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git01.mediatek.com / haproxy / 13c29dee21eff53916e60872202faac2c5668f68 / . / src / proto_http.c
blob: 920dca99c4746166579a959ae77b3937ecdc068f [file] [log] [blame]
/*
* HTTP protocol analyzer
*
* Copyright 2000-2010 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.
*
*/
#include <ctype.h>
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <syslog.h>
#include <time.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <common/appsession.h>
#include <common/base64.h>
#include <common/compat.h>
#include <common/config.h>
#include <common/debug.h>
#include <common/memory.h>
#include <common/mini-clist.h>
#include <common/standard.h>
#include <common/ticks.h>
#include <common/time.h>
#include <common/uri_auth.h>
#include <common/version.h>
#include <types/capture.h>
#include <types/global.h>
#include <proto/acl.h>
#include <proto/auth.h>
#include <proto/backend.h>
#include <proto/buffers.h>
#include <proto/checks.h>
#include <proto/dumpstats.h>
#include <proto/fd.h>
#include <proto/frontend.h>
#include <proto/log.h>
#include <proto/hdr_idx.h>
#include <proto/pattern.h>
#include <proto/proto_tcp.h>
#include <proto/proto_http.h>
#include <proto/proxy.h>
#include <proto/queue.h>
#include <proto/server.h>
#include <proto/session.h>
#include <proto/stream_interface.h>
#include <proto/stream_sock.h>
#include <proto/task.h>
const char HTTP_100[] =
"HTTP/1.1 100 Continue\r\n\r\n";
const struct chunk http_100_chunk = {
.str = (char *)&HTTP_100,
.len = sizeof(HTTP_100)-1
};
/* This is used by remote monitoring */
const char HTTP_200[] =
"HTTP/1.0 200 OK\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"\r\n"
"<html><body><h1>200 OK</h1>\nHAProxy: service ready.\n</body></html>\n";
const struct chunk http_200_chunk = {
.str = (char *)&HTTP_200,
.len = sizeof(HTTP_200)-1
};
/* Warning: no "connection" header is provided with the 3xx messages below */
const char *HTTP_301 =
"HTTP/1.1 301 Moved Permanently\r\n"
"Cache-Control: no-cache\r\n"
"Content-length: 0\r\n"
"Location: "; /* not terminated since it will be concatenated with the URL */
const char *HTTP_302 =
"HTTP/1.1 302 Found\r\n"
"Cache-Control: no-cache\r\n"
"Content-length: 0\r\n"
"Location: "; /* not terminated since it will be concatenated with the URL */
/* same as 302 except that the browser MUST retry with the GET method */
const char *HTTP_303 =
"HTTP/1.1 303 See Other\r\n"
"Cache-Control: no-cache\r\n"
"Content-length: 0\r\n"
"Location: "; /* not terminated since it will be concatenated with the URL */
/* Warning: this one is an sprintf() fmt string, with <realm> as its only argument */
const char *HTTP_401_fmt =
"HTTP/1.0 401 Unauthorized\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"WWW-Authenticate: Basic realm=\"%s\"\r\n"
"\r\n"
"<html><body><h1>401 Unauthorized</h1>\nYou need a valid user and password to access this content.\n</body></html>\n";
const char *HTTP_407_fmt =
"HTTP/1.0 407 Unauthorized\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"Proxy-Authenticate: Basic realm=\"%s\"\r\n"
"\r\n"
"<html><body><h1>401 Unauthorized</h1>\nYou need a valid user and password to access this content.\n</body></html>\n";
const int http_err_codes[HTTP_ERR_SIZE] = {
[HTTP_ERR_400] = 400,
[HTTP_ERR_403] = 403,
[HTTP_ERR_408] = 408,
[HTTP_ERR_500] = 500,
[HTTP_ERR_502] = 502,
[HTTP_ERR_503] = 503,
[HTTP_ERR_504] = 504,
};
static const char *http_err_msgs[HTTP_ERR_SIZE] = {
[HTTP_ERR_400] =
"HTTP/1.0 400 Bad request\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"\r\n"
"<html><body><h1>400 Bad request</h1>\nYour browser sent an invalid request.\n</body></html>\n",
[HTTP_ERR_403] =
"HTTP/1.0 403 Forbidden\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"\r\n"
"<html><body><h1>403 Forbidden</h1>\nRequest forbidden by administrative rules.\n</body></html>\n",
[HTTP_ERR_408] =
"HTTP/1.0 408 Request Time-out\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"\r\n"
"<html><body><h1>408 Request Time-out</h1>\nYour browser didn't send a complete request in time.\n</body></html>\n",
[HTTP_ERR_500] =
"HTTP/1.0 500 Server Error\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"\r\n"
"<html><body><h1>500 Server Error</h1>\nAn internal server error occured.\n</body></html>\n",
[HTTP_ERR_502] =
"HTTP/1.0 502 Bad Gateway\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"\r\n"
"<html><body><h1>502 Bad Gateway</h1>\nThe server returned an invalid or incomplete response.\n</body></html>\n",
[HTTP_ERR_503] =
"HTTP/1.0 503 Service Unavailable\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"\r\n"
"<html><body><h1>503 Service Unavailable</h1>\nNo server is available to handle this request.\n</body></html>\n",
[HTTP_ERR_504] =
"HTTP/1.0 504 Gateway Time-out\r\n"
"Cache-Control: no-cache\r\n"
"Connection: close\r\n"
"Content-Type: text/html\r\n"
"\r\n"
"<html><body><h1>504 Gateway Time-out</h1>\nThe server didn't respond in time.\n</body></html>\n",
};
/* We must put the messages here since GCC cannot initialize consts depending
* on strlen().
*/
struct chunk http_err_chunks[HTTP_ERR_SIZE];
#define FD_SETS_ARE_BITFIELDS
#ifdef FD_SETS_ARE_BITFIELDS
/*
* This map is used with all the FD_* macros to check whether a particular bit
* is set or not. Each bit represents an ACSII code. FD_SET() sets those bytes
* which should be encoded. When FD_ISSET() returns non-zero, it means that the
* byte should be encoded. Be careful to always pass bytes from 0 to 255
* exclusively to the macros.
*/
fd_set hdr_encode_map[(sizeof(fd_set) > (256/8)) ? 1 : ((256/8) / sizeof(fd_set))];
fd_set url_encode_map[(sizeof(fd_set) > (256/8)) ? 1 : ((256/8) / sizeof(fd_set))];
#else
#error "Check if your OS uses bitfields for fd_sets"
#endif
void init_proto_http()
{
int i;
char *tmp;
int msg;
for (msg = 0; msg < HTTP_ERR_SIZE; msg++) {
if (!http_err_msgs[msg]) {
Alert("Internal error: no message defined for HTTP return code %d. Aborting.\n", msg);
abort();
}
http_err_chunks[msg].str = (char *)http_err_msgs[msg];
http_err_chunks[msg].len = strlen(http_err_msgs[msg]);
}
/* initialize the log header encoding map : '{|}"#' should be encoded with
* '#' as prefix, as well as non-printable characters ( <32 or >= 127 ).
* URL encoding only requires '"', '#' to be encoded as well as non-
* printable characters above.
*/
memset(hdr_encode_map, 0, sizeof(hdr_encode_map));
memset(url_encode_map, 0, sizeof(url_encode_map));
for (i = 0; i < 32; i++) {
FD_SET(i, hdr_encode_map);
FD_SET(i, url_encode_map);
}
for (i = 127; i < 256; i++) {
FD_SET(i, hdr_encode_map);
FD_SET(i, url_encode_map);
}
tmp = "\"#{|}";
while (*tmp) {
FD_SET(*tmp, hdr_encode_map);
tmp++;
}
tmp = "\"#";
while (*tmp) {
FD_SET(*tmp, url_encode_map);
tmp++;
}
/* memory allocations */
pool2_requri = create_pool("requri", REQURI_LEN, MEM_F_SHARED);
pool2_capture = create_pool("capture", CAPTURE_LEN, MEM_F_SHARED);
}
/*
* We have 26 list of methods (1 per first letter), each of which can have
* up to 3 entries (2 valid, 1 null).
*/
struct http_method_desc {
http_meth_t meth;
int len;
const char text[8];
};
const struct http_method_desc http_methods[26][3] = {
['C' - 'A'] = {
[0] = { .meth = HTTP_METH_CONNECT , .len=7, .text="CONNECT" },
},
['D' - 'A'] = {
[0] = { .meth = HTTP_METH_DELETE , .len=6, .text="DELETE" },
},
['G' - 'A'] = {
[0] = { .meth = HTTP_METH_GET , .len=3, .text="GET" },
},
['H' - 'A'] = {
[0] = { .meth = HTTP_METH_HEAD , .len=4, .text="HEAD" },
},
['P' - 'A'] = {
[0] = { .meth = HTTP_METH_POST , .len=4, .text="POST" },
[1] = { .meth = HTTP_METH_PUT , .len=3, .text="PUT" },
},
['T' - 'A'] = {
[0] = { .meth = HTTP_METH_TRACE , .len=5, .text="TRACE" },
},
/* rest is empty like this :
* [1] = { .meth = HTTP_METH_NONE , .len=0, .text="" },
*/
};
/* It is about twice as fast on recent architectures to lookup a byte in a
* table than to perform a boolean AND or OR between two tests. Refer to
* RFC2616 for those chars.
*/
const char http_is_spht[256] = {
[' '] = 1, ['\t'] = 1,
};
const char http_is_crlf[256] = {
['\r'] = 1, ['\n'] = 1,
};
const char http_is_lws[256] = {
[' '] = 1, ['\t'] = 1,
['\r'] = 1, ['\n'] = 1,
};
const char http_is_sep[256] = {
['('] = 1, [')'] = 1, ['<'] = 1, ['>'] = 1,
['@'] = 1, [','] = 1, [';'] = 1, [':'] = 1,
['"'] = 1, ['/'] = 1, ['['] = 1, [']'] = 1,
['{'] = 1, ['}'] = 1, ['?'] = 1, ['='] = 1,
[' '] = 1, ['\t'] = 1, ['\\'] = 1,
};
const char http_is_ctl[256] = {
[0 ... 31] = 1,
[127] = 1,
};
/*
* A token is any ASCII char that is neither a separator nor a CTL char.
* Do not overwrite values in assignment since gcc-2.95 will not handle
* them correctly. Instead, define every non-CTL char's status.
*/
const char http_is_token[256] = {
[' '] = 0, ['!'] = 1, ['"'] = 0, ['#'] = 1,
['$'] = 1, ['%'] = 1, ['&'] = 1, ['\''] = 1,
['('] = 0, [')'] = 0, ['*'] = 1, ['+'] = 1,
[','] = 0, ['-'] = 1, ['.'] = 1, ['/'] = 0,
['0'] = 1, ['1'] = 1, ['2'] = 1, ['3'] = 1,
['4'] = 1, ['5'] = 1, ['6'] = 1, ['7'] = 1,
['8'] = 1, ['9'] = 1, [':'] = 0, [';'] = 0,
['<'] = 0, ['='] = 0, ['>'] = 0, ['?'] = 0,
['@'] = 0, ['A'] = 1, ['B'] = 1, ['C'] = 1,
['D'] = 1, ['E'] = 1, ['F'] = 1, ['G'] = 1,
['H'] = 1, ['I'] = 1, ['J'] = 1, ['K'] = 1,
['L'] = 1, ['M'] = 1, ['N'] = 1, ['O'] = 1,
['P'] = 1, ['Q'] = 1, ['R'] = 1, ['S'] = 1,
['T'] = 1, ['U'] = 1, ['V'] = 1, ['W'] = 1,
['X'] = 1, ['Y'] = 1, ['Z'] = 1, ['['] = 0,
['\\'] = 0, [']'] = 0, ['^'] = 1, ['_'] = 1,
['`'] = 1, ['a'] = 1, ['b'] = 1, ['c'] = 1,
['d'] = 1, ['e'] = 1, ['f'] = 1, ['g'] = 1,
['h'] = 1, ['i'] = 1, ['j'] = 1, ['k'] = 1,
['l'] = 1, ['m'] = 1, ['n'] = 1, ['o'] = 1,
['p'] = 1, ['q'] = 1, ['r'] = 1, ['s'] = 1,
['t'] = 1, ['u'] = 1, ['v'] = 1, ['w'] = 1,
['x'] = 1, ['y'] = 1, ['z'] = 1, ['{'] = 0,
['|'] = 1, ['}'] = 0, ['~'] = 1,
};
/*
* An http ver_token is any ASCII which can be found in an HTTP version,
* which includes 'H', 'T', 'P', '/', '.' and any digit.
*/
const char http_is_ver_token[256] = {
['.'] = 1, ['/'] = 1,
['0'] = 1, ['1'] = 1, ['2'] = 1, ['3'] = 1, ['4'] = 1,
['5'] = 1, ['6'] = 1, ['7'] = 1, ['8'] = 1, ['9'] = 1,
['H'] = 1, ['P'] = 1, ['T'] = 1,
};
/*
* Silent debug that outputs only in strace, using fd #-1. Trash is modified.
*/
#if defined(DEBUG_FSM)
static void http_silent_debug(int line, struct session *s)
{
int size = 0;
size += snprintf(trash + size, sizeof(trash) - size,
"[%04d] req: p=%d(%d) s=%d bf=%08x an=%08x data=%p size=%d l=%d w=%p r=%p lr=%p sm=%d fw=%ld tf=%08x\n",
line,
s->si[0].state, s->si[0].fd, s->txn.req.msg_state, s->req->flags, s->req->analysers,
s->req->data, s->req->size, s->req->l, s->req->w, s->req->r, s->req->lr, s->req->send_max, s->req->to_forward, s->txn.flags);
write(-1, trash, size);
size = 0;
size += snprintf(trash + size, sizeof(trash) - size,
" %04d rep: p=%d(%d) s=%d bf=%08x an=%08x data=%p size=%d l=%d w=%p r=%p lr=%p sm=%d fw=%ld\n",
line,
s->si[1].state, s->si[1].fd, s->txn.rsp.msg_state, s->rep->flags, s->rep->analysers,
s->rep->data, s->rep->size, s->rep->l, s->rep->w, s->rep->r, s->rep->lr, s->rep->send_max, s->rep->to_forward);
write(-1, trash, size);
}
#else
#define http_silent_debug(l,s) do { } while (0)
#endif
/*
* Adds a header and its CRLF at the tail of buffer <b>, just before the last
* CRLF. Text length is measured first, so it cannot be NULL.
* The header is also automatically added to the index <hdr_idx>, and the end
* of headers is automatically adjusted. The number of bytes added is returned
* on success, otherwise <0 is returned indicating an error.
*/
int http_header_add_tail(struct buffer *b, struct http_msg *msg,
struct hdr_idx *hdr_idx, const char *text)
{
int bytes, len;
len = strlen(text);
bytes = buffer_insert_line2(b, b->data + msg->eoh, text, len);
if (!bytes)
return -1;
http_msg_move_end(msg, bytes);
return hdr_idx_add(len, 1, hdr_idx, hdr_idx->tail);
}
/*
* Adds a header and its CRLF at the tail of buffer <b>, just before the last
* CRLF. <len> bytes are copied, not counting the CRLF. If <text> is NULL, then
* the buffer is only opened and the space reserved, but nothing is copied.
* The header is also automatically added to the index <hdr_idx>, and the end
* of headers is automatically adjusted. The number of bytes added is returned
* on success, otherwise <0 is returned indicating an error.
*/
int http_header_add_tail2(struct buffer *b, struct http_msg *msg,
struct hdr_idx *hdr_idx, const char *text, int len)
{
int bytes;
bytes = buffer_insert_line2(b, b->data + msg->eoh, text, len);
if (!bytes)
return -1;
http_msg_move_end(msg, bytes);
return hdr_idx_add(len, 1, hdr_idx, hdr_idx->tail);
}
/*
* Checks if <hdr> is exactly <name> for <len> chars, and ends with a colon.
* If so, returns the position of the first non-space character relative to
* <hdr>, or <end>-<hdr> if not found before. If no value is found, it tries
* to return a pointer to the place after the first space. Returns 0 if the
* header name does not match. Checks are case-insensitive.
*/
int http_header_match2(const char *hdr, const char *end,
const char *name, int len)
{
const char *val;
if (hdr + len >= end)
return 0;
if (hdr[len] != ':')
return 0;
if (strncasecmp(hdr, name, len) != 0)
return 0;
val = hdr + len + 1;
while (val < end && HTTP_IS_SPHT(*val))
val++;
if ((val >= end) && (len + 2 <= end - hdr))
return len + 2; /* we may replace starting from second space */
return val - hdr;
}
/* Find the end of the header value contained between <s> and <e>. See RFC2616,
* par 2.2 for more information. Note that it requires a valid header to return
* a valid result. This works for headers defined as comma-separated lists.
*/
char *find_hdr_value_end(char *s, const char *e)
{
int quoted, qdpair;
quoted = qdpair = 0;
for (; s < e; s++) {
if (qdpair) qdpair = 0;
else if (quoted && *s == '\\') qdpair = 1;
else if (quoted && *s == '"') quoted = 0;
else if (*s == '"') quoted = 1;
else if (*s == ',') return s;
}
return s;
}
/* Find the first or next occurrence of header <name> in message buffer <sol>
* using headers index <idx>, and return it in the <ctx> structure. This
* structure holds everything necessary to use the header and find next
* occurrence. If its <idx> member is 0, the header is searched from the
* beginning. Otherwise, the next occurrence is returned. The function returns
* 1 when it finds a value, and 0 when there is no more. It is designed to work
* with headers defined as comma-separated lists. As a special case, if ctx->val
* is NULL when searching for a new values of a header, the current header is
* rescanned. This allows rescanning after a header deletion.
*/
int http_find_header2(const char *name, int len,
char *sol, struct hdr_idx *idx,
struct hdr_ctx *ctx)
{
char *eol, *sov;
int cur_idx, old_idx;
cur_idx = ctx->idx;
if (cur_idx) {
/* We have previously returned a value, let's search
* another one on the same line.
*/
sol = ctx->line;
ctx->del = ctx->val + ctx->vlen;
sov = sol + ctx->del;
eol = sol + idx->v[cur_idx].len;
if (sov >= eol)
/* no more values in this header */
goto next_hdr;
/* values remaining for this header, skip the comma but save it
* for later use (eg: for header deletion).
*/
sov++;
while (sov < eol && http_is_lws[(unsigned char)*sov])
sov++;
goto return_hdr;
}
/* first request for this header */
sol += hdr_idx_first_pos(idx);
old_idx = 0;
cur_idx = hdr_idx_first_idx(idx);
while (cur_idx) {
eol = sol + idx->v[cur_idx].len;
if (len == 0) {
/* No argument was passed, we want any header.
* To achieve this, we simply build a fake request. */
while (sol + len < eol && sol[len] != ':')
len++;
name = sol;
}
if ((len < eol - sol) &&
(sol[len] == ':') &&
(strncasecmp(sol, name, len) == 0)) {
ctx->del = len;
sov = sol + len + 1;
while (sov < eol && http_is_lws[(unsigned char)*sov])
sov++;
ctx->line = sol;
ctx->prev = old_idx;
return_hdr:
ctx->idx = cur_idx;
ctx->val = sov - sol;
eol = find_hdr_value_end(sov, eol);
ctx->vlen = eol - sov;
return 1;
}
next_hdr:
sol = eol + idx->v[cur_idx].cr + 1;
old_idx = cur_idx;
cur_idx = idx->v[cur_idx].next;
}
return 0;
}
int http_find_header(const char *name,
char *sol, struct hdr_idx *idx,
struct hdr_ctx *ctx)
{
return http_find_header2(name, strlen(name), sol, idx, ctx);
}
/* Remove one value of a header. This only works on a <ctx> returned by one of
* the http_find_header functions. The value is removed, as well as surrounding
* commas if any. If the removed value was alone, the whole header is removed.
* The ctx is always updated accordingly, as well as buffer <buf> and HTTP
* message <msg>. The new index is returned. If it is zero, it means there is
* no more header, so any processing may stop. The ctx is always left in a form
* that can be handled by http_find_header2() to find next occurrence.
*/
int http_remove_header2(struct http_msg *msg, struct buffer *buf,
struct hdr_idx *idx, struct hdr_ctx *ctx)
{
int cur_idx = ctx->idx;
char *sol = ctx->line;
struct hdr_idx_elem *hdr;
int delta, skip_comma;
if (!cur_idx)
return 0;
hdr = &idx->v[cur_idx];
if (sol[ctx->del] == ':' && ctx->val + ctx->vlen == hdr->len) {
/* This was the only value of the header, we must now remove it entirely. */
delta = buffer_replace2(buf, sol, sol + hdr->len + hdr->cr + 1, NULL, 0);
http_msg_move_end(msg, delta);
idx->used--;
hdr->len = 0; /* unused entry */
idx->v[ctx->prev].next = idx->v[ctx->idx].next;
ctx->idx = ctx->prev; /* walk back to the end of previous header */
ctx->line -= idx->v[ctx->idx].len + idx->v[cur_idx].cr + 1;
ctx->val = idx->v[ctx->idx].len; /* point to end of previous header */
ctx->vlen = 0;
return ctx->idx;
}
/* This was not the only value of this header. We have to remove between
* ctx->del+1 and ctx->val+ctx->vlen+1 included. If it is the last entry
* of the list, we remove the last separator.
*/
skip_comma = (ctx->val + ctx->vlen == hdr->len) ? 0 : 1;
delta = buffer_replace2(buf, sol + ctx->del + skip_comma,
sol + ctx->val + ctx->vlen + skip_comma,
NULL, 0);
hdr->len += delta;
http_msg_move_end(msg, delta);
ctx->val = ctx->del;
ctx->vlen = 0;
return ctx->idx;
}
/* This function handles a server error at the stream interface level. The
* stream interface is assumed to be already in a closed state. An optional
* message is copied into the input buffer, and an HTTP status code stored.
* The error flags are set to the values in arguments. Any pending request
* in this buffer will be lost.
*/
static void http_server_error(struct session *t, struct stream_interface *si,
int err, int finst, int status, const struct chunk *msg)
{
buffer_auto_read(si->ob);
buffer_abort(si->ob);
buffer_auto_close(si->ob);
buffer_erase(si->ob);
buffer_auto_close(si->ib);
buffer_auto_read(si->ib);
if (status > 0 && msg) {
t->txn.status = status;
buffer_write(si->ib, msg->str, msg->len);
}
if (!(t->flags & SN_ERR_MASK))
t->flags |= err;
if (!(t->flags & SN_FINST_MASK))
t->flags |= finst;
}
/* This function returns the appropriate error location for the given session
* and message.
*/
struct chunk *error_message(struct session *s, int msgnum)
{
if (s->be->errmsg[msgnum].str)
return &s->be->errmsg[msgnum];
else if (s->fe->errmsg[msgnum].str)
return &s->fe->errmsg[msgnum];
else
return &http_err_chunks[msgnum];
}
/*
* returns HTTP_METH_NONE if there is nothing valid to read (empty or non-text
* string), HTTP_METH_OTHER for unknown methods, or the identified method.
*/
static http_meth_t find_http_meth(const char *str, const int len)
{
unsigned char m;
const struct http_method_desc *h;
m = ((unsigned)*str - 'A');
if (m < 26) {
for (h = http_methods[m]; h->len > 0; h++) {
if (unlikely(h->len != len))
continue;
if (likely(memcmp(str, h->text, h->len) == 0))
return h->meth;
};
return HTTP_METH_OTHER;
}
return HTTP_METH_NONE;
}
/* Parse the URI from the given transaction (which is assumed to be in request
* phase) and look for the "/" beginning the PATH. If not found, return NULL.
* It is returned otherwise.
*/
static char *
http_get_path(struct http_txn *txn)
{
char *ptr, *end;
ptr = txn->req.sol + txn->req.sl.rq.u;
end = ptr + txn->req.sl.rq.u_l;
if (ptr >= end)
return NULL;
/* RFC2616, par. 5.1.2 :
* Request-URI = "*" | absuri | abspath | authority
*/
if (*ptr == '*')
return NULL;
if (isalpha((unsigned char)*ptr)) {
/* this is a scheme as described by RFC3986, par. 3.1 */
ptr++;
while (ptr < end &&
(isalnum((unsigned char)*ptr) || *ptr == '+' || *ptr == '-' || *ptr == '.'))
ptr++;
/* skip '://' */
if (ptr == end || *ptr++ != ':')
return NULL;
if (ptr == end || *ptr++ != '/')
return NULL;
if (ptr == end || *ptr++ != '/')
return NULL;
}
/* skip [user[:passwd]@]host[:[port]] */
while (ptr < end && *ptr != '/')
ptr++;
if (ptr == end)
return NULL;
/* OK, we got the '/' ! */
return ptr;
}
/* Returns a 302 for a redirectable request. This may only be called just after
* the stream interface has moved to SI_ST_ASS. Unprocessable requests are
* left unchanged and will follow normal proxy processing.
