/* Copyright (c) 2001-2004, Roger Dingledine. * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson. * Copyright (c) 2007-2019, The Tor Project, Inc. */ /* See LICENSE for licensing information */ #include "orconfig.h" #define COMPAT_PRIVATE #define COMPAT_TIME_PRIVATE #define CONTROL_PRIVATE #define UTIL_PRIVATE #define UTIL_MALLOC_PRIVATE #define SOCKET_PRIVATE #define SUBPROCESS_PRIVATE #include "lib/testsupport/testsupport.h" #include "core/or/or.h" #include "lib/container/buffers.h" #include "app/config/config.h" #include "feature/control/control.h" #include "feature/client/transports.h" #include "lib/crypt_ops/crypto_format.h" #include "lib/crypt_ops/crypto_rand.h" #include "test/test.h" #include "lib/memarea/memarea.h" #include "lib/process/waitpid.h" #include "test/log_test_helpers.h" #include "lib/compress/compress.h" #include "lib/compress/compress_zstd.h" #include "lib/encoding/keyval.h" #include "lib/fdio/fdio.h" #include "lib/fs/winlib.h" #include "lib/process/env.h" #include "lib/process/pidfile.h" #include "lib/process/subprocess.h" #include "lib/intmath/weakrng.h" #include "lib/thread/numcpus.h" #include "lib/math/fp.h" #include "lib/math/laplace.h" #include "lib/meminfo/meminfo.h" #include "lib/time/tvdiff.h" #include "lib/encoding/confline.h" #include "lib/net/socketpair.h" #ifdef HAVE_PWD_H #include #endif #ifdef HAVE_SYS_UTIME_H #include #endif #ifdef HAVE_UTIME_H #include #endif #ifdef HAVE_SYS_STAT_H #include #endif #ifdef HAVE_FCNTL_H #include #endif #ifdef HAVE_UNISTD_H #include #endif #ifdef _WIN32 #include #endif #include #include #include #define INFINITY_DBL ((double)INFINITY) #define NAN_DBL ((double)NAN) /* XXXX this is a minimal wrapper to make the unit tests compile with the * changed tor_timegm interface. */ static time_t tor_timegm_wrapper(const struct tm *tm) { time_t t; if (tor_timegm(tm, &t) < 0) return -1; return t; } #define tor_timegm tor_timegm_wrapper static void test_util_read_until_eof_impl(const char *fname, size_t file_len, size_t read_limit) { char *fifo_name = NULL; char *test_str = NULL; char *str = NULL; size_t sz = 9999999; int fd = -1; int r; fifo_name = tor_strdup(get_fname(fname)); test_str = tor_malloc(file_len); crypto_rand(test_str, file_len); r = write_bytes_to_file(fifo_name, test_str, file_len, 1); tt_int_op(r, OP_EQ, 0); fd = open(fifo_name, O_RDONLY|O_BINARY); tt_int_op(fd, OP_GE, 0); str = read_file_to_str_until_eof(fd, read_limit, &sz); tt_ptr_op(str, OP_NE, NULL); if (read_limit < file_len) tt_int_op(sz, OP_EQ, read_limit); else tt_int_op(sz, OP_EQ, file_len); tt_mem_op(test_str, OP_EQ, str, sz); tt_int_op(str[sz], OP_EQ, '\0'); done: unlink(fifo_name); tor_free(fifo_name); tor_free(test_str); tor_free(str); if (fd >= 0) close(fd); } static void test_util_read_file_eof_tiny_limit(void *arg) { (void)arg; // purposely set limit shorter than what we wrote to the FIFO to // test the maximum, and that it puts the NUL in the right spot test_util_read_until_eof_impl("tor_test_fifo_tiny", 5, 4); } static void test_util_read_file_eof_one_loop_a(void *arg) { (void)arg; test_util_read_until_eof_impl("tor_test_fifo_1ka", 1024, 1023); } static void test_util_read_file_eof_one_loop_b(void *arg) { (void)arg; test_util_read_until_eof_impl("tor_test_fifo_1kb", 1024, 1024); } static void test_util_read_file_eof_two_loops(void *arg) { (void)arg; // write more than 1024 bytes to the FIFO to test two passes through // the loop in the method; if the re-alloc size is changed this // should be updated as well. test_util_read_until_eof_impl("tor_test_fifo_2k", 2048, 10000); } static void test_util_read_file_eof_two_loops_b(void *arg) { (void)arg; test_util_read_until_eof_impl("tor_test_fifo_2kb", 2048, 2048); } static void test_util_read_file_eof_zero_bytes(void *arg) { (void)arg; // zero-byte fifo test_util_read_until_eof_impl("tor_test_fifo_empty", 0, 10000); } /* Test the basic expected behaviour for write_chunks_to_file. * NOTE: This will need to be updated if we ever change the tempfile location * or extension */ static void test_util_write_chunks_to_file(void *arg) { char *fname = NULL; char *tempname = NULL; char *str = NULL; int r; struct stat st; /* These should be two different sizes to ensure the data is different * between the data file and the temp file's 'known string' */ int temp_str_len = 1024; int data_str_len = 512; char *data_str = tor_malloc(data_str_len); char *temp_str = tor_malloc(temp_str_len); smartlist_t *chunks = smartlist_new(); sized_chunk_t c = {data_str, data_str_len/2}; sized_chunk_t c2 = {data_str + data_str_len/2, data_str_len/2}; (void)arg; crypto_rand(temp_str, temp_str_len); crypto_rand(data_str, data_str_len); // Ensure it can write multiple chunks smartlist_add(chunks, &c); smartlist_add(chunks, &c2); /* * Check if it writes using a tempfile */ fname = tor_strdup(get_fname("write_chunks_with_tempfile")); tor_asprintf(&tempname, "%s.tmp", fname); // write a known string to a file where the tempfile will be r = write_bytes_to_file(tempname, temp_str, temp_str_len, 1); tt_int_op(r, OP_EQ, 0); // call write_chunks_to_file r = write_chunks_to_file(fname, chunks, 1, 0); tt_int_op(r, OP_EQ, 0); // assert the file has been written (expected size) str = read_file_to_str(fname, RFTS_BIN, &st); tt_assert(str != NULL); tt_u64_op((uint64_t)st.st_size, OP_EQ, data_str_len); tt_mem_op(data_str, OP_EQ, str, data_str_len); tor_free(str); // assert that the tempfile is removed (should not leave artifacts) str = read_file_to_str(tempname, RFTS_BIN|RFTS_IGNORE_MISSING, &st); tt_assert(str == NULL); // Remove old testfile for second test r = unlink(fname); tt_int_op(r, OP_EQ, 0); tor_free(fname); tor_free(tempname); /* * Check if it skips using a tempfile with flags */ fname = tor_strdup(get_fname("write_chunks_with_no_tempfile")); tor_asprintf(&tempname, "%s.tmp", fname); // write a known string to a file where the tempfile will be r = write_bytes_to_file(tempname, temp_str, temp_str_len, 1); tt_int_op(r, OP_EQ, 0); // call write_chunks_to_file with no_tempfile = true r = write_chunks_to_file(fname, chunks, 1, 1); tt_int_op(r, OP_EQ, 0); // assert the file has been written (expected size) str = read_file_to_str(fname, RFTS_BIN, &st); tt_assert(str != NULL); tt_u64_op((uint64_t)st.st_size, OP_EQ, data_str_len); tt_mem_op(data_str, OP_EQ, str, data_str_len); tor_free(str); // assert the tempfile still contains the known string str = read_file_to_str(tempname, RFTS_BIN, &st); tt_assert(str != NULL); tt_u64_op((uint64_t)st.st_size, OP_EQ, temp_str_len); tt_mem_op(temp_str, OP_EQ, str, temp_str_len); done: unlink(fname); unlink(tempname); smartlist_free(chunks); tor_free(fname); tor_free(tempname); tor_free(str); tor_free(data_str); tor_free(temp_str); } #define _TFE(a, b, f) tt_int_op((a).f, OP_EQ, (b).f) /** test the minimum set of struct tm fields needed for a unique epoch value * this is also the set we use to test tor_timegm */ #define TM_EQUAL(a, b) \ TT_STMT_BEGIN \ _TFE(a, b, tm_year); \ _TFE(a, b, tm_mon ); \ _TFE(a, b, tm_mday); \ _TFE(a, b, tm_hour); \ _TFE(a, b, tm_min ); \ _TFE(a, b, tm_sec ); \ TT_STMT_END static void test_util_time(void *arg) { struct timeval start, end; struct tm a_time, b_time; char timestr[128]; time_t t_res; int i; struct timeval tv; /* Test tv_udiff and tv_mdiff */ (void)arg; start.tv_sec = 5; start.tv_usec = 5000; end.tv_sec = 5; end.tv_usec = 5000; tt_int_op(0L,OP_EQ, tv_udiff(&start, &end)); tt_int_op(0L,OP_EQ, tv_mdiff(&start, &end)); tt_int_op(0L,OP_EQ, tv_udiff(&end, &start)); tt_int_op(0L,OP_EQ, tv_mdiff(&end, &start)); end.tv_usec = 7000; tt_int_op(2000L,OP_EQ, tv_udiff(&start, &end)); tt_int_op(2L,OP_EQ, tv_mdiff(&start, &end)); tt_int_op(-2000L,OP_EQ, tv_udiff(&end, &start)); tt_int_op(-2L,OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = 6; tt_int_op(1002000L,OP_EQ, tv_udiff(&start, &end)); tt_int_op(1002L,OP_EQ, tv_mdiff(&start, &end)); tt_int_op(-1002000L,OP_EQ, tv_udiff(&end, &start)); tt_int_op(-1002L,OP_EQ, tv_mdiff(&end, &start)); end.tv_usec = 0; tt_int_op(995000L,OP_EQ, tv_udiff(&start, &end)); tt_int_op(995L,OP_EQ, tv_mdiff(&start, &end)); tt_int_op(-995000L,OP_EQ, tv_udiff(&end, &start)); tt_int_op(-995L,OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = 4; tt_int_op(-1005000L,OP_EQ, tv_udiff(&start, &end)); tt_int_op(-1005L,OP_EQ, tv_mdiff(&start, &end)); tt_int_op(1005000L,OP_EQ, tv_udiff(&end, &start)); tt_int_op(1005L,OP_EQ, tv_mdiff(&end, &start)); /* Negative tv_sec values, these will break on platforms where tv_sec is * unsigned */ end.tv_sec = -10; tt_int_op(-15005000L,OP_EQ, tv_udiff(&start, &end)); tt_int_op(-15005L,OP_EQ, tv_mdiff(&start, &end)); tt_int_op(15005000L,OP_EQ, tv_udiff(&end, &start)); tt_int_op(15005L,OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = -100; tt_int_op(89995000L,OP_EQ, tv_udiff(&start, &end)); tt_int_op(89995L,OP_EQ, tv_mdiff(&start, &end)); tt_int_op(-89995000L,OP_EQ, tv_udiff(&end, &start)); tt_int_op(-89995L,OP_EQ, tv_mdiff(&end, &start)); /* Test that tv_usec values round away from zero when converted to msec */ start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = 10; end.tv_usec = 499; tt_int_op(10000499L, OP_EQ, tv_udiff(&start, &end)); tt_int_op(10000L, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(-10000499L, OP_EQ, tv_udiff(&end, &start)); tt_int_op(-10000L, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = 10; end.tv_usec = 500; tt_int_op(10000500L, OP_EQ, tv_udiff(&start, &end)); tt_int_op(10001L, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(-10000500L, OP_EQ, tv_udiff(&end, &start)); tt_int_op(-10000L, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = 10; end.tv_usec = 501; tt_int_op(10000501L, OP_EQ, tv_udiff(&start, &end)); tt_int_op(10001L, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(-10000501L, OP_EQ, tv_udiff(&end, &start)); tt_int_op(-10001L, OP_EQ, tv_mdiff(&end, &start)); /* Overflow conditions */ #ifdef _WIN32 /* Would you believe that tv_sec is a long on windows? Of course you would.*/ #define TV_SEC_MAX LONG_MAX #define TV_SEC_MIN LONG_MIN #else /* Some BSDs have struct timeval.tv_sec 64-bit, but time_t (and long) 32-bit * Which means TIME_MAX is not actually the maximum value of tv_sec. * But that's ok for the moment, because the code correctly performs 64-bit * calculations internally, then catches the overflow. */ #define TV_SEC_MAX TIME_MAX #define TV_SEC_MIN TIME_MIN #endif /* defined(_WIN32) */ /* Assume tv_usec is an unsigned integer until proven otherwise */ #define TV_USEC_MAX UINT_MAX #define TOR_USEC_PER_SEC 1000000 /* Overflows in the result type */ /* All comparisons work */ start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = LONG_MAX/1000 - 2; end.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(end.tv_sec*1000L, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(-end.tv_sec*1000L, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = LONG_MAX/1000000 - 1; end.tv_usec = 0; tt_int_op(end.tv_sec*1000000L, OP_EQ, tv_udiff(&start, &end)); tt_int_op(end.tv_sec*1000L, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(-end.tv_sec*1000000L, OP_EQ, tv_udiff(&end, &start)); tt_int_op(-end.tv_sec*1000L, OP_EQ, tv_mdiff(&end, &start)); /* No comparisons work */ start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = LONG_MAX/1000 + 1; end.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = LONG_MAX/1000000 + 1; end.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(end.tv_sec*1000L, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(-end.tv_sec*1000L, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = LONG_MAX/1000; end.tv_usec = TOR_USEC_PER_SEC; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = LONG_MAX/1000000; end.tv_usec = TOR_USEC_PER_SEC; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op((end.tv_sec + 1)*1000L, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(-(end.tv_sec + 1)*1000L, OP_EQ, tv_mdiff(&end, &start)); /* Overflows on comparison to zero */ start.tv_sec = 0; start.tv_usec = 0; end.tv_sec = TV_SEC_MAX; end.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = TV_SEC_MAX; end.tv_usec = TOR_USEC_PER_SEC; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = 0; end.tv_usec = TV_USEC_MAX; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = TV_SEC_MAX; end.tv_usec = TV_USEC_MAX; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = 0; end.tv_usec = 0; start.tv_sec = TV_SEC_MIN; start.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = TV_SEC_MIN; start.tv_usec = TOR_USEC_PER_SEC; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = TV_SEC_MIN; start.tv_usec = TV_USEC_MAX; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); /* overflows on comparison to maxima / minima */ start.tv_sec = TV_SEC_MIN; start.tv_usec = 0; end.tv_sec = TV_SEC_MAX; end.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = TV_SEC_MAX; end.tv_usec = TOR_USEC_PER_SEC; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = TV_SEC_MAX; end.tv_usec = 0; start.tv_sec = TV_SEC_MIN; start.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = TV_SEC_MIN; start.tv_usec = TOR_USEC_PER_SEC; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); /* overflows on comparison to maxima / minima with extra usec */ start.tv_sec = TV_SEC_MIN; start.tv_usec = TOR_USEC_PER_SEC; end.tv_sec = TV_SEC_MAX; end.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = TV_SEC_MAX; end.tv_usec = TOR_USEC_PER_SEC; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); end.tv_sec = TV_SEC_MAX; end.tv_usec = TOR_USEC_PER_SEC; start.tv_sec = TV_SEC_MIN; start.tv_usec = 0; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); start.tv_sec = TV_SEC_MIN; start.tv_usec = TOR_USEC_PER_SEC; tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&start, &end)); tt_int_op(LONG_MAX, OP_EQ, tv_udiff(&end, &start)); tt_int_op(LONG_MAX, OP_EQ, tv_mdiff(&end, &start)); /* Test tor_timegm & tor_gmtime_r */ /* The test values here are confirmed to be correct on a platform * with a working timegm & gmtime_r. */ /* Start with known-zero a_time and b_time. * This avoids passing uninitialised values to TM_EQUAL in a_time. * Zeroing may not be needed for b_time, as long as tor_gmtime_r * never reads the existing values in the structure. * But we really don't want intermittently failing tests. */ memset(&a_time, 0, sizeof(struct tm)); memset(&b_time, 0, sizeof(struct tm)); 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; t_res = 1062224095UL; tt_int_op(t_res, OP_EQ, tor_timegm(&a_time)); tor_gmtime_r(&t_res, &b_time); TM_EQUAL(a_time, b_time); a_time.tm_year = 2004-1900; /* Try a leap year, after feb. */ t_res = 1093846495UL; tt_int_op(t_res, OP_EQ, tor_timegm(&a_time)); tor_gmtime_r(&t_res, &b_time); TM_EQUAL(a_time, b_time); a_time.tm_mon = 1; /* Try a leap year, in feb. */ a_time.tm_mday = 10; t_res = 1076393695UL; tt_int_op(t_res, OP_EQ, tor_timegm(&a_time)); tor_gmtime_r(&t_res, &b_time); TM_EQUAL(a_time, b_time); a_time.tm_mon = 0; t_res = 1073715295UL; tt_int_op(t_res, OP_EQ, tor_timegm(&a_time)); tor_gmtime_r(&t_res, &b_time); TM_EQUAL(a_time, b_time); /* This value is in range with 32 bit and 64 bit time_t */ a_time.tm_year = 2037-1900; t_res = 2115180895UL; tt_int_op(t_res, OP_EQ, tor_timegm(&a_time)); tor_gmtime_r(&t_res, &b_time); TM_EQUAL(a_time, b_time); /* This value is out of range with 32 bit time_t, but in range for 64 bit * time_t */ a_time.tm_year = 2039-1900; #if SIZEOF_TIME_T == 4 setup_full_capture_of_logs(LOG_WARN); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); expect_single_log_msg_containing("Result does not fit in tor_timegm"); teardown_capture_of_logs(); #elif SIZEOF_TIME_T == 8 t_res = 2178252895UL; tt_int_op(t_res, OP_EQ, tor_timegm(&a_time)); tor_gmtime_r(&t_res, &b_time); TM_EQUAL(a_time, b_time); #endif /* SIZEOF_TIME_T == 4 || ... */ /* Test tor_timegm out of range */ /* The below tests will all cause a BUG message, so we capture, suppress, * and detect. */ #define CAPTURE() do { \ setup_full_capture_of_logs(LOG_WARN); \ } while (0) #define CHECK_TIMEGM_WARNING(msg) do { \ expect_single_log_msg_containing(msg); \ teardown_capture_of_logs(); \ } while (0) #define CHECK_POSSIBLE_EINVAL() do { \ if (mock_saved_log_n_entries()) { \ expect_single_log_msg_containing("Invalid argument"); \ } \ teardown_capture_of_logs(); \ } while (0) #define CHECK_TIMEGM_ARG_OUT_OF_RANGE(msg) \ CHECK_TIMEGM_WARNING("Out-of-range argument to tor_timegm") /* year */ /* Wrong year < 1970 */ a_time.tm_year = 1969-1900; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_year = -1-1900; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); #if SIZEOF_INT == 4 || SIZEOF_INT == 8 a_time.tm_year = -1*(1 << 16); CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); /* one of the smallest tm_year values my 64 bit system supports: * t_res = -9223372036854775LL without clamping */ a_time.tm_year = -292275055-1900; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_year = INT32_MIN; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); #endif /* SIZEOF_INT == 4 || SIZEOF_INT == 8 */ #if SIZEOF_INT == 8 a_time.tm_year = -1*(1 << 48); CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); /* while unlikely, the system's gmtime(_r) could return * a "correct" retrospective gregorian negative year value, * which I'm pretty sure is: * -1*(2^63)/60/60/24*2000/730485 + 1970 = -292277022657 * 730485 is the number of days in two millennia, including leap days */ a_time.tm_year = -292277022657-1900; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_year = INT64_MIN; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); #endif /* SIZEOF_INT == 8 */ /* Wrong year >= INT32_MAX - 1900 */ #if SIZEOF_INT == 4 || SIZEOF_INT == 8 a_time.tm_year = INT32_MAX-1900; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_year = INT32_MAX; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); #endif /* SIZEOF_INT == 4 || SIZEOF_INT == 8 */ #if SIZEOF_INT == 8 /* one of the largest tm_year values my 64 bit system supports */ a_time.tm_year = 292278994-1900; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); /* while unlikely, the system's gmtime(_r) could return * a "correct" proleptic gregorian year value, * which I'm pretty sure is: * (2^63-1)/60/60/24*2000/730485 + 1970 = 292277026596 * 730485 is the number of days in two millennia, including leap days */ a_time.tm_year = 292277026596-1900; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_year = INT64_MAX-1900; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_year = INT64_MAX; CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); #endif /* SIZEOF_INT == 8 */ /* month */ a_time.tm_year = 2007-1900; /* restore valid year */ a_time.tm_mon = 12; /* Wrong month, it's 0-based */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_mon = -1; /* Wrong month */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); /* day */ a_time.tm_mon = 6; /* Try July */ a_time.tm_mday = 32; /* Wrong day */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_mon = 5; /* Try June */ a_time.tm_mday = 31; /* Wrong day */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_year = 2008-1900; /* Try a leap year */ a_time.tm_mon = 1; /* in feb. */ a_time.tm_mday = 30; /* Wrong day */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_year = 2011-1900; /* Try a non-leap year */ a_time.tm_mon = 1; /* in feb. */ a_time.tm_mday = 29; /* Wrong day */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_mday = 0; /* Wrong day, it's 1-based (to be different) */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); /* hour */ a_time.tm_mday = 3; /* restore valid month day */ a_time.tm_hour = 24; /* Wrong hour, it's 0-based */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_hour = -1; /* Wrong hour */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); /* minute */ a_time.tm_hour = 22; /* restore valid hour */ a_time.tm_min = 60; /* Wrong minute, it's 0-based */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_min = -1; /* Wrong minute */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); /* second */ a_time.tm_min = 37; /* restore valid minute */ a_time.tm_sec = 61; /* Wrong second: 0-based with leap seconds */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); a_time.tm_sec = -1; /* Wrong second */ CAPTURE(); tt_int_op((time_t) -1,OP_EQ, tor_timegm(&a_time)); CHECK_TIMEGM_ARG_OUT_OF_RANGE(); /* Test tor_gmtime_r out of range */ /* time_t < 0 yields a year clamped to 1 or 1970, * depending on whether the implementation of the system gmtime(_r) * sets struct tm (1) or not (1970) */ t_res = -1; tor_gmtime_r(&t_res, &b_time); tt_assert(b_time.tm_year == (1970-1900) || b_time.tm_year == (1969-1900)); if (sizeof(time_t) == 4 || sizeof(time_t) == 8) { t_res = -1*(1 << 30); CAPTURE(); tor_gmtime_r(&t_res, &b_time); CHECK_POSSIBLE_EINVAL(); tt_assert(b_time.tm_year == (1970-1900) || b_time.tm_year == (1935-1900)); t_res = INT32_MIN; CAPTURE(); tor_gmtime_r(&t_res, &b_time); CHECK_POSSIBLE_EINVAL(); tt_assert(b_time.tm_year == (1970-1900) || b_time.tm_year == (1901-1900)); } #if SIZEOF_TIME_T == 8 { /* one of the smallest tm_year values my 64 bit system supports: * b_time.tm_year == (-292275055LL-1900LL) without clamping */ t_res = -9223372036854775LL; CAPTURE(); tor_gmtime_r(&t_res, &b_time); CHECK_POSSIBLE_EINVAL(); tt_assert(b_time.tm_year == (1970-1900) || b_time.tm_year == (1-1900)); /* while unlikely, the system's gmtime(_r) could return * a "correct" retrospective gregorian negative year value, * which I'm pretty sure is: * -1*(2^63)/60/60/24*2000/730485 + 1970 = -292277022657 * 730485 is the number of days in two millennia, including leap days * (int64_t)b_time.tm_year == (-292277022657LL-1900LL) without clamping */ t_res = INT64_MIN; CAPTURE(); tor_gmtime_r(&t_res, &b_time); if (! (b_time.tm_year == (1970-1900) || b_time.tm_year == (1-1900))) { tt_int_op(b_time.tm_year, OP_EQ, 1970-1900); } if (b_time.tm_year != 1970-1900) { CHECK_TIMEGM_WARNING("Rounding up to "); } else { teardown_capture_of_logs(); } } { /* As above, but with localtime. */ t_res = -9223372036854775LL; CAPTURE(); tor_localtime_r(&t_res, &b_time); CHECK_POSSIBLE_EINVAL(); tt_assert(b_time.tm_year == (1970-1900) || b_time.tm_year == (1-1900)); /* while unlikely, the system's gmtime(_r) could return * a "correct" retrospective gregorian negative year value, * which I'm pretty sure is: * -1*(2^63)/60/60/24*2000/730485 + 1970 = -292277022657 * 730485 is the number of days in two millennia, including leap days * (int64_t)b_time.tm_year == (-292277022657LL-1900LL) without clamping */ t_res = INT64_MIN; CAPTURE(); tor_localtime_r(&t_res, &b_time); if (! (b_time.tm_year == (1970-1900) || b_time.tm_year == (1-1900))) { tt_int_op(b_time.tm_year, OP_EQ, 1970-1900); } if (b_time.tm_year != 1970-1900) { CHECK_TIMEGM_WARNING("Rounding up to "); } else { teardown_capture_of_logs(); } } #endif /* SIZEOF_TIME_T == 8 */ /* time_t >= INT_MAX yields a year clamped to 2037 or 9999, * depending on whether the implementation of the system gmtime(_r) * sets struct tm (9999) or not (2037) */ #if SIZEOF_TIME_T == 4 || SIZEOF_TIME_T == 8 { t_res = 3*(1 << 29); tor_gmtime_r(&t_res, &b_time); tt_assert(b_time.tm_year == (2021-1900)); t_res = INT32_MAX; tor_gmtime_r(&t_res, &b_time); tt_assert(b_time.tm_year == (2037-1900) || b_time.tm_year == (2038-1900)); } { /* as above but with localtime. */ t_res = 3*(1 << 29); tor_localtime_r(&t_res, &b_time); tt_assert(b_time.tm_year == (2021-1900)); t_res = INT32_MAX; tor_localtime_r(&t_res, &b_time); tt_assert(b_time.tm_year == (2037-1900) || b_time.tm_year == (2038-1900)); } #endif /* SIZEOF_TIME_T == 4 || SIZEOF_TIME_T == 8 */ #if SIZEOF_TIME_T == 8 { /* one of the largest tm_year values my 64 bit system supports: * b_time.tm_year == (292278994L-1900L) without clamping */ t_res = 9223372036854775LL; CAPTURE(); tor_gmtime_r(&t_res, &b_time); CHECK_POSSIBLE_EINVAL(); tt_assert(b_time.tm_year == (2037-1900) || b_time.tm_year == (9999-1900)); /* while unlikely, the system's gmtime(_r) could return * a "correct" proleptic gregorian year value, * which I'm pretty sure is: * (2^63-1)/60/60/24*2000/730485 + 1970 = 292277026596 * 730485 is the number of days in two millennia, including leap days * (int64_t)b_time.tm_year == (292277026596L-1900L) without clamping */ t_res = INT64_MAX; CAPTURE(); tor_gmtime_r(&t_res, &b_time); CHECK_TIMEGM_WARNING("Rounding down to "); tt_assert(b_time.tm_year == (2037-1900) || b_time.tm_year == (9999-1900)); } { /* As above but with localtime. */ t_res = 9223372036854775LL; CAPTURE(); tor_localtime_r(&t_res, &b_time); CHECK_POSSIBLE_EINVAL(); tt_assert(b_time.tm_year == (2037-1900) || b_time.tm_year == (9999-1900)); /* while unlikely, the system's gmtime(_r) could return * a "correct" proleptic gregorian year value, * which I'm pretty sure is: * (2^63-1)/60/60/24*2000/730485 + 1970 = 292277026596 * 730485 is the number of days in two millennia, including leap days * (int64_t)b_time.tm_year == (292277026596L-1900L) without clamping */ t_res = INT64_MAX; CAPTURE(); tor_localtime_r(&t_res, &b_time); CHECK_TIMEGM_WARNING("Rounding down to "); tt_assert(b_time.tm_year == (2037-1900) || b_time.tm_year == (9999-1900)); } #endif /* SIZEOF_TIME_T == 8 */ /* Test {format,parse}_rfc1123_time */ format_rfc1123_time(timestr, 0); tt_str_op("Thu, 01 Jan 1970 00:00:00 GMT",OP_EQ, timestr); format_rfc1123_time(timestr, (time_t)1091580502UL); tt_str_op("Wed, 04 Aug 2004 00:48:22 GMT",OP_EQ, timestr); t_res = 0; i = parse_rfc1123_time(timestr, &t_res); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)1091580502UL); /* This value is in range with 32 bit and 64 bit time_t */ format_rfc1123_time(timestr, (time_t)2080000000UL); tt_str_op("Fri, 30 Nov 2035 01:46:40 GMT",OP_EQ, timestr); t_res = 0; i = parse_rfc1123_time(timestr, &t_res); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)2080000000UL); /* This value is out of range with 32 bit time_t, but in range for 64 bit * time_t */ CAPTURE(); format_rfc1123_time(timestr, (time_t)2150000000UL); CHECK_POSSIBLE_EINVAL(); #if SIZEOF_TIME_T == 4 #if 0 /* Wrapping around will have made it this. */ /* On windows, at least, this is clipped to 1 Jan 1970. ??? */ tt_str_op("Sat, 11 Jan 1902 23:45:04 GMT",OP_EQ, timestr); #endif /* Make sure that the right date doesn't parse. */ strlcpy(timestr, "Wed, 17 Feb 2038 06:13:20 GMT", sizeof(timestr)); t_res = 0; CAPTURE(); i = parse_rfc1123_time(timestr, &t_res); CHECK_TIMEGM_WARNING("does not fit in tor_timegm"); tt_int_op(-1,OP_EQ, i); #elif SIZEOF_TIME_T == 8 tt_str_op("Wed, 17 Feb 2038 06:13:20 GMT",OP_EQ, timestr); t_res = 0; i = parse_rfc1123_time(timestr, &t_res); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)2150000000UL); #endif /* SIZEOF_TIME_T == 4 || ... */ /* The timezone doesn't matter */ t_res = 0; tt_int_op(0,OP_EQ, parse_rfc1123_time("Wed, 04 Aug 2004 00:48:22 ZUL", &t_res)); tt_int_op(t_res,OP_EQ, (time_t)1091580502UL); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, zz Aug 2004 99-99x99 GMT", &t_res)); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 32 Mar 2011 00:00:00 GMT", &t_res)); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 30 Mar 2011 24:00:00 GMT", &t_res)); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 30 Mar 2011 23:60:00 GMT", &t_res)); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 30 Mar 2011 23:59:62 GMT", &t_res)); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 30 Mar 1969 23:59:59 GMT", &t_res)); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 30 Ene 2011 23:59:59 GMT", &t_res)); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 30 Mar 2011 23:59:59 GM", &t_res)); tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 30 Mar 1900 23:59:59 GMT", &t_res)); /* Leap year. */ tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 29 Feb 2011 16:00:00 GMT", &t_res)); tt_int_op(0,OP_EQ, parse_rfc1123_time("Wed, 29 Feb 2012 16:00:00 GMT", &t_res)); /* Leap second plus one */ tt_int_op(-1,OP_EQ, parse_rfc1123_time("Wed, 30 Mar 2011 23:59:61 GMT", &t_res)); /* Test parse_iso_time */ t_res = 0; i = parse_iso_time("", &t_res); tt_int_op(-1,OP_EQ, i); t_res = 0; i = parse_iso_time("2004-08-32 00:48:22", &t_res); tt_int_op(-1,OP_EQ, i); t_res = 0; i = parse_iso_time("1969-08-03 00:48:22", &t_res); tt_int_op(-1,OP_EQ, i); t_res = 0; i = parse_iso_time("2004-08-04 00:48:22", &t_res); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)1091580502UL); t_res = 0; i = parse_iso_time("2004-8-4 0:48:22", &t_res); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)1091580502UL); /* This value is in range with 32 bit and 64 bit time_t */ t_res = 0; i = parse_iso_time("2035-11-30 01:46:40", &t_res); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)2080000000UL); /* This value is out of range with 32 bit time_t, but in range for 64 bit * time_t */ t_res = 0; #if SIZEOF_TIME_T == 4 CAPTURE(); i = parse_iso_time("2038-02-17 06:13:20", &t_res); tt_int_op(-1,OP_EQ, i); CHECK_TIMEGM_WARNING("does not fit in tor_timegm"); #elif SIZEOF_TIME_T == 8 i = parse_iso_time("2038-02-17 06:13:20", &t_res); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)2150000000UL); #endif /* SIZEOF_TIME_T == 4 || ... */ tt_int_op(-1,OP_EQ, parse_iso_time("2004-08-zz 99-99x99", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2011-03-32 00:00:00", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2011-03-30 24:00:00", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2011-03-30 23:60:00", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2011-03-30 23:59:62", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("1969-03-30 23:59:59", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2011-00-30 23:59:59", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2147483647-08-29 14:00:00", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2011-03-30 23:59", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2004-08-04 00:48:22.100", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2004-08-04 00:48:22XYZ", &t_res)); /* but... that _is_ acceptable if we aren't being strict. */ t_res = 0; i = parse_iso_time_("2004-08-04 00:48:22XYZ", &t_res, 0, 0); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)1091580502UL); /* try nospace variant. */ t_res = 0; i = parse_iso_time_nospace("2004-08-04T00:48:22", &t_res); tt_int_op(0,OP_EQ, i); tt_int_op(t_res,OP_EQ, (time_t)1091580502UL); tt_int_op(-1,OP_EQ, parse_iso_time("2004-08-04T00:48:22", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time_nospace("2004-08-04 00:48:22", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time("2004-08-04x00:48:22", &t_res)); tt_int_op(-1,OP_EQ, parse_iso_time_nospace("2004-08-04x00:48:22", &t_res)); /* Test tor_gettimeofday */ end.tv_sec = 4; end.tv_usec = 999990; start.tv_sec = 1; start.tv_usec = 500; tor_gettimeofday(&start); /* now make sure time works. */ tor_gettimeofday(&end); /* We might've timewarped a little. */ tt_int_op(tv_udiff(&start, &end), OP_GE, -5000); /* Test format_iso_time */ tv.tv_sec = (time_t)1326296338UL; tv.tv_usec = 3060; format_iso_time(timestr, (time_t)tv.tv_sec); tt_str_op("2012-01-11 15:38:58",OP_EQ, timestr); /* The output of format_local_iso_time will vary by timezone, and setting our timezone for testing purposes would be a nontrivial flaky pain. Skip this test for now. format_local_iso_time(timestr, tv.tv_sec); test_streq("2012-01-11 10:38:58", timestr); */ format_iso_time_nospace(timestr, (time_t)tv.tv_sec); tt_str_op("2012-01-11T15:38:58",OP_EQ, timestr); tt_int_op(strlen(timestr),OP_EQ, ISO_TIME_LEN); format_iso_time_nospace_usec(timestr, &tv); tt_str_op("2012-01-11T15:38:58.003060",OP_EQ, timestr); tt_int_op(strlen(timestr),OP_EQ, ISO_TIME_USEC_LEN); tv.tv_usec = 0; /* This value is in range with 32 bit and 64 bit time_t */ tv.tv_sec = (time_t)2080000000UL; format_iso_time(timestr, (time_t)tv.tv_sec); tt_str_op("2035-11-30 01:46:40",OP_EQ, timestr); /* This value is out of range with 32 bit time_t, but in range for 64 bit * time_t */ tv.tv_sec = (time_t)2150000000UL; CAPTURE(); format_iso_time(timestr, (time_t)tv.tv_sec); CHECK_POSSIBLE_EINVAL(); #if SIZEOF_TIME_T == 4 /* format_iso_time should indicate failure on overflow, but it doesn't yet. * Hopefully #18480 will improve the failure semantics in this case. tt_str_op("2038-02-17 06:13:20",OP_EQ, timestr); */ #elif SIZEOF_TIME_T == 8 #ifndef _WIN32 /* This SHOULD work on windows too; see bug #18665 */ tt_str_op("2038-02-17 06:13:20",OP_EQ, timestr); #endif #endif /* SIZEOF_TIME_T == 4 || ... */ #undef CAPTURE #undef CHECK_TIMEGM_ARG_OUT_OF_RANGE #undef CHECK_POSSIBLE_EINVAL done: teardown_capture_of_logs(); } static void test_util_parse_http_time(void *arg) { struct tm a_time; char b[ISO_TIME_LEN+1]; (void)arg; #define T(s) do { \ format_iso_time(b, tor_timegm(&a_time)); \ tt_str_op(b, OP_EQ, (s)); \ b[0]='\0'; \ } while (0) /* Test parse_http_time */ tt_int_op(-1,OP_EQ, parse_http_time("", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("Sunday, 32 Aug 2004 00:48:22 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("Sunday, 3 Aug 1869 00:48:22 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("Sunday, 32-Aug-94 00:48:22 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("Sunday, 3-Ago-04 00:48:22", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("Sunday, August the third", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("Wednesday,,04 Aug 1994 00:48:22 GMT", &a_time)); tt_int_op(0,OP_EQ, parse_http_time("Wednesday, 04 Aug 1994 00:48:22 GMT", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ, parse_http_time("Wednesday, 4 Aug 1994 0:48:22 GMT", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ, parse_http_time("Miercoles, 4 Aug 1994 0:48:22 GMT", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ, parse_http_time("Wednesday, 04-Aug-94 00:48:22 GMT", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ, parse_http_time("Wednesday, 4-Aug-94 0:48:22 GMT", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ, parse_http_time("Miercoles, 4-Aug-94 0:48:22 GMT", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ, parse_http_time("Wed Aug 04 00:48:22 1994", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ, parse_http_time("Wed Aug 4 0:48:22 1994", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ, parse_http_time("Mie Aug 4 0:48:22 1994", &a_time)); tt_int_op((time_t)775961302UL,OP_EQ, tor_timegm(&a_time)); T("1994-08-04 00:48:22"); tt_int_op(0,OP_EQ,parse_http_time("Sun, 1 Jan 2012 00:00:00 GMT", &a_time)); tt_int_op((time_t)1325376000UL,OP_EQ, tor_timegm(&a_time)); T("2012-01-01 00:00:00"); tt_int_op(0,OP_EQ,parse_http_time("Mon, 31 Dec 2012 00:00:00 GMT", &a_time)); tt_int_op((time_t)1356912000UL,OP_EQ, tor_timegm(&a_time)); T("2012-12-31 00:00:00"); /* This value is in range with 32 bit and 64 bit time_t */ tt_int_op(0,OP_EQ,parse_http_time("Fri, 30 Nov 2035 01:46:40 GMT", &a_time)); tt_int_op((time_t)2080000000UL,OP_EQ, tor_timegm(&a_time)); T("2035-11-30 01:46:40"); /* This value is out of range with 32 bit time_t, but in range for 64 bit * time_t */ #if SIZEOF_TIME_T == 4 /* parse_http_time should indicate failure on overflow, but it doesn't yet. * Hopefully #18480 will improve the failure semantics in this case. */ setup_full_capture_of_logs(LOG_WARN); tt_int_op(0,OP_EQ,parse_http_time("Wed, 17 Feb 2038 06:13:20 GMT", &a_time)); tt_int_op((time_t)-1,OP_EQ, tor_timegm(&a_time)); expect_single_log_msg_containing("does not fit in tor_timegm"); teardown_capture_of_logs(); #elif SIZEOF_TIME_T == 8 tt_int_op(0,OP_EQ,parse_http_time("Wed, 17 Feb 2038 06:13:20 GMT", &a_time)); tt_int_op((time_t)2150000000UL,OP_EQ, tor_timegm(&a_time)); T("2038-02-17 06:13:20"); #endif /* SIZEOF_TIME_T == 4 || ... */ tt_int_op(-1,OP_EQ, parse_http_time("2004-08-zz 99-99x99 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("2011-03-32 00:00:00 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("2011-03-30 24:00:00 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("2011-03-30 23:60:00 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("2011-03-30 23:59:62 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("1969-03-30 23:59:59 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("2011-00-30 23:59:59 GMT", &a_time)); tt_int_op(-1,OP_EQ, parse_http_time("2011-03-30 23:59", &a_time)); #undef T done: teardown_capture_of_logs(); } static void test_util_config_line(void *arg) { char buf[1024]; char *k=NULL, *v=NULL; const char *str; /* Test parse_config_line_from_str */ (void)arg; 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" "k9 a line that\\\n spans two lines.\n\n" "k10 more than\\\n one contin\\\nuation\n" "k11 \\\ncontinuation at the start\n" "k12 line with a\\\n#comment\n embedded\n" "k13\\\ncontinuation at the very start\n" "k14 a line that has a comment and # ends with a slash \\\n" "k15 this should be the next new line\n" "k16 a line that has a comment and # ends without a slash \n" "k17 this should be the next new line\n" , sizeof(buf)); str = buf; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k"); tt_str_op(v,OP_EQ, "v"); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "key value with")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "key"); tt_str_op(v,OP_EQ, "value with spaces"); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "keykey")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "keykey"); tt_str_op(v,OP_EQ, "val"); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "k2\n")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k2"); tt_str_op(v,OP_EQ, ""); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "k3 \n")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k3"); tt_str_op(v,OP_EQ, ""); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "#comment")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k4"); tt_str_op(v,OP_EQ, ""); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "k5#abc")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k5"); tt_str_op(v,OP_EQ, ""); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "k6")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k6"); tt_str_op(v,OP_EQ, "val"); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "kseven")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "kseven"); tt_str_op(v,OP_EQ, "a quoted \'string"); tor_free(k); tor_free(v); tt_assert(!strcmpstart(str, "k8 ")); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k8"); tt_str_op(v,OP_EQ, "a quoted\n\"str\\ing\t\x01\x01\x01\""); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k9"); tt_str_op(v,OP_EQ, "a line that spans two lines."); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k10"); tt_str_op(v,OP_EQ, "more than one continuation"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k11"); tt_str_op(v,OP_EQ, "continuation at the start"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k12"); tt_str_op(v,OP_EQ, "line with a embedded"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k13"); tt_str_op(v,OP_EQ, "continuation at the very start"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k14"); tt_str_op(v,OP_EQ, "a line that has a comment and" ); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k15"); tt_str_op(v,OP_EQ, "this should be the next new line"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k16"); tt_str_op(v,OP_EQ, "a line that has a comment and" ); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k17"); tt_str_op(v,OP_EQ, "this should be the next new line"); tor_free(k); tor_free(v); tt_str_op(str,OP_EQ, ""); done: tor_free(k); tor_free(v); } static void