits = 8; ex2->prt_min = ex2->prt_max = 24; r2 = tor_malloc_zero(sizeof(routerinfo_t)); r2->address = tor_strdup("1.1.1.1"); r2->addr = 0x0a030201u; /* 10.3.2.1 */ r2->platform = tor_strdup(platform); r2->cache_info.published_on = 5; r2->or_port = 9005; r2->dir_port = 0; r2->onion_pkey = crypto_pk_dup_key(pk2); r2->identity_pkey = crypto_pk_dup_key(pk1); r2->bandwidthrate = r2->bandwidthburst = r2->bandwidthcapacity = 3000; r2->exit_policy = smartlist_create(); smartlist_add(r2->exit_policy, ex2); smartlist_add(r2->exit_policy, ex1); r2->nickname = tor_strdup("Fred"); test_assert(!crypto_pk_write_public_key_to_string(pk1, &pk1_str, &pk1_str_len)); test_assert(!crypto_pk_write_public_key_to_string(pk2 , &pk2_str, &pk2_str_len)); test_assert(!crypto_pk_write_public_key_to_string(pk3 , &pk3_str, &pk3_str_len)); memset(buf, 0, 2048); test_assert(router_dump_router_to_string(buf, 2048, r1, pk2)>0); strlcpy(buf2, "router Magri 18.244.0.1 9000 0 9003\n" "platform Tor "VERSION" on ", sizeof(buf2)); strlcat(buf2, get_uname(), sizeof(buf2)); strlcat(buf2, "\n" "opt protocols Link 1 2 Circuit 1\n" "published 1970-01-01 00:00:00\n" "opt fingerprint ", sizeof(buf2)); test_assert(!crypto_pk_get_fingerprint(pk2, fingerprint, 1)); strlcat(buf2, fingerprint, sizeof(buf2)); strlcat(buf2, "\nuptime 0\n" /* XXX the "0" above is hardcoded, but even if we made it reflect * uptime, that still wouldn't make it right, because the two * descriptors might be made on different seconds... hm. */ "bandwidth 1000 5000 10000\n" "opt extra-info-digest 0000000000000000000000000000000000000000\n" "onion-key\n", sizeof(buf2)); strlcat(buf2, pk1_str, sizeof(buf2)); strlcat(buf2, "signing-key\n", sizeof(buf2)); strlcat(buf2, pk2_str, sizeof(buf2)); strlcat(buf2, "opt hidden-service-dir\n", sizeof(buf2)); strlcat(buf2, "reject *:*\nrouter-signature\n", sizeof(buf2)); buf[strlen(buf2)] = '\0'; /* Don't compare the sig; it's never the same * twice */ test_streq(buf, buf2); test_assert(router_dump_router_to_string(buf, 2048, r1, pk2)>0); cp = buf; rp1 = router_parse_entry_from_string((const char*)cp,NULL,1,0,NULL); test_assert(rp1); test_streq(rp1->address, r1->address); test_eq(rp1->or_port, r1->or_port); //test_eq(rp1->dir_port, r1->dir_port); test_eq(rp1->bandwidthrate, r1->bandwidthrate); test_eq(rp1->bandwidthburst, r1->bandwidthburst); test_eq(rp1->bandwidthcapacity, r1->bandwidthcapacity); test_assert(crypto_pk_cmp_keys(rp1->onion_pkey, pk1) == 0); test_assert(crypto_pk_cmp_keys(rp1->identity_pkey, pk2) == 0); //test_assert(rp1->exit_policy == NULL); #if 0 /* XXX Once we have exit policies, test this again. XXX */ strlcpy(buf2, "router tor.tor.tor 9005 0 0 3000\n", sizeof(buf2)); strlcat(buf2, pk2_str, sizeof(buf2)); strlcat(buf2, "signing-key\n", sizeof(buf2)); strlcat(buf2, pk1_str, sizeof(buf2)); strlcat(buf2, "accept *:80\nreject 18.*:24\n\n", sizeof(buf2)); test_assert(router_dump_router_to_string(buf, 2048, &r2, pk2)>0); test_streq(buf, buf2); cp = buf; rp2 = router_parse_entry_from_string(&cp,1); test_assert(rp2); test_streq(rp2->address, r2.address); test_eq(rp2->or_port, r2.or_port); test_eq(rp2->dir_port, r2.dir_port); test_eq(rp2->bandwidth, r2.bandwidth); test_assert(crypto_pk_cmp_keys(rp2->onion_pkey, pk2) == 0); test_assert(crypto_pk_cmp_keys(rp2->identity_pkey, pk1) == 0); test_eq(rp2->exit_policy->policy_type, EXIT_POLICY_ACCEPT); test_streq(rp2->exit_policy->string, "accept *:80"); test_streq(rp2->exit_policy->address, "*"); test_streq(rp2->exit_policy->port, "80"); test_eq(rp2->exit_policy->next->policy_type, EXIT_POLICY_REJECT); test_streq(rp2->exit_policy->next->string, "reject 18.*:24"); test_streq(rp2->exit_policy->next->address, "18.