*/
void perform_http_redirect(struct session *s, struct stream_interface *si)
{
struct http_txn *txn;
struct chunk rdr;
char *path;
int len;
/* 1: create the response header */
rdr.len = strlen(HTTP_302);
rdr.str = trash;
rdr.size = sizeof(trash);
memcpy(rdr.str, HTTP_302, rdr.len);
/* 2: add the server's prefix */
if (rdr.len + s->srv->rdr_len > rdr.size)
return;
/* special prefix "/" means don't change URL */
if (s->srv->rdr_len != 1 || *s->srv->rdr_pfx != '/') {
memcpy(rdr.str + rdr.len, s->srv->rdr_pfx, s->srv->rdr_len);
rdr.len += s->srv->rdr_len;
}
/* 3: add the request URI */
txn = &s->txn;
path = http_get_path(txn);
if (!path)
return;
len = txn->req.sl.rq.u_l + (txn->req.sol + txn->req.sl.rq.u) - path;
if (rdr.len + len > rdr.size - 4) /* 4 for CRLF-CRLF */
return;
memcpy(rdr.str + rdr.len, path, len);
rdr.len += len;
if (unlikely(txn->flags & TX_USE_PX_CONN)) {
memcpy(rdr.str + rdr.len, "\r\nProxy-Connection: close\r\n\r\n", 29);
rdr.len += 29;
} else {
memcpy(rdr.str + rdr.len, "\r\nConnection: close\r\n\r\n", 23);
rdr.len += 23;
}
/* prepare to return without error. */
si->shutr(si);
si->shutw(si);
si->err_type = SI_ET_NONE;
si->err_loc = NULL;
si->state = SI_ST_CLO;
/* send the message */
http_server_error(s, si, SN_ERR_PRXCOND, SN_FINST_C, 302, &rdr);
/* FIXME: we should increase a counter of redirects per server and per backend. */
if (s->srv)
srv_inc_sess_ctr(s->srv);
}
/* Return the error message corresponding to si->err_type. It is assumed
* that the server side is closed. Note that err_type is actually a
* bitmask, where almost only aborts may be cumulated with other
* values. We consider that aborted operations are more important
* than timeouts or errors due to the fact that nobody else in the
* logs might explain incomplete retries. All others should avoid
* being cumulated. It should normally not be possible to have multiple
* aborts at once, but just in case, the first one in sequence is reported.
*/
void http_return_srv_error(struct session *s, struct stream_interface *si)
{
int err_type = si->err_type;
if (err_type & SI_ET_QUEUE_ABRT)
http_server_error(s, si, SN_ERR_CLICL, SN_FINST_Q,
503, error_message(s, HTTP_ERR_503));
else if (err_type & SI_ET_CONN_ABRT)
http_server_error(s, si, SN_ERR_CLICL, SN_FINST_C,
503, error_message(s, HTTP_ERR_503));
else if (err_type & SI_ET_QUEUE_TO)
http_server_error(s, si, SN_ERR_SRVTO, SN_FINST_Q,
503, error_message(s, HTTP_ERR_503));
else if (err_type & SI_ET_QUEUE_ERR)
http_server_error(s, si, SN_ERR_SRVCL, SN_FINST_Q,
503, error_message(s, HTTP_ERR_503));
else if (err_type & SI_ET_CONN_TO)
http_server_error(s, si, SN_ERR_SRVTO, SN_FINST_C,
503, error_message(s, HTTP_ERR_503));
else if (err_type & SI_ET_CONN_ERR)
http_server_error(s, si, SN_ERR_SRVCL, SN_FINST_C,
503, error_message(s, HTTP_ERR_503));
else /* SI_ET_CONN_OTHER and others */
http_server_error(s, si, SN_ERR_INTERNAL, SN_FINST_C,
500, error_message(s, HTTP_ERR_500));
}
extern const char sess_term_cond[8];
extern const char sess_fin_state[8];
extern const char *monthname[12];
const char sess_cookie[4] = "NIDV"; /* No cookie, Invalid cookie, cookie for a Down server, Valid cookie */
const char sess_set_cookie[8] = "N1I3PD5R"; /* No set-cookie, unknown, Set-Cookie Inserted, unknown,
Set-cookie seen and left unchanged (passive), Set-cookie Deleted,
unknown, Set-cookie Rewritten */
struct pool_head *pool2_requri;
struct pool_head *pool2_capture;
void http_sess_clflog(struct session *s)
{
char pn[INET6_ADDRSTRLEN + strlen(":65535")];
struct proxy *fe = s->fe;
struct proxy *be = s->be;
struct proxy *prx_log;
struct http_txn *txn = &s->txn;
int tolog, level, err;
char *uri, *h;
char *svid;
struct tm tm;
static char tmpline[MAX_SYSLOG_LEN];
int hdr;
size_t w;
int t_request;
prx_log = fe;
err = (s->flags & (SN_ERR_MASK | SN_REDISP)) ||
(s->req->cons->conn_retries != be->conn_retries) ||
txn->status >= 500;
if (s->cli_addr.ss_family == AF_INET)
inet_ntop(AF_INET,
(const void *)&((struct sockaddr_in *)&s->cli_addr)->sin_addr,
pn, sizeof(pn));
else
inet_ntop(AF_INET6,
(const void *)&((struct sockaddr_in6 *)(&s->cli_addr))->sin6_addr,
pn, sizeof(pn));
get_gmtime(s->logs.accept_date.tv_sec, &tm);
/* FIXME: let's limit ourselves to frontend logging for now. */
tolog = fe->to_log;
h = tmpline;
w = snprintf(h, sizeof(tmpline),
"%s - - [%02d/%s/%04d:%02d:%02d:%02d +0000]",
pn,
tm.tm_mday, monthname[tm.tm_mon], tm.tm_year+1900,
tm.tm_hour, tm.tm_min, tm.tm_sec);
if (w < 0 || w >= sizeof(tmpline) - (h - tmpline))
goto trunc;
h += w;
if (h >= tmpline + sizeof(tmpline) - 4)
goto trunc;
*(h++) = ' ';
*(h++) = '\"';
uri = txn->uri ? txn->uri : "<BADREQ>";
h = encode_string(h, tmpline + sizeof(tmpline) - 1,
'#', url_encode_map, uri);
*(h++) = '\"';
w = snprintf(h, sizeof(tmpline) - (h - tmpline), " %d %lld", txn->status, s->logs.bytes_out);
if (w < 0 || w >= sizeof(tmpline) - (h - tmpline))
goto trunc;
h += w;
if (h >= tmpline + sizeof(tmpline) - 9)
goto trunc;
memcpy(h, " \"-\" \"-\"", 8);
h += 8;
w = snprintf(h, sizeof(tmpline) - (h - tmpline),
" %d %03d",
(s->cli_addr.ss_family == AF_INET) ?
ntohs(((struct sockaddr_in *)&s->cli_addr)->sin_port) :
ntohs(((struct sockaddr_in6 *)&s->cli_addr)->sin6_port),
(int)s->logs.accept_date.tv_usec/1000);
if (w < 0 || w >= sizeof(tmpline) - (h - tmpline))
goto trunc;
h += w;
w = strlen(fe->id);
if (h >= tmpline + sizeof(tmpline) - 4 - w)
goto trunc;
*(h++) = ' ';
*(h++) = '\"';
memcpy(h, fe->id, w);
h += w;
*(h++) = '\"';
w = strlen(be->id);
if (h >= tmpline + sizeof(tmpline) - 4 - w)
goto trunc;
*(h++) = ' ';
*(h++) = '\"';
memcpy(h, be->id, w);
h += w;
*(h++) = '\"';
svid = (tolog & LW_SVID) ?
(s->data_source != DATA_SRC_STATS) ?
(s->srv != NULL) ? s->srv->id : "<NOSRV>" : "<STATS>" : "-";
w = strlen(svid);
if (h >= tmpline + sizeof(tmpline) - 4 - w)
goto trunc;
*(h++) = ' ';
*(h++) = '\"';
memcpy(h, svid, w);
h += w;
*(h++) = '\"';
t_request = -1;
if (tv_isge(&s->logs.tv_request, &s->logs.tv_accept))
t_request = tv_ms_elapsed(&s->logs.tv_accept, &s->logs.tv_request);
w = snprintf(h, sizeof(tmpline) - (h - tmpline),
" %d %ld %ld %ld %ld",
t_request,
(s->logs.t_queue >= 0) ? s->logs.t_queue - t_request : -1,
(s->logs.t_connect >= 0) ? s->logs.t_connect - s->logs.t_queue : -1,
(s->logs.t_data >= 0) ? s->logs.t_data - s->logs.t_connect : -1,
s->logs.t_close);
if (w < 0 || w >= sizeof(tmpline) - (h - tmpline))
goto trunc;
h += w;
if (h >= tmpline + sizeof(tmpline) - 8)
goto trunc;
*(h++) = ' ';
*(h++) = '\"';
*(h++) = sess_term_cond[(s->flags & SN_ERR_MASK) >> SN_ERR_SHIFT];
*(h++) = sess_fin_state[(s->flags & SN_FINST_MASK) >> SN_FINST_SHIFT];
*(h++) = (be->options & PR_O_COOK_ANY) ? sess_cookie[(txn->flags & TX_CK_MASK) >> TX_CK_SHIFT] : '-',
*(h++) = (be->options & PR_O_COOK_ANY) ? sess_set_cookie[(txn->flags & TX_SCK_MASK) >> TX_SCK_SHIFT] : '-';
*(h++) = '\"';
w = snprintf(h, sizeof(tmpline) - (h - tmpline),
" %d %d %d %d %d %ld %ld",
actconn, fe->feconn, be->beconn, s->srv ? s->srv->cur_sess : 0,
(s->req->cons->conn_retries > 0) ? (be->conn_retries - s->req->cons->conn_retries) : be->conn_retries,
s->logs.srv_queue_size, s->logs.prx_queue_size);
if (w < 0 || w >= sizeof(tmpline) - (h - tmpline))
goto trunc;
h += w;
if (txn->cli_cookie) {
w = strlen(txn->cli_cookie);
if (h >= tmpline + sizeof(tmpline) - 4 - w)
goto trunc;
*(h++) = ' ';
*(h++) = '\"';
memcpy(h, txn->cli_cookie, w);
h += w;
*(h++) = '\"';
} else {
if (h >= tmpline + sizeof(tmpline) - 5)
goto trunc;
memcpy(h, " \"-\"", 4);
h += 4;
}
if (txn->srv_cookie) {
w = strlen(txn->srv_cookie);
if (h >= tmpline + sizeof(tmpline) - 4 - w)
goto trunc;
*(h++) = ' ';
*(h++) = '\"';
memcpy(h, txn->srv_cookie, w);
h += w;
*(h++) = '\"';
} else {
if (h >= tmpline + sizeof(tmpline) - 5)
goto trunc;
memcpy(h, " \"-\"", 4);
h += 4;
}
if ((fe->to_log & LW_REQHDR) && txn->req.cap) {
for (hdr = 0; hdr < fe->nb_req_cap; hdr++) {
if (h >= sizeof (tmpline) + tmpline - 4)
goto trunc;
if (txn->req.cap[hdr] != NULL) {
*(h++) = ' ';
*(h++) = '\"';
h = encode_string(h, tmpline + sizeof(tmpline) - 2,
'#', hdr_encode_map, txn->req.cap[hdr]);
*(h++) = '\"';
} else {
memcpy(h, " \"-\"", 4);
h += 4;
}
}
}
if ((fe->to_log & LW_RSPHDR) && txn->rsp.cap) {
for (hdr = 0; hdr < fe->nb_rsp_cap; hdr++) {
if (h >= sizeof (tmpline) + tmpline - 4)
goto trunc;
if (txn->rsp.cap[hdr] != NULL) {
*(h++) = ' ';
*(h++) = '\"';
h = encode_string(h, tmpline + sizeof(tmpline) - 2,
'#', hdr_encode_map, txn->rsp.cap[hdr]);
*(h++) = '\"';
} else {
memcpy(h, " \"-\"", 4);
h += 4;
}
}
}
trunc:
*h = '\0';
level = LOG_INFO;
if (err && (fe->options2 & PR_O2_LOGERRORS))
level = LOG_ERR;
send_log(prx_log, level, "%s\n", tmpline);
s->logs.logwait = 0;
}
/*
* send a log for the session when we have enough info about it.
* Will not log if the frontend has no log defined.
*/
void http_sess_log(struct session *s)
{
char pn[INET6_ADDRSTRLEN + strlen(":65535")];
struct proxy *fe = s->fe;
struct proxy *be = s->be;
struct proxy *prx_log;
struct http_txn *txn = &s->txn;
int tolog, level, err;
char *uri, *h;
char *svid;
struct tm tm;
static char tmpline[MAX_SYSLOG_LEN];
int t_request;
int hdr;
/* if we don't want to log normal traffic, return now */
err = (s->flags & (SN_ERR_MASK | SN_REDISP)) ||
(s->req->cons->conn_retries != be->conn_retries) ||
txn->status >= 500;
if (!err && (fe->options2 & PR_O2_NOLOGNORM))
return;
if (fe->logfac1 < 0 && fe->logfac2 < 0)
return;
prx_log = fe;
if (prx_log->options2 & PR_O2_CLFLOG)
return http_sess_clflog(s);
if (s->cli_addr.ss_family == AF_INET)
inet_ntop(AF_INET,
(const void *)&((struct sockaddr_in *)&s->cli_addr)->sin_addr,
pn, sizeof(pn));
else
inet_ntop(AF_INET6,
(const void *)&((struct sockaddr_in6 *)(&s->cli_addr))->sin6_addr,
pn, sizeof(pn));
get_localtime(s->logs.accept_date.tv_sec, &tm);
/* FIXME: let's limit ourselves to frontend logging for now. */
tolog = fe->to_log;
h = tmpline;
if (fe->to_log & LW_REQHDR &&
txn->req.cap &&
(h < tmpline + sizeof(tmpline) - 10)) {
*(h++) = ' ';
*(h++) = '{';
for (hdr = 0; hdr < fe->nb_req_cap; hdr++) {
if (hdr)
*(h++) = '|';
if (txn->req.cap[hdr] != NULL)
h = encode_string(h, tmpline + sizeof(tmpline) - 7,
'#', hdr_encode_map, txn->req.cap[hdr]);
}
*(h++) = '}';
}
if (fe->to_log & LW_RSPHDR &&
txn->rsp.cap &&
(h < tmpline + sizeof(tmpline) - 7)) {
*(h++) = ' ';
*(h++) = '{';
for (hdr = 0; hdr < fe->nb_rsp_cap; hdr++) {
if (hdr)
*(h++) = '|';
if (txn->rsp.cap[hdr] != NULL)
h = encode_string(h, tmpline + sizeof(tmpline) - 4,
'#', hdr_encode_map, txn->rsp.cap[hdr]);
}
*(h++) = '}';
}
if (h < tmpline + sizeof(tmpline) - 4) {
*(h++) = ' ';
*(h++) = '"';
uri = txn->uri ? txn->uri : "<BADREQ>";
h = encode_string(h, tmpline + sizeof(tmpline) - 1,
'#', url_encode_map, uri);
*(h++) = '"';
}
*h = '\0';
svid = (tolog & LW_SVID) ?
(s->data_source != DATA_SRC_STATS) ?
(s->srv != NULL) ? s->srv->id : "<NOSRV>" : "<STATS>" : "-";
t_request = -1;
if (tv_isge(&s->logs.tv_request, &s->logs.tv_accept))
t_request = tv_ms_elapsed(&s->logs.tv_accept, &s->logs.tv_request);
level = LOG_INFO;
if (err && (fe->options2 & PR_O2_LOGERRORS))
level = LOG_ERR;
send_log(prx_log, level,
"%s:%d [%02d/%s/%04d:%02d:%02d:%02d.%03d]"
" %s %s/%s %d/%ld/%ld/%ld/%s%ld %d %s%lld"
" %s %s %c%c%c%c %d/%d/%d/%d/%s%u %ld/%ld%s\n",
pn,
(s->cli_addr.ss_family == AF_INET) ?
ntohs(((struct sockaddr_in *)&s->cli_addr)->sin_port) :
ntohs(((struct sockaddr_in6 *)&s->cli_addr)->sin6_port),
tm.tm_mday, monthname[tm.tm_mon], tm.tm_year+1900,
tm.tm_hour, tm.tm_min, tm.tm_sec, (int)s->logs.accept_date.tv_usec/1000,
fe->id, be->id, svid,
t_request,
(s->logs.t_queue >= 0) ? s->logs.t_queue - t_request : -1,
(s->logs.t_connect >= 0) ? s->logs.t_connect - s->logs.t_queue : -1,
(s->logs.t_data >= 0) ? s->logs.t_data - s->logs.t_connect : -1,
(tolog & LW_BYTES) ? "" : "+", s->logs.t_close,
txn->status,
(tolog & LW_BYTES) ? "" : "+", s->logs.bytes_out,
txn->cli_cookie ? txn->cli_cookie : "-",
txn->srv_cookie ? txn->srv_cookie : "-",
sess_term_cond[(s->flags & SN_ERR_MASK) >> SN_ERR_SHIFT],
sess_fin_state[(s->flags & SN_FINST_MASK) >> SN_FINST_SHIFT],
(be->options & PR_O_COOK_ANY) ? sess_cookie[(txn->flags & TX_CK_MASK) >> TX_CK_SHIFT] : '-',
(be->options & PR_O_COOK_ANY) ? sess_set_cookie[(txn->flags & TX_SCK_MASK) >> TX_SCK_SHIFT] : '-',
actconn, fe->feconn, be->beconn, s->srv ? s->srv->cur_sess : 0,
(s->flags & SN_REDISP)?"+":"",
(s->req->cons->conn_retries>0)?(be->conn_retries - s->req->cons->conn_retries):be->conn_retries,
s->logs.srv_queue_size, s->logs.prx_queue_size, tmpline);
s->logs.logwait = 0;
}
/*
* Capture headers from message starting at <som> according to header list
* <cap_hdr>, and fill the <idx> structure appropriately.
*/
void capture_headers(char *som, struct hdr_idx *idx,
char **cap, struct cap_hdr *cap_hdr)
{
char *eol, *sol, *col, *sov;
int cur_idx;
struct cap_hdr *h;
int len;
sol = som + hdr_idx_first_pos(idx);
cur_idx = hdr_idx_first_idx(idx);
while (cur_idx) {
eol = sol + idx->v[cur_idx].len;
col = sol;
while (col < eol && *col != ':')
col++;
sov = col + 1;
while (sov < eol && http_is_lws[(unsigned char)*sov])
sov++;
for (h = cap_hdr; h; h = h->next) {
if ((h->namelen == col - sol) &&
(strncasecmp(sol, h->name, h->namelen) == 0)) {
if (cap[h->index] == NULL)
cap[h->index] =
pool_alloc2(h->pool);
if (cap[h->index] == NULL) {
Alert("HTTP capture : out of memory.\n");
continue;
}
len = eol - sov;
if (len > h->len)
len = h->len;
memcpy(cap[h->index], sov, len);
cap[h->index][len]=0;
}
}
sol = eol + idx->v[cur_idx].cr + 1;
cur_idx = idx->v[cur_idx].next;
}
}
/* either we find an LF at <ptr> or we jump to <bad>.
*/
#define EXPECT_LF_HERE(ptr, bad) do { if (unlikely(*(ptr) != '\n')) goto bad; } while (0)
/* plays with variables <ptr>, <end> and <state>. Jumps to <good> if OK,
* otherwise to <http_msg_ood> with <state> set to <st>.
*/
#define EAT_AND_JUMP_OR_RETURN(good, st) do { \
ptr++; \
if (likely(ptr < end)) \
goto good; \
else { \
state = (st); \
goto http_msg_ood; \
} \
} while (0)
/*
* This function parses a status line between <ptr> and <end>, starting with
* parser state <state>. Only states HTTP_MSG_RPVER, HTTP_MSG_RPVER_SP,
* HTTP_MSG_RPCODE, HTTP_MSG_RPCODE_SP and HTTP_MSG_RPREASON are handled. Others
* will give undefined results.
* Note that it is upon the caller's responsibility to ensure that ptr < end,
* and that msg->sol points to the beginning of the response.
* If a complete line is found (which implies that at least one CR or LF is
* found before <end>, the updated <ptr> is returned, otherwise NULL is
* returned indicating an incomplete line (which does not mean that parts have
* not been updated). In the incomplete case, if <ret_ptr> or <ret_state> are
* non-NULL, they are fed with the new <ptr> and <state> values to be passed
* upon next call.
*
* This function was intentionally designed to be called from
* http_msg_analyzer() with the lowest overhead. It should integrate perfectly
* within its state machine and use the same macros, hence the need for same
* labels and variable names. Note that msg->sol is left unchanged.
*/
const char *http_parse_stsline(struct http_msg *msg, const char *msg_buf,
unsigned int state, const char *ptr, const char *end,
char **ret_ptr, unsigned int *ret_state)
{
switch (state) {
http_msg_rpver:
case HTTP_MSG_RPVER:
if (likely(HTTP_IS_VER_TOKEN(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rpver, HTTP_MSG_RPVER);
if (likely(HTTP_IS_SPHT(*ptr))) {
msg->sl.st.v_l = (ptr - msg_buf) - msg->som;
EAT_AND_JUMP_OR_RETURN(http_msg_rpver_sp, HTTP_MSG_RPVER_SP);
}
state = HTTP_MSG_ERROR;
break;
http_msg_rpver_sp:
case HTTP_MSG_RPVER_SP:
if (likely(!HTTP_IS_LWS(*ptr))) {
msg->sl.st.c = (ptr - msg_buf) - msg->som;
goto http_msg_rpcode;
}
if (likely(HTTP_IS_SPHT(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rpver_sp, HTTP_MSG_RPVER_SP);
/* so it's a CR/LF, this is invalid */
state = HTTP_MSG_ERROR;
break;
http_msg_rpcode:
case HTTP_MSG_RPCODE:
if (likely(!HTTP_IS_LWS(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rpcode, HTTP_MSG_RPCODE);
if (likely(HTTP_IS_SPHT(*ptr))) {
msg->sl.st.c_l = (ptr - msg_buf) - msg->som - msg->sl.st.c;
EAT_AND_JUMP_OR_RETURN(http_msg_rpcode_sp, HTTP_MSG_RPCODE_SP);
}
/* so it's a CR/LF, so there is no reason phrase */
msg->sl.st.c_l = (ptr - msg_buf) - msg->som - msg->sl.st.c;
http_msg_rsp_reason:
/* FIXME: should we support HTTP responses without any reason phrase ? */
msg->sl.st.r = (ptr - msg_buf) - msg->som;
msg->sl.st.r_l = 0;
goto http_msg_rpline_eol;
http_msg_rpcode_sp:
case HTTP_MSG_RPCODE_SP:
if (likely(!HTTP_IS_LWS(*ptr))) {
msg->sl.st.r = (ptr - msg_buf) - msg->som;
goto http_msg_rpreason;
}
if (likely(HTTP_IS_SPHT(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rpcode_sp, HTTP_MSG_RPCODE_SP);
/* so it's a CR/LF, so there is no reason phrase */
goto http_msg_rsp_reason;
http_msg_rpreason:
case HTTP_MSG_RPREASON:
if (likely(!HTTP_IS_CRLF(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rpreason, HTTP_MSG_RPREASON);
msg->sl.st.r_l = (ptr - msg_buf) - msg->som - msg->sl.st.r;
http_msg_rpline_eol:
/* We have seen the end of line. Note that we do not
* necessarily have the \n yet, but at least we know that we
* have EITHER \r OR \n, otherwise the response would not be
* complete. We can then record the response length and return
* to the caller which will be able to register it.
*/
msg->sl.st.l = ptr - msg->sol;
return ptr;
#ifdef DEBUG_FULL
default:
fprintf(stderr, "FIXME !!!! impossible state at %s:%d = %d\n", __FILE__, __LINE__, state);
exit(1);
#endif
}
http_msg_ood:
/* out of valid data */
if (ret_state)
*ret_state = state;
if (ret_ptr)
*ret_ptr = (char *)ptr;
return NULL;
}
/*
* This function parses a request line between <ptr> and <end>, starting with
* parser state <state>. Only states HTTP_MSG_RQMETH, HTTP_MSG_RQMETH_SP,
* HTTP_MSG_RQURI, HTTP_MSG_RQURI_SP and HTTP_MSG_RQVER are handled. Others
* will give undefined results.
* Note that it is upon the caller's responsibility to ensure that ptr < end,
* and that msg->sol points to the beginning of the request.
* If a complete line is found (which implies that at least one CR or LF is
* found before <end>, the updated <ptr> is returned, otherwise NULL is
* returned indicating an incomplete line (which does not mean that parts have
* not been updated). In the incomplete case, if <ret_ptr> or <ret_state> are
* non-NULL, they are fed with the new <ptr> and <state> values to be passed
* upon next call.
*
* This function was intentionally designed to be called from
* http_msg_analyzer() with the lowest overhead. It should integrate perfectly
* within its state machine and use the same macros, hence the need for same
* labels and variable names. Note that msg->sol is left unchanged.
