/* Copyright (c) 2001-2004, Roger Dingledine. * Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson. * Copyright (c) 2007-2013, The Tor Project, Inc. */ /* See LICENSE for licensing information */ #define BUFFERS_PRIVATE #include "or.h" #include "buffers.h" #include "ext_orport.h" #include "test.h" /** Run unit tests for buffers.c */ static void test_buffers_basic(void *arg) { char str[256]; char str2[256]; buf_t *buf = NULL, *buf2 = NULL; const char *cp; int j; size_t r; (void) arg; /**** * buf_new ****/ if (!(buf = buf_new())) test_fail(); //test_eq(buf_capacity(buf), 4096); test_eq(buf_datalen(buf), 0); /**** * General pointer frobbing */ for (j=0;j<256;++j) { str[j] = (char)j; } write_to_buf(str, 256, buf); write_to_buf(str, 256, buf); test_eq(buf_datalen(buf), 512); fetch_from_buf(str2, 200, buf); test_memeq(str, str2, 200); test_eq(buf_datalen(buf), 312); memset(str2, 0, sizeof(str2)); fetch_from_buf(str2, 256, buf); test_memeq(str+200, str2, 56); test_memeq(str, str2+56, 200); test_eq(buf_datalen(buf), 56); memset(str2, 0, sizeof(str2)); /* Okay, now we should be 512 bytes into the 4096-byte buffer. If we add * another 3584 bytes, we hit the end. */ for (j=0;j<15;++j) { write_to_buf(str, 256, buf); } assert_buf_ok(buf); test_eq(buf_datalen(buf), 3896); fetch_from_buf(str2, 56, buf); test_eq(buf_datalen(buf), 3840); test_memeq(str+200, str2, 56); for (j=0;j<15;++j) { memset(str2, 0, sizeof(str2)); fetch_from_buf(str2, 256, buf); test_memeq(str, str2, 256); } test_eq(buf_datalen(buf), 0); buf_free(buf); buf = NULL; /* Okay, now make sure growing can work. */ buf = buf_new_with_capacity(16); //test_eq(buf_capacity(buf), 16); write_to_buf(str+1, 255, buf); //test_eq(buf_capacity(buf), 256); fetch_from_buf(str2, 254, buf); test_memeq(str+1, str2, 254); //test_eq(buf_capacity(buf), 256); assert_buf_ok(buf); write_to_buf(str, 32, buf); //test_eq(buf_capacity(buf), 256); assert_buf_ok(buf); write_to_buf(str, 256, buf); assert_buf_ok(buf); //test_eq(buf_capacity(buf), 512); test_eq(buf_datalen(buf), 33+256); fetch_from_buf(str2, 33, buf); test_eq(*str2, str[255]); test_memeq(str2+1, str, 32); //test_eq(buf_capacity(buf), 512); test_eq(buf_datalen(buf), 256); fetch_from_buf(str2, 256, buf); test_memeq(str, str2, 256); /* now try shrinking: case 1. */ buf_free(buf); buf = buf_new_with_capacity(33668); for (j=0;j<67;++j) { write_to_buf(str,255, buf); } //test_eq(buf_capacity(buf), 33668); test_eq(buf_datalen(buf), 17085); for (j=0; j < 40; ++j) { fetch_from_buf(str2, 255,buf); test_memeq(str2, str, 255); } /* now try shrinking: case 2. */ buf_free(buf); buf = buf_new_with_capacity(33668); for (j=0;j<67;++j) { write_to_buf(str,255, buf); } for (j=0; j < 20; ++j) { fetch_from_buf(str2, 255,buf); test_memeq(str2, str, 255); } for (j=0;j<80;++j) { write_to_buf(str,255, buf); } //test_eq(buf_capacity(buf),33668); for (j=0; j < 120; ++j) { fetch_from_buf(str2, 255,buf); test_memeq(str2, str, 255); } /* Move from buf to buf. */ buf_free(buf); buf = buf_new_with_capacity(4096); buf2 = buf_new_with_capacity(4096); for (j=0;j<100;++j) write_to_buf(str, 255, buf); test_eq(buf_datalen(buf), 25500); for (j=0;j<100;++j) { r = 10; move_buf_to_buf(buf2, buf, &r); test_eq(r, 0); } test_eq(buf_datalen(buf), 24500); test_eq(buf_datalen(buf2), 