include/haproxy/channel-t.h - haproxy - Gitiles

 /*
  * include/haproxy/channel-t.h
  * Channel management definitions, macros and inline functions.
  *
  * Copyright (C) 2000-2014 Willy Tarreau - w@1wt.eu
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Lesser General Public
  * License as published by the Free Software Foundation, version 2.1
  * exclusively.
  *
  * This library is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * Lesser General Public License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with this library; if not, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301  USA
  */

 #ifndef _HAPROXY_CHANNEL_T_H
 #define _HAPROXY_CHANNEL_T_H

 #include <haproxy/api-t.h>
 #include <haproxy/buf-t.h>

 /* The CF_* macros designate Channel Flags, which may be ORed in the bit field
  * member 'flags' in struct channel. Here we have several types of flags :
  *
  *   - pure status flags, reported by the data layer, which must be cleared
  *     before doing further I/O :
  *     CF_*_NULL, CF_*_PARTIAL
  *
  *   - pure status flags, reported by stream-interface layer, which must also
  *     be cleared before doing further I/O :
  *     CF_*_TIMEOUT, CF_*_ERROR
  *
  *   - read-only indicators reported by lower data levels :
  *     CF_STREAMER, CF_STREAMER_FAST
  *
  *   - write-once status flags reported by the stream-interface layer :
  *     CF_SHUTR, CF_SHUTW
  *
  *   - persistent control flags managed only by application level :
  *     CF_SHUT*_NOW, CF_*_ENA
  *
  * The flags have been arranged for readability, so that the read and write
  * bits have the same position in a byte (read being the lower byte and write
  * the second one). All flag names are relative to the channel. For instance,
  * 'write' indicates the direction from the channel to the stream interface.
  */

 #define CF_READ_NULL      0x00000001  /* last read detected on producer side */
 #define CF_READ_PARTIAL   0x00000002  /* some data were read from producer or a read exception occurred */
 #define CF_READ_TIMEOUT   0x00000004  /* timeout while waiting for producer */
 #define CF_READ_ERROR     0x00000008  /* unrecoverable error on producer side */
 #define CF_READ_ACTIVITY  (CF_READ_NULL|CF_READ_PARTIAL|CF_READ_ERROR)

 /* unused: 0x00000010 */
 #define CF_SHUTR          0x00000020  /* producer has already shut down */
 #define CF_SHUTR_NOW      0x00000040  /* the producer must shut down for reads ASAP */
 #define CF_READ_NOEXP     0x00000080  /* producer should not expire */

 #define CF_WRITE_NULL     0x00000100  /* write(0) or connect() succeeded on consumer side */
 #define CF_WRITE_PARTIAL  0x00000200  /* some data were written to the consumer */
 #define CF_WRITE_TIMEOUT  0x00000400  /* timeout while waiting for consumer */
 #define CF_WRITE_ERROR    0x00000800  /* unrecoverable error on consumer side */
 #define CF_WRITE_ACTIVITY (CF_WRITE_NULL|CF_WRITE_PARTIAL|CF_WRITE_ERROR)

 #define CF_WAKE_WRITE     0x00001000  /* wake the task up when there's write activity */
 #define CF_SHUTW          0x00002000  /* consumer has already shut down */
 #define CF_SHUTW_NOW      0x00004000  /* the consumer must shut down for writes ASAP */
 #define CF_AUTO_CLOSE     0x00008000  /* producer can forward shutdown to other side */

 /* When CF_SHUTR_NOW is set, it is strictly forbidden for the producer to alter
  * the buffer contents. When CF_SHUTW_NOW is set, the consumer is free to perform
  * a shutw() when it has consumed the last contents, otherwise the session processor
  * will do it anyway.
  *
  * The SHUT* flags work like this :
  *
  *  SHUTR SHUTR_NOW  meaning
  *    0       0      normal case, connection still open and data is being read
  *    0       1      closing : the producer cannot feed data anymore but can close
  *    1       0      closed: the producer has closed its input channel.
  *    1       1      impossible
  *
  *  SHUTW SHUTW_NOW  meaning
  *    0       0      normal case, connection still open and data is being written
  *    0       1      closing: the consumer can send last data and may then close
  *    1       0      closed: the consumer has closed its output channel.
  *    1       1      impossible
  *
  * The SHUTW_NOW flag should be set by the session processor when SHUTR and AUTO_CLOSE
  * are both set. And it may also be set by the producer when it detects SHUTR while
  * directly forwarding data to the consumer.
  *
  * The SHUTR_NOW flag is mostly used to force the producer to abort when an error is
  * detected on the consumer side.
  */