*"); test_streq(rp2->exit_policy->next->port, "24"); test_assert(rp2->exit_policy->next->next == NULL); /* Okay, now for the directories. */ { fingerprint_list = smartlist_create(); crypto_pk_get_fingerprint(pk2, buf, 1); add_fingerprint_to_dir("Magri", buf, fingerprint_list); crypto_pk_get_fingerprint(pk1, buf, 1); add_fingerprint_to_dir("Fred", buf, fingerprint_list); } { char d[DIGEST_LEN]; const char *m; /* XXXX NM re-enable. */ /* Make sure routers aren't too far in the past any more. */ r1->cache_info.published_on = time(NULL); r2->cache_info.published_on = time(NULL)-3*60*60; test_assert(router_dump_router_to_string(buf, 2048, r1, pk2)>0); test_eq(dirserv_add_descriptor(buf,&m), ROUTER_ADDED_NOTIFY_GENERATOR); test_assert(router_dump_router_to_string(buf, 2048, r2, pk1)>0); test_eq(dirserv_add_descriptor(buf,&m), ROUTER_ADDED_NOTIFY_GENERATOR); get_options()->Nickname = tor_strdup("DirServer"); test_assert(!dirserv_dump_directory_to_string(&cp,pk3, 0)); crypto_pk_get_digest(pk3, d); test_assert(!router_parse_directory(cp)); test_eq(2, smartlist_len(dir1->routers)); tor_free(cp); } #endif dirserv_free_fingerprint_list(); /* Try out version parsing functionality */ test_eq(0, tor_version_parse("0.3.4pre2-cvs", &ver1)); test_eq(0, ver1.major); test_eq(3, ver1.minor); test_eq(4, ver1.micro); test_eq(VER_PRE, ver1.status); test_eq(2, ver1.patchlevel); test_eq(0, tor_version_parse("0.3.4rc1", &ver1)); test_eq(0, ver1.major); test_eq(3, ver1.minor); test_eq(4, ver1.micro); test_eq(VER_RC, ver1.status); test_eq(1, ver1.patchlevel); test_eq(0, tor_version_parse("1.3.4", &ver1)); test_eq(1, ver1.major); test_eq(3, ver1.minor); test_eq(4, ver1.micro); test_eq(VER_RELEASE, ver1.status); test_eq(0, ver1.patchlevel); test_eq(0, tor_version_parse("1.3.4.999", &ver1)); test_eq(1, ver1.major); test_eq(3, ver1.minor); test_eq(4, ver1.micro); test_eq(VER_RELEASE, ver1.status); test_eq(999, ver1.patchlevel); test_eq(0, tor_version_parse("0.1.2.4-alpha", &ver1)); test_eq(0, ver1.major); test_eq(1, ver1.minor); test_eq(2, ver1.micro); test_eq(4, ver1.patchlevel); test_eq(VER_RELEASE, ver1.status); test_streq("alpha", ver1.status_tag); test_eq(0, tor_version_parse("0.1.2.4", &ver1)); test_eq(0, ver1.major); test_eq(1, ver1.minor); test_eq(2, ver1.micro); test_eq(4, ver1.patchlevel); test_eq(VER_RELEASE, ver1.status); test_streq("", ver1.status_tag); #define test_eq_vs(vs1, vs2) test_eq_type(version_status_t, "%d", (vs1), (vs2)) #define test_v_i_o(val, ver, lst) \ test_eq_vs(val, tor_version_is_obsolete(ver, lst)) /* make sure tor_version_is_obsolete() works */ test_v_i_o(VS_OLD, "0.0.1", "Tor 0.0.2"); test_v_i_o(VS_OLD, "0.0.1", "0.0.2, Tor 0.0.3"); test_v_i_o(VS_OLD, "0.0.1", "0.0.2,Tor 0.0.3"); test_v_i_o(VS_OLD, "0.0.1","0.0.3,BetterTor 0.0.1"); test_v_i_o(VS_RECOMMENDED, "0.0.2", "Tor 0.0.2,Tor 0.0.3"); test_v_i_o(VS_NEW_IN_SERIES, "0.0.2", "Tor 0.0.2pre1,Tor 0.0.3"); test_v_i_o(VS_OLD, "0.0.2", "Tor 0.0.2.1,Tor 0.0.3"); test_v_i_o(VS_NEW, "0.1.0", "Tor 0.0.2,Tor 0.0.3"); test_v_i_o(VS_RECOMMENDED, "0.0.7rc2", "0.0.7,Tor 0.0.7rc2,Tor 0.0.8"); test_v_i_o(VS_OLD, "0.0.5.0", "0.0.5.1-cvs"); test_v_i_o(VS_NEW_IN_SERIES, "0.0.5.1-cvs", "0.0.5, 0.0.6"); /* Not on list, but newer than any in same series. */ test_v_i_o(VS_NEW_IN_SERIES, "0.1.0.3", "Tor 0.1.0.2,Tor 0.0.9.5,Tor 0.1.1.0"); /* Series newer than any on list. */ test_v_i_o(VS_NEW, "0.1.2.3", "Tor 0.1.0.2,Tor 0.0.9.5,Tor 0.1.1.0"); /* Series older than any on list. */ test_v_i_o(VS_OLD, "0.0.1.3", "Tor 0.1.0.2,Tor 0.0.9.5,Tor 0.1.1.0"); /* Not on list, not newer than any on same series. */ test_v_i_o(VS_UNRECOMMENDED, "0.1.0.1", "Tor 0.1.0.2,Tor 0.0.9.5,Tor 0.1.1.0"); /* On list, not newer than any on same series. */ test_v_i_o(VS_UNRECOMMENDED, "0.1.0.1", "Tor 0.1.0.2,Tor 0.0.9.5,Tor 0.1.1.0"); test_eq(0, tor_version_as_new_as("Tor 0.0.5", "0.0.9pre1-cvs")); test_eq(1, tor_version_as_new_as( "Tor 0.0.8 on Darwin 64-121-192-100.c3-0." "sfpo-ubr1.sfrn-sfpo.ca.cable.rcn.com Power Macintosh", "0.0.8rc2")); test_eq(0, tor_version_as_new_as( "Tor 0.0.8 on Darwin 64-121-192-100.c3-0." "sfpo-ubr1.sfrn-sfpo.ca.cable.rcn.com Power Macintosh", "0.0.8.2")); /* Now try svn revisions. */ test_eq(1, tor_version_as_new_as("Tor 0.2.1.0-dev (r100)", "Tor 0.2.1.0-dev (r99)")); test_eq(1, tor_version_as_new_as("Tor 0.2.1.0-dev (r100) on Banana