*/
const char *http_parse_reqline(struct http_msg *msg, const char *msg_buf,
unsigned int state, const char *ptr, const char *end,
char **ret_ptr, unsigned int *ret_state)
{
switch (state) {
http_msg_rqmeth:
case HTTP_MSG_RQMETH:
if (likely(HTTP_IS_TOKEN(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rqmeth, HTTP_MSG_RQMETH);
if (likely(HTTP_IS_SPHT(*ptr))) {
msg->sl.rq.m_l = (ptr - msg_buf) - msg->som;
EAT_AND_JUMP_OR_RETURN(http_msg_rqmeth_sp, HTTP_MSG_RQMETH_SP);
}
if (likely(HTTP_IS_CRLF(*ptr))) {
/* HTTP 0.9 request */
msg->sl.rq.m_l = (ptr - msg_buf) - msg->som;
http_msg_req09_uri:
msg->sl.rq.u = (ptr - msg_buf) - msg->som;
http_msg_req09_uri_e:
msg->sl.rq.u_l = (ptr - msg_buf) - msg->som - msg->sl.rq.u;
http_msg_req09_ver:
msg->sl.rq.v = (ptr - msg_buf) - msg->som;
msg->sl.rq.v_l = 0;
goto http_msg_rqline_eol;
}
state = HTTP_MSG_ERROR;
break;
http_msg_rqmeth_sp:
case HTTP_MSG_RQMETH_SP:
if (likely(!HTTP_IS_LWS(*ptr))) {
msg->sl.rq.u = (ptr - msg_buf) - msg->som;
goto http_msg_rquri;
}
if (likely(HTTP_IS_SPHT(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rqmeth_sp, HTTP_MSG_RQMETH_SP);
/* so it's a CR/LF, meaning an HTTP 0.9 request */
goto http_msg_req09_uri;
http_msg_rquri:
case HTTP_MSG_RQURI:
if (likely(!HTTP_IS_LWS(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rquri, HTTP_MSG_RQURI);
if (likely(HTTP_IS_SPHT(*ptr))) {
msg->sl.rq.u_l = (ptr - msg_buf) - msg->som - msg->sl.rq.u;
EAT_AND_JUMP_OR_RETURN(http_msg_rquri_sp, HTTP_MSG_RQURI_SP);
}
/* so it's a CR/LF, meaning an HTTP 0.9 request */
goto http_msg_req09_uri_e;
http_msg_rquri_sp:
case HTTP_MSG_RQURI_SP:
if (likely(!HTTP_IS_LWS(*ptr))) {
msg->sl.rq.v = (ptr - msg_buf) - msg->som;
goto http_msg_rqver;
}
if (likely(HTTP_IS_SPHT(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rquri_sp, HTTP_MSG_RQURI_SP);
/* so it's a CR/LF, meaning an HTTP 0.9 request */
goto http_msg_req09_ver;
http_msg_rqver:
case HTTP_MSG_RQVER:
if (likely(HTTP_IS_VER_TOKEN(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_rqver, HTTP_MSG_RQVER);
if (likely(HTTP_IS_CRLF(*ptr))) {
msg->sl.rq.v_l = (ptr - msg_buf) - msg->som - msg->sl.rq.v;
http_msg_rqline_eol:
/* We have seen the end of line. Note that we do not
* necessarily have the \n yet, but at least we know that we
* have EITHER \r OR \n, otherwise the request would not be
* complete. We can then record the request length and return
* to the caller which will be able to register it.
*/
msg->sl.rq.l = ptr - msg->sol;
return ptr;
}
/* neither an HTTP_VER token nor a CRLF */
state = HTTP_MSG_ERROR;
break;
#ifdef DEBUG_FULL
default:
fprintf(stderr, "FIXME !!!! impossible state at %s:%d = %d\n", __FILE__, __LINE__, state);
exit(1);
#endif
}
http_msg_ood:
/* out of valid data */
if (ret_state)
*ret_state = state;
if (ret_ptr)
*ret_ptr = (char *)ptr;
return NULL;
}
/*
* Returns the data from Authorization header. Function may be called more
* than once so data is stored in txn->auth_data. When no header is found
* or auth method is unknown auth_method is set to HTTP_AUTH_WRONG to avoid
* searching again for something we are unable to find anyway.
*/
char get_http_auth_buff[BUFSIZE];
int
get_http_auth(struct session *s)
{
struct http_txn *txn = &s->txn;
struct chunk auth_method;
struct hdr_ctx ctx;
char *h, *p;
int len;
#ifdef DEBUG_AUTH
printf("Auth for session %p: %d\n", s, txn->auth.method);
#endif
if (txn->auth.method == HTTP_AUTH_WRONG)
return 0;
if (txn->auth.method)
return 1;
txn->auth.method = HTTP_AUTH_WRONG;
ctx.idx = 0;
if (txn->flags & TX_USE_PX_CONN) {
h = "Proxy-Authorization";
len = strlen(h);
} else {
h = "Authorization";
len = strlen(h);
}
if (!http_find_header2(h, len, txn->req.sol, &txn->hdr_idx, &ctx))
return 0;
h = ctx.line + ctx.val;
p = memchr(h, ' ', ctx.vlen);
if (!p || p == h)
return 0;
chunk_initlen(&auth_method, h, 0, p-h);
chunk_initlen(&txn->auth.method_data, p+1, 0, ctx.vlen-(p-h)-1);
if (!strncasecmp("Basic", auth_method.str, auth_method.len)) {
len = base64dec(txn->auth.method_data.str, txn->auth.method_data.len,
get_http_auth_buff, BUFSIZE - 1);
if (len < 0)
return 0;
get_http_auth_buff[len] = '\0';
p = strchr(get_http_auth_buff, ':');
if (!p)
return 0;
txn->auth.user = get_http_auth_buff;
*p = '\0';
txn->auth.pass = p+1;
txn->auth.method = HTTP_AUTH_BASIC;
return 1;
}
return 0;
}
/*
* This function parses an HTTP message, either a request or a response,
* depending on the initial msg->msg_state. It can be preempted everywhere
* when data are missing and recalled at the exact same location with no
* information loss. The header index is re-initialized when switching from
* MSG_R[PQ]BEFORE to MSG_RPVER|MSG_RQMETH. It modifies msg->sol among other
* fields. Note that msg->som and msg->sol will be initialized after completing
* the first state, so that none of the msg pointers has to be initialized
* prior to the first call.
*/
void http_msg_analyzer(struct buffer *buf, struct http_msg *msg, struct hdr_idx *idx)
{
unsigned int state; /* updated only when leaving the FSM */
register char *ptr, *end; /* request pointers, to avoid dereferences */
state = msg->msg_state;
ptr = buf->lr;
end = buf->r;
if (unlikely(ptr >= end))
goto http_msg_ood;
switch (state) {
/*
* First, states that are specific to the response only.
* We check them first so that request and headers are
* closer to each other (accessed more often).
*/
http_msg_rpbefore:
case HTTP_MSG_RPBEFORE:
if (likely(HTTP_IS_TOKEN(*ptr))) {
/* we have a start of message, but we have to check
* first if we need to remove some CRLF. We can only
* do this when send_max=0.
*/
char *beg = buf->w + buf->send_max;
if (beg >= buf->data + buf->size)
beg -= buf->size;
if (unlikely(ptr != beg)) {
if (buf->send_max)
goto http_msg_ood;
/* Remove empty leading lines, as recommended by RFC2616. */
buffer_ignore(buf, ptr - beg);
}
msg->som = ptr - buf->data;
msg->sol = ptr;
hdr_idx_init(idx);
state = HTTP_MSG_RPVER;
goto http_msg_rpver;
}
if (unlikely(!HTTP_IS_CRLF(*ptr)))
goto http_msg_invalid;
if (unlikely(*ptr == '\n'))
EAT_AND_JUMP_OR_RETURN(http_msg_rpbefore, HTTP_MSG_RPBEFORE);
EAT_AND_JUMP_OR_RETURN(http_msg_rpbefore_cr, HTTP_MSG_RPBEFORE_CR);
/* stop here */
http_msg_rpbefore_cr:
case HTTP_MSG_RPBEFORE_CR:
EXPECT_LF_HERE(ptr, http_msg_invalid);
EAT_AND_JUMP_OR_RETURN(http_msg_rpbefore, HTTP_MSG_RPBEFORE);
/* stop here */
http_msg_rpver:
case HTTP_MSG_RPVER:
case HTTP_MSG_RPVER_SP:
case HTTP_MSG_RPCODE:
case HTTP_MSG_RPCODE_SP:
case HTTP_MSG_RPREASON:
ptr = (char *)http_parse_stsline(msg, buf->data, state, ptr, end,
&buf->lr, &msg->msg_state);
if (unlikely(!ptr))
return;
/* we have a full response and we know that we have either a CR
* or an LF at <ptr>.
*/
//fprintf(stderr,"som=%d rq.l=%d *ptr=0x%02x\n", msg->som, msg->sl.st.l, *ptr);
hdr_idx_set_start(idx, msg->sl.st.l, *ptr == '\r');
msg->sol = ptr;
if (likely(*ptr == '\r'))
EAT_AND_JUMP_OR_RETURN(http_msg_rpline_end, HTTP_MSG_RPLINE_END);
goto http_msg_rpline_end;
http_msg_rpline_end:
case HTTP_MSG_RPLINE_END:
/* msg->sol must point to the first of CR or LF. */
EXPECT_LF_HERE(ptr, http_msg_invalid);
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_first, HTTP_MSG_HDR_FIRST);
/* stop here */
/*
* Second, states that are specific to the request only
*/
http_msg_rqbefore:
case HTTP_MSG_RQBEFORE:
if (likely(HTTP_IS_TOKEN(*ptr))) {
/* we have a start of message, but we have to check
* first if we need to remove some CRLF. We can only
* do this when send_max=0.
*/
char *beg = buf->w + buf->send_max;
if (beg >= buf->data + buf->size)
beg -= buf->size;
if (likely(ptr != beg)) {
if (buf->send_max)
goto http_msg_ood;
/* Remove empty leading lines, as recommended by RFC2616. */
buffer_ignore(buf, ptr - beg);
}
msg->som = ptr - buf->data;
msg->sol = ptr;
/* we will need this when keep-alive will be supported
hdr_idx_init(idx);
*/
state = HTTP_MSG_RQMETH;
goto http_msg_rqmeth;
}
if (unlikely(!HTTP_IS_CRLF(*ptr)))
goto http_msg_invalid;
if (unlikely(*ptr == '\n'))
EAT_AND_JUMP_OR_RETURN(http_msg_rqbefore, HTTP_MSG_RQBEFORE);
EAT_AND_JUMP_OR_RETURN(http_msg_rqbefore_cr, HTTP_MSG_RQBEFORE_CR);
/* stop here */
http_msg_rqbefore_cr:
case HTTP_MSG_RQBEFORE_CR:
EXPECT_LF_HERE(ptr, http_msg_invalid);
EAT_AND_JUMP_OR_RETURN(http_msg_rqbefore, HTTP_MSG_RQBEFORE);
/* stop here */
http_msg_rqmeth:
case HTTP_MSG_RQMETH:
case HTTP_MSG_RQMETH_SP:
case HTTP_MSG_RQURI:
case HTTP_MSG_RQURI_SP:
case HTTP_MSG_RQVER:
ptr = (char *)http_parse_reqline(msg, buf->data, state, ptr, end,
&buf->lr, &msg->msg_state);
if (unlikely(!ptr))
return;
/* we have a full request and we know that we have either a CR
* or an LF at <ptr>.
*/
//fprintf(stderr,"som=%d rq.l=%d *ptr=0x%02x\n", msg->som, msg->sl.rq.l, *ptr);
hdr_idx_set_start(idx, msg->sl.rq.l, *ptr == '\r');
msg->sol = ptr;
if (likely(*ptr == '\r'))
EAT_AND_JUMP_OR_RETURN(http_msg_rqline_end, HTTP_MSG_RQLINE_END);
goto http_msg_rqline_end;
http_msg_rqline_end:
case HTTP_MSG_RQLINE_END:
/* check for HTTP/0.9 request : no version information available.
* msg->sol must point to the first of CR or LF.
*/
if (unlikely(msg->sl.rq.v_l == 0))
goto http_msg_last_lf;
EXPECT_LF_HERE(ptr, http_msg_invalid);
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_first, HTTP_MSG_HDR_FIRST);
/* stop here */
/*
* Common states below
*/
http_msg_hdr_first:
case HTTP_MSG_HDR_FIRST:
msg->sol = ptr;
if (likely(!HTTP_IS_CRLF(*ptr))) {
goto http_msg_hdr_name;
}
if (likely(*ptr == '\r'))
EAT_AND_JUMP_OR_RETURN(http_msg_last_lf, HTTP_MSG_LAST_LF);
goto http_msg_last_lf;
http_msg_hdr_name:
case HTTP_MSG_HDR_NAME:
/* assumes msg->sol points to the first char */
if (likely(HTTP_IS_TOKEN(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_name, HTTP_MSG_HDR_NAME);
if (likely(*ptr == ':')) {
msg->col = ptr - buf->data;
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_l1_sp, HTTP_MSG_HDR_L1_SP);
}
if (likely(msg->err_pos < -1) || *ptr == '\n')
goto http_msg_invalid;
if (msg->err_pos == -1) /* capture error pointer */
msg->err_pos = ptr - buf->data; /* >= 0 now */
/* and we still accept this non-token character */
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_name, HTTP_MSG_HDR_NAME);
http_msg_hdr_l1_sp:
case HTTP_MSG_HDR_L1_SP:
/* assumes msg->sol points to the first char and msg->col to the colon */
if (likely(HTTP_IS_SPHT(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_l1_sp, HTTP_MSG_HDR_L1_SP);
/* header value can be basically anything except CR/LF */
msg->sov = ptr - buf->data;
if (likely(!HTTP_IS_CRLF(*ptr))) {
goto http_msg_hdr_val;
}
if (likely(*ptr == '\r'))
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_l1_lf, HTTP_MSG_HDR_L1_LF);
goto http_msg_hdr_l1_lf;
http_msg_hdr_l1_lf:
case HTTP_MSG_HDR_L1_LF:
EXPECT_LF_HERE(ptr, http_msg_invalid);
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_l1_lws, HTTP_MSG_HDR_L1_LWS);
http_msg_hdr_l1_lws:
case HTTP_MSG_HDR_L1_LWS:
if (likely(HTTP_IS_SPHT(*ptr))) {
/* replace HT,CR,LF with spaces */
for (; buf->data+msg->sov < ptr; msg->sov++)
buf->data[msg->sov] = ' ';
goto http_msg_hdr_l1_sp;
}
/* we had a header consisting only in spaces ! */
msg->eol = buf->data + msg->sov;
goto http_msg_complete_header;
http_msg_hdr_val:
case HTTP_MSG_HDR_VAL:
/* assumes msg->sol points to the first char, msg->col to the
* colon, and msg->sov points to the first character of the
* value.
*/
if (likely(!HTTP_IS_CRLF(*ptr)))
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_val, HTTP_MSG_HDR_VAL);
msg->eol = ptr;
/* Note: we could also copy eol into ->eoh so that we have the
* real header end in case it ends with lots of LWS, but is this
* really needed ?
*/
if (likely(*ptr == '\r'))
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_l2_lf, HTTP_MSG_HDR_L2_LF);
goto http_msg_hdr_l2_lf;
http_msg_hdr_l2_lf:
case HTTP_MSG_HDR_L2_LF:
EXPECT_LF_HERE(ptr, http_msg_invalid);
EAT_AND_JUMP_OR_RETURN(http_msg_hdr_l2_lws, HTTP_MSG_HDR_L2_LWS);
http_msg_hdr_l2_lws:
case HTTP_MSG_HDR_L2_LWS:
if (unlikely(HTTP_IS_SPHT(*ptr))) {
/* LWS: replace HT,CR,LF with spaces */
for (; msg->eol < ptr; msg->eol++)
*msg->eol = ' ';
goto http_msg_hdr_val;
}
http_msg_complete_header:
/*
* It was a new header, so the last one is finished.
* Assumes msg->sol points to the first char, msg->col to the
* colon, msg->sov points to the first character of the value
* and msg->eol to the first CR or LF so we know how the line
* ends. We insert last header into the index.
*/
/*
fprintf(stderr,"registering %-2d bytes : ", msg->eol - msg->sol);
write(2, msg->sol, msg->eol-msg->sol);
fprintf(stderr,"\n");
*/
if (unlikely(hdr_idx_add(msg->eol - msg->sol, *msg->eol == '\r',
idx, idx->tail) < 0))
goto http_msg_invalid;
msg->sol = ptr;
if (likely(!HTTP_IS_CRLF(*ptr))) {
goto http_msg_hdr_name;
}
if (likely(*ptr == '\r'))
EAT_AND_JUMP_OR_RETURN(http_msg_last_lf, HTTP_MSG_LAST_LF);
goto http_msg_last_lf;
http_msg_last_lf:
case HTTP_MSG_LAST_LF:
/* Assumes msg->sol points to the first of either CR or LF */
EXPECT_LF_HERE(ptr, http_msg_invalid);
ptr++;
buf->lr = ptr;
msg->col = msg->sov = buf->lr - buf->data;
msg->eoh = msg->sol - buf->data;
msg->sol = buf->data + msg->som;
msg->msg_state = HTTP_MSG_BODY;
return;
#ifdef DEBUG_FULL
default:
fprintf(stderr, "FIXME !!!! impossible state at %s:%d = %d\n", __FILE__, __LINE__, state);
exit(1);
#endif
}
http_msg_ood:
/* out of data */
msg->msg_state = state;
buf->lr = ptr;
return;
http_msg_invalid:
/* invalid message */
msg->msg_state = HTTP_MSG_ERROR;
buf->lr = ptr;
return;
}
/* convert an HTTP/0.9 request into an HTTP/1.0 request. Returns 1 if the
* conversion succeeded, 0 in case of error. If the request was already 1.X,
* nothing is done and 1 is returned.
*/
static int http_upgrade_v09_to_v10(struct buffer *req, struct http_msg *msg, struct http_txn *txn)
{
int delta;
char *cur_end;
if (msg->sl.rq.v_l != 0)
return 1;
cur_end = msg->sol + msg->sl.rq.l;
delta = 0;
if (msg->sl.rq.u_l == 0) {
/* if no URI was set, add "/" */
delta = buffer_replace2(req, cur_end, cur_end, " /", 2);
cur_end += delta;
http_msg_move_end(msg, delta);
}
/* add HTTP version */
delta = buffer_replace2(req, cur_end, cur_end, " HTTP/1.0\r\n", 11);
http_msg_move_end(msg, delta);
cur_end += delta;
cur_end = (char *)http_parse_reqline(msg, req->data,
HTTP_MSG_RQMETH,
msg->sol, cur_end + 1,
NULL, NULL);
if (unlikely(!cur_end))
return 0;
/* we have a full HTTP/1.0 request now and we know that
* we have either a CR or an LF at <ptr>.
*/
hdr_idx_set_start(&txn->hdr_idx, msg->sl.rq.l, *cur_end == '\r');
return 1;
}
/* Parse the Connection: header of an HTTP request, looking for both "close"
* and "keep-alive" values. If a buffer is provided and we already know that
* some headers may safely be removed, we remove them now. The <to_del> flags
* are used for that :
* - bit 0 means remove "close" headers (in HTTP/1.0 requests/responses)
* - bit 1 means remove "keep-alive" headers (in HTTP/1.1 reqs/resp to 1.1).
* The TX_HDR_CONN_* flags are adjusted in txn->flags depending on what was
* found, and TX_CON_*_SET is adjusted depending on what is left so only
* harmless combinations may be removed. Do not call that after changes have
* been processed. If unused, the buffer can be NULL, and no data will be
* changed.
*/
void http_parse_connection_header(struct http_txn *txn, struct http_msg *msg, struct buffer *buf, int to_del)
{
struct hdr_ctx ctx;
const char *hdr_val = "Connection";
int hdr_len = 10;
if (txn->flags & TX_HDR_CONN_PRS)
return;
if (unlikely(txn->flags & TX_USE_PX_CONN)) {
hdr_val = "Proxy-Connection";
hdr_len = 16;
}
ctx.idx = 0;
txn->flags &= ~(TX_CON_KAL_SET|TX_CON_CLO_SET);
while (http_find_header2(hdr_val, hdr_len, msg->sol, &txn->hdr_idx, &ctx)) {
if (ctx.vlen >= 10 && word_match(ctx.line + ctx.val, ctx.vlen, "keep-alive", 10)) {
txn->flags |= TX_HDR_CONN_KAL;
if ((to_del & 2) && buf)
http_remove_header2(msg, buf, &txn->hdr_idx, &ctx);
else
txn->flags |= TX_CON_KAL_SET;
}
else if (ctx.vlen >= 5 && word_match(ctx.line + ctx.val, ctx.vlen, "close", 5)) {
txn->flags |= TX_HDR_CONN_CLO;
if ((to_del & 1) && buf)
http_remove_header2(msg, buf, &txn->hdr_idx, &ctx);
else
txn->flags |= TX_CON_CLO_SET;
}
}
txn->flags |= TX_HDR_CONN_PRS;
return;
}
/* Apply desired changes on the Connection: header. Values may be removed and/or
* added depending on the <wanted> flags, which are exclusively composed of
* TX_CON_CLO_SET and TX_CON_KAL_SET, depending on what flags are desired. The
* TX_CON_*_SET flags are adjusted in txn->flags depending on what is left.
*/
void http_change_connection_header(struct http_txn *txn, struct http_msg *msg, struct buffer *buf, int wanted)
{
struct hdr_ctx ctx;
const char *hdr_val = "Connection";
int hdr_len = 10;
ctx.idx = 0;
if (unlikely(txn->flags & TX_USE_PX_CONN)) {
hdr_val = "Proxy-Connection";
hdr_len = 16;
}
txn->flags &= ~(TX_CON_CLO_SET | TX_CON_KAL_SET);
while (http_find_header2(hdr_val, hdr_len, msg->sol, &txn->hdr_idx, &ctx)) {
if (ctx.vlen >= 10 && word_match(ctx.line + ctx.val, ctx.vlen, "keep-alive", 10)) {
if (wanted & TX_CON_KAL_SET)
txn->flags |= TX_CON_KAL_SET;
else
http_remove_header2(msg, buf, &txn->hdr_idx, &ctx);
}
else if (ctx.vlen >= 5 && word_match(ctx.line + ctx.val, ctx.vlen, "close", 5)) {
if (wanted & TX_CON_CLO_SET)
txn->flags |= TX_CON_CLO_SET;
else
http_remove_header2(msg, buf, &txn->hdr_idx, &ctx);
}
}
if (wanted == (txn->flags & (TX_CON_CLO_SET|TX_CON_KAL_SET)))
return;
if ((wanted & TX_CON_CLO_SET) && !(txn->flags & TX_CON_CLO_SET)) {
txn->flags |= TX_CON_CLO_SET;
hdr_val = "Connection: close";
hdr_len = 17;
if (unlikely(txn->flags & TX_USE_PX_CONN)) {
hdr_val = "Proxy-Connection: close";
hdr_len = 23;
}
http_header_add_tail2(buf, msg, &txn->hdr_idx, hdr_val, hdr_len);
}
if ((wanted & TX_CON_KAL_SET) && !(txn->flags & TX_CON_KAL_SET)) {
txn->flags |= TX_CON_KAL_SET;
hdr_val = "Connection: keep-alive";
hdr_len = 22;
if (unlikely(txn->flags & TX_USE_PX_CONN)) {
hdr_val = "Proxy-Connection: keep-alive";
hdr_len = 28;
}
http_header_add_tail2(buf, msg, &txn->hdr_idx, hdr_val, hdr_len);
}
return;
}
/* Parse the chunk size at buf->lr. Once done, it adjusts ->lr to point to the
* first byte of body, and increments msg->sov by the number of bytes parsed,
* so that we know we can forward between ->som and ->sov. Note that due to
* possible wrapping at the end of the buffer, it is possible that msg->sov is
* lower than msg->som.
* Return >0 on success, 0 when some data is missing, <0 on error.
* Note: this function is designed to parse wrapped CRLF at the end of the buffer.
*/
int http_parse_chunk_size(struct buffer *buf, struct http_msg *msg)
{
char *ptr = buf->lr;
char *end = buf->data + buf->size;
unsigned int chunk = 0;
/* 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 (ptr == buf->r)
return 0;
c = hex2i(*ptr);
if (c < 0) /* not a hex digit anymore */
break;
if (++ptr >= end)
ptr = buf->data;
if (chunk & 0xF000000) /* overflow will occur */
return -1;
chunk = (chunk << 4) + c;
}
/* empty size not allowed */
if (ptr == buf->lr)
return -1;
while (http_is_spht[(unsigned char)*ptr]) {
if (++ptr >= end)
ptr = buf->data;
if (ptr == buf->r)
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 = buf->data;
if (ptr == buf->r)
return 0;
}
if (*ptr != '\n')
return -1;
if (++ptr >= end)
ptr = buf->data;
/* done */
break;
}
else if (*ptr == ';') {
/* chunk extension, ends at next CRLF */
if (++ptr >= end)
ptr = buf->data;
if (ptr == buf->r)
return 0;
while (!HTTP_IS_CRLF(*ptr)) {
if (++ptr >= end)
ptr = buf->data;
if (ptr == buf->r)
return 0;
}
/* we have a CRLF now, loop above */
continue;
}
else
return -1;
}
/* OK we found our CRLF and now <ptr> points to the next byte,
* which may or may not be present. We save that into ->lr and
* ->sov.