 #define CF_STREAMER       0x00010000  /* the producer is identified as streaming data */
 #define CF_STREAMER_FAST  0x00020000  /* the consumer seems to eat the stream very fast */

 #define CF_WROTE_DATA     0x00040000  /* some data were sent from this buffer */
 #define CF_ANA_TIMEOUT    0x00080000  /* the analyser timeout has expired */
 #define CF_READ_ATTACHED  0x00100000  /* the read side is attached for the first time */
 #define CF_KERN_SPLICING  0x00200000  /* kernel splicing desired for this channel */
 #define CF_READ_DONTWAIT  0x00400000  /* wake the task up after every read (eg: HTTP request) */
 #define CF_AUTO_CONNECT   0x00800000  /* consumer may attempt to establish a new connection */

 #define CF_DONT_READ      0x01000000  /* disable reading for now */
 #define CF_EXPECT_MORE    0x02000000  /* more data expected to be sent very soon (one-shoot) */
 #define CF_SEND_DONTWAIT  0x04000000  /* don't wait for sending data (one-shoot) */
 #define CF_NEVER_WAIT     0x08000000  /* never wait for sending data (permanent) */

 #define CF_WAKE_ONCE      0x10000000  /* pretend there is activity on this channel (one-shoot) */
 #define CF_FLT_ANALYZE    0x20000000  /* at least one filter is still analyzing this channel */
 #define CF_EOI            0x40000000  /* end-of-input has been reached */
 #define CF_ISRESP         0x80000000  /* 0 = request channel, 1 = response channel */

 /* Masks which define input events for stream analysers */
 #define CF_MASK_ANALYSER  (CF_READ_ATTACHED|CF_READ_ACTIVITY|CF_READ_TIMEOUT|CF_ANA_TIMEOUT|CF_WRITE_ACTIVITY|CF_WAKE_ONCE)

 /* Mask for static flags which cause analysers to be woken up when they change */
 #define CF_MASK_STATIC    (CF_SHUTR|CF_SHUTW|CF_SHUTR_NOW|CF_SHUTW_NOW)


 /* Analysers (channel->analysers).
  * Those bits indicate that there are some processing to do on the buffer
  * contents. It will probably evolve into a linked list later. Those
  * analysers could be compared to higher level processors.
  * The field is blanked by channel_init() and only by analysers themselves
  * afterwards.
  */
 /* AN_REQ_FLT_START_FE:         0x00000001 */
 #define AN_REQ_INSPECT_FE       0x00000002  /* inspect request contents in the frontend */
 #define AN_REQ_WAIT_HTTP        0x00000004  /* wait for an HTTP request */
 #define AN_REQ_HTTP_BODY        0x00000008  /* wait for HTTP request body */
 #define AN_REQ_HTTP_PROCESS_FE  0x00000010  /* process the frontend's HTTP part */
 #define AN_REQ_SWITCHING_RULES  0x00000020  /* apply the switching rules */
 /* AN_REQ_FLT_START_BE:         0x00000040 */
 #define AN_REQ_INSPECT_BE       0x00000080  /* inspect request contents in the backend */
 #define AN_REQ_HTTP_PROCESS_BE  0x00000100  /* process the backend's HTTP part */
 #define AN_REQ_HTTP_TARPIT      0x00000200  /* wait for end of HTTP tarpit */
 #define AN_REQ_SRV_RULES        0x00000400  /* use-server rules */
 #define AN_REQ_HTTP_INNER       0x00000800  /* inner processing of HTTP request */
 #define AN_REQ_PRST_RDP_COOKIE  0x00001000  /* persistence on rdp cookie */
 #define AN_REQ_STICKING_RULES   0x00002000  /* table persistence matching */
 /* AN_REQ_FLT_HTTP_HDRS:        0x00004000 */
 #define AN_REQ_HTTP_XFER_BODY   0x00008000  /* forward request body */
 #define AN_REQ_WAIT_CLI         0x00010000
 /* AN_REQ_FLT_XFER_DATA:        0x00020000 */
 /* AN_REQ_FLT_END:              0x00040000 */
 #define AN_REQ_ALL              0x0001bfbe  /* all of the request analysers */

