include/haproxy/h1.h - haproxy - Gitiles

 /*
  * include/haproxy/h1.h
  * This file contains HTTP/1 protocol definitions.
  *
  * Copyright (C) 2000-2020 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_H1_H
 #define _HAPROXY_H1_H

 #include <import/ist.h>
 #include <haproxy/api.h>
 #include <haproxy/buf.h>
 #include <haproxy/http.h>
 #include <haproxy/http-hdr-t.h>
 #include <haproxy/intops.h>


 /* Possible states while parsing HTTP/1 messages (request|response) */
 enum h1m_state {
 	H1_MSG_RQBEFORE     =  0, // request: leading LF, before start line
 	H1_MSG_RQBEFORE_CR  =  1, // request: leading CRLF, before start line
 	/* these ones define a request start line */
 	H1_MSG_RQMETH       =  2, // parsing the Method
 	H1_MSG_RQMETH_SP    =  3, // space(s) after the Method
 	H1_MSG_RQURI        =  4, // parsing the Request URI
 	H1_MSG_RQURI_SP     =  5, // space(s) after the Request URI
 	H1_MSG_RQVER        =  6, // parsing the Request Version
 	H1_MSG_RQLINE_END   =  7, // end of request line (CR or LF)

 	H1_MSG_RPBEFORE     =  8, // response: leading LF, before start line
 	H1_MSG_RPBEFORE_CR  =  9, // response: leading CRLF, before start line

 	/* these ones define a response start line */
 	H1_MSG_RPVER        = 10, // parsing the Response Version
 	H1_MSG_RPVER_SP     = 11, // space(s) after the Response Version
 	H1_MSG_RPCODE       = 12, // response code
 	H1_MSG_RPCODE_SP    = 13, // space(s) after the response code
 	H1_MSG_RPREASON     = 14, // response reason
 	H1_MSG_RPLINE_END   = 15, // end of response line (CR or LF)

 	/* common header processing */
 	H1_MSG_HDR_FIRST    = 16, // waiting for first header or last CRLF (no LWS possible)
 	H1_MSG_HDR_NAME     = 17, // parsing header name
 	H1_MSG_HDR_COL      = 18, // parsing header colon
 	H1_MSG_HDR_L1_SP    = 19, // parsing header LWS (SP|HT) before value
 	H1_MSG_HDR_L1_LF    = 20, // parsing header LWS (LF) before value
 	H1_MSG_HDR_L1_LWS   = 21, // checking whether it's a new header or an LWS
 	H1_MSG_HDR_VAL      = 22, // parsing header value
 	H1_MSG_HDR_L2_LF    = 23, // parsing header LWS (LF) inside/after value
 	H1_MSG_HDR_L2_LWS   = 24, // checking whether it's a new header or an LWS

 	H1_MSG_LAST_LF      = 25, // parsing last LF, last state for headers

 	/* Body processing. */

 	H1_MSG_CHUNK_SIZE   = 26, // parsing the chunk size (RFC7230 #4.1)
 	H1_MSG_DATA         = 27, // skipping data chunk / content-length data
 	H1_MSG_CHUNK_CRLF   = 28, // skipping CRLF after data chunk
 	H1_MSG_TRAILERS     = 29, // trailers (post-data entity headers)
 	/* we enter this state when we've received the end of the current message */
 	H1_MSG_DONE         = 30, // message end received, waiting for resync or close
 	H1_MSG_TUNNEL       = 31, // tunneled data after DONE
 } __attribute__((packed));


