Mercurial > dropbear
view fuzz-wrapfd.c @ 1659:d32bcb5c557d
Add Ed25519 support (#91)
* Add support for Ed25519 as a public key type
Ed25519 is a elliptic curve signature scheme that offers
better security than ECDSA and DSA and good performance. It may be
used for both user and host keys.
OpenSSH key import and fuzzer are not supported yet.
Initially inspired by Peter Szabo.
* Add curve25519 and ed25519 fuzzers
* Add import and export of Ed25519 keys
author | Vladislav Grishenko <themiron@users.noreply.github.com> |
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date | Wed, 11 Mar 2020 21:09:45 +0500 |
parents | 60fceff95858 |
children | dfbe947bdf0d |
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#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; buffer *buf; int closein; int closeout; }; static struct fdwrap wrap_fds[IOWRAP_MAXFD+1]; /* for quick selection of in-use descriptors */ static int wrap_used[IOWRAP_MAXFD+1]; static unsigned int nused; static unsigned short rand_state[3]; void wrapfd_setup(void) { TRACE(("wrapfd_setup")) nused = 0; memset(wrap_fds, 0x0, sizeof(wrap_fds)); memset(wrap_used, 0x0, sizeof(wrap_used)); memset(rand_state, 0x0, sizeof(rand_state)); wrapfd_setseed(50); } void wrapfd_setseed(uint32_t seed) { memcpy(rand_state, &seed, sizeof(seed)); nrand48(rand_state); } void wrapfd_add(int fd, buffer *buf, enum wrapfd_mode mode) { TRACE(("wrapfd_add %d buf %p mode %d", fd, buf, mode)) assert(fd >= 0); assert(fd <= IOWRAP_MAXFD); assert(wrap_fds[fd].mode == UNUSED); assert(buf || mode == RANDOMIN); wrap_fds[fd].mode = mode; wrap_fds[fd].buf = buf; wrap_fds[fd].closein = 0; wrap_fds[fd].closeout = 0; wrap_used[nused] = fd; nused++; } void wrapfd_remove(int fd) { unsigned int i, j; TRACE(("wrapfd_remove %d", fd)) assert(fd >= 0); assert(fd <= IOWRAP_MAXFD); assert(wrap_fds[fd].mode != UNUSED); wrap_fds[fd].mode = UNUSED; /* remove from used list */ for (i = 0, j = 0; i < nused; i++) { if (wrap_used[i] != fd) { wrap_used[j] = wrap_used[i]; j++; } } nused--; } 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; buffer *buf; 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; } buf = wrap_fds[fd].buf; if (buf) { maxread = MIN(buf->len - buf->pos, count); /* returns 0 if buf is EOF, as intended */ if (maxread > 0) { maxread = nrand48(rand_state) % maxread + 1; } memcpy(out, buf_getptr(buf, maxread), maxread); buf_incrpos(buf, maxread); return maxread; } 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]; memset(fdlist, 0x0, sizeof(fdlist)); 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; }