 /* response analysers */
 /* AN_RES_FLT_START_FE:         0x00080000 */
 /* AN_RES_FLT_START_BE:         0x00100000 */
 #define AN_RES_INSPECT          0x00200000  /* content inspection */
 #define AN_RES_WAIT_HTTP        0x00400000  /* wait for HTTP response */
 #define AN_RES_STORE_RULES      0x00800000  /* table persistence matching */
 #define AN_RES_HTTP_PROCESS_BE  0x01000000  /* process backend's HTTP part */
 #define AN_RES_HTTP_PROCESS_FE  0x01000000  /* process frontend's HTTP part (same for now) */
 /* AN_RES_FLT_HTTP_HDRS:        0x02000000 */
 #define AN_RES_HTTP_XFER_BODY   0x04000000  /* forward response body */
 #define AN_RES_WAIT_CLI         0x08000000
 /* AN_RES_FLT_XFER_DATA:        0x10000000 */
 /* AN_RES_FLT_END:              0x20000000 */
 #define AN_RES_ALL              0x0de00000  /* all of the response analysers */

 /* filters interleaved with analysers, see above */
 #define AN_REQ_FLT_START_FE     0x00000001
 #define AN_REQ_FLT_START_BE     0x00000040
 #define AN_REQ_FLT_HTTP_HDRS    0x00004000
 #define AN_REQ_FLT_XFER_DATA    0x00020000
 #define AN_REQ_FLT_END          0x00040000

 #define AN_RES_FLT_START_FE     0x00080000
 #define AN_RES_FLT_START_BE     0x00100000
 #define AN_RES_FLT_HTTP_HDRS    0x02000000
 #define AN_RES_FLT_XFER_DATA    0x10000000
 #define AN_RES_FLT_END          0x20000000

 /* Magic value to forward infinite size (TCP, ...), used with ->to_forward */
 #define CHN_INFINITE_FORWARD    MAX_RANGE(unsigned int)


 struct channel {
 	unsigned int flags;             /* CF_* */
 	unsigned int analysers;         /* bit field indicating what to do on the channel */
 	struct buffer buf;		/* buffer attached to the channel, always present but may move */
 	struct pipe *pipe;		/* non-NULL only when data present */
 	size_t output;                  /* part of buffer which is to be forwarded */
 	unsigned int to_forward;        /* number of bytes to forward after out without a wake-up */
 	unsigned short last_read;       /* 16 lower bits of last read date (max pause=65s) */
 	unsigned char xfer_large;       /* number of consecutive large xfers */
 	unsigned char xfer_small;       /* number of consecutive small xfers */
 	unsigned long long total;       /* total data read */
 	int rex;                        /* expiration date for a read, in ticks */
 	int wex;                        /* expiration date for a write or connect, in ticks */
 	int rto;                        /* read timeout, in ticks */
 	int wto;                        /* write timeout, in ticks */
 	int analyse_exp;                /* expiration date for current analysers (if set) */
 };


