blob: 74fe0b296fa6724e7516385aff00ae79d8f9b4e9 [file] [log] [blame]
/*
* Functions operating on SOCK_STREAM and buffers.
*
* Copyright 2000-2011 Willy Tarreau <w@1wt.eu>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*
*/
#define _GNU_SOURCE
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <netinet/tcp.h>
#include <common/compat.h>
#include <common/config.h>
#include <common/debug.h>
#include <common/standard.h>
#include <common/ticks.h>
#include <common/time.h>
#include <proto/buffers.h>
#include <proto/fd.h>
#include <proto/freq_ctr.h>
#include <proto/frontend.h>
#include <proto/log.h>
#include <proto/pipe.h>
#include <proto/protocols.h>
#include <proto/stream_sock.h>
#include <proto/task.h>
#include <types/global.h>
#if defined(CONFIG_HAP_LINUX_SPLICE)
#include <common/splice.h>
/* A pipe contains 16 segments max, and it's common to see segments of 1448 bytes
* because of timestamps. Use this as a hint for not looping on splice().
*/
#define SPLICE_FULL_HINT 16*1448
/* how many data we attempt to splice at once when the buffer is configured for
* infinite forwarding */
#define MAX_SPLICE_AT_ONCE (1<<30)
/* Returns :
* -1 if splice is not possible or not possible anymore and we must switch to
* user-land copy (eg: to_forward reached)
* 0 when we know that polling is required to get more data (EAGAIN)
* 1 for all other cases (we can safely try again, or if an activity has been
* detected (DATA/NULL/ERR))
* Sets :
* BF_READ_NULL
* BF_READ_PARTIAL
* BF_WRITE_PARTIAL (during copy)
* BF_OUT_EMPTY (during copy)
* SI_FL_ERR
* SI_FL_WAIT_ROOM
* (SI_FL_WAIT_RECV)
*
* This function automatically allocates a pipe from the pipe pool. It also
* carefully ensures to clear b->pipe whenever it leaves the pipe empty.
*/
static int stream_sock_splice_in(struct buffer *b, struct stream_interface *si)
{
static int splice_detects_close;
int fd = si->fd;
int ret;
unsigned long max;
int retval = 1;
if (!b->to_forward)
return -1;
if (!(b->flags & BF_KERN_SPLICING))
return -1;
if (buffer_not_empty(b)) {
/* We're embarrassed, there are already data pending in
* the buffer and we don't want to have them at two
* locations at a time. Let's indicate we need some
* place and ask the consumer to hurry.
*/
si->flags |= SI_FL_WAIT_ROOM;
EV_FD_CLR(fd, DIR_RD);
b->rex = TICK_ETERNITY;
b->cons->chk_snd(b->cons);
return 1;
}
if (unlikely(b->pipe == NULL)) {
if (pipes_used >= global.maxpipes || !(b->pipe = get_pipe())) {
b->flags &= ~BF_KERN_SPLICING;
return -1;
}
}
/* At this point, b->pipe is valid */
while (1) {
if (b->to_forward == BUF_INFINITE_FORWARD)
max = MAX_SPLICE_AT_ONCE;
else
max = b->to_forward;
if (!max) {
/* It looks like the buffer + the pipe already contain
* the maximum amount of data to be transferred. Try to
* send those data immediately on the other side if it
* is currently waiting.
*/
retval = -1; /* end of forwarding */
break;
}
ret = splice(fd, NULL, b->pipe->prod, NULL, max,
SPLICE_F_MOVE|SPLICE_F_NONBLOCK);
if (ret <= 0) {
if (ret == 0) {
/* connection closed. This is only detected by
* recent kernels (>= 2.6.27.13). If we notice
* it works, we store the info for later use.
*/
splice_detects_close = 1;
b->flags |= BF_READ_NULL;
retval = 1; /* no need for further polling */
break;
}
if (errno == EAGAIN) {
/* there are two reasons for EAGAIN :
* - nothing in the socket buffer (standard)
* - pipe is full
* - the connection is closed (kernel < 2.6.27.13)
* Since we don't know if pipe is full, we'll
* stop if the pipe is not empty. Anyway, we
* will almost always fill/empty the pipe.
*/
if (b->pipe->data) {
si->flags |= SI_FL_WAIT_ROOM;
retval = 1;
break;
}
/* We don't know if the connection was closed,
* but if we know splice detects close, then we
* know it for sure.
* But if we're called upon POLLIN with an empty
* pipe and get EAGAIN, it is suspect enough to
* try to fall back to the normal recv scheme
* which will be able to deal with the situation.
*/
if (splice_detects_close)
retval = 0; /* we know for sure that it's EAGAIN */
else
retval = -1;
break;
}
if (errno == ENOSYS || errno == EINVAL) {
/* splice not supported on this end, disable it */
b->flags &= ~BF_KERN_SPLICING;
si->flags &= ~SI_FL_CAP_SPLICE;
put_pipe(b->pipe);
b->pipe = NULL;
return -1;
}
/* here we have another error */
si->flags |= SI_FL_ERR;
retval = 1;
break;
} /* ret <= 0 */
if (b->to_forward != BUF_INFINITE_FORWARD)
b->to_forward -= ret;
b->total += ret;
b->pipe->data += ret;
b->flags |= BF_READ_PARTIAL;
b->flags &= ~BF_OUT_EMPTY;
if (b->pipe->data >= SPLICE_FULL_HINT ||
ret >= global.tune.recv_enough) {
/* We've read enough of it for this time. */
retval = 1;
break;
}
} /* while */
if (unlikely(!b->pipe->data)) {
put_pipe(b->pipe);
b->pipe = NULL;
}
return retval;
}
#endif /* CONFIG_HAP_LINUX_SPLICE */
/*
* this function is called on a read event from a stream socket.