test_util_config_line_quotes(void *arg) { char buf1[1024]; char buf2[128]; char buf3[128]; char buf4[128]; char *k=NULL, *v=NULL; const char *str; /* Test parse_config_line_from_str */ (void)arg; strlcpy(buf1, "kTrailingSpace \"quoted value\" \n" "kTrailingGarbage \"quoted value\"trailing garbage\n" , sizeof(buf1)); strlcpy(buf2, "kTrailingSpaceAndGarbage \"quoted value\" trailing space+g\n" , sizeof(buf2)); strlcpy(buf3, "kMultilineTrailingSpace \"mline\\ \nvalue w/ trailing sp\"\n" , sizeof(buf3)); strlcpy(buf4, "kMultilineNoTrailingBackslash \"naked multiline\nvalue\"\n" , sizeof(buf4)); str = buf1; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "kTrailingSpace"); tt_str_op(v,OP_EQ, "quoted value"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str = buf2; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str = buf3; const char *err = NULL; str = parse_config_line_from_str_verbose(str, &k, &v, &err); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); tt_str_op(err, OP_EQ, "Invalid escape sequence in quoted string"); str = buf4; err = NULL; str = parse_config_line_from_str_verbose(str, &k, &v, &err); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); tt_str_op(err, OP_EQ, "Invalid escape sequence in quoted string"); done: tor_free(k); tor_free(v); } static void test_util_config_line_comment_character(void *arg) { char buf[1024]; char *k=NULL, *v=NULL; const char *str; /* Test parse_config_line_from_str */ (void)arg; strlcpy(buf, "k1 \"# in quotes\"\n" "k2 some value # some comment\n" "k3 /home/user/myTorNetwork#2\n" /* Testcase for #1323 */ , sizeof(buf)); str = buf; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k1"); tt_str_op(v,OP_EQ, "# in quotes"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "k2"); tt_str_op(v,OP_EQ, "some value"); tor_free(k); tor_free(v); tt_str_op(str,OP_EQ, "k3 /home/user/myTorNetwork#2\n"); #if 0 str = parse_config_line_from_str_verbose(str, &k, &v, NULL); test_streq(k, "k3"); test_streq(v, "/home/user/myTorNetwork#2"); tor_free(k); tor_free(v); test_streq(str, ""); #endif /* 0 */ done: tor_free(k); tor_free(v); } static void test_util_config_line_escaped_content(void *arg) { char buf1[1024]; char buf2[128]; char buf3[128]; char buf4[128]; char buf5[128]; char buf6[128]; char *k=NULL, *v=NULL; const char *str; /* Test parse_config_line_from_str */ (void)arg; strlcpy(buf1, "HexadecimalLower \"\\x2a\"\n" "HexadecimalUpper \"\\x2A\"\n" "HexadecimalUpperX \"\\X2A\"\n" "Octal \"\\52\"\n" "Newline \"\\n\"\n" "Tab \"\\t\"\n" "CarriageReturn \"\\r\"\n" "DoubleQuote \"\\\"\"\n" "SimpleQuote \"\\'\"\n" "Backslash \"\\\\\"\n" "Mix \"This is a \\\"star\\\":\\t\\'\\x2a\\'\\nAnd second line\"\n" , sizeof(buf1)); strlcpy(buf2, "BrokenEscapedContent \"\\a\"\n" , sizeof(buf2)); strlcpy(buf3, "BrokenEscapedContent \"\\x\"\n" , sizeof(buf3)); strlcpy(buf4, "BrokenOctal \"\\8\"\n" , sizeof(buf4)); strlcpy(buf5, "BrokenHex \"\\xg4\"\n" , sizeof(buf5)); strlcpy(buf6, "BrokenEscape \"\\" , sizeof(buf6)); str = buf1; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "HexadecimalLower"); tt_str_op(v,OP_EQ, "*"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "HexadecimalUpper"); tt_str_op(v,OP_EQ, "*"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "HexadecimalUpperX"); tt_str_op(v,OP_EQ, "*"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "Octal"); tt_str_op(v,OP_EQ, "*"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "Newline"); tt_str_op(v,OP_EQ, "\n"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "Tab"); tt_str_op(v,OP_EQ, "\t"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "CarriageReturn"); tt_str_op(v,OP_EQ, "\r"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "DoubleQuote"); tt_str_op(v,OP_EQ, "\""); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "SimpleQuote"); tt_str_op(v,OP_EQ, "'"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "Backslash"); tt_str_op(v,OP_EQ, "\\"); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_str_op(k,OP_EQ, "Mix"); tt_str_op(v,OP_EQ, "This is a \"star\":\t'*'\nAnd second line"); tor_free(k); tor_free(v); tt_str_op(str,OP_EQ, ""); str = buf2; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str = buf3; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str = buf4; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); #if 0 str = buf5; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str, OP_EQ, NULL); tor_free(k); tor_free(v); #endif /* 0 */ str = buf6; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); /* more things to try. */ /* Bad hex: */ strlcpy(buf1, "Foo \"\\x9g\"\n", sizeof(buf1)); strlcpy(buf2, "Foo \"\\xg0\"\n", sizeof(buf2)); strlcpy(buf3, "Foo \"\\xf\"\n", sizeof(buf3)); /* bad escape */ strlcpy(buf4, "Foo \"\\q\"\n", sizeof(buf4)); /* missing endquote */ strlcpy(buf5, "Foo \"hello\n", sizeof(buf5)); /* extra stuff */ strlcpy(buf6, "Foo \"hello\" world\n", sizeof(buf6)); str=buf1; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str=buf2; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str=buf3; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str=buf4; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str=buf5; str = parse_config_line_from_str_verbose(str, &k, &v, NULL); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); str=buf6; const char *err = NULL; str = parse_config_line_from_str_verbose(str, &k, &v, &err); tt_ptr_op(str,OP_EQ, NULL); tor_free(k); tor_free(v); tt_str_op(err,OP_EQ, "Excess data after quoted string"); done: tor_free(k); tor_free(v); } static void test_util_config_line_crlf(void *arg) { char *k=NULL, *v=NULL; const char *err = NULL; (void)arg; const char *str = "Hello world\r\n" "Hello \"nice big world\"\r\n"; str = parse_config_line_from_str_verbose(str, &k, &v, &err); tt_assert(str); tt_str_op(k,OP_EQ,"Hello"); tt_str_op(v,OP_EQ,"world"); tt_ptr_op(err, OP_EQ, NULL); tor_free(k); tor_free(v); str = parse_config_line_from_str_verbose(str, &k, &v, &err); tt_assert(str); tt_str_op(k,OP_EQ,"Hello"); tt_str_op(v,OP_EQ,"nice big world"); tt_ptr_op(err, OP_EQ, NULL); tor_free(k); tor_free(v); tt_str_op(str,OP_EQ, ""); done: tor_free(k); tor_free(v); } #ifndef _WIN32 static void test_util_expand_filename(void *arg) { char *str; (void)arg; setenv("HOME", "/home/itv", 1); /* For "internal test value" */ str = expand_filename(""); tt_str_op("",OP_EQ, str); tor_free(str); str = expand_filename("/normal/path"); tt_str_op("/normal/path",OP_EQ, str); tor_free(str); str = expand_filename("/normal/trailing/path/"); tt_str_op("/normal/trailing/path/",OP_EQ, str); tor_free(str); str = expand_filename("~"); tt_str_op("/home/itv/",OP_EQ, str); tor_free(str); str = expand_filename("$HOME/nodice"); tt_str_op("$HOME/nodice",OP_EQ, str); tor_free(str); str = expand_filename("~/"); tt_str_op("/home/itv/",OP_EQ, str); tor_free(str); str = expand_filename("~/foobarqux"); tt_str_op("/home/itv/foobarqux",OP_EQ, str); tor_free(str); str = expand_filename("~/../../etc/passwd"); tt_str_op("/home/itv/../../etc/passwd",OP_EQ, str); tor_free(str); str = expand_filename("~/trailing/"); tt_str_op("/home/itv/trailing/",OP_EQ, str); tor_free(str); /* Ideally we'd test ~anotheruser, but that's shady to test (we'd have to somehow inject/fake the get_user_homedir call) */ /* $HOME ending in a trailing slash */ setenv("HOME", "/home/itv/", 1); str = expand_filename("~"); tt_str_op("/home/itv/",OP_EQ, str); tor_free(str); str = expand_filename("~/"); tt_str_op("/home/itv/",OP_EQ, str); tor_free(str); str = expand_filename("~/foo"); tt_str_op("/home/itv/foo",OP_EQ, str); tor_free(str); /* Try with empty $HOME */ setenv("HOME", "", 1); str = expand_filename("~"); tt_str_op("/",OP_EQ, str); tor_free(str); str = expand_filename("~/"); tt_str_op("/",OP_EQ, str); tor_free(str); str = expand_filename("~/foobar"); tt_str_op("/foobar",OP_EQ, str); tor_free(str); /* Try with $HOME unset */ unsetenv("HOME"); str = expand_filename("~"); tt_str_op("/",OP_EQ, str); tor_free(str); str = expand_filename("~/"); tt_str_op("/",OP_EQ, str); tor_free(str); str = expand_filename("~/foobar"); tt_str_op("/foobar",OP_EQ, str); tor_free(str); done: tor_free(str); } #endif /* !defined(_WIN32) */ /** Test tor_escape_str_for_pt_args(). */ static void test_util_escape_string_socks(void *arg) { char *escaped_string = NULL; /** Simple backslash escape. */ (void)arg; escaped_string = tor_escape_str_for_pt_args("This is a backslash: \\",";\\"); tt_assert(escaped_string); tt_str_op(escaped_string,OP_EQ, "This is a backslash: \\\\"); tor_free(escaped_string); /** Simple semicolon escape. */ escaped_string = tor_escape_str_for_pt_args("First rule:Do not use ;",";\\"); tt_assert(escaped_string); tt_str_op(escaped_string,OP_EQ, "First rule:Do not use \\;"); tor_free(escaped_string); /** Empty string. */ escaped_string = tor_escape_str_for_pt_args("", ";\\"); tt_assert(escaped_string); tt_str_op(escaped_string,OP_EQ, ""); tor_free(escaped_string); /** Escape all characters. */ escaped_string = tor_escape_str_for_pt_args(";\\;\\", ";\\"); tt_assert(escaped_string); tt_str_op(escaped_string,OP_EQ, "\\;\\\\\\;\\\\"); tor_free(escaped_string); escaped_string = tor_escape_str_for_pt_args(";", ";\\"); tt_assert(escaped_string); tt_str_op(escaped_string,OP_EQ, "\\;"); tor_free(escaped_string); done: tor_free(escaped_string); } static void test_util_string_is_key_value(void *ptr) { (void)ptr; tt_assert(string_is_key_value(LOG_WARN, "key=value")); tt_assert(string_is_key_value(LOG_WARN, "k=v")); tt_assert(string_is_key_value(LOG_WARN, "key=")); tt_assert(string_is_key_value(LOG_WARN, "x=")); tt_assert(string_is_key_value(LOG_WARN, "xx=")); tt_assert(!string_is_key_value(LOG_WARN, "=value")); tt_assert(!string_is_key_value(LOG_WARN, "=x")); tt_assert(!string_is_key_value(LOG_WARN, "=")); /* ??? */ /* tt_assert(!string_is_key_value(LOG_WARN, "===")); */ done: ; } /** Test basic string functionality. */ static void test_util_strmisc(void *arg) { char buf[1024]; char *cp_tmp = NULL; /* Test strl operations */ (void)arg; tt_int_op(5,OP_EQ, strlcpy(buf, "Hello", 0)); tt_int_op(5,OP_EQ, strlcpy(buf, "Hello", 10)); tt_str_op(buf,OP_EQ, "Hello"); tt_int_op(5,OP_EQ, strlcpy(buf, "Hello", 6)); tt_str_op(buf,OP_EQ, "Hello"); tt_int_op(5,OP_EQ, strlcpy(buf, "Hello", 5)); tt_str_op(buf,OP_EQ, "Hell"); strlcpy(buf, "Hello", sizeof(buf)); tt_int_op(10,OP_EQ, strlcat(buf, "Hello", 5)); /* Test strstrip() */ strlcpy(buf, "Testing 1 2 3", sizeof(buf)); tor_strstrip(buf, ",!"); tt_str_op(buf,OP_EQ, "Testing 1 2 3"); strlcpy(buf, "!Testing 1 2 3?", sizeof(buf)); tor_strstrip(buf, "!? "); tt_str_op(buf,OP_EQ, "Testing123"); strlcpy(buf, "!!!Testing 1 2 3??", sizeof(buf)); tor_strstrip(buf, "!? "); tt_str_op(buf,OP_EQ, "Testing123"); /* Test snprintf */ /* Returning -1 when there's not enough room in the output buffer */ tt_int_op(-1,OP_EQ, tor_snprintf(buf, 0, "Foo")); tt_int_op(-1,OP_EQ, tor_snprintf(buf, 2, "Foo")); tt_int_op(-1,OP_EQ, tor_snprintf(buf, 3, "Foo")); tt_int_op(-1,OP_NE, tor_snprintf(buf, 4, "Foo")); /* Always NUL-terminate the output */ tor_snprintf(buf, 5, "abcdef"); tt_int_op(0,OP_EQ, buf[4]); tor_snprintf(buf, 10, "abcdef"); tt_int_op(0,OP_EQ, buf[6]); /* uint64 */ tor_snprintf(buf, sizeof(buf), "x!%"PRIu64"!x", (UINT64_C(12345678901))); tt_str_op("x!12345678901!x",OP_EQ, buf); /* Test str{,case}cmpstart */ tt_assert(strcmpstart("abcdef", "abcdef")==0); tt_assert(strcmpstart("abcdef", "abc")==0); tt_assert(strcmpstart("abcdef", "abd")<0); tt_assert(strcmpstart("abcdef", "abb")>0); tt_assert(strcmpstart("ab", "abb")<0); tt_assert(strcmpstart("ab", "")==0); tt_assert(strcmpstart("ab", "ab ")<0); tt_assert(strcasecmpstart("abcdef", "abCdEF")==0); tt_assert(strcasecmpstart("abcDeF", "abc")==0); tt_assert(strcasecmpstart("abcdef", "Abd")<0); tt_assert(strcasecmpstart("Abcdef", "abb")>0); tt_assert(strcasecmpstart("ab", "Abb")<0); tt_assert(strcasecmpstart("ab", "")==0); tt_assert(strcasecmpstart("ab", "ab ")<0); /* Test str{,case}cmpend */ tt_assert(strcmpend("abcdef", "abcdef")==0); tt_assert(strcmpend("abcdef", "def")==0); tt_assert(strcmpend("abcdef", "deg")<0); tt_assert(strcmpend("abcdef", "dee")>0); tt_assert(strcmpend("ab", "aab")>0); tt_assert(strcasecmpend("AbcDEF", "abcdef")==0); tt_assert(strcasecmpend("abcdef", "dEF")==0); tt_assert(strcasecmpend("abcdef", "Deg")<0); tt_assert(strcasecmpend("abcDef", "dee")>0); tt_assert(strcasecmpend("AB", "abb")<0); /* Test digest_is_zero */ memset(buf,0,20); buf[20] = 'x'; tt_assert(tor_digest_is_zero(buf)); buf[19] = 'x'; tt_assert(!tor_digest_is_zero(buf)); /* Test mem_is_zero */ memset(buf,0,128); buf[128] = 'x'; tt_assert(tor_mem_is_zero(buf, 10)); tt_assert(tor_mem_is_zero(buf, 20)); tt_assert(tor_mem_is_zero(buf, 128)); tt_assert(!tor_mem_is_zero(buf, 129)); buf[60] = (char)255; tt_assert(!tor_mem_is_zero(buf, 128)); buf[0] = (char)1; tt_assert(!tor_mem_is_zero(buf, 10)); /* Test 'escaped' */ tt_ptr_op(escaped(NULL), OP_EQ, NULL); tt_str_op("\"\"",OP_EQ, escaped("")); tt_str_op("\"abcd\"",OP_EQ, escaped("abcd")); tt_str_op("\"\\\\ \\n\\r\\t\\\"\\'\"",OP_EQ, escaped("\\ \n\r\t\"'")); tt_str_op("\"unnecessary \\'backslashes\\'\"",OP_EQ, escaped("unnecessary \'backslashes\'")); /* Non-printable characters appear as octal */ tt_str_op("\"z\\001abc\\277d\"",OP_EQ, escaped("z\001abc\277d")); tt_str_op("\"z\\336\\255 ;foo\"",OP_EQ, escaped("z\xde\xad\x20;foo")); /* Other cases of esc_for_log{,_len} */ cp_tmp = esc_for_log(NULL); tt_str_op(cp_tmp, OP_EQ, "(null)"); tor_free(cp_tmp); cp_tmp = esc_for_log_len("abcdefg", 3); tt_str_op(cp_tmp, OP_EQ, "\"abc\""); tor_free(cp_tmp); cp_tmp = esc_for_log_len("abcdefg", 100); tt_str_op(cp_tmp, OP_EQ, "\"abcdefg\""); tor_free(cp_tmp); /* Test strndup and memdup */ { const char *s = "abcdefghijklmnopqrstuvwxyz"; cp_tmp = tor_strndup(s, 30); tt_str_op(cp_tmp,OP_EQ, s); /* same string, */ tt_ptr_op(cp_tmp,OP_NE,s); /* but different pointers. */ tor_free(cp_tmp); cp_tmp = tor_strndup(s, 5); tt_str_op(cp_tmp,OP_EQ, "abcde"); tor_free(cp_tmp); s = "a\0b\0c\0d\0e\0"; cp_tmp = tor_memdup(s,10); tt_mem_op(cp_tmp,OP_EQ, s, 10); /* same ram, */ tt_ptr_op(cp_tmp,OP_NE,s); /* but different pointers. */ tor_free(cp_tmp); } /* Test str-foo functions */ cp_tmp = tor_strdup("abcdef"); tt_assert(tor_strisnonupper(cp_tmp)); cp_tmp[3] = 'D'; tt_assert(!tor_strisnonupper(cp_tmp)); tor_strupper(cp_tmp); tt_str_op(cp_tmp,OP_EQ, "ABCDEF"); tor_strlower(cp_tmp); tt_str_op(cp_tmp,OP_EQ, "abcdef"); tt_assert(tor_strisnonupper(cp_tmp)); tt_assert(tor_strisprint(cp_tmp)); cp_tmp[3] = 3; tt_assert(!tor_strisprint(cp_tmp)); tor_free(cp_tmp); /* Test memmem and memstr */ { const char *haystack = "abcde"; tt_ptr_op(tor_memmem(haystack, 5, "ef", 2), OP_EQ, NULL); tt_ptr_op(tor_memmem(haystack, 5, "cd", 2),OP_EQ, haystack + 2); tt_ptr_op(tor_memmem(haystack, 5, "cde", 3),OP_EQ, haystack + 2); tt_ptr_op(tor_memmem(haystack, 4, "cde", 3), OP_EQ, NULL); haystack = "ababcad"; tt_ptr_op(tor_memmem(haystack, 7, "abc", 3),OP_EQ, haystack + 2); tt_ptr_op(tor_memmem(haystack, 7, "ad", 2),OP_EQ, haystack + 5); tt_ptr_op(tor_memmem(haystack, 7, "cad", 3),OP_EQ, haystack + 4); tt_ptr_op(tor_memmem(haystack, 7, "dadad", 5), OP_EQ, NULL); tt_ptr_op(tor_memmem(haystack, 7, "abcdefghij", 10), OP_EQ, NULL); /* memstr */ tt_ptr_op(tor_memstr(haystack, 7, "abc"),OP_EQ, haystack + 2); tt_ptr_op(tor_memstr(haystack, 7, "cad"),OP_EQ, haystack + 4); tt_ptr_op(tor_memstr(haystack, 6, "cad"), OP_EQ, NULL); tt_ptr_op(tor_memstr(haystack, 7, "cadd"), OP_EQ, NULL); tt_ptr_op(tor_memstr(haystack, 7, "fe"), OP_EQ, NULL); tt_ptr_op(tor_memstr(haystack, 7, "ababcade"), OP_EQ, NULL); } /* Test hex_str */ { char binary_data[68]; size_t idx; for (idx = 0; idx < sizeof(binary_data); ++idx) binary_data[idx] = idx; tt_str_op(hex_str(binary_data, 0),OP_EQ, ""); tt_str_op(hex_str(binary_data, 1),OP_EQ, "00"); tt_str_op(hex_str(binary_data, 17),OP_EQ, "000102030405060708090A0B0C0D0E0F10"); tt_str_op(hex_str(binary_data, 32),OP_EQ, "000102030405060708090A0B0C0D0E0F" "101112131415161718191A1B1C1D1E1F"); tt_str_op(hex_str(binary_data, 34),OP_EQ, "000102030405060708090A0B0C0D0E0F" "101112131415161718191A1B1C1D1E1F"); /* Repeat these tests for shorter strings after longer strings have been tried, to make sure we're correctly terminating strings */ tt_str_op(hex_str(binary_data, 1),OP_EQ, "00"); tt_str_op(hex_str(binary_data, 0),OP_EQ, ""); } /* Test strcmp_opt */ tt_int_op(strcmp_opt("", "foo"), OP_LT, 0); tt_int_op(strcmp_opt("", ""), OP_EQ, 0); tt_int_op(strcmp_opt("foo", ""), OP_GT, 0); tt_int_op(strcmp_opt(NULL, ""), OP_LT, 0); tt_int_op(strcmp_opt(NULL, NULL), OP_EQ, 0); tt_int_op(strcmp_opt("", NULL), OP_GT, 0); tt_int_op(strcmp_opt(NULL, "foo"), OP_LT, 0); tt_int_op(strcmp_opt("foo", NULL), OP_GT, 0); /* Test strcmp_len */ tt_int_op(strcmp_len("foo", "bar", 3), OP_GT, 0); tt_int_op(strcmp_len("foo", "bar", 2), OP_LT, 0); tt_int_op(strcmp_len("foo2", "foo1", 4), OP_GT, 0); tt_int_op(strcmp_len("foo2", "foo1", 3), OP_LT, 0); /* Really stop at len */ tt_int_op(strcmp_len("foo2", "foo", 3), OP_EQ, 0); /* Really stop at len */ tt_int_op(strcmp_len("blah", "", 4), OP_GT, 0); tt_int_op(strcmp_len("blah", "", 0), OP_EQ, 0); done: tor_free(cp_tmp); } static void test_util_parse_integer(void *arg) { (void)arg; int i; char *cp; /* Test parse_long */ /* Empty/zero input */ tt_int_op(0L,OP_EQ, tor_parse_long("",10,0,100,&i,NULL)); tt_int_op(0,OP_EQ, i); tt_int_op(0L,OP_EQ, tor_parse_long("0",10,0,100,&i,NULL)); tt_int_op(1,OP_EQ, i); /* Normal cases */ tt_int_op(10L,OP_EQ, tor_parse_long("10",10,0,100,&i,NULL)); tt_int_op(1,OP_EQ, i); tt_int_op(10L,OP_EQ, tor_parse_long("10",10,0,10,&i,NULL)); tt_int_op(1,OP_EQ, i); tt_int_op(10L,OP_EQ, tor_parse_long("10",10,10,100,&i,NULL)); tt_int_op(1,OP_EQ, i); tt_int_op(-50L,OP_EQ, tor_parse_long("-50",10,-100,100,&i,NULL)); tt_int_op(1,OP_EQ, i); tt_int_op(-50L,OP_EQ, tor_parse_long("-50",10,-100,0,&i,NULL)); tt_int_op(1,OP_EQ, i); tt_int_op(-50L,OP_EQ, tor_parse_long("-50",10,-50,0,&i,NULL)); tt_int_op(1,OP_EQ, i); /* Extra garbage */ tt_int_op(0L,OP_EQ, tor_parse_long("10m",10,0,100,&i,NULL)); tt_int_op(0,OP_EQ, i); tt_int_op(0L,OP_EQ, tor_parse_long("-50 plus garbage",10,-100,100,&i,NULL)); tt_int_op(0,OP_EQ, i); tt_int_op(10L,OP_EQ, tor_parse_long("10m",10,0,100,&i,&cp)); tt_int_op(1,OP_EQ, i); tt_str_op(cp,OP_EQ, "m"); tt_int_op(-50L,OP_EQ, tor_parse_long("-50 plus garbage",10,-100,100,&i,&cp)); tt_int_op(1,OP_EQ, i); tt_str_op(cp,OP_EQ, " plus garbage"); /* Illogical min max */ tt_int_op(0L,OP_EQ, tor_parse_long("10",10,50,4,&i,NULL)); tt_int_op(0,OP_EQ, i); tt_int_op(0L,OP_EQ, tor_parse_long("-50",10,100,-100,&i,NULL)); tt_int_op(0,OP_EQ, i); /* Out of bounds */ tt_int_op(0L,OP_EQ, tor_parse_long("10",10,50,100,&i,NULL)); tt_int_op(0,OP_EQ, i); tt_int_op(0L,OP_EQ, tor_parse_long("-50",10,0,100,&i,NULL)); tt_int_op(0,OP_EQ, i); /* Base different than 10 */ tt_int_op(2L,OP_EQ, tor_parse_long("10",2,0,100,NULL,NULL)); tt_int_op(0L,OP_EQ, tor_parse_long("2",2,0,100,NULL,NULL)); tt_int_op(68284L,OP_EQ, tor_parse_long("10abc",16,0,70000,NULL,NULL)); tt_int_op(68284L,OP_EQ, tor_parse_long("10ABC",16,0,70000,NULL,NULL)); tt_int_op(0L,OP_EQ, tor_parse_long("10",-2,0,100,NULL,NULL)); tt_int_op(0,OP_EQ, tor_parse_long("10ABC",-1,0,70000,&i,NULL)); tt_int_op(i,OP_EQ, 0); /* Test parse_ulong */ tt_int_op(0UL,OP_EQ, tor_parse_ulong("",10,0,100,NULL,NULL)); tt_int_op(0UL,OP_EQ, tor_parse_ulong("0",10,0,100,NULL,NULL)); tt_int_op(10UL,OP_EQ, tor_parse_ulong("10",10,0,100,NULL,NULL)); tt_int_op(0UL,OP_EQ, tor_parse_ulong("10",10,50,100,NULL,NULL)); tt_int_op(10UL,OP_EQ, tor_parse_ulong("10",10,0,10,NULL,NULL)); tt_int_op(10UL,OP_EQ, tor_parse_ulong("10",10,10,100,NULL,NULL)); tt_int_op(0UL,OP_EQ, tor_parse_ulong("8",8,0,100,NULL,NULL)); tt_int_op(50UL,OP_EQ, tor_parse_ulong("50",10,50,100,NULL,NULL)); tt_int_op(0UL,OP_EQ, tor_parse_ulong("-50",10,0,100,NULL,NULL)); tt_int_op(0UL,OP_EQ, tor_parse_ulong("50",-1,50,100,&i,NULL)); tt_int_op(0,OP_EQ, i); tt_int_op(0UL,OP_EQ, tor_parse_ulong("-50",10,0,100,&i,NULL)); tt_int_op(0,OP_EQ, i); /* Test