*/
msg->sov += ptr - buf->lr;
buf->lr = ptr;
msg->hdr_content_len = chunk;
msg->msg_state = chunk ? HTTP_MSG_DATA : HTTP_MSG_TRAILERS;
return 1;
}
/* This function skips trailers in the buffer <buf> associated with HTTP
* message <msg>. The first visited position is buf->lr. If the end of
* the trailers is found, it is automatically scheduled to be forwarded,
* msg->msg_state switches to HTTP_MSG_DONE, and the function returns >0.
* If not enough data are available, the function does not change anything
* except maybe buf->lr and msg->sov if it could parse some lines, and returns
* zero. If a parse error is encountered, the function returns < 0 and does not
* change anything except maybe buf->lr and msg->sov. Note that the message
* must already be in HTTP_MSG_TRAILERS state before calling this function,
* which implies that all non-trailers data have already been scheduled for
* forwarding, and that the difference between msg->som and msg->sov exactly
* matches the length of trailers already parsed and not forwarded. It is also
* important to note that this function is designed to be able to parse wrapped
* headers at end of buffer.
*/
int http_forward_trailers(struct buffer *buf, struct http_msg *msg)
{
/* we have buf->lr which points to next line. Look for CRLF. */
while (1) {
char *p1 = NULL, *p2 = NULL;
char *ptr = buf->lr;
int bytes;
/* scan current line and stop at LF or CRLF */
while (1) {
if (ptr == buf->r)
return 0;
if (*ptr == '\n') {
if (!p1)
p1 = ptr;
p2 = ptr;
break;
}
if (*ptr == '\r') {
if (p1)
return -1;
p1 = ptr;
}
ptr++;
if (ptr >= buf->data + buf->size)
ptr = buf->data;
}
/* after LF; point to beginning of next line */
p2++;
if (p2 >= buf->data + buf->size)
p2 = buf->data;
bytes = p2 - buf->lr;
if (bytes < 0)
bytes += buf->size;
/* schedule this line for forwarding */
msg->sov += bytes;
if (msg->sov >= buf->size)
msg->sov -= buf->size;
if (p1 == buf->lr) {
/* LF/CRLF at beginning of line => end of trailers at p2.
* Everything was scheduled for forwarding, there's nothing
* left from this message.
*/
buf->lr = p2;
msg->msg_state = HTTP_MSG_DONE;
return 1;
}
/* OK, next line then */
buf->lr = p2;
}
}
/* This function may be called only in HTTP_MSG_DATA_CRLF. It reads the CRLF or
* a possible LF alone at the end of a chunk. It automatically adjusts msg->sov,
* ->som, buf->lr in order to include this part into the next forwarding phase.
* It also sets msg_state to HTTP_MSG_CHUNK_SIZE and returns >0 on success. If
* not enough data are available, the function does not change anything and
* returns zero. If a parse error is encountered, the function returns < 0 and
* does not change anything. Note: this function is designed to parse wrapped
* CRLF at the end of the buffer.
*/
int http_skip_chunk_crlf(struct buffer *buf, struct http_msg *msg)
{
char *ptr;
int bytes;
/* NB: we'll check data availabilty at the end. It's not a
* problem because whatever we match first will be checked
* against the correct length.
*/
bytes = 1;
ptr = buf->lr;
if (*ptr == '\r') {
bytes++;
ptr++;
if (ptr >= buf->data + buf->size)
ptr = buf->data;
}
if (bytes > buf->l - buf->send_max)
return 0;
if (*ptr != '\n')
return -1;
ptr++;
if (ptr >= buf->data + buf->size)
ptr = buf->data;
buf->lr = ptr;
/* prepare the CRLF to be forwarded. msg->som may be before data but we don't care */
msg->sov = ptr - buf->data;
msg->som = msg->sov - bytes;
msg->msg_state = HTTP_MSG_CHUNK_SIZE;
return 1;
}
void http_buffer_heavy_realign(struct buffer *buf, struct http_msg *msg)
{
char *end = buf->data + buf->size;
int off = buf->data + buf->size - buf->w;
/* two possible cases :
* - the buffer is in one contiguous block, we move it in-place
* - the buffer is in two blocks, we move it via the swap_buffer
*/
if (buf->l) {
int block1 = buf->l;
int block2 = 0;
if (buf->r <= buf->w) {
/* non-contiguous block */
block1 = buf->data + buf->size - buf->w;
block2 = buf->r - buf->data;
}
if (block2)
memcpy(swap_buffer, buf->data, block2);
memmove(buf->data, buf->w, block1);
if (block2)
memcpy(buf->data + block1, swap_buffer, block2);
}
/* adjust all known pointers */
buf->w = buf->data;
buf->lr += off; if (buf->lr >= end) buf->lr -= buf->size;
buf->r += off; if (buf->r >= end) buf->r -= buf->size;
msg->sol += off; if (msg->sol >= end) msg->sol -= buf->size;
msg->eol += off; if (msg->eol >= end) msg->eol -= buf->size;
/* adjust relative pointers */
msg->som = 0;
msg->eoh += off; if (msg->eoh >= buf->size) msg->eoh -= buf->size;
msg->col += off; if (msg->col >= buf->size) msg->col -= buf->size;
msg->sov += off; if (msg->sov >= buf->size) msg->sov -= buf->size;
if (msg->err_pos >= 0) {
msg->err_pos += off;
if (msg->err_pos >= buf->size)
msg->err_pos -= buf->size;
}
buf->flags &= ~BF_FULL;
if (buf->l >= buffer_max_len(buf))
buf->flags |= BF_FULL;
}
/* This stream analyser waits for a complete HTTP request. It returns 1 if the
* processing can continue on next analysers, or zero if it either needs more
* data or wants to immediately abort the request (eg: timeout, error, ...). It
* is tied to AN_REQ_WAIT_HTTP and may may remove itself from s->req->analysers
* when it has nothing left to do, and may remove any analyser when it wants to
* abort.
*/
int http_wait_for_request(struct session *s, struct buffer *req, int an_bit)
{
/*
* We will parse the partial (or complete) lines.
* We will check the request syntax, and also join multi-line
* headers. An index of all the lines will be elaborated while
* parsing.
*
* For the parsing, we use a 28 states FSM.
*
* Here is the information we currently have :
* req->data + msg->som = beginning of request
* req->data + msg->eoh = end of processed headers / start of current one
* msg->eol = end of current header or line (LF or CRLF)
* req->lr = first non-visited byte
* req->r = end of data
*
* At end of parsing, we may perform a capture of the error (if any), and
* we will set a few fields (msg->sol, txn->meth, sn->flags/SN_REDIRECTABLE).
* We also check for monitor-uri, logging, HTTP/0.9 to 1.0 conversion, and
* finally headers capture.
*/
int cur_idx;
int use_close_only;
struct http_txn *txn = &s->txn;
struct http_msg *msg = &txn->req;
struct hdr_ctx ctx;
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bl=%d analysers=%02x\n",
now_ms, __FUNCTION__,
s,
req,
req->rex, req->wex,
req->flags,
req->l,
req->analysers);
/* we're speaking HTTP here, so let's speak HTTP to the client */
s->srv_error = http_return_srv_error;
/* There's a protected area at the end of the buffer for rewriting
* purposes. We don't want to start to parse the request if the
* protected area is affected, because we may have to move processed
* data later, which is much more complicated.
*/
if (req->l && msg->msg_state < HTTP_MSG_ERROR) {
if ((txn->flags & TX_NOT_FIRST) &&
unlikely((req->flags & BF_FULL) ||
req->r < req->lr ||
req->r > req->data + req->size - global.tune.maxrewrite)) {
if (req->send_max) {
if (req->flags & (BF_SHUTW|BF_SHUTW_NOW|BF_WRITE_ERROR|BF_WRITE_TIMEOUT))
goto failed_keep_alive;
/* some data has still not left the buffer, wake us once that's done */
buffer_dont_connect(req);
req->flags |= BF_READ_DONTWAIT; /* try to get back here ASAP */
return 0;
}
if (req->l <= req->size - global.tune.maxrewrite)
http_buffer_heavy_realign(req, msg);
}
/* Note that we have the same problem with the response ; we
* may want to send a redirect, error or anything which requires
* some spare space. So we'll ensure that we have at least
* maxrewrite bytes available in the response buffer before
* processing that one. This will only affect pipelined
* keep-alive requests.
*/
if ((txn->flags & TX_NOT_FIRST) &&
unlikely((s->rep->flags & BF_FULL) ||
s->rep->r < s->rep->lr ||
s->rep->r > s->rep->data + s->rep->size - global.tune.maxrewrite)) {
if (s->rep->send_max) {
if (s->rep->flags & (BF_SHUTW|BF_SHUTW_NOW|BF_WRITE_ERROR|BF_WRITE_TIMEOUT))
goto failed_keep_alive;
/* don't let a connection request be initiated */
buffer_dont_connect(req);
s->rep->flags &= ~BF_EXPECT_MORE; /* speed up sending a previous response */
return 0;
}
}
if (likely(req->lr < req->r))
http_msg_analyzer(req, msg, &txn->hdr_idx);
}
/* 1: we might have to print this header in debug mode */
if (unlikely((global.mode & MODE_DEBUG) &&
(!(global.mode & MODE_QUIET) || (global.mode & MODE_VERBOSE)) &&
msg->sol &&
(msg->msg_state >= HTTP_MSG_BODY || msg->msg_state == HTTP_MSG_ERROR))) {
char *eol, *sol;
sol = req->data + msg->som;
eol = sol + msg->sl.rq.l;
debug_hdr("clireq", s, sol, eol);
sol += hdr_idx_first_pos(&txn->hdr_idx);
cur_idx = hdr_idx_first_idx(&txn->hdr_idx);
while (cur_idx) {
eol = sol + txn->hdr_idx.v[cur_idx].len;
debug_hdr("clihdr", s, sol, eol);
sol = eol + txn->hdr_idx.v[cur_idx].cr + 1;
cur_idx = txn->hdr_idx.v[cur_idx].next;
}
}
/*
* Now we quickly check if we have found a full valid request.
* If not so, we check the FD and buffer states before leaving.
* A full request is indicated by the fact that we have seen
* the double LF/CRLF, so the state is >= HTTP_MSG_BODY. Invalid
* requests are checked first. When waiting for a second request
* on a keep-alive session, if we encounter and error, close, t/o,
* we note the error in the session flags but don't set any state.
* Since the error will be noted there, it will not be counted by
* process_session() as a frontend error.
*/
if (unlikely(msg->msg_state < HTTP_MSG_BODY)) {
/*
* First, let's catch bad requests.
*/
if (unlikely(msg->msg_state == HTTP_MSG_ERROR)) {
proxy_inc_fe_req_ctr(s->fe);
goto return_bad_req;
}
/* 1: Since we are in header mode, if there's no space
* left for headers, we won't be able to free more
* later, so the session will never terminate. We
* must terminate it now.
*/
if (unlikely(req->flags & BF_FULL)) {
/* FIXME: check if URI is set and return Status
* 414 Request URI too long instead.
*/
proxy_inc_fe_req_ctr(s->fe);
goto return_bad_req;
}
/* 2: have we encountered a read error ? */
else if (req->flags & BF_READ_ERROR) {
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_CLICL;
if (txn->flags & TX_WAIT_NEXT_RQ)
goto failed_keep_alive;
/* we cannot return any message on error */
if (msg->err_pos >= 0)
http_capture_bad_message(&s->fe->invalid_req, s, req, msg, s->fe);
msg->msg_state = HTTP_MSG_ERROR;
req->analysers = 0;
proxy_inc_fe_req_ctr(s->fe);
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
return 0;
}
/* 3: has the read timeout expired ? */
else if (req->flags & BF_READ_TIMEOUT || tick_is_expired(req->analyse_exp, now_ms)) {
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_CLITO;
if (txn->flags & TX_WAIT_NEXT_RQ)
goto failed_keep_alive;
/* read timeout : give up with an error message. */
if (msg->err_pos >= 0)
http_capture_bad_message(&s->fe->invalid_req, s, req, msg, s->fe);
txn->status = 408;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_408));
msg->msg_state = HTTP_MSG_ERROR;
req->analysers = 0;
proxy_inc_fe_req_ctr(s->fe);
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
return 0;
}
/* 4: have we encountered a close ? */
else if (req->flags & BF_SHUTR) {
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_CLICL;
if (txn->flags & TX_WAIT_NEXT_RQ)
goto failed_keep_alive;
if (msg->err_pos >= 0)
http_capture_bad_message(&s->fe->invalid_req, s, req, msg, s->fe);
txn->status = 400;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_400));
msg->msg_state = HTTP_MSG_ERROR;
req->analysers = 0;
proxy_inc_fe_req_ctr(s->fe);
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
return 0;
}
buffer_dont_connect(req);
req->flags |= BF_READ_DONTWAIT; /* try to get back here ASAP */
s->rep->flags &= ~BF_EXPECT_MORE; /* speed up sending a previous response */
if ((msg->msg_state != HTTP_MSG_RQBEFORE) && (txn->flags & TX_WAIT_NEXT_RQ)) {
/* If the client starts to talk, let's fall back to
* request timeout processing.
*/
txn->flags &= ~TX_WAIT_NEXT_RQ;
req->analyse_exp = TICK_ETERNITY;
}
/* just set the request timeout once at the beginning of the request */
if (!tick_isset(req->analyse_exp)) {
if ((msg->msg_state == HTTP_MSG_RQBEFORE) &&
(txn->flags & TX_WAIT_NEXT_RQ) &&
tick_isset(s->be->timeout.httpka))
req->analyse_exp = tick_add(now_ms, s->be->timeout.httpka);
else
req->analyse_exp = tick_add_ifset(now_ms, s->be->timeout.httpreq);
}
/* we're not ready yet */
return 0;
failed_keep_alive:
/* Here we process low-level errors for keep-alive requests. In
* short, if the request is not the first one and it experiences
* a timeout, read error or shutdown, we just silently close so
* that the client can try again.
*/
txn->status = 0;
msg->msg_state = HTTP_MSG_RQBEFORE;
req->analysers = 0;
s->logs.logwait = 0;
s->rep->flags &= ~BF_EXPECT_MORE; /* speed up sending a previous response */
stream_int_retnclose(req->prod, NULL);
return 0;
}
/* OK now we have a complete HTTP request with indexed headers. Let's
* complete the request parsing by setting a few fields we will need
* later. At this point, we have the last CRLF at req->data + msg->eoh.
* If the request is in HTTP/0.9 form, the rule is still true, and eoh
* points to the CRLF of the request line. req->lr points to the first
* byte after the last LF. msg->col and msg->sov point to the first
* byte of data. msg->eol cannot be trusted because it may have been
* left uninitialized (for instance in the absence of headers).
*/
proxy_inc_fe_req_ctr(s->fe); /* one more valid request for this FE */
if (txn->flags & TX_WAIT_NEXT_RQ) {
/* kill the pending keep-alive timeout */
txn->flags &= ~TX_WAIT_NEXT_RQ;
req->analyse_exp = TICK_ETERNITY;
}
/* Maybe we found in invalid header name while we were configured not
* to block on that, so we have to capture it now.
*/
if (unlikely(msg->err_pos >= 0))
http_capture_bad_message(&s->fe->invalid_req, s, req, msg, s->fe);
/*
* 1: identify the method
*/
txn->meth = find_http_meth(msg->sol, msg->sl.rq.m_l);
/* we can make use of server redirect on GET and HEAD */
if (txn->meth == HTTP_METH_GET || txn->meth == HTTP_METH_HEAD)
s->flags |= SN_REDIRECTABLE;
/*
* 2: check if the URI matches the monitor_uri.
* We have to do this for every request which gets in, because
* the monitor-uri is defined by the frontend.
*/
if (unlikely((s->fe->monitor_uri_len != 0) &&
(s->fe->monitor_uri_len == msg->sl.rq.u_l) &&
!memcmp(msg->sol + msg->sl.rq.u,
s->fe->monitor_uri,
s->fe->monitor_uri_len))) {
/*
* We have found the monitor URI
*/
struct acl_cond *cond;
s->flags |= SN_MONITOR;
/* Check if we want to fail this monitor request or not */
list_for_each_entry(cond, &s->fe->mon_fail_cond, list) {
int ret = acl_exec_cond(cond, s->fe, s, txn, ACL_DIR_REQ);
ret = acl_pass(ret);
if (cond->pol == ACL_COND_UNLESS)
ret = !ret;
if (ret) {
/* we fail this request, let's return 503 service unavail */
txn->status = 503;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_503));
goto return_prx_cond;
}
}
/* nothing to fail, let's reply normaly */
txn->status = 200;
stream_int_retnclose(req->prod, &http_200_chunk);
goto return_prx_cond;
}
/*
* 3: Maybe we have to copy the original REQURI for the logs ?
* Note: we cannot log anymore if the request has been
* classified as invalid.
*/
if (unlikely(s->logs.logwait & LW_REQ)) {
/* we have a complete HTTP request that we must log */
if ((txn->uri = pool_alloc2(pool2_requri)) != NULL) {
int urilen = msg->sl.rq.l;
if (urilen >= REQURI_LEN)
urilen = REQURI_LEN - 1;
memcpy(txn->uri, &req->data[msg->som], urilen);
txn->uri[urilen] = 0;
if (!(s->logs.logwait &= ~LW_REQ))
s->do_log(s);
} else {
Alert("HTTP logging : out of memory.\n");
}
}
/* 4. We may have to convert HTTP/0.9 requests to HTTP/1.0 */
if (unlikely(msg->sl.rq.v_l == 0) && !http_upgrade_v09_to_v10(req, msg, txn))
goto return_bad_req;
/* ... and check if the request is HTTP/1.1 or above */
if ((msg->sl.rq.v_l == 8) &&
((msg->sol[msg->sl.rq.v + 5] > '1') ||
((msg->sol[msg->sl.rq.v + 5] == '1') &&
(msg->sol[msg->sl.rq.v + 7] >= '1'))))
txn->flags |= TX_REQ_VER_11;
/* "connection" has not been parsed yet */
txn->flags &= ~(TX_HDR_CONN_PRS | TX_HDR_CONN_CLO | TX_HDR_CONN_KAL);
/* if the frontend has "option http-use-proxy-header", we'll check if
* we have what looks like a proxied connection instead of a connection,
* and in this case set the TX_USE_PX_CONN flag to use Proxy-connection.
* Note that this is *not* RFC-compliant, however browsers and proxies
* happen to do that despite being non-standard :-(
* We consider that a request not beginning with either '/' or '*' is
* a proxied connection, which covers both "scheme://location" and
* CONNECT ip:port.
*/
if ((s->fe->options2 & PR_O2_USE_PXHDR) &&
msg->sol[msg->sl.rq.u] != '/' && msg->sol[msg->sl.rq.u] != '*')
txn->flags |= TX_USE_PX_CONN;
/* transfer length unknown*/
txn->flags &= ~TX_REQ_XFER_LEN;
/* 5: we may need to capture headers */
if (unlikely((s->logs.logwait & LW_REQHDR) && s->fe->req_cap))
capture_headers(msg->sol, &txn->hdr_idx,
txn->req.cap, s->fe->req_cap);
/* 6: determine the transfer-length.
* According to RFC2616 #4.4, amended by the HTTPbis working group,
* the presence of a message-body in a REQUEST and its transfer length
* must be determined that way (in order of precedence) :
* 1. The presence of a message-body in a request is signaled by the
* inclusion of a Content-Length or Transfer-Encoding header field
* in the request's header fields. When a request message contains
* both a message-body of non-zero length and a method that does
* not define any semantics for that request message-body, then an
* origin server SHOULD either ignore the message-body or respond
* with an appropriate error message (e.g., 413). A proxy or
* gateway, when presented the same request, SHOULD either forward
* the request inbound with the message- body or ignore the
* message-body when determining a response.
*
* 2. If a Transfer-Encoding header field (Section 9.7) is present
* and the "chunked" transfer-coding (Section 6.2) is used, the
* transfer-length is defined by the use of this transfer-coding.
* If a Transfer-Encoding header field is present and the "chunked"
* transfer-coding is not present, the transfer-length is defined
* by the sender closing the connection.
*
* 3. If a Content-Length header field is present, its decimal value in
* OCTETs represents both the entity-length and the transfer-length.
* If a message is received with both a Transfer-Encoding header
* field and a Content-Length header field, the latter MUST be ignored.
*
* 4. By the server closing the connection. (Closing the connection
* cannot be used to indicate the end of a request body, since that
* would leave no possibility for the server to send back a response.)
*
* Whenever a transfer-coding is applied to a message-body, the set of
* transfer-codings MUST include "chunked", unless the message indicates
* it is terminated by closing the connection. When the "chunked"
* transfer-coding is used, it MUST be the last transfer-coding applied
* to the message-body.
*/
use_close_only = 0;
ctx.idx = 0;
/* set TE_CHNK and XFER_LEN only if "chunked" is seen last */
while ((txn->flags & TX_REQ_VER_11) &&
http_find_header2("Transfer-Encoding", 17, msg->sol, &txn->hdr_idx, &ctx)) {
if (ctx.vlen == 7 && strncasecmp(ctx.line + ctx.val, "chunked", 7) == 0)
txn->flags |= (TX_REQ_TE_CHNK | TX_REQ_XFER_LEN);
else if (txn->flags & TX_REQ_TE_CHNK) {
/* bad transfer-encoding (chunked followed by something else) */
use_close_only = 1;
txn->flags &= ~(TX_REQ_TE_CHNK | TX_REQ_XFER_LEN);
break;
}
}
ctx.idx = 0;
while (!(txn->flags & TX_REQ_TE_CHNK) && !use_close_only &&
http_find_header2("Content-Length", 14, msg->sol, &txn->hdr_idx, &ctx)) {
signed long long cl;
if (!ctx.vlen)
goto return_bad_req;
if (strl2llrc(ctx.line + ctx.val, ctx.vlen, &cl))
goto return_bad_req; /* parse failure */
if (cl < 0)
goto return_bad_req;
if ((txn->flags & TX_REQ_CNT_LEN) && (msg->hdr_content_len != cl))
goto return_bad_req; /* already specified, was different */
txn->flags |= TX_REQ_CNT_LEN | TX_REQ_XFER_LEN;
msg->hdr_content_len = cl;
}
/* bodyless requests have a known length */
if (!use_close_only)
txn->flags |= TX_REQ_XFER_LEN;
/* end of job, return OK */
req->analysers &= ~an_bit;
req->analyse_exp = TICK_ETERNITY;
return 1;
return_bad_req:
/* We centralize bad requests processing here */
if (unlikely(msg->msg_state == HTTP_MSG_ERROR) || msg->err_pos >= 0) {
/* we detected a parsing error. We want to archive this request
* in the dedicated proxy area for later troubleshooting.
*/
http_capture_bad_message(&s->fe->invalid_req, s, req, msg, s->fe);
}
txn->req.msg_state = HTTP_MSG_ERROR;
txn->status = 400;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_400));
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
return_prx_cond:
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_PRXCOND;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
req->analysers = 0;
req->analyse_exp = TICK_ETERNITY;
return 0;
}
/* This stream analyser runs all HTTP request processing which is common to
* frontends and backends, which means blocking ACLs, filters, connection-close,
* reqadd, stats and redirects. This is performed for the designated proxy.
* It returns 1 if the processing can continue on next analysers, or zero if it
* either needs more data or wants to immediately abort the request (eg: deny,
* error, ...).
*/
int http_process_req_common(struct session *s, struct buffer *req, int an_bit, struct proxy *px)
{
struct http_txn *txn = &s->txn;
struct http_msg *msg = &txn->req;
struct acl_cond *cond;
struct req_acl_rule *req_acl, *req_acl_final = NULL;
struct redirect_rule *rule;
struct cond_wordlist *wl;
int del_ka, del_cl, do_stats;
if (unlikely(msg->msg_state < HTTP_MSG_BODY)) {
/* we need more data */
buffer_dont_connect(req);
return 0;
}
req->analysers &= ~an_bit;
req->analyse_exp = TICK_ETERNITY;
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bl=%d analysers=%02x\n",
now_ms, __FUNCTION__,
s,
req,
req->rex, req->wex,
req->flags,
req->l,
req->analysers);
/* first check whether we have some ACLs set to block this request */
list_for_each_entry(cond, &px->block_cond, list) {
int ret = acl_exec_cond(cond, px, s, txn, ACL_DIR_REQ);
ret = acl_pass(ret);
if (cond->pol == ACL_COND_UNLESS)
ret = !ret;
if (ret) {
txn->status = 403;
/* let's log the request time */
s->logs.tv_request = now;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_403));
goto return_prx_cond;
}
}
do_stats = stats_check_uri(s, px);
list_for_each_entry(req_acl, (do_stats?&px->uri_auth->req_acl:&px->req_acl), list) {
int ret = 1;
if (req_acl->action >= PR_REQ_ACL_ACT_MAX)
continue;
/* check condition, but only if attached */
if (req_acl->cond) {
ret = acl_exec_cond(req_acl->cond, px, s, txn, ACL_DIR_REQ);
ret = acl_pass(ret);
if (req_acl->cond->pol == ACL_COND_UNLESS)
ret = !ret;
}
if (ret) {
req_acl_final = req_acl;
break;
}
}
if (req_acl_final && req_acl_final->action == PR_REQ_ACL_ACT_DENY) {
txn->status = 403;
s->logs.tv_request = now;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_403));
goto return_prx_cond;
}
/* try headers filters */
if (px->req_exp != NULL) {
if (apply_filters_to_request(s, req, px) < 0)
goto return_bad_req;
/* has the request been denied ? */
if (txn->flags & TX_CLDENY) {
/* no need to go further */
txn->status = 403;
/* let's log the request time */
s->logs.tv_request = now;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_403));
goto return_prx_cond;
}
/* When a connection is tarpitted, we use the tarpit timeout,
* which may be the same as the connect timeout if unspecified.