* It returns 0 if we have a high confidence that we will not be
* able to read more data without polling first. Returns non-zero
* otherwise.
*/
int stream_sock_read(int fd) {
struct stream_interface *si = fdtab[fd].owner;
struct buffer *b = si->ib;
int ret, max, retval, cur_read;
int read_poll = MAX_READ_POLL_LOOPS;
#ifdef DEBUG_FULL
fprintf(stderr,"stream_sock_read : fd=%d, ev=0x%02x, owner=%p\n", fd, fdtab[fd].ev, fdtab[fd].owner);
#endif
retval = 1;
/* stop immediately on errors. Note that we DON'T want to stop on
* POLL_ERR, as the poller might report a write error while there
* are still data available in the recv buffer. This typically
* happens when we send too large a request to a backend server
* which rejects it before reading it all.
*/
if (fdtab[fd].state == FD_STERROR)
goto out_error;
/* stop here if we reached the end of data */
if ((fdtab[fd].ev & (FD_POLL_IN|FD_POLL_HUP)) == FD_POLL_HUP)
goto out_shutdown_r;
/* maybe we were called immediately after an asynchronous shutr */
if (b->flags & BF_SHUTR)
goto out_wakeup;
#if defined(CONFIG_HAP_LINUX_SPLICE)
if (b->to_forward >= MIN_SPLICE_FORWARD && b->flags & BF_KERN_SPLICING) {
/* Under Linux, if FD_POLL_HUP is set, we have reached the end.
* Since older splice() implementations were buggy and returned
* EAGAIN on end of read, let's bypass the call to splice() now.
*/
if (fdtab[fd].ev & FD_POLL_HUP)
goto out_shutdown_r;
retval = stream_sock_splice_in(b, si);
if (retval >= 0) {
if (si->flags & SI_FL_ERR)
goto out_error;
if (b->flags & BF_READ_NULL)
goto out_shutdown_r;
goto out_wakeup;
}
/* splice not possible (anymore), let's go on on standard copy */
}
#endif
cur_read = 0;
while (1) {
max = buffer_max_len(b) - buffer_len(b);
if (max <= 0) {
b->flags |= BF_FULL;
si->flags |= SI_FL_WAIT_ROOM;
break;
}
/*
* 1. compute the maximum block size we can read at once.
*/
if (buffer_empty(b)) {
/* let's realign the buffer to optimize I/O */
b->r = b->w = b->lr = b->data;
}
else if (b->r > b->w) {
/* remaining space wraps at the end, with a moving limit */
if (max > b->data + b->size - b->r)
max = b->data + b->size - b->r;
}
/* else max is already OK */
/*
* 2. read the largest possible block
*/
ret = recv(fd, b->r, max, 0);
if (ret > 0) {
b->r += ret;
b->i += ret;
cur_read += ret;
/* if we're allowed to directly forward data, we must update ->o */
if (b->to_forward && !(b->flags & (BF_SHUTW|BF_SHUTW_NOW))) {
unsigned long fwd = ret;
if (b->to_forward != BUF_INFINITE_FORWARD) {
if (fwd > b->to_forward)
fwd = b->to_forward;
b->to_forward -= fwd;
}
b->o += fwd;
b->i -= fwd;
b->flags &= ~BF_OUT_EMPTY;
}
if (fdtab[fd].state == FD_STCONN)
fdtab[fd].state = FD_STREADY;
b->flags |= BF_READ_PARTIAL;
if (b->r == b->data + b->size) {
b->r = b->data; /* wrap around the buffer */
}
b->total += ret;
if (buffer_len(b) >= buffer_max_len(b)) {
/* The buffer is now full, there's no point in going through
* the loop again.
*/
if (!(b->flags & BF_STREAMER_FAST) && (cur_read == buffer_len(b))) {
b->xfer_small = 0;
b->xfer_large++;
if (b->xfer_large >= 3) {
/* we call this buffer a fast streamer if it manages
* to be filled in one call 3 consecutive times.
*/
b->flags |= (BF_STREAMER | BF_STREAMER_FAST);
//fputc('+', stderr);
}
}
else if ((b->flags & (BF_STREAMER | BF_STREAMER_FAST)) &&
(cur_read <= b->size / 2)) {
b->xfer_large = 0;
b->xfer_small++;
if (b->xfer_small >= 2) {
/* if the buffer has been at least half full twice,
* we receive faster than we send, so at least it
* is not a "fast streamer".
*/
b->flags &= ~BF_STREAMER_FAST;
//fputc('-', stderr);
}
}
else {
b->xfer_small = 0;
b->xfer_large = 0;
}
b->flags |= BF_FULL;
si->flags |= SI_FL_WAIT_ROOM;
break;
}
/* if too many bytes were missing from last read, it means that
* it's pointless trying to read again because the system does
* not have them in buffers. BTW, if FD_POLL_HUP was present,
* it means that we have reached the end and that the connection
* is closed.
*/
if (ret < max) {
if ((b->flags & (BF_STREAMER | BF_STREAMER_FAST)) &&
(cur_read <= b->size / 2)) {
b->xfer_large = 0;
b->xfer_small++;
if (b->xfer_small >= 3) {
/* we have read less than half of the buffer in
* one pass, and this happened at least 3 times.
* This is definitely not a streamer.
