Stop leaking sock descriptors in error path.
/* $OpenBSD: ioev.c,v 1.18 2014/04/19 17:36:54 gilles Exp $ */
/*
* Copyright (c) 2012 Eric Faurot <eric@openbsd.org>
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*/
#include <sys/types.h>
#include <sys/queue.h>
#include <sys/socket.h>
#include <err.h>
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include <unistd.h>
#include "ioev.h"
#include "iobuf.h"
#ifdef IO_SSL
#include <openssl/err.h>
#include <openssl/ssl.h>
#endif
enum {
IO_STATE_NONE,
IO_STATE_CONNECT,
IO_STATE_CONNECT_SSL,
IO_STATE_ACCEPT_SSL,
IO_STATE_UP,
IO_STATE_MAX,
};
const char* io_strflags(int);
const char* io_evstr(short);
void _io_init(void);
void io_hold(struct io *);
void io_release(struct io *);
void io_callback(struct io*, int);
void io_dispatch(int, short, void *);
void io_dispatch_connect(int, short, void *);
size_t io_pending(struct io *);
size_t io_queued(struct io*);
void io_reset(struct io *, short, void (*)(int, short, void*));
void io_frame_enter(const char *, struct io *, int);
void io_frame_leave(struct io *);
#ifdef IO_SSL
void ssl_error(const char *); /* XXX external */
static const char* io_ssl_error(void);
void io_dispatch_accept_ssl(int, short, void *);
void io_dispatch_connect_ssl(int, short, void *);
void io_dispatch_read_ssl(int, short, void *);
void io_dispatch_write_ssl(int, short, void *);
void io_reload_ssl(struct io *io);
#endif
static struct io *current = NULL;
static uint64_t frame = 0;
static int _io_debug = 0;
#define io_debug(args...) do { if (_io_debug) printf(args); } while(0)
const char*
io_strio(struct io *io)
{
static char buf[128];
char ssl[128];
ssl[0] = '\0';
#ifdef IO_SSL
if (io->ssl) {
(void)snprintf(ssl, sizeof ssl, " ssl=%s:%s:%d",
SSL_get_cipher_version(io->ssl),
SSL_get_cipher_name(io->ssl),
SSL_get_cipher_bits(io->ssl, NULL));
}
#endif
if (io->iobuf == NULL)
(void)snprintf(buf, sizeof buf,
"<io:%p fd=%d to=%d fl=%s%s>",
io, io->sock, io->timeout, io_strflags(io->flags), ssl);
else
(void)snprintf(buf, sizeof buf,
"<io:%p fd=%d to=%d fl=%s%s ib=%zu ob=%zu>",
io, io->sock, io->timeout, io_strflags(io->flags), ssl,
io_pending(io), io_queued(io));
return (buf);
}
#define CASE(x) case x : return #x
const char*
io_strevent(int evt)
{
static char buf[32];
switch (evt) {
CASE(IO_CONNECTED);
CASE(IO_TLSREADY);
CASE(IO_TLSVERIFIED);
CASE(IO_DATAIN);
CASE(IO_LOWAT);
CASE(IO_DISCONNECTED);
CASE(IO_TIMEOUT);
CASE(IO_ERROR);
default:
(void)snprintf(buf, sizeof(buf), "IO_? %d", evt);
return buf;
}
}
void
io_set_blocking(int fd, int blocking)
{
int flags;
if ((flags = fcntl(fd, F_GETFL, 0)) == -1)
err(1, "io_set_blocking:fcntl(F_GETFL)");
if (blocking)
flags &= ~O_NONBLOCK;
else
flags |= O_NONBLOCK;
if ((flags = fcntl(fd, F_SETFL, flags)) == -1)
err(1, "io_set_blocking:fcntl(F_SETFL)");
}
void
io_set_linger(int fd, int linger)
{
struct linger l;
memset(&l, 0, sizeof(l));
l.l_onoff = linger ? 1 : 0;
l.l_linger = linger;
if (setsockopt(fd, SOL_SOCKET, SO_LINGER, &l, sizeof(l)) == -1)
err(1, "io_set_linger:setsockopt()");
}
/*
* Event framing must not rely on an io pointer to refer to the "same" io
* throughout the frame, beacuse this is not always the case:
*
* 1) enter(addr0) -> free(addr0) -> leave(addr0) = SEGV
* 2) enter(addr0) -> free(addr0) -> malloc == addr0 -> leave(addr0) = BAD!
*
* In both case, the problem is that the io is freed in the callback, so
* the pointer becomes invalid. If that happens, the user is required to
* call io_clear, so we can adapt the frame state there.