1000); for (j=0;j<3;++j) { fetch_from_buf(str2, 255, buf2); test_memeq(str2, str, 255); } r = 8192; /*big move*/ move_buf_to_buf(buf2, buf, &r); test_eq(r, 0); r = 30000; /* incomplete move */ move_buf_to_buf(buf2, buf, &r); test_eq(r, 13692); for (j=0;j<97;++j) { fetch_from_buf(str2, 255, buf2); test_memeq(str2, str, 255); } buf_free(buf); buf_free(buf2); buf = buf2 = NULL; buf = buf_new_with_capacity(5); cp = "Testing. This is a moderately long Testing string."; for (j = 0; cp[j]; j++) write_to_buf(cp+j, 1, buf); test_eq(0, buf_find_string_offset(buf, "Testing", 7)); test_eq(1, buf_find_string_offset(buf, "esting", 6)); test_eq(1, buf_find_string_offset(buf, "est", 3)); test_eq(39, buf_find_string_offset(buf, "ing str", 7)); test_eq(35, buf_find_string_offset(buf, "Testing str", 11)); test_eq(32, buf_find_string_offset(buf, "ng ", 3)); test_eq(43, buf_find_string_offset(buf, "string.", 7)); test_eq(-1, buf_find_string_offset(buf, "shrdlu", 6)); test_eq(-1, buf_find_string_offset(buf, "Testing thing", 13)); test_eq(-1, buf_find_string_offset(buf, "ngx", 3)); buf_free(buf); buf = NULL; /* Try adding a string too long for any freelist. */ { char *cp = tor_malloc_zero(65536); buf = buf_new(); write_to_buf(cp, 65536, buf); tor_free(cp); tt_int_op(buf_datalen(buf), ==, 65536); buf_free(buf); buf = NULL; } done: if (buf) buf_free(buf); if (buf2) buf_free(buf2); buf_shrink_freelists(1); } static void test_buffer_pullup(void *arg) { buf_t *buf; char *stuff, *tmp; const char *cp; size_t sz; (void)arg; stuff = tor_malloc(16384); tmp = tor_malloc(16384); /* Note: this test doesn't check the nulterminate argument to buf_pullup, since nothing actually uses it. We should remove it some time. */ buf = buf_new_with_capacity(3000); /* rounds up to next power of 2. */ tt_assert(buf); tt_int_op(buf_get_default_chunk_size(buf), ==, 4096); tt_int_op(buf_get_total_allocation(), ==, 0); /* There are a bunch of cases for pullup. One is the trivial case. Let's mess around with an empty buffer. */ buf_pullup(buf, 16, 1); buf_get_first_chunk_data(buf, &cp, &sz); tt_ptr_op(cp, ==, NULL); tt_uint_op(sz, ==, 0); /* Let's make sure nothing got allocated */ tt_int_op(buf_get_total_allocation(), ==, 0); /* Case 1: everything puts into the first chunk with some moving. */ /* Let's add some data. */ crypto_rand(stuff, 16384); write_to_buf(stuff, 3000, buf); write_to_buf(stuff+3000, 3000, buf); buf_get_first_chunk_data(buf, &cp, &sz); tt_ptr_op(cp, !=, NULL); tt_int_op(sz, <=, 4096); /* Make room for 3000 bytes in the first chunk, so that the pullup-move code * can get tested. */ tt_int_op(fetch_from_buf(tmp, 3000, buf), ==, 3000); test_memeq(tmp, stuff, 3000); buf_pullup(buf, 2048, 0); assert_buf_ok(buf); buf_get_first_chunk_data(buf, &cp, &sz); tt_ptr_op(cp, !=, NULL); tt_int_op(sz, >=, 2048); test_memeq(cp, stuff+3000, 2048); tt_int_op(3000, ==, buf_datalen(buf)); tt_int_op(fetch_from_buf(tmp, 3000, buf), ==, 0); test_memeq(tmp, stuff+3000, 2048); buf_free(buf); /* Now try the large-chunk case. */ buf = buf_new_with_capacity(3000); /* rounds up to next power of 2. */ write_to_buf(stuff, 4000, buf); write_to_buf(stuff+4000, 4000, buf); write_to_buf(stuff+8000, 4000, buf); write_to_buf(stuff+12000, 4000, buf); tt_int_op(buf_datalen(buf), ==, 16000); buf_get_first_chunk_data(buf, &cp, &sz); tt_ptr_op(cp, !