* If unset, then set it to zero because we really want it to
* eventually expire. We build the tarpit as an analyser.
*/
if (txn->flags & TX_CLTARPIT) {
buffer_erase(s->req);
/* wipe the request out so that we can drop the connection early
* if the client closes first.
*/
buffer_dont_connect(req);
req->analysers = 0; /* remove switching rules etc... */
req->analysers |= AN_REQ_HTTP_TARPIT;
req->analyse_exp = tick_add_ifset(now_ms, s->be->timeout.tarpit);
if (!req->analyse_exp)
req->analyse_exp = tick_add(now_ms, 0);
return 1;
}
}
/* Until set to anything else, the connection mode is set as TUNNEL. It will
* only change if both the request and the config reference something else.
* Option httpclose by itself does not set a mode, it remains a tunnel mode
* in which headers are mangled. However, if another mode is set, it will
* affect it (eg: server-close/keep-alive + httpclose = close). Note that we
* avoid to redo the same work if FE and BE have the same settings (common).
* The method consists in checking if options changed between the two calls
* (implying that either one is non-null, or one of them is non-null and we
* are there for the first time.
*/
del_cl = del_ka = 0;
if ((!(txn->flags & TX_HDR_CONN_PRS) &&
(s->fe->options & (PR_O_KEEPALIVE|PR_O_SERVER_CLO|PR_O_HTTP_CLOSE|PR_O_FORCE_CLO))) ||
((s->fe->options & (PR_O_KEEPALIVE|PR_O_SERVER_CLO|PR_O_HTTP_CLOSE|PR_O_FORCE_CLO)) !=
(s->be->options & (PR_O_KEEPALIVE|PR_O_SERVER_CLO|PR_O_HTTP_CLOSE|PR_O_FORCE_CLO)))) {
int tmp = TX_CON_WANT_TUN;
if ((s->fe->options|s->be->options) & PR_O_KEEPALIVE)
tmp = TX_CON_WANT_KAL;
if ((s->fe->options|s->be->options) & PR_O_SERVER_CLO)
tmp = TX_CON_WANT_SCL;
if ((s->fe->options|s->be->options) & PR_O_FORCE_CLO)
tmp = TX_CON_WANT_CLO;
if ((txn->flags & TX_CON_WANT_MSK) < tmp)
txn->flags = (txn->flags & ~TX_CON_WANT_MSK) | tmp;
if (!(txn->flags & TX_HDR_CONN_PRS)) {
/* parse the Connection header and possibly clean it */
int to_del = 0;
if ((txn->flags & TX_REQ_VER_11) ||
((txn->flags & TX_CON_WANT_MSK) >= TX_CON_WANT_SCL &&
!((s->fe->options2|s->be->options2) & PR_O2_FAKE_KA)))
to_del |= 2; /* remove "keep-alive" */
if (!(txn->flags & TX_REQ_VER_11))
to_del |= 1; /* remove "close" */
http_parse_connection_header(txn, msg, req, to_del);
}
/* check if client or config asks for explicit close in KAL/SCL */
if (((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_KAL ||
(txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_SCL) &&
((txn->flags & TX_HDR_CONN_CLO) || /* "connection: close" */
(txn->flags & (TX_REQ_VER_11|TX_HDR_CONN_KAL)) == 0 || /* no "connection: k-a" in 1.0 */
((s->fe->options|s->be->options) & PR_O_HTTP_CLOSE) || /* httpclose + any = forceclose */
!(txn->flags & TX_REQ_XFER_LEN) || /* no length known => close */
s->fe->state == PR_STSTOPPED)) /* frontend is stopping */
txn->flags = (txn->flags & ~TX_CON_WANT_MSK) | TX_CON_WANT_CLO;
}
/* add request headers from the rule sets in the same order */
list_for_each_entry(wl, &px->req_add, list) {
if (wl->cond) {
int ret = acl_exec_cond(wl->cond, px, s, txn, ACL_DIR_REQ);
ret = acl_pass(ret);
if (((struct acl_cond *)wl->cond)->pol == ACL_COND_UNLESS)
ret = !ret;
if (!ret)
continue;
}
if (unlikely(http_header_add_tail(req, &txn->req, &txn->hdr_idx, wl->s) < 0))
goto return_bad_req;
}
if (req_acl_final && req_acl_final->action == PR_REQ_ACL_ACT_HTTP_AUTH) {
struct chunk msg;
char *realm = req_acl->http_auth.realm;
if (!realm)
realm = do_stats?STATS_DEFAULT_REALM:px->id;
sprintf(trash, (txn->flags & TX_USE_PX_CONN) ? HTTP_407_fmt : HTTP_401_fmt, realm);
chunk_initlen(&msg, trash, sizeof(trash), strlen(trash));
txn->status = 401;
stream_int_retnclose(req->prod, &msg);
goto return_prx_cond;
}
if (do_stats) {
/* We need to provied stats for this request.
* FIXME!!! that one is rather dangerous, we want to
* make it follow standard rules (eg: clear req->analysers).
*/
s->logs.tv_request = now;
s->data_source = DATA_SRC_STATS;
s->data_state = DATA_ST_INIT;
s->task->nice = -32; /* small boost for HTTP statistics */
stream_int_register_handler(s->rep->prod, http_stats_io_handler);
s->rep->prod->private = s;
s->rep->prod->st0 = s->rep->prod->st1 = 0;
req->analysers = 0;
return 0;
}
/* check whether we have some ACLs set to redirect this request */
list_for_each_entry(rule, &px->redirect_rules, list) {
int ret = ACL_PAT_PASS;
if (rule->cond) {
ret = acl_exec_cond(rule->cond, px, s, txn, ACL_DIR_REQ);
ret = acl_pass(ret);
if (rule->cond->pol == ACL_COND_UNLESS)
ret = !ret;
}
if (ret) {
struct chunk rdr = { .str = trash, .size = sizeof(trash), .len = 0 };
const char *msg_fmt;
/* build redirect message */
switch(rule->code) {
case 303:
msg_fmt = HTTP_303;
break;
case 301:
msg_fmt = HTTP_301;
break;
case 302:
default:
msg_fmt = HTTP_302;
break;
}
if (unlikely(!chunk_strcpy(&rdr, msg_fmt)))
goto return_bad_req;
switch(rule->type) {
case REDIRECT_TYPE_PREFIX: {
const char *path;
int pathlen;
path = http_get_path(txn);
/* build message using path */
if (path) {
pathlen = txn->req.sl.rq.u_l + (txn->req.sol + txn->req.sl.rq.u) - path;
if (rule->flags & REDIRECT_FLAG_DROP_QS) {
int qs = 0;
while (qs < pathlen) {
if (path[qs] == '?') {
pathlen = qs;
break;
}
qs++;
}
}
} else {
path = "/";
pathlen = 1;
}
if (rdr.len + rule->rdr_len + pathlen > rdr.size - 4)
goto return_bad_req;
/* add prefix. Note that if prefix == "/", we don't want to
* add anything, otherwise it makes it hard for the user to
* configure a self-redirection.
*/
if (rule->rdr_len != 1 || *rule->rdr_str != '/') {
memcpy(rdr.str + rdr.len, rule->rdr_str, rule->rdr_len);
rdr.len += rule->rdr_len;
}
/* add path */
memcpy(rdr.str + rdr.len, path, pathlen);
rdr.len += pathlen;
/* append a slash at the end of the location is needed and missing */
if (rdr.len && rdr.str[rdr.len - 1] != '/' &&
(rule->flags & REDIRECT_FLAG_APPEND_SLASH)) {
if (rdr.len > rdr.size - 5)
goto return_bad_req;
rdr.str[rdr.len] = '/';
rdr.len++;
}
break;
}
case REDIRECT_TYPE_LOCATION:
default:
if (rdr.len + rule->rdr_len > rdr.size - 4)
goto return_bad_req;
/* add location */
memcpy(rdr.str + rdr.len, rule->rdr_str, rule->rdr_len);
rdr.len += rule->rdr_len;
break;
}
if (rule->cookie_len) {
memcpy(rdr.str + rdr.len, "\r\nSet-Cookie: ", 14);
rdr.len += 14;
memcpy(rdr.str + rdr.len, rule->cookie_str, rule->cookie_len);
rdr.len += rule->cookie_len;
memcpy(rdr.str + rdr.len, "\r\n", 2);
rdr.len += 2;
}
/* add end of headers and the keep-alive/close status.
* We may choose to set keep-alive if the Location begins
* with a slash, because the client will come back to the
* same server.
*/
txn->status = rule->code;
/* let's log the request time */
s->logs.tv_request = now;
if (rule->rdr_len >= 1 && *rule->rdr_str == '/' &&
(txn->flags & TX_REQ_XFER_LEN) &&
!(txn->flags & TX_REQ_TE_CHNK) && !txn->req.hdr_content_len &&
((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_SCL ||
(txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_KAL)) {
/* keep-alive possible */
if (!(txn->flags & TX_REQ_VER_11)) {
if (unlikely(txn->flags & TX_USE_PX_CONN)) {
memcpy(rdr.str + rdr.len, "\r\nProxy-Connection: keep-alive", 30);
rdr.len += 30;
} else {
memcpy(rdr.str + rdr.len, "\r\nConnection: keep-alive", 24);
rdr.len += 24;
}
}
memcpy(rdr.str + rdr.len, "\r\n\r\n", 4);
rdr.len += 4;
buffer_write(req->prod->ob, rdr.str, rdr.len);
/* "eat" the request */
buffer_ignore(req, msg->sov - msg->som);
msg->som = msg->sov;
req->analysers = AN_REQ_HTTP_XFER_BODY;
s->rep->analysers = AN_RES_HTTP_XFER_BODY;
txn->req.msg_state = HTTP_MSG_CLOSED;
txn->rsp.msg_state = HTTP_MSG_DONE;
break;
} else {
/* keep-alive not possible */
if (unlikely(txn->flags & TX_USE_PX_CONN)) {
memcpy(rdr.str + rdr.len, "\r\nProxy-Connection: close\r\n\r\n", 29);
rdr.len += 29;
} else {
memcpy(rdr.str + rdr.len, "\r\nConnection: close\r\n\r\n", 23);
rdr.len += 23;
}
stream_int_retnclose(req->prod, &rdr);
goto return_prx_cond;
}
}
}
/* POST requests may be accompanied with an "Expect: 100-Continue" header.
* If this happens, then the data will not come immediately, so we must
* send all what we have without waiting. Note that due to the small gain
* in waiting for the body of the request, it's easier to simply put the
* BF_SEND_DONTWAIT flag any time. It's a one-shot flag so it will remove
* itself once used.
*/
req->flags |= BF_SEND_DONTWAIT;
/* that's OK for us now, let's move on to next analysers */
return 1;
return_bad_req:
/* We centralize bad requests processing here */
if (unlikely(msg->msg_state == HTTP_MSG_ERROR) || msg->err_pos >= 0) {
/* we detected a parsing error. We want to archive this request
* in the dedicated proxy area for later troubleshooting.
*/
http_capture_bad_message(&s->fe->invalid_req, s, req, msg, s->fe);
}
txn->req.msg_state = HTTP_MSG_ERROR;
txn->status = 400;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_400));
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
return_prx_cond:
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_PRXCOND;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
req->analysers = 0;
req->analyse_exp = TICK_ETERNITY;
return 0;
}
/* This function performs all the processing enabled for the current request.
* It returns 1 if the processing can continue on next analysers, or zero if it
* needs more data, encounters an error, or wants to immediately abort the
* request. It relies on buffers flags, and updates s->req->analysers.
*/
int http_process_request(struct session *s, struct buffer *req, int an_bit)
{
struct http_txn *txn = &s->txn;
struct http_msg *msg = &txn->req;
if (unlikely(msg->msg_state < HTTP_MSG_BODY)) {
/* we need more data */
buffer_dont_connect(req);
return 0;
}
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bl=%d analysers=%02x\n",
now_ms, __FUNCTION__,
s,
req,
req->rex, req->wex,
req->flags,
req->l,
req->analysers);
/*
* Right now, we know that we have processed the entire headers
* and that unwanted requests have been filtered out. We can do
* whatever we want with the remaining request. Also, now we
* may have separate values for ->fe, ->be.
*/
/*
* If HTTP PROXY is set we simply get remote server address
* parsing incoming request.
*/
if ((s->be->options & PR_O_HTTP_PROXY) && !(s->flags & SN_ADDR_SET)) {
url2sa(msg->sol + msg->sl.rq.u, msg->sl.rq.u_l, &s->srv_addr);
}
/*
* 7: Now we can work with the cookies.
* Note that doing so might move headers in the request, but
* the fields will stay coherent and the URI will not move.
* This should only be performed in the backend.
*/
if ((s->be->cookie_name || s->be->appsession_name || s->fe->capture_name)
&& !(txn->flags & (TX_CLDENY|TX_CLTARPIT)))
manage_client_side_cookies(s, req);
/*
* 8: the appsession cookie was looked up very early in 1.2,
* so let's do the same now.
*/
/* It needs to look into the URI unless persistence must be ignored */
if ((txn->sessid == NULL) && s->be->appsession_name && !(s->flags & SN_IGNORE_PRST)) {
get_srv_from_appsession(s, msg->sol + msg->sl.rq.u, msg->sl.rq.u_l);
}
/*
* 9: add X-Forwarded-For if either the frontend or the backend
* asks for it.
*/
if ((s->fe->options | s->be->options) & PR_O_FWDFOR) {
if (s->cli_addr.ss_family == AF_INET) {
/* Add an X-Forwarded-For header unless the source IP is
* in the 'except' network range.
*/
if ((!s->fe->except_mask.s_addr ||
(((struct sockaddr_in *)&s->cli_addr)->sin_addr.s_addr & s->fe->except_mask.s_addr)
!= s->fe->except_net.s_addr) &&
(!s->be->except_mask.s_addr ||
(((struct sockaddr_in *)&s->cli_addr)->sin_addr.s_addr & s->be->except_mask.s_addr)
!= s->be->except_net.s_addr)) {
int len;
unsigned char *pn;
pn = (unsigned char *)&((struct sockaddr_in *)&s->cli_addr)->sin_addr;
/* Note: we rely on the backend to get the header name to be used for
* x-forwarded-for, because the header is really meant for the backends.
* However, if the backend did not specify any option, we have to rely
* on the frontend's header name.
*/
if (s->be->fwdfor_hdr_len) {
len = s->be->fwdfor_hdr_len;
memcpy(trash, s->be->fwdfor_hdr_name, len);
} else {
len = s->fe->fwdfor_hdr_len;
memcpy(trash, s->fe->fwdfor_hdr_name, len);
}
len += sprintf(trash + len, ": %d.%d.%d.%d", pn[0], pn[1], pn[2], pn[3]);
if (unlikely(http_header_add_tail2(req, &txn->req,
&txn->hdr_idx, trash, len) < 0))
goto return_bad_req;
}
}
else if (s->cli_addr.ss_family == AF_INET6) {
/* FIXME: for the sake of completeness, we should also support
* 'except' here, although it is mostly useless in this case.
*/
int len;
char pn[INET6_ADDRSTRLEN];
inet_ntop(AF_INET6,
(const void *)&((struct sockaddr_in6 *)(&s->cli_addr))->sin6_addr,
pn, sizeof(pn));
/* Note: we rely on the backend to get the header name to be used for
* x-forwarded-for, because the header is really meant for the backends.
* However, if the backend did not specify any option, we have to rely
* on the frontend's header name.
*/
if (s->be->fwdfor_hdr_len) {
len = s->be->fwdfor_hdr_len;
memcpy(trash, s->be->fwdfor_hdr_name, len);
} else {
len = s->fe->fwdfor_hdr_len;
memcpy(trash, s->fe->fwdfor_hdr_name, len);
}
len += sprintf(trash + len, ": %s", pn);
if (unlikely(http_header_add_tail2(req, &txn->req,
&txn->hdr_idx, trash, len) < 0))
goto return_bad_req;
}
}
/*
* 10: add X-Original-To if either the frontend or the backend
* asks for it.
*/
if ((s->fe->options | s->be->options) & PR_O_ORGTO) {
/* FIXME: don't know if IPv6 can handle that case too. */
if (s->cli_addr.ss_family == AF_INET) {
/* Add an X-Original-To header unless the destination IP is
* in the 'except' network range.
*/
if (!(s->flags & SN_FRT_ADDR_SET))
get_frt_addr(s);
if ((!s->fe->except_mask_to.s_addr ||
(((struct sockaddr_in *)&s->frt_addr)->sin_addr.s_addr & s->fe->except_mask_to.s_addr)
!= s->fe->except_to.s_addr) &&
(!s->be->except_mask_to.s_addr ||
(((struct sockaddr_in *)&s->frt_addr)->sin_addr.s_addr & s->be->except_mask_to.s_addr)
!= s->be->except_to.s_addr)) {
int len;
unsigned char *pn;
pn = (unsigned char *)&((struct sockaddr_in *)&s->frt_addr)->sin_addr;
/* Note: we rely on the backend to get the header name to be used for
* x-original-to, because the header is really meant for the backends.
* However, if the backend did not specify any option, we have to rely
* on the frontend's header name.
*/
if (s->be->orgto_hdr_len) {
len = s->be->orgto_hdr_len;
memcpy(trash, s->be->orgto_hdr_name, len);
} else {
len = s->fe->orgto_hdr_len;
memcpy(trash, s->fe->orgto_hdr_name, len);
}
len += sprintf(trash + len, ": %d.%d.%d.%d", pn[0], pn[1], pn[2], pn[3]);
if (unlikely(http_header_add_tail2(req, &txn->req,
&txn->hdr_idx, trash, len) < 0))
goto return_bad_req;
}
}
}
/* 11: add "Connection: close" or "Connection: keep-alive" if needed and not yet set. */
if (((txn->flags & TX_CON_WANT_MSK) != TX_CON_WANT_TUN) ||
((s->fe->options|s->be->options) & PR_O_HTTP_CLOSE)) {
unsigned int want_flags = 0;
if (txn->flags & TX_REQ_VER_11) {
if (((txn->flags & TX_CON_WANT_MSK) >= TX_CON_WANT_SCL &&
!((s->fe->options2|s->be->options2) & PR_O2_FAKE_KA)) ||
((s->fe->options|s->be->options) & PR_O_HTTP_CLOSE))
want_flags |= TX_CON_CLO_SET;
} else {
if ((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_KAL ||
(((s->fe->options2|s->be->options2) & PR_O2_FAKE_KA) &&
!((s->fe->options|s->be->options) & PR_O_HTTP_CLOSE)))
want_flags |= TX_CON_KAL_SET;
}
if (want_flags != (txn->flags & (TX_CON_CLO_SET|TX_CON_KAL_SET)))
http_change_connection_header(txn, msg, req, want_flags);
}
/* If we have no server assigned yet and we're balancing on url_param
* with a POST request, we may be interested in checking the body for
* that parameter. This will be done in another analyser.
*/
if (!(s->flags & (SN_ASSIGNED|SN_DIRECT)) &&
s->txn.meth == HTTP_METH_POST && s->be->url_param_name != NULL &&
s->be->url_param_post_limit != 0 &&
(txn->flags & (TX_REQ_CNT_LEN|TX_REQ_TE_CHNK)) &&
memchr(msg->sol + msg->sl.rq.u, '?', msg->sl.rq.u_l) == NULL) {
buffer_dont_connect(req);
req->analysers |= AN_REQ_HTTP_BODY;
}
if (txn->flags & TX_REQ_XFER_LEN)
req->analysers |= AN_REQ_HTTP_XFER_BODY;
/*************************************************************
* OK, that's finished for the headers. We have done what we *
* could. Let's switch to the DATA state. *
************************************************************/
req->analyse_exp = TICK_ETERNITY;
req->analysers &= ~an_bit;
s->logs.tv_request = now;
/* OK let's go on with the BODY now */
return 1;
return_bad_req: /* let's centralize all bad requests */
if (unlikely(msg->msg_state == HTTP_MSG_ERROR) || msg->err_pos >= 0) {
/* we detected a parsing error. We want to archive this request
* in the dedicated proxy area for later troubleshooting.
*/
http_capture_bad_message(&s->fe->invalid_req, s, req, msg, s->fe);
}
txn->req.msg_state = HTTP_MSG_ERROR;
txn->status = 400;
req->analysers = 0;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_400));
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_PRXCOND;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
return 0;
}
/* This function is an analyser which processes the HTTP tarpit. It always
* returns zero, at the beginning because it prevents any other processing
* from occurring, and at the end because it terminates the request.
*/
int http_process_tarpit(struct session *s, struct buffer *req, int an_bit)
{
struct http_txn *txn = &s->txn;
/* This connection is being tarpitted. The CLIENT side has
* already set the connect expiration date to the right
* timeout. We just have to check that the client is still
* there and that the timeout has not expired.
*/
buffer_dont_connect(req);
if ((req->flags & (BF_SHUTR|BF_READ_ERROR)) == 0 &&
!tick_is_expired(req->analyse_exp, now_ms))
return 0;
/* We will set the queue timer to the time spent, just for
* logging purposes. We fake a 500 server error, so that the
* attacker will not suspect his connection has been tarpitted.
* It will not cause trouble to the logs because we can exclude
* the tarpitted connections by filtering on the 'PT' status flags.
*/
s->logs.t_queue = tv_ms_elapsed(&s->logs.tv_accept, &now);
txn->status = 500;
if (req->flags != BF_READ_ERROR)
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_500));
req->analysers = 0;
req->analyse_exp = TICK_ETERNITY;
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_PRXCOND;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_T;
return 0;
}
/* This function is an analyser which processes the HTTP request body. It looks
* for parameters to be used for the load balancing algorithm (url_param). It
* must only be called after the standard HTTP request processing has occurred,
* because it expects the request to be parsed. It returns zero if it needs to
* read more data, or 1 once it has completed its analysis.
*/
int http_process_request_body(struct session *s, struct buffer *req, int an_bit)
{
struct http_txn *txn = &s->txn;
struct http_msg *msg = &s->txn.req;
long long limit = s->be->url_param_post_limit;
/* We have to parse the HTTP request body to find any required data.
* "balance url_param check_post" should have been the only way to get
* into this. We were brought here after HTTP header analysis, so all
* related structures are ready.
*/
if (unlikely(msg->msg_state < HTTP_MSG_BODY))
goto missing_data;
if (msg->msg_state < HTTP_MSG_100_SENT) {
/* If we have HTTP/1.1 and Expect: 100-continue, then we must
* send an HTTP/1.1 100 Continue intermediate response.
*/
if (txn->flags & TX_REQ_VER_11) {
struct hdr_ctx ctx;
ctx.idx = 0;
/* Expect is allowed in 1.1, look for it */
if (http_find_header2("Expect", 6, msg->sol, &txn->hdr_idx, &ctx) &&
unlikely(ctx.vlen == 12 && strncasecmp(ctx.line+ctx.val, "100-continue", 12) == 0)) {
buffer_write(s->rep, http_100_chunk.str, http_100_chunk.len);
}
}
msg->msg_state = HTTP_MSG_100_SENT;
}
if (msg->msg_state < HTTP_MSG_CHUNK_SIZE) {
/* we have msg->col and msg->sov which both point to the first
* byte of message body. msg->som still points to the beginning
* of the message. We must save the body in req->lr because it
* survives buffer re-alignments.
*/
req->lr = req->data + msg->sov;
if (txn->flags & TX_REQ_TE_CHNK)
msg->msg_state = HTTP_MSG_CHUNK_SIZE;
else
msg->msg_state = HTTP_MSG_DATA;
}
if (msg->msg_state == HTTP_MSG_CHUNK_SIZE) {
/* read the chunk size and assign it to ->hdr_content_len, then
* set ->sov and ->lr to point to the body and switch to DATA or
* TRAILERS state.
*/
int ret = http_parse_chunk_size(req, msg);
if (!ret)
goto missing_data;
else if (ret < 0)
goto return_bad_req;
}
/* Now we're in HTTP_MSG_DATA or HTTP_MSG_TRAILERS state.