*/
void
io_frame_enter(const char *where, struct io *io, int ev)
{
io_debug("\n=== %" PRIu64 " ===\n"
"io_frame_enter(%s, %s, %s)\n",
frame, where, io_evstr(ev), io_strio(io));
if (current)
errx(1, "io_frame_enter: interleaved frames");
current = io;
io_hold(io);
}
void
io_frame_leave(struct io *io)
{
io_debug("io_frame_leave(%" PRIu64 ")\n", frame);
if (current && current != io)
errx(1, "io_frame_leave: io mismatch");
/* io has been cleared */
if (current == NULL)
goto done;
/* TODO: There is a possible optimization there:
* In a typical half-duplex request/response scenario,
* the io is waiting to read a request, and when done, it queues
* the response in the output buffer and goes to write mode.
* There, the write event is set and will be triggered in the next
* event frame. In most case, the write call could be done
* immediatly as part of the last read frame, thus avoiding to go
* through the event loop machinery. So, as an optimisation, we
* could detect that case here and force an event dispatching.
*/
/* Reload the io if it has not been reset already. */
io_release(io);
current = NULL;
done:
io_debug("=== /%" PRIu64 "\n", frame);
frame += 1;
}
void
_io_init()
{
static int init = 0;
if (init)
return;
init = 1;
_io_debug = getenv("IO_DEBUG") != NULL;
}
void
io_init(struct io *io, int sock, void *arg,
void(*cb)(struct io*, int), struct iobuf *iobuf)
{
_io_init();
memset(io, 0, sizeof *io);
io->sock = sock;
io->timeout = -1;
io->arg = arg;
io->iobuf = iobuf;
io->cb = cb;
if (sock != -1)
io_reload(io);
}
void
io_clear(struct io *io)
{
io_debug("io_clear(%p)\n", io);
/* the current io is virtually dead */
if (io == current)
current = NULL;
#ifdef IO_SSL
if (io->ssl) {
SSL_free(io->ssl);
io->ssl = NULL;
}
#endif
if (event_initialized(&io->ev))
event_del(&io->ev);
if (io->sock != -1) {
close(io->sock);
io->sock = -1;
}
}
void
io_hold(struct io *io)
{
io_debug("io_enter(%p)\n", io);
if (io->flags & IO_HELD)
errx(1, "io_hold: io is already held");
io->flags &= ~IO_RESET;
io->flags |= IO_HELD;
}
void
io_release(struct io *io)
{
if (!(io->flags & IO_HELD))
errx(1, "io_release: io is not held");
io->flags &= ~IO_HELD;
if (!(io->flags & IO_RESET))
io_reload(io);
}
void
io_set_timeout(struct io *io, int msec)
{
io_debug("io_set_timeout(%p, %d)\n", io, msec);
io->timeout = msec;
}
void
io_set_lowat(struct io *io, size_t lowat)
{
io_debug("io_set_lowat(%p, %zu)\n", io, lowat);
io->lowat = lowat;
}
void
io_pause(struct io *io, int dir)
{
io_debug("io_pause(%p, %x)\n", io, dir);
io->flags |= dir & (IO_PAUSE_IN | IO_PAUSE_OUT);
io_reload(io);
}
void
io_resume(struct io *io, int dir)
{
io_debug("io_resume(%p, %x)\n", io, dir);
io->flags &= ~(dir & (IO_PAUSE_IN | IO_PAUSE_OUT));
io_reload(io);
}
void
io_set_read(struct io *io)
{
int mode;
io_debug("io_set_read(%p)\n", io);
mode = io->flags & IO_RW;
if (!(mode == 0 || mode == IO_WRITE))
errx(1, "io_set_read(): full-duplex or reading");
io->flags &= ~IO_RW;
io->flags |= IO_READ;
io_reload(io);
}
void
io_set_write(struct io *io)
{
int mode;
io_debug("io_set_write(%p)\n", io);
mode = io->flags & IO_RW;
if (!(mode == 0 || mode == IO_READ))
errx(1, "io_set_write(): full-duplex or writing");
io->flags &= ~IO_RW;
io->flags |= IO_WRITE;
io_reload(io);
}
#define IO_READING(io) (((io)->flags & IO_RW) != IO_WRITE)
#define IO_WRITING(io) (((io)->flags & IO_RW) != IO_READ)
/*
* Setup the necessary events as required by the current io state,
* honouring duplex mode and i/o pauses.