=, NULL); tt_int_op(sz, <=, 4096); buf_pullup(buf, 12500, 0); assert_buf_ok(buf); buf_get_first_chunk_data(buf, &cp, &sz); tt_ptr_op(cp, !=, NULL); tt_int_op(sz, >=, 12500); test_memeq(cp, stuff, 12500); tt_int_op(buf_datalen(buf), ==, 16000); fetch_from_buf(tmp, 12400, buf); test_memeq(tmp, stuff, 12400); tt_int_op(buf_datalen(buf), ==, 3600); fetch_from_buf(tmp, 3500, buf); test_memeq(tmp, stuff+12400, 3500); fetch_from_buf(tmp, 100, buf); test_memeq(tmp, stuff+15900, 10); buf_free(buf); /* Make sure that the pull-up-whole-buffer case works */ buf = buf_new_with_capacity(3000); /* rounds up to next power of 2. */ write_to_buf(stuff, 4000, buf); write_to_buf(stuff+4000, 4000, buf); fetch_from_buf(tmp, 100, buf); /* dump 100 bytes from first chunk */ buf_pullup(buf, 16000, 0); /* Way too much. */ assert_buf_ok(buf); buf_get_first_chunk_data(buf, &cp, &sz); tt_ptr_op(cp, !=, NULL); tt_int_op(sz, ==, 7900); test_memeq(cp, stuff+100, 7900); buf_free(buf); buf = NULL; buf_shrink_freelists(1); tt_int_op(buf_get_total_allocation(), ==, 0); done: buf_free(buf); buf_shrink_freelists(1); tor_free(stuff); tor_free(tmp); } static void test_buffer_copy(void *arg) { generic_buffer_t *buf=NULL, *buf2=NULL; const char *s; size_t len; char b[256]; int i; (void)arg; buf = generic_buffer_new(); tt_assert(buf); /* Copy an empty buffer. */ tt_int_op(0, ==, generic_buffer_set_to_copy(&buf2, buf)); tt_assert(buf2); tt_int_op(0, ==, generic_buffer_len(buf2)); /* Now try with a short buffer. */ s = "And now comes an act of enormous enormance!"; len = strlen(s); generic_buffer_add(buf, s, len); tt_int_op(len, ==, generic_buffer_len(buf)); /* Add junk to buf2 so we can test replacing.*/ generic_buffer_add(buf2, "BLARG", 5); tt_int_op(0, ==, generic_buffer_set_to_copy(&buf2, buf)); tt_int_op(len, ==, generic_buffer_len(buf2)); generic_buffer_get(buf2, b, len); test_mem_op(b, ==, s, len); /* Now free buf2 and retry so we can test allocating */ generic_buffer_free(buf2); buf2 = NULL; tt_int_op(0, ==, generic_buffer_set_to_copy(&buf2, buf)); tt_int_op(len, ==, generic_buffer_len(buf2)); generic_buffer_get(buf2, b, len); test_mem_op(b, ==, s, len); /* Clear buf for next test */ generic_buffer_get(buf, b, len); tt_int_op(generic_buffer_len(buf),==,0); /* Okay, now let's try a bigger buffer. */ s = "Quis autem vel eum iure reprehenderit qui in ea voluptate velit " "esse quam nihil molestiae consequatur, vel illum qui dolorem eum " "fugiat quo voluptas nulla pariatur?"; len = strlen(s); for (i = 0; i < 256; ++i) { b[0]=i; generic_buffer_add(buf, b, 1); generic_buffer_add(buf, s, len); } tt_int_op(0, ==, generic_buffer_set_to_copy(&buf2, buf)); tt_int_op(generic_buffer_len(buf2), ==, generic_buffer_len(buf)); for (i = 0; i < 256; ++i) { generic_buffer_get(buf2, b, len+1); tt_int_op((unsigned char)b[0],==,i); test_mem_op(b+1, ==, s, len); } done: if (buf) generic_buffer_free(buf); if (buf2) generic_buffer_free(buf2); buf_shrink_freelists(1); } static void test_buffer_ext_or_cmd(void *arg) { ext_or_cmd_t *cmd = NULL; generic_buffer_t *buf = generic_buffer_new(); char *tmp = NULL; (void) arg; /* Empty -- should give "not there. */ tt_int_op(0, ==, generic_buffer_fetch_ext_or_cmd(buf, &cmd)); tt_ptr_op(NULL, ==, cmd); /* Three bytes: shouldn't work. */ generic_buffer_add(buf, "\x00\x20\x00", 3); tt_int_op(0, ==, generic_buffer_fetch_ext_or_cmd(buf, &cmd)); tt_ptr_op(NULL, ==, cmd); tt_int_op(3, ==, generic_buffer_len(buf)); /* 0020 0000: That's a nil command. It should work. */ generic_buffer_add(buf, "\x00", 1); tt_int_op(1, ==, generic_buffer_fetch_ext_or_cmd(buf, &cmd)); tt_ptr_op(NULL, !