llvm-project/compiler-rt/test/dfsan/custom.cc

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// RUN: %clang_dfsan %s -o %t && DFSAN_OPTIONS="strict_data_dependencies=0" %run %t
// RUN: %clang_dfsan -mllvm -dfsan-args-abi %s -o %t && DFSAN_OPTIONS="strict_data_dependencies=0" %run %t
// RUN: %clang_dfsan -DSTRICT_DATA_DEPENDENCIES %s -o %t && %run %t
// RUN: %clang_dfsan -DSTRICT_DATA_DEPENDENCIES -mllvm -dfsan-args-abi %s -o %t && %run %t
// Tests custom implementations of various glibc functions.
#include <sanitizer/dfsan_interface.h>
#include <arpa/inet.h>
#include <assert.h>
#include <fcntl.h>
#include <link.h>
#include <poll.h>
#include <pthread.h>
#include <pwd.h>
#include <sched.h>
#include <signal.h>
#include <stdio.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <sys/select.h>
#include <sys/resource.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <sys/types.h>
#include <time.h>
#include <unistd.h>
dfsan_label i_label = 0;
dfsan_label j_label = 0;
dfsan_label k_label = 0;
dfsan_label i_j_label = 0;
#define ASSERT_ZERO_LABEL(data) \
assert(0 == dfsan_get_label((long) (data)))
#define ASSERT_READ_ZERO_LABEL(ptr, size) \
assert(0 == dfsan_read_label(ptr, size))
#define ASSERT_LABEL(data, label) \
assert(label == dfsan_get_label((long) (data)))
#define ASSERT_READ_LABEL(ptr, size, label) \
assert(label == dfsan_read_label(ptr, size))
void test_stat() {
int i = 1;
dfsan_set_label(i_label, &i, sizeof(i));
struct stat s;
s.st_dev = i;
assert(0 == stat("/", &s));
ASSERT_ZERO_LABEL(s.st_dev);
s.st_dev = i;
assert(-1 == stat("/nonexistent", &s));
ASSERT_LABEL(s.st_dev, i_label);
}
void test_fstat() {
int i = 1;
dfsan_set_label(i_label, &i, sizeof(i));
struct stat s;
int fd = open("/dev/zero", O_RDONLY);
s.st_dev = i;
int rv = fstat(fd, &s);
assert(0 == rv);
ASSERT_ZERO_LABEL(s.st_dev);
}
void test_memcmp() {
char str1[] = "str1", str2[] = "str2";
dfsan_set_label(i_label, &str1[3], 1);
dfsan_set_label(j_label, &str2[3], 1);
int rv = memcmp(str1, str2, sizeof(str1));
assert(rv < 0);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, i_j_label);
#endif
}
void test_memcpy() {
char str1[] = "str1";
char str2[sizeof(str1)];
dfsan_set_label(i_label, &str1[3], 1);
ASSERT_ZERO_LABEL(memcpy(str2, str1, sizeof(str1)));
assert(0 == memcmp(str2, str1, sizeof(str1)));
ASSERT_ZERO_LABEL(str2[0]);
ASSERT_LABEL(str2[3], i_label);
}
void test_memset() {
char buf[8];
int j = 'a';
dfsan_set_label(j_label, &j, sizeof(j));
ASSERT_ZERO_LABEL(memset(&buf, j, sizeof(buf)));
for (int i = 0; i < 8; ++i) {
ASSERT_LABEL(buf[i], j_label);
assert(buf[i] == 'a');
}
}
void test_strcmp() {
char str1[] = "str1", str2[] = "str2";
dfsan_set_label(i_label, &str1[3], 1);
dfsan_set_label(j_label, &str2[3], 1);
int rv = strcmp(str1, str2);
assert(rv < 0);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, i_j_label);