*/
void
io_reload(struct io *io)
{
short events;
/* io will be reloaded at release time */
if (io->flags & IO_HELD)
return;
#ifdef IO_SSL
if (io->ssl) {
io_reload_ssl(io);
return;
}
#endif
io_debug("io_reload(%p)\n", io);
events = 0;
if (IO_READING(io) && !(io->flags & IO_PAUSE_IN))
events = EV_READ;
if (IO_WRITING(io) && !(io->flags & IO_PAUSE_OUT) && io_queued(io))
events |= EV_WRITE;
io_reset(io, events, io_dispatch);
}
/* Set the requested event. */
void
io_reset(struct io *io, short events, void (*dispatch)(int, short, void*))
{
struct timeval tv, *ptv;
io_debug("io_reset(%p, %s, %p) -> %s\n",
io, io_evstr(events), dispatch, io_strio(io));
/*
* Indicate that the event has already been reset so that reload
* is not called on frame_leave.
*/
io->flags |= IO_RESET;
if (event_initialized(&io->ev))
event_del(&io->ev);
/*
* The io is paused by the user, so we don't want the timeout to be
* effective.
*/
if (events == 0)
return;
event_set(&io->ev, io->sock, events, dispatch, io);
if (io->timeout >= 0) {
tv.tv_sec = io->timeout / 1000;
tv.tv_usec = (io->timeout % 1000) * 1000;
ptv = &tv;
} else
ptv = NULL;
event_add(&io->ev, ptv);
}
size_t
io_pending(struct io *io)
{
return iobuf_len(io->iobuf);
}
size_t
io_queued(struct io *io)
{
return iobuf_queued(io->iobuf);
}
const char*
io_strflags(int flags)
{
static char buf[64];
buf[0] = '\0';
switch (flags & IO_RW) {
case 0:
(void)strlcat(buf, "rw", sizeof buf);
break;
case IO_READ:
(void)strlcat(buf, "R", sizeof buf);
break;
case IO_WRITE:
(void)strlcat(buf, "W", sizeof buf);
break;
case IO_RW:
(void)strlcat(buf, "RW", sizeof buf);
break;
}
if (flags & IO_PAUSE_IN)
(void)strlcat(buf, ",F_PI", sizeof buf);
if (flags & IO_PAUSE_OUT)
(void)strlcat(buf, ",F_PO", sizeof buf);
return buf;
}
const char*
io_evstr(short ev)
{
static char buf[64];
char buf2[16];
int n;
n = 0;
buf[0] = '\0';
if (ev == 0) {
(void)strlcat(buf, "<NONE>", sizeof(buf));
return buf;
}
if (ev & EV_TIMEOUT) {
(void)strlcat(buf, "EV_TIMEOUT", sizeof(buf));
ev &= ~EV_TIMEOUT;
n++;
}
if (ev & EV_READ) {
if (n)
(void)strlcat(buf, "|", sizeof(buf));
(void)strlcat(buf, "EV_READ", sizeof(buf));
ev &= ~EV_READ;
n++;
}
if (ev & EV_WRITE) {
if (n)
(void)strlcat(buf, "|", sizeof(buf));
(void)strlcat(buf, "EV_WRITE", sizeof(buf));
ev &= ~EV_WRITE;
n++;
}
if (ev & EV_SIGNAL) {
if (n)
(void)strlcat(buf, "|", sizeof(buf));
(void)strlcat(buf, "EV_SIGNAL", sizeof(buf));
ev &= ~EV_SIGNAL;
n++;
}
if (ev) {
if (n)
(void)strlcat(buf, "|", sizeof(buf));
(void)strlcat(buf, "EV_?=0x", sizeof(buf));
(void)snprintf(buf2, sizeof(buf2), "%hx", ev);
(void)strlcat(buf, buf2, sizeof(buf));
}
return buf;
}
void
io_dispatch(int fd, short ev, void *humppa)
{
struct io *io = humppa;
size_t w;
ssize_t n;
int saved_errno;
io_frame_enter("io_dispatch", io, ev);
if (ev == EV_TIMEOUT) {
io_callback(io, IO_TIMEOUT);
goto leave;
}
if (ev & EV_WRITE && (w = io_queued(io))) {
if ((n = iobuf_write(io->iobuf, io->sock)) < 0) {
if (n == IOBUF_WANT_WRITE) /* kqueue bug? */
goto read;
if (n == IOBUF_CLOSED)
io_callback(io, IO_DISCONNECTED);
else {
saved_errno = errno;
io->error = strerror(errno);
errno = saved_errno;
io_callback(io, IO_ERROR);
}
goto leave;
}