=, cmd); tt_int_op(0x20, ==, cmd->cmd); tt_int_op(0, ==, cmd->len); tt_int_op(0, ==, generic_buffer_len(buf)); ext_or_cmd_free(cmd); cmd = NULL; /* Now try a length-6 command with one byte missing. */ generic_buffer_add(buf, "\x10\x21\x00\x06""abcde", 9); tt_int_op(0, ==, generic_buffer_fetch_ext_or_cmd(buf, &cmd)); tt_ptr_op(NULL, ==, cmd); generic_buffer_add(buf, "f", 1); tt_int_op(1, ==, generic_buffer_fetch_ext_or_cmd(buf, &cmd)); tt_ptr_op(NULL, !=, cmd); tt_int_op(0x1021, ==, cmd->cmd); tt_int_op(6, ==, cmd->len); test_mem_op("abcdef", ==, cmd->body, 6); tt_int_op(0, ==, generic_buffer_len(buf)); ext_or_cmd_free(cmd); cmd = NULL; /* Now try a length-10 command with 4 extra bytes. */ generic_buffer_add(buf, "\xff\xff\x00\x0a" "loremipsum\x10\x00\xff\xff", 18); tt_int_op(1, ==, generic_buffer_fetch_ext_or_cmd(buf, &cmd)); tt_ptr_op(NULL, !=, cmd); tt_int_op(0xffff, ==, cmd->cmd); tt_int_op(10, ==, cmd->len); test_mem_op("loremipsum", ==, cmd->body, 10); tt_int_op(4, ==, generic_buffer_len(buf)); ext_or_cmd_free(cmd); cmd = NULL; /* Finally, let's try a maximum-length command. We already have the header * waiting. */ tt_int_op(0, ==, generic_buffer_fetch_ext_or_cmd(buf, &cmd)); tmp = tor_malloc_zero(65535); generic_buffer_add(buf, tmp, 65535); tt_int_op(1, ==, generic_buffer_fetch_ext_or_cmd(buf, &cmd)); tt_ptr_op(NULL, !=, cmd); tt_int_op(0x1000, ==, cmd->cmd); tt_int_op(0xffff, ==, cmd->len); test_mem_op(tmp, ==, cmd->body, 65535); tt_int_op(0, ==, generic_buffer_len(buf)); ext_or_cmd_free(cmd); cmd = NULL; done: ext_or_cmd_free(cmd); generic_buffer_free(buf); tor_free(tmp); buf_shrink_freelists(1); } static void test_buffer_allocation_tracking(void *arg) { char *junk = tor_malloc(16384); buf_t *buf1 = NULL, *buf2 = NULL; int i; (void)arg; crypto_rand(junk, 16384); tt_int_op(buf_get_total_allocation(), ==, 0); buf1 = buf_new(); tt_assert(buf1); buf2 = buf_new(); tt_assert(buf2); tt_int_op(buf_allocation(buf1), ==, 0); tt_int_op(buf_get_total_allocation(), ==, 0); write_to_buf(junk, 4000, buf1); write_to_buf(junk, 4000, buf1); write_to_buf(junk, 4000, buf1); write_to_buf(junk, 4000, buf1); tt_int_op(buf_allocation(buf1), ==, 16384); fetch_from_buf(junk, 100, buf1); tt_int_op(buf_allocation(buf1), ==, 16384); /* still 4 4k chunks */ tt_int_op(buf_get_total_allocation(), ==, 16384); fetch_from_buf(junk, 4096, buf1); /* drop a 1k chunk... */ tt_int_op(buf_allocation(buf1), ==, 3*4096); /* now 3 4k chunks */ #ifdef ENABLE_BUF_FREELISTS tt_int_op(buf_get_total_allocation(), ==, 16384); /* that chunk went onto the freelist. */ #else tt_int_op(buf_get_total_allocation(), ==, 12288); /* that chunk was really freed. */ #endif write_to_buf(junk, 4000, buf2); tt_int_op(buf_allocation(buf2), ==, 4096); /* another 4k chunk. */ /* * If we're using freelists, size stays at 16384 because we just pulled a * chunk