#endif
}
void test_strlen() {
char str1[] = "str1";
dfsan_set_label(i_label, &str1[3], 1);
int rv = strlen(str1);
assert(rv == 4);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, i_label);
#endif
}
void test_strdup() {
char str1[] = "str1";
dfsan_set_label(i_label, &str1[3], 1);
char *strd = strdup(str1);
ASSERT_ZERO_LABEL(strd[0]);
ASSERT_LABEL(strd[3], i_label);
free(strd);
}
void test_strncpy() {
char str1[] = "str1";
char str2[sizeof(str1)];
dfsan_set_label(i_label, &str1[3], 1);
char *strd = strncpy(str2, str1, 5);
assert(strd == str2);
assert(strcmp(str1, str2) == 0);
ASSERT_ZERO_LABEL(strd);
ASSERT_ZERO_LABEL(strd[0]);
ASSERT_ZERO_LABEL(strd[1]);
ASSERT_ZERO_LABEL(strd[2]);
ASSERT_LABEL(strd[3], i_label);
strd = strncpy(str2, str1, 3);
assert(strd == str2);
assert(strncmp(str1, str2, 3) == 0);
ASSERT_ZERO_LABEL(strd);
ASSERT_ZERO_LABEL(strd[0]);
ASSERT_ZERO_LABEL(strd[1]);
ASSERT_ZERO_LABEL(strd[2]);
}
void test_strncmp() {
char str1[] = "str1", str2[] = "str2";
dfsan_set_label(i_label, &str1[3], 1);
dfsan_set_label(j_label, &str2[3], 1);
int rv = strncmp(str1, str2, sizeof(str1));
assert(rv < 0);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, dfsan_union(i_label, j_label));
#endif
rv = strncmp(str1, str2, 3);
assert(rv == 0);
ASSERT_ZERO_LABEL(rv);
}
void test_strcasecmp() {
char str1[] = "str1", str2[] = "str2", str3[] = "Str1";
dfsan_set_label(i_label, &str1[3], 1);
dfsan_set_label(j_label, &str2[3], 1);
dfsan_set_label(j_label, &str3[2], 1);
int rv = strcasecmp(str1, str2);
assert(rv < 0);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, dfsan_union(i_label, j_label));
#endif
rv = strcasecmp(str1, str3);
assert(rv == 0);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, dfsan_union(i_label, j_label));
#endif
}
void test_strncasecmp() {
char str1[] = "Str1", str2[] = "str2";
dfsan_set_label(i_label, &str1[3], 1);
dfsan_set_label(j_label, &str2[3], 1);
int rv = strncasecmp(str1, str2, sizeof(str1));
assert(rv < 0);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, dfsan_union(i_label, j_label));
#endif
rv = strncasecmp(str1, str2, 3);
assert(rv == 0);
ASSERT_ZERO_LABEL(rv);
}
void test_strchr() {
char str1[] = "str1";
dfsan_set_label(i_label, &str1[3], 1);
char *crv = strchr(str1, 'r');
assert(crv == &str1[2]);
ASSERT_ZERO_LABEL(crv);
crv = strchr(str1, '1');
assert(crv == &str1[3]);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(crv);
#else
ASSERT_LABEL(crv, i_label);
#endif
crv = strchr(str1, 'x');
assert(!crv);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(crv);
#else
ASSERT_LABEL(crv, i_label);
#endif
}
void test_calloc() {
// With any luck this sequence of calls will cause calloc to return the same
// pointer both times. This is probably the best we can do to test this
// function.