 /* HTTP/1 message flags (32 bit), for use in h1m->flags only */
 #define H1_MF_NONE              0x00000000
 #define H1_MF_CLEN              0x00000001 // content-length present
 #define H1_MF_CHNK              0x00000002 // chunk present, exclusive with c-l
 #define H1_MF_RESP              0x00000004 // this message is the response message
 #define H1_MF_TOLOWER           0x00000008 // turn the header names to lower case
 #define H1_MF_VER_11            0x00000010 // message indicates version 1.1 or above
 #define H1_MF_CONN_CLO          0x00000020 // message contains "connection: close"
 #define H1_MF_CONN_KAL          0x00000040 // message contains "connection: keep-alive"
 #define H1_MF_CONN_UPG          0x00000080 // message contains "connection: upgrade"
 #define H1_MF_XFER_LEN          0x00000100 // message xfer size can be determined
 #define H1_MF_XFER_ENC          0x00000200 // transfer-encoding is present
 #define H1_MF_NO_PHDR           0x00000400 // don't add pseudo-headers in the header list
 #define H1_MF_HDRS_ONLY         0x00000800 // parse headers only
 #define H1_MF_CLEAN_CONN_HDR    0x00001000 // skip close/keep-alive values of connection headers during parsing
 #define H1_MF_METH_CONNECT      0x00002000 // Set for a response to a CONNECT request
 #define H1_MF_METH_HEAD         0x00004000 // Set for a response to a HEAD request
 #define H1_MF_UPG_WEBSOCKET     0x00008000 // Set for a Websocket upgrade handshake

 /* Note: for a connection to be persistent, we need this for the request :
  *   - one of CLEN or CHNK
  *   - version 1.0 and KAL and not CLO
  *   - or version 1.1 and not CLO
  * For the response it's the same except that UPG must not appear either.
  * So in short, for a request it's (CLEN|CHNK) > 0 && !CLO && (VER_11 || KAL)
  * and for a response it's (CLEN|CHNK) > 0 && !(CLO|UPG) && (VER_11 || KAL)
  */


 /* basic HTTP/1 message state for use in parsers. The err_pos field is special,
  * it is pre-set to a negative value (-1 or -2), and once non-negative it contains
  * the relative position in the message of the first parse error. -2 is used to tell
  * the parser that we want to block the invalid message. -1 is used to only perform
  * a silent capture.
  */
 struct h1m {
 	enum h1m_state state;       // H1 message state (H1_MSG_*)
 	/* 24 bits available here */
 	uint32_t flags;             // H1 message flags (H1_MF_*)
 	uint64_t curr_len;          // content-length or last chunk length
 	uint64_t body_len;          // total known size of the body length
 	uint32_t next;              // next byte to parse, relative to buffer's head
 	int err_pos;                // position in the byte stream of the first error (H1 or H2)
 	int err_state;              // state where the first error was met (H1 or H2)
 };

 /* basic H1 start line, describes either the request and the response */
 union h1_sl {                          /* useful start line pointers, relative to ->sol */
 	struct {
 		struct ist m;          /* METHOD */
 		struct ist u;          /* URI */
 		struct ist v;          /* VERSION */
 		enum http_meth_t meth; /* method */
 	} rq;                          /* request line : field, length */
 	struct {
 		struct ist v;          /* VERSION */
 		struct ist c;          /* CODE */
 		struct ist r;          /* REASON */
 		uint16_t status;       /* status code */
 	} st;                          /* status line : field, length */
 };

 int h1_headers_to_hdr_list(char *start, const char *stop,
                            struct http_hdr *hdr, unsigned int hdr_num,
                            struct h1m *h1m, union h1_sl *slp);
 int h1_measure_trailers(const struct buffer *buf, unsigned int ofs, unsigned int max);

 int h1_parse_cont_len_header(struct h1m *h1m, struct ist *value);
 void h1_parse_xfer_enc_header(struct h1m *h1m, struct ist value);
 void h1_parse_connection_header(struct h1m *h1m, struct ist *value);
 void h1_parse_upgrade_header(struct h1m *h1m, struct ist value);

 void h1_generate_random_ws_input_key(char key_out[25]);
 void h1_calculate_ws_output_key(const char *key, char *result);