parse_uint64 */ tt_assert(UINT64_C(10) == tor_parse_uint64("10 x",10,0,100, &i, &cp)); tt_int_op(1,OP_EQ, i); tt_str_op(cp,OP_EQ, " x"); tt_assert(UINT64_C(12345678901) == tor_parse_uint64("12345678901",10,0,UINT64_MAX, &i, &cp)); tt_int_op(1,OP_EQ, i); tt_str_op(cp,OP_EQ, ""); tt_assert(UINT64_C(0) == tor_parse_uint64("12345678901",10,500,INT32_MAX, &i, &cp)); tt_int_op(0,OP_EQ, i); tt_assert(UINT64_C(0) == tor_parse_uint64("123",-1,0,INT32_MAX, &i, &cp)); tt_int_op(0,OP_EQ, i); { /* Test parse_double */ double d = tor_parse_double("10", 0, (double)UINT64_MAX,&i,NULL); tt_int_op(1,OP_EQ, i); tt_assert(((uint64_t)d) == 10); d = tor_parse_double("0", 0, (double)UINT64_MAX,&i,NULL); tt_int_op(1,OP_EQ, i); tt_assert(((uint64_t)d) == 0); d = tor_parse_double(" ", 0, (double)UINT64_MAX,&i,NULL); tt_double_op(fabs(d), OP_LT, 1e-10); tt_int_op(0,OP_EQ, i); d = tor_parse_double(".0a", 0, (double)UINT64_MAX,&i,NULL); tt_double_op(fabs(d), OP_LT, 1e-10); tt_int_op(0,OP_EQ, i); d = tor_parse_double(".0a", 0, (double)UINT64_MAX,&i,&cp); tt_double_op(fabs(d), OP_LT, 1e-10); tt_int_op(1,OP_EQ, i); d = tor_parse_double("-.0", 0, (double)UINT64_MAX,&i,NULL); tt_int_op(1,OP_EQ, i); tt_assert(((uint64_t)d) == 0); d = tor_parse_double("-10", -100.0, 100.0,&i,NULL); tt_int_op(1,OP_EQ, i); tt_double_op(fabs(d - -10.0),OP_LT, 1E-12); } { /* Test tor_parse_* where we overflow/underflow the underlying type. */ /* This string should overflow 64-bit ints. */ #define TOOBIG "100000000000000000000000000" tt_int_op(0L, OP_EQ, tor_parse_long(TOOBIG, 10, LONG_MIN, LONG_MAX, &i, NULL)); tt_int_op(i,OP_EQ, 0); tt_int_op(0L,OP_EQ, tor_parse_long("-"TOOBIG, 10, LONG_MIN, LONG_MAX, &i, NULL)); tt_int_op(i,OP_EQ, 0); tt_int_op(0UL,OP_EQ, tor_parse_ulong(TOOBIG, 10, 0, ULONG_MAX, &i, NULL)); tt_int_op(i,OP_EQ, 0); tt_u64_op(UINT64_C(0), OP_EQ, tor_parse_uint64(TOOBIG, 10, 0, UINT64_MAX, &i, NULL)); tt_int_op(i,OP_EQ, 0); } done: ; } static void test_util_pow2(void *arg) { /* Test tor_log2(). */ (void)arg; tt_int_op(tor_log2(64),OP_EQ, 6); tt_int_op(tor_log2(65),OP_EQ, 6); tt_int_op(tor_log2(63),OP_EQ, 5); /* incorrect mathematically, but as specified: */ tt_int_op(tor_log2(0),OP_EQ, 0); tt_int_op(tor_log2(1),OP_EQ, 0); tt_int_op(tor_log2(2),OP_EQ, 1); tt_int_op(tor_log2(3),OP_EQ, 1); tt_int_op(tor_log2(4),OP_EQ, 2); tt_int_op(tor_log2(5),OP_EQ, 2); tt_int_op(tor_log2(UINT64_C(40000000000000000)),OP_EQ, 55); tt_int_op(tor_log2(UINT64_MAX),OP_EQ, 63); /* Test round_to_power_of_2 */ tt_u64_op(round_to_power_of_2(120), OP_EQ, 128); tt_u64_op(round_to_power_of_2(128), OP_EQ, 128); tt_u64_op(round_to_power_of_2(130), OP_EQ, 128); tt_u64_op(round_to_power_of_2(UINT64_C(40000000000000000)), OP_EQ, UINT64_C(1)<<55); tt_u64_op(round_to_power_of_2(UINT64_C(0xffffffffffffffff)), OP_EQ, UINT64_C(1)<<63); tt_u64_op(round_to_power_of_2(0), OP_EQ, 1); tt_u64_op(round_to_power_of_2(1), OP_EQ, 1); tt_u64_op(round_to_power_of_2(2), OP_EQ, 2); tt_u64_op(round_to_power_of_2(3), OP_EQ, 2); tt_u64_op(round_to_power_of_2(4), OP_EQ, 4); tt_u64_op(round_to_power_of_2(5), OP_EQ, 4); tt_u64_op(round_to_power_of_2(6), OP_EQ, 4); tt_u64_op(round_to_power_of_2(7), OP_EQ, 8); done: ; } static void test_util_compress_impl(compress_method_t method) { char *buf1=NULL, *buf2=NULL, *buf3=NULL; size_t len1, len2; tt_assert(tor_compress_supports_method(method)); if (method != NO_METHOD) { tt_ptr_op(tor_compress_version_str(method), OP_NE, NULL); tt_ptr_op(tor_compress_header_version_str(method), OP_NE, NULL); } buf1 = tor_strdup("AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAZAAAAAAAAAAAAAAAAAAAZ"); tt_assert(detect_compression_method(buf1, strlen(buf1)) == UNKNOWN_METHOD); tt_assert(!tor_compress(&buf2, &len1, buf1, strlen(buf1)+1, method)); tt_ptr_op(buf2, OP_NE, NULL); if (method == NO_METHOD) { // The identity transform doesn't actually compress, and it isn't // detectable as "the identity transform." tt_int_op(len1, OP_EQ, strlen(buf1)+1); tt_int_op(detect_compression_method(buf2, len1), OP_EQ, UNKNOWN_METHOD); } else { tt_int_op(len1, OP_LT, strlen(buf1)); tt_int_op(detect_compression_method(buf2, len1), OP_EQ, method); } tt_assert(!tor_uncompress(&buf3, &len2, buf2, len1, method, 1, LOG_INFO)); tt_ptr_op(buf3, OP_NE, NULL); tt_int_op(strlen(buf1) + 1, OP_EQ, len2); tt_str_op(buf1, OP_EQ, buf3); tt_int_op(buf3[len2], OP_EQ, 0); /* Check whether we can uncompress concatenated, compressed strings. */ tor_free(buf3); buf2 = tor_reallocarray(buf2, len1, 2); memcpy(buf2+len1, buf2, len1); tt_assert(!tor_uncompress(&buf3, &len2, buf2, len1*2, method, 1, LOG_INFO)); tt_int_op((strlen(buf1)+1)*2, OP_EQ, len2); tt_mem_op(buf3, OP_EQ, "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAZAAAAAAAAAAAAAAAAAAAZ\0" "AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAZAAAAAAAAAAAAAAAAAAAZ\0", (strlen(buf1)+1)*2); tt_int_op(buf3[len2], OP_EQ, 0); /* Check whether we can uncompress partial strings */ tor_free(buf1); tor_free(buf2); tor_free(buf3); size_t b1len = 1<<10; if (method == ZSTD_METHOD) { // zstd needs a big input before it starts generating output that it // can partially decompress. b1len = 1<<18; } buf1 = tor_malloc(b1len); crypto_rand(buf1, b1len); tt_assert(!tor_compress(&buf2, &len1, buf1, b1len, method)); tt_int_op(len1, OP_GT, 16); /* when we allow an incomplete output we should succeed.*/ tt_assert(!tor_uncompress(&buf3, &len2, buf2, len1-16, method, 0, LOG_INFO)); tt_int_op(len2, OP_GT, 5); tt_int_op(len2, OP_LE, len1); tt_assert(fast_memeq(buf1, buf3, len2)); tt_int_op(buf3[len2], OP_EQ, 0); /* when we demand a complete output from a real compression method, this * must fail. */ tor_free(buf3); if (method != NO_METHOD) { tt_assert(tor_uncompress(&buf3, &len2, buf2, len1-16, method, 1, LOG_INFO)); tt_ptr_op(buf3, OP_EQ, NULL); } done: tor_free(buf1); tor_free(buf2); tor_free(buf3); } static void test_util_compress_stream_impl(compress_method_t method, compression_level_t level) { char *buf1=NULL, *buf2=NULL, *buf3=NULL, *cp1, *cp2; const char *ccp2; size_t len1, len2; tor_compress_state_t *state = NULL; state = tor_compress_new(1, method, level); tt_assert(state); cp1 = buf1 = tor_malloc(1024); len1 = 1024; ccp2 = "ABCDEFGHIJABCDEFGHIJ"; len2 = 21; tt_int_op(tor_compress_process(state, &cp1, &len1, &ccp2, &len2, 0), OP_EQ, TOR_COMPRESS_OK); tt_int_op(0, OP_EQ, len2); /* Make sure we compressed it all. */ tt_assert(cp1 > buf1); len2 = 0; cp2 = cp1; tt_int_op(tor_compress_process(state, &cp1, &len1, &ccp2, &len2, 1), OP_EQ, TOR_COMPRESS_DONE); tt_int_op(0, OP_EQ, len2); if (method == NO_METHOD) { tt_ptr_op(cp1, OP_EQ, cp2); } else { tt_assert(cp1 > cp2); /* Make sure we really added something. */ } tt_int_op(tor_compress_state_size(state), OP_GT, 0); tt_assert(!tor_uncompress(&buf3, &len2, buf1, 1024-len1, method, 1, LOG_WARN)); /* Make sure it compressed right. */ tt_str_op(buf3, OP_EQ, "ABCDEFGHIJABCDEFGHIJ"); tt_int_op(21, OP_EQ, len2); done: if (state) tor_compress_free(state); tor_free(buf1); tor_free(buf2); tor_free(buf3); } /** Setup function for compression tests: handles x-zstd:nostatic */ static void * compression_test_setup(const struct testcase_t *testcase) { tor_assert(testcase->setup_data); tor_assert(testcase->setup_data != (void*)TT_SKIP); const char *methodname = testcase->setup_data; if (!strcmp(methodname, "x-zstd:nostatic")) { methodname = "x-zstd"; tor_zstd_set_static_apis_disabled_for_testing(1); } return (void *)methodname; } /** Cleanup for compression tests: disables nostatic */ static int compression_test_cleanup(const struct testcase_t *testcase, void *ptr) { (void)testcase; (void)ptr; tor_zstd_set_static_apis_disabled_for_testing(0); return 1; } static const struct testcase_setup_t compress_setup = { compression_test_setup, compression_test_cleanup }; /** Run unit tests for compression functions */ static void test_util_compress(void *arg) { const char *methodname = arg; tt_assert(methodname); compress_method_t method = compression_method_get_by_name(methodname); tt_int_op(method, OP_NE, UNKNOWN_METHOD); if (! tor_compress_supports_method(method)) { tt_skip(); } compression_level_t levels[] = { BEST_COMPRESSION, HIGH_COMPRESSION, MEDIUM_COMPRESSION, LOW_COMPRESSION }; test_util_compress_impl(method); for (unsigned l = 0; l < ARRAY_LENGTH(levels); ++l) { compression_level_t level = levels[l]; test_util_compress_stream_impl(method, level); } done: ; } static void test_util_decompress_concatenated_impl(compress_method_t method) { char input[4096]; char *c1 = NULL, *c2 = NULL, *c3 = NULL; char *result = NULL; size_t sz1, sz2, sz3, szr; int r; crypto_rand(input, sizeof(input)); /* Compress the input in two chunks. */ r = tor_compress(&c1, &sz1, input, 2048, method); tt_int_op(r, OP_EQ, 0); r = tor_compress(&c2, &sz2, input+2048, 2048, method); tt_int_op(r, OP_EQ, 0); /* concatenate the chunks. */ sz3 = sz1 + sz2; c3 = tor_malloc(sz3); memcpy(c3, c1, sz1); memcpy(c3+sz1, c2, sz2); /* decompress the concatenated result */ r = tor_uncompress(&result, &szr, c3, sz3, method, 0, LOG_WARN); tt_int_op(r, OP_EQ, 0); tt_int_op(szr, OP_EQ, sizeof(input)); tt_mem_op(result, OP_EQ, input, sizeof(input)); done: tor_free(c1); tor_free(c2); tor_free(c3); tor_free(result); } static void test_util_decompress_concatenated(void *arg) { const char *methodname = arg; tt_assert(methodname); compress_method_t method = compression_method_get_by_name(methodname); tt_int_op(method, OP_NE, UNKNOWN_METHOD); if (! tor_compress_supports_method(method)) { tt_skip(); } test_util_decompress_concatenated_impl(method); done: ; } static void test_util_decompress_junk_impl(compress_method_t method) { char input[4096]; char *result = NULL, *result2 = NULL; size_t szr, szr2, sz; int r; /* This shouldn't be a compressed string according to any method. */ strlcpy(input, "This shouldn't be a compressed string by any means.", sizeof(input)); sz = strlen(input); setup_capture_of_logs(LOG_WARN); r = tor_uncompress(&result, &szr, input, sz, method, 0, LOG_WARN); tt_int_op(r, OP_EQ, -1); tt_ptr_op(result, OP_EQ, NULL); expect_log_msg_containing("Error while uncompressing data: bad input?"); mock_clean_saved_logs(); /* Now try again, with a compressed object that starts out good and turns to junk. */ crypto_rand(input, sizeof(input)); r = tor_compress(&result, &szr, input, sizeof(input), method); tt_int_op(r, OP_EQ, 0); crypto_rand(result+szr/2, szr-(szr/2)); // trash the 2nd half of the result r = tor_uncompress(&result2, &szr2, result, szr, method, 0, LOG_WARN); tt_int_op(r, OP_EQ, -1); expect_log_msg_containing("Error while uncompressing data: bad input?"); done: teardown_capture_of_logs(); tor_free(result); tor_free(result2); } static void test_util_decompress_junk(void *arg) { const char *methodname = arg; tt_assert(methodname); compress_method_t method = compression_method_get_by_name(methodname); tt_int_op(method, OP_NE, UNKNOWN_METHOD); if (! tor_compress_supports_method(method)) { tt_skip(); } test_util_decompress_junk_impl(method); done: ; } /* mock replacement for tor_compress_is_compression_bomb that doesn't * believe in compression bombs. */ static int mock_is_never_compression_bomb(size_t in, size_t out) { (void)in; (void) out; return 0; } static void test_util_decompress_dos_impl(compress_method_t method) { char *input; char *result = NULL, *result2 = NULL; size_t szr, szr2; int r; const size_t big = 1024*1024; /* one megabyte of 0s. */ input = tor_malloc_zero(big); /* Compress it into "result": it should fail. */ setup_full_capture_of_logs(LOG_WARN); r = tor_compress(&result, &szr, input, big, method); tt_int_op(r, OP_EQ, -1); expect_log_msg_containing( "other Tors would think this was a compression bomb"); teardown_capture_of_logs(); /* Try again, but this time suppress compression-bomb detection */ MOCK(tor_compress_is_compression_bomb, mock_is_never_compression_bomb); r = tor_compress(&result, &szr, input, big, method); UNMOCK(tor_compress_is_compression_bomb); tt_int_op(r, OP_EQ, 0); tt_ptr_op(result, OP_NE, NULL); /* We should refuse to uncomrpess it again, since it looks like a * compression bomb. */ setup_capture_of_logs(LOG_WARN); r = tor_uncompress(&result2, &szr2, result, szr, method, 0, LOG_WARN); tt_int_op(r, OP_EQ, -1); expect_log_msg_containing("bomb; abandoning stream"); done: teardown_capture_of_logs(); tor_free(input); tor_free(result); tor_free(result2); } static void test_util_decompress_dos(void *arg) { const char *methodname = arg; tt_assert(methodname); compress_method_t method = compression_method_get_by_name(methodname); tt_int_op(method, OP_NE, UNKNOWN_METHOD); if (! tor_compress_supports_method(method)) { tt_skip(); } test_util_decompress_dos_impl(method); done: ; } static void test_util_gzip_compression_bomb(void *arg) { /* A 'compression bomb' is a very small object that uncompresses to a huge * one. Most compression formats support them, but they can be a DOS vector. * In Tor we try not to generate them, and we don't accept them. */ (void) arg; size_t one_million = 1<<20; char *one_mb = tor_malloc_zero(one_million); char *result = NULL; size_t result_len = 0; tor_compress_state_t *state = NULL; /* Make sure we can't produce a compression bomb */ setup_full_capture_of_logs(LOG_WARN); tt_int_op(-1, OP_EQ, tor_compress(&result, &result_len, one_mb, one_million, ZLIB_METHOD)); expect_single_log_msg_containing( "We compressed something and got an insanely high " "compression factor; other Tors would think this " "was a compression bomb."); teardown_capture_of_logs(); /* Here's a compression bomb that we made manually. */ const char compression_bomb[1039] = { 0x78, 0xDA, 0xED, 0xC1, 0x31, 0x01, 0x00, 0x00, 0x00, 0xC2, 0xA0, 0xF5, 0x4F, 0x6D, 0x08, 0x5F, 0xA0 /* .... */ }; tt_int_op(-1, OP_EQ, tor_uncompress(&result, &result_len, compression_bomb, 1039, ZLIB_METHOD, 0, LOG_WARN)); /* Now try streaming that. */ state = tor_compress_new(0, ZLIB_METHOD, HIGH_COMPRESSION); tor_compress_output_t r; const char *inp = compression_bomb; size_t inlen = 1039; do { char *outp = one_mb; size_t outleft = 4096; /* small on purpose */ r = tor_compress_process(state, &outp, &outleft, &inp, &inlen, 0); tt_int_op(inlen, OP_NE, 0); } while (r == TOR_COMPRESS_BUFFER_FULL); tt_int_op(r, OP_EQ, TOR_COMPRESS_ERROR); done: tor_free(one_mb); tor_compress_free(state); } /** Run unit tests for mmap() wrapper functionality. */ static void test_util_mmap(void *arg) { 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; (void)arg; crypto_rand(buf, buflen); mapping = tor_mmap_file(fname1); tt_ptr_op(mapping, OP_EQ, NULL); write_str_to_file(fname1, "Short file.", 1); mapping = tor_mmap_file(fname1); tt_assert(mapping); tt_int_op(mapping->size,OP_EQ, strlen("Short file.")); tt_str_op(mapping->data,OP_EQ, "Short file."); #ifdef _WIN32 tt_int_op(0, OP_EQ, tor_munmap_file(mapping)); mapping = NULL; tt_assert(unlink(fname1) == 0); #else /* make sure we can unlink. */ tt_assert(unlink(fname1) == 0); tt_str_op(mapping->data,OP_EQ, "Short file."); tt_int_op(0, OP_EQ, tor_munmap_file(mapping)); mapping = NULL; #endif /* defined(_WIN32) */ /* Now a zero-length file. */ write_str_to_file(fname1, "", 1); mapping = tor_mmap_file(fname1); tt_ptr_op(mapping,OP_EQ, NULL); tt_int_op(ERANGE,OP_EQ, errno); unlink(fname1); /* Make sure that we fail to map a no-longer-existent file. */ mapping = tor_mmap_file(fname1); tt_ptr_op(mapping, OP_EQ, NULL); /* Now try a big file that stretches across a few pages and isn't aligned */ write_bytes_to_file(fname2, buf, buflen, 1); mapping = tor_mmap_file(fname2); tt_assert(mapping); tt_int_op(mapping->size,OP_EQ, buflen); tt_mem_op(mapping->data,OP_EQ, buf, buflen); tt_int_op(0, OP_EQ, tor_munmap_file(mapping)); mapping = NULL; /* Now try a big aligned file. */ write_bytes_to_file(fname3, buf, 16384, 1); mapping = tor_mmap_file(fname3); tt_assert(mapping); tt_int_op(mapping->size,OP_EQ, 16384); tt_mem_op(mapping->data,OP_EQ, buf, 16384); tt_int_op(0, OP_EQ, 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); tor_munmap_file(mapping); } /** Run unit tests for escaping/unescaping data for use by controllers. */ static void test_util_control_formats(void *arg) { char *out = NULL; const char *inp = "..This is a test\r\n.of the emergency \n..system.\r\n\rZ.\r\n"; size_t sz; (void)arg; sz = read_escaped_data(inp, strlen(inp), &out); tt_str_op(out,OP_EQ, ".This is a test\nof the emergency \n.system.\n\rZ.\n"); tt_int_op(sz,OP_EQ, strlen(out)); done: tor_free(out); } #define test_feq(value1,value2) do { \ double v1 = (value1), v2=(value2); \ double tf_diff = v1-v2; \ double tf_tolerance = ((v1+v2)/2.0)/1e8; \ if (tf_diff<0) tf_diff=-tf_diff; \ if (tf_tolerance<0) tf_tolerance=-tf_tolerance; \ if (tf_diff 1 year are reported in days (warn?) */ /* ignore exact spelling of "days(s)," etc., if present */ format_time_interval(dbuf, sizeof(dbuf), 758635154); tt_int_op(strnlen(dbuf, DBUF_SIZE),OP_LE, DBUF_SIZE - 1); r = tor_sscanf(dbuf, TL_ " " TL_ " " TL_, &day, label_d, &hour, label_h, &min, label_m); tt_int_op(r,OP_EQ, 6); tt_int_op(day,OP_EQ, 8780); tt_ci_char_op(label_d[0],OP_EQ, 'd'); tt_int_op(hour,OP_EQ, 11); tt_ci_char_op(label_h[0],OP_EQ, 'h'); tt_int_op(min,OP_EQ, 59); tt_ci_char_op(label_m[0],OP_EQ, 'm'); /* negative periods > 1 year are reported in days (warn?) */ format_time_interval(dbuf, sizeof(dbuf), -1427014922); tt_int_op(strnlen(dbuf, DBUF_SIZE),OP_LE, DBUF_SIZE - 1); r = tor_sscanf(dbuf, TL_ " " TL_ " " TL_, &day, label_d, &hour, label_h, &min, label_m); tt_int_op(r,OP_EQ, 6); tt_int_op(day,OP_EQ, 16516); tt_ci_char_op(label_d[0],OP_EQ, 'd'); tt_int_op(hour,OP_EQ, 9); tt_ci_char_op(label_h[0],OP_EQ, 'h'); tt_int_op(min,OP_EQ, 2); tt_ci_char_op(label_m[0],OP_EQ, 'm'); #if SIZEOF_LONG == 4 || SIZEOF_LONG == 8 /* We can try INT32_MIN/MAX */ /* Always ignore second(s) */ /* INT32_MAX */ format_time_interval(dbuf, sizeof(dbuf), 2147483647); tt_int_op(strnlen(dbuf, DBUF_SIZE),OP_LE, DBUF_SIZE - 1); r = tor_sscanf(dbuf, TL_ " " TL_ " " TL_, &day, label_d, &hour, label_h, &min, label_m); tt_int_op(r,OP_EQ, 6); tt_int_op(day,OP_EQ, 24855); tt_ci_char_op(label_d[0],OP_EQ, 'd'); tt_int_op(hour,OP_EQ, 3); tt_ci_char_op(label_h[0],OP_EQ, 'h'); tt_int_op(min,OP_EQ, 14); tt_ci_char_op(label_m[0],OP_EQ, 'm'); /* and 7 seconds - ignored */ /* INT32_MIN: check that we get the absolute value of interval, * which doesn't actually fit in int32_t. * We expect INT32_MAX or INT32_MAX + 1 with 64 bit longs */ format_time_interval(dbuf, sizeof(dbuf), -2147483647L - 1L); tt_int_op(strnlen(dbuf, DBUF_SIZE),OP_LE, DBUF_SIZE - 1); r = tor_sscanf(dbuf, TL_ " " TL_ " " TL_, &day, label_d, &hour, label_h, &min, label_m); tt_int_op(r,OP_EQ, 6); tt_int_op(day,OP_EQ, 24855); tt_ci_char_op(label_d[0],OP_EQ, 'd'); tt_int_op(hour,OP_EQ, 3); tt_ci_char_op(label_h[0],OP_EQ, 'h'); tt_int_op(min,OP_EQ, 14); tt_ci_char_op(label_m[0],OP_EQ, 'm'); /* and 7 or 8 seconds - ignored */ #endif /* SIZEOF_LONG == 4 || SIZEOF_LONG == 8 */ #if SIZEOF_LONG == 8 /* We can try INT64_MIN/MAX */ /* Always ignore second(s) */ /* INT64_MAX */ format_time_interval(dbuf, sizeof(dbuf), 9223372036854775807L); tt_int_op(strnlen(dbuf, DBUF_SIZE),OP_LE, DBUF_SIZE - 1); r = tor_sscanf(dbuf, TL_ " " TL_ " " TL_, &day, label_d, &hour, label_h, &min, label_m); tt_int_op(r,OP_EQ, 6); tt_int_op(day,OP_EQ, 106751991167300L); tt_ci_char_op(label_d[0],OP_EQ, 'd'); tt_int_op(hour,OP_EQ, 15); tt_ci_char_op(label_h[0],OP_EQ, 'h'); tt_int_op(min,OP_EQ, 30); tt_ci_char_op(label_m[0],OP_EQ, 'm'); /* and 7 seconds - ignored */ /* INT64_MIN: check that we get the absolute