* We have the first non-header byte in msg->col, which is either the
* beginning of the chunk size or of the data. The first data byte is in
* msg->sov, which is equal to msg->col when not using transfer-encoding.
* We're waiting for at least <url_param_post_limit> bytes after msg->sov.
*/
if (msg->hdr_content_len < limit)
limit = msg->hdr_content_len;
if (req->l - (msg->sov - msg->som) >= limit) /* we have enough bytes now */
goto http_end;
missing_data:
/* we get here if we need to wait for more data */
if (req->flags & BF_FULL)
goto return_bad_req;
if ((req->flags & BF_READ_TIMEOUT) || tick_is_expired(req->analyse_exp, now_ms)) {
txn->status = 408;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_408));
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_CLITO;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_D;
goto return_err_msg;
}
/* we get here if we need to wait for more data */
if (!(req->flags & (BF_FULL | BF_READ_ERROR | BF_SHUTR))) {
/* Not enough data. We'll re-use the http-request
* timeout here. Ideally, we should set the timeout
* relative to the accept() date. We just set the
* request timeout once at the beginning of the
* request.
*/
buffer_dont_connect(req);
if (!tick_isset(req->analyse_exp))
req->analyse_exp = tick_add_ifset(now_ms, s->be->timeout.httpreq);
return 0;
}
http_end:
/* The situation will not evolve, so let's give up on the analysis. */
s->logs.tv_request = now; /* update the request timer to reflect full request */
req->analysers &= ~an_bit;
req->analyse_exp = TICK_ETERNITY;
return 1;
return_bad_req: /* let's centralize all bad requests */
txn->req.msg_state = HTTP_MSG_ERROR;
txn->status = 400;
stream_int_retnclose(req->prod, error_message(s, HTTP_ERR_400));
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_PRXCOND;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
return_err_msg:
req->analysers = 0;
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
return 0;
}
/* Terminate current transaction and prepare a new one. This is very tricky
* right now but it works.
*/
void http_end_txn_clean_session(struct session *s)
{
/* FIXME: We need a more portable way of releasing a backend's and a
* server's connections. We need a safer way to reinitialize buffer
* flags. We also need a more accurate method for computing per-request
* data.
*/
http_silent_debug(__LINE__, s);
s->req->cons->flags |= SI_FL_NOLINGER;
s->req->cons->shutr(s->req->cons);
s->req->cons->shutw(s->req->cons);
http_silent_debug(__LINE__, s);
if (s->flags & SN_BE_ASSIGNED)
s->be->beconn--;
s->logs.t_close = tv_ms_elapsed(&s->logs.tv_accept, &now);
session_process_counters(s);
if (s->txn.status) {
int n;
n = s->txn.status / 100;
if (n < 1 || n > 5)
n = 0;
if (s->fe->mode == PR_MODE_HTTP)
s->fe->counters.fe.http.rsp[n]++;
if ((s->flags & SN_BE_ASSIGNED) &&
(s->be->mode == PR_MODE_HTTP))
s->be->counters.be.http.rsp[n]++;
}
/* don't count other requests' data */
s->logs.bytes_in -= s->req->l - s->req->send_max;
s->logs.bytes_out -= s->rep->l - s->rep->send_max;
/* let's do a final log if we need it */
if (s->logs.logwait &&
!(s->flags & SN_MONITOR) &&
(!(s->fe->options & PR_O_NULLNOLOG) || s->req->total)) {
s->do_log(s);
}
s->logs.accept_date = date; /* user-visible date for logging */
s->logs.tv_accept = now; /* corrected date for internal use */
tv_zero(&s->logs.tv_request);
s->logs.t_queue = -1;
s->logs.t_connect = -1;
s->logs.t_data = -1;
s->logs.t_close = 0;
s->logs.prx_queue_size = 0; /* we get the number of pending conns before us */
s->logs.srv_queue_size = 0; /* we will get this number soon */
s->logs.bytes_in = s->req->total = s->req->l - s->req->send_max;
s->logs.bytes_out = s->rep->total = s->rep->l - s->rep->send_max;
if (s->pend_pos)
pendconn_free(s->pend_pos);
if (s->srv) {
if (s->flags & SN_CURR_SESS) {
s->flags &= ~SN_CURR_SESS;
s->srv->cur_sess--;
}
if (may_dequeue_tasks(s->srv, s->be))
process_srv_queue(s->srv);
}
if (unlikely(s->srv_conn))
sess_change_server(s, NULL);
s->srv = NULL;
s->req->cons->state = s->req->cons->prev_state = SI_ST_INI;
s->req->cons->fd = -1; /* just to help with debugging */
s->req->cons->err_type = SI_ET_NONE;
s->req->cons->err_loc = NULL;
s->req->cons->exp = TICK_ETERNITY;
s->req->cons->flags = SI_FL_NONE;
s->req->flags &= ~(BF_SHUTW|BF_SHUTW_NOW|BF_AUTO_CONNECT|BF_WRITE_ERROR|BF_STREAMER|BF_STREAMER_FAST);
s->rep->flags &= ~(BF_SHUTR|BF_SHUTR_NOW|BF_READ_ATTACHED|BF_READ_ERROR|BF_READ_NOEXP|BF_STREAMER|BF_STREAMER_FAST|BF_WRITE_PARTIAL);
s->flags &= ~(SN_DIRECT|SN_ASSIGNED|SN_ADDR_SET|SN_BE_ASSIGNED|SN_FORCE_PRST|SN_IGNORE_PRST);
s->flags &= ~(SN_CURR_SESS|SN_REDIRECTABLE);
s->txn.meth = 0;
http_reset_txn(s);
s->txn.flags |= TX_NOT_FIRST | TX_WAIT_NEXT_RQ;
if (s->fe->options2 & PR_O2_INDEPSTR)
s->req->cons->flags |= SI_FL_INDEP_STR;
/* if the request buffer is not empty, it means we're
* about to process another request, so send pending
* data with MSG_MORE to merge TCP packets when possible.
* Just don't do this if the buffer is close to be full,
* because the request will wait for it to flush a little
* bit before proceeding.
*/
if (s->req->l > s->req->send_max) {
if (s->rep->send_max &&
!(s->rep->flags & BF_FULL) &&
s->rep->r <= s->rep->data + s->rep->size - global.tune.maxrewrite)
s->rep->flags |= BF_EXPECT_MORE;
}
/* we're removing the analysers, we MUST re-enable events detection */
buffer_auto_read(s->req);
buffer_auto_close(s->req);
buffer_auto_read(s->rep);
buffer_auto_close(s->rep);
/* make ->lr point to the first non-forwarded byte */
s->req->lr = s->req->w + s->req->send_max;
if (s->req->lr >= s->req->data + s->req->size)
s->req->lr -= s->req->size;
s->rep->lr = s->rep->w + s->rep->send_max;
if (s->rep->lr >= s->rep->data + s->rep->size)
s->rep->lr -= s->req->size;
s->req->analysers |= s->fe->fe_req_ana;
s->rep->analysers = 0;
http_silent_debug(__LINE__, s);
}
/* This function updates the request state machine according to the response
* state machine and buffer flags. It returns 1 if it changes anything (flag
* or state), otherwise zero. It ignores any state before HTTP_MSG_DONE, as
* it is only used to find when a request/response couple is complete. Both
* this function and its equivalent should loop until both return zero. It
* can set its own state to DONE, CLOSING, CLOSED, TUNNEL, ERROR.
*/
int http_sync_req_state(struct session *s)
{
struct buffer *buf = s->req;
struct http_txn *txn = &s->txn;
unsigned int old_flags = buf->flags;
unsigned int old_state = txn->req.msg_state;
http_silent_debug(__LINE__, s);
if (unlikely(txn->req.msg_state < HTTP_MSG_BODY))
return 0;
if (txn->req.msg_state == HTTP_MSG_DONE) {
/* No need to read anymore, the request was completely parsed.
* We can shut the read side unless we want to abort_on_close.
*/
if (buf->cons->state == SI_ST_EST || !(s->be->options & PR_O_ABRT_CLOSE))
buffer_dont_read(buf);
if (txn->rsp.msg_state == HTTP_MSG_ERROR)
goto wait_other_side;
if (txn->rsp.msg_state < HTTP_MSG_DONE) {
/* The server has not finished to respond, so we
* don't want to move in order not to upset it.
*/
goto wait_other_side;
}
if (txn->rsp.msg_state == HTTP_MSG_TUNNEL) {
/* if any side switches to tunnel mode, the other one does too */
buffer_auto_read(buf);
txn->req.msg_state = HTTP_MSG_TUNNEL;
goto wait_other_side;
}
/* When we get here, it means that both the request and the
* response have finished receiving. Depending on the connection
* mode, we'll have to wait for the last bytes to leave in either
* direction, and sometimes for a close to be effective.
*/
if ((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_SCL) {
/* Server-close mode : queue a connection close to the server */
if (!(buf->flags & (BF_SHUTW|BF_SHUTW_NOW)))
buffer_shutw_now(buf);
}
else if ((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_CLO) {
/* Option forceclose is set, or either side wants to close,
* let's enforce it now that we're not expecting any new
* data to come. The caller knows the session is complete
* once both states are CLOSED.
*/
if (!(buf->flags & (BF_SHUTW|BF_SHUTW_NOW))) {
buffer_shutr_now(buf);
buffer_shutw_now(buf);
}
}
else {
/* The last possible modes are keep-alive and tunnel. Since tunnel
* mode does not set the body analyser, we can't reach this place
* in tunnel mode, so we're left with keep-alive only.
* This mode is currently not implemented, we switch to tunnel mode.
*/
buffer_auto_read(buf);
txn->req.msg_state = HTTP_MSG_TUNNEL;
}
if (buf->flags & (BF_SHUTW|BF_SHUTW_NOW)) {
/* if we've just closed an output, let's switch */
buf->cons->flags |= SI_FL_NOLINGER; /* we want to close ASAP */
if (!(buf->flags & BF_OUT_EMPTY)) {
txn->req.msg_state = HTTP_MSG_CLOSING;
goto http_msg_closing;
}
else {
txn->req.msg_state = HTTP_MSG_CLOSED;
goto http_msg_closed;
}
}
goto wait_other_side;
}
if (txn->req.msg_state == HTTP_MSG_CLOSING) {
http_msg_closing:
/* nothing else to forward, just waiting for the output buffer
* to be empty and for the shutw_now to take effect.
*/
if (buf->flags & BF_OUT_EMPTY) {
txn->req.msg_state = HTTP_MSG_CLOSED;
goto http_msg_closed;
}
else if (buf->flags & BF_SHUTW) {
txn->req.msg_state = HTTP_MSG_ERROR;
goto wait_other_side;
}
}
if (txn->req.msg_state == HTTP_MSG_CLOSED) {
http_msg_closed:
goto wait_other_side;
}
wait_other_side:
http_silent_debug(__LINE__, s);
return txn->req.msg_state != old_state || buf->flags != old_flags;
}
/* This function updates the response state machine according to the request
* state machine and buffer flags. It returns 1 if it changes anything (flag
* or state), otherwise zero. It ignores any state before HTTP_MSG_DONE, as
* it is only used to find when a request/response couple is complete. Both
* this function and its equivalent should loop until both return zero. It
* can set its own state to DONE, CLOSING, CLOSED, TUNNEL, ERROR.
*/
int http_sync_res_state(struct session *s)
{
struct buffer *buf = s->rep;
struct http_txn *txn = &s->txn;
unsigned int old_flags = buf->flags;
unsigned int old_state = txn->rsp.msg_state;
http_silent_debug(__LINE__, s);
if (unlikely(txn->rsp.msg_state < HTTP_MSG_BODY))
return 0;
if (txn->rsp.msg_state == HTTP_MSG_DONE) {
/* In theory, we don't need to read anymore, but we must
* still monitor the server connection for a possible close
* while the request is being uploaded, so we don't disable
* reading.
*/
/* buffer_dont_read(buf); */
if (txn->req.msg_state == HTTP_MSG_ERROR)
goto wait_other_side;
if (txn->req.msg_state < HTTP_MSG_DONE) {
/* The client seems to still be sending data, probably
* because we got an error response during an upload.
* We have the choice of either breaking the connection
* or letting it pass through. Let's do the later.
*/
goto wait_other_side;
}
if (txn->req.msg_state == HTTP_MSG_TUNNEL) {
/* if any side switches to tunnel mode, the other one does too */
buffer_auto_read(buf);
txn->rsp.msg_state = HTTP_MSG_TUNNEL;
goto wait_other_side;
}
/* When we get here, it means that both the request and the
* response have finished receiving. Depending on the connection
* mode, we'll have to wait for the last bytes to leave in either
* direction, and sometimes for a close to be effective.
*/
if ((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_SCL) {
/* Server-close mode : shut read and wait for the request
* side to close its output buffer. The caller will detect
* when we're in DONE and the other is in CLOSED and will
* catch that for the final cleanup.
*/
if (!(buf->flags & (BF_SHUTR|BF_SHUTR_NOW)))
buffer_shutr_now(buf);
}
else if ((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_CLO) {
/* Option forceclose is set, or either side wants to close,
* let's enforce it now that we're not expecting any new
* data to come. The caller knows the session is complete
* once both states are CLOSED.
*/
if (!(buf->flags & (BF_SHUTW|BF_SHUTW_NOW))) {
buffer_shutr_now(buf);
buffer_shutw_now(buf);
}
}
else {
/* The last possible modes are keep-alive and tunnel. Since tunnel
* mode does not set the body analyser, we can't reach this place
* in tunnel mode, so we're left with keep-alive only.
* This mode is currently not implemented, we switch to tunnel mode.
*/
buffer_auto_read(buf);
txn->rsp.msg_state = HTTP_MSG_TUNNEL;
}
if (buf->flags & (BF_SHUTW|BF_SHUTW_NOW)) {
/* if we've just closed an output, let's switch */
if (!(buf->flags & BF_OUT_EMPTY)) {
txn->rsp.msg_state = HTTP_MSG_CLOSING;
goto http_msg_closing;
}
else {
txn->rsp.msg_state = HTTP_MSG_CLOSED;
goto http_msg_closed;
}
}
goto wait_other_side;
}
if (txn->rsp.msg_state == HTTP_MSG_CLOSING) {
http_msg_closing:
/* nothing else to forward, just waiting for the output buffer
* to be empty and for the shutw_now to take effect.
*/
if (buf->flags & BF_OUT_EMPTY) {
txn->rsp.msg_state = HTTP_MSG_CLOSED;
goto http_msg_closed;
}
else if (buf->flags & BF_SHUTW) {
txn->rsp.msg_state = HTTP_MSG_ERROR;
s->be->counters.cli_aborts++;
if (s->srv)
s->srv->counters.cli_aborts++;
goto wait_other_side;
}
}
if (txn->rsp.msg_state == HTTP_MSG_CLOSED) {
http_msg_closed:
/* drop any pending data */
buffer_ignore(buf, buf->l - buf->send_max);
buffer_auto_close(buf);
buffer_auto_read(buf);
goto wait_other_side;
}
wait_other_side:
http_silent_debug(__LINE__, s);
return txn->rsp.msg_state != old_state || buf->flags != old_flags;
}
/* Resync the request and response state machines. Return 1 if either state
* changes.
*/
int http_resync_states(struct session *s)
{
struct http_txn *txn = &s->txn;
int old_req_state = txn->req.msg_state;
int old_res_state = txn->rsp.msg_state;
http_silent_debug(__LINE__, s);
http_sync_req_state(s);
while (1) {
http_silent_debug(__LINE__, s);
if (!http_sync_res_state(s))
break;
http_silent_debug(__LINE__, s);
if (!http_sync_req_state(s))
break;
}
http_silent_debug(__LINE__, s);
/* OK, both state machines agree on a compatible state.
* There are a few cases we're interested in :
* - HTTP_MSG_TUNNEL on either means we have to disable both analysers
* - HTTP_MSG_CLOSED on both sides means we've reached the end in both
* directions, so let's simply disable both analysers.
* - HTTP_MSG_CLOSED on the response only means we must abort the
* request.
* - HTTP_MSG_CLOSED on the request and HTTP_MSG_DONE on the response
* with server-close mode means we've completed one request and we
* must re-initialize the server connection.
*/
if (txn->req.msg_state == HTTP_MSG_TUNNEL ||
txn->rsp.msg_state == HTTP_MSG_TUNNEL ||
(txn->req.msg_state == HTTP_MSG_CLOSED &&
txn->rsp.msg_state == HTTP_MSG_CLOSED)) {
s->req->analysers = 0;
buffer_auto_close(s->req);
buffer_auto_read(s->req);
s->rep->analysers = 0;
buffer_auto_close(s->rep);
buffer_auto_read(s->rep);
}
else if (txn->rsp.msg_state == HTTP_MSG_CLOSED ||
txn->rsp.msg_state == HTTP_MSG_ERROR ||
txn->req.msg_state == HTTP_MSG_ERROR ||
(s->rep->flags & BF_SHUTW)) {
s->rep->analysers = 0;
buffer_auto_close(s->rep);
buffer_auto_read(s->rep);
s->req->analysers = 0;
buffer_abort(s->req);
buffer_auto_close(s->req);
buffer_auto_read(s->req);
buffer_ignore(s->req, s->req->l - s->req->send_max);
}
else if (txn->req.msg_state == HTTP_MSG_CLOSED &&
txn->rsp.msg_state == HTTP_MSG_DONE &&
((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_SCL)) {
/* server-close: terminate this server connection and
* reinitialize a fresh-new transaction.
*/
http_end_txn_clean_session(s);
}
http_silent_debug(__LINE__, s);
return txn->req.msg_state != old_req_state ||
txn->rsp.msg_state != old_res_state;
}
/* This function is an analyser which forwards request body (including chunk
* sizes if any). It is called as soon as we must forward, even if we forward
* zero byte. The only situation where it must not be called is when we're in
* tunnel mode and we want to forward till the close. It's used both to forward
* remaining data and to resync after end of body. It expects the msg_state to
* be between MSG_BODY and MSG_DONE (inclusive). It returns zero if it needs to
* read more data, or 1 once we can go on with next request or end the session.
* When in MSG_DATA or MSG_TRAILERS, it will automatically forward hdr_content_len
* bytes of pending data + the headers if not already done (between som and sov).
* It eventually adjusts som to match sov after the data in between have been sent.
*/
int http_request_forward_body(struct session *s, struct buffer *req, int an_bit)
{
struct http_txn *txn = &s->txn;
struct http_msg *msg = &s->txn.req;
if (unlikely(msg->msg_state < HTTP_MSG_BODY))
return 0;
if ((req->flags & (BF_READ_ERROR|BF_READ_TIMEOUT|BF_WRITE_ERROR|BF_WRITE_TIMEOUT)) ||
((req->flags & BF_SHUTW) && (req->to_forward || req->send_max))) {
/* Output closed while we were sending data. We must abort and
* wake the other side up.
*/
msg->msg_state = HTTP_MSG_ERROR;
http_resync_states(s);
return 1;
}
/* in most states, we should abort in case of early close */
buffer_auto_close(req);
/* Note that we don't have to send 100-continue back because we don't
* need the data to complete our job, and it's up to the server to
* decide whether to return 100, 417 or anything else in return of
* an "Expect: 100-continue" header.
*/
if (msg->msg_state < HTTP_MSG_CHUNK_SIZE) {
/* we have msg->col and msg->sov which both point to the first
* byte of message body. msg->som still points to the beginning
* of the message. We must save the body in req->lr because it
* survives buffer re-alignments.
*/
req->lr = req->data + msg->sov;
if (txn->flags & TX_REQ_TE_CHNK)
msg->msg_state = HTTP_MSG_CHUNK_SIZE;
else {
msg->msg_state = HTTP_MSG_DATA;
}
}
while (1) {
http_silent_debug(__LINE__, s);
/* we may have some data pending */
if (msg->hdr_content_len || msg->som != msg->sov) {
int bytes = msg->sov - msg->som;
if (bytes < 0) /* sov may have wrapped at the end */
bytes += req->size;
buffer_forward(req, bytes + msg->hdr_content_len);
msg->hdr_content_len = 0; /* don't forward that again */
msg->som = msg->sov;
}
if (msg->msg_state == HTTP_MSG_DATA) {
/* must still forward */
if (req->to_forward)
goto missing_data;
/* nothing left to forward */
if (txn->flags & TX_REQ_TE_CHNK)
msg->msg_state = HTTP_MSG_DATA_CRLF;
else
msg->msg_state = HTTP_MSG_DONE;
}
else if (msg->msg_state == HTTP_MSG_CHUNK_SIZE) {
/* read the chunk size and assign it to ->hdr_content_len, then
* set ->sov and ->lr to point to the body and switch to DATA or
* TRAILERS state.
*/
int ret = http_parse_chunk_size(req, msg);
if (!ret)
goto missing_data;
else if (ret < 0)
goto return_bad_req;
/* otherwise we're in HTTP_MSG_DATA or HTTP_MSG_TRAILERS state */
}
else if (msg->msg_state == HTTP_MSG_DATA_CRLF) {
/* we want the CRLF after the data */
int ret;
req->lr = req->w + req->send_max;
if (req->lr >= req->data + req->size)
req->lr -= req->size;
ret = http_skip_chunk_crlf(req, msg);
if (ret == 0)
goto missing_data;
else if (ret < 0)
goto return_bad_req;
/* we're in MSG_CHUNK_SIZE now */
}
else if (msg->msg_state == HTTP_MSG_TRAILERS) {
int ret = http_forward_trailers(req, msg);
if (ret == 0)
goto missing_data;
else if (ret < 0)
goto return_bad_req;
/* we're in HTTP_MSG_DONE now */
}
else {
/* other states, DONE...TUNNEL */
/* for keep-alive we don't want to forward closes on DONE */
buffer_dont_close(req);
if (http_resync_states(s)) {
/* some state changes occurred, maybe the analyser
* was disabled too.
*/
if (unlikely(msg->msg_state == HTTP_MSG_ERROR))
goto return_bad_req;
return 1;
}
return 0;
}
}
missing_data:
/* stop waiting for data if the input is closed before the end */
if (req->flags & BF_SHUTR) {
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_CLICL;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_D;
goto return_bad_req;
}
/* waiting for the last bits to leave the buffer */
if (req->flags & BF_SHUTW) {
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_SRVCL;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_D;
goto return_bad_req;
}
http_silent_debug(__LINE__, s);
return 0;
return_bad_req: /* let's centralize all bad requests */
txn->req.msg_state = HTTP_MSG_ERROR;
txn->status = 400;
/* Note: we don't send any error if some data were already sent */
stream_int_retnclose(req->prod, (txn->rsp.msg_state < HTTP_MSG_BODY) ? error_message(s, HTTP_ERR_400) : NULL);
req->analysers = 0;
s->fe->counters.failed_req++;
if (s->listener->counters)
s->listener->counters->failed_req++;
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_PRXCOND;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_R;
http_silent_debug(__LINE__, s);
return 0;
}
/* This stream analyser waits for a complete HTTP response. It returns 1 if the
* processing can continue on next analysers, or zero if it either needs more
* data or wants to immediately abort the response (eg: timeout, error, ...). It
* is tied to AN_RES_WAIT_HTTP and may may remove itself from s->rep->analysers
* when it has nothing left to do, and may remove any analyser when it wants to
* abort.
*/
int http_wait_for_response(struct session *s, struct buffer *rep, int an_bit)
{
struct http_txn *txn = &s->txn;
struct http_msg *msg = &txn->rsp;
struct hdr_ctx ctx;
int use_close_only;
int cur_idx;
int n;
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bl=%d analysers=%02x\n",
now_ms, __FUNCTION__,
s,
rep,
rep->rex, rep->wex,
rep->flags,
rep->l,
rep->analysers);
/*
* Now parse the partial (or complete) lines.
* We will check the response syntax, and also join multi-line
* headers. An index of all the lines will be elaborated while
* parsing.
*
* For the parsing, we use a 28 states FSM.
*
* Here is the information we currently have :
* rep->data + msg->som = beginning of response
* rep->data + msg->eoh = end of processed headers / start of current one
* msg->eol = end of current header or line (LF or CRLF)
* rep->lr = first non-visited byte
* rep->r = end of data
* Once we reach MSG_BODY, rep->sol = rep->data + msg->som
*/
/* There's a protected area at the end of the buffer for rewriting
* purposes. We don't want to start to parse the request if the
* protected area is affected, because we may have to move processed
* data later, which is much more complicated.