 /* for debugging, reports the HTTP/1 message state name */
 static inline const char *h1m_state_str(enum h1m_state msg_state)
 {
 	switch (msg_state) {
 	case H1_MSG_RQBEFORE:    return "MSG_RQBEFORE";
 	case H1_MSG_RQBEFORE_CR: return "MSG_RQBEFORE_CR";
 	case H1_MSG_RQMETH:      return "MSG_RQMETH";
 	case H1_MSG_RQMETH_SP:   return "MSG_RQMETH_SP";
 	case H1_MSG_RQURI:       return "MSG_RQURI";
 	case H1_MSG_RQURI_SP:    return "MSG_RQURI_SP";
 	case H1_MSG_RQVER:       return "MSG_RQVER";
 	case H1_MSG_RQLINE_END:  return "MSG_RQLINE_END";
 	case H1_MSG_RPBEFORE:    return "MSG_RPBEFORE";
 	case H1_MSG_RPBEFORE_CR: return "MSG_RPBEFORE_CR";
 	case H1_MSG_RPVER:       return "MSG_RPVER";
 	case H1_MSG_RPVER_SP:    return "MSG_RPVER_SP";
 	case H1_MSG_RPCODE:      return "MSG_RPCODE";
 	case H1_MSG_RPCODE_SP:   return "MSG_RPCODE_SP";
 	case H1_MSG_RPREASON:    return "MSG_RPREASON";
 	case H1_MSG_RPLINE_END:  return "MSG_RPLINE_END";
 	case H1_MSG_HDR_FIRST:   return "MSG_HDR_FIRST";
 	case H1_MSG_HDR_NAME:    return "MSG_HDR_NAME";
 	case H1_MSG_HDR_COL:     return "MSG_HDR_COL";
 	case H1_MSG_HDR_L1_SP:   return "MSG_HDR_L1_SP";
 	case H1_MSG_HDR_L1_LF:   return "MSG_HDR_L1_LF";
 	case H1_MSG_HDR_L1_LWS:  return "MSG_HDR_L1_LWS";
 	case H1_MSG_HDR_VAL:     return "MSG_HDR_VAL";
 	case H1_MSG_HDR_L2_LF:   return "MSG_HDR_L2_LF";
 	case H1_MSG_HDR_L2_LWS:  return "MSG_HDR_L2_LWS";
 	case H1_MSG_LAST_LF:     return "MSG_LAST_LF";
 	case H1_MSG_CHUNK_SIZE:  return "MSG_CHUNK_SIZE";
 	case H1_MSG_DATA:        return "MSG_DATA";
 	case H1_MSG_CHUNK_CRLF:  return "MSG_CHUNK_CRLF";
 	case H1_MSG_TRAILERS:    return "MSG_TRAILERS";
 	case H1_MSG_DONE:        return "MSG_DONE";
 	case H1_MSG_TUNNEL:      return "MSG_TUNNEL";
 	default:                 return "MSG_??????";
 	}
 }

 /* This function may be called only in HTTP_MSG_CHUNK_CRLF. It reads the CRLF or
  * a possible LF alone at the end of a chunk. The caller should adjust msg->next
  * in order to include this part into the next forwarding phase.  Note that the
  * caller must ensure that head+start points to the first byte to parse.  It
  * returns the number of bytes parsed on success, so the caller can set msg_state
  * to HTTP_MSG_CHUNK_SIZE. If not enough data are available, the function does not
  * change anything and returns zero. Otherwise it returns a negative value
  * indicating the error position relative to <stop>. Note: this function is
  * designed to parse wrapped CRLF at the end of the buffer.
  */
 static inline int h1_skip_chunk_crlf(const struct buffer *buf, int start, int stop)
 {
 	const char *ptr = b_peek(buf, start);
 	int bytes = 1;

 	if (stop <= start)
 		return 0;