value of interval, * which doesn't actually fit in int64_t. * We expect INT64_MAX */ format_time_interval(dbuf, sizeof(dbuf), -9223372036854775807L - 1L); tt_int_op(strnlen(dbuf, DBUF_SIZE),OP_LE, DBUF_SIZE - 1); r = tor_sscanf(dbuf, TL_ " " TL_ " " TL_, &day, label_d, &hour, label_h, &min, label_m); tt_int_op(r,OP_EQ, 6); tt_int_op(day,OP_EQ, 106751991167300L); tt_ci_char_op(label_d[0],OP_EQ, 'd'); tt_int_op(hour,OP_EQ, 15); tt_ci_char_op(label_h[0],OP_EQ, 'h'); tt_int_op(min,OP_EQ, 30); tt_ci_char_op(label_m[0],OP_EQ, 'm'); /* and 7 or 8 seconds - ignored */ #endif /* SIZEOF_LONG == 8 */ done: ; } #undef tt_char_op #undef tt_ci_char_op #undef DBUF_SIZE #undef T_ #undef LABEL_SIZE #undef L_ #undef TL_ static void test_util_path_is_relative(void *arg) { /* OS-independent tests */ (void)arg; tt_int_op(1,OP_EQ, path_is_relative("")); tt_int_op(1,OP_EQ, path_is_relative("dir")); tt_int_op(1,OP_EQ, path_is_relative("dir/")); tt_int_op(1,OP_EQ, path_is_relative("./dir")); tt_int_op(1,OP_EQ, path_is_relative("../dir")); tt_int_op(0,OP_EQ, path_is_relative("/")); tt_int_op(0,OP_EQ, path_is_relative("/dir")); tt_int_op(0,OP_EQ, path_is_relative("/dir/")); /* Windows */ #ifdef _WIN32 /* I don't have Windows so I can't test this, hence the "#ifdef 0". These are tests that look useful, so please try to get them running and uncomment if it all works as it should */ tt_int_op(1,OP_EQ, path_is_relative("dir")); tt_int_op(1,OP_EQ, path_is_relative("dir\\")); tt_int_op(1,OP_EQ, path_is_relative("dir\\a:")); tt_int_op(1,OP_EQ, path_is_relative("dir\\a:\\")); tt_int_op(1,OP_EQ, path_is_relative("http:\\dir")); tt_int_op(0,OP_EQ, path_is_relative("\\dir")); tt_int_op(0,OP_EQ, path_is_relative("a:\\dir")); tt_int_op(0,OP_EQ, path_is_relative("z:\\dir")); #endif /* defined(_WIN32) */ done: ; } /** Run unittests for memory area allocator */ static void test_util_memarea(void *arg) { memarea_t *area = memarea_new(); char *p1, *p2, *p3, *p1_orig; void *malloced_ptr = NULL; int i; #ifdef DISABLE_MEMORY_SENTINELS /* If memory sentinels are disabled, this whole module is just an alias for malloc(), which is free to lay out memory most any way it wants. */ if (1) tt_skip(); #endif /* defined(DISABLE_MEMORY_SENTINELS) */ (void)arg; tt_assert(area); p1_orig = p1 = memarea_alloc(area,64); p2 = memarea_alloc_zero(area,52); p3 = memarea_alloc(area,11); tt_assert(memarea_owns_ptr(area, p1)); tt_assert(memarea_owns_ptr(area, p2)); tt_assert(memarea_owns_ptr(area, p3)); /* Make sure we left enough space. */ tt_assert(p1+64 <= p2); tt_assert(p2+52 <= p3); /* Make sure we aligned. */ tt_int_op(((uintptr_t)p1) % sizeof(void*),OP_EQ, 0); tt_int_op(((uintptr_t)p2) % sizeof(void*),OP_EQ, 0); tt_int_op(((uintptr_t)p3) % sizeof(void*),OP_EQ, 0); tt_assert(!memarea_owns_ptr(area, p3+8192)); tt_assert(!memarea_owns_ptr(area, p3+30)); tt_assert(tor_mem_is_zero(p2, 52)); /* Make sure we don't overalign. */ p1 = memarea_alloc(area, 1); p2 = memarea_alloc(area, 1); tt_ptr_op(p1+sizeof(void*),OP_EQ, p2); { malloced_ptr = tor_malloc(64); tt_assert(!memarea_owns_ptr(area, malloced_ptr)); tor_free(malloced_ptr); } /* memarea_memdup */ { malloced_ptr = tor_malloc(64); crypto_rand((char*)malloced_ptr, 64); p1 = memarea_memdup(area, malloced_ptr, 64); tt_assert(p1 != malloced_ptr); tt_mem_op(p1,OP_EQ, malloced_ptr, 64); tor_free(malloced_ptr); } /* memarea_strdup. */ p1 = memarea_strdup(area,""); p2 = memarea_strdup(area, "abcd"); tt_assert(p1); tt_assert(p2); tt_str_op(p1,OP_EQ, ""); tt_str_op(p2,OP_EQ, "abcd"); /* memarea_strndup. */ { const char *s = "Ad ogni porta batte la morte e grida: il nome!"; /* (From Turandot, act 3.) */ size_t len = strlen(s); p1 = memarea_strndup(area, s, 1000); p2 = memarea_strndup(area, s, 10); tt_str_op(p1,OP_EQ, s); tt_assert(p2 >= p1 + len + 1); tt_mem_op(s,OP_EQ, p2, 10); tt_int_op(p2[10],OP_EQ, '\0'); p3 = memarea_strndup(area, s, len); tt_str_op(p3,OP_EQ, s); p3 = memarea_strndup(area, s, len-1); tt_mem_op(s,OP_EQ, p3, len-1); tt_int_op(p3[len-1],OP_EQ, '\0'); } memarea_clear(area); p1 = memarea_alloc(area, 1); tt_ptr_op(p1,OP_EQ, p1_orig); memarea_clear(area); size_t total = 0, initial_allocation, allocation2, dummy; memarea_get_stats(area, &initial_allocation, &dummy); /* Check for running over an area's size. */ for (i = 0; i < 4096; ++i) { size_t n = crypto_rand_int(6); p1 = memarea_alloc(area, n); total += n; tt_assert(memarea_owns_ptr(area, p1)); } memarea_assert_ok(area); memarea_get_stats(area, &allocation2, &dummy); /* Make sure we can allocate a too-big object. */ p1 = memarea_alloc_zero(area, 9000); p2 = memarea_alloc_zero(area, 16); total += 9000; total += 16; tt_assert(memarea_owns_ptr(area, p1)); tt_assert(memarea_owns_ptr(area, p2)); /* Now test stats... */ size_t allocated = 0, used = 0; memarea_get_stats(area, &allocated, &used); tt_int_op(used, OP_LE, allocated); tt_int_op(used, OP_GE, total); /* not EQ, because of alignment and headers*/ tt_int_op(allocated, OP_GT, allocation2); tt_int_op(allocation2, OP_GT, initial_allocation); memarea_clear(area); memarea_get_stats(area, &allocated, &used); tt_int_op(used, OP_LT, 128); /* Not 0, because of header */ tt_int_op(allocated, OP_EQ, initial_allocation); done: memarea_drop_all(area); tor_free(malloced_ptr); } /** Run unit tests for utility functions to get file names relative to * the data directory. */ static void test_util_datadir(void *arg) { char buf[1024]; char *f = NULL; char *temp_dir = NULL; (void)arg; temp_dir = get_datadir_fname(NULL); f = get_datadir_fname("state"); tor_snprintf(buf, sizeof(buf), "%s"PATH_SEPARATOR"state", temp_dir); tt_str_op(f,OP_EQ, buf); tor_free(f); f = get_datadir_fname2("cache", "thingy"); tor_snprintf(buf, sizeof(buf), "%s"PATH_SEPARATOR"cache"PATH_SEPARATOR"thingy", temp_dir); tt_str_op(f,OP_EQ, buf); tor_free(f); f = get_datadir_fname2_suffix("cache", "thingy", ".foo"); tor_snprintf(buf, sizeof(buf), "%s"PATH_SEPARATOR"cache"PATH_SEPARATOR"thingy.foo", temp_dir); tt_str_op(f,OP_EQ, buf); tor_free(f); f = get_datadir_fname_suffix("cache", ".foo"); tor_snprintf(buf, sizeof(buf), "%s"PATH_SEPARATOR"cache.foo", temp_dir); tt_str_op(f,OP_EQ, buf); done: tor_free(f); tor_free(temp_dir); } static void test_util_strtok(void *arg) { char buf[128]; char buf2[128]; int i; char *cp1, *cp2; (void)arg; for (i = 0; i < 3; i++) { const char *pad1="", *pad2=""; switch (i) { case 0: break; case 1: pad1 = " "; pad2 = "!"; break; case 2: pad1 = " "; pad2 = ";!"; break; } tor_snprintf(buf, sizeof(buf), "%s", pad1); tor_snprintf(buf2, sizeof(buf2), "%s", pad2); tt_ptr_op(tor_strtok_r_impl(buf, " ", &cp1), OP_EQ, NULL); tt_ptr_op(tor_strtok_r_impl(buf2, ".!..;!", &cp2), OP_EQ, NULL); tor_snprintf(buf, sizeof(buf), "%sGraved on the dark in gestures of descent%s", pad1, pad1); tor_snprintf(buf2, sizeof(buf2), "%sthey.seemed;;their!.own;most.perfect;monument%s",pad2,pad2); /* -- "Year's End", Richard Wilbur */ tt_str_op("Graved",OP_EQ, tor_strtok_r_impl(buf, " ", &cp1)); tt_str_op("they",OP_EQ, tor_strtok_r_impl(buf2, ".!..;!", &cp2)); #define S1() tor_strtok_r_impl(NULL, " ", &cp1) #define S2() tor_strtok_r_impl(NULL, ".!..;!", &cp2) tt_str_op("on",OP_EQ, S1()); tt_str_op("the",OP_EQ, S1()); tt_str_op("dark",OP_EQ, S1()); tt_str_op("seemed",OP_EQ, S2()); tt_str_op("their",OP_EQ, S2()); tt_str_op("own",OP_EQ, S2()); tt_str_op("in",OP_EQ, S1()); tt_str_op("gestures",OP_EQ, S1()); tt_str_op("of",OP_EQ, S1()); tt_str_op("most",OP_EQ, S2()); tt_str_op("perfect",OP_EQ, S2()); tt_str_op("descent",OP_EQ, S1()); tt_str_op("monument",OP_EQ, S2()); tt_ptr_op(NULL,OP_EQ, S1()); tt_ptr_op(NULL,OP_EQ, S2()); } buf[0] = 0; tt_ptr_op(NULL,OP_EQ, tor_strtok_r_impl(buf, " ", &cp1)); tt_ptr_op(NULL,OP_EQ, tor_strtok_r_impl(buf, "!", &cp1)); strlcpy(buf, "Howdy!", sizeof(buf)); tt_str_op("Howdy",OP_EQ, tor_strtok_r_impl(buf, "!", &cp1)); tt_ptr_op(NULL,OP_EQ, tor_strtok_r_impl(NULL, "!", &cp1)); strlcpy(buf, " ", sizeof(buf)); tt_ptr_op(NULL,OP_EQ, tor_strtok_r_impl(buf, " ", &cp1)); strlcpy(buf, " ", sizeof(buf)); tt_ptr_op(NULL,OP_EQ, tor_strtok_r_impl(buf, " ", &cp1)); strlcpy(buf, "something ", sizeof(buf)); tt_str_op("something",OP_EQ, tor_strtok_r_impl(buf, " ", &cp1)); tt_ptr_op(NULL,OP_EQ, tor_strtok_r_impl(NULL, ";", &cp1)); done: ; } static void test_util_find_str_at_start_of_line(void *ptr) { const char *long_string = "howdy world. how are you? i hope it's fine.\n" "hello kitty\n" "third line"; char *line2 = strchr(long_string,'\n')+1; char *line3 = strchr(line2,'\n')+1; const char *short_string = "hello kitty\n" "second line\n"; char *short_line2 = strchr(short_string,'\n')+1; (void)ptr; tt_ptr_op(long_string,OP_EQ, find_str_at_start_of_line(long_string, "")); tt_ptr_op(NULL,OP_EQ, find_str_at_start_of_line(short_string, "nonsense")); tt_ptr_op(NULL,OP_EQ, find_str_at_start_of_line(long_string, "nonsense")); tt_ptr_op(NULL,OP_EQ, find_str_at_start_of_line(long_string, "\n")); tt_ptr_op(NULL,OP_EQ, find_str_at_start_of_line(long_string, "how ")); tt_ptr_op(NULL,OP_EQ, find_str_at_start_of_line(long_string, "kitty")); tt_ptr_op(long_string,OP_EQ, find_str_at_start_of_line(long_string, "h")); tt_ptr_op(long_string,OP_EQ, find_str_at_start_of_line(long_string, "how")); tt_ptr_op(line2,OP_EQ, find_str_at_start_of_line(long_string, "he")); tt_ptr_op(line2,OP_EQ, find_str_at_start_of_line(long_string, "hell")); tt_ptr_op(line2,OP_EQ, find_str_at_start_of_line(long_string, "hello k")); tt_ptr_op(line2,OP_EQ, find_str_at_start_of_line(long_string, "hello kitty\n")); tt_ptr_op(line2,OP_EQ, find_str_at_start_of_line(long_string, "hello kitty\nt")); tt_ptr_op(line3,OP_EQ, find_str_at_start_of_line(long_string, "third")); tt_ptr_op(line3,OP_EQ, find_str_at_start_of_line(long_string, "third line")); tt_ptr_op(NULL, OP_EQ, find_str_at_start_of_line(long_string, "third line\n")); tt_ptr_op(short_line2,OP_EQ, find_str_at_start_of_line(short_string, "second line\n")); done: ; } static void test_util_string_is_C_identifier(void *ptr) { (void)ptr; tt_int_op(1,OP_EQ, string_is_C_identifier("string_is_C_identifier")); tt_int_op(1,OP_EQ, string_is_C_identifier("_string_is_C_identifier")); tt_int_op(1,OP_EQ, string_is_C_identifier("_")); tt_int_op(1,OP_EQ, string_is_C_identifier("i")); tt_int_op(1,OP_EQ, string_is_C_identifier("_____")); tt_int_op(1,OP_EQ, string_is_C_identifier("__00__")); tt_int_op(1,OP_EQ, string_is_C_identifier("__init__")); tt_int_op(1,OP_EQ, string_is_C_identifier("_0")); tt_int_op(1,OP_EQ, string_is_C_identifier("_0string_is_C_identifier")); tt_int_op(1,OP_EQ, string_is_C_identifier("_0")); tt_int_op(0,OP_EQ, string_is_C_identifier("0_string_is_C_identifier")); tt_int_op(0,OP_EQ, string_is_C_identifier("0")); tt_int_op(0,OP_EQ, string_is_C_identifier("")); tt_int_op(0,OP_EQ, string_is_C_identifier(";")); tt_int_op(0,OP_EQ, string_is_C_identifier("i;")); tt_int_op(0,OP_EQ, string_is_C_identifier("_;")); tt_int_op(0,OP_EQ, string_is_C_identifier("í")); tt_int_op(0,OP_EQ, string_is_C_identifier("ñ")); done: ; } static void test_util_string_is_utf8(void *ptr) { (void)ptr; tt_int_op(1, OP_EQ, string_is_utf8(NULL, 0)); tt_int_op(1, OP_EQ, string_is_utf8("", 1)); tt_int_op(1, OP_EQ, string_is_utf8("\uFEFF", 3)); tt_int_op(1, OP_EQ, string_is_utf8("\uFFFE", 3)); tt_int_op(1, OP_EQ, string_is_utf8("ascii\x7f\n", 7)); tt_int_op(1, OP_EQ, string_is_utf8("Risqu\u00e9=1", 9)); // Validate exactly 'len' bytes. tt_int_op(0, OP_EQ, string_is_utf8("\0\x80", 2)); tt_int_op(0, OP_EQ, string_is_utf8("Risqu\u00e9=1", 6)); // Reject sequences with missing bytes. tt_int_op(0, OP_EQ, string_is_utf8("\x80", 1)); tt_int_op(0, OP_EQ, string_is_utf8("\xc2", 1)); tt_int_op(0, OP_EQ, string_is_utf8("\xc2 ", 2)); tt_int_op(0, OP_EQ, string_is_utf8("\xe1\x80", 2)); tt_int_op(0, OP_EQ, string_is_utf8("\xe1\x80 ", 3)); tt_int_op(0, OP_EQ, string_is_utf8("\xf1\x80\x80", 3)); tt_int_op(0, OP_EQ, string_is_utf8("\xf1\x80\x80 ", 4)); // Reject encodings that are overly long. tt_int_op(0, OP_EQ, string_is_utf8("\xc1\xbf", 2)); tt_int_op(1, OP_EQ, string_is_utf8("\xc2\x80", 2)); tt_int_op(0, OP_EQ, string_is_utf8("\xe0\x9f\xbf", 3)); tt_int_op(1, OP_EQ, string_is_utf8("\xe0\xa0\x80", 3)); tt_int_op(0, OP_EQ, string_is_utf8("\xf0\x8f\xbf\xbf", 4)); tt_int_op(1, OP_EQ, string_is_utf8("\xf0\x90\x80\x80", 4)); // Reject UTF-16 surrogate halves. tt_int_op(1, OP_EQ, string_is_utf8("\xed\x9f\xbf", 3)); tt_int_op(0, OP_EQ, string_is_utf8("\xed\xa0\x80", 3)); tt_int_op(0, OP_EQ, string_is_utf8("\xed\xbf\xbf", 3)); tt_int_op(1, OP_EQ, string_is_utf8("\xee\x80\x80", 3)); // The maximum legal codepoint, 10FFFF. tt_int_op(1, OP_EQ, string_is_utf8("\xf4\x8f\xbf\xbf", 4)); tt_int_op(0, OP_EQ, string_is_utf8("\xf4\x90\x80\x80", 4)); done: ; } static void test_util_asprintf(void *ptr) { #define LOREMIPSUM \ "Lorem ipsum dolor sit amet, consectetur adipisicing elit" char *cp=NULL, *cp2=NULL; int r; (void)ptr; /* simple string */ r = tor_asprintf(&cp, "simple string 100%% safe"); tt_assert(cp); tt_str_op("simple string 100% safe",OP_EQ, cp); tt_int_op(strlen(cp),OP_EQ, r); tor_free(cp); /* empty string */ r = tor_asprintf(&cp, "%s", ""); tt_assert(cp); tt_str_op("",OP_EQ, cp); tt_int_op(strlen(cp),OP_EQ, r); tor_free(cp); /* numbers (%i) */ r = tor_asprintf(&cp, "I like numbers-%2i, %i, etc.", -1, 2); tt_assert(cp); tt_str_op("I like numbers--1, 2, etc.",OP_EQ, cp); tt_int_op(strlen(cp),OP_EQ, r); /* don't free cp; next test uses it. */ /* numbers (%d) */ r = tor_asprintf(&cp2, "First=%d, Second=%d", 101, 202); tt_assert(cp2); tt_int_op(strlen(cp2),OP_EQ, r); tt_str_op("First=101, Second=202",OP_EQ, cp2); tt_assert(cp != cp2); tor_free(cp); tor_free(cp2); /* Glass-box test: a string exactly 128 characters long. */ r = tor_asprintf(&cp, "Lorem1: %sLorem2: %s", LOREMIPSUM, LOREMIPSUM); tt_assert(cp); tt_int_op(128,OP_EQ, r); tt_int_op(cp[128], OP_EQ, '\0'); tt_str_op("Lorem1: "LOREMIPSUM"Lorem2: "LOREMIPSUM,OP_EQ, cp); tor_free(cp); /* String longer than 128 characters */ r = tor_asprintf(&cp, "1: %s 2: %s 3: %s", LOREMIPSUM, LOREMIPSUM, LOREMIPSUM); tt_assert(cp); tt_int_op(strlen(cp),OP_EQ, r); tt_str_op("1: "LOREMIPSUM" 2: "LOREMIPSUM" 3: "LOREMIPSUM,OP_EQ, cp); done: tor_free(cp); tor_free(cp2); } static void test_util_listdir(void *ptr) { smartlist_t *dir_contents = NULL; char *fname1=NULL, *fname2=NULL, *fname3=NULL, *dir1=NULL, *dirname=NULL; int r; (void)ptr; fname1 = tor_strdup(get_fname("hopscotch")); fname2 = tor_strdup(get_fname("mumblety-peg")); fname3 = tor_strdup(get_fname(".hidden-file")); dir1 = tor_strdup(get_fname("some-directory")); dirname = tor_strdup(get_fname(NULL)); tt_int_op(0,OP_EQ, write_str_to_file(fname1, "X\n", 0)); tt_int_op(0,OP_EQ, write_str_to_file(fname2, "Y\n", 0)); tt_int_op(0,OP_EQ, write_str_to_file(fname3, "Z\n", 0)); #ifdef _WIN32 r = mkdir(dir1); #else r = mkdir(dir1, 0700); #endif if (r) { fprintf(stderr, "Can't create directory %s:", dir1); perror(""); exit(1); } dir_contents = tor_listdir(dirname); tt_assert(dir_contents); /* make sure that each filename is listed. */ tt_assert(smartlist_contains_string_case(dir_contents, "hopscotch")); tt_assert(smartlist_contains_string_case(dir_contents, "mumblety-peg")); tt_assert(smartlist_contains_string_case(dir_contents, ".hidden-file")); tt_assert(smartlist_contains_string_case(dir_contents, "some-directory")); tt_assert(!smartlist_contains_string(dir_contents, ".")); tt_assert(!smartlist_contains_string(dir_contents, "..")); done: tor_free(fname1); tor_free(fname2); tor_free(fname3); tor_free(dir1); tor_free(dirname); if (dir_contents) { SMARTLIST_FOREACH(dir_contents, char *, cp, tor_free(cp)); smartlist_free(dir_contents); } } static void test_util_parent_dir(void *ptr) { char *cp; (void)ptr; #define T(output,expect_ok,input) \ do { \ int ok; \ cp = tor_strdup(input); \ ok = get_parent_directory(cp); \ tt_int_op(expect_ok, OP_EQ, ok); \ if (ok==0) \ tt_str_op(output, OP_EQ, cp); \ tor_free(cp); \ } while (0); T("/home/wombat", 0, "/home/wombat/knish"); T("/home/wombat", 0, "/home/wombat/knish/"); T("/home/wombat", 0, "/home/wombat/knish///"); T("./home/wombat", 0, "./home/wombat/knish/"); T("/", 0, "/home"); T("/", 0, "/home//"); T(".", 0, "./wombat"); T(".", 0, "./wombat/"); T(".", 0, "./wombat//"); T("wombat", 0, "wombat/foo"); T("wombat/..", 0, "wombat/../foo"); T("wombat/../", 0, "wombat/..//foo"); /* Is this correct? */ T("wombat/.", 0, "wombat/./foo"); T("wombat/./", 0, "wombat/.//foo"); /* Is this correct? */ T("wombat", 0, "wombat/..//"); T("wombat", 0, "wombat/foo/"); T("wombat", 0, "wombat/.foo"); T("wombat", 0, "wombat/.foo/"); T("wombat", -1, ""); T("w", -1, ""); T("wombat", 0, "wombat/knish"); T("/", 0, "/"); T("/", 0, "////"); done: tor_free(cp); } static void test_util_ftruncate(void *ptr) { char *buf = NULL; const char *fname; int fd = -1; const char *message = "Hello world"; const char *message2 = "Hola mundo"; struct stat st; (void) ptr; fname = get_fname("ftruncate"); fd = tor_open_cloexec(fname, O_WRONLY|O_CREAT, 0600); tt_int_op(fd, OP_GE, 0); /* Make the file be there. */ tt_int_op(strlen(message), OP_EQ, write_all_to_fd(fd, message, strlen(message))); tt_int_op((int)tor_fd_getpos(fd), OP_EQ, strlen(message)); tt_int_op(0, OP_EQ, fstat(fd, &st)); tt_int_op((int)st.st_size, OP_EQ, strlen(message)); /* Truncate and see if it got truncated */ tt_int_op(0, OP_EQ, tor_ftruncate(fd)); tt_int_op((int)tor_fd_getpos(fd), OP_EQ, 0); tt_int_op(0, OP_EQ, fstat(fd, &st)); tt_int_op((int)st.st_size, OP_EQ, 0); /* Replace, and see if it got replaced */ tt_int_op(strlen(message2), OP_EQ, write_all_to_fd(fd, message2, strlen(message2))); tt_int_op((int)tor_fd_getpos(fd), OP_EQ, strlen(message2)); tt_int_op(0, OP_EQ, fstat(fd, &st)); tt_int_op((int)st.st_size, OP_EQ, strlen(message2)); close(fd); fd = -1; buf = read_file_to_str(fname, 0, NULL); tt_str_op(message2, OP_EQ, buf); done: if (fd >= 0) close(fd); tor_free(buf); } static void test_util_num_cpus(void *arg) { (void)arg; int num = compute_num_cpus(); if (num < 0) tt_skip(); tt_int_op(num, OP_GE, 1); tt_int_op(num, OP_LE, 16); done: ; } #ifdef _WIN32 static void test_util_load_win_lib(void *ptr) { HANDLE h = load_windows_system_library(_T("advapi32.dll")); (void) ptr; tt_assert(h); done: if (h) FreeLibrary(h); } #endif /* defined(_WIN32) */ #ifndef _WIN32 static void clear_hex_errno(char *hex_errno) { memset(hex_errno, '\0', HEX_ERRNO_SIZE + 1); } static void test_util_exit_status(void *ptr) { /* Leave an extra byte for a \0 so we can do string comparison */ char hex_errno[HEX_ERRNO_SIZE + 1]; int n; (void)ptr; clear_hex_errno(hex_errno); tt_str_op("",OP_EQ, hex_errno); clear_hex_errno(hex_errno); n = format_helper_exit_status(0, 0, hex_errno); tt_str_op("0/0\n",OP_EQ, hex_errno); tt_int_op(n,OP_EQ, strlen(hex_errno)); #if SIZEOF_INT == 4 clear_hex_errno(hex_errno); n = format_helper_exit_status(0, 0x7FFFFFFF, hex_errno); tt_str_op("0/7FFFFFFF\n",OP_EQ, hex_errno); tt_int_op(n,OP_EQ, strlen(hex_errno)); clear_hex_errno(hex_errno); n = format_helper_exit_status(0xFF, -0x80000000, hex_errno); tt_str_op("FF/-80000000\n",OP_EQ, hex_errno); tt_int_op(n,OP_EQ, strlen(hex_errno)); tt_int_op(n,OP_EQ, HEX_ERRNO_SIZE); #elif SIZEOF_INT == 8 clear_hex_errno(hex_errno); n = format_helper_exit_status(0, 0x7FFFFFFFFFFFFFFF, hex_errno); tt_str_op("0/7FFFFFFFFFFFFFFF\n",OP_EQ, hex_errno); tt_int_op(n,OP_EQ, strlen(hex_errno)); clear_hex_errno(hex_errno); n = format_helper_exit_status(0xFF, -0x8000000000000000, hex_errno); tt_str_op("FF/-8000000000000000\n",OP_EQ, hex_errno); tt_int_op(n,OP_EQ, strlen(hex_errno)); tt_int_op(n,OP_EQ, HEX_ERRNO_SIZE); #endif /* SIZEOF_INT == 4 || ... */ clear_hex_errno(hex_errno); n = format_helper_exit_status(0x7F, 0, hex_errno); tt_str_op("7F/0\n",OP_EQ, hex_errno); tt_int_op(n,OP_EQ, strlen(hex_errno)); clear_hex_errno(hex_errno); n = format_helper_exit_status(0x08, -0x242, hex_errno); tt_str_op("8/-242\n",OP_EQ, hex_errno); tt_int_op(n,OP_EQ, strlen(hex_errno)); clear_hex_errno(hex_errno); tt_str_op("",OP_EQ, hex_errno); done: ; } #endif /* !defined(_WIN32) */ #ifndef _WIN32 static void test_util_string_from_pipe(void *ptr) { int test_pipe[2] = {-1, -1}; int retval = 0; enum stream_status status = IO_STREAM_TERM; ssize_t retlen; char buf[4] = { 0 }; (void)ptr; errno = 0; /* Set up a pipe to test on */ retval = pipe(test_pipe); tt_int_op(retval, OP_EQ, 0); /* Send in a string. */ retlen = write(test_pipe[1], "ABC", 3); tt_int_op(retlen, OP_EQ, 3); status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, "ABC"); errno = 0; /* Send in a string that contains a nul. */ retlen = write(test_pipe[1], "AB\0", 3); tt_int_op(retlen, OP_EQ, 3); status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, "AB"); errno = 0; /* Send in a string that contains a nul only. */ retlen = write(test_pipe[1], "\0", 1); tt_int_op(retlen, OP_EQ, 1); status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, ""); errno = 0; /* Send in a string that contains a trailing newline. */ retlen = write(test_pipe[1], "AB\n", 3); tt_int_op(retlen, OP_EQ, 3); status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, "AB"); errno = 0; /* Send in a string that contains a newline only. */ retlen = write(test_pipe[1], "\n", 1); tt_int_op(retlen, OP_EQ, 1); status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, ""); errno = 0; /* Send in a string and check that we nul terminate return values. */ retlen = write(test_pipe[1], "AAA", 3); tt_int_op(retlen, OP_EQ, 3); status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, "AAA"); tt_mem_op(buf, OP_EQ, "AAA\0", sizeof(buf)); errno = 0; retlen = write(test_pipe[1], "B", 1); tt_int_op(retlen, OP_EQ, 1); memset(buf, '\xff', sizeof(buf)); status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, "B"); tt_mem_op(buf, OP_EQ, "B\0\xff\xff", sizeof(buf)); errno = 0; /* Send in multiple lines. */ retlen = write(test_pipe[1], "A\nB", 3); tt_int_op(retlen, OP_EQ, 3); status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, "A\nB"); errno = 0; /* Send in a line and close */ retlen = write(test_pipe[1], "AB", 2); tt_int_op(retlen, OP_EQ, 2); retval = close(test_pipe[1]); tt_int_op(retval, OP_EQ, 0); test_pipe[1] = -1; status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_OKAY); tt_str_op(buf, OP_EQ, "AB"); errno = 0; /* Check for EOF */ status = get_string_from_pipe(test_pipe[0], buf, sizeof(buf)-1); tt_int_op(errno, OP_EQ, 0); tt_int_op(status, OP_EQ, IO_STREAM_CLOSED); errno = 0; done: if (test_pipe[0] != -1) close(test_pipe[0]); if (test_pipe[1] != -1) close(test_pipe[1]); } #endif /* !defined(_WIN32) */ /** * Test for format_hex_number_sigsafe() */ static void test_util_format_hex_number(void *ptr) { int i, len; char buf[33]; const struct { const char *str; unsigned int x; } test_data[] = { {"0", 0}, {"1", 1}, {"273A", 0x273a}, {"FFFF", 0xffff}, {"7FFFFFFF", 0x7fffffff}, {"FFFFFFFF", 0xffffffff}, #if UINT_MAX >= 0xffffffff {"31BC421D", 0x31bc421d}, {"FFFFFFFF", 0xffffffff}, #endif {NULL, 0} }; (void)ptr; for (i = 0; test_data[i].str != NULL; ++i) { len = format_hex_number_sigsafe(test_data[i].x, buf, sizeof(buf)); tt_int_op(len,OP_NE, 0); tt_int_op(len,OP_EQ, strlen(buf)); tt_str_op(buf,OP_EQ, test_data[i].str); } tt_int_op(4,OP_EQ, format_hex_number_sigsafe(0xffff, buf, 5)); tt_str_op(buf,OP_EQ, "FFFF"); tt_int_op(0,OP_EQ, format_hex_number_sigsafe(0xffff, buf, 4)); tt_int_op(0,OP_EQ, format_hex_number_sigsafe(0, buf, 1)); done: return; } /** * Test for format_hex_number_sigsafe() */ static void test_util_format_dec_number(void *ptr) { int i, len; char buf[33]; const struct { const char *str; unsigned int x; } test_data[] = { {"0", 0}, {"1", 1}, {"1234", 1234}, {"12345678", 12345678}, {"99999999", 99999999}, {"100000000", 100000000}, {"4294967295", 4294967295u}, #if UINT_MAX > 0xffffffff {"18446744073709551615", 18446744073709551615u }, #endif {NULL, 0} }; (void)ptr; for (i = 0; test_data[i].str != NULL; ++i) { len = format_dec_number_sigsafe(test_data[i].x, buf, sizeof(buf)); tt_int_op(len,OP_NE, 0); tt_int_op(len,OP_EQ, strlen(buf)); tt_str_op(buf,OP_EQ, test_data[i].str); len = format_dec_number_sigsafe(test_data[i].x, buf, (int)(strlen(test_data[i].str) + 1)); tt_int_op(len,OP_EQ, strlen(buf)); tt_str_op(buf,OP_EQ, test_data[i].str); } tt_int_op(4,OP_EQ, format_dec_number_sigsafe(7331, buf, 5)); tt_str_op(buf,OP_EQ, "7331"); tt_int_op(0,OP_EQ, format_dec_number_sigsafe(7331, buf, 4)); tt_int_op(1,OP_EQ, format_dec_number_sigsafe(0, buf, 2)); tt_int_op(0,OP_EQ, format_dec_number_sigsafe(0, buf, 1)); done: return; } /** * Test that we can properly format a Windows command line */ static void test_util_join_win_cmdline(void *ptr) { /* Based on some test cases from "Parsing C++ Command-Line Arguments" in * MSDN but we don't exercise all quoting rules because tor_join_win_cmdline * will try to only generate simple cases for the child process to parse; * i.e. we never embed quoted strings in arguments. */ const char *argvs[][4] = { {"a", "bb", "CCC", NULL}, // Normal {NULL, NULL, NULL, NULL}, // Empty argument list {"", NULL, NULL, NULL}, // Empty argument {"\"a", "b\"b", "CCC\"", NULL}, // Quotes {"a\tbc", "dd dd", "E", NULL}, // Whitespace {"a\\\\\\b", "de fg", "H", NULL}, // Backslashes {"a\\\"b", "\\c", "D\\", NULL}, // Backslashes before quote {"a\\\\b c", "d", "E", NULL}, // Backslashes not before quote { NULL } // Terminator }; const char *cmdlines[] = { "a bb CCC", "", "\"\"", "\\\"a b\\\"b CCC\\\"", "\"a\tbc\" \"dd dd\" E", "a\\\\\\b \"de fg\" H", "a\\\\\\\"b \\c D\\", "\"a\\\\b c\" d E", NULL // Terminator }; int i; char *joined_argv = NULL; (void)ptr; for (i=0; cmdlines[i]!=NULL; i++) { log_info(LD_GENERAL, "Joining argvs[%d], expecting <%s>", i, cmdlines[i]); joined_argv = tor_join_win_cmdline(argvs[i]); tt_str_op(cmdlines[i],OP_EQ, joined_argv); tor_free(joined_argv); } done: tor_free(joined_argv); } #define MAX_SPLIT_LINE_COUNT 4 struct split_lines_test_t { const char *orig_line; // Line to be split (may contain \0's) int orig_length; // Length of orig_line const char *split_line[MAX_SPLIT_LINE_COUNT]; // Split lines }; /** * Test that we properly split a buffer into lines */ static void test_util_split_lines(void *ptr) { /* Test cases. orig_line of last test case must be NULL. * The last element of split_line[i] must be NULL. */ struct split_lines_test_t tests[] = { {"", 0, {NULL}}, {"foo", 3, {"foo", NULL}}, {"\n\rfoo\n\rbar\r\n", 12, {"foo", "bar", NULL}}, {"fo o\r\nb\tar", 10, {"fo o", "b.ar", NULL}}, {"\x0f""f\0o\0\n\x01""b\0r\0\r", 12, {".f.o.", ".b.r.", NULL}}, {"line 1\r\nline 2", 14, {"line 1", "line 2", NULL}}, {"line 1\r\n\r\nline 2", 16, {"line 1", "line 2", NULL}}, {"line 1\r\n\r\r\r\nline 2", 18, {"line 1", "line 2", NULL}}, {"line 1\r\n\n\n\n\rline 2", 18, {"line 1", "line 2", NULL}}, {"line 1\r\n\r\t\r\nline 3", 18, {"line 1", ".", "line 3", NULL}}, {"\n\t\r\t\nline 3", 11, {".", ".", "line 3", NULL}}, {NULL, 0, { NULL }} }; int i, j; char *orig_line=NULL; smartlist_t *sl=NULL; (void)ptr; for (i=0; tests[i].orig_line; i++) { sl = smartlist_new(); /* Allocate space for string and trailing NULL */ orig_line = tor_memdup(tests[i].orig_line, tests[i].orig_length + 1); tor_split_lines(sl, orig_line, tests[i].orig_length); j = 0; log_info(LD_GENERAL, "Splitting test %d of length %d", i, tests[i].orig_length); SMARTLIST_FOREACH_BEGIN(sl, const char *, line) { /* Check we have not got too many lines */ tt_int_op(MAX_SPLIT_LINE_COUNT, OP_GT, j); /* Check that there actually should be a line here */ tt_ptr_op(tests[i].split_line[j], OP_NE, NULL); log_info(LD_GENERAL, "Line %d of test %d, should be <%s>", j, i, tests[i].split_line[j]); /* Check that the line is as expected */ tt_str_op(line,OP_EQ, tests[i].split_line[j]); j++; } SMARTLIST_FOREACH_END(line); /* Check that we didn't miss some lines */ tt_ptr_op(NULL,OP_EQ, tests[i].split_line[j]); tor_free(orig_line); smartlist_free(sl); sl = NULL; } done: tor_free(orig_line); smartlist_free(sl); } static void test_util_di_ops(void *arg) { #define LT -1 #define GT 1 #define EQ 0 const struct { const char *a; int want_sign; const char *b; } examples[] = { { "Foo", EQ, "Foo" }, { "foo", GT, "bar", }, { "foobar", EQ ,"foobar" }, { "foobar", LT, "foobaw" }, { "foobar", GT, "f00bar" }, { "foobar", GT, "boobar" }, { "", EQ, "" }, { NULL, 0, NULL }, }; int i; (void)arg; for (i = 0; examples[i].a; ++i) { size_t len = strlen(examples[i].a); int eq1, eq2, neq1, neq2, cmp1, cmp2; tt_int_op(len,OP_EQ, strlen(examples[i].b)); /* We do all of the operations, with operands in both orders. */ eq1 = tor_memeq(examples[i].a, examples[i].b, len); eq2 = tor_memeq(examples[i].b, examples[i].a, len); neq1 = tor_memneq(examples[i].a, examples[i].b, len); neq2 = tor_memneq(examples[i].b, examples[i].a, len); cmp1 = tor_memcmp(examples[i].a, examples[i].b, len); cmp2 = tor_memcmp(examples[i].b, examples[i].a, len); /* Check for correctness of cmp1 */ if (cmp1 < 0 && examples[i].want_sign != LT) TT_DIE(("Assertion failed.")); else if (cmp1 > 0 && examples[i].want_sign != GT) TT_DIE(("Assertion failed.")); else if (cmp1 == 0 && examples[i].want_sign != EQ) TT_DIE(("Assertion failed.")); /* Check for consistency of everything else with cmp1 */ tt_int_op(eq1,OP_EQ, eq2); tt_int_op(neq1,OP_EQ, neq2); tt_int_op(cmp1,OP_EQ, -cmp2); tt_int_op(eq1,OP_EQ, cmp1 == 0); tt_int_op(neq1,OP_EQ, !eq1); } { uint8_t zz = 0; uint8_t ii = 0; int z; /* exhaustively test tor_memeq and tor_memcmp * against each possible single-byte numeric difference * some arithmetic bugs only appear with certain bit patterns */ for (z = 0; z < 256; z++) { for (i = 0; i < 256; i++) { ii = (uint8_t)i; zz = (uint8_t)z; tt_int_op(tor_memeq(&zz, &ii, 1),OP_EQ, zz == ii); tt_int_op(tor_memcmp(&zz, &ii, 1) > 0 ? GT : EQ,OP_EQ, zz > ii ? GT : EQ); tt_int_op(tor_memcmp(&ii, &zz, 1) < 0 ? LT : EQ,OP_EQ, ii < zz ? LT : EQ); } } } tt_int_op(1, OP_EQ, safe_mem_is_zero("", 0)); tt_int_op(1, OP_EQ, safe_mem_is_zero("", 1)); tt_int_op(0, OP_EQ, safe_mem_is_zero("a", 1)); tt_int_op(0, OP_EQ, safe_mem_is_zero("a", 2)); tt_int_op(0, OP_EQ, safe_mem_is_zero("\0a", 2)); tt_int_op(1, OP_EQ, safe_mem_is_zero("\0\0a", 2)); tt_int_op(1, OP_EQ, safe_mem_is_zero("\0\0\0\0\0\0\0\0", 8)); tt_int_op(1, OP_EQ, safe_mem_is_zero("\0\0\0\0\0\0\0\0a", 8)); tt_int_op(0, OP_EQ, safe_mem_is_zero("\0\0\0\0\0\0\0\0a", 9)); done: ; } static void test_util_di_map(void *arg) { (void)arg; di_digest256_map_t *dimap = NULL; uint8_t key1[] = "Robert Anton Wilson "; uint8_t key2[] = "Martin Gardner, _Fads&fallacies"; uint8_t key3[] = "Tom Lehrer, _Be Prepared_. "; uint8_t key4[] = "Ursula Le Guin,_A Wizard of... "; char dflt_entry[] = "'You have made a good beginning', but no more"; tt_int_op(32, OP_EQ, sizeof(key1)); tt_int_op(32, OP_EQ, sizeof(key2)); tt_int_op(32, OP_EQ, sizeof(key3)); tt_ptr_op(dflt_entry, OP_EQ, dimap_search(dimap, key1, dflt_entry)); char *str1 = tor_strdup("You are precisely as big as what you love" " and precisely as small as what you allow" " to annoy you."); char *str2 = tor_strdup("Let us hope that Lysenko's success in Russia will" " serve for many generations to come as another" " reminder to the world of how quickly and easily" " a science can be corrupted when ignorant" " political leaders deem themselves competent" " to arbitrate scientific disputes"); char *str3 = tor_strdup("Don't write naughty words on walls " "if you can't spell."); dimap_add_entry(&dimap, key1, str1); dimap_add_entry(&dimap, key2, str2); dimap_add_entry(&dimap, key3, str3); tt_ptr_op(str1, OP_EQ, dimap_search(dimap, key1, dflt_entry)); tt_ptr_op(str3, OP_EQ, dimap_search(dimap, key3, dflt_entry)); tt_ptr_op(str2, OP_EQ, dimap_search(dimap, key2, dflt_entry)); tt_ptr_op(dflt_entry, OP_EQ, dimap_search(dimap, key4, dflt_entry)); done: dimap_free(dimap, tor_free_); } /** * Test counting high bits */ static void test_util_n_bits_set(void *ptr) { (void)ptr; tt_int_op(0,OP_EQ, n_bits_set_u8(0)); tt_int_op(1,OP_EQ, n_bits_set_u8(1)); tt_int_op(3,OP_EQ, n_bits_set_u8(7)); tt_int_op(1,OP_EQ, n_bits_set_u8(8)); tt_int_op(2,OP_EQ, n_bits_set_u8(129)); tt_int_op(8,OP_EQ, n_bits_set_u8(255)); done: ; } /** * Test LHS whitespace (and comment) eater */ static void test_util_eat_whitespace(void *ptr) { const char ws[] = { ' ', '\t', '\r' }; /* Except NL */ char str[80]; size_t i; (void)ptr; /* Try one leading ws */ strlcpy(str, "fuubaar", sizeof(str)); for (i = 0; i < sizeof(ws); ++i) { str[0] = ws[i]; tt_ptr_op(str + 1,OP_EQ, eat_whitespace(str)); tt_ptr_op(str + 1,OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str + 1,OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str + 1,OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); } str[0] = '\n'; tt_ptr_op(str + 1,OP_EQ, eat_whitespace(str)); tt_ptr_op(str + 1,OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str,OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str,OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); /* Empty string */ strlcpy(str, "", sizeof(str)); tt_ptr_op(str,OP_EQ, eat_whitespace(str)); tt_ptr_op(str,OP_EQ, eat_whitespace_eos(str, str)); tt_ptr_op(str,OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str,OP_EQ, eat_whitespace_eos_no_nl(str, str)); /* Only ws */ strlcpy(str, " \t\r\n", sizeof(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str + strlen(str) - 1,OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str + strlen(str) - 1,OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); strlcpy(str, " \t\r ", sizeof(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); /* Multiple ws */ strlcpy(str, "fuubaar", sizeof(str)); for (i = 0; i < sizeof(ws); ++i) str[i] = ws[i]; tt_ptr_op(str + sizeof(ws),OP_EQ, eat_whitespace(str)); tt_ptr_op(str + sizeof(ws),OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str + sizeof(ws),OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str + sizeof(ws),OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); /* Eat comment */ strlcpy(str, "# Comment \n No Comment", sizeof(str)); tt_str_op("No Comment",OP_EQ, eat_whitespace(str)); tt_str_op("No Comment",OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str,OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str,OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); /* Eat comment & ws mix */ strlcpy(str, " # \t Comment \n\t\nNo Comment", sizeof(str)); tt_str_op("No Comment",OP_EQ, eat_whitespace(str)); tt_str_op("No Comment",OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str + 1,OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str + 1,OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); /* Eat entire comment */ strlcpy(str, "#Comment", sizeof(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str,OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str,OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); /* Blank line, then comment */ strlcpy(str, " \t\n # Comment", sizeof(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace(str)); tt_ptr_op(str + strlen(str),OP_EQ, eat_whitespace_eos(str, str + strlen(str))); tt_ptr_op(str + 2,OP_EQ, eat_whitespace_no_nl(str)); tt_ptr_op(str + 2,OP_EQ, eat_whitespace_eos_no_nl(str, str + strlen(str))); done: ; } /** Return a newly allocated smartlist containing the lines of text in * lines. The returned strings are heap-allocated, and must be * freed by the caller. * * XXXX? Move to container.[hc] ? */ static smartlist_t * smartlist_new_from_text_lines(const char *lines) { smartlist_t *sl = smartlist_new(); char *last_line; smartlist_split_string(sl, lines, "\n", 0, 0); last_line = smartlist_pop_last(sl); if (last_line != NULL && *last_line != '\0') { smartlist_add(sl, last_line); } else { tor_free(last_line); } return sl; } /** Test smartlist_new_from_text_lines */ static void test_util_sl_new_from_text_lines(void *ptr) { (void)ptr; { /* Normal usage */ smartlist_t *sl = smartlist_new_from_text_lines("foo\nbar\nbaz\n"); int sl_len = smartlist_len(sl); tt_want_int_op(sl_len, OP_EQ, 3); if (sl_len > 0) tt_want_str_op(smartlist_get(sl, 0), OP_EQ, "foo"); if (sl_len > 1) tt_want_str_op(smartlist_get(sl, 1), OP_EQ, "bar"); if (sl_len > 2) tt_want_str_op(smartlist_get(sl, 2), OP_EQ, "baz"); SMARTLIST_FOREACH(sl, void *, x, tor_free(x)); smartlist_free(sl); } { /* No final newline */ smartlist_t *sl = smartlist_new_from_text_lines("foo\nbar\nbaz"); int sl_len = smartlist_len(sl); tt_want_int_op(sl_len, OP_EQ, 3); if (sl_len > 0) tt_want_str_op(smartlist_get(sl, 0), OP_EQ, "foo"); if (sl_len > 1) tt_want_str_op(smartlist_get(sl, 1), OP_EQ, "bar"); if (sl_len > 2) tt_want_str_op(smartlist_get(sl, 2), OP_EQ, "baz"); SMARTLIST_FOREACH(sl, void *, x, tor_free(x)); smartlist_free(sl); } { /* No newlines */ smartlist_t *sl = smartlist_new_from_text_lines("foo"); int sl_len = smartlist_len(sl); tt_want_int_op(sl_len, OP_EQ, 1); if (sl_len > 0) tt_want_str_op(smartlist_get(sl, 0), OP_EQ, "foo"); SMARTLIST_FOREACH(sl, void *, x, tor_free(x)); smartlist_free(sl); } { /* No text at all */ smartlist_t *sl = smartlist_new_from_text_lines(""); int sl_len = smartlist_len(sl); tt_want_int_op(sl_len, OP_EQ, 0); SMARTLIST_FOREACH(sl, void *, x, tor_free(x)); smartlist_free(sl); } } static void test_util_envnames(void *ptr) { (void) ptr; tt_assert(environment_variable_names_equal("abc", "abc")); tt_assert(environment_variable_names_equal("abc", "abc=")); tt_assert(environment_variable_names_equal("abc", "abc=def")); tt_assert(environment_variable_names_equal("abc=def", "abc")); tt_assert(environment_variable_names_equal("abc=def", "abc=ghi")); tt_assert(environment_variable_names_equal("abc", "abc")); tt_assert(environment_variable_names_equal("abc", "abc=")); tt_assert(environment_variable_names_equal("abc", "abc=def")); tt_assert(environment_variable_names_equal("abc=def", "abc")); tt_assert(environment_variable_names_equal("abc=def", "abc=ghi")); tt_assert(!environment_variable_names_equal("abc", "abcd")); tt_assert(!environment_variable_names_equal("abc=", "abcd")); tt_assert(!environment_variable_names_equal("abc=", "abcd")); tt_assert(!environment_variable_names_equal("abc=", "def")); tt_assert(!environment_variable_names_equal("abc=", "def=")); tt_assert(!environment_variable_names_equal("abc=x", "def=x")); tt_assert(!environment_variable_names_equal("", "a=def")); /* A bit surprising. */ tt_assert(environment_variable_names_equal("", "=def")); tt_assert(environment_variable_names_equal("=y", "=x")); done: ; } /** Test process_environment_make */ static void test_util_make_environment(void *ptr) { const char *env_vars_string = "PATH=/bin:/sbin:/usr/bin:/usr/sbin:/usr/local/bin:/usr/local/bin\n" "HOME=/home/foozer\n"; const char expected_windows_env_block[] = "HOME=/home/foozer\000" "PATH=/bin:/sbin:/usr/bin:/usr/sbin:/usr/local/bin:/usr/local/bin\000" "\000"; size_t expected_windows_env_block_len = sizeof(expected_windows_env_block) - 1; smartlist_t *env_vars = smartlist_new_from_text_lines(env_vars_string); smartlist_t *env_vars_sorted = smartlist_new(); smartlist_t *env_vars_in_unixoid_env_block_sorted = smartlist_new(); process_environment_t *env; (void)ptr; env = process_environment_make(env_vars); /* Check that the Windows environment block is correct. */ tt_want(tor_memeq(expected_windows_env_block, env->windows_environment_block, expected_windows_env_block_len)); /* Now for the Unixoid environment block. We don't care which order * these environment variables are in, so we sort both lists first. */ smartlist_add_all(env_vars_sorted, env_vars); { char **v; for (v = env->unixoid_environment_block; *v; ++v) { smartlist_add(env_vars_in_unixoid_env_block_sorted, *v); } } smartlist_sort_strings(env_vars_sorted); smartlist_sort_strings(env_vars_in_unixoid_env_block_sorted); tt_want_int_op(smartlist_len(env_vars_sorted), OP_EQ, smartlist_len(env_vars_in_unixoid_env_block_sorted)); { int len = smartlist_len(env_vars_sorted); int i; if (smartlist_len(env_vars_in_unixoid_env_block_sorted) < len) { len = smartlist_len(env_vars_in_unixoid_env_block_sorted); } for (i = 0; i < len; ++i) { tt_want_str_op(smartlist_get(env_vars_sorted, i), OP_EQ, smartlist_get(env_vars_in_unixoid_env_block_sorted, i)); } } /* Clean up. */ smartlist_free(env_vars_in_unixoid_env_block_sorted); smartlist_free(env_vars_sorted); SMARTLIST_FOREACH(env_vars, char *, x, tor_free(x)); smartlist_free(env_vars); process_environment_free(env); } /** Test set_environment_variable_in_smartlist */ static void test_util_set_env_var_in_sl(void *ptr) { /* The environment variables in these strings are in arbitrary * order; we sort the resulting lists before comparing them. * * (They *will not* end up in the order shown in * expected_resulting_env_vars_string.) */ const char *base_env_vars_string = "PATH=/bin:/sbin:/usr/bin:/usr/sbin:/usr/local/bin:/usr/local/bin\n" "HOME=/home/foozer\n" "TERM=xterm\n" "SHELL=/bin/ksh\n" "USER=foozer\n" "LOGNAME=foozer\n" "USERNAME=foozer\n" "LANG=en_US.utf8\n" ; const char *new_env_vars_string = "TERM=putty\n" "DISPLAY=:18.0\n" ; const char *expected_resulting_env_vars_string = "PATH=/bin:/sbin:/usr/bin:/usr/sbin:/usr/local/bin:/usr/local/bin\n" "HOME=/home/foozer\n" "TERM=putty\n" "SHELL=/bin/ksh\n" "USER=foozer\n" "LOGNAME=foozer\n" "USERNAME=foozer\n" "LANG=en_US.utf8\n" "DISPLAY=:18.0\n" ; smartlist_t *merged_env_vars = smartlist_new_from_text_lines(base_env_vars_string); smartlist_t *new_env_vars = smartlist_new_from_text_lines(new_env_vars_string); smartlist_t *expected_resulting_env_vars = smartlist_new_from_text_lines(expected_resulting_env_vars_string); /* Elements of merged_env_vars are heap-allocated, and must be * freed. Some of them are (or should) be freed by * set_environment_variable_in_smartlist. * * Elements of new_env_vars are heap-allocated, but are copied into * merged_env_vars, so they are not freed separately at the end of * the function. * * Elements of expected_resulting_env_vars are heap-allocated, and * must be freed. */ (void)ptr; SMARTLIST_FOREACH(new_env_vars, char *, env_var, set_environment_variable_in_smartlist(merged_env_vars, env_var, tor_free_, 1)); smartlist_sort_strings(merged_env_vars); smartlist_sort_strings(expected_resulting_env_vars); tt_want_int_op(smartlist_len(merged_env_vars), OP_EQ, smartlist_len(expected_resulting_env_vars)); { int len = smartlist_len(merged_env_vars); int i; if (smartlist_len(expected_resulting_env_vars) < len) { len = smartlist_len(expected_resulting_env_vars); } for (i = 0; i < len; ++i) { tt_want_str_op(smartlist_get(merged_env_vars, i), OP_EQ, smartlist_get(expected_resulting_env_vars, i)); } } /* Clean up. */ SMARTLIST_FOREACH(merged_env_vars, char *, x, tor_free(x)); smartlist_free(merged_env_vars); smartlist_free(new_env_vars); SMARTLIST_FOREACH(expected_resulting_env_vars, char *, x, tor_free(x)); smartlist_free(expected_resulting_env_vars); } static void test_util_weak_random(void *arg) { int i, j, n[16]; tor_weak_rng_t rng; (void) arg; tor_init_weak_random(&rng, (unsigned)time(NULL)); for (i = 1; i <= 256; ++i) { for (j=0;j<100;++j) { int r = tor_weak_random_range(&rng, i); tt_int_op(0, OP_LE, r); tt_int_op(r, OP_LT, i); } } memset(n,0,sizeof(n)); for (j=0;j<8192;++j) { n[tor_weak_random_range(&rng, 16)]++; } for (i=0;i<16;++i) tt_int_op(n[i], OP_GT, 0); done: ; } static void test_util_mathlog(void *arg) { double d; (void) arg; d = tor_mathlog(2.718281828); tt_double_op(fabs(d - 1.0), OP_LT, .000001); d = tor_mathlog(10); tt_double_op(fabs(d - 2.30258509), OP_LT, .000001); done: ; } static void test_util_fraction(void *arg) { uint64_t a,b; (void)arg; a = 99; b = 30; simplify_fraction64(&a,&b); tt_u64_op(a, OP_EQ, 33); tt_u64_op(b, OP_EQ, 10); a = 3000000; b = 10000000; simplify_fraction64(&a,&b); tt_u64_op(a, OP_EQ, 3); tt_u64_op(b, OP_EQ, 10); a = 0; b = 15; simplify_fraction64(&a,&b); tt_u64_op(a, OP_EQ, 0); tt_u64_op(b, OP_EQ, 1); done: ; } static void test_util_round_to_next_multiple_of(void *arg) { (void)arg; tt_u64_op(round_uint64_to_next_multiple_of(0,1), OP_EQ, 0); tt_u64_op(round_uint64_to_next_multiple_of(0,7), OP_EQ, 0); tt_u64_op(round_uint64_to_next_multiple_of(99,1), OP_EQ, 99); tt_u64_op(round_uint64_to_next_multiple_of(99,7), OP_EQ, 105); tt_u64_op(round_uint64_to_next_multiple_of(99,9), OP_EQ, 99); tt_u64_op(round_uint64_to_next_multiple_of(UINT64_MAX,2), OP_EQ, UINT64_MAX); tt_int_op(round_uint32_to_next_multiple_of(0,1), OP_EQ, 0); tt_int_op(round_uint32_to_next_multiple_of(0,7), OP_EQ, 0); tt_int_op(round_uint32_to_next_multiple_of(99,1), OP_EQ, 99); tt_int_op(round_uint32_to_next_multiple_of(99,7), OP_EQ, 105); tt_int_op(round_uint32_to_next_multiple_of(99,9), OP_EQ, 99); tt_int_op(round_uint32_to_next_multiple_of(UINT32_MAX,2), OP_EQ, UINT32_MAX); tt_uint_op(round_to_next_multiple_of(0,1), OP_EQ, 0); tt_uint_op(round_to_next_multiple_of(0,7), OP_EQ, 0); tt_uint_op(round_to_next_multiple_of(99,1), OP_EQ, 99); tt_uint_op(round_to_next_multiple_of(99,7), OP_EQ, 105); tt_uint_op(round_to_next_multiple_of(99,9), OP_EQ, 99); tt_uint_op(round_to_next_multiple_of(UINT_MAX,2), OP_EQ, UINT_MAX); done: ; } static void test_util_laplace(void *arg) { /* Sample values produced using Python's SciPy: * * >>> from scipy.stats import laplace * >>> laplace.ppf([-0.01, 0.0, 0.01, 0.5, 0.51, 0.99, 1.0, 1.01], ... loc = 24, scale = 24) * array([ nan, -inf, -69.88855213, 24. , * 24.48486498, 117.88855213, inf, nan]) */ const double mu = 24.0, b = 24.0; const double delta_f = 15.0, epsilon = 0.3; /* b = 15.0 / 0.3 = 50.0 */ (void)arg; tt_i64_op(INT64_MIN, OP_EQ, sample_laplace_distribution(mu, b, 0.0)); tt_i64_op(-69, OP_EQ, sample_laplace_distribution(mu, b, 0.01)); tt_i64_op(24, OP_EQ, sample_laplace_distribution(mu, b, 0.5)); tt_i64_op(24, OP_EQ, sample_laplace_distribution(mu, b, 0.51)); tt_i64_op(117, OP_EQ, sample_laplace_distribution(mu, b, 0.99)); /* >>> laplace.ppf([0.0, 0.1, 0.25, 0.5, 0.75, 0.9, 0.99], * ... loc = 0, scale = 50) * array([ -inf, -80.47189562, -34.65735903, 0. , * 34.65735903, 80.47189562, 195.60115027]) */ tt_i64_op(INT64_MIN + 20, OP_EQ, add_laplace_noise(20, 0.0, delta_f, epsilon)); tt_i64_op(-60, OP_EQ, add_laplace_noise(20, 0.1, delta_f, epsilon)); tt_i64_op(-14, OP_EQ, add_laplace_noise(20, 0.25, delta_f, epsilon)); tt_i64_op(20, OP_EQ, add_laplace_noise(20, 0.5, delta_f, epsilon)); tt_i64_op(54, OP_EQ, add_laplace_noise(20, 0.75, delta_f, epsilon)); tt_i64_op(100, OP_EQ, add_laplace_noise(20, 0.9, delta_f, epsilon)); tt_i64_op(215, OP_EQ, add_laplace_noise(20, 0.99, delta_f, epsilon)); /* Test extreme values of signal with maximally negative values of noise * 1.0000000000000002 is the smallest number > 1 * 0.0000000000000002 is the double epsilon (error when calculating near 1) * this is approximately 1/(2^52) * per https://en.wikipedia.org/wiki/Double_precision * (let's not descend into the world of subnormals) * >>> laplace.ppf([0, 0.0000000000000002], loc = 0, scale = 1) * array([ -inf, -35.45506713]) */ const double noscale_df = 1.0, noscale_eps = 1.0; tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(0, 0.0, noscale_df, noscale_eps)); /* is it clipped to INT64_MIN? */ tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(-1, 0.0, noscale_df, noscale_eps)); tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(INT64_MIN, 0.0, noscale_df, noscale_eps)); /* ... even when scaled? */ tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(0, 0.0, delta_f, epsilon)); tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(0, 0.0, DBL_MAX, 1)); tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(INT64_MIN, 0.0, DBL_MAX, 1)); /* does it play nice with INT64_MAX? */ tt_i64_op((INT64_MIN + INT64_MAX), OP_EQ, add_laplace_noise(INT64_MAX, 0.0, noscale_df, noscale_eps)); /* do near-zero fractional values work? */ const double min_dbl_error = 0.0000000000000002; tt_i64_op(-35, OP_EQ, add_laplace_noise(0, min_dbl_error, noscale_df, noscale_eps)); tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(INT64_MIN, min_dbl_error, noscale_df, noscale_eps)); tt_i64_op((-35 + INT64_MAX), OP_EQ, add_laplace_noise(INT64_MAX, min_dbl_error, noscale_df, noscale_eps)); tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(0, min_dbl_error, DBL_MAX, 1)); tt_i64_op((INT64_MAX + INT64_MIN), OP_EQ, add_laplace_noise(INT64_MAX, min_dbl_error, DBL_MAX, 1)); tt_i64_op(INT64_MIN, OP_EQ, add_laplace_noise(INT64_MIN, min_dbl_error, DBL_MAX, 1)); /* does it play nice with INT64_MAX? */ tt_i64_op((INT64_MAX - 35), OP_EQ, add_laplace_noise(INT64_MAX, min_dbl_error, noscale_df, noscale_eps)); /* Test extreme values of signal with maximally positive values of noise * 1.0000000000000002 is the smallest number > 1 * 0.9999999999999998 is the greatest number < 1 by calculation * per https://en.wikipedia.org/wiki/Double_precision * >>> laplace.ppf([1.0, 0.9999999999999998], loc = 0, scale = 1) * array([inf, 35.35050621]) * but the function rejects p == 1.0, so we just use max_dbl_lt_one */ const double max_dbl_lt_one = 0.9999999999999998; /* do near-one fractional values work? */ tt_i64_op(35, OP_EQ, add_laplace_noise(0, max_dbl_lt_one, noscale_df, noscale_eps)); /* is it clipped to INT64_MAX? */ tt_i64_op(INT64_MAX, OP_EQ, add_laplace_noise(INT64_MAX - 35, max_dbl_lt_one, noscale_df, noscale_eps)); tt_i64_op(INT64_MAX, OP_EQ, add_laplace_noise(INT64_MAX - 34, max_dbl_lt_one, noscale_df, noscale_eps)); tt_i64_op(INT64_MAX, OP_EQ, add_laplace_noise(INT64_MAX, max_dbl_lt_one, noscale_df, noscale_eps)); /* ... even when scaled? */ tt_i64_op(INT64_MAX, OP_EQ, add_laplace_noise(INT64_MAX, max_dbl_lt_one, delta_f, epsilon)); tt_i64_op((INT64_MIN + INT64_MAX), OP_EQ, add_laplace_noise(INT64_MIN, max_dbl_lt_one, DBL_MAX, 1)); tt_i64_op(INT64_MAX, OP_EQ, add_laplace_noise(INT64_MAX, max_dbl_lt_one, DBL_MAX, 1)); /* does it play nice with INT64_MIN? */ tt_i64_op((INT64_MIN + 35), OP_EQ, add_laplace_noise(INT64_MIN, max_dbl_lt_one, noscale_df, noscale_eps)); done: ; } static void test_util_clamp_double_to_int64(void *arg) { (void)arg; tt_i64_op(INT64_MIN, OP_EQ, clamp_double_to_int64(-INFINITY_DBL)); tt_i64_op(INT64_MIN, OP_EQ, clamp_double_to_int64(-1.0 * pow(2.0, 64.0) - 1.0)); tt_i64_op(INT64_MIN, OP_EQ, clamp_double_to_int64(-1.0 * pow(2.0, 63.0) - 1.0)); tt_i64_op(((uint64_t) -1) << 53, OP_EQ, clamp_double_to_int64(-1.0 * pow(2.0, 53.0))); tt_i64_op((((uint64_t) -1) << 53) + 1, OP_EQ, clamp_double_to_int64(-1.0 * pow(2.0, 53.0) + 1.0)); tt_i64_op(-1, OP_EQ, clamp_double_to_int64(-1.0)); tt_i64_op(0, OP_EQ, clamp_double_to_int64(-0.9)); tt_i64_op(0, OP_EQ, clamp_double_to_int64(-0.1)); tt_i64_op(0, OP_EQ, clamp_double_to_int64(0.0)); tt_i64_op(0, OP_EQ, clamp_double_to_int64(NAN_DBL)); tt_i64_op(0, OP_EQ, clamp_double_to_int64(0.1)); tt_i64_op(0, OP_EQ, clamp_double_to_int64(0.9)); tt_i64_op(1, OP_EQ, clamp_double_to_int64(1.0)); tt_i64_op((((int64_t) 1) << 53) - 1, OP_EQ, clamp_double_to_int64(pow(2.0, 53.0) - 1.0)); tt_i64_op(((int64_t) 1) << 53, OP_EQ, clamp_double_to_int64(pow(2.0, 53.0))); tt_i64_op(INT64_MAX, OP_EQ, clamp_double_to_int64(pow(2.0, 63.0))); tt_i64_op(INT64_MAX, OP_EQ, clamp_double_to_int64(pow(2.0, 64.0))); tt_i64_op(INT64_MAX, OP_EQ, clamp_double_to_int64(INFINITY_DBL)); done: ; } #ifdef FD_CLOEXEC #define CAN_CHECK_CLOEXEC static int fd_is_cloexec(tor_socket_t fd) { int flags = fcntl(fd, F_GETFD, 0); return (flags & FD_CLOEXEC) == FD_CLOEXEC; } #endif /* defined(FD_CLOEXEC) */ #ifndef _WIN32 #define CAN_CHECK_NONBLOCK static int fd_is_nonblocking(tor_socket_t fd) { int flags = fcntl(fd, F_GETFL, 0); return (flags & O_NONBLOCK) == O_NONBLOCK; } #endif /* !defined(_WIN32) */ #define ERRNO_IS_EPROTO(e) (e == SOCK_ERRNO(EPROTONOSUPPORT)) #define SOCK_ERR_IS_EPROTO(s) ERRNO_IS_EPROTO(tor_socket_errno(s)) /* Test for tor_open_socket*, using IPv4 or IPv6 depending on arg. */ static void test_util_socket(void *arg) { const int domain = !strcmp(arg, "4") ? AF_INET : AF_INET6; tor_socket_t fd1 = TOR_INVALID_SOCKET; tor_socket_t fd2 = TOR_INVALID_SOCKET; tor_socket_t fd3 = TOR_INVALID_SOCKET; tor_socket_t fd4 = TOR_INVALID_SOCKET; int n = get_n_open_sockets(); TT_BLATHER(("Starting with %d open sockets.", n)); (void)arg; fd1 = tor_open_socket_with_extensions(domain, SOCK_STREAM, 0, 0, 0); int err = tor_socket_errno(fd1); if (fd1 < 0 && (err == SOCK_ERRNO(EPROTONOSUPPORT) || err == SOCK_ERRNO(EAFNOSUPPORT))) { /* Assume we're on an IPv4-only or IPv6-only system, and give up now. */ goto done; } fd2 = tor_open_socket_with_extensions(domain, SOCK_STREAM, 0, 0, 1); tt_assert(SOCKET_OK(fd1)); tt_assert(SOCKET_OK(fd2)); tt_int_op(get_n_open_sockets(), OP_EQ, n + 2); //fd3 = tor_open_socket_with_extensions(domain, SOCK_STREAM, 0, 1, 0); //fd4 = tor_open_socket_with_extensions(domain, SOCK_STREAM, 0, 1, 1); fd3 = tor_open_socket(domain, SOCK_STREAM, 0); fd4 = tor_open_socket_nonblocking(domain, SOCK_STREAM, 0); tt_assert(SOCKET_OK(fd3)); tt_assert(SOCKET_OK(fd4)); tt_int_op(get_n_open_sockets(), OP_EQ, n + 4); #ifdef CAN_CHECK_CLOEXEC tt_int_op(fd_is_cloexec(fd1), OP_EQ, 0); tt_int_op(fd_is_cloexec(fd2), OP_EQ, 0); tt_int_op(fd_is_cloexec(fd3), OP_EQ, 1); tt_int_op(fd_is_cloexec(fd4), OP_EQ, 1); #endif /* defined(CAN_CHECK_CLOEXEC) */ #ifdef CAN_CHECK_NONBLOCK tt_int_op(fd_is_nonblocking(fd1), OP_EQ, 0); tt_int_op(fd_is_nonblocking(fd2), OP_EQ, 1); tt_int_op(fd_is_nonblocking(fd3), OP_EQ, 0); tt_int_op(fd_is_nonblocking(fd4), OP_EQ, 1); #endif /* defined(CAN_CHECK_NONBLOCK) */ tor_assert(tor_close_socket == tor_close_socket__real); /* we use close_socket__real here so that coverity can tell that we are * really closing these sockets. */ tor_close_socket__real(fd1); tor_close_socket__real(fd2); fd1 = fd2 = TOR_INVALID_SOCKET; tt_int_op(get_n_open_sockets(), OP_EQ, n + 2); tor_close_socket__real(fd3); tor_close_socket__real(fd4); fd3 = fd4 = TOR_INVALID_SOCKET; tt_int_op(get_n_open_sockets(), OP_EQ, n); done: if (SOCKET_OK(fd1)) tor_close_socket__real(fd1); if (SOCKET_OK(fd2)) tor_close_socket__real(fd2); if (SOCKET_OK(fd3)) tor_close_socket__real(fd3); if (SOCKET_OK(fd4)) tor_close_socket__real(fd4); } #if 0 static int is_there_a_localhost(int family) { tor_socket_t s; s = tor_open_socket(family, SOCK_STREAM, IPPROTO_TCP); tor_assert(SOCKET_OK(s)); int result = 0; if (family == AF_INET) { struct sockaddr_in s_in; memset(&s_in, 0, sizeof(s_in)); s_in.sin_family = AF_INET; s_in.sin_addr.s_addr = htonl(0x7f000001); s_in.sin_port = 0; if (bind(s, (void*)&s_in, sizeof(s_in)) == 0) { result = 1; } } else if (family == AF_INET6) { struct sockaddr_in6 sin6; memset(&sin6, 0, sizeof(sin6)); sin6.sin6_family = AF_INET6; sin6.sin6_addr.s6_addr[15] = 1; sin6.sin6_port = 0; } tor_close_socket(s); return result; } #endif /* 0 */ /* Test for socketpair and ersatz_socketpair(). We test them both, since * the latter is a tolerably good way to exercise tor_accept_socket(). */ static void test_util_socketpair(void *arg) { const int ersatz = !strcmp(arg, "1"); int (*const tor_socketpair_fn)(int, int, int, tor_socket_t[2]) = ersatz ? tor_ersatz_socketpair : tor_socketpair; int n = get_n_open_sockets(); tor_socket_t fds[2] = {TOR_INVALID_SOCKET, TOR_INVALID_SOCKET}; const int family = AF_UNIX; int socketpair_result = 0; socketpair_result = tor_socketpair_fn(family, SOCK_STREAM, 0, fds); #ifdef __FreeBSD__ /* If there is no 127.0.0.1, tor_ersatz_socketpair will and must fail. * Otherwise, we risk exposing a socketpair on a routable IP address. (Some * BSD jails use a routable address for localhost. Fortunately, they have * the real AF_UNIX socketpair.) */ if (ersatz && socketpair_result < 0) { /* In my testing, an IPv6-only FreeBSD jail without ::1 returned EINVAL. * Assume we're on a machine without 127.0.0.1 or ::1 and give up now. */ tt_skip(); } #endif /* defined(__FreeBSD__) */ tt_int_op(0, OP_EQ, socketpair_result); tt_assert(SOCKET_OK(fds[0])); tt_assert(SOCKET_OK(fds[1])); if (ersatz) tt_int_op(get_n_open_sockets(), OP_EQ, n); else tt_int_op(get_n_open_sockets(), OP_EQ, n + 2); #ifdef CAN_CHECK_CLOEXEC tt_int_op(fd_is_cloexec(fds[0]), OP_EQ, !ersatz); tt_int_op(fd_is_cloexec(fds[1]), OP_EQ, !ersatz); #endif #ifdef CAN_CHECK_NONBLOCK tt_int_op(fd_is_nonblocking(fds[0]), OP_EQ, 0); tt_int_op(fd_is_nonblocking(fds[1]), OP_EQ, 0); #endif done: if (ersatz) { if (SOCKET_OK(fds[0])) tor_close_socket_simple(fds[0]); if (SOCKET_OK(fds[1])) tor_close_socket_simple(fds[1]); } else { if (SOCKET_OK(fds[0])) tor_close_socket(fds[0]); if (SOCKET_OK(fds[1])) tor_close_socket(fds[1]); } } #undef SOCKET_EPROTO static void test_util_max_mem(void *arg) { size_t memory1, memory2; int r, r2; (void) arg; r = get_total_system_memory(&memory1); r2 = get_total_system_memory(&memory2); tt_int_op(r, OP_EQ, r2); tt_uint_op(memory2, OP_EQ, memory1); TT_BLATHER(("System memory: %"TOR_PRIuSZ, (memory1))); if (r==0) { /* You have at least a megabyte. */ tt_uint_op(memory1, OP_GT, (1<<20)); } else { /* You do not have a petabyte. */ #if SIZEOF_SIZE_T >= 8 tt_u64_op(memory1, OP_LT, (UINT64_C(1)<<50)); #endif } done: ; } static void test_util_dest_validation_edgecase(void *arg) { (void)arg; tt_assert(!string_is_valid_dest(NULL)); tt_assert(!string_is_valid_dest("")); done: return; } static void test_util_hostname_validation(void *arg) { (void)arg; // Lets try valid hostnames first. tt_assert(string_is_valid_nonrfc_hostname("torproject.org")); tt_assert(string_is_valid_nonrfc_hostname("ocw.mit.edu")); tt_assert(string_is_valid_nonrfc_hostname("i.4cdn.org")); tt_assert(string_is_valid_nonrfc_hostname("stanford.edu")); tt_assert(string_is_valid_nonrfc_hostname("multiple-words-with-hypens.jp")); // Subdomain name cannot start with '-' or '_'. tt_assert(!string_is_valid_nonrfc_hostname("-torproject.org")); tt_assert(!string_is_valid_nonrfc_hostname("subdomain.-domain.org")); tt_assert(!string_is_valid_nonrfc_hostname("-subdomain.domain.org")); tt_assert(!string_is_valid_nonrfc_hostname("___abc.org")); // Hostnames cannot contain non-alphanumeric characters. tt_assert(!string_is_valid_nonrfc_hostname("%%domain.