char *crv = (char *) calloc(4096, 1);
ASSERT_ZERO_LABEL(crv[0]);
dfsan_set_label(i_label, crv, 100);
free(crv);
crv = (char *) calloc(4096, 1);
ASSERT_ZERO_LABEL(crv[0]);
free(crv);
}
void test_read() {
char buf[16];
dfsan_set_label(i_label, buf, 1);
dfsan_set_label(j_label, buf + 15, 1);
ASSERT_LABEL(buf[0], i_label);
ASSERT_LABEL(buf[15], j_label);
int fd = open("/dev/zero", O_RDONLY);
int rv = read(fd, buf, sizeof(buf));
assert(rv == sizeof(buf));
ASSERT_ZERO_LABEL(rv);
ASSERT_ZERO_LABEL(buf[0]);
ASSERT_ZERO_LABEL(buf[15]);
close(fd);
}
void test_pread() {
char buf[16];
dfsan_set_label(i_label, buf, 1);
dfsan_set_label(j_label, buf + 15, 1);
ASSERT_LABEL(buf[0], i_label);
ASSERT_LABEL(buf[15], j_label);
int fd = open("/bin/sh", O_RDONLY);
int rv = pread(fd, buf, sizeof(buf), 0);
assert(rv == sizeof(buf));
ASSERT_ZERO_LABEL(rv);
ASSERT_ZERO_LABEL(buf[0]);
ASSERT_ZERO_LABEL(buf[15]);
close(fd);
}
void test_dlopen() {
void *map = dlopen(NULL, RTLD_NOW);
assert(map);
ASSERT_ZERO_LABEL(map);
dlclose(map);
map = dlopen("/nonexistent", RTLD_NOW);
assert(!map);
ASSERT_ZERO_LABEL(map);
}
void test_clock_gettime() {
struct timespec tp;
dfsan_set_label(j_label, ((char *)&tp) + 3, 1);
int t = clock_gettime(CLOCK_REALTIME, &tp);
assert(t == 0);
ASSERT_ZERO_LABEL(t);
ASSERT_ZERO_LABEL(((char *)&tp)[3]);
}
void test_ctime_r() {
char *buf = (char*) malloc(64);
time_t t = 0;
char *ret = ctime_r(&t, buf);
ASSERT_ZERO_LABEL(ret);
assert(buf == ret);
ASSERT_READ_ZERO_LABEL(buf, strlen(buf) + 1);
dfsan_set_label(i_label, &t, sizeof(t));
ret = ctime_r(&t, buf);
ASSERT_ZERO_LABEL(ret);
ASSERT_READ_LABEL(buf, strlen(buf) + 1, i_label);
t = 0;
dfsan_set_label(j_label, &buf, sizeof(&buf));
ret = ctime_r(&t, buf);
ASSERT_LABEL(ret, j_label);
ASSERT_READ_ZERO_LABEL(buf, strlen(buf) + 1);
}
static int write_callback_count = 0;
static int last_fd;
static const unsigned char *last_buf;
static size_t last_count;
void write_callback(int fd, const void *buf, size_t count) {
write_callback_count++;
last_fd = fd;
last_buf = (const unsigned char*) buf;
last_count = count;
}
void test_dfsan_set_write_callback() {
char buf[] = "Sample chars";
int buf_len = strlen(buf);
int fd = open("/dev/null", O_WRONLY);
dfsan_set_write_callback(write_callback);
write_callback_count = 0;
// Callback should be invoked on every call to write().
int res = write(fd, buf, buf_len);
assert(write_callback_count == 1);
ASSERT_READ_ZERO_LABEL(&res, sizeof(res));
ASSERT_READ_ZERO_LABEL(&last_fd, sizeof(last_fd));
ASSERT_READ_ZERO_LABEL(last_buf, sizeof(last_buf));
ASSERT_READ_ZERO_LABEL(&last_count, sizeof(last_count));
// Add a label to write() arguments. Check that the labels are readable from
// the values passed to the callback.