 	/* NB: we'll check data availability at the end. It's not a
 	 * problem because whatever we match first will be checked
 	 * against the correct length.
 	 */
 	if (*ptr == '\r') {
 		bytes++;
 		ptr++;
 		if (ptr >= b_wrap(buf))
 			ptr = b_orig(buf);
 	}

 	if (bytes > stop - start)
 		return 0;

 	if (*ptr != '\n') // negative position to stop
 		return ptr - __b_peek(buf, stop);

 	return bytes;
 }

 /* Parse the chunk size start at buf + start and stops before buf + stop. The
  * positions are relative to the buffer's head.
  * It returns the chunk size in <res> and the amount of bytes read this way :
  *   < 0 : error at this position relative to <stop>
  *   = 0 : not enough bytes to read a complete chunk size
  *   > 0 : number of bytes successfully read that the caller can skip
  * On success, the caller should adjust its msg->next to point to the first
  * byte of data after the chunk size, so that we know we can forward exactly
  * msg->next bytes, and msg->sol to contain the exact number of bytes forming
  * the chunk size. That way it is always possible to differentiate between the
  * start of the body and the start of the data. Note: this function is designed
  * to parse wrapped CRLF at the end of the buffer.
  */
 static inline int h1_parse_chunk_size(const struct buffer *buf, int start, int stop, uint64_t *res)
 {
 	const char *ptr = b_peek(buf, start);
 	const char *ptr_old = ptr;
 	const char *end = b_wrap(buf);
 	uint64_t chunk = 0;

 	stop -= start; // bytes left
 	start = stop;  // bytes to transfer

 	/* The chunk size is in the following form, though we are only
 	 * interested in the size and CRLF :
 	 *    1*HEXDIGIT *WSP *[ ';' extensions ] CRLF
 	 */
 	while (1) {
 		int c;
 		if (!stop)
 			return 0;
 		c = hex2i(*ptr);
 		if (c < 0) /* not a hex digit anymore */
 			break;
 		if (unlikely(++ptr >= end))
 			ptr = b_orig(buf);
 		chunk = (chunk << 4) + c;
 		if (unlikely(chunk & 0xF0000000000000ULL)) {
 			/* Don't get more than 13 hexa-digit (2^52 - 1) to never fed possibly
 			 * bogus values from languages that use floats for their integers
 			 */
 			goto error;
 		}
 		stop--;
 	}

 	/* empty size not allowed */
 	if (unlikely(ptr == ptr_old))
 		goto error;

 	while (HTTP_IS_SPHT(*ptr)) {
 		if (++ptr >= end)
 			ptr = b_orig(buf);
 		if (--stop == 0)
 			return 0;
 	}

 	/* Up to there, we know that at least one byte is present at *ptr. Check
 	 * for the end of chunk size.
 	 */
 	while (1) {
 		if (likely(HTTP_IS_CRLF(*ptr))) {
 			/* we now have a CR or an LF at ptr */
 			if (likely(*ptr == '\r')) {
 				if (++ptr >= end)
 					ptr = b_orig(buf);
 				if (--stop == 0)
 					return 0;
 			}

 			if (*ptr != '\n')
 				goto error;
 			if (++ptr >= end)
 				ptr = b_orig(buf);
 			--stop;
 			/* done */
 			break;
 		}
 		else if (likely(*ptr == ';')) {
 			/* chunk extension, ends at next CRLF */
 			if (++ptr >= end)
 				ptr = b_orig(buf);
 			if (--stop == 0)
 				return 0;

 			while (!HTTP_IS_CRLF(*ptr)) {
 				if (++ptr >= end)
 					ptr = b_orig(buf);
 				if (--stop == 0)
 					return 0;
 			}
 			/* we have a CRLF now, loop above */
 			continue;
 		}
 		else
 			goto error;
 	}

 	/* OK we found our CRLF and now <ptr> points to the next byte, which may
 	 * or may not be present. Let's return the number of bytes parsed.
 	 */
 	*res = chunk;
 	return start - stop;
  error:
 	*res = 0; // just to stop gcc's -Wuninitialized warning :-(
 	return -stop;
 }

 /* initializes an H1 message for a request */
 static inline struct h1m *h1m_init_req(struct h1m *h1m)
 {
 	h1m->state = H1_MSG_RQBEFORE;
 	h1m->next = 0;
 	h1m->flags = H1_MF_NONE;
 	h1m->curr_len = 0;
 	h1m->body_len = 0;
 	h1m->err_pos = -2;
 	h1m->err_state = 0;
 	return h1m;
 }