if (w > io->lowat && w - n <= io->lowat)
io_callback(io, IO_LOWAT);
}
read:
if (ev & EV_READ) {
if ((n = iobuf_read(io->iobuf, io->sock)) < 0) {
if (n == IOBUF_CLOSED)
io_callback(io, IO_DISCONNECTED);
else {
saved_errno = errno;
io->error = strerror(errno);
errno = saved_errno;
io_callback(io, IO_ERROR);
}
goto leave;
}
if (n)
io_callback(io, IO_DATAIN);
}
leave:
io_frame_leave(io);
}
void
io_callback(struct io *io, int evt)
{
io->cb(io, evt);
}
int
io_connect(struct io *io, const struct sockaddr *sa, const struct sockaddr *bsa)
{
int sock, errno_save;
if ((sock = socket(sa->sa_family, SOCK_STREAM, 0)) == -1)
goto fail;
io_set_blocking(sock, 0);
io_set_linger(sock, 0);
if (bsa && bind(sock, bsa, bsa->sa_len) == -1)
goto fail;
if (connect(sock, sa, sa->sa_len) == -1)
if (errno != EINPROGRESS)
goto fail;
io->sock = sock;
io_reset(io, EV_WRITE, io_dispatch_connect);
return (sock);
fail:
if (sock != -1) {
errno_save = errno;
close(sock);
errno = errno_save;
io->error = strerror(errno);
}
return (-1);
}
void
io_dispatch_connect(int fd, short ev, void *humppa)
{
struct io *io = humppa;
int r, e;
socklen_t sl;
io_frame_enter("io_dispatch_connect", io, ev);
if (ev == EV_TIMEOUT) {
close(fd);
io->sock = -1;
io_callback(io, IO_TIMEOUT);
} else {
sl = sizeof(e);
r = getsockopt(fd, SOL_SOCKET, SO_ERROR, &e, &sl);
if (r == -1) {
warn("io_dispatch_connect: getsockopt");
e = errno;
}
if (e) {
close(fd);
io->sock = -1;
io->error = strerror(e);
io_callback(io, e == ETIMEDOUT ? IO_TIMEOUT : IO_ERROR);
}
else {
io->state = IO_STATE_UP;
io_callback(io, IO_CONNECTED);
}
}
io_frame_leave(io);
}
#ifdef IO_SSL
static const char*
io_ssl_error(void)
{
static char buf[128];
unsigned long e;
e = ERR_peek_last_error();
if (e) {
ERR_error_string(e, buf);
return (buf);
}
return ("No SSL error");
}
int
io_start_tls(struct io *io, void *ssl)
{
int mode;
mode = io->flags & IO_RW;
if (mode == 0 || mode == IO_RW)
errx(1, "io_start_tls(): full-duplex or unset");
if (io->ssl)
errx(1, "io_start_tls(): SSL already started");
io->ssl = ssl;
if (SSL_set_fd(io->ssl, io->sock) == 0) {
ssl_error("io_start_ssl:SSL_set_fd");
return (-1);
}
if (mode == IO_WRITE) {
io->state = IO_STATE_CONNECT_SSL;
SSL_set_connect_state(io->ssl);
io_reset(io, EV_WRITE, io_dispatch_connect_ssl);
} else {
io->state = IO_STATE_ACCEPT_SSL;
SSL_set_accept_state(io->ssl);
io_reset(io, EV_READ, io_dispatch_accept_ssl);
}
return (0);
}
void
io_dispatch_accept_ssl(int fd, short event, void *humppa)
{
struct io *io = humppa;
int e, ret;
io_frame_enter("io_dispatch_accept_ssl", io, event);
if (event == EV_TIMEOUT) {
io_callback(io, IO_TIMEOUT);
goto leave;
}
if ((ret = SSL_accept(io->ssl)) > 0) {
io->state = IO_STATE_UP;
io_callback(io, IO_TLSREADY);
goto leave;
}
switch ((e = SSL_get_error(io->ssl, ret))) {
case SSL_ERROR_WANT_READ:
io_reset(io, EV_READ, io_dispatch_accept_ssl);
break;
case SSL_ERROR_WANT_WRITE:
io_reset(io, EV_WRITE, io_dispatch_accept_ssl);
break;
default:
io->error = io_ssl_error();
ssl_error("io_dispatch_accept_ssl:SSL_accept");
io_callback(io, IO_ERROR);
break;
}
leave:
io_frame_leave(io);
}
void
io_dispatch_connect_ssl(int fd, short event, void *humppa)
{
struct io *io = humppa;
int e, ret;