dfsan_set_label(i_label, &fd, sizeof(fd));
dfsan_set_label(j_label, &(buf[3]), 1);
dfsan_set_label(k_label, &buf_len, sizeof(buf_len));
res = write(fd, buf, buf_len);
assert(write_callback_count == 2);
ASSERT_READ_ZERO_LABEL(&res, sizeof(res));
ASSERT_READ_LABEL(&last_fd, sizeof(last_fd), i_label);
ASSERT_READ_LABEL(&last_buf[3], sizeof(last_buf[3]), j_label);
ASSERT_READ_LABEL(last_buf, sizeof(last_buf), j_label);
ASSERT_READ_LABEL(&last_count, sizeof(last_count), k_label);
dfsan_set_write_callback(NULL);
}
void test_fgets() {
char *buf = (char*) malloc(128);
FILE *f = fopen("/etc/passwd", "r");
dfsan_set_label(j_label, buf, 1);
char *ret = fgets(buf, sizeof(buf), f);
assert(ret == buf);
ASSERT_ZERO_LABEL(ret);
ASSERT_READ_ZERO_LABEL(buf, 128);
dfsan_set_label(j_label, &buf, sizeof(&buf));
ret = fgets(buf, sizeof(buf), f);
ASSERT_LABEL(ret, j_label);
fclose(f);
}
void test_getcwd() {
char buf[1024];
char *ptr = buf;
dfsan_set_label(i_label, buf + 2, 2);
char* ret = getcwd(buf, sizeof(buf));
assert(ret == buf);
assert(ret[0] == '/');
ASSERT_READ_ZERO_LABEL(buf + 2, 2);
dfsan_set_label(i_label, &ptr, sizeof(ptr));
ret = getcwd(ptr, sizeof(buf));
ASSERT_LABEL(ret, i_label);
}
void test_get_current_dir_name() {
char* ret = get_current_dir_name();
assert(ret);
assert(ret[0] == '/');
ASSERT_READ_ZERO_LABEL(ret, strlen(ret) + 1);
}
void test_gethostname() {
char buf[1024];
dfsan_set_label(i_label, buf + 2, 2);
assert(gethostname(buf, sizeof(buf)) == 0);
ASSERT_READ_ZERO_LABEL(buf + 2, 2);
}
void test_getrlimit() {
struct rlimit rlim;
dfsan_set_label(i_label, &rlim, sizeof(rlim));
assert(getrlimit(RLIMIT_CPU, &rlim) == 0);
ASSERT_READ_ZERO_LABEL(&rlim, sizeof(rlim));
}
void test_getrusage() {
struct rusage usage;
dfsan_set_label(i_label, &usage, sizeof(usage));
assert(getrusage(RUSAGE_SELF, &usage) == 0);
ASSERT_READ_ZERO_LABEL(&usage, sizeof(usage));
}
void test_strcpy() {
char src[] = "hello world";
char dst[sizeof(src) + 2];
dfsan_set_label(0, src, sizeof(src));
dfsan_set_label(0, dst, sizeof(dst));
dfsan_set_label(i_label, src + 2, 1);
dfsan_set_label(j_label, src + 3, 1);
dfsan_set_label(j_label, dst + 4, 1);
dfsan_set_label(i_label, dst + 12, 1);
char *ret = strcpy(dst, src);
assert(ret == dst);
assert(strcmp(src, dst) == 0);
for (int i = 0; i < strlen(src) + 1; ++i) {
assert(dfsan_get_label(dst[i]) == dfsan_get_label(src[i]));
}
// Note: if strlen(src) + 1 were used instead to compute the first untouched
// byte of dest, the label would be I|J. This is because strlen() might
// return a non-zero label, and because by default pointer labels are not
// ignored on loads.