 /* initializes an H1 message for a response */
 static inline struct h1m *h1m_init_res(struct h1m *h1m)
 {
 	h1m->state = H1_MSG_RPBEFORE;
 	h1m->next = 0;
 	h1m->flags = H1_MF_RESP;
 	h1m->curr_len = 0;
 	h1m->body_len = 0;
 	h1m->err_pos = -2;
 	h1m->err_state = 0;
 	return h1m;
 }

 #endif /* _HAPROXY_H1_H */
	/*
	* include/haproxy/h1.h
	* This file contains HTTP/1 protocol definitions.
	*
	* Copyright (C) 2000-2020 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_H1_H
	#define _HAPROXY_H1_H

	#include <import/ist.h>
	#include <haproxy/api.h>
	#include <haproxy/buf.h>
	#include <haproxy/http.h>
	#include <haproxy/http-hdr-t.h>
	#include <haproxy/intops.h>


	/* Possible states while parsing HTTP/1 messages (request\|response) */
	enum h1m_state {
	H1_MSG_RQBEFORE = 0, // request: leading LF, before start line
	H1_MSG_RQBEFORE_CR = 1, // request: leading CRLF, before start line
	/* these ones define a request start line */
	H1_MSG_RQMETH = 2, // parsing the Method
	H1_MSG_RQMETH_SP = 3, // space(s) after the Method
	H1_MSG_RQURI = 4, // parsing the Request URI
	H1_MSG_RQURI_SP = 5, // space(s) after the Request URI
	H1_MSG_RQVER = 6, // parsing the Request Version
	H1_MSG_RQLINE_END = 7, // end of request line (CR or LF)

	H1_MSG_RPBEFORE = 8, // response: leading LF, before start line
	H1_MSG_RPBEFORE_CR = 9, // response: leading CRLF, before start line

	/* these ones define a response start line */
	H1_MSG_RPVER = 10, // parsing the Response Version
	H1_MSG_RPVER_SP = 11, // space(s) after the Response Version
	H1_MSG_RPCODE = 12, // response code
	H1_MSG_RPCODE_SP = 13, // space(s) after the response code
	H1_MSG_RPREASON = 14, // response reason
	H1_MSG_RPLINE_END = 15, // end of response line (CR or LF)

	/* common header processing */
	H1_MSG_HDR_FIRST = 16, // waiting for first header or last CRLF (no LWS possible)
	H1_MSG_HDR_NAME = 17, // parsing header name
	H1_MSG_HDR_COL = 18, // parsing header colon
	H1_MSG_HDR_L1_SP = 19, // parsing header LWS (SP\|HT) before value
	H1_MSG_HDR_L1_LF = 20, // parsing header LWS (LF) before value
	H1_MSG_HDR_L1_LWS = 21, // checking whether it's a new header or an LWS
	H1_MSG_HDR_VAL = 22, // parsing header value
	H1_MSG_HDR_L2_LF = 23, // parsing header LWS (LF) inside/after value
	H1_MSG_HDR_L2_LWS = 24, // checking whether it's a new header or an LWS

	H1_MSG_LAST_LF = 25, // parsing last LF, last state for headers

	/* Body processing. */

	H1_MSG_CHUNK_SIZE = 26, // parsing the chunk size (RFC7230 #4.1)
	H1_MSG_DATA = 27, // skipping data chunk / content-length data
	H1_MSG_CHUNK_CRLF = 28, // skipping CRLF after data chunk
	H1_MSG_TRAILERS = 29, // trailers (post-data entity headers)
	/* we enter this state when we've received the end of the current message */
	H1_MSG_DONE = 30, // message end received, waiting for resync or close
	H1_MSG_TUNNEL = 31, // tunneled data after DONE
	} __attribute__((packed));