 /* Note about the channel structure
  *
  * A channel stores information needed to reliably transport data in a single
  * direction. It stores status flags, timeouts, counters, subscribed analysers,
  * pointers to a data producer and to a data consumer, and information about
  * the amount of data which is allowed to flow directly from the producer to
  * the consumer without waking up the analysers.
  *
  * A channel may buffer data into two locations :
  *   - a visible buffer (->buf)
  *   - an invisible buffer which right now consists in a pipe making use of
  *     kernel buffers that cannot be tampered with.
  *
  * Data stored into the first location may be analysed and altered by analysers
  * while data stored in pipes is only aimed at being transported from one
  * network socket to another one without being subject to memory copies. This
  * buffer may only be used when both the socket layer and the data layer of the
  * producer and the consumer support it, which typically is the case with Linux
  * splicing over sockets, and when there are enough data to be transported
  * without being analyzed (transport of TCP/HTTP payload or tunnelled data,
  * which is indicated by ->to_forward).
  *
  * In order not to mix data streams, the producer may only feed the invisible
  * data with data to forward, and only when the visible buffer is empty. The
  * producer may not always be able to feed the invisible buffer due to platform
  * limitations (lack of kernel support).
  *
  * Conversely, the consumer must always take data from the invisible data first
  * before ever considering visible data. There is no limit to the size of data
  * to consume from the invisible buffer, as platform-specific implementations
  * will rarely leave enough control on this. So any byte fed into the invisible
  * buffer is expected to reach the destination file descriptor, by any means.
  * However, it's the consumer's responsibility to ensure that the invisible
  * data has been entirely consumed before consuming visible data. This must be
  * reflected by ->pipe->data. This is very important as this and only this can
  * ensure strict ordering of data between buffers.
  *
  * The producer is responsible for decreasing ->to_forward. The ->to_forward
  * parameter indicates how many bytes may be fed into either data buffer
  * without waking the parent up. The special value CHN_INFINITE_FORWARD is
  * never decreased nor increased.
  *
  * The buf->o parameter says how many bytes may be consumed from the visible
  * buffer. This parameter is updated by any buffer_write() as well as any data
  * forwarded through the visible buffer. Since the ->to_forward attribute
  * applies to data after buf->p, an analyser will not see a buffer which has a
  * non-null ->to_forward with buf->i > 0. A producer is responsible for raising
  * buf->o by min(to_forward, buf->i) when it injects data into the buffer.
  *
  * The consumer is responsible for decreasing ->buf->o when it sends data
  * from the visible buffer, and ->pipe->data when it sends data from the
  * invisible buffer.
  *
  * A real-world example consists in part in an HTTP response waiting in a
  * buffer to be forwarded. We know the header length (300) and the amount of
  * data to forward (content-length=9000). The buffer already contains 1000
  * bytes of data after the 300 bytes of headers. Thus the caller will set
  * buf->o to 300 indicating that it explicitly wants to send those data, and
  * set ->to_forward to 9000 (content-length). This value must be normalised
  * immediately after updating ->to_forward : since there are already 1300 bytes
  * in the buffer, 300 of which are already counted in buf->o, and that size
  * is smaller than ->to_forward, we must update buf->o to 1300 to flush the
  * whole buffer, and reduce ->to_forward to 8000. After that, the producer may
  * try to feed the additional data through the invisible buffer using a
  * platform-specific method such as splice().
  *
  * The ->to_forward entry is also used to detect whether we can fill the buffer
  * or not. The idea is that we need to save some space for data manipulation
  * (mainly header rewriting in HTTP) so we don't want to have a full buffer on
  * input before processing a request or response. Thus, we ensure that there is
  * always global.maxrewrite bytes of free space. Since we don't want to forward
  * chunks without filling the buffer, we rely on ->to_forward. When ->to_forward
  * is null, we may have some processing to do so we don't want to fill the
  * buffer. When ->to_forward is non-null, we know we don't care for at least as
  * many bytes. In the end, we know that each of the ->to_forward bytes will
  * eventually leave the buffer. So as long as ->to_forward is larger than
  * global.maxrewrite, we can fill the buffer. If ->to_forward is smaller than
  * global.maxrewrite, then we don't want to fill the buffer with more than
  * buf->size - global.maxrewrite + ->to_forward.
  *
  * A buffer may contain up to 5 areas :
  *   - the data waiting to be sent. These data are located between buf->p-o and
  *     buf->p ;
  *   - the data to process and possibly transform. These data start at
  *     buf->p and may be up to ->i bytes long.
  *   - the data to preserve. They start at ->p and stop at ->p+i. The limit
  *     between the two solely depends on the protocol being analysed.
  *   - the spare area : it is the remainder of the buffer, which can be used to
  *     store new incoming data. It starts at ->p+i and is up to ->size-i-o long.
  *     It may be limited by global.maxrewrite.
  *   - the reserved area : this is the area which must not be filled and is
  *     reserved for possible rewrites ; it is up to global.maxrewrite bytes
  *     long.
  */