ASSERT_LABEL(dst[12], i_label);
}
void test_strtol() {
char buf[] = "1234578910";
char *endptr = NULL;
dfsan_set_label(i_label, buf + 1, 1);
dfsan_set_label(j_label, buf + 10, 1);
long int ret = strtol(buf, &endptr, 10);
assert(ret == 1234578910);
assert(endptr == buf + 10);
ASSERT_LABEL(ret, i_j_label);
}
void test_strtoll() {
char buf[] = "1234578910 ";
char *endptr = NULL;
dfsan_set_label(i_label, buf + 1, 1);
dfsan_set_label(j_label, buf + 2, 1);
long long int ret = strtoll(buf, &endptr, 10);
assert(ret == 1234578910);
assert(endptr == buf + 10);
ASSERT_LABEL(ret, i_j_label);
}
void test_strtoul() {
char buf[] = "0xffffffffffffaa";
char *endptr = NULL;
dfsan_set_label(i_label, buf + 1, 1);
dfsan_set_label(j_label, buf + 2, 1);
long unsigned int ret = strtol(buf, &endptr, 16);
assert(ret == 72057594037927850);
assert(endptr == buf + 16);
ASSERT_LABEL(ret, i_j_label);
}
void test_strtoull() {
char buf[] = "0xffffffffffffffaa";
char *endptr = NULL;
dfsan_set_label(i_label, buf + 1, 1);
dfsan_set_label(j_label, buf + 2, 1);
long long unsigned int ret = strtoull(buf, &endptr, 16);
assert(ret == 0xffffffffffffffaa);
assert(endptr == buf + 18);
ASSERT_LABEL(ret, i_j_label);
}
void test_strtod() {
char buf[] = "12345.76 foo";
char *endptr = NULL;
dfsan_set_label(i_label, buf + 1, 1);
dfsan_set_label(j_label, buf + 6, 1);
double ret = strtod(buf, &endptr);
assert(ret == 12345.76);
assert(endptr == buf + 8);
ASSERT_LABEL(ret, i_j_label);
}
void test_time() {
time_t t = 0;
dfsan_set_label(i_label, &t, 1);
time_t ret = time(&t);
assert(ret == t);
assert(ret > 0);
ASSERT_ZERO_LABEL(t);
}
void test_inet_pton() {
char addr4[] = "127.0.0.1";
dfsan_set_label(i_label, addr4 + 3, 1);
struct in_addr in4;
int ret4 = inet_pton(AF_INET, addr4, &in4);
assert(ret4 == 1);
ASSERT_READ_LABEL(&in4, sizeof(in4), i_label);
assert(in4.s_addr == 0x0100007f);
char addr6[] = "::1";
dfsan_set_label(j_label, addr6 + 3, 1);
struct in6_addr in6;
int ret6 = inet_pton(AF_INET6, addr6, &in6);
assert(ret6 == 1);
ASSERT_READ_LABEL(((char *) &in6) + sizeof(in6) - 1, 1, j_label);
}
void test_localtime_r() {
time_t t0 = 1384800998;
struct tm t1;
dfsan_set_label(i_label, &t0, sizeof(t0));
struct tm* ret = localtime_r(&t0, &t1);
assert(ret == &t1);
assert(t1.tm_min == 56);
ASSERT_LABEL(t1.tm_mon, i_label);
}
void test_getpwuid_r() {
struct passwd pwd;
char buf[1024];
struct passwd *result;
dfsan_set_label(i_label, &pwd, 4);
int ret = getpwuid_r(0, &pwd, buf, sizeof(buf), &result);
assert(ret == 0);
assert(strcmp(pwd.pw_name, "root") == 0);
assert(result == &pwd);
ASSERT_READ_ZERO_LABEL(&pwd, 4);
}
void test_poll() {
struct pollfd fd;
fd.fd = 0;
fd.events = POLLIN;
dfsan_set_label(i_label, &fd.revents, sizeof(fd.revents));
int ret = poll(&fd, 1, 1);
ASSERT_ZERO_LABEL(fd.revents);
assert(ret >= 0);
}
void test_select() {
struct timeval t;
fd_set fds;
t.tv_sec = 2;
FD_SET(0, &fds);
dfsan_set_label(i_label, &fds, sizeof(fds));
dfsan_set_label(j_label, &t, sizeof(t));
int ret = select(1, &fds, NULL, NULL, &t);
assert(ret >= 0);
ASSERT_ZERO_LABEL(t.tv_sec);
ASSERT_READ_ZERO_LABEL(&fds, sizeof(fds));
}
void test_sched_getaffinity() {
cpu_set_t mask;
dfsan_set_label(j_label, &mask, 1);
int ret = sched_getaffinity(0, sizeof(mask), &mask);
assert(ret == 0);