Jr", "Tor 0.2.1.0-dev (r99) on Hal 9000")); test_eq(1, tor_version_as_new_as("Tor 0.2.1.0-dev (r100)", "Tor 0.2.1.0-dev on Colossus")); test_eq(0, tor_version_as_new_as("Tor 0.2.1.0-dev (r99)", "Tor 0.2.1.0-dev (r100)")); test_eq(0, tor_version_as_new_as("Tor 0.2.1.0-dev (r99) on MCP", "Tor 0.2.1.0-dev (r100) on AM")); test_eq(0, tor_version_as_new_as("Tor 0.2.1.0-dev", "Tor 0.2.1.0-dev (r99)")); test_eq(1, tor_version_as_new_as("Tor 0.2.1.1", "Tor 0.2.1.0-dev (r99)")); done: if (r1) routerinfo_free(r1); if (r2) routerinfo_free(r2); tor_free(pk1_str); tor_free(pk2_str); tor_free(pk3_str); if (pk1) crypto_free_pk_env(pk1); if (pk2) crypto_free_pk_env(pk2); if (pk3) crypto_free_pk_env(pk3); if (rp1) routerinfo_free(rp1); tor_free(dir1); /* XXXX And more !*/ tor_free(dir2); /* And more !*/ } /** Run unit tests for misc directory functions. */ static void test_dirutil(void) { smartlist_t *sl = smartlist_create(); fp_pair_t *pair; dir_split_resource_into_fingerprint_pairs( /* Two pairs, out of order, with one duplicate. */ "73656372657420646174612E0000000000FFFFFF-" "557365204145532d32353620696e73746561642e+" "73656372657420646174612E0000000000FFFFFF-" "557365204145532d32353620696e73746561642e+" "48657861646563696d616c2069736e277420736f-" "676f6f6420666f7220686964696e6720796f7572.z", sl); test_eq(smartlist_len(sl), 2); pair = smartlist_get(sl, 0); test_memeq(pair->first, "Hexadecimal isn't so", DIGEST_LEN); test_memeq(pair->second, "good for hiding your", DIGEST_LEN); pair = smartlist_get(sl, 1); test_memeq(pair->first, "secret data.\0\0\0\0\0\xff\xff\xff", DIGEST_LEN); test_memeq(pair->second, "Use AES-256 instead.", DIGEST_LEN); done: SMARTLIST_FOREACH(sl, fp_pair_t *, pair, tor_free(pair)); smartlist_free(sl); } extern const char AUTHORITY_CERT_1[]; extern const char AUTHORITY_SIGNKEY_1[]; extern const char AUTHORITY_CERT_2[]; extern const char AUTHORITY_SIGNKEY_2[]; extern const char AUTHORITY_CERT_3[]; extern const char AUTHORITY_SIGNKEY_3[]; /** Helper: Test that two networkstatus_voter_info_t do in fact represent the * same voting authority, and that they do in fact have all the same * information. */ static void test_same_voter(networkstatus_voter_info_t *v1, networkstatus_voter_info_t *v2) { test_streq(v1->nickname, v2->nickname); test_memeq(v1->identity_digest, v2->identity_digest, DIGEST_LEN); test_streq(v1->address, v2->address); test_eq(v1->addr, v2->addr); test_eq(v1->dir_port, v2->dir_port); test_eq(v1->or_port, v2->or_port); test_streq(v1->contact, v2->contact); test_memeq(v1->vote_digest, v2->vote_digest, DIGEST_LEN); done: ; } /** Run unit tests for getting the median of a list. */ static void test_util_order_functions(void) { int lst[25], n = 0; // int a=12,b=24,c=25,d=60,e=77; #define median() median_int(lst, n) lst[n++] = 12; test_eq(12, median()); /* 12 */ lst[n++] = 77; //smartlist_shuffle(sl); test_eq(12, median()); /* 12, 77 */ lst[n++] = 77; //smartlist_shuffle(sl); test_eq(77, median()); /* 12, 77, 77 */ lst[n++] = 24; test_eq(24, median()); /* 12,24,77,77 */ lst[n++] = 60; lst[n++] = 12; lst[n++] = 25; //smartlist_shuffle(sl); test_eq(25, median()); /* 12,12,24,25,60,77,77 */ #undef median done: ; } /** Helper: Make a new routerinfo containing the right information for a * given vote_routerstatus_t. */ static routerinfo_t * generate_ri_from_rs(const vote_routerstatus_t *vrs) { routerinfo_t *r; const routerstatus_t *rs = &vrs->status; static time_t published = 0; r = tor_malloc_zero(sizeof(routerinfo_t)); memcpy(r->cache_info.identity_digest, rs->identity_digest, DIGEST_LEN); memcpy(r->cache_info.signed_descriptor_digest, rs->descriptor_digest, DIGEST_LEN); r->cache_info.do_not_cache = 1; r->cache_info.routerlist_index = -1; r->cache_info.signed_descriptor_body = tor_strdup("123456789012345678901234567890123"); r->cache_info.signed_descriptor_len = strlen(r->cache_info.signed_descriptor_body); r->exit_policy = smartlist_create(); r->cache_info.published_on = ++published + time(NULL); return r; } /** Run unit tests for generating