*/
b->flags &= ~(BF_STREAMER | BF_STREAMER_FAST);
//fputc('!', stderr);
}
}
/* unfortunately, on level-triggered events, POLL_HUP
* is generally delivered AFTER the system buffer is
* empty, so this one might never match.
*/
if (fdtab[fd].ev & FD_POLL_HUP)
goto out_shutdown_r;
/* if a streamer has read few data, it may be because we
* have exhausted system buffers. It's not worth trying
* again.
*/
if (b->flags & BF_STREAMER)
break;
/* generally if we read something smaller than 1 or 2 MSS,
* it means that either we have exhausted the system's
* buffers (streamer or question-response protocol) or
* that the connection will be closed. Streamers are
* easily detected so we return early. For other cases,
* it's still better to perform a last read to be sure,
* because it may save one complete poll/read/wakeup cycle
* in case of shutdown.
*/
if (ret < MIN_RET_FOR_READ_LOOP && b->flags & BF_STREAMER)
break;
/* if we read a large block smaller than what we requested,
* it's almost certain we'll never get anything more.
*/
if (ret >= global.tune.recv_enough)
break;
}
if ((b->flags & BF_READ_DONTWAIT) || --read_poll <= 0)
break;
}
else if (ret == 0) {
/* connection closed */
goto out_shutdown_r;
}
else if (errno == EAGAIN) {
/* Ignore EAGAIN but inform the poller that there is
* nothing to read left if we did not read much, ie
* less than what we were still expecting to read.
* But we may have done some work justifying to notify
* the task.
*/
if (cur_read < MIN_RET_FOR_READ_LOOP)
retval = 0;
break;
}
else {
goto out_error;
}
} /* while (1) */
out_wakeup:
/* We might have some data the consumer is waiting for.
* We can do fast-forwarding, but we avoid doing this for partial
* buffers, because it is very likely that it will be done again
* immediately afterwards once the following data is parsed (eg:
* HTTP chunking).
*/
if (b->pipe || /* always try to send spliced data */
(b->i == 0 && (b->cons->flags & SI_FL_WAIT_DATA))) {
int last_len = b->pipe ? b->pipe->data : 0;
b->cons->chk_snd(b->cons);
/* check if the consumer has freed some space */
if (!(b->flags & BF_FULL) &&
(!last_len || !b->pipe || b->pipe->data < last_len))
si->flags &= ~SI_FL_WAIT_ROOM;
}
if (si->flags & SI_FL_WAIT_ROOM) {
EV_FD_CLR(fd, DIR_RD);
b->rex = TICK_ETERNITY;
}
else if ((b->flags & (BF_SHUTR|BF_READ_PARTIAL|BF_FULL|BF_DONT_READ|BF_READ_NOEXP)) == BF_READ_PARTIAL)
b->rex = tick_add_ifset(now_ms, b->rto);
/* we have to wake up if there is a special event or if we don't have
* any more data to forward.
*/
if ((b->flags & (BF_READ_NULL|BF_READ_ERROR)) ||
si->state != SI_ST_EST ||
(si->flags & SI_FL_ERR) ||
((b->flags & BF_READ_PARTIAL) && (!b->to_forward || b->cons->state != SI_ST_EST)))
task_wakeup(si->owner, TASK_WOKEN_IO);
if (b->flags & BF_READ_ACTIVITY)
b->flags &= ~BF_READ_DONTWAIT;
fdtab[fd].ev &= ~FD_POLL_IN;
return retval;
out_shutdown_r:
/* we received a shutdown */
fdtab[fd].ev &= ~FD_POLL_HUP;
b->flags |= BF_READ_NULL;
if (b->flags & BF_AUTO_CLOSE)
buffer_shutw_now(b);
stream_sock_shutr(si);
goto out_wakeup;
out_error:
/* Read error on the file descriptor. We mark the FD as STERROR so
* that we don't use it anymore. The error is reported to the stream
* interface which will take proper action. We must not perturbate the
* buffer because the stream interface wants to ensure transparent
* connection retries.
*/
fdtab[fd].state = FD_STERROR;
fdtab[fd].ev &= ~FD_POLL_STICKY;
EV_FD_REM(fd);
si->flags |= SI_FL_ERR;
retval = 1;
goto out_wakeup;
}
/*
* This function is called to send buffer data to a stream socket.
* It returns -1 in case of unrecoverable error, 0 if the caller needs to poll
* before calling it again, otherwise 1. If a pipe was associated with the
* buffer and it empties it, it releases it as well.
*/
static int stream_sock_write_loop(struct stream_interface *si, struct buffer *b)
{
int write_poll = MAX_WRITE_POLL_LOOPS;
int retval = 1;
int ret, max;
if (unlikely(si->send_proxy_ofs)) {
/* The target server expects a PROXY line to be sent first.
* If the send_proxy_ofs is negative, it corresponds to the
* offset to start sending from then end of the proxy string
* (which is recomputed every time since it's constant). If
* it is positive, it means we have to send from the start.