ASSERT_READ_ZERO_LABEL(&mask, sizeof(mask));
}
void test_sigemptyset() {
sigset_t set;
dfsan_set_label(j_label, &set, 1);
int ret = sigemptyset(&set);
assert(ret == 0);
ASSERT_READ_ZERO_LABEL(&set, sizeof(set));
}
void test_sigaction() {
struct sigaction oldact;
dfsan_set_label(j_label, &oldact, 1);
int ret = sigaction(SIGUSR1, NULL, &oldact);
assert(ret == 0);
ASSERT_READ_ZERO_LABEL(&oldact, sizeof(oldact));
}
void test_gettimeofday() {
struct timeval tv;
struct timezone tz;
dfsan_set_label(i_label, &tv, sizeof(tv));
dfsan_set_label(j_label, &tz, sizeof(tz));
int ret = gettimeofday(&tv, &tz);
assert(ret == 0);
ASSERT_READ_ZERO_LABEL(&tv, sizeof(tv));
ASSERT_READ_ZERO_LABEL(&tz, sizeof(tz));
}
void *pthread_create_test_cb(void *p) {
assert(p == (void *)1);
ASSERT_ZERO_LABEL(p);
return (void *)2;
}
void test_pthread_create() {
pthread_t pt;
pthread_create(&pt, 0, pthread_create_test_cb, (void *)1);
void *cbrv;
pthread_join(pt, &cbrv);
assert(cbrv == (void *)2);
}
int dl_iterate_phdr_test_cb(struct dl_phdr_info *info, size_t size,
void *data) {
assert(data == (void *)3);
ASSERT_ZERO_LABEL(info);
ASSERT_ZERO_LABEL(size);
ASSERT_ZERO_LABEL(data);
return 0;
}
void test_dl_iterate_phdr() {
dl_iterate_phdr(dl_iterate_phdr_test_cb, (void *)3);
}
void test_strrchr() {
char str1[] = "str1str1";
dfsan_set_label(i_label, &str1[7], 1);
char *rv = strrchr(str1, 'r');
assert(rv == &str1[6]);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, i_label);
#endif
}
void test_strstr() {
char str1[] = "str1str1";
dfsan_set_label(i_label, &str1[3], 1);
dfsan_set_label(j_label, &str1[5], 1);
char *rv = strstr(str1, "1s");
assert(rv == &str1[3]);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, i_label);
#endif
rv = strstr(str1, "2s");
assert(rv == NULL);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(rv);
#else
ASSERT_LABEL(rv, i_j_label);
#endif
}
void test_memchr() {
char str1[] = "str1";
dfsan_set_label(i_label, &str1[3], 1);
dfsan_set_label(j_label, &str1[4], 1);
char *crv = (char *) memchr(str1, 'r', sizeof(str1));
assert(crv == &str1[2]);
ASSERT_ZERO_LABEL(crv);
crv = (char *) memchr(str1, '1', sizeof(str1));
assert(crv == &str1[3]);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(crv);
#else
ASSERT_LABEL(crv, i_label);
#endif
crv = (char *) memchr(str1, 'x', sizeof(str1));
assert(!crv);
#ifdef STRICT_DATA_DEPENDENCIES
ASSERT_ZERO_LABEL(crv);
#else
ASSERT_LABEL(crv, i_j_label);
#endif
}
void alarm_handler(int unused) {
;
}
void test_nanosleep() {
struct timespec req, rem;
req.tv_sec = 1;
req.tv_nsec = 0;
dfsan_set_label(i_label, &rem, sizeof(rem));
// non interrupted
int rv = nanosleep(&req, &rem);
assert(rv == 0);
ASSERT_ZERO_LABEL(rv);
ASSERT_READ_LABEL(&rem, 1, i_label);
// interrupted by an alarm
signal(SIGALRM, alarm_handler);
req.tv_sec = 3;
alarm(1);
rv = nanosleep(&req, &rem);
assert(rv == -1);
ASSERT_ZERO_LABEL(rv);
ASSERT_READ_ZERO_LABEL(&rem, sizeof(rem));
}
void test_socketpair() {
int fd[2];
dfsan_set_label(i_label, fd, sizeof(fd));
int rv = socketpair(PF_LOCAL, SOCK_STREAM, 0, fd);
assert(rv == 0);
ASSERT_ZERO_LABEL(rv);
ASSERT_READ_ZERO_LABEL(fd, sizeof(fd));
}
void test_write() {
int fd = open("/dev/null", O_WRONLY);
char buf[] = "a string";
int len = strlen(buf);
// The result of a write always unlabeled.