	/* HTTP/1 message flags (32 bit), for use in h1m->flags only */
	#define H1_MF_NONE 0x00000000
	#define H1_MF_CLEN 0x00000001 // content-length present
	#define H1_MF_CHNK 0x00000002 // chunk present, exclusive with c-l
	#define H1_MF_RESP 0x00000004 // this message is the response message
	#define H1_MF_TOLOWER 0x00000008 // turn the header names to lower case
	#define H1_MF_VER_11 0x00000010 // message indicates version 1.1 or above
	#define H1_MF_CONN_CLO 0x00000020 // message contains "connection: close"
	#define H1_MF_CONN_KAL 0x00000040 // message contains "connection: keep-alive"
	#define H1_MF_CONN_UPG 0x00000080 // message contains "connection: upgrade"
	#define H1_MF_XFER_LEN 0x00000100 // message xfer size can be determined
	#define H1_MF_XFER_ENC 0x00000200 // transfer-encoding is present
	#define H1_MF_NO_PHDR 0x00000400 // don't add pseudo-headers in the header list
	#define H1_MF_HDRS_ONLY 0x00000800 // parse headers only
	#define H1_MF_CLEAN_CONN_HDR 0x00001000 // skip close/keep-alive values of connection headers during parsing
	#define H1_MF_METH_CONNECT 0x00002000 // Set for a response to a CONNECT request
	#define H1_MF_METH_HEAD 0x00004000 // Set for a response to a HEAD request
	#define H1_MF_UPG_WEBSOCKET 0x00008000 // Set for a Websocket upgrade handshake

	/* Note: for a connection to be persistent, we need this for the request :
	* - one of CLEN or CHNK
	* - version 1.0 and KAL and not CLO
	* - or version 1.1 and not CLO
	* For the response it's the same except that UPG must not appear either.
	* So in short, for a request it's (CLEN\|CHNK) > 0 && !CLO && (VER_11 \|\| KAL)
	* and for a response it's (CLEN\|CHNK) > 0 && !(CLO\|UPG) && (VER_11 \|\| KAL)
	*/


	/* basic HTTP/1 message state for use in parsers. The err_pos field is special,
	* it is pre-set to a negative value (-1 or -2), and once non-negative it contains
	* the relative position in the message of the first parse error. -2 is used to tell
	* the parser that we want to block the invalid message. -1 is used to only perform
	* a silent capture.
	*/
	struct h1m {
	enum h1m_state state; // H1 message state (H1_MSG_*)
	/* 24 bits available here */
	uint32_t flags; // H1 message flags (H1_MF_*)
	uint64_t curr_len; // content-length or last chunk length
	uint64_t body_len; // total known size of the body length
	uint32_t next; // next byte to parse, relative to buffer's head
	int err_pos; // position in the byte stream of the first error (H1 or H2)
	int err_state; // state where the first error was met (H1 or H2)
	};

	/* basic H1 start line, describes either the request and the response */
	union h1_sl { /* useful start line pointers, relative to ->sol */
	struct {
	struct ist m; /* METHOD */
	struct ist u; /* URI */
	struct ist v; /* VERSION */
	enum http_meth_t meth; /* method */
	} rq; /* request line : field, length */
	struct {
	struct ist v; /* VERSION */
	struct ist c; /* CODE */
	struct ist r; /* REASON */
	uint16_t status; /* status code */
	} st; /* status line : field, length */
	};

	int h1_headers_to_hdr_list(char start, const char stop,
	struct http_hdr *hdr, unsigned int hdr_num,
	struct h1m h1m, union h1_sl slp);
	int h1_measure_trailers(const struct buffer *buf, unsigned int ofs, unsigned int max);

	int h1_parse_cont_len_header(struct h1m h1m, struct ist value);
	void h1_parse_xfer_enc_header(struct h1m *h1m, struct ist value);
	void h1_parse_connection_header(struct h1m h1m, struct ist value);
	void h1_parse_upgrade_header(struct h1m *h1m, struct ist value);

	void h1_generate_random_ws_input_key(char key_out[25]);
	void h1_calculate_ws_output_key(const char key, char result);