and parsing V3 consensus networkstatus * documents. */ static void test_v3_networkstatus(void) { authority_cert_t *cert1=NULL, *cert2=NULL, *cert3=NULL; crypto_pk_env_t *sign_skey_1=NULL, *sign_skey_2=NULL, *sign_skey_3=NULL; crypto_pk_env_t *sign_skey_leg1=NULL; const char *msg=NULL; time_t now = time(NULL); networkstatus_voter_info_t *voter; networkstatus_t *vote=NULL, *v1=NULL, *v2=NULL, *v3=NULL, *con=NULL; vote_routerstatus_t *vrs; routerstatus_t *rs; char *v1_text=NULL, *v2_text=NULL, *v3_text=NULL, *consensus_text=NULL, *cp; smartlist_t *votes = smartlist_create(); /* For generating the two other consensuses. */ char *detached_text1=NULL, *detached_text2=NULL; char *consensus_text2=NULL, *consensus_text3=NULL; networkstatus_t *con2=NULL, *con3=NULL; ns_detached_signatures_t *dsig1=NULL, *dsig2=NULL; /* Parse certificates and keys. */ cert1 = authority_cert_parse_from_string(AUTHORITY_CERT_1, NULL); test_assert(cert1); test_assert(cert1->is_cross_certified); cert2 = authority_cert_parse_from_string(AUTHORITY_CERT_2, NULL); test_assert(cert2); cert3 = authority_cert_parse_from_string(AUTHORITY_CERT_3, NULL); test_assert(cert3); sign_skey_1 = crypto_new_pk_env(); sign_skey_2 = crypto_new_pk_env(); sign_skey_3 = crypto_new_pk_env(); sign_skey_leg1 = pk_generate(4); test_assert(!crypto_pk_read_private_key_from_string(sign_skey_1, AUTHORITY_SIGNKEY_1)); test_assert(!crypto_pk_read_private_key_from_string(sign_skey_2, AUTHORITY_SIGNKEY_2)); test_assert(!crypto_pk_read_private_key_from_string(sign_skey_3, AUTHORITY_SIGNKEY_3)); test_assert(!crypto_pk_cmp_keys(sign_skey_1, cert1->signing_key)); test_assert(!crypto_pk_cmp_keys(sign_skey_2, cert2->signing_key)); /* * Set up a vote; generate it; try to parse it. */ vote = tor_malloc_zero(sizeof(networkstatus_t)); vote->type = NS_TYPE_VOTE; vote->published = now; vote->valid_after = now+1000; vote->fresh_until = now+2000; vote->valid_until = now+3000; vote->vote_seconds = 100; vote->dist_seconds = 200; vote->supported_methods = smartlist_create(); smartlist_split_string(vote->supported_methods, "1 2 3", NULL, 0, -1); vote->client_versions = tor_strdup("0.1.2.14,0.1.2.15"); vote->server_versions = tor_strdup("0.1.2.14,0.1.2.15,0.1.2.16"); vote->known_flags = smartlist_create(); smartlist_split_string(vote->known_flags, "Authority Exit Fast Guard Running Stable V2Dir Valid", 0, SPLIT_SKIP_SPACE|SPLIT_IGNORE_BLANK, 0); vote->voters = smartlist_create(); voter = tor_malloc_zero(sizeof(networkstatus_voter_info_t)); voter->nickname = tor_strdup("Voter1"); voter->address = tor_strdup("1.2.3.4"); voter->addr = 0x01020304; voter->dir_port = 80; voter->or_port = 9000; voter->contact = tor_strdup("voter@example.com"); crypto_pk_get_digest(cert1->identity_key, voter->identity_digest); smartlist_add(vote->voters, voter); vote->cert = authority_cert_dup(cert1); vote->routerstatus_list = smartlist_create(); /* add the first routerstatus. */ vrs = tor_malloc_zero(sizeof(vote_routerstatus_t)); rs = &vrs->status; vrs->version = tor_strdup("0.1.2.14"); rs->published_on = now-1500; strlcpy(rs->nickname, "router2", sizeof(rs->nickname)); memset(rs->identity_digest, 3, DIGEST_LEN); memset(rs->descriptor_digest, 78, DIGEST_LEN); rs->addr = 0x99008801; rs->or_port = 443; rs->dir_port = 8000; /* all flags but running cleared */ rs->is_running = 1; smartlist_add(vote->routerstatus_list, vrs); test_assert(router_add_to_routerlist(generate_ri_from_rs(vrs), &msg,0,0)>=0); /* add the second routerstatus. */ vrs = tor_malloc_zero(sizeof(vote_routerstatus_t)); rs = &vrs->status; vrs->version = tor_strdup("0.2.0.5"); rs->published_on = now-1000; strlcpy(rs->nickname, "router1", sizeof(rs->nickname)); memset(rs->identity_digest, 5, DIGEST_LEN); memset(rs->descriptor_digest, 77, DIGEST_LEN); rs->addr = 0x99009901; rs->or_port = 443; rs->dir_port = 0; rs->is_exit = rs->is_stable = rs->is_fast = rs->is_running = rs->is_valid = rs->is_v2_dir = rs->is_possible_guard = 1; smartlist_add(vote->routerstatus_list, vrs); test_assert(router_add_to_routerlist(generate_ri_from_rs(vrs), &msg,0,0)>=0); /* add