int res = write(fd, buf, len);
assert(res > 0);
ASSERT_ZERO_LABEL(res);
// Label all arguments to write().
dfsan_set_label(i_label, &(buf[3]), 1);
dfsan_set_label(j_label, &fd, sizeof(fd));
dfsan_set_label(i_label, &len, sizeof(len));
// The value returned by write() should have no label.
res = write(fd, buf, len);
ASSERT_ZERO_LABEL(res);
close(fd);
}
template <class T>
void test_sprintf_chunk(const char* expected, const char* format, T arg) {
char buf[512];
memset(buf, 'a', sizeof(buf));
char padded_expected[512];
strcpy(padded_expected, "foo ");
strcat(padded_expected, expected);
strcat(padded_expected, " bar");
char padded_format[512];
strcpy(padded_format, "foo ");
strcat(padded_format, format);
strcat(padded_format, " bar");
// Non labelled arg.
assert(sprintf(buf, padded_format, arg) == strlen(padded_expected));
assert(strcmp(buf, padded_expected) == 0);
ASSERT_READ_LABEL(buf, strlen(padded_expected), 0);
memset(buf, 'a', sizeof(buf));
// Labelled arg.
dfsan_set_label(i_label, &arg, sizeof(arg));
assert(sprintf(buf, padded_format, arg) == strlen(padded_expected));
assert(strcmp(buf, padded_expected) == 0);
ASSERT_READ_LABEL(buf, 4, 0);
ASSERT_READ_LABEL(buf + 4, strlen(padded_expected) - 8, i_label);
ASSERT_READ_LABEL(buf + (strlen(padded_expected) - 4), 4, 0);
}
void test_sprintf() {
char buf[2048];
memset(buf, 'a', sizeof(buf));
// Test formatting (no conversion specifier).
assert(sprintf(buf, "Hello world!") == 12);
assert(strcmp(buf, "Hello world!") == 0);
ASSERT_READ_LABEL(buf, sizeof(buf), 0);
// Test for extra arguments.
assert(sprintf(buf, "Hello world!", 42, "hello") == 12);
assert(strcmp(buf, "Hello world!") == 0);
ASSERT_READ_LABEL(buf, sizeof(buf), 0);
// Test formatting & label propagation (multiple conversion specifiers): %s,
// %d, %n, %f, and %%.
const char* s = "world";
int m = 8;
int d = 27;
dfsan_set_label(k_label, (void *) (s + 1), 2);
dfsan_set_label(i_label, &m, sizeof(m));
dfsan_set_label(j_label, &d, sizeof(d));
int n;
int r = sprintf(buf, "hello %s, %-d/%d/%d %f %% %n%d", s, 2014, m, d,
12345.6781234, &n, 1000);
assert(r == 42);
assert(strcmp(buf, "hello world, 2014/8/27 12345.678123 % 1000") == 0);
ASSERT_READ_LABEL(buf, 7, 0);
ASSERT_READ_LABEL(buf + 7, 2, k_label);
ASSERT_READ_LABEL(buf + 9, 9, 0);
ASSERT_READ_LABEL(buf + 18, 1, i_label);
ASSERT_READ_LABEL(buf + 19, 1, 0);
ASSERT_READ_LABEL(buf + 20, 2, j_label);
ASSERT_READ_LABEL(buf + 22, 15, 0);
ASSERT_LABEL(r, 0);
assert(n == 38);
// Test formatting & label propagation (single conversion specifier, with
// additional length and precision modifiers).