	/* for debugging, reports the HTTP/1 message state name */
	static inline const char *h1m_state_str(enum h1m_state msg_state)
	{
	switch (msg_state) {
	case H1_MSG_RQBEFORE: return "MSG_RQBEFORE";
	case H1_MSG_RQBEFORE_CR: return "MSG_RQBEFORE_CR";
	case H1_MSG_RQMETH: return "MSG_RQMETH";
	case H1_MSG_RQMETH_SP: return "MSG_RQMETH_SP";
	case H1_MSG_RQURI: return "MSG_RQURI";
	case H1_MSG_RQURI_SP: return "MSG_RQURI_SP";
	case H1_MSG_RQVER: return "MSG_RQVER";
	case H1_MSG_RQLINE_END: return "MSG_RQLINE_END";
	case H1_MSG_RPBEFORE: return "MSG_RPBEFORE";
	case H1_MSG_RPBEFORE_CR: return "MSG_RPBEFORE_CR";
	case H1_MSG_RPVER: return "MSG_RPVER";
	case H1_MSG_RPVER_SP: return "MSG_RPVER_SP";
	case H1_MSG_RPCODE: return "MSG_RPCODE";
	case H1_MSG_RPCODE_SP: return "MSG_RPCODE_SP";
	case H1_MSG_RPREASON: return "MSG_RPREASON";
	case H1_MSG_RPLINE_END: return "MSG_RPLINE_END";
	case H1_MSG_HDR_FIRST: return "MSG_HDR_FIRST";
	case H1_MSG_HDR_NAME: return "MSG_HDR_NAME";
	case H1_MSG_HDR_COL: return "MSG_HDR_COL";
	case H1_MSG_HDR_L1_SP: return "MSG_HDR_L1_SP";
	case H1_MSG_HDR_L1_LF: return "MSG_HDR_L1_LF";
	case H1_MSG_HDR_L1_LWS: return "MSG_HDR_L1_LWS";
	case H1_MSG_HDR_VAL: return "MSG_HDR_VAL";
	case H1_MSG_HDR_L2_LF: return "MSG_HDR_L2_LF";
	case H1_MSG_HDR_L2_LWS: return "MSG_HDR_L2_LWS";
	case H1_MSG_LAST_LF: return "MSG_LAST_LF";
	case H1_MSG_CHUNK_SIZE: return "MSG_CHUNK_SIZE";
	case H1_MSG_DATA: return "MSG_DATA";
	case H1_MSG_CHUNK_CRLF: return "MSG_CHUNK_CRLF";
	case H1_MSG_TRAILERS: return "MSG_TRAILERS";
	case H1_MSG_DONE: return "MSG_DONE";
	case H1_MSG_TUNNEL: return "MSG_TUNNEL";
	default: return "MSG_??????";
	}
	}

	/* This function may be called only in HTTP_MSG_CHUNK_CRLF. It reads the CRLF or
	* a possible LF alone at the end of a chunk. The caller should adjust msg->next
	* in order to include this part into the next forwarding phase. Note that the
	* caller must ensure that head+start points to the first byte to parse. It
	* returns the number of bytes parsed on success, so the caller can set msg_state
	* to HTTP_MSG_CHUNK_SIZE. If not enough data are available, the function does not
	* change anything and returns zero. Otherwise it returns a negative value
	* indicating the error position relative to <stop>. Note: this function is
	* designed to parse wrapped CRLF at the end of the buffer.
	*/
	static inline int h1_skip_chunk_crlf(const struct buffer *buf, int start, int stop)
	{
	const char *ptr = b_peek(buf, start);
	int bytes = 1;

	if (stop <= start)
	return 0;

	/* NB: we'll check data availability at the end. It's not a
	* problem because whatever we match first will be checked
	* against the correct length.
	*/
	if (*ptr == '\r') {
	bytes++;
	ptr++;
	if (ptr >= b_wrap(buf))
	ptr = b_orig(buf);
	}

	if (bytes > stop - start)
	return 0;

	if (*ptr != '\n') // negative position to stop
	return ptr - __b_peek(buf, stop);