the third routerstatus. */ vrs = tor_malloc_zero(sizeof(vote_routerstatus_t)); rs = &vrs->status; vrs->version = tor_strdup("0.1.0.3"); rs->published_on = now-1000; strlcpy(rs->nickname, "router3", sizeof(rs->nickname)); memset(rs->identity_digest, 33, DIGEST_LEN); memset(rs->descriptor_digest, 79, DIGEST_LEN); rs->addr = 0xAA009901; rs->or_port = 400; rs->dir_port = 9999; rs->is_authority = rs->is_exit = rs->is_stable = rs->is_fast = rs->is_running = rs->is_valid = rs->is_v2_dir = rs->is_possible_guard = 1; smartlist_add(vote->routerstatus_list, vrs); test_assert(router_add_to_routerlist(generate_ri_from_rs(vrs), &msg,0,0)>=0); /* add a fourth routerstatus that is not running. */ vrs = tor_malloc_zero(sizeof(vote_routerstatus_t)); rs = &vrs->status; vrs->version = tor_strdup("0.1.6.3"); rs->published_on = now-1000; strlcpy(rs->nickname, "router4", sizeof(rs->nickname)); memset(rs->identity_digest, 34, DIGEST_LEN); memset(rs->descriptor_digest, 48, DIGEST_LEN); rs->addr = 0xC0000203; rs->or_port = 500; rs->dir_port = 1999; /* Running flag (and others) cleared */ smartlist_add(vote->routerstatus_list, vrs); test_assert(router_add_to_routerlist(generate_ri_from_rs(vrs), &msg,0,0)>=0); /* dump the vote and try to parse it. */ v1_text = format_networkstatus_vote(sign_skey_1, vote); test_assert(v1_text); v1 = networkstatus_parse_vote_from_string(v1_text, NULL, NS_TYPE_VOTE); test_assert(v1); /* Make sure the parsed thing was right. */ test_eq(v1->type, NS_TYPE_VOTE); test_eq(v1->published, vote->published); test_eq(v1->valid_after, vote->valid_after); test_eq(v1->fresh_until, vote->fresh_until); test_eq(v1->valid_until, vote->valid_until); test_eq(v1->vote_seconds, vote->vote_seconds); test_eq(v1->dist_seconds, vote->dist_seconds); test_streq(v1->client_versions, vote->client_versions); test_streq(v1->server_versions, vote->server_versions); test_assert(v1->voters && smartlist_len(v1->voters)); voter = smartlist_get(v1->voters, 0); test_streq(voter->nickname, "Voter1"); test_streq(voter->address, "1.2.3.4"); test_eq(voter->addr, 0x01020304); test_eq(voter->dir_port, 80); test_eq(voter->or_port, 9000); test_streq(voter->contact, "voter@example.com"); test_assert(v1->cert); test_assert(!crypto_pk_cmp_keys(sign_skey_1, v1->cert->signing_key)); cp = smartlist_join_strings(v1->known_flags, ":", 0, NULL); test_streq(cp, "Authority:Exit:Fast:Guard:Running:Stable:V2Dir:Valid"); tor_free(cp); test_eq(smartlist_len(v1->routerstatus_list), 4); /* Check the first routerstatus. */ vrs = smartlist_get(v1->routerstatus_list, 0); rs = &vrs->status; test_streq(vrs->version, "0.1.2.14"); test_eq(rs->published_on, now-1500); test_streq(rs->nickname, "router2"); test_memeq(rs->identity_digest, "\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3", DIGEST_LEN); test_memeq(rs->descriptor_digest, "NNNNNNNNNNNNNNNNNNNN", DIGEST_LEN); test_eq(rs->addr, 0x99008801); test_eq(rs->or_port, 443); test_eq(rs->dir_port, 8000); test_eq(vrs->flags, U64_LITERAL(16)); // no flags except "running" /* Check the second routerstatus. */ vrs = smartlist_get(v1->routerstatus_list, 1); rs = &vrs->status; test_streq(vrs->version, "0.2.0.5"); test_eq(rs->published_on, now-1000); test_streq(rs->nickname, "router1"); test_memeq(rs->identity_digest, "\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5", DIGEST_LEN); test_memeq(rs->descriptor_digest, "MMMMMMMMMMMMMMMMMMMM", DIGEST_LEN); test_eq(rs->addr, 0x99009901); test_eq(rs->or_port, 443); test_eq(rs->dir_port, 0); test_eq(vrs->flags, U64_LITERAL(254)); // all flags except "authority." /* Generate second vote. It disagrees on some of the times, * and doesn't list versions, and knows some crazy flags */ vote->published = now+1; vote->fresh_until = now+3005; vote->dist_seconds = 300; authority_cert_free(vote->cert); vote->cert = authority_cert_dup(cert2); tor_free(vote->client_versions); tor_free(vote->server_versions); voter = smartlist_get(vote->voters, 