*/
if (rep->l && msg->msg_state < HTTP_MSG_ERROR) {
if (unlikely((rep->flags & BF_FULL) ||
rep->r < rep->lr ||
rep->r > rep->data + rep->size - global.tune.maxrewrite)) {
if (rep->send_max) {
/* some data has still not left the buffer, wake us once that's done */
if (rep->flags & (BF_SHUTW|BF_SHUTW_NOW|BF_WRITE_ERROR|BF_WRITE_TIMEOUT))
goto abort_response;
buffer_dont_close(rep);
rep->flags |= BF_READ_DONTWAIT; /* try to get back here ASAP */
return 0;
}
if (rep->l <= rep->size - global.tune.maxrewrite)
http_buffer_heavy_realign(rep, msg);
}
if (likely(rep->lr < rep->r))
http_msg_analyzer(rep, msg, &txn->hdr_idx);
}
/* 1: we might have to print this header in debug mode */
if (unlikely((global.mode & MODE_DEBUG) &&
(!(global.mode & MODE_QUIET) || (global.mode & MODE_VERBOSE)) &&
msg->sol &&
(msg->msg_state >= HTTP_MSG_BODY || msg->msg_state == HTTP_MSG_ERROR))) {
char *eol, *sol;
sol = rep->data + msg->som;
eol = sol + msg->sl.st.l;
debug_hdr("srvrep", s, sol, eol);
sol += hdr_idx_first_pos(&txn->hdr_idx);
cur_idx = hdr_idx_first_idx(&txn->hdr_idx);
while (cur_idx) {
eol = sol + txn->hdr_idx.v[cur_idx].len;
debug_hdr("srvhdr", s, sol, eol);
sol = eol + txn->hdr_idx.v[cur_idx].cr + 1;
cur_idx = txn->hdr_idx.v[cur_idx].next;
}
}
/*
* Now we quickly check if we have found a full valid response.
* If not so, we check the FD and buffer states before leaving.
* A full response is indicated by the fact that we have seen
* the double LF/CRLF, so the state is >= HTTP_MSG_BODY. Invalid
* responses are checked first.
*
* Depending on whether the client is still there or not, we
* may send an error response back or not. Note that normally
* we should only check for HTTP status there, and check I/O
* errors somewhere else.
*/
if (unlikely(msg->msg_state < HTTP_MSG_BODY)) {
/* Invalid response */
if (unlikely(msg->msg_state == HTTP_MSG_ERROR)) {
/* we detected a parsing error. We want to archive this response
* in the dedicated proxy area for later troubleshooting.
*/
hdr_response_bad:
if (msg->msg_state == HTTP_MSG_ERROR || msg->err_pos >= 0)
http_capture_bad_message(&s->be->invalid_rep, s, rep, msg, s->fe);
s->be->counters.failed_resp++;
if (s->srv) {
s->srv->counters.failed_resp++;
health_adjust(s->srv, HANA_STATUS_HTTP_HDRRSP);
}
abort_response:
buffer_auto_close(rep);
rep->analysers = 0;
txn->status = 502;
rep->prod->flags |= SI_FL_NOLINGER;
buffer_ignore(rep, rep->l - rep->send_max);
stream_int_retnclose(rep->cons, error_message(s, HTTP_ERR_502));
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_PRXCOND;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_H;
return 0;
}
/* too large response does not fit in buffer. */
else if (rep->flags & BF_FULL) {
goto hdr_response_bad;
}
/* read error */
else if (rep->flags & BF_READ_ERROR) {
if (msg->err_pos >= 0)
http_capture_bad_message(&s->be->invalid_rep, s, rep, msg, s->fe);
s->be->counters.failed_resp++;
if (s->srv) {
s->srv->counters.failed_resp++;
health_adjust(s->srv, HANA_STATUS_HTTP_READ_ERROR);
}
buffer_auto_close(rep);
rep->analysers = 0;
txn->status = 502;
rep->prod->flags |= SI_FL_NOLINGER;
buffer_ignore(rep, rep->l - rep->send_max);
stream_int_retnclose(rep->cons, error_message(s, HTTP_ERR_502));
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_SRVCL;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_H;
return 0;
}
/* read timeout : return a 504 to the client. */
else if (rep->flags & BF_READ_TIMEOUT) {
if (msg->err_pos >= 0)
http_capture_bad_message(&s->be->invalid_rep, s, rep, msg, s->fe);
s->be->counters.failed_resp++;
if (s->srv) {
s->srv->counters.failed_resp++;
health_adjust(s->srv, HANA_STATUS_HTTP_READ_TIMEOUT);
}
buffer_auto_close(rep);
rep->analysers = 0;
txn->status = 504;
rep->prod->flags |= SI_FL_NOLINGER;
buffer_ignore(rep, rep->l - rep->send_max);
stream_int_retnclose(rep->cons, error_message(s, HTTP_ERR_504));
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_SRVTO;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_H;
return 0;
}
/* close from server */
else if (rep->flags & BF_SHUTR) {
if (msg->err_pos >= 0)
http_capture_bad_message(&s->be->invalid_rep, s, rep, msg, s->fe);
s->be->counters.failed_resp++;
if (s->srv) {
s->srv->counters.failed_resp++;
health_adjust(s->srv, HANA_STATUS_HTTP_BROKEN_PIPE);
}
buffer_auto_close(rep);
rep->analysers = 0;
txn->status = 502;
rep->prod->flags |= SI_FL_NOLINGER;
buffer_ignore(rep, rep->l - rep->send_max);
stream_int_retnclose(rep->cons, error_message(s, HTTP_ERR_502));
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_SRVCL;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_H;
return 0;
}
/* write error to client (we don't send any message then) */
else if (rep->flags & BF_WRITE_ERROR) {
if (msg->err_pos >= 0)
http_capture_bad_message(&s->be->invalid_rep, s, rep, msg, s->fe);
s->be->counters.failed_resp++;
rep->analysers = 0;
buffer_auto_close(rep);
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_CLICL;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_H;
/* process_session() will take care of the error */
return 0;
}
buffer_dont_close(rep);
return 0;
}
/* More interesting part now : we know that we have a complete
* response which at least looks like HTTP. We have an indicator
* of each header's length, so we can parse them quickly.
*/
if (unlikely(msg->err_pos >= 0))
http_capture_bad_message(&s->be->invalid_rep, s, rep, msg, s->fe);
/*
* 1: get the status code
*/
n = msg->sol[msg->sl.st.c] - '0';
if (n < 1 || n > 5)
n = 0;
if (s->srv)
s->srv->counters.p.http.rsp[n]++;
/* check if the response is HTTP/1.1 or above */
if ((msg->sl.st.v_l == 8) &&
((msg->sol[5] > '1') ||
((msg->sol[5] == '1') &&
(msg->sol[7] >= '1'))))
txn->flags |= TX_RES_VER_11;
/* "connection" has not been parsed yet */
txn->flags &= ~(TX_HDR_CONN_PRS|TX_HDR_CONN_CLO|TX_HDR_CONN_KAL|TX_CON_CLO_SET|TX_CON_KAL_SET);
/* transfer length unknown*/
txn->flags &= ~TX_RES_XFER_LEN;
txn->status = strl2ui(msg->sol + msg->sl.st.c, msg->sl.st.c_l);
/* Adjust server's health based on status code. Note: status codes 501
* and 505 are triggered on demand by client request, so we must not
* count them as server failures.
*/
if (s->srv) {
if (txn->status >= 100 && (txn->status < 500 || txn->status == 501 || txn->status == 505))
health_adjust(s->srv, HANA_STATUS_HTTP_OK);
else
health_adjust(s->srv, HANA_STATUS_HTTP_STS);
}
/*
* 2: check for cacheability.
*/
switch (txn->status) {
case 200:
case 203:
case 206:
case 300:
case 301:
case 410:
/* RFC2616 @13.4:
* "A response received with a status code of
* 200, 203, 206, 300, 301 or 410 MAY be stored
* by a cache (...) unless a cache-control
* directive prohibits caching."
*
* RFC2616 @9.5: POST method :
* "Responses to this method are not cacheable,
* unless the response includes appropriate
* Cache-Control or Expires header fields."
*/
if (likely(txn->meth != HTTP_METH_POST) &&
(s->be->options & (PR_O_CHK_CACHE|PR_O_COOK_NOC)))
txn->flags |= TX_CACHEABLE | TX_CACHE_COOK;
break;
default:
break;
}
/*
* 3: we may need to capture headers
*/
s->logs.logwait &= ~LW_RESP;
if (unlikely((s->logs.logwait & LW_RSPHDR) && s->fe->rsp_cap))
capture_headers(msg->sol, &txn->hdr_idx,
txn->rsp.cap, s->fe->rsp_cap);
/* 4: determine the transfer-length.
* According to RFC2616 #4.4, amended by the HTTPbis working group,
* the presence of a message-body in a RESPONSE and its transfer length
* must be determined that way :
*
* All responses to the HEAD request method MUST NOT include a
* message-body, even though the presence of entity-header fields
* might lead one to believe they do. All 1xx (informational), 204
* (No Content), and 304 (Not Modified) responses MUST NOT include a
* message-body. All other responses do include a message-body,
* although it MAY be of zero length.
*
* 1. Any response which "MUST NOT" include a message-body (such as the
* 1xx, 204 and 304 responses and any response to a HEAD request) is
* always terminated by the first empty line after the header fields,
* regardless of the entity-header fields present in the message.
*
* 2. If a Transfer-Encoding header field (Section 9.7) is present and
* the "chunked" transfer-coding (Section 6.2) is used, the
* transfer-length is defined by the use of this transfer-coding.
* If a Transfer-Encoding header field is present and the "chunked"
* transfer-coding is not present, the transfer-length is defined by
* the sender closing the connection.
*
* 3. If a Content-Length header field is present, its decimal value in
* OCTETs represents both the entity-length and the transfer-length.
* If a message is received with both a Transfer-Encoding header
* field and a Content-Length header field, the latter MUST be ignored.
*
* 4. If the message uses the media type "multipart/byteranges", and
* the transfer-length is not otherwise specified, then this self-
* delimiting media type defines the transfer-length. This media
* type MUST NOT be used unless the sender knows that the recipient
* can parse it; the presence in a request of a Range header with
* multiple byte-range specifiers from a 1.1 client implies that the
* client can parse multipart/byteranges responses.
*
* 5. By the server closing the connection.
*/
/* Skip parsing if no content length is possible. The response flags
* remain 0 as well as the hdr_content_len, which may or may not mirror
* the real header value, and we note that we know the response's length.
* FIXME: should we parse anyway and return an error on chunked encoding ?
*/
if (txn->meth == HTTP_METH_HEAD ||
(txn->status >= 100 && txn->status < 200) ||
txn->status == 204 || txn->status == 304) {
txn->flags |= TX_RES_XFER_LEN;
goto skip_content_length;
}
use_close_only = 0;
ctx.idx = 0;
while ((txn->flags & TX_RES_VER_11) &&
http_find_header2("Transfer-Encoding", 17, msg->sol, &txn->hdr_idx, &ctx)) {
if (ctx.vlen == 7 && strncasecmp(ctx.line + ctx.val, "chunked", 7) == 0)
txn->flags |= (TX_RES_TE_CHNK | TX_RES_XFER_LEN);
else if (txn->flags & TX_RES_TE_CHNK) {
/* bad transfer-encoding (chunked followed by something else) */
use_close_only = 1;
txn->flags &= ~(TX_RES_TE_CHNK | TX_RES_XFER_LEN);
break;
}
}
/* FIXME: below we should remove the content-length header(s) in case of chunked encoding */
ctx.idx = 0;
while (!(txn->flags & TX_RES_TE_CHNK) && !use_close_only &&
http_find_header2("Content-Length", 14, msg->sol, &txn->hdr_idx, &ctx)) {
signed long long cl;
if (!ctx.vlen)
goto hdr_response_bad;
if (strl2llrc(ctx.line + ctx.val, ctx.vlen, &cl))
goto hdr_response_bad; /* parse failure */
if (cl < 0)
goto hdr_response_bad;
if ((txn->flags & TX_RES_CNT_LEN) && (msg->hdr_content_len != cl))
goto hdr_response_bad; /* already specified, was different */
txn->flags |= TX_RES_CNT_LEN | TX_RES_XFER_LEN;
msg->hdr_content_len = cl;
}
/* FIXME: we should also implement the multipart/byterange method.
* For now on, we resort to close mode in this case (unknown length).
*/
skip_content_length:
/* end of job, return OK */
rep->analysers &= ~an_bit;
rep->analyse_exp = TICK_ETERNITY;
buffer_auto_close(rep);
return 1;
}
/* This function performs all the processing enabled for the current response.
* It normally returns 1 unless it wants to break. It relies on buffers flags,
* and updates t->rep->analysers. It might make sense to explode it into several
* other functions. It works like process_request (see indications above).
*/
int http_process_res_common(struct session *t, struct buffer *rep, int an_bit, struct proxy *px)
{
struct http_txn *txn = &t->txn;
struct http_msg *msg = &txn->rsp;
struct proxy *cur_proxy;
struct cond_wordlist *wl;
DPRINTF(stderr,"[%u] %s: session=%p b=%p, exp(r,w)=%u,%u bf=%08x bl=%d analysers=%02x\n",
now_ms, __FUNCTION__,
t,
rep,
rep->rex, rep->wex,
rep->flags,
rep->l,
rep->analysers);
if (unlikely(msg->msg_state < HTTP_MSG_BODY)) /* we need more data */
return 0;
rep->analysers &= ~an_bit;
rep->analyse_exp = TICK_ETERNITY;
/* Now we have to check if we need to modify the Connection header.
* This is more difficult on the response than it is on the request,
* because we can have two different HTTP versions and we don't know
* how the client will interprete a response. For instance, let's say
* that the client sends a keep-alive request in HTTP/1.0 and gets an
* HTTP/1.1 response without any header. Maybe it will bound itself to
* HTTP/1.0 because it only knows about it, and will consider the lack
* of header as a close, or maybe it knows HTTP/1.1 and can consider
* the lack of header as a keep-alive. Thus we will use two flags
* indicating how a request MAY be understood by the client. In case
* of multiple possibilities, we'll fix the header to be explicit. If
* ambiguous cases such as both close and keepalive are seen, then we
* will fall back to explicit close. Note that we won't take risks with
* HTTP/1.0 clients which may not necessarily understand keep-alive.
* See doc/internals/connection-header.txt for the complete matrix.
*/
if (unlikely((txn->meth == HTTP_METH_CONNECT && txn->status == 200) ||
txn->status == 101)) {
/* Either we've established an explicit tunnel, or we're
* switching the protocol. In both cases, we're very unlikely
* to understand the next protocols. We have to switch to tunnel
* mode, so that we transfer the request and responses then let
* this protocol pass unmodified. When we later implement specific
* parsers for such protocols, we'll want to check the Upgrade
* header which contains information about that protocol for
* responses with status 101 (eg: see RFC2817 about TLS).
*/
txn->flags = (txn->flags & ~TX_CON_WANT_MSK) | TX_CON_WANT_TUN;
}
else if ((txn->status >= 200) && !(txn->flags & TX_HDR_CONN_PRS) &&
((txn->flags & TX_CON_WANT_MSK) != TX_CON_WANT_TUN ||
((t->fe->options|t->be->options) & PR_O_HTTP_CLOSE))) {
int to_del = 0;
/* on unknown transfer length, we must close */
if (!(txn->flags & TX_RES_XFER_LEN) &&
(txn->flags & TX_CON_WANT_MSK) != TX_CON_WANT_TUN)
txn->flags = (txn->flags & ~TX_CON_WANT_MSK) | TX_CON_WANT_CLO;
/* now adjust header transformations depending on current state */
if ((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_TUN ||
(txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_CLO) {
to_del |= 2; /* remove "keep-alive" on any response */
if (!(txn->flags & TX_RES_VER_11))
to_del |= 1; /* remove "close" for HTTP/1.0 responses */
}
else { /* SCL / KAL */
to_del |= 1; /* remove "close" on any response */
if ((txn->flags & (TX_RES_VER_11|TX_REQ_VER_11)) == (TX_RES_VER_11|TX_REQ_VER_11))
to_del |= 2; /* remove "keep-alive" on pure 1.1 responses */
}
/* Parse and remove some headers from the connection header */
http_parse_connection_header(txn, msg, rep, to_del);
/* Some keep-alive responses are converted to Server-close if
* the server wants to close.
*/
if ((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_KAL) {
if ((txn->flags & TX_HDR_CONN_CLO) ||
(txn->flags & (TX_HDR_CONN_KAL|TX_RES_VER_11)) == 0)
txn->flags = (txn->flags & ~TX_CON_WANT_MSK) | TX_CON_WANT_SCL;
}
}
if (1) {
/*
* 3: we will have to evaluate the filters.
* As opposed to version 1.2, now they will be evaluated in the
* filters order and not in the header order. This means that
* each filter has to be validated among all headers.
*
* Filters are tried with ->be first, then with ->fe if it is
* different from ->be.
*/
cur_proxy = t->be;
while (1) {
struct proxy *rule_set = cur_proxy;
/* try headers filters */
if (rule_set->rsp_exp != NULL) {
if (apply_filters_to_response(t, rep, rule_set) < 0) {
return_bad_resp:
if (t->srv) {
t->srv->counters.failed_resp++;
health_adjust(t->srv, HANA_STATUS_HTTP_RSP);
}
cur_proxy->counters.failed_resp++;
return_srv_prx_502:
rep->analysers = 0;
txn->status = 502;
rep->prod->flags |= SI_FL_NOLINGER;
buffer_ignore(rep, rep->l - rep->send_max);
stream_int_retnclose(rep->cons, error_message(t, HTTP_ERR_502));
if (!(t->flags & SN_ERR_MASK))
t->flags |= SN_ERR_PRXCOND;
if (!(t->flags & SN_FINST_MASK))
t->flags |= SN_FINST_H;
return 0;
}
}
/* has the response been denied ? */
if (txn->flags & TX_SVDENY) {
if (t->srv)
t->srv->counters.failed_secu++;
cur_proxy->counters.denied_resp++;
if (t->listener->counters)
t->listener->counters->denied_resp++;
goto return_srv_prx_502;
}
/* add response headers from the rule sets in the same order */
list_for_each_entry(wl, &rule_set->rsp_add, list) {
if (txn->status < 200)
break;
if (wl->cond) {
int ret = acl_exec_cond(wl->cond, px, t, txn, ACL_DIR_RTR);
ret = acl_pass(ret);
if (((struct acl_cond *)wl->cond)->pol == ACL_COND_UNLESS)
ret = !ret;
if (!ret)
continue;
}
if (unlikely(http_header_add_tail(rep, &txn->rsp, &txn->hdr_idx, wl->s) < 0))
goto return_bad_resp;
}
/* check whether we're already working on the frontend */
if (cur_proxy == t->fe)
break;
cur_proxy = t->fe;
}
/*
* We may be facing a 100-continue response, in which case this
* is not the right response, and we're waiting for the next one.
* Let's allow this response to go to the client and wait for the
* next one.
*/
if (unlikely(txn->status == 100)) {
hdr_idx_init(&txn->hdr_idx);
buffer_forward(rep, rep->lr - msg->sol);
msg->msg_state = HTTP_MSG_RPBEFORE;
txn->status = 0;
rep->analysers |= AN_RES_WAIT_HTTP | an_bit;
return 1;
}
else if (unlikely(txn->status < 200))
goto skip_header_mangling;
/* we don't have any 1xx status code now */
/*
* 4: check for server cookie.
*/
if (t->be->cookie_name || t->be->appsession_name || t->fe->capture_name ||
(t->be->options & PR_O_CHK_CACHE))
manage_server_side_cookies(t, rep);
/*
* 5: check for cache-control or pragma headers if required.
*/
if ((t->be->options & (PR_O_COOK_NOC | PR_O_CHK_CACHE)) != 0)
check_response_for_cacheability(t, rep);
/*
* 6: add server cookie in the response if needed
*/
if ((t->srv) && !(t->flags & SN_DIRECT) && (t->be->options & PR_O_COOK_INS) &&
(!(t->be->options & PR_O_COOK_POST) || (txn->meth == HTTP_METH_POST)) &&
!(t->flags & SN_IGNORE_PRST)) {
int len;
/* the server is known, it's not the one the client requested, we have to
* insert a set-cookie here, except if we want to insert only on POST
* requests and this one isn't. Note that servers which don't have cookies
* (eg: some backup servers) will return a full cookie removal request.
*/
len = sprintf(trash, "Set-Cookie: %s=%s; path=/",
t->be->cookie_name,
t->srv->cookie ? t->srv->cookie : "; Expires=Thu, 01-Jan-1970 00:00:01 GMT");
if (t->be->cookie_domain)
len += sprintf(trash+len, "; domain=%s", t->be->cookie_domain);
if (unlikely(http_header_add_tail2(rep, &txn->rsp, &txn->hdr_idx,
trash, len) < 0))
goto return_bad_resp;
txn->flags |= TX_SCK_INSERTED;
/* Here, we will tell an eventual cache on the client side that we don't
* want it to cache this reply because HTTP/1.0 caches also cache cookies !
* Some caches understand the correct form: 'no-cache="set-cookie"', but
* others don't (eg: apache <= 1.3.26). So we use 'private' instead.
*/
if ((t->be->options & PR_O_COOK_NOC) && (txn->flags & TX_CACHEABLE)) {
txn->flags &= ~TX_CACHEABLE & ~TX_CACHE_COOK;
if (unlikely(http_header_add_tail2(rep, &txn->rsp, &txn->hdr_idx,
"Cache-control: private", 22) < 0))
goto return_bad_resp;
}
}
/*
* 7: check if result will be cacheable with a cookie.
* We'll block the response if security checks have caught
* nasty things such as a cacheable cookie.
*/
if (((txn->flags & (TX_CACHEABLE | TX_CACHE_COOK | TX_SCK_ANY)) ==
(TX_CACHEABLE | TX_CACHE_COOK | TX_SCK_ANY)) &&
(t->be->options & PR_O_CHK_CACHE)) {
/* we're in presence of a cacheable response containing
* a set-cookie header. We'll block it as requested by
* the 'checkcache' option, and send an alert.
*/
if (t->srv)
t->srv->counters.failed_secu++;
cur_proxy->counters.denied_resp++;
if (t->listener->counters)
t->listener->counters->denied_resp++;
Alert("Blocking cacheable cookie in response from instance %s, server %s.\n",
t->be->id, t->srv?t->srv->id:"<dispatch>");
send_log(t->be, LOG_ALERT,
"Blocking cacheable cookie in response from instance %s, server %s.\n",
t->be->id, t->srv?t->srv->id:"<dispatch>");
goto return_srv_prx_502;
}
/*
* 8: adjust "Connection: close" or "Connection: keep-alive" if needed.
*/
if (((txn->flags & TX_CON_WANT_MSK) != TX_CON_WANT_TUN) ||
((t->fe->options|t->be->options) & PR_O_HTTP_CLOSE)) {
unsigned int want_flags = 0;
if ((txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_KAL ||
(txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_SCL) {
/* we want a keep-alive response here. Keep-alive header
* required if either side is not 1.1.
*/
if ((txn->flags & (TX_REQ_VER_11|TX_RES_VER_11)) != (TX_REQ_VER_11|TX_RES_VER_11))
want_flags |= TX_CON_KAL_SET;
}
else {
/* we want a close response here. Close header required if
* the server is 1.1, regardless of the client.
*/
if (txn->flags & TX_RES_VER_11)
want_flags |= TX_CON_CLO_SET;
}
if (want_flags != (txn->flags & (TX_CON_CLO_SET|TX_CON_KAL_SET)))
http_change_connection_header(txn, msg, rep, want_flags);
}
skip_header_mangling:
if ((txn->flags & TX_RES_XFER_LEN) ||
(txn->flags & TX_CON_WANT_MSK) == TX_CON_WANT_TUN)
rep->analysers |= AN_RES_HTTP_XFER_BODY;
/*************************************************************
* OK, that's finished for the headers. We have done what we *
* could. Let's switch to the DATA state. *
************************************************************/
t->logs.t_data = tv_ms_elapsed(&t->logs.tv_accept, &now);
/* if the user wants to log as soon as possible, without counting
* bytes from the server, then this is the right moment. We have
* to temporarily assign bytes_out to log what we currently have.
*/
if (t->fe->to_log && !(t->logs.logwait & LW_BYTES)) {
t->logs.t_close = t->logs.t_data; /* to get a valid end date */
t->logs.bytes_out = txn->rsp.eoh;
t->do_log(t);
t->logs.bytes_out = 0;
}
/* Note: we must not try to cheat by jumping directly to DATA,
* otherwise we would not let the client side wake up.
*/
return 1;
}
return 1;
}
/* This function is an analyser which forwards response body (including chunk
* sizes if any). It is called as soon as we must forward, even if we forward
* zero byte. The only situation where it must not be called is when we're in
* tunnel mode and we want to forward till the close. It's used both to forward
* remaining data and to resync after end of body. It expects the msg_state to
* be between MSG_BODY and MSG_DONE (inclusive). It returns zero if it needs to
* read more data, or 1 once we can go on with next request or end the session.
* When in MSG_DATA or MSG_TRAILERS, it will automatically forward hdr_content_len
* bytes of pending data + the headers if not already done (between som and sov).
* It eventually adjusts som to match sov after the data in between have been sent.
*/
int http_response_forward_body(struct session *s, struct buffer *res, int an_bit)
{
struct http_txn *txn = &s->txn;
struct http_msg *msg = &s->txn.rsp;
if (unlikely(msg->msg_state < HTTP_MSG_BODY))
return 0;
if ((res->flags & (BF_READ_ERROR|BF_READ_TIMEOUT|BF_WRITE_ERROR|BF_WRITE_TIMEOUT)) ||
((res->flags & BF_SHUTW) && (res->to_forward || res->send_max)) ||
!s->req->analysers) {
/* Output closed while we were sending data. We must abort and
* wake the other side up.