test_sprintf_chunk("-559038737", "%d", 0xdeadbeef);
test_sprintf_chunk("3735928559", "%u", 0xdeadbeef);
test_sprintf_chunk("12345", "%i", 12345);
test_sprintf_chunk("751", "%o", 0751);
test_sprintf_chunk("babe", "%x", 0xbabe);
test_sprintf_chunk("0000BABE", "%.8X", 0xbabe);
test_sprintf_chunk("-17", "%hhd", 0xdeadbeef);
test_sprintf_chunk("-16657", "%hd", 0xdeadbeef);
test_sprintf_chunk("deadbeefdeadbeef", "%lx", 0xdeadbeefdeadbeef);
test_sprintf_chunk("0xdeadbeefdeadbeef", "%p",
(void *) 0xdeadbeefdeadbeef);
test_sprintf_chunk("18446744073709551615", "%ju", (intmax_t) -1);
test_sprintf_chunk("18446744073709551615", "%zu", (size_t) -1);
test_sprintf_chunk("18446744073709551615", "%tu", (size_t) -1);
test_sprintf_chunk("0x1.f9acffa7eb6bfp-4", "%a", 0.123456);
test_sprintf_chunk("0X1.F9ACFFA7EB6BFP-4", "%A", 0.123456);
test_sprintf_chunk("0.12346", "%.5f", 0.123456);
test_sprintf_chunk("0.123456", "%g", 0.123456);
test_sprintf_chunk("1.234560e-01", "%e", 0.123456);
test_sprintf_chunk("1.234560E-01", "%E", 0.123456);
test_sprintf_chunk("0.1234567891234560", "%.16Lf",
(long double) 0.123456789123456);
test_sprintf_chunk("z", "%c", 'z');
// %n, %s, %d, %f, and %% already tested
// Test formatting with width passed as an argument.
r = sprintf(buf, "hi %*d my %*s friend %.*f", 3, 1, 6, "dear", 4, 3.14159265359);
assert(r == 30);
assert(strcmp(buf, "hi 1 my dear friend 3.1416") == 0);
}
void test_snprintf() {
char buf[2048];
memset(buf, 'a', sizeof(buf));
dfsan_set_label(0, buf, sizeof(buf));
const char* s = "world";
int y = 2014;
int m = 8;
int d = 27;
dfsan_set_label(k_label, (void *) (s + 1), 2);
dfsan_set_label(i_label, &y, sizeof(y));
dfsan_set_label(j_label, &m, sizeof(m));
int r = snprintf(buf, 19, "hello %s, %-d/%d/%d %f", s, y, m, d,
12345.6781234);
// The return value is the number of bytes that would have been written to
// the final string if enough space had been available.
assert(r == 35);
assert(memcmp(buf, "hello world, 2014/", 19) == 0);
ASSERT_READ_LABEL(buf, 7, 0);
ASSERT_READ_LABEL(buf + 7, 2, k_label);
ASSERT_READ_LABEL(buf + 9, 4, 0);
ASSERT_READ_LABEL(buf + 13, 4, i_label);
ASSERT_READ_LABEL(buf + 17, 2, 0);
ASSERT_LABEL(r, 0);
}
int main(void) {
i_label = dfsan_create_label("i", 0);
j_label = dfsan_create_label("j", 0);
k_label = dfsan_create_label("k", 0);
i_j_label = dfsan_union(i_label, j_label);
test_calloc();
test_clock_gettime();
test_ctime_r();
test_dfsan_set_write_callback();
test_dl_iterate_phdr();
test_dlopen();
test_fgets();
test_fstat();
test_get_current_dir_name();
test_getcwd();
test_gethostname();
test_getpwuid_r();
test_getrlimit();
test_getrusage();
test_gettimeofday();
test_inet_pton();
test_localtime_r();
test_memchr();
test_memcmp();
test_memcpy();
test_memset();
test_nanosleep();
test_poll();
test_pread();
test_pthread_create();
test_read();
test_sched_getaffinity();
test_select();
test_sigaction();
test_sigemptyset();
test_snprintf();
test_socketpair();
test_sprintf();
test_stat();
test_strcasecmp();
test_strchr();
test_strcmp();
test_strcpy();
test_strdup();
test_strlen();
test_strncasecmp();
test_strncmp();
test_strncpy();
test_strrchr();
test_strstr();
test_strtod();
test_strtol();
test_strtoll();
test_strtoul();
test_strtoull();
test_time();
test_write();
}