	return bytes;
	}

	/* Parse the chunk size start at buf + start and stops before buf + stop. The
	* positions are relative to the buffer's head.
	* It returns the chunk size in <res> and the amount of bytes read this way :
	* < 0 : error at this position relative to <stop>
	* = 0 : not enough bytes to read a complete chunk size
	* > 0 : number of bytes successfully read that the caller can skip
	* On success, the caller should adjust its msg->next to point to the first
	* byte of data after the chunk size, so that we know we can forward exactly
	* msg->next bytes, and msg->sol to contain the exact number of bytes forming
	* the chunk size. That way it is always possible to differentiate between the
	* start of the body and the start of the data. Note: this function is designed
	* to parse wrapped CRLF at the end of the buffer.
	*/
	static inline int h1_parse_chunk_size(const struct buffer buf, int start, int stop, uint64_t res)
	{
	const char *ptr = b_peek(buf, start);
	const char *ptr_old = ptr;
	const char *end = b_wrap(buf);
	uint64_t chunk = 0;

	stop -= start; // bytes left
	start = stop; // bytes to transfer

	/* The chunk size is in the following form, though we are only
	* interested in the size and CRLF :
	* 1HEXDIGIT WSP *[ ';' extensions ] CRLF
	*/
	while (1) {
	int c;
	if (!stop)
	return 0;
	c = hex2i(*ptr);
	if (c < 0) /* not a hex digit anymore */
	break;
	if (unlikely(++ptr >= end))
	ptr = b_orig(buf);
	chunk = (chunk << 4) + c;
	if (unlikely(chunk & 0xF0000000000000ULL)) {
	/* Don't get more than 13 hexa-digit (2^52 - 1) to never fed possibly
	* bogus values from languages that use floats for their integers
	*/
	goto error;
	}
	stop--;
	}

	/* empty size not allowed */
	if (unlikely(ptr == ptr_old))
	goto error;

	while (HTTP_IS_SPHT(*ptr)) {
	if (++ptr >= end)
	ptr = b_orig(buf);
	if (--stop == 0)
	return 0;
	}

	/* Up to there, we know that at least one byte is present at *ptr. Check
	* for the end of chunk size.
	*/
	while (1) {
	if (likely(HTTP_IS_CRLF(*ptr))) {
	/* we now have a CR or an LF at ptr */
	if (likely(*ptr == '\r')) {
	if (++ptr >= end)
	ptr = b_orig(buf);
	if (--stop == 0)
	return 0;
	}

	if (*ptr != '\n')
	goto error;
	if (++ptr >= end)
	ptr = b_orig(buf);
	--stop;
	/* done */
	break;
	}
	else if (likely(*ptr == ';')) {
	/* chunk extension, ends at next CRLF */
	if (++ptr >= end)
	ptr = b_orig(buf);
	if (--stop == 0)
	return 0;

	while (!HTTP_IS_CRLF(*ptr)) {
	if (++ptr >= end)
	ptr = b_orig(buf);
	if (--stop == 0)
	return 0;
	}
	/* we have a CRLF now, loop above */
	continue;
	}
	else
	goto error;
	}

	/* OK we found our CRLF and now <ptr> points to the next byte, which may
	* or may not be present. Let's return the number of bytes parsed.
	*/
	*res = chunk;
	return start - stop;
	error:
	*res = 0; // just to stop gcc's -Wuninitialized warning :-(
	return -stop;
	}

	/* initializes an H1 message for a request */
	static inline struct h1m h1m_init_req(struct h1m h1m)
	{
	h1m->state = H1_MSG_RQBEFORE;
	h1m->next = 0;
	h1m->flags = H1_MF_NONE;
	h1m->curr_len = 0;
	h1m->body_len = 0;
	h1m->err_pos = -2;
	h1m->err_state = 0;
	return h1m;
	}

	/* initializes an H1 message for a response */
	static inline struct h1m h1m_init_res(struct h1m h1m)
	{
	h1m->state = H1_MSG_RPBEFORE;
	h1m->next = 0;
	h1m->flags = H1_MF_RESP;
	h1m->curr_len = 0;
	h1m->body_len = 0;
	h1m->err_pos = -2;
	h1m->err_state = 0;
	return h1m;
	}

	#endif /* _HAPROXY_H1_H */