 #endif /* _HAPROXY_CHANNEL_T_H */

 /*
  * Local variables:
  *  c-indent-level: 8
  *  c-basic-offset: 8
  * End:
  */
	/*
	* include/haproxy/channel-t.h
	* Channel management definitions, macros and inline functions.
	*
	* Copyright (C) 2000-2014 Willy Tarreau - w@1wt.eu
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Lesser General Public
	* License as published by the Free Software Foundation, version 2.1
	* exclusively.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this library; if not, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
	*/

	#ifndef _HAPROXY_CHANNEL_T_H
	#define _HAPROXY_CHANNEL_T_H

	#include <haproxy/api-t.h>
	#include <haproxy/buf-t.h>

	/* The CF_* macros designate Channel Flags, which may be ORed in the bit field
	* member 'flags' in struct channel. Here we have several types of flags :
	*
	* - pure status flags, reported by the data layer, which must be cleared
	* before doing further I/O :
	* CF__NULL, CF__PARTIAL
	*
	* - pure status flags, reported by stream-interface layer, which must also
	* be cleared before doing further I/O :
	* CF__TIMEOUT, CF__ERROR
	*
	* - read-only indicators reported by lower data levels :
	* CF_STREAMER, CF_STREAMER_FAST
	*
	* - write-once status flags reported by the stream-interface layer :
	* CF_SHUTR, CF_SHUTW
	*
	* - persistent control flags managed only by application level :
	* CF_SHUT_NOW, CF__ENA
	*
	* The flags have been arranged for readability, so that the read and write
	* bits have the same position in a byte (read being the lower byte and write
	* the second one). All flag names are relative to the channel. For instance,
	* 'write' indicates the direction from the channel to the stream interface.
	*/

	#define CF_READ_NULL 0x00000001 /* last read detected on producer side */
	#define CF_READ_PARTIAL 0x00000002 /* some data were read from producer or a read exception occurred */
	#define CF_READ_TIMEOUT 0x00000004 /* timeout while waiting for producer */
	#define CF_READ_ERROR 0x00000008 /* unrecoverable error on producer side */
	#define CF_READ_ACTIVITY (CF_READ_NULL\|CF_READ_PARTIAL\|CF_READ_ERROR)

	/* unused: 0x00000010 */
	#define CF_SHUTR 0x00000020 /* producer has already shut down */
	#define CF_SHUTR_NOW 0x00000040 /* the producer must shut down for reads ASAP */
	#define CF_READ_NOEXP 0x00000080 /* producer should not expire */

	#define CF_WRITE_NULL 0x00000100 /* write(0) or connect() succeeded on consumer side */
	#define CF_WRITE_PARTIAL 0x00000200 /* some data were written to the consumer */
	#define CF_WRITE_TIMEOUT 0x00000400 /* timeout while waiting for consumer */
	#define CF_WRITE_ERROR 0x00000800 /* unrecoverable error on consumer side */
	#define CF_WRITE_ACTIVITY (CF_WRITE_NULL\|CF_WRITE_PARTIAL\|CF_WRITE_ERROR)

	#define CF_WAKE_WRITE 0x00001000 /* wake the task up when there's write activity */
	#define CF_SHUTW 0x00002000 /* consumer has already shut down */
	#define CF_SHUTW_NOW 0x00004000 /* the consumer must shut down for writes ASAP */
	#define CF_AUTO_CLOSE 0x00008000 /* producer can forward shutdown to other side */

	/* When CF_SHUTR_NOW is set, it is strictly forbidden for the producer to alter
	* the buffer contents. When CF_SHUTW_NOW is set, the consumer is free to perform
	* a shutw() when it has consumed the last contents, otherwise the session processor
	* will do it anyway.
	*
	* The SHUT* flags work like this :
	*
	* SHUTR SHUTR_NOW meaning
	* 0 0 normal case, connection still open and data is being read
	* 0 1 closing : the producer cannot feed data anymore but can close
	* 1 0 closed: the producer has closed its input channel.
	* 1 1 impossible
	*
	* SHUTW SHUTW_NOW meaning
	* 0 0 normal case, connection still open and data is being written
	* 0 1 closing: the consumer can send last data and may then close
	* 1 0 closed: the consumer has closed its output channel.
	* 1 1 impossible
	*
	* The SHUTW_NOW flag should be set by the session processor when SHUTR and AUTO_CLOSE
	* are both set. And it may also be set by the producer when it detects SHUTR while
	* directly forwarding data to the consumer.
	*
	* The SHUTR_NOW flag is mostly used to force the producer to abort when an error is
	* detected on the consumer side.
	*/