0); tor_free(voter->nickname); tor_free(voter->address); voter->nickname = tor_strdup("Voter2"); voter->address = tor_strdup("2.3.4.5"); voter->addr = 0x02030405; crypto_pk_get_digest(cert2->identity_key, voter->identity_digest); smartlist_add(vote->known_flags, tor_strdup("MadeOfCheese")); smartlist_add(vote->known_flags, tor_strdup("MadeOfTin")); smartlist_sort_strings(vote->known_flags); vrs = smartlist_get(vote->routerstatus_list, 2); smartlist_del_keeporder(vote->routerstatus_list, 2); tor_free(vrs->version); tor_free(vrs); vrs = smartlist_get(vote->routerstatus_list, 0); vrs->status.is_fast = 1; /* generate and parse. */ v2_text = format_networkstatus_vote(sign_skey_2, vote); test_assert(v2_text); v2 = networkstatus_parse_vote_from_string(v2_text, NULL, NS_TYPE_VOTE); test_assert(v2); /* Check that flags come out right.*/ cp = smartlist_join_strings(v2->known_flags, ":", 0, NULL); test_streq(cp, "Authority:Exit:Fast:Guard:MadeOfCheese:MadeOfTin:" "Running:Stable:V2Dir:Valid"); tor_free(cp); vrs = smartlist_get(v2->routerstatus_list, 1); /* 1023 - authority(1) - madeofcheese(16) - madeoftin(32) */ test_eq(vrs->flags, U64_LITERAL(974)); /* Generate the third vote. */ vote->published = now; vote->fresh_until = now+2003; vote->dist_seconds = 250; authority_cert_free(vote->cert); vote->cert = authority_cert_dup(cert3); smartlist_add(vote->supported_methods, tor_strdup("4")); vote->client_versions = tor_strdup("0.1.2.14,0.1.2.17"); vote->server_versions = tor_strdup("0.1.2.10,0.1.2.15,0.1.2.16"); voter = smartlist_get(vote->voters, 0); tor_free(voter->nickname); tor_free(voter->address); voter->nickname = tor_strdup("Voter3"); voter->address = tor_strdup("3.4.5.6"); voter->addr = 0x03040506; crypto_pk_get_digest(cert3->identity_key, voter->identity_digest); /* This one has a legacy id. */ memset(voter->legacy_id_digest, (int)'A', DIGEST_LEN); vrs = smartlist_get(vote->routerstatus_list, 0); smartlist_del_keeporder(vote->routerstatus_list, 0); tor_free(vrs->version); tor_free(vrs); vrs = smartlist_get(vote->routerstatus_list, 0); memset(vrs->status.descriptor_digest, (int)'Z', DIGEST_LEN); test_assert(router_add_to_routerlist(generate_ri_from_rs(vrs), &msg,0,0)>=0); v3_text = format_networkstatus_vote(sign_skey_3, vote); test_assert(v3_text); v3 = networkstatus_parse_vote_from_string(v3_text, NULL, NS_TYPE_VOTE); test_assert(v3); /* Compute a consensus as voter 3. */ smartlist_add(votes, v3); smartlist_add(votes, v1); smartlist_add(votes, v2); consensus_text = networkstatus_compute_consensus(votes, 3, cert3->identity_key, sign_skey_3, "AAAAAAAAAAAAAAAAAAAA", sign_skey_leg1); test_assert(consensus_text); con = networkstatus_parse_vote_from_string(consensus_text, NULL, NS_TYPE_CONSENSUS); test_assert(con); //log_notice(LD_GENERAL, "<<%s>>\n<<%s>>\n<<%s>>\n", // v1_text, v2_text, v3_text); /* Check consensus contents. */ test_assert(con->type == NS_TYPE_CONSENSUS); test_eq(con->published, 0); /* this field only appears in votes. */ test_eq(con->valid_after, now+1000); test_eq(con->fresh_until, now+2003); /* median */ test_eq(con->valid_until, now+3000); test_eq(con->vote_seconds, 100); test_eq(con->dist_seconds, 250); /* median */ test_streq(con->client_versions, "0.1.2.14"); test_streq(con->server_versions, "0.1.2.15,0.1.2.16"); cp = smartlist_join_strings(v2->known_flags, ":", 0, NULL); test_streq(cp, "Authority:Exit:Fast:Guard:MadeOfCheese:MadeOfTin:" "Running:Stable:V2Dir:Valid"); tor_free(cp); test_eq(4, smartlist_len(con->voters)); /*3 voters, 1 legacy key.