\\org.")); tt_assert(!string_is_valid_nonrfc_hostname("***x.net")); tt_assert(!string_is_valid_nonrfc_hostname("\xff\xffxyz.org")); tt_assert(!string_is_valid_nonrfc_hostname("word1 word2.net")); // Test workaround for nytimes.com stupidity, technically invalid, // but we allow it since they are big, even though they are failing to // comply with a ~30 year old standard. tt_assert(string_is_valid_nonrfc_hostname("core3_euw1.fabrik.nytimes.com")); // Firefox passes FQDNs with trailing '.'s directly to the SOCKS proxy, // which is redundant since the spec states DOMAINNAME addresses are fully // qualified. While unusual, this should be tollerated. tt_assert(string_is_valid_nonrfc_hostname("core9_euw1.fabrik.nytimes.com.")); tt_assert(!string_is_valid_nonrfc_hostname( "..washingtonpost.is.better.com")); tt_assert(!string_is_valid_nonrfc_hostname("so.is..ft.com")); tt_assert(!string_is_valid_nonrfc_hostname("...")); // XXX: do we allow single-label DNS names? // We shouldn't for SOCKS (spec says "contains a fully-qualified domain name" // but only test pathologically malformed traling '.' cases for now. tt_assert(!string_is_valid_nonrfc_hostname(".")); tt_assert(!string_is_valid_nonrfc_hostname("..")); // IP address strings are not hostnames. tt_assert(!string_is_valid_nonrfc_hostname("8.8.8.8")); tt_assert(!string_is_valid_nonrfc_hostname("[2a00:1450:401b:800::200e]")); tt_assert(!string_is_valid_nonrfc_hostname("2a00:1450:401b:800::200e")); // We allow alphanumeric TLDs. For discussion, see ticket #25055. tt_assert(string_is_valid_nonrfc_hostname("lucky.13")); tt_assert(string_is_valid_nonrfc_hostname("luck.y13")); tt_assert(string_is_valid_nonrfc_hostname("luck.y13.")); // We allow punycode TLDs. For examples, see // http://data.iana.org/TLD/tlds-alpha-by-domain.txt tt_assert(string_is_valid_nonrfc_hostname("example.xn--l1acc")); done: return; } static void test_util_ipv4_validation(void *arg) { (void)arg; tt_assert(string_is_valid_ipv4_address("192.168.0.1")); tt_assert(string_is_valid_ipv4_address("8.8.8.8")); tt_assert(!string_is_valid_ipv4_address("abcd")); tt_assert(!string_is_valid_ipv4_address("300.300.300.300")); tt_assert(!string_is_valid_ipv4_address("8.8.")); done: return; } static void test_util_writepid(void *arg) { (void) arg; char *contents = NULL; const char *fname = get_fname("tmp_pid"); unsigned long pid; char c; write_pidfile(fname); contents = read_file_to_str(fname, 0, NULL); tt_assert(contents); int n = tor_sscanf(contents, "%lu\n%c", &pid, &c); tt_int_op(n, OP_EQ, 1); #ifdef _WIN32 tt_uint_op(pid, OP_EQ, _getpid()); #else tt_uint_op(pid, OP_EQ, getpid()); #endif done: tor_free(contents); } static void test_util_get_avail_disk_space(void *arg) { (void) arg; int64_t val; /* No answer for nonexistent directory */ val = tor_get_avail_disk_space("/akljasdfklsajdklasjkldjsa"); tt_i64_op(val, OP_EQ, -1); /* Try the current directory */ val = tor_get_avail_disk_space("."); #if !defined(HAVE_STATVFS) && !defined(_WIN32) tt_i64_op(val, OP_EQ, -1); /* You don't have an implementation for this */ #else tt_i64_op(val, OP_GT, 0); /* You have some space. */ tt_i64_op(val, OP_LT, ((int64_t)1)<<56); /* You don't have a zebibyte */ #endif /* !defined(HAVE_STATVFS) && !defined(_WIN32) */ done: ; } static void test_util_touch_file(void *arg) { (void) arg; const char *fname = get_fname("touch"); const time_t now = time(NULL); struct stat st; write_bytes_to_file(fname, "abc", 3, 1); tt_int_op(0, OP_EQ, stat(fname, &st)); /* A subtle point: the filesystem time is not necessarily equal to the * system clock time, since one can be using a monotonic clock, or coarse * monotonic clock, or whatever. So we might wind up with an mtime a few * microseconds ago. Let's just give it a lot of wiggle room. */ tt_i64_op(st.st_mtime, OP_GE, now - 1); const time_t five_sec_ago = now - 5; struct utimbuf u = { five_sec_ago, five_sec_ago }; tt_int_op(0, OP_EQ, utime(fname, &u)); tt_int_op(0, OP_EQ, stat(fname, &st)); /* Let's hope that utime/stat give the same second as a round-trip? */ tt_i64_op(st.st_mtime, OP_EQ, five_sec_ago); /* Finally we can touch the file */ tt_int_op(0, OP_EQ, touch_file(fname)); tt_int_op(0, OP_EQ, stat(fname, &st)); tt_i64_op(st.st_mtime, OP_GE, now-1); done: ; } #ifndef _WIN32 static void test_util_pwdb(void *arg) { (void) arg; const struct passwd *me = NULL, *me2, *me3; char *name = NULL; char *dir = NULL; /* Uncached case. */ /* Let's assume that we exist. */ me = tor_getpwuid(getuid()); tt_ptr_op(me, OP_NE, NULL); name = tor_strdup(me->pw_name); /* Uncached case */ me2 = tor_getpwnam(name); tt_ptr_op(me2, OP_NE, NULL); tt_int_op(me2->pw_uid, OP_EQ, getuid()); /* Cached case */ me3 = tor_getpwuid(getuid()); tt_ptr_op(me3, OP_NE, NULL); tt_str_op(me3->pw_name, OP_EQ, name); me3 = tor_getpwnam(name); tt_ptr_op(me3, OP_NE, NULL); tt_int_op(me3->pw_uid, OP_EQ, getuid()); dir = get_user_homedir(name); tt_ptr_op(dir, OP_NE, NULL); /* Try failing cases. First find a user that doesn't exist by name */ char randbytes[4]; char badname[9]; int i, found=0; for (i = 0; i < 100; ++i) { crypto_rand(randbytes, sizeof(randbytes)); base16_encode(badname, sizeof(badname), randbytes, sizeof(randbytes)); if (tor_getpwnam(badname) == NULL) { found = 1; break; } } tt_assert(found); tor_free(dir); /* We should do a LOG_ERR */ setup_full_capture_of_logs(LOG_ERR); dir = get_user_homedir(badname); tt_ptr_op(dir, OP_EQ, NULL); expect_log_msg_containing("not found"); tt_int_op(smartlist_len(mock_saved_logs()), OP_EQ, 1); teardown_capture_of_logs(); /* Now try to find a user that doesn't exist by ID. */ found = 0; for (i = 0; i < 1000; ++i) { uid_t u; crypto_rand((char*)&u, sizeof(u)); if (tor_getpwuid(u) == NULL) { found = 1; break; } } tt_assert(found); done: tor_free(name); tor_free(dir); teardown_capture_of_logs(); } #endif /* !defined(_WIN32) */ static void test_util_calloc_check(void *arg) { (void) arg; /* Easy cases that are good. */ tt_assert(size_mul_check(0,0)); tt_assert(size_mul_check(0,100)); tt_assert(size_mul_check(100,0)); tt_assert(size_mul_check(100,100)); /* Harder cases that are still good. */ tt_assert(size_mul_check(SIZE_MAX, 1)); tt_assert(size_mul_check(1, SIZE_MAX)); tt_assert(size_mul_check(SIZE_MAX / 10, 9)); tt_assert(size_mul_check(11, SIZE_MAX / 12)); const size_t sqrt_size_max_p1 = ((size_t)1) << (sizeof(size_t) * 4); tt_assert(size_mul_check(sqrt_size_max_p1, sqrt_size_max_p1 - 1)); /* Cases that overflow */ tt_assert(! size_mul_check(SIZE_MAX, 2)); tt_assert(! size_mul_check(2, SIZE_MAX)); tt_assert(! size_mul_check(SIZE_MAX / 10, 11)); tt_assert(! size_mul_check(11, SIZE_MAX / 10)); tt_assert(! size_mul_check(SIZE_MAX / 8, 9)); tt_assert(! size_mul_check(sqrt_size_max_p1, sqrt_size_max_p1)); done: ; } static void test_util_monotonic_time(void *arg) { (void)arg; monotime_t mt1, mt2; monotime_coarse_t mtc1, mtc2; uint64_t nsec1, nsec2, usec1, msec1; uint64_t nsecc1, nsecc2, usecc1, msecc1; uint32_t stamp1, stamp2; monotime_init(); monotime_get(&mt1); monotime_coarse_get(&mtc1); nsec1 = monotime_absolute_nsec(); usec1 = monotime_absolute_usec(); msec1 = monotime_absolute_msec(); nsecc1 = monotime_coarse_absolute_nsec(); usecc1 = monotime_coarse_absolute_usec(); msecc1 = monotime_coarse_absolute_msec(); stamp1 = monotime_coarse_to_stamp(&mtc1); tor_sleep_msec(200); monotime_get(&mt2); monotime_coarse_get(&mtc2); nsec2 = monotime_absolute_nsec(); nsecc2 = monotime_coarse_absolute_nsec(); stamp2 = monotime_coarse_to_stamp(&mtc2); /* We need to be a little careful here since we don't know the system load. */ tt_i64_op(monotime_diff_msec(&mt1, &mt2), OP_GE, 175); tt_i64_op(monotime_diff_msec(&mt1, &mt2), OP_LT, 1000); tt_i64_op(monotime_coarse_diff_msec(&mtc1, &mtc2), OP_GE, 125); tt_i64_op(monotime_coarse_diff_msec(&mtc1, &mtc2), OP_LT, 1000); tt_u64_op(nsec2-nsec1, OP_GE, 175000000); tt_u64_op(nsec2-nsec1, OP_LT, 1000000000); tt_u64_op(nsecc2-nsecc1, OP_GE, 125000000); tt_u64_op(nsecc2-nsecc1, OP_LT, 1000000000); tt_u64_op(msec1, OP_GE, nsec1 / 1000000); tt_u64_op(usec1, OP_GE, nsec1 / 1000); tt_u64_op(msecc1, OP_GE, nsecc1 / 1000000); tt_u64_op(usecc1, OP_GE, nsecc1 / 1000); tt_u64_op(msec1, OP_LE, nsec1 / 1000000 + 10); tt_u64_op(usec1, OP_LE, nsec1 / 1000 + 10000); tt_u64_op(msecc1, OP_LE, nsecc1 / 1000000 + 10); tt_u64_op(usecc1, OP_LE, nsecc1 / 1000 + 10000); uint64_t coarse_stamp_diff = monotime_coarse_stamp_units_to_approx_msec(stamp2-stamp1); tt_u64_op(coarse_stamp_diff, OP_GE, 120); tt_u64_op(coarse_stamp_diff, OP_LE, 1200); { uint64_t units = monotime_msec_to_approx_coarse_stamp_units(5000); uint64_t ms = monotime_coarse_stamp_units_to_approx_msec(units); tt_u64_op(ms, OP_GE, 4950); tt_u64_op(ms, OP_LT, 5050); } done: ; } static void test_util_monotonic_time_ratchet(void *arg) { (void)arg; monotime_init(); monotime_reset_ratchets_for_testing(); /* win32, performance counter ratchet. */ tt_i64_op(100, OP_EQ, ratchet_performance_counter(100)); tt_i64_op(101, OP_EQ, ratchet_performance_counter(101)); tt_i64_op(2000, OP_EQ, ratchet_performance_counter(2000)); tt_i64_op(2000, OP_EQ, ratchet_performance_counter(100)); tt_i64_op(2005, OP_EQ, ratchet_performance_counter(105)); tt_i64_op(3005, OP_EQ, ratchet_performance_counter(1105)); tt_i64_op(3005, OP_EQ, ratchet_performance_counter(1000)); tt_i64_op(3010, OP_EQ, ratchet_performance_counter(1005)); /* win32, GetTickCounts32 ratchet-and-rollover-detector. */ const int64_t R = ((int64_t)1) << 32; tt_i64_op(5, OP_EQ, ratchet_coarse_performance_counter(5)); tt_i64_op(1000, OP_EQ, ratchet_coarse_performance_counter(1000)); tt_i64_op(5+R, OP_EQ, ratchet_coarse_performance_counter(5)); tt_i64_op(10+R, OP_EQ, ratchet_coarse_performance_counter(10)); tt_i64_op(4+R*2, OP_EQ, ratchet_coarse_performance_counter(4)); /* gettimeofday regular ratchet. */ struct timeval tv_in = {0,0}, tv_out; tv_in.tv_usec = 9000; ratchet_timeval(&tv_in, &tv_out); tt_int_op(tv_out.tv_usec, OP_EQ, 9000); tt_i64_op(tv_out.tv_sec, OP_EQ, 0); tv_in.tv_sec = 1337; tv_in.tv_usec = 0; ratchet_timeval(&tv_in, &tv_out); tt_int_op(tv_out.tv_usec, OP_EQ, 0); tt_i64_op(tv_out.tv_sec, OP_EQ, 1337); tv_in.tv_sec = 1336; tv_in.tv_usec = 500000; ratchet_timeval(&tv_in, &tv_out); tt_int_op(tv_out.tv_usec, OP_EQ, 0); tt_i64_op(tv_out.tv_sec, OP_EQ, 1337); tv_in.tv_sec = 1337; tv_in.tv_usec = 0; ratchet_timeval(&tv_in, &tv_out); tt_int_op(tv_out.tv_usec, OP_EQ, 500000); tt_i64_op(tv_out.tv_sec, OP_EQ, 1337); tv_in.tv_sec = 1337; tv_in.tv_usec = 600000; ratchet_timeval(&tv_in, &tv_out); tt_int_op(tv_out.tv_usec, OP_EQ, 100000); tt_i64_op(tv_out.tv_sec, OP_EQ, 1338); tv_in.tv_sec = 1000; tv_in.tv_usec = 1000; ratchet_timeval(&tv_in, &tv_out); tt_int_op(tv_out.tv_usec, OP_EQ, 100000); tt_i64_op(tv_out.tv_sec, OP_EQ, 1338); tv_in.tv_sec = 2000; tv_in.tv_usec = 2000; ratchet_timeval(&tv_in, &tv_out); tt_int_op(tv_out.tv_usec, OP_EQ, 101000); tt_i64_op(tv_out.tv_sec, OP_EQ, 2338); done: ; } static void test_util_monotonic_time_zero(void *arg) { (void) arg; monotime_t t1; monotime_coarse_t ct1; monotime_init(); /* Check 1: The current time is not zero. */ monotime_get(&t1); monotime_coarse_get(&ct1); tt_assert(!monotime_is_zero(&t1)); tt_assert(!monotime_coarse_is_zero(&ct1)); /* Check 2: The _zero() makes the time zero. */ monotime_zero(&t1); monotime_coarse_zero(&ct1); tt_assert(monotime_is_zero(&t1)); tt_assert(monotime_coarse_is_zero(&ct1)); done: ; } static void test_util_monotonic_time_add_msec(void *arg) { (void) arg; monotime_t t1, t2; monotime_coarse_t ct1, ct2; monotime_init(); monotime_get(&t1); monotime_coarse_get(&ct1); /* adding zero does nothing */ monotime_add_msec(&t2, &t1, 0); monotime_coarse_add_msec(&ct2, &ct1, 0); tt_i64_op(monotime_diff_msec(&t1, &t2), OP_EQ, 0); tt_i64_op(monotime_coarse_diff_msec(&ct1, &ct2), OP_EQ, 0); /* Add 1337 msec; see if the diff function agree */ monotime_add_msec(&t2, &t1, 1337); monotime_coarse_add_msec(&ct2, &ct1, 1337); tt_i64_op(monotime_diff_msec(&t1, &t2), OP_EQ, 1337); tt_i64_op(monotime_coarse_diff_msec(&ct1, &ct2), OP_EQ, 1337); // The 32-bit variant must be within 1% of the regular one. tt_int_op(monotime_coarse_diff_msec32_(&ct1, &ct2), OP_GT, 1323); tt_int_op(monotime_coarse_diff_msec32_(&ct1, &ct2), OP_LT, 1350); /* Add 1337 msec twice more; make sure that any second rollover issues * worked. */ monotime_add_msec(&t2, &t2, 1337); monotime_coarse_add_msec(&ct2, &ct2, 1337); monotime_add_msec(&t2, &t2, 1337); monotime_coarse_add_msec(&ct2, &ct2, 1337); tt_i64_op(monotime_diff_msec(&t1, &t2), OP_EQ, 1337*3); tt_i64_op(monotime_coarse_diff_msec(&ct1, &ct2), OP_EQ, 1337*3); tt_int_op(monotime_coarse_diff_msec32_(&ct1, &ct2), OP_GT, 3970); tt_int_op(monotime_coarse_diff_msec32_(&ct1, &ct2), OP_LT, 4051); done: ; } static void test_util_nowrap_math(void *arg) { (void)arg; tt_u64_op(0, OP_EQ, tor_add_u32_nowrap(0, 0)); tt_u64_op(1, OP_EQ, tor_add_u32_nowrap(0, 1)); tt_u64_op(1, OP_EQ, tor_add_u32_nowrap(1, 0)); tt_u64_op(4, OP_EQ, tor_add_u32_nowrap(2, 2)); tt_u64_op(UINT32_MAX, OP_EQ, tor_add_u32_nowrap(UINT32_MAX-1, 2)); tt_u64_op(UINT32_MAX, OP_EQ, tor_add_u32_nowrap(2, UINT32_MAX-1)); tt_u64_op(UINT32_MAX, OP_EQ, tor_add_u32_nowrap(UINT32_MAX, UINT32_MAX)); done: ; } static void test_util_htonll(void *arg) { (void)arg; #ifdef WORDS_BIGENDIAN const uint64_t res_be = 0x8877665544332211; #else const uint64_t res_le = 0x1122334455667788; #endif tt_u64_op(0, OP_EQ, tor_htonll(0)); tt_u64_op(0, OP_EQ, tor_ntohll(0)); tt_u64_op(UINT64_MAX, OP_EQ, tor_htonll(UINT64_MAX)); tt_u64_op(UINT64_MAX, OP_EQ, tor_ntohll(UINT64_MAX)); #ifdef WORDS_BIGENDIAN tt_u64_op(res_be, OP_EQ, tor_htonll(0x8877665544332211)); tt_u64_op(res_be, OP_EQ, tor_ntohll(0x8877665544332211)); #else tt_u64_op(res_le, OP_EQ, tor_htonll(0x8877665544332211)); tt_u64_op(res_le, OP_EQ, tor_ntohll(0x8877665544332211)); #endif /* defined(WORDS_BIGENDIAN) */ done: ; } static void test_util_get_unquoted_path(void *arg) { (void)arg; char *r = NULL; r = get_unquoted_path("\""); // " tt_ptr_op(r, OP_EQ, NULL); tor_free(r); r = get_unquoted_path("\"\"\""); // """ tt_ptr_op(r, OP_EQ, NULL); tor_free(r); r = get_unquoted_path("\\\""); // \" tt_ptr_op(r, OP_EQ, NULL); tor_free(r); r = get_unquoted_path("\\\"\\\""); // \"\" tt_ptr_op(r, OP_EQ, NULL); tor_free(r); r = get_unquoted_path("A\\B\\C\""); // A\B\C" tt_ptr_op(r, OP_EQ, NULL); tor_free(r); r = get_unquoted_path("\"A\\B\\C"); // "A\B\C tt_ptr_op(r, OP_EQ, NULL); tor_free(r); r = get_unquoted_path("\"A\\B\"C\""); // "A\B"C" tt_ptr_op(r, OP_EQ, NULL); tor_free(r); r = get_unquoted_path("A\\B\"C"); // A\B"C tt_ptr_op(r, OP_EQ, NULL); tor_free(r); r = get_unquoted_path(""); tt_str_op(r, OP_EQ, ""); tor_free(r); r = get_unquoted_path("\"\""); // "" tt_str_op(r, OP_EQ, ""); tor_free(r); r = get_unquoted_path("A\\B\\C"); // A\B\C tt_str_op(r, OP_EQ, "A\\B\\C"); // A\B\C tor_free(r); r = get_unquoted_path("\"A\\B\\C\""); // "A\B\C" tt_str_op(r, OP_EQ, "A\\B\\C"); // A\B\C tor_free(r); r = get_unquoted_path("\"\\\""); // "\" tt_str_op(r, OP_EQ, "\\"); // \ /* comment to prevent line continuation */ tor_free(r); r = get_unquoted_path("\"\\\"\""); // "\"" tt_str_op(r, OP_EQ, "\""); // " tor_free(r); r = get_unquoted_path("\"A\\B\\C\\\"\""); // "A\B\C\"" tt_str_op(r, OP_EQ, "A\\B\\C\""); // A\B\C" tor_free(r); r = get_unquoted_path("A\\B\\\"C"); // A\B\"C tt_str_op(r, OP_EQ, "A\\B\"C"); // A\B"C tor_free(r); r = get_unquoted_path("\"A\\B\\\"C\""); // "A\B\"C" tt_str_op(r, OP_EQ, "A\\B\"C"); // A\B"C done: tor_free(r); } static void test_util_log_mallinfo(void *arg) { (void)arg; char *log1 = NULL, *log2 = NULL, *mem = NULL; #ifdef HAVE_MALLINFO setup_capture_of_logs(LOG_INFO); tor_log_mallinfo(LOG_INFO); expect_single_log_msg_containing("mallinfo() said: "); mock_saved_log_entry_t *lg = smartlist_get(mock_saved_logs(), 0); log1 = tor_strdup(lg->generated_msg); mock_clean_saved_logs(); mem = tor_malloc(8192); tor_log_mallinfo(LOG_INFO); expect_single_log_msg_containing("mallinfo() said: "); lg = smartlist_get(mock_saved_logs(), 0); log2 = tor_strdup(lg->generated_msg); /* Make sure that the amount of used memory increased. */ const char *used1 = strstr(log1, "uordblks="); const char *used2 = strstr(log2, "uordblks="); tt_assert(used1); tt_assert(used2); used1 += strlen("uordblks="); used2 += strlen("uordblks="); int ok1, ok2; char *next1 = NULL, *next2 = NULL; uint64_t mem1 = tor_parse_uint64(used1, 10, 0, UINT64_MAX, &ok1, &next1); uint64_t mem2 = tor_parse_uint64(used2, 10, 0, UINT64_MAX, &ok2, &next2); tt_assert(ok1); tt_assert(ok2); tt_assert(next1); tt_assert(next2); if (mem2 == 0) { /* This is a fake mallinfo that doesn't actually fill in its outputs. */ tt_u64_op(mem1, OP_EQ, 0); } else { tt_u64_op(mem1, OP_LT, mem2); } #else tt_skip(); #endif done: teardown_capture_of_logs(); tor_free(log1); tor_free(log2); tor_free(mem); } #define UTIL_LEGACY(name) \ { #name, test_util_ ## name , 0, NULL, NULL } #define UTIL_TEST(name, flags) \ { #name, test_util_ ## name, flags, NULL, NULL } #define COMPRESS(name, identifier) \ { "compress/" #name, test_util_compress, 0, &compress_setup, \ (char*)(identifier) } #define COMPRESS_CONCAT(name, identifier) \ { "compress_concat/" #name, test_util_decompress_concatenated, 0, \ &compress_setup, \ (char*)(identifier) } #define COMPRESS_JUNK(name, identifier) \ { "compress_junk/" #name, test_util_decompress_junk, 0, \ &compress_setup, \ (char*)(identifier) } #define COMPRESS_DOS(name, identifier) \ { "compress_dos/" #name, test_util_decompress_dos, 0, \ &compress_setup, \ (char*)(identifier) } #ifdef _WIN32 #define UTIL_TEST_NO_WIN(n, f) { #n, NULL, TT_SKIP, NULL, NULL } #define UTIL_TEST_WIN_ONLY(n, f) UTIL_TEST(n, (f)) #define UTIL_LEGACY_NO_WIN(n) UTIL_TEST_NO_WIN(n, 0) #else #define UTIL_TEST_NO_WIN(n, f) UTIL_TEST(n, (f)) #define UTIL_TEST_WIN_ONLY(n, f) { #n, NULL, TT_SKIP, NULL, NULL } #define UTIL_LEGACY_NO_WIN(n) UTIL_LEGACY(n) #endif /* defined(_WIN32) */ struct testcase_t util_tests[] = { UTIL_LEGACY(time), UTIL_TEST(parse_http_time, 0), UTIL_LEGACY(config_line), UTIL_LEGACY(config_line_quotes), UTIL_LEGACY(config_line_comment_character), UTIL_LEGACY(config_line_escaped_content), UTIL_LEGACY(config_line_crlf), UTIL_LEGACY_NO_WIN(expand_filename), UTIL_LEGACY(escape_string_socks), UTIL_LEGACY(string_is_key_value), UTIL_LEGACY(strmisc), UTIL_TEST(parse_integer, 0), UTIL_LEGACY(pow2), COMPRESS(zlib, "deflate"), COMPRESS(gzip, "gzip"), COMPRESS(lzma, "x-tor-lzma"), COMPRESS(zstd, "x-zstd"), COMPRESS(zstd_nostatic, "x-zstd:nostatic"), COMPRESS(none, "identity"), COMPRESS_CONCAT(zlib, "deflate"), COMPRESS_CONCAT(gzip, "gzip"), COMPRESS_CONCAT(lzma, "x-tor-lzma"), COMPRESS_CONCAT(zstd, "x-zstd"), COMPRESS_CONCAT(zstd_nostatic, "x-zstd:nostatic"), COMPRESS_CONCAT(none, "identity"), COMPRESS_JUNK(zlib, "deflate"), COMPRESS_JUNK(gzip, "gzip"), COMPRESS_JUNK(lzma, "x-tor-lzma"), COMPRESS_DOS(zlib, "deflate"), COMPRESS_DOS(gzip, "gzip"), COMPRESS_DOS(lzma, "x-tor-lzma"), COMPRESS_DOS(zstd, "x-zstd"), COMPRESS_DOS(zstd_nostatic, "x-zstd:nostatic"), UTIL_TEST(gzip_compression_bomb, TT_FORK), UTIL_LEGACY(datadir), UTIL_LEGACY(memarea), UTIL_LEGACY(control_formats), UTIL_LEGACY(mmap), UTIL_TEST(sscanf, TT_FORK), UTIL_LEGACY(format_time_interval), UTIL_LEGACY(path_is_relative), UTIL_LEGACY(strtok), UTIL_LEGACY(di_ops), UTIL_TEST(di_map, 0), UTIL_TEST(round_to_next_multiple_of, 0), UTIL_TEST(laplace, 0), UTIL_TEST(clamp_double_to_int64, 0), UTIL_TEST(find_str_at_start_of_line, 0), UTIL_TEST(string_is_C_identifier, 0), UTIL_TEST(string_is_utf8, 0), UTIL_TEST(asprintf, 0), UTIL_TEST(listdir, 0), UTIL_TEST(parent_dir, 0), UTIL_TEST(ftruncate, 0), UTIL_TEST(nowrap_math, 0), UTIL_TEST(num_cpus, 0), UTIL_TEST_WIN_ONLY(load_win_lib, 0), UTIL_TEST_NO_WIN(exit_status, 0), UTIL_TEST_NO_WIN(string_from_pipe, 0), UTIL_TEST(format_hex_number, 0), UTIL_TEST(format_dec_number, 0), UTIL_TEST(join_win_cmdline, 0), UTIL_TEST(split_lines, 0), UTIL_TEST(n_bits_set, 0), UTIL_TEST(eat_whitespace, 0), UTIL_TEST(sl_new_from_text_lines, 0), UTIL_TEST(envnames, 0), UTIL_TEST(make_environment, 0), UTIL_TEST(set_env_var_in_sl, 0), UTIL_TEST(read_file_eof_tiny_limit, 0), UTIL_TEST(read_file_eof_one_loop_a, 0), UTIL_TEST(read_file_eof_one_loop_b, 0), UTIL_TEST(read_file_eof_two_loops, 0), UTIL_TEST(read_file_eof_two_loops_b, 0), UTIL_TEST(read_file_eof_zero_bytes, 0), UTIL_TEST(write_chunks_to_file, 0), UTIL_TEST(mathlog, 0), UTIL_TEST(fraction, 0), UTIL_TEST(weak_random, 0), { "socket_ipv4", test_util_socket, TT_FORK, &passthrough_setup, (void*)"4" }, { "socket_ipv6", test_util_socket, TT_FORK, &passthrough_setup, (void*)"6" }, { "socketpair", test_util_socketpair, TT_FORK, &passthrough_setup, (void*)"0" }, { "socketpair_ersatz", test_util_socketpair, TT_FORK, &passthrough_setup, (void*)"1" }, UTIL_TEST(max_mem, 0), UTIL_TEST(hostname_validation, 0), UTIL_TEST(dest_validation_edgecase, 0), UTIL_TEST(ipv4_validation, 0), UTIL_TEST(writepid, 0), UTIL_TEST(get_avail_disk_space, 0), UTIL_TEST(touch_file, 0), UTIL_TEST_NO_WIN(pwdb, TT_FORK), UTIL_TEST(calloc_check, 0), UTIL_TEST(monotonic_time, 0), UTIL_TEST(monotonic_time_ratchet, TT_FORK), UTIL_TEST(monotonic_time_zero, 0), UTIL_TEST(monotonic_time_add_msec, 0), UTIL_TEST(htonll, 0), UTIL_TEST(get_unquoted_path, 0), UTIL_TEST(log_mallinfo, 0), END_OF_TESTCASES };