	#define CF_STREAMER 0x00010000 /* the producer is identified as streaming data */
	#define CF_STREAMER_FAST 0x00020000 /* the consumer seems to eat the stream very fast */

	#define CF_WROTE_DATA 0x00040000 /* some data were sent from this buffer */
	#define CF_ANA_TIMEOUT 0x00080000 /* the analyser timeout has expired */
	#define CF_READ_ATTACHED 0x00100000 /* the read side is attached for the first time */
	#define CF_KERN_SPLICING 0x00200000 /* kernel splicing desired for this channel */
	#define CF_READ_DONTWAIT 0x00400000 /* wake the task up after every read (eg: HTTP request) */
	#define CF_AUTO_CONNECT 0x00800000 /* consumer may attempt to establish a new connection */

	#define CF_DONT_READ 0x01000000 /* disable reading for now */
	#define CF_EXPECT_MORE 0x02000000 /* more data expected to be sent very soon (one-shoot) */
	#define CF_SEND_DONTWAIT 0x04000000 /* don't wait for sending data (one-shoot) */
	#define CF_NEVER_WAIT 0x08000000 /* never wait for sending data (permanent) */

	#define CF_WAKE_ONCE 0x10000000 /* pretend there is activity on this channel (one-shoot) */
	#define CF_FLT_ANALYZE 0x20000000 /* at least one filter is still analyzing this channel */
	#define CF_EOI 0x40000000 /* end-of-input has been reached */
	#define CF_ISRESP 0x80000000 /* 0 = request channel, 1 = response channel */

	/* Masks which define input events for stream analysers */
	#define CF_MASK_ANALYSER (CF_READ_ATTACHED\|CF_READ_ACTIVITY\|CF_READ_TIMEOUT\|CF_ANA_TIMEOUT\|CF_WRITE_ACTIVITY\|CF_WAKE_ONCE)

	/* Mask for static flags which cause analysers to be woken up when they change */
	#define CF_MASK_STATIC (CF_SHUTR\|CF_SHUTW\|CF_SHUTR_NOW\|CF_SHUTW_NOW)


	/* Analysers (channel->analysers).
	* Those bits indicate that there are some processing to do on the buffer
	* contents. It will probably evolve into a linked list later. Those
	* analysers could be compared to higher level processors.
	* The field is blanked by channel_init() and only by analysers themselves
	* afterwards.
	*/
	/* AN_REQ_FLT_START_FE: 0x00000001 */
	#define AN_REQ_INSPECT_FE 0x00000002 /* inspect request contents in the frontend */
	#define AN_REQ_WAIT_HTTP 0x00000004 /* wait for an HTTP request */
	#define AN_REQ_HTTP_BODY 0x00000008 /* wait for HTTP request body */
	#define AN_REQ_HTTP_PROCESS_FE 0x00000010 /* process the frontend's HTTP part */
	#define AN_REQ_SWITCHING_RULES 0x00000020 /* apply the switching rules */
	/* AN_REQ_FLT_START_BE: 0x00000040 */
	#define AN_REQ_INSPECT_BE 0x00000080 /* inspect request contents in the backend */
	#define AN_REQ_HTTP_PROCESS_BE 0x00000100 /* process the backend's HTTP part */
	#define AN_REQ_HTTP_TARPIT 0x00000200 /* wait for end of HTTP tarpit */
	#define AN_REQ_SRV_RULES 0x00000400 /* use-server rules */
	#define AN_REQ_HTTP_INNER 0x00000800 /* inner processing of HTTP request */
	#define AN_REQ_PRST_RDP_COOKIE 0x00001000 /* persistence on rdp cookie */
	#define AN_REQ_STICKING_RULES 0x00002000 /* table persistence matching */
	/* AN_REQ_FLT_HTTP_HDRS: 0x00004000 */
	#define AN_REQ_HTTP_XFER_BODY 0x00008000 /* forward request body */
	#define AN_REQ_WAIT_CLI 0x00010000
	/* AN_REQ_FLT_XFER_DATA: 0x00020000 */
	/* AN_REQ_FLT_END: 0x00040000 */
	#define AN_REQ_ALL 0x0001bfbe /* all of the request analysers */