*/
ret = make_proxy_line(trash, sizeof(trash),
&b->prod->addr.from, &b->prod->addr.to);
if (!ret)
return -1;
if (si->send_proxy_ofs > 0)
si->send_proxy_ofs = -ret; /* first call */
/* we have to send trash from (ret+sp for -sp bytes) */
ret = send(si->fd, trash + ret + si->send_proxy_ofs, -si->send_proxy_ofs,
(b->flags & BF_OUT_EMPTY) ? 0 : MSG_MORE);
if (ret > 0) {
if (fdtab[si->fd].state == FD_STCONN)
fdtab[si->fd].state = FD_STREADY;
si->send_proxy_ofs += ret; /* becomes zero once complete */
b->flags |= BF_WRITE_NULL; /* connect() succeeded */
}
else if (ret == 0 || errno == EAGAIN) {
/* nothing written, we need to poll for write first */
return 0;
}
else {
/* bad, we got an error */
return -1;
}
}
#if defined(CONFIG_HAP_LINUX_SPLICE)
while (b->pipe) {
ret = splice(b->pipe->cons, NULL, si->fd, NULL, b->pipe->data,
SPLICE_F_MOVE|SPLICE_F_NONBLOCK);
if (ret <= 0) {
if (ret == 0 || errno == EAGAIN) {
retval = 0;
return retval;
}
/* here we have another error */
retval = -1;
return retval;
}
b->flags |= BF_WRITE_PARTIAL;
b->pipe->data -= ret;
if (!b->pipe->data) {
put_pipe(b->pipe);
b->pipe = NULL;
break;
}
if (--write_poll <= 0)
return retval;
/* The only reason we did not empty the pipe is that the output
* buffer is full.
*/
return 0;
}
/* At this point, the pipe is empty, but we may still have data pending
* in the normal buffer.
*/
#endif
if (!b->o) {
b->flags |= BF_OUT_EMPTY;
return retval;
}
/* when we're in this loop, we already know that there is no spliced
* data left, and that there are sendable buffered data.
*/
while (1) {
if (b->r > b->w)
max = b->r - b->w;
else
max = b->data + b->size - b->w;
/* limit the amount of outgoing data if required */
if (max > b->o)
max = b->o;
/* check if we want to inform the kernel that we're interested in
* sending more data after this call. We want this if :
* - we're about to close after this last send and want to merge
* the ongoing FIN with the last segment.
* - we know we can't send everything at once and must get back
* here because of unaligned data
* - there is still a finite amount of data to forward
* The test is arranged so that the most common case does only 2
* tests.
*/
if (MSG_NOSIGNAL && MSG_MORE) {
unsigned int send_flag = MSG_DONTWAIT | MSG_NOSIGNAL;
if ((!(b->flags & BF_NEVER_WAIT) &&
((b->to_forward && b->to_forward != BUF_INFINITE_FORWARD) ||
(b->flags & BF_EXPECT_MORE))) ||
((b->flags & (BF_SHUTW|BF_SHUTW_NOW|BF_HIJACK)) == BF_SHUTW_NOW && (max == b->o)) ||
(max != b->o)) {
send_flag |= MSG_MORE;
}
/* this flag has precedence over the rest */
if (b->flags & BF_SEND_DONTWAIT)
send_flag &= ~MSG_MORE;
ret = send(si->fd, b->w, max, send_flag);
} else {
int skerr;
socklen_t lskerr = sizeof(skerr);
ret = getsockopt(si->fd, SOL_SOCKET, SO_ERROR, &skerr, &lskerr);
if (ret == -1 || skerr)
ret = -1;
else
ret = send(si->fd, b->w, max, MSG_DONTWAIT);
}
if (ret > 0) {
if (fdtab[si->fd].state == FD_STCONN)
fdtab[si->fd].state = FD_STREADY;
b->flags |= BF_WRITE_PARTIAL;
b->w += ret;
if (b->w == b->data + b->size)
b->w = b->data; /* wrap around the buffer */
b->o -= ret;
if (likely(!buffer_len(b)))
/* optimize data alignment in the buffer */
b->r = b->w = b->lr = b->data;
if (likely(buffer_len(b) < buffer_max_len(b)))
b->flags &= ~BF_FULL;
if (!b->o) {
/* Always clear both flags once everything has been sent, they're one-shot */
b->flags &= ~(BF_EXPECT_MORE | BF_SEND_DONTWAIT);
if (likely(!b->pipe))
b->flags |= BF_OUT_EMPTY;
break;
}
/* if the system buffer is full, don't insist */
if (ret < max)
break;
if (--write_poll <= 0)
break;
}
else if (ret == 0 || errno == EAGAIN) {
/* nothing written, we need to poll for write first */
retval = 0;
break;
}
else {
/* bad, we got an error */
retval = -1;
break;
}
} /* while (1) */
return retval;
}
/*
* This function is called on a write event from a stream socket.
* It returns 0 if the caller needs to poll before calling it again, otherwise
* non-zero.
*/
int stream_sock_write(int fd)
{
struct stream_interface *si = fdtab[fd].owner;
struct buffer *b = si->ob;
int retval = 1;
#ifdef DEBUG_FULL
fprintf(stderr,"stream_sock_write : fd=%d, owner=%p\n", fd, fdtab[fd].owner);
#endif
retval = 1;
if (fdtab[fd].state == FD_STERROR)
goto out_error;
/* we might have been called just after an asynchronous shutw */
if (b->flags & BF_SHUTW)
goto out_wakeup;
if (likely(!(b->flags & BF_OUT_EMPTY) || si->send_proxy_ofs)) {
/* OK there are data waiting to be sent */
retval = stream_sock_write_loop(si, b);
if (retval < 0)
goto out_error;
else if (retval == 0 && si->send_proxy_ofs)
goto out_may_wakeup; /* we failed to send the PROXY string */
}
else {
/* may be we have received a connection acknowledgement in TCP mode without data */
if (likely(fdtab[fd].state == FD_STCONN)) {
/* We have no data to send to check the connection, and
* getsockopt() will not inform us whether the connection
* is still pending. So we'll reuse connect() to check the
* state of the socket. This has the advantage of givig us
* the following info :
* - error
* - connecting (EALREADY, EINPROGRESS)
* - connected (EISCONN, 0)
*/
if ((connect(fd, fdinfo[fd].peeraddr, fdinfo[fd].peerlen) == 0))
errno = 0;
if (errno == EALREADY || errno == EINPROGRESS) {
retval = 0;
goto out_may_wakeup;
}
if (errno && errno != EISCONN)
goto out_error;
/* OK we just need to indicate that we got a connection
* and that we wrote nothing.