*/ /* The voter id digests should be in this order. */ test_assert(memcmp(cert2->cache_info.identity_digest, cert1->cache_info.identity_digest,DIGEST_LEN)<0); test_assert(memcmp(cert1->cache_info.identity_digest, cert3->cache_info.identity_digest,DIGEST_LEN)<0); test_same_voter(smartlist_get(con->voters, 1), smartlist_get(v2->voters, 0)); test_same_voter(smartlist_get(con->voters, 2), smartlist_get(v1->voters, 0)); test_same_voter(smartlist_get(con->voters, 3), smartlist_get(v3->voters, 0)); test_assert(!con->cert); test_eq(2, smartlist_len(con->routerstatus_list)); /* There should be two listed routers: one with identity 3, one with * identity 5. */ /* This one showed up in 2 digests. */ rs = smartlist_get(con->routerstatus_list, 0); test_memeq(rs->identity_digest, "\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3\x3", DIGEST_LEN); test_memeq(rs->descriptor_digest, "NNNNNNNNNNNNNNNNNNNN", DIGEST_LEN); test_assert(!rs->is_authority); test_assert(!rs->is_exit); test_assert(!rs->is_fast); test_assert(!rs->is_possible_guard); test_assert(!rs->is_stable); test_assert(rs->is_running); /* If it wasn't running it wouldn't be here */ test_assert(!rs->is_v2_dir); test_assert(!rs->is_valid); test_assert(!rs->is_named); /* XXXX check version */ rs = smartlist_get(con->routerstatus_list, 1); /* This one showed up in 3 digests. Twice with ID 'M', once with 'Z'. */ test_memeq(rs->identity_digest, "\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5\x5", DIGEST_LEN); test_streq(rs->nickname, "router1"); test_memeq(rs->descriptor_digest, "MMMMMMMMMMMMMMMMMMMM", DIGEST_LEN); test_eq(rs->published_on, now-1000); test_eq(rs->addr, 0x99009901); test_eq(rs->or_port, 443); test_eq(rs->dir_port, 0); test_assert(!rs->is_authority); test_assert(rs->is_exit); test_assert(rs->is_fast); test_assert(rs->is_possible_guard); test_assert(rs->is_stable); test_assert(rs->is_running); test_assert(rs->is_v2_dir); test_assert(rs->is_valid); test_assert(!rs->is_named); /* XXXX check version */ // x231 // x213 /* Check signatures. the first voter is a pseudo-entry with a legacy key. * The second one hasn't signed. The fourth one has signed: validate it. */ voter = smartlist_get(con->voters, 1); test_assert(!voter->signature); test_assert(!voter->good_signature); test_assert(!voter->bad_signature); voter = smartlist_get(con->voters, 3); test_assert(voter->signature); test_assert(!voter->good_signature); test_assert(!voter->bad_signature); test_assert(!networkstatus_check_voter_signature(con, smartlist_get(con->voters, 3), cert3)); test_assert(voter->signature); test_assert(voter->good_signature); test_assert(!voter->bad_signature); { const char *msg=NULL; /* Compute the other two signed consensuses. */ smartlist_shuffle(votes); consensus_text2 = networkstatus_compute_consensus(votes, 3, cert2->identity_key, sign_skey_2, NULL,NULL); smartlist_shuffle(votes); consensus_text3 = networkstatus_compute_consensus(votes, 3, cert1->identity_key, sign_skey_1, NULL,NULL); test_assert(consensus_text2); test_assert(consensus_text3); con2 = networkstatus_parse_vote_from_string(consensus_text2, NULL, NS_TYPE_CONSENSUS); con3 = networkstatus_parse_vote_from_string(consensus_text3, NULL, NS_TYPE_CONSENSUS); test_assert(con2); test_assert(con3); /* All three should have the same digest. */ test_memeq(con->networkstatus_digest, con2->networkstatus_digest, DIGEST_LEN); test_memeq(con->networkstatus_digest, con3->networkstatus_digest, DIGEST_LEN); /* Extract a detached signature from con3. */ detached_text1 = networkstatus_get_detached_signatures(con3); tor_assert(detached_text1); /* Try to parse it. */ dsig1 = networkstatus_parse_detached_signatures(detached_text1, NULL); tor_assert(dsig1); /* Are parsed values as expected? */ test_eq(dsig1->valid_after, con3->valid_after); test_eq(dsig1->fresh_until, con3->fresh_until); test_eq(dsig1->valid_until, con3->valid_until); test_memeq(dsig1->networkstatus_digest, con3->networkstatus_digest, DIGEST_LEN); test_eq(1, smartlist_len(dsig1->signatures)); voter = smartlist_get(dsig1->signatures, 0); test_memeq(voter->identity_digest, cert1->cache_info.identity_digest, DIGEST_LEN); /* Try adding it to con2. */ detached_text2 = networkstatus_get_detached_signatures(con2); test_eq(1, networkstatus_add_detached_signatures(con2, dsig1, &msg)); tor_free(detached_text2); detached_text2 = networkstatus_get_detached_signatures(con2); //printf("\n<%s>\n", detached_text2); dsig2 = networkstatus_parse_detached_signatures(detached_text2, NULL); test_assert(dsig2); /* printf("\n"); SMARTLIST_FOREACH(dsig2->signatures, networkstatus_voter_info_t *, vi, { char hd[64]; base16_encode(hd, sizeof(hd), vi->identity_digest, DIGEST_LEN); printf("%s\n", hd); }); */ test_eq(2, smartlist_len(dsig2->signatures)); /* Try adding to con2 twice; verify that nothing changes. */ test_eq(0, networkstatus_add_detached_signatures(con2, dsig1, &msg)); /* Add to con. */ test_eq(2, networkstatus_add_detached_signatures(con, dsig2, &msg)); /* Check signatures */ test_assert(!networkstatus_check_voter_signature(con, smartlist_get(con->voters, 1), cert2)); test_assert(!networkstatus_check_voter_signature(con, smartlist_get(con->voters, 2), cert1)); } done: smartlist_free(votes); tor_free(v1_text); tor_free(v2_text); tor_free(v3_text); tor_free(consensus_text); if (vote) networkstatus_vote_free(vote); if (v1) networkstatus_vote_free(v1); if (v2) networkstatus_vote_free(v2); if (v3) networkstatus_vote_free(v3); if (con) networkstatus_vote_free(con); if (sign_skey_1) crypto_free_pk_env(sign_skey_1); if (sign_skey_2) crypto_free_pk_env(sign_skey_2); if (sign_skey_3) crypto_free_pk_env(sign_skey_3); if (sign_skey_leg1) crypto_free_pk_env(sign_skey_leg1); if (cert1) authority_cert_free(cert1); if (cert2) authority_cert_free(cert2); if (cert3) authority_cert_free(cert3); tor_free(consensus_text2); tor_free(consensus_text3); tor_free(detached_text1); tor_free(detached_text2); if (con2) networkstatus_vote_free(con2); if (con3) networkstatus_vote_free(con3); if (dsig1) ns_detached_signatures_free(dsig1); if (dsig2) ns_detached_signatures_free(dsig2); } /** Helper: Parse the exit policy string in policy_str, and make sure * that policies_summarize() produces the string expected_summary from * it. */ static void test_policy_summary_helper(const char *policy_str, const char *expected_summary) { config_line_t line; smartlist_t *policy = smartlist_create(); char *summary = NULL; int r; line.key = (char*)"foo"; line.value = (char *)policy_str; line.next = NULL; r = policies_parse_exit_policy(&line, &policy, 0, NULL); test_eq(r, 0); summary = policy_summarize(policy); test_assert(summary != NULL); test_streq(summary, expected_summary); done: tor_free(summary); if (policy) addr_policy_list_free(policy); } /** Run unit tests for generating summary lines of exit policies */ static void test_policies(void) { int i; smartlist_t *policy = NULL, *policy2 = NULL; addr_policy_t *p; tor_addr_t tar; config_line_t line; smartlist_t *sm = NULL; char *policy_str = NULL; policy = smartlist_create(); p = router_parse_addr_policy_item_from_string("reject 192.168.0.0/16:*",-1); test_assert(p != NULL); test_eq(ADDR_POLICY_REJECT, p->policy_type); tor_addr_from_ipv4h(&tar, 0xc0a80000u); test_eq(0, tor_addr_compare(&p->addr, &tar, CMP_EXACT)); test_eq(16, p->maskbits); test_eq(1, p->prt_min); test_eq(65535, p->prt_max); smartlist_add(policy, p); test_assert(ADDR_POLICY_ACCEPTED == compare_addr_to_addr_policy(0x01020304u, 2, policy)); test_assert(ADDR_POLICY_PROBABLY_ACCEPTED == compare_addr_to_addr_policy(0, 2, policy)); test_assert(ADDR_POLICY_REJECTED == compare_addr_to_addr_policy(0xc0a80102, 2, policy)); policy2 = NULL; test_assert(0 == policies_parse_exit_policy(NULL, &policy2, 1, NULL)); test_assert(policy2); test_assert(!exit_policy_is_general_exit(policy)); test_assert(exit_policy_is_general_exit(policy2)); test_assert(!exit_policy_is_general_exit(NULL)); test_assert(cmp_addr_policies(policy, policy2)); test_assert(cmp_addr_policies(policy, NULL)); test_assert(!cmp_addr_policies(policy2, policy2)); test_assert(!cmp_addr_policies(NULL, NULL)); test_assert(!policy_is_reject_star(policy2)); test_assert(policy_is_reject_star(policy)); test_assert(policy_is_reject_star(NULL)); addr_policy_list_free(policy); policy = NULL; /* make sure compacting logic works. */ policy = NULL; line.key = (char*)"foo"; line.value = (char*)"accept *:80,reject private:*,reject *:*"; line.next = NULL; test_assert(0 == policies_parse_exit_policy(&line, &policy, 0, NULL)); test_assert(policy); //test_s