	/* response analysers */
	/* AN_RES_FLT_START_FE: 0x00080000 */
	/* AN_RES_FLT_START_BE: 0x00100000 */
	#define AN_RES_INSPECT 0x00200000 /* content inspection */
	#define AN_RES_WAIT_HTTP 0x00400000 /* wait for HTTP response */
	#define AN_RES_STORE_RULES 0x00800000 /* table persistence matching */
	#define AN_RES_HTTP_PROCESS_BE 0x01000000 /* process backend's HTTP part */
	#define AN_RES_HTTP_PROCESS_FE 0x01000000 /* process frontend's HTTP part (same for now) */
	/* AN_RES_FLT_HTTP_HDRS: 0x02000000 */
	#define AN_RES_HTTP_XFER_BODY 0x04000000 /* forward response body */
	#define AN_RES_WAIT_CLI 0x08000000
	/* AN_RES_FLT_XFER_DATA: 0x10000000 */
	/* AN_RES_FLT_END: 0x20000000 */
	#define AN_RES_ALL 0x0de00000 /* all of the response analysers */

	/* filters interleaved with analysers, see above */
	#define AN_REQ_FLT_START_FE 0x00000001
	#define AN_REQ_FLT_START_BE 0x00000040
	#define AN_REQ_FLT_HTTP_HDRS 0x00004000
	#define AN_REQ_FLT_XFER_DATA 0x00020000
	#define AN_REQ_FLT_END 0x00040000

	#define AN_RES_FLT_START_FE 0x00080000
	#define AN_RES_FLT_START_BE 0x00100000
	#define AN_RES_FLT_HTTP_HDRS 0x02000000
	#define AN_RES_FLT_XFER_DATA 0x10000000
	#define AN_RES_FLT_END 0x20000000

	/* Magic value to forward infinite size (TCP, ...), used with ->to_forward */
	#define CHN_INFINITE_FORWARD MAX_RANGE(unsigned int)


	struct channel {
	unsigned int flags; /* CF_* */
	unsigned int analysers; /* bit field indicating what to do on the channel */
	struct buffer buf; /* buffer attached to the channel, always present but may move */
	struct pipe pipe; / non-NULL only when data present */
	size_t output; /* part of buffer which is to be forwarded */
	unsigned int to_forward; /* number of bytes to forward after out without a wake-up */
	unsigned short last_read; /* 16 lower bits of last read date (max pause=65s) */
	unsigned char xfer_large; /* number of consecutive large xfers */
	unsigned char xfer_small; /* number of consecutive small xfers */
	unsigned long long total; /* total data read */
	int rex; /* expiration date for a read, in ticks */
	int wex; /* expiration date for a write or connect, in ticks */
	int rto; /* read timeout, in ticks */
	int wto; /* write timeout, in ticks */
	int analyse_exp; /* expiration date for current analysers (if set) */
	};