*/
b->flags |= BF_WRITE_NULL;
fdtab[fd].state = FD_STREADY;
}
/* Funny, we were called to write something but there wasn't
* anything. We can get there, for example if we were woken up
* on a write event to finish the splice, but the ->o is 0
* so we cannot write anything from the buffer. Let's disable
* the write event and pretend we never came there.
*/
}
if (b->flags & BF_OUT_EMPTY) {
/* the connection is established but we can't write. Either the
* buffer is empty, or we just refrain from sending because the
* ->o limit was reached. Maybe we just wrote the last
* chunk and need to close.
*/
if (((b->flags & (BF_SHUTW|BF_HIJACK|BF_SHUTW_NOW)) == BF_SHUTW_NOW) &&
(si->state == SI_ST_EST)) {
stream_sock_shutw(si);
goto out_wakeup;
}
if ((b->flags & (BF_SHUTW|BF_SHUTW_NOW|BF_FULL|BF_HIJACK)) == 0)
si->flags |= SI_FL_WAIT_DATA;
EV_FD_CLR(fd, DIR_WR);
b->wex = TICK_ETERNITY;
}
out_may_wakeup:
if (b->flags & BF_WRITE_ACTIVITY) {
/* update timeout if we have written something */
if ((b->flags & (BF_OUT_EMPTY|BF_SHUTW|BF_WRITE_PARTIAL)) == BF_WRITE_PARTIAL)
b->wex = tick_add_ifset(now_ms, b->wto);
out_wakeup:
if (tick_isset(si->ib->rex) && !(si->flags & SI_FL_INDEP_STR)) {
/* Note: to prevent the client from expiring read timeouts
* during writes, we refresh it. We only do this if the
* interface is not configured for "independant streams",
* because for some applications it's better not to do this,
* for instance when continuously exchanging small amounts
* of data which can full the socket buffers long before a
* write timeout is detected.
*/
si->ib->rex = tick_add_ifset(now_ms, si->ib->rto);
}
/* the producer might be waiting for more room to store data */
if (likely((b->flags & (BF_SHUTW|BF_WRITE_PARTIAL|BF_FULL|BF_DONT_READ)) == BF_WRITE_PARTIAL &&
(b->prod->flags & SI_FL_WAIT_ROOM)))
b->prod->chk_rcv(b->prod);
/* we have to wake up if there is a special event or if we don't have
* any more data to forward and it's not planned to send any more.
*/
if (likely((b->flags & (BF_WRITE_NULL|BF_WRITE_ERROR|BF_SHUTW)) ||
((b->flags & BF_OUT_EMPTY) && !b->to_forward) ||
si->state != SI_ST_EST ||
b->prod->state != SI_ST_EST))
task_wakeup(si->owner, TASK_WOKEN_IO);
}
fdtab[fd].ev &= ~FD_POLL_OUT;
return retval;
out_error:
/* Write error on the file descriptor. We mark the FD as STERROR so
* that we don't use it anymore. The error is reported to the stream
* interface which will take proper action. We must not perturbate the
* buffer because the stream interface wants to ensure transparent
* connection retries.
*/
fdtab[fd].state = FD_STERROR;
fdtab[fd].ev &= ~FD_POLL_STICKY;
EV_FD_REM(fd);
si->flags |= SI_FL_ERR;
task_wakeup(si->owner, TASK_WOKEN_IO);
return 1;
}
/*
* This function performs a shutdown-write on a stream interface in a connected or
* init state (it does nothing for other states). It either shuts the write side
* or closes the file descriptor and marks itself as closed. The buffer flags are
* updated to reflect the new state. It does also close everything is the SI was
* marked as being in error state.
*/
void stream_sock_shutw(struct stream_interface *si)
{
si->ob->flags &= ~BF_SHUTW_NOW;
if (si->ob->flags & BF_SHUTW)
return;
si->ob->flags |= BF_SHUTW;
si->ob->wex = TICK_ETERNITY;
si->flags &= ~SI_FL_WAIT_DATA;
switch (si->state) {
case SI_ST_EST:
/* we have to shut before closing, otherwise some short messages
* may never leave the system, especially when there are remaining
* unread data in the socket input buffer, or when nolinger is set.
* However, if SI_FL_NOLINGER is explicitly set, we know there is
* no risk so we close both sides immediately.
*/
if (si->flags & SI_FL_ERR) {
/* quick close, the socket is already shut. Remove pending flags. */
si->flags &= ~SI_FL_NOLINGER;
} else if (si->flags & SI_FL_NOLINGER) {
si->flags &= ~SI_FL_NOLINGER;
setsockopt(si->fd, SOL_SOCKET, SO_LINGER,
(struct linger *) &nolinger, sizeof(struct linger));
} else {
EV_FD_CLR(si->fd, DIR_WR);
shutdown(si->fd, SHUT_WR);
if (!(si->ib->flags & (BF_SHUTR|BF_DONT_READ)))
return;
}
/* fall through */
case SI_ST_CON:
/* we may have to close a pending connection, and mark the
* response buffer as shutr
*/
fd_delete(si->fd);
/* fall through */
case SI_ST_CER:
case SI_ST_QUE:
case SI_ST_TAR:
si->state = SI_ST_DIS;
if (si->release)
si->release(si);
default:
si->flags &= ~SI_FL_WAIT_ROOM;
si->ib->flags |= BF_SHUTR;
si->ib->rex = TICK_ETERNITY;
si->exp = TICK_ETERNITY;
}
}
/*
* This function performs a shutdown-read on a stream interface in a connected or
* init state (it does nothing for other states). It either shuts the read side
* or closes the file descriptor and marks itself as closed. The buffer flags are
* updated to reflect the new state.