io_frame_enter("io_dispatch_connect_ssl", io, event);
if (event == EV_TIMEOUT) {
io_callback(io, IO_TIMEOUT);
goto leave;
}
if ((ret = SSL_connect(io->ssl)) > 0) {
io->state = IO_STATE_UP;
io_callback(io, IO_TLSREADY);
goto leave;
}
switch ((e = SSL_get_error(io->ssl, ret))) {
case SSL_ERROR_WANT_READ:
io_reset(io, EV_READ, io_dispatch_connect_ssl);
break;
case SSL_ERROR_WANT_WRITE:
io_reset(io, EV_WRITE, io_dispatch_connect_ssl);
break;
default:
io->error = io_ssl_error();
ssl_error("io_dispatch_connect_ssl:SSL_connect");
io_callback(io, IO_ERROR);
break;
}
leave:
io_frame_leave(io);
}
void
io_dispatch_read_ssl(int fd, short event, void *humppa)
{
struct io *io = humppa;
int n, saved_errno;
io_frame_enter("io_dispatch_read_ssl", io, event);
if (event == EV_TIMEOUT) {
io_callback(io, IO_TIMEOUT);
goto leave;
}
again:
switch ((n = iobuf_read_ssl(io->iobuf, (SSL*)io->ssl))) {
case IOBUF_WANT_READ:
io_reset(io, EV_READ, io_dispatch_read_ssl);
break;
case IOBUF_WANT_WRITE:
io_reset(io, EV_WRITE, io_dispatch_read_ssl);
break;
case IOBUF_CLOSED:
io_callback(io, IO_DISCONNECTED);
break;
case IOBUF_ERROR:
saved_errno = errno;
io->error = strerror(errno);
errno = saved_errno;
io_callback(io, IO_ERROR);
break;
case IOBUF_SSLERROR:
io->error = io_ssl_error();
ssl_error("io_dispatch_read_ssl:SSL_read");
io_callback(io, IO_ERROR);
break;
default:
io_debug("io_dispatch_read_ssl(...) -> r=%d\n", n);
io_callback(io, IO_DATAIN);
if (current == io && IO_READING(io) && SSL_pending(io->ssl))
goto again;
}
leave:
io_frame_leave(io);
}
void
io_dispatch_write_ssl(int fd, short event, void *humppa)
{
struct io *io = humppa;
int n, saved_errno;
size_t w2, w;
io_frame_enter("io_dispatch_write_ssl", io, event);
if (event == EV_TIMEOUT) {
io_callback(io, IO_TIMEOUT);
goto leave;
}
w = io_queued(io);
switch ((n = iobuf_write_ssl(io->iobuf, (SSL*)io->ssl))) {
case IOBUF_WANT_READ:
io_reset(io, EV_READ, io_dispatch_write_ssl);
break;
case IOBUF_WANT_WRITE:
io_reset(io, EV_WRITE, io_dispatch_write_ssl);
break;
case IOBUF_CLOSED:
io_callback(io, IO_DISCONNECTED);
break;
case IOBUF_ERROR:
saved_errno = errno;
io->error = strerror(errno);
errno = saved_errno;
io_callback(io, IO_ERROR);
break;
case IOBUF_SSLERROR:
io->error = io_ssl_error();
ssl_error("io_dispatch_write_ssl:SSL_write");
io_callback(io, IO_ERROR);
break;
default:
io_debug("io_dispatch_write_ssl(...) -> w=%d\n", n);
w2 = io_queued(io);
if (w > io->lowat && w2 <= io->lowat)
io_callback(io, IO_LOWAT);
break;
}
leave:
io_frame_leave(io);
}
void
io_reload_ssl(struct io *io)
{
short ev = 0;
void (*dispatch)(int, short, void*) = NULL;
switch (io->state) {
case IO_STATE_CONNECT_SSL:
ev = EV_WRITE;
dispatch = io_dispatch_connect_ssl;
break;
case IO_STATE_ACCEPT_SSL:
ev = EV_READ;
dispatch = io_dispatch_accept_ssl;
break;
case IO_STATE_UP:
ev = 0;
if (IO_READING(io) && !(io->flags & IO_PAUSE_IN)) {
ev = EV_READ;
dispatch = io_dispatch_read_ssl;
}
else if (IO_WRITING(io) && !(io->flags & IO_PAUSE_OUT) && io_queued(io)) {
ev = EV_WRITE;
dispatch = io_dispatch_write_ssl;
}
if (! ev)
return; /* paused */
break;
default:
errx(1, "io_reload_ssl(): bad state");
}
io_reset(io, ev, dispatch);
}
#endif /* IO_SSL */