	/* Note about the channel structure
	*
	* A channel stores information needed to reliably transport data in a single
	* direction. It stores status flags, timeouts, counters, subscribed analysers,
	* pointers to a data producer and to a data consumer, and information about
	* the amount of data which is allowed to flow directly from the producer to
	* the consumer without waking up the analysers.
	*
	* A channel may buffer data into two locations :
	* - a visible buffer (->buf)
	* - an invisible buffer which right now consists in a pipe making use of
	* kernel buffers that cannot be tampered with.
	*
	* Data stored into the first location may be analysed and altered by analysers
	* while data stored in pipes is only aimed at being transported from one
	* network socket to another one without being subject to memory copies. This
	* buffer may only be used when both the socket layer and the data layer of the
	* producer and the consumer support it, which typically is the case with Linux
	* splicing over sockets, and when there are enough data to be transported
	* without being analyzed (transport of TCP/HTTP payload or tunnelled data,
	* which is indicated by ->to_forward).
	*
	* In order not to mix data streams, the producer may only feed the invisible
	* data with data to forward, and only when the visible buffer is empty. The
	* producer may not always be able to feed the invisible buffer due to platform
	* limitations (lack of kernel support).
	*
	* Conversely, the consumer must always take data from the invisible data first
	* before ever considering visible data. There is no limit to the size of data
	* to consume from the invisible buffer, as platform-specific implementations
	* will rarely leave enough control on this. So any byte fed into the invisible
	* buffer is expected to reach the destination file descriptor, by any means.
	* However, it's the consumer's responsibility to ensure that the invisible
	* data has been entirely consumed before consuming visible data. This must be
	* reflected by ->pipe->data. This is very important as this and only this can
	* ensure strict ordering of data between buffers.
	*
	* The producer is responsible for decreasing ->to_forward. The ->to_forward
	* parameter indicates how many bytes may be fed into either data buffer
	* without waking the parent up. The special value CHN_INFINITE_FORWARD is
	* never decreased nor increased.
	*
	* The buf->o parameter says how many bytes may be consumed from the visible
	* buffer. This parameter is updated by any buffer_write() as well as any data
	* forwarded through the visible buffer. Since the ->to_forward attribute
	* applies to data after buf->p, an analyser will not see a buffer which has a
	* non-null ->to_forward with buf->i > 0. A producer is responsible for raising
	* buf->o by min(to_forward, buf->i) when it injects data into the buffer.
	*
	* The consumer is responsible for decreasing ->buf->o when it sends data
	* from the visible buffer, and ->pipe->data when it sends data from the
	* invisible buffer.
	*
	* A real-world example consists in part in an HTTP response waiting in a
	* buffer to be forwarded. We know the header length (300) and the amount of
	* data to forward (content-length=9000). The buffer already contains 1000
	* bytes of data after the 300 bytes of headers. Thus the caller will set
	* buf->o to 300 indicating that it explicitly wants to send those data, and
	* set ->to_forward to 9000 (content-length). This value must be normalised
	* immediately after updating ->to_forward : since there are already 1300 bytes
	* in the buffer, 300 of which are already counted in buf->o, and that size
	* is smaller than ->to_forward, we must update buf->o to 1300 to flush the
	* whole buffer, and reduce ->to_forward to 8000. After that, the producer may
	* try to feed the additional data through the invisible buffer using a
	* platform-specific method such as splice().
	*
	* The ->to_forward entry is also used to detect whether we can fill the buffer
	* or not. The idea is that we need to save some space for data manipulation
	* (mainly header rewriting in HTTP) so we don't want to have a full buffer on
	* input before processing a request or response. Thus, we ensure that there is
	* always global.maxrewrite bytes of free space. Since we don't want to forward
	* chunks without filling the buffer, we rely on ->to_forward. When ->to_forward
	* is null, we may have some processing to do so we don't want to fill the
	* buffer. When ->to_forward is non-null, we know we don't care for at least as
	* many bytes. In the end, we know that each of the ->to_forward bytes will
	* eventually leave the buffer. So as long as ->to_forward is larger than
	* global.maxrewrite, we can fill the buffer. If ->to_forward is smaller than
	* global.maxrewrite, then we don't want to fill the buffer with more than
	* buf->size - global.maxrewrite + ->to_forward.
	*
	* A buffer may contain up to 5 areas :
	* - the data waiting to be sent. These data are located between buf->p-o and
	* buf->p ;
	* - the data to process and possibly transform. These data start at
	* buf->p and may be up to ->i bytes long.
	* - the data to preserve. They start at ->p and stop at ->p+i. The limit
	* between the two solely depends on the protocol being analysed.
	* - the spare area : it is the remainder of the buffer, which can be used to
	* store new incoming data. It starts at ->p+i and is up to ->size-i-o long.
	* It may be limited by global.maxrewrite.
	* - the reserved area : this is the area which must not be filled and is
	* reserved for possible rewrites ; it is up to global.maxrewrite bytes
	* long.
	*/

	#endif /* _HAPROXY_CHANNEL_T_H */

	/*
	* Local variables:
	* c-indent-level: 8
	* c-basic-offset: 8
	* End:
	*/