*/
void stream_sock_shutr(struct stream_interface *si)
{
si->ib->flags &= ~BF_SHUTR_NOW;
if (si->ib->flags & BF_SHUTR)
return;
si->ib->flags |= BF_SHUTR;
si->ib->rex = TICK_ETERNITY;
si->flags &= ~SI_FL_WAIT_ROOM;
if (si->state != SI_ST_EST && si->state != SI_ST_CON)
return;
if (si->ob->flags & BF_SHUTW) {
fd_delete(si->fd);
si->state = SI_ST_DIS;
si->exp = TICK_ETERNITY;
if (si->release)
si->release(si);
return;
}
EV_FD_CLR(si->fd, DIR_RD);
return;
}
/*
* Updates a connected stream_sock file descriptor status and timeouts
* according to the buffers' flags. It should only be called once after the
* buffer flags have settled down, and before they are cleared. It doesn't
* harm to call it as often as desired (it just slightly hurts performance).
*/
void stream_sock_data_finish(struct stream_interface *si)
{
struct buffer *ib = si->ib;
struct buffer *ob = si->ob;
int fd = si->fd;
DPRINTF(stderr,"[%u] %s: fd=%d owner=%p ib=%p, ob=%p, exp(r,w)=%u,%u ibf=%08x obf=%08x ibh=%d ibt=%d obh=%d obd=%d si=%d\n",
now_ms, __FUNCTION__,
fd, fdtab[fd].owner,
ib, ob,
ib->rex, ob->wex,
ib->flags, ob->flags,
ib->i, ib->o, ob->i, ob->o, si->state);
/* Check if we need to close the read side */
if (!(ib->flags & BF_SHUTR)) {
/* Read not closed, update FD status and timeout for reads */
if (ib->flags & (BF_FULL|BF_HIJACK|BF_DONT_READ)) {
/* stop reading */
if (!(si->flags & SI_FL_WAIT_ROOM)) {
if ((ib->flags & (BF_FULL|BF_HIJACK|BF_DONT_READ)) == BF_FULL)
si->flags |= SI_FL_WAIT_ROOM;
EV_FD_COND_C(fd, DIR_RD);
ib->rex = TICK_ETERNITY;
}
}
else {
/* (re)start reading and update timeout. Note: we don't recompute the timeout
* everytime we get here, otherwise it would risk never to expire. We only
* update it if is was not yet set. The stream socket handler will already
* have updated it if there has been a completed I/O.
*/
si->flags &= ~SI_FL_WAIT_ROOM;
EV_FD_COND_S(fd, DIR_RD);
if (!(ib->flags & (BF_READ_NOEXP|BF_DONT_READ)) && !tick_isset(ib->rex))
ib->rex = tick_add_ifset(now_ms, ib->rto);
}
}
/* Check if we need to close the write side */
if (!(ob->flags & BF_SHUTW)) {
/* Write not closed, update FD status and timeout for writes */
if (ob->flags & BF_OUT_EMPTY) {
/* stop writing */
if (!(si->flags & SI_FL_WAIT_DATA)) {
if ((ob->flags & (BF_FULL|BF_HIJACK|BF_SHUTW_NOW)) == 0)
si->flags |= SI_FL_WAIT_DATA;
EV_FD_COND_C(fd, DIR_WR);
ob->wex = TICK_ETERNITY;
}
}
else {
/* (re)start writing and update timeout. Note: we don't recompute the timeout
* everytime we get here, otherwise it would risk never to expire. We only
* update it if is was not yet set. The stream socket handler will already
* have updated it if there has been a completed I/O.
*/
si->flags &= ~SI_FL_WAIT_DATA;
EV_FD_COND_S(fd, DIR_WR);
if (!tick_isset(ob->wex)) {
ob->wex = tick_add_ifset(now_ms, ob->wto);
if (tick_isset(ib->rex) && !(si->flags & SI_FL_INDEP_STR)) {
/* Note: depending on the protocol, we don't know if we're waiting
* for incoming data or not. So in order to prevent the socket from
* expiring read timeouts during writes, we refresh the read timeout,
* except if it was already infinite or if we have explicitly setup
* independant streams.
*/
ib->rex = tick_add_ifset(now_ms, ib->rto);
}
}
}
}
}
/* This function is used for inter-stream-interface calls. It is called by the
* consumer to inform the producer side that it may be interested in checking
* for free space in the buffer. Note that it intentionally does not update
* timeouts, so that we can still check them later at wake-up.