from the freelist. If we aren't, we bounce back up to 16384 by * allocating a new chunk. */ tt_int_op(buf_get_total_allocation(), ==, 16384); write_to_buf(junk, 4000, buf2); tt_int_op(buf_allocation(buf2), ==, 8192); /* another 4k chunk. */ tt_int_op(buf_get_total_allocation(), ==, 5*4096); /* that chunk was new. */ /* Make a really huge buffer */ for (i = 0; i < 1000; ++i) { write_to_buf(junk, 4000, buf2); } tt_int_op(buf_allocation(buf2), >=, 4008000); tt_int_op(buf_get_total_allocation(), >=, 4008000); buf_free(buf2); buf2 = NULL; tt_int_op(buf_get_total_allocation(), <, 4008000); buf_shrink_freelists(1); tt_int_op(buf_get_total_allocation(), ==, buf_allocation(buf1)); buf_free(buf1); buf1 = NULL; buf_shrink_freelists(1); tt_int_op(buf_get_total_allocation(), ==, 0); done: buf_free(buf1); buf_free(buf2); buf_shrink_freelists(1); tor_free(junk); } static void test_buffer_time_tracking(void *arg) { buf_t *buf=NULL, *buf2=NULL; struct timeval tv0; const time_t START = 1389288246; const uint32_t START_MSEC = (uint32_t) ((uint64_t)START * 1000); int i; char tmp[4096]; (void)arg; crypto_rand(tmp, sizeof(tmp)); tv0.tv_sec = START; tv0.tv_usec = 0; buf = buf_new_with_capacity(3000); /* rounds up to next power of 2. */ tt_assert(buf); /* Empty buffer means the timestamp is 0. */ tt_int_op(0, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC)); tt_int_op(0, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC+1000)); tor_gettimeofday_cache_set(&tv0); write_to_buf("ABCDEFG", 7, buf); tt_int_op(1000, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC+1000)); buf2 = buf_copy(buf); tt_assert(buf2); tt_int_op(1234, ==, buf_get_oldest_chunk_timestamp(buf2, START_MSEC+1234)); /* Now add more bytes; enough to overflow the first chunk. */ tv0.tv_usec += 123 * 1000; tor_gettimeofday_cache_set(&tv0); for (i = 0; i < 600; ++i) write_to_buf("ABCDEFG", 7, buf); tt_int_op(4207, ==, buf_datalen(buf)); /* The oldest bytes are still in the front. */ tt_int_op(2000, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC+2000)); /* Once those bytes are dropped, the chunk is still on the first * timestamp. */ fetch_from_buf(tmp, 100, buf); tt_int_op(2000, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC+2000)); /* But once we discard the whole first chunk, we get the data in the second * chunk. */ fetch_from_buf(tmp, 4000, buf); tt_int_op(107, ==, buf_datalen(buf)); tt_int_op(2000, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC+2123)); /* This time we'll be grabbing a chunk from the freelist, and making sure its time gets updated */ tv0.tv_sec += 5; tv0.tv_usec = 617*1000; tor_gettimeofday_cache_set(&tv0); for (i = 0; i < 600; ++i) write_to_buf("ABCDEFG", 7, buf); tt_int_op(4307, ==, buf_datalen(buf)); tt_int_op(2000, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC+2123)); fetch_from_buf(tmp, 4000, buf); fetch_from_buf(tmp, 306, buf); tt_int_op(0, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC+5617)); tt_int_op(383, ==, buf_get_oldest_chunk_timestamp(buf, START_MSEC+6000)); done: buf_free(buf); buf_free(buf2); } static void test_buffers_zlib_impl(int finalize_with_nil) { char *msg = NULL; char *contents = NULL; char *expanded = NULL; buf_t *buf = NULL; tor_zlib_state_t *zlib_state = NULL; size_t out_len, in_len; int