#define FUZZ_SKIP_WRAP 1 #include "includes.h" #include "fuzz-wrapfd.h" #include "dbutil.h" #include "fuzz.h" #define IOWRAP_MAXFD (FD_SETSIZE-1) static const int MAX_RANDOM_IN = 50000; static const double CHANCE_CLOSE = 1.0 / 600; static const double CHANCE_INTR = 1.0 / 900; static const double CHANCE_READ1 = 0.96; static const double CHANCE_READ2 = 0.5; static const double CHANCE_WRITE1 = 0.96; static const double CHANCE_WRITE2 = 0.5; struct fdwrap { enum wrapfd_mode mode; int closein; int closeout; }; static struct fdwrap wrap_fds[IOWRAP_MAXFD+1] = {{UNUSED, 0, 0}}; static int wrapfd_maxfd = -1; static unsigned short rand_state[3]; static buffer *input_buf; static int devnull_fd = -1; static void wrapfd_remove(int fd); void wrapfd_setup(buffer *buf) { TRACE(("wrapfd_setup")) // clean old ones int i; for (i = 0; i <= wrapfd_maxfd; i++) { if (wrap_fds[i].mode != UNUSED) { wrapfd_remove(i); } } wrapfd_maxfd = -1; memset(rand_state, 0x0, sizeof(rand_state)); wrapfd_setseed(50); input_buf = buf; } void wrapfd_setseed(uint32_t seed) { memcpy(rand_state, &seed, sizeof(seed)); nrand48(rand_state); } int wrapfd_new_fuzzinput() { if (devnull_fd == -1) { devnull_fd = open("/dev/null", O_RDONLY); assert(devnull_fd != -1); } int fd = dup(devnull_fd); assert(fd != -1); assert(wrap_fds[fd].mode == UNUSED); wrap_fds[fd].mode = COMMONBUF; wrap_fds[fd].closein = 0; wrap_fds[fd].closeout = 0; wrapfd_maxfd = MAX(fd, wrapfd_maxfd); return fd; } int wrapfd_new_dummy() { if (devnull_fd == -1) { devnull_fd = open("/dev/null", O_RDONLY); assert(devnull_fd != -1); } int fd = dup(devnull_fd); assert(fd != -1); assert(wrap_fds[fd].mode == UNUSED); wrap_fds[fd].mode = DUMMY; wrap_fds[fd].closein = 0; wrap_fds[fd].closeout = 0; wrapfd_maxfd = MAX(fd, wrapfd_maxfd); return fd; } static void wrapfd_remove(int fd) { TRACE(("wrapfd_remove %d", fd)) assert(fd >= 0); assert(fd <= IOWRAP_MAXFD); assert(wrap_fds[fd].mode != UNUSED); wrap_fds[fd].mode = UNUSED; m_close(fd); } int wrapfd_close(int fd) { if (fd >= 0 && fd <= IOWRAP_MAXFD && wrap_fds[fd].mode != UNUSED) { wrapfd_remove(fd); return 0; } else { return close(fd); } } int wrapfd_read(int fd, void *out, size_t count) { size_t maxread; if (!fuzz.wrapfds) { return read(fd, out, count); } if (fd < 0 || fd > IOWRAP_MAXFD || wrap_fds[fd].mode == UNUSED) { /* XXX - assertion failure? */ TRACE(("Bad read descriptor %d\n", fd)) errno = EBADF; return -1; } assert(count != 0); if (wrap_fds[fd].closein || erand48(rand_state) < CHANCE_CLOSE) { wrap_fds[fd].closein = 1; errno = ECONNRESET; return -1; } if (erand48(rand_state) < CHANCE_INTR) { errno = EINTR; return -1; } if (input_buf && wrap_fds[fd].mode == COMMONBUF) { maxread = MIN(input_buf->len - input_buf->pos, count); /* returns 0 if buf is EOF, as intended */ if (maxread > 0) { maxread = nrand48(rand_state) % maxread + 1; } memcpy(out, buf_getptr(input_buf, maxread), maxread); buf_incrpos(input_buf, maxread); return maxread; } // return fixed output, of random length maxread = MIN(MAX_RANDOM_IN, count); maxread = nrand48(rand_state) % maxread + 1; memset(out, 0xef, maxread); return maxread; } int wrapfd_write(int fd, const void* in, size_t count) { unsigned const volatile char* volin = in; unsigned int i; if (!fuzz.wrapfds) { return write(fd, in, count); } if (fd < 0 || fd > IOWRAP_MAXFD || wrap_fds[fd].mode == UNUSED) { /* XXX - assertion failure? */ TRACE(("Bad read descriptor %d\n", fd)) errno = EBADF; return -1; } assert(count != 0); /* force read to exercise sanitisers */ for (i = 0; i < count; i++) { (void)volin[i]; } if (wrap_fds[fd].closeout || erand48(rand_state) < CHANCE_CLOSE) { wrap_fds[fd].closeout = 1; errno = ECONNRESET; return -1; } if (erand48(rand_state) < CHANCE_INTR) { errno = EINTR; return -1; } return nrand48(rand_state) % (count+1); } int wrapfd_select(int nfds, fd_set *readfds, fd_set *writefds, fd_set *exceptfds, struct timeval *timeout) { int i, nset, sel; int ret = 0; int fdlist[IOWRAP_MAXFD+1]; if (!fuzz.wrapfds) { return select(nfds, readfds, writefds, exceptfds, timeout); } assert(nfds <= IOWRAP_MAXFD+1); if (erand48(rand_state) < CHANCE_INTR) { errno = EINTR; return -1; } /* read */ if (readfds != NULL && erand48(rand_state) < CHANCE_READ1) { for (i = 0, nset = 0; i < nfds; i++) { if (FD_ISSET(i, readfds)) { assert(wrap_fds[i].mode != UNUSED); fdlist[nset] = i; nset++; } } DROPBEAR_FD_ZERO(readfds); if (nset > 0) { /* set one */ sel = fdlist[nrand48(rand_state) % nset]; FD_SET(sel, readfds); ret++; if (erand48(rand_state) < CHANCE_READ2) { sel = fdlist[nrand48(rand_state) % nset]; if (!FD_ISSET(sel, readfds)) { FD_SET(sel, readfds); ret++; } } } } /* write */ if (writefds != NULL && erand48(rand_state) < CHANCE_WRITE1) { for (i = 0, nset = 0; i < nfds; i++) { if (FD_ISSET(i, writefds)) { assert(wrap_fds[i].mode != UNUSED); fdlist[nset] = i; nset++; } } DROPBEAR_FD_ZERO(writefds); /* set one */ if (nset > 0) { sel = fdlist[nrand48(rand_state) % nset]; FD_SET(sel, writefds); ret++; if (erand48(rand_state) < CHANCE_WRITE2) { sel = fdlist[nrand48(rand_state) % nset]; if (!FD_ISSET(sel, writefds)) { FD_SET(sel, writefds); ret++; } } } } return ret; } int fuzz_kill(pid_t pid, int sig) { if (fuzz.fuzzing) { TRACE(("fuzz_kill ignoring pid %d signal %d", (pid), sig)) if (sig >= 0) { return 0; } else { errno = EINVAL; return -1; } } return kill(pid, sig); }