*/
void stream_sock_chk_rcv(struct stream_interface *si)
{
struct buffer *ib = si->ib;
DPRINTF(stderr,"[%u] %s: fd=%d owner=%p ib=%p, ob=%p, exp(r,w)=%u,%u ibf=%08x obf=%08x ibh=%d ibt=%d obh=%d obd=%d si=%d\n",
now_ms, __FUNCTION__,
si->fd, fdtab[si->fd].owner,
ib, si->ob,
ib->rex, si->ob->wex,
ib->flags, si->ob->flags,
ib->i, ib->o, si->ob->i, si->ob->o, si->state);
if (unlikely(si->state != SI_ST_EST || (ib->flags & BF_SHUTR)))
return;
if (ib->flags & (BF_FULL|BF_HIJACK|BF_DONT_READ)) {
/* stop reading */
if ((ib->flags & (BF_FULL|BF_HIJACK|BF_DONT_READ)) == BF_FULL)
si->flags |= SI_FL_WAIT_ROOM;
EV_FD_COND_C(si->fd, DIR_RD);
}
else {
/* (re)start reading */
si->flags &= ~SI_FL_WAIT_ROOM;
EV_FD_COND_S(si->fd, DIR_RD);
}
}
/* This function is used for inter-stream-interface calls. It is called by the
* producer to inform the consumer side that it may be interested in checking
* for data in the buffer. Note that it intentionally does not update timeouts,
* so that we can still check them later at wake-up.
*/
void stream_sock_chk_snd(struct stream_interface *si)
{
struct buffer *ob = si->ob;
int retval;
DPRINTF(stderr,"[%u] %s: fd=%d owner=%p ib=%p, ob=%p, exp(r,w)=%u,%u ibf=%08x obf=%08x ibh=%d ibt=%d obh=%d obd=%d si=%d\n",
now_ms, __FUNCTION__,
si->fd, fdtab[si->fd].owner,
si->ib, ob,
si->ib->rex, ob->wex,
si->ib->flags, ob->flags,
si->ib->i, si->ib->o, ob->i, ob->o, si->state);
if (unlikely(si->state != SI_ST_EST || (ob->flags & BF_SHUTW)))
return;
if (unlikely((ob->flags & BF_OUT_EMPTY) && !(si->send_proxy_ofs))) /* called with nothing to send ! */
return;
if (!ob->pipe && /* spliced data wants to be forwarded ASAP */
(!(si->flags & SI_FL_WAIT_DATA) || /* not waiting for data */
(fdtab[si->fd].ev & FD_POLL_OUT))) /* we'll be called anyway */
return;
retval = stream_sock_write_loop(si, ob);
/* here, we have :
* retval < 0 if an error was encountered during write.
* retval = 0 if we can't write anymore without polling
* retval = 1 if we're invited to come back when desired
*/
if (retval < 0) {
/* Write error on the file descriptor. We mark the FD as STERROR so
* that we don't use it anymore and we notify the task.
*/
fdtab[si->fd].state = FD_STERROR;
fdtab[si->fd].ev &= ~FD_POLL_STICKY;
EV_FD_REM(si->fd);
si->flags |= SI_FL_ERR;
goto out_wakeup;
}
else if (retval == 0 && si->send_proxy_ofs)
goto out_may_wakeup; /* we failed to send the PROXY string */
/* OK, so now we know that retval >= 0 means that some data might have
* been sent, and that we may have to poll first. We have to do that
* too if the buffer is not empty.
*/
if (ob->flags & BF_OUT_EMPTY) {
/* the connection is established but we can't write. Either the
* buffer is empty, or we just refrain from sending because the
* ->o limit was reached. Maybe we just wrote the last
* chunk and need to close.
*/
if (((ob->flags & (BF_SHUTW|BF_HIJACK|BF_AUTO_CLOSE|BF_SHUTW_NOW)) ==
(BF_AUTO_CLOSE|BF_SHUTW_NOW)) &&
(si->state == SI_ST_EST)) {
stream_sock_shutw(si);
goto out_wakeup;
}
if ((ob->flags & (BF_SHUTW|BF_SHUTW_NOW|BF_FULL|BF_HIJACK)) == 0)
si->flags |= SI_FL_WAIT_DATA;
ob->wex = TICK_ETERNITY;
}
else {
/* Otherwise there are remaining data to be sent in the buffer,
* which means we have to poll before doing so.
*/
EV_FD_COND_S(si->fd, DIR_WR);
si->flags &= ~SI_FL_WAIT_DATA;
if (!tick_isset(ob->wex))
ob->wex = tick_add_ifset(now_ms, ob->wto);
}
out_may_wakeup:
if (likely(ob->flags & BF_WRITE_ACTIVITY)) {
/* update timeout if we have written something */
if ((ob->flags & (BF_OUT_EMPTY|BF_SHUTW|BF_WRITE_PARTIAL)) == BF_WRITE_PARTIAL)
ob->wex = tick_add_ifset(now_ms, ob->wto);
if (tick_isset(si->ib->rex) && !(si->flags & SI_FL_INDEP_STR)) {
/* Note: to prevent the client from expiring read timeouts
* during writes, we refresh it. We only do this if the
* interface is not configured for "independant streams",
* because for some applications it's better not to do this,
* for instance when continuously exchanging small amounts
* of data which can full the socket buffers long before a
* write timeout is detected.
*/
si->ib->rex = tick_add_ifset(now_ms, si->ib->rto);
}
}
/* in case of special condition (error, shutdown, end of write...), we
* have to notify the task.
*/
if (likely((ob->flags & (BF_WRITE_NULL|BF_WRITE_ERROR|BF_SHUTW)) ||
((ob->flags & BF_OUT_EMPTY) && !ob->to_forward) ||
si->state != SI_ST_EST)) {
out_wakeup:
if (!(si->flags & SI_FL_DONT_WAKE) && si->owner)
task_wakeup(si->owner, TASK_WOKEN_IO);
}
}
/* This function is called on a read event from a listening socket, corresponding
* to an accept. It tries to accept as many connections as possible, and for each
* calls the listener's accept handler (generally the frontend's accept handler).