done; buf = buf_new_with_capacity(128); /* will round up */ zlib_state = tor_zlib_new(1, ZLIB_METHOD); msg = tor_malloc(512); crypto_rand(msg, 512); tt_int_op(write_to_buf_zlib(buf, zlib_state, msg, 128, 0), ==, 0); tt_int_op(write_to_buf_zlib(buf, zlib_state, msg+128, 128, 0), ==, 0); tt_int_op(write_to_buf_zlib(buf, zlib_state, msg+256, 256, 0), ==, 0); done = !finalize_with_nil; tt_int_op(write_to_buf_zlib(buf, zlib_state, "all done", 9, done), ==, 0); if (finalize_with_nil) { tt_int_op(write_to_buf_zlib(buf, zlib_state, "", 0, 1), ==, 0); } in_len = buf_datalen(buf); contents = tor_malloc(in_len); tt_int_op(fetch_from_buf(contents, in_len, buf), ==, 0); tt_int_op(0, ==, tor_gzip_uncompress(&expanded, &out_len, contents, in_len, ZLIB_METHOD, 1, LOG_WARN)); tt_int_op(out_len, >=, 128); tt_mem_op(msg, ==, expanded, 128); tt_int_op(out_len, >=, 512); tt_mem_op(msg, ==, expanded, 512); tt_int_op(out_len, ==, 512+9); tt_mem_op("all done", ==, expanded+512, 9); done: buf_free(buf); tor_zlib_free(zlib_state); tor_free(contents); tor_free(expanded); tor_free(msg); } static void test_buffers_zlib(void *arg) { (void) arg; test_buffers_zlib_impl(0); } static void test_buffers_zlib_fin_with_nil(void *arg) { (void) arg; test_buffers_zlib_impl(1); } static void test_buffers_zlib_fin_at_chunk_end(void *arg) { char *msg = NULL; char *contents = NULL; char *expanded = NULL; buf_t *buf = NULL; tor_zlib_state_t *zlib_state = NULL; size_t out_len, in_len; size_t sz, headerjunk; (void) arg; buf = buf_new_with_capacity(128); /* will round up */ sz = buf_get_default_chunk_size(buf); msg = tor_malloc_zero(sz); write_to_buf(msg, 1, buf); tt_assert(buf->head); /* Fill up the chunk so the zlib stuff won't fit in one chunk. */ tt_uint_op(buf->head->memlen, <, sz); headerjunk = buf->head->memlen - 7; write_to_buf(msg, headerjunk-1, buf); tt_uint_op(buf->head->datalen, ==, headerjunk); printf("<%u>\n", (unsigned)buf_datalen(buf)); tt_uint_op(buf_datalen(buf), ==, headerjunk); /* Write an empty string, with finalization on. */ zlib_state = tor_zlib_new(1, ZLIB_METHOD); tt_int_op(write_to_buf_zlib(buf, zlib_state, "", 0, 1), ==, 0); printf("<%u>\n", (unsigned)buf_datalen(buf)); in_len = buf_datalen(buf); contents = tor_malloc(in_len); tt_int_op(fetch_from_buf(contents, in_len, buf), ==, 0); tt_uint_op(in_len, >, headerjunk); tt_int_op(0, ==, tor_gzip_uncompress(&expanded, &out_len, contents + headerjunk, in_len - headerjunk, ZLIB_METHOD, 1, LOG_WARN)); tt_int_op(out_len, ==, 0); tt_assert(expanded); done: buf_free(buf); tor_zlib_free(zlib_state); tor_free(contents); tor_free(expanded); tor_free(msg); } struct testcase_t buffer_tests[] = { { "basic", test_buffers_basic, TT_FORK, NULL, NULL }, { "copy", test_buffer_copy, TT_FORK, NULL, NULL }, { "pullup", test_buffer_pullup, TT_FORK, NULL, NULL }, { "ext_or_cmd", test_buffer_ext_or_cmd, TT_FORK, NULL, NULL }, { "allocation_tracking", test_buffer_allocation_tracking, TT_FORK, NULL, NULL }, { "time_tracking", test_buffer_time_tracking, TT_FORK, NULL, NULL }, { "zlib", test_buffers_zlib, TT_FORK, NULL, NULL }, { "zlib_fin_with_nil", test_buffers_zlib_fin_with_nil, TT_FORK, NULL, NULL }, { "zlib_fin_at_chunk_end", test_buffers_zlib_fin_at_chunk_end, TT_FORK, NULL, NULL}, END_OF_TESTCASES };