*/
int stream_sock_accept(int fd)
{
struct listener *l = fdtab[fd].owner;
struct proxy *p = l->frontend;
int max_accept = global.tune.maxaccept;
int cfd;
int ret;
if (unlikely(l->nbconn >= l->maxconn)) {
listener_full(l);
return 0;
}
if (global.cps_lim && !(l->options & LI_O_UNLIMITED)) {
int max = freq_ctr_remain(&global.conn_per_sec, global.cps_lim, 0);
if (unlikely(!max)) {
/* frontend accept rate limit was reached */
limit_listener(l, &global_listener_queue);
task_schedule(global_listener_queue_task, tick_add(now_ms, next_event_delay(&global.conn_per_sec, global.cps_lim, 0)));
return 0;
}
if (max_accept > max)
max_accept = max;
}
if (p && p->fe_sps_lim) {
int max = freq_ctr_remain(&p->fe_sess_per_sec, p->fe_sps_lim, 0);
if (unlikely(!max)) {
/* frontend accept rate limit was reached */
limit_listener(l, &p->listener_queue);
task_schedule(p->task, tick_add(now_ms, next_event_delay(&p->fe_sess_per_sec, p->fe_sps_lim, 0)));
return 0;
}
if (max_accept > max)
max_accept = max;
}
/* Note: if we fail to allocate a connection because of configured
* limits, we'll schedule a new attempt worst 1 second later in the
* worst case. If we fail due to system limits or temporary resource
* shortage, we try again 100ms later in the worst case.
*/
while (max_accept--) {
struct sockaddr_storage addr;
socklen_t laddr = sizeof(addr);
if (unlikely(actconn >= global.maxconn) && !(l->options & LI_O_UNLIMITED)) {
limit_listener(l, &global_listener_queue);
task_schedule(global_listener_queue_task, tick_add(now_ms, 1000)); /* try again in 1 second */
return 0;
}
if (unlikely(p && p->feconn >= p->maxconn)) {
limit_listener(l, &p->listener_queue);
return 0;
}
cfd = accept(fd, (struct sockaddr *)&addr, &laddr);
if (unlikely(cfd == -1)) {
switch (errno) {
case EAGAIN:
case EINTR:
case ECONNABORTED:
return 0; /* nothing more to accept */
case ENFILE:
if (p)
send_log(p, LOG_EMERG,
"Proxy %s reached system FD limit at %d. Please check system tunables.\n",
p->id, maxfd);
limit_listener(l, &global_listener_queue);
task_schedule(global_listener_queue_task, tick_add(now_ms, 100)); /* try again in 100 ms */
return 0;
case EMFILE:
if (p)
send_log(p, LOG_EMERG,
"Proxy %s reached process FD limit at %d. Please check 'ulimit-n' and restart.\n",
p->id, maxfd);
limit_listener(l, &global_listener_queue);
task_schedule(global_listener_queue_task, tick_add(now_ms, 100)); /* try again in 100 ms */
return 0;
case ENOBUFS:
case ENOMEM:
if (p)
send_log(p, LOG_EMERG,
"Proxy %s reached system memory limit at %d sockets. Please check system tunables.\n",
p->id, maxfd);
limit_listener(l, &global_listener_queue);
task_schedule(global_listener_queue_task, tick_add(now_ms, 100)); /* try again in 100 ms */
return 0;
default:
return 0;
}
}
if (unlikely(cfd >= global.maxsock)) {
send_log(p, LOG_EMERG,
"Proxy %s reached the configured maximum connection limit. Please check the global 'maxconn' value.\n",
p->id);
close(cfd);
limit_listener(l, &global_listener_queue);
task_schedule(global_listener_queue_task, tick_add(now_ms, 1000)); /* try again in 1 second */
return 0;
}
/* increase the per-process number of cumulated connections */
if (!(l->options & LI_O_UNLIMITED)) {
update_freq_ctr(&global.conn_per_sec, 1);
if (global.conn_per_sec.curr_ctr > global.cps_max)
global.cps_max = global.conn_per_sec.curr_ctr;
actconn++;
}
jobs++;
totalconn++;
l->nbconn++;
if (l->counters) {
if (l->nbconn > l->counters->conn_max)
l->counters->conn_max = l->nbconn;
}
ret = l->accept(l, cfd, &addr);
if (unlikely(ret <= 0)) {
/* The connection was closed by session_accept(). Either
* we just have to ignore it (ret == 0) or it's a critical
* error due to a resource shortage, and we must stop the
* listener (ret < 0).
*/
if (!(l->options & LI_O_UNLIMITED))
actconn--;
jobs--;
l->nbconn--;
if (ret == 0) /* successful termination */
continue;
limit_listener(l, &global_listener_queue);
task_schedule(global_listener_queue_task, tick_add(now_ms, 100)); /* try again in 100 ms */
return 0;
}
if (l->nbconn >= l->maxconn) {
listener_full(l);
return 0;
}
} /* end of while (p->feconn < p->maxconn) */
return 0;
}
/* Prepare a stream interface to be used in socket mode. */
void stream_sock_prepare_interface(struct stream_interface *si)
{
si->update = stream_sock_data_finish;
si->shutr = stream_sock_shutr;
si->shutw = stream_sock_shutw;
si->chk_rcv = stream_sock_chk_rcv;
si->chk_snd = stream_sock_chk_snd;
}
/*
* Local variables:
* c-indent-level: 8
* c-basic-offset: 8
* End:
*/