*/
msg->msg_state = HTTP_MSG_ERROR;
http_resync_states(s);
return 1;
}
/* in most states, we should abort in case of early close */
buffer_auto_close(res);
if (msg->msg_state < HTTP_MSG_CHUNK_SIZE) {
/* we have msg->col and msg->sov which both point to the first
* byte of message body. msg->som still points to the beginning
* of the message. We must save the body in req->lr because it
* survives buffer re-alignments.
*/
res->lr = res->data + msg->sov;
if (txn->flags & TX_RES_TE_CHNK)
msg->msg_state = HTTP_MSG_CHUNK_SIZE;
else {
msg->msg_state = HTTP_MSG_DATA;
}
}
while (1) {
http_silent_debug(__LINE__, s);
/* we may have some data pending */
if (msg->hdr_content_len || msg->som != msg->sov) {
int bytes = msg->sov - msg->som;
if (bytes < 0) /* sov may have wrapped at the end */
bytes += res->size;
buffer_forward(res, bytes + msg->hdr_content_len);
msg->hdr_content_len = 0; /* don't forward that again */
msg->som = msg->sov;
}
if (msg->msg_state == HTTP_MSG_DATA) {
/* must still forward */
if (res->to_forward)
goto missing_data;
/* nothing left to forward */
if (txn->flags & TX_RES_TE_CHNK)
msg->msg_state = HTTP_MSG_DATA_CRLF;
else
msg->msg_state = HTTP_MSG_DONE;
}
else if (msg->msg_state == HTTP_MSG_CHUNK_SIZE) {
/* read the chunk size and assign it to ->hdr_content_len, then
* set ->sov to point to the body and switch to DATA or TRAILERS state.
*/
int ret = http_parse_chunk_size(res, msg);
if (!ret)
goto missing_data;
else if (ret < 0)
goto return_bad_res;
/* otherwise we're in HTTP_MSG_DATA or HTTP_MSG_TRAILERS state */
}
else if (msg->msg_state == HTTP_MSG_DATA_CRLF) {
/* we want the CRLF after the data */
int ret;
res->lr = res->w + res->send_max;
if (res->lr >= res->data + res->size)
res->lr -= res->size;
ret = http_skip_chunk_crlf(res, msg);
if (!ret)
goto missing_data;
else if (ret < 0)
goto return_bad_res;
/* we're in MSG_CHUNK_SIZE now */
}
else if (msg->msg_state == HTTP_MSG_TRAILERS) {
int ret = http_forward_trailers(res, msg);
if (ret == 0)
goto missing_data;
else if (ret < 0)
goto return_bad_res;
/* we're in HTTP_MSG_DONE now */
}
else {
/* other states, DONE...TUNNEL */
/* for keep-alive we don't want to forward closes on DONE */
buffer_dont_close(res);
if (http_resync_states(s)) {
http_silent_debug(__LINE__, s);
/* some state changes occurred, maybe the analyser
* was disabled too.
*/
if (unlikely(msg->msg_state == HTTP_MSG_ERROR))
goto return_bad_res;
return 1;
}
return 0;
}
}
missing_data:
/* stop waiting for data if the input is closed before the end */
if (res->flags & BF_SHUTR) {
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_SRVCL;
s->be->counters.srv_aborts++;
if (s->srv)
s->srv->counters.srv_aborts++;
goto return_bad_res;
}
/* we need to obey the req analyser, so if it leaves, we must too */
if (!s->req->analysers)
goto return_bad_res;
/* forward the chunk size as well as any pending data */
if (msg->hdr_content_len || msg->som != msg->sov) {
buffer_forward(res, msg->sov - msg->som + msg->hdr_content_len);
msg->hdr_content_len = 0; /* don't forward that again */
msg->som = msg->sov;
}
/* the session handler will take care of timeouts and errors */
http_silent_debug(__LINE__, s);
return 0;
return_bad_res: /* let's centralize all bad responses */
txn->rsp.msg_state = HTTP_MSG_ERROR;
/* don't send any error message as we're in the body */
stream_int_retnclose(res->cons, NULL);
res->analysers = 0;
s->be->counters.failed_resp++;
if (s->srv) {
s->srv->counters.failed_resp++;
health_adjust(s->srv, HANA_STATUS_HTTP_HDRRSP);
}
if (!(s->flags & SN_ERR_MASK))
s->flags |= SN_ERR_PRXCOND;
if (!(s->flags & SN_FINST_MASK))
s->flags |= SN_FINST_D;
http_silent_debug(__LINE__, s);
return 0;
}
/* Iterate the same filter through all request headers.
* Returns 1 if this filter can be stopped upon return, otherwise 0.
* Since it can manage the switch to another backend, it updates the per-proxy
* DENY stats.
*/
int apply_filter_to_req_headers(struct session *t, struct buffer *req, struct hdr_exp *exp)
{
char term;
char *cur_ptr, *cur_end, *cur_next;
int cur_idx, old_idx, last_hdr;
struct http_txn *txn = &t->txn;
struct hdr_idx_elem *cur_hdr;
int len, delta;
last_hdr = 0;
cur_next = txn->req.sol + hdr_idx_first_pos(&txn->hdr_idx);
old_idx = 0;
while (!last_hdr) {
if (unlikely(txn->flags & (TX_CLDENY | TX_CLTARPIT)))
return 1;
else if (unlikely(txn->flags & TX_CLALLOW) &&
(exp->action == ACT_ALLOW ||
exp->action == ACT_DENY ||
exp->action == ACT_TARPIT))
return 0;
cur_idx = txn->hdr_idx.v[old_idx].next;
if (!cur_idx)
break;
cur_hdr = &txn->hdr_idx.v[cur_idx];
cur_ptr = cur_next;
cur_end = cur_ptr + cur_hdr->len;
cur_next = cur_end + cur_hdr->cr + 1;
/* Now we have one header between cur_ptr and cur_end,
* and the next header starts at cur_next.
*/
/* The annoying part is that pattern matching needs
* that we modify the contents to null-terminate all
* strings before testing them.
*/
term = *cur_end;
*cur_end = '\0';
if (regexec(exp->preg, cur_ptr, MAX_MATCH, pmatch, 0) == 0) {
switch (exp->action) {
case ACT_SETBE:
/* It is not possible to jump a second time.
* FIXME: should we return an HTTP/500 here so that
* the admin knows there's a problem ?
*/
if (t->be != t->fe)
break;
/* Swithing Proxy */
session_set_backend(t, (struct proxy *)exp->replace);
last_hdr = 1;
break;
case ACT_ALLOW:
txn->flags |= TX_CLALLOW;
last_hdr = 1;
break;
case ACT_DENY:
txn->flags |= TX_CLDENY;
last_hdr = 1;
t->be->counters.denied_req++;
if (t->listener->counters)
t->listener->counters->denied_resp++;
break;
case ACT_TARPIT:
txn->flags |= TX_CLTARPIT;
last_hdr = 1;
t->be->counters.denied_req++;
if (t->listener->counters)
t->listener->counters->denied_resp++;
break;
case ACT_REPLACE:
len = exp_replace(trash, cur_ptr, exp->replace, pmatch);
delta = buffer_replace2(req, cur_ptr, cur_end, trash, len);
/* FIXME: if the user adds a newline in the replacement, the
* index will not be recalculated for now, and the new line
* will not be counted as a new header.
*/
cur_end += delta;
cur_next += delta;
cur_hdr->len += delta;
http_msg_move_end(&txn->req, delta);
break;
case ACT_REMOVE:
delta = buffer_replace2(req, cur_ptr, cur_next, NULL, 0);
cur_next += delta;
http_msg_move_end(&txn->req, delta);
txn->hdr_idx.v[old_idx].next = cur_hdr->next;
txn->hdr_idx.used--;
cur_hdr->len = 0;
cur_end = NULL; /* null-term has been rewritten */
break;
}
}
if (cur_end)
*cur_end = term; /* restore the string terminator */
/* keep the link from this header to next one in case of later
* removal of next header.
*/
old_idx = cur_idx;
}
return 0;
}
/* Apply the filter to the request line.
* Returns 0 if nothing has been done, 1 if the filter has been applied,
* or -1 if a replacement resulted in an invalid request line.
* Since it can manage the switch to another backend, it updates the per-proxy
* DENY stats.
*/
int apply_filter_to_req_line(struct session *t, struct buffer *req, struct hdr_exp *exp)
{
char term;
char *cur_ptr, *cur_end;
int done;
struct http_txn *txn = &t->txn;
int len, delta;
if (unlikely(txn->flags & (TX_CLDENY | TX_CLTARPIT)))
return 1;
else if (unlikely(txn->flags & TX_CLALLOW) &&
(exp->action == ACT_ALLOW ||
exp->action == ACT_DENY ||
exp->action == ACT_TARPIT))
return 0;
else if (exp->action == ACT_REMOVE)
return 0;
done = 0;
cur_ptr = txn->req.sol;
cur_end = cur_ptr + txn->req.sl.rq.l;
/* Now we have the request line between cur_ptr and cur_end */
/* The annoying part is that pattern matching needs
* that we modify the contents to null-terminate all
* strings before testing them.
*/
term = *cur_end;
*cur_end = '\0';
if (regexec(exp->preg, cur_ptr, MAX_MATCH, pmatch, 0) == 0) {
switch (exp->action) {
case ACT_SETBE:
/* It is not possible to jump a second time.
* FIXME: should we return an HTTP/500 here so that
* the admin knows there's a problem ?
*/
if (t->be != t->fe)
break;
/* Swithing Proxy */
session_set_backend(t, (struct proxy *)exp->replace);
done = 1;
break;
case ACT_ALLOW:
txn->flags |= TX_CLALLOW;
done = 1;
break;
case ACT_DENY:
txn->flags |= TX_CLDENY;
t->be->counters.denied_req++;
if (t->listener->counters)
t->listener->counters->denied_resp++;
done = 1;
break;
case ACT_TARPIT:
txn->flags |= TX_CLTARPIT;
t->be->counters.denied_req++;
if (t->listener->counters)
t->listener->counters->denied_resp++;
done = 1;
break;
case ACT_REPLACE:
*cur_end = term; /* restore the string terminator */
len = exp_replace(trash, cur_ptr, exp->replace, pmatch);
delta = buffer_replace2(req, cur_ptr, cur_end, trash, len);
/* FIXME: if the user adds a newline in the replacement, the
* index will not be recalculated for now, and the new line
* will not be counted as a new header.
*/
http_msg_move_end(&txn->req, delta);
cur_end += delta;
cur_end = (char *)http_parse_reqline(&txn->req, req->data,
HTTP_MSG_RQMETH,
cur_ptr, cur_end + 1,
NULL, NULL);
if (unlikely(!cur_end))
return -1;
/* we have a full request and we know that we have either a CR
* or an LF at <ptr>.
*/
txn->meth = find_http_meth(cur_ptr, txn->req.sl.rq.m_l);
hdr_idx_set_start(&txn->hdr_idx, txn->req.sl.rq.l, *cur_end == '\r');
/* there is no point trying this regex on headers */
return 1;
}
}
*cur_end = term; /* restore the string terminator */
return done;
}
/*
* Apply all the req filters of proxy <px> to all headers in buffer <req> of session <s>.
* Returns 0 if everything is alright, or -1 in case a replacement lead to an
* unparsable request. Since it can manage the switch to another backend, it
* updates the per-proxy DENY stats.
*/
int apply_filters_to_request(struct session *s, struct buffer *req, struct proxy *px)
{
struct http_txn *txn = &s->txn;
struct hdr_exp *exp;
for (exp = px->req_exp; exp; exp = exp->next) {
int ret;
/*
* The interleaving of transformations and verdicts
* makes it difficult to decide to continue or stop
* the evaluation.
*/
if (txn->flags & (TX_CLDENY|TX_CLTARPIT))
break;
if ((txn->flags & TX_CLALLOW) &&
(exp->action == ACT_ALLOW || exp->action == ACT_DENY ||
exp->action == ACT_TARPIT || exp->action == ACT_PASS))
continue;
/* if this filter had a condition, evaluate it now and skip to
* next filter if the condition does not match.
*/
if (exp->cond) {
ret = acl_exec_cond(exp->cond, px, s, txn, ACL_DIR_REQ);
ret = acl_pass(ret);
if (((struct acl_cond *)exp->cond)->pol == ACL_COND_UNLESS)
ret = !ret;
if (!ret)
continue;
}
/* Apply the filter to the request line. */
ret = apply_filter_to_req_line(s, req, exp);
if (unlikely(ret < 0))
return -1;
if (likely(ret == 0)) {
/* The filter did not match the request, it can be
* iterated through all headers.
*/
apply_filter_to_req_headers(s, req, exp);
}
}
return 0;
}
/*
* Try to retrieve the server associated to the appsession.
* If the server is found, it's assigned to the session.
*/
void manage_client_side_appsession(struct session *t, const char *buf, int len) {
struct http_txn *txn = &t->txn;
appsess *asession = NULL;
char *sessid_temp = NULL;
if (len > t->be->appsession_len) {
len = t->be->appsession_len;
}
if (t->be->options2 & PR_O2_AS_REQL) {
/* request-learn option is enabled : store the sessid in the session for future use */
if (txn->sessid != NULL) {
/* free previously allocated memory as we don't need the session id found in the URL anymore */
pool_free2(apools.sessid, txn->sessid);
}
if ((txn->sessid = pool_alloc2(apools.sessid)) == NULL) {
Alert("Not enough memory process_cli():asession->sessid:malloc().\n");
send_log(t->be, LOG_ALERT, "Not enough memory process_cli():asession->sessid:malloc().\n");
return;
}
memcpy(txn->sessid, buf, len);
txn->sessid[len] = 0;
}
if ((sessid_temp = pool_alloc2(apools.sessid)) == NULL) {
Alert("Not enough memory process_cli():asession->sessid:malloc().\n");
send_log(t->be, LOG_ALERT, "Not enough memory process_cli():asession->sessid:malloc().\n");
return;
}
memcpy(sessid_temp, buf, len);
sessid_temp[len] = 0;
asession = appsession_hash_lookup(&(t->be->htbl_proxy), sessid_temp);
/* free previously allocated memory */
pool_free2(apools.sessid, sessid_temp);
if (asession != NULL) {
asession->expire = tick_add_ifset(now_ms, t->be->timeout.appsession);
if (!(t->be->options2 & PR_O2_AS_REQL))
asession->request_count++;
if (asession->serverid != NULL) {
struct server *srv = t->be->srv;
while (srv) {
if (strcmp(srv->id, asession->serverid) == 0) {
if ((srv->state & SRV_RUNNING) ||
(t->be->options & PR_O_PERSIST) ||
(t->flags & SN_FORCE_PRST)) {
/* we found the server and it's usable */
txn->flags &= ~TX_CK_MASK;
txn->flags |= (srv->state & SRV_RUNNING) ? TX_CK_VALID : TX_CK_DOWN;
t->flags |= SN_DIRECT | SN_ASSIGNED;
t->srv = srv;
break;
} else {
txn->flags &= ~TX_CK_MASK;
txn->flags |= TX_CK_DOWN;
}
}
srv = srv->next;
}
}
}
}
/*
* Manage client-side cookie. It can impact performance by about 2% so it is
* desirable to call it only when needed.
*/
void manage_client_side_cookies(struct session *t, struct buffer *req)
{
struct http_txn *txn = &t->txn;
char *p1, *p2, *p3, *p4, *p5;
char *del_colon, *del_cookie, *colon;
int app_cookies;
char *cur_ptr, *cur_end, *cur_next;
int cur_idx, old_idx;
/* Iterate through the headers.
* we start with the start line.
*/
old_idx = 0;
cur_next = txn->req.sol + hdr_idx_first_pos(&txn->hdr_idx);
while ((cur_idx = txn->hdr_idx.v[old_idx].next)) {
struct hdr_idx_elem *cur_hdr;
int val;
cur_hdr = &txn->hdr_idx.v[cur_idx];
cur_ptr = cur_next;
cur_end = cur_ptr + cur_hdr->len;
cur_next = cur_end + cur_hdr->cr + 1;
/* We have one full header between cur_ptr and cur_end, and the
* next header starts at cur_next. We're only interested in
* "Cookie:" headers.
*/
val = http_header_match2(cur_ptr, cur_end, "Cookie", 6);
if (!val) {
old_idx = cur_idx;
continue;
}
/* Now look for cookies. Conforming to RFC2109, we have to support
* attributes whose name begin with a '$', and associate them with
* the right cookie, if we want to delete this cookie.
* So there are 3 cases for each cookie read :
* 1) it's a special attribute, beginning with a '$' : ignore it.
* 2) it's a server id cookie that we *MAY* want to delete : save
* some pointers on it (last semi-colon, beginning of cookie...)
* 3) it's an application cookie : we *MAY* have to delete a previous
* "special" cookie.
* At the end of loop, if a "special" cookie remains, we may have to
* remove it. If no application cookie persists in the header, we
* *MUST* delete it
*/
colon = p1 = cur_ptr + val; /* first non-space char after 'Cookie:' */
/* del_cookie == NULL => nothing to be deleted */
del_colon = del_cookie = NULL;
app_cookies = 0;
while (p1 < cur_end) {
/* skip spaces and colons, but keep an eye on these ones */
resync_name:
while (p1 < cur_end) {
if (*p1 == ';' || *p1 == ',')
colon = p1;
else if (!isspace((unsigned char)*p1))
break;
p1++;
}
if (p1 == cur_end)
break;
/* p1 is at the beginning of the cookie name */
p2 = p1;
while (p2 < cur_end && *p2 != '=') {
if (*p2 == ',' || *p2 == ';' || isspace((unsigned char)*p2)) {
/* oops, the cookie name was truncated, resync */
p1 = p2;
goto resync_name;
}
p2++;
}
if (p2 == cur_end)
break;
p3 = p2 + 1; /* skips the '=' sign */
if (p3 == cur_end)
break;
/* parse the value, stripping leading and trailing spaces but keeping insiders. */
p5 = p4 = p3;
while (p5 < cur_end && *p5 != ';' && *p5 != ',') {
if (!isspace((unsigned char)*p5))
p4 = p5 + 1;
p5++;
}
/* here, we have the cookie name between p1 and p2,
* and its value between p3 and p4.
* we can process it :
*
* Cookie: NAME=VALUE ;
* | || || |+-> p5
* | || || +--> p4
* | || |+-------> p3
* | || +--------> p2
* | |+------------> p1
* | +-------------> colon
* +--------------------> cur_ptr
*/
if (*p1 == '$') {
/* skip this one */
}
else {
/* first, let's see if we want to capture it */
if (t->fe->capture_name != NULL &&
txn->cli_cookie == NULL &&
(p4 - p1 >= t->fe->capture_namelen) &&
memcmp(p1, t->fe->capture_name, t->fe->capture_namelen) == 0) {
int log_len = p4 - p1;
if ((txn->cli_cookie = pool_alloc2(pool2_capture)) == NULL) {
Alert("HTTP logging : out of memory.\n");
} else {
if (log_len > t->fe->capture_len)
log_len = t->fe->capture_len;
memcpy(txn->cli_cookie, p1, log_len);
txn->cli_cookie[log_len] = 0;
}
}
if ((p2 - p1 == t->be->cookie_len) && (t->be->cookie_name != NULL) &&
(memcmp(p1, t->be->cookie_name, p2 - p1) == 0)) {
/* Cool... it's the right one */
struct server *srv = t->be->srv;
char *delim;
/* if we're in cookie prefix mode, we'll search the delimitor so that we
* have the server ID betweek p3 and delim, and the original cookie between
* delim+1 and p4. Otherwise, delim==p4 :
*
* Cookie: NAME=SRV~VALUE ;
* | || || | |+-> p5
* | || || | +--> p4
* | || || +--------> delim
* | || |+-----------> p3
* | || +------------> p2
* | |+----------------> p1
* | +-----------------> colon
* +------------------------> cur_ptr
*/
if (t->be->options & PR_O_COOK_PFX) {
for (delim = p3; delim < p4; delim++)
if (*delim == COOKIE_DELIM)
break;
}
else
delim = p4;
/* Here, we'll look for the first running server which supports the cookie.
* This allows to share a same cookie between several servers, for example
* to dedicate backup servers to specific servers only.
* However, to prevent clients from sticking to cookie-less backup server
* when they have incidentely learned an empty cookie, we simply ignore
* empty cookies and mark them as invalid.
* The same behaviour is applied when persistence must be ignored.
*/
if ((delim == p3) || (t->flags & SN_IGNORE_PRST))
srv = NULL;
while (srv) {
if (srv->cookie && (srv->cklen == delim - p3) &&
!memcmp(p3, srv->cookie, delim - p3)) {
if ((srv->state & SRV_RUNNING) ||
(t->be->options & PR_O_PERSIST) ||
(t->flags & SN_FORCE_PRST)) {
/* we found the server and it's usable */
txn->flags &= ~TX_CK_MASK;
txn->flags |= (srv->state & SRV_RUNNING) ? TX_CK_VALID : TX_CK_DOWN;
t->flags |= SN_DIRECT | SN_ASSIGNED;
t->srv = srv;
break;
} else {
/* we found a server, but it's down */
txn->flags &= ~TX_CK_MASK;
txn->flags |= TX_CK_DOWN;
}
}
srv = srv->next;
}
if (!srv && !(txn->flags & TX_CK_DOWN)) {
/* no server matched this cookie */
txn->flags &= ~TX_CK_MASK;
txn->flags |= TX_CK_INVALID;
}
/* depending on the cookie mode, we may have to either :
* - delete the complete cookie if we're in insert+indirect mode, so that
* the server never sees it ;
* - remove the server id from the cookie value, and tag the cookie as an
* application cookie so that it does not get accidentely removed later,
* if we're in cookie prefix mode
*/
if ((t->be->options & PR_O_COOK_PFX) && (delim != p4)) {
int delta; /* negative */
delta = buffer_replace2(req, p3, delim + 1, NULL, 0);
p4 += delta;
p5 += delta;
cur_end += delta;
cur_next += delta;
cur_hdr->len += delta;
http_msg_move_end(&txn->req, delta);
del_cookie = del_colon = NULL;
app_cookies++; /* protect the header from deletion */
}
else if (del_cookie == NULL &&
(t->be->options & (PR_O_COOK_INS | PR_O_COOK_IND)) == (PR_O_COOK_INS | PR_O_COOK_IND)) {
del_cookie = p1;
del_colon = colon;
}
} else {
/* now we know that we must keep this cookie since it's
* not ours. But if we wanted to delete our cookie
* earlier, we cannot remove the complete header, but we
* can remove the previous block itself.
*/
app_cookies++;
if (del_cookie != NULL) {
int delta; /* negative */
delta = buffer_replace2(req, del_cookie, p1, NULL, 0);
p4 += delta;
p5 += delta;
cur_end += delta;
cur_next += delta;
cur_hdr->len += delta;
http_msg_move_end(&txn->req, delta);
del_cookie = del_colon = NULL;
}
}
/* Look for the appsession cookie unless persistence must be ignored */
if (!(t->flags & SN_IGNORE_PRST) && (t->be->appsession_name != NULL)) {
int cmp_len, value_len;
char *value_begin;
if (t->be->options2 & PR_O2_AS_PFX) {
cmp_len = MIN(p4 - p1, t->be->appsession_name_len);
value_begin = p1 + t->be->appsession_name_len;
value_len = p4 - p1 - t->be->appsession_name_len;
} else {
cmp_len = p2 - p1;
value_begin = p3;
value_len = p4 - p3;
}
/* let's see if the cookie is our appcookie */
if ((cmp_len == t->be->appsession_name_len) &&
(memcmp(p1, t->be->appsession_name, t->be->appsession_name_len) == 0)) {
/* Cool... it's the right one */
manage_client_side_appsession(t, value_begin, value_len);
}
#if defined(DEBUG_HASH)
Alert("manage_client_side_cookies\n");
appsession_hash_dump(&(t->be->htbl_proxy));
#endif
}/* end if ((t->proxy->appsession_name != NULL) ... */
}
/* we'll have to look for another cookie ... */
p1 = p5;
} /* while (p1 < cur_end) */
/* There's no more cookie on this line.
* We may have marked the last one(s) for deletion.
* We must do this now in two ways :
* - if there is no app cookie, we simply delete the header ;
* - if there are app cookies, we must delete the end of the
* string properly, including the colon/semi-colon before
* the cookie name.
*/
if (del_cookie != NULL) {
int delta;
if (app_cookies) {
delta = buffer_replace2(req, del_colon, cur_end, NULL, 0);
cur_end = del_colon;
cur_hdr->len += delta;
} else {
delta = buffer_replace2(req, cur_ptr, cur_next, NULL, 0);
/* FIXME: this should be a separate function */
txn->hdr_idx.v[old_idx].next = cur_hdr->next;
txn->hdr_idx.used--;
cur_hdr->len = 0;
}
cur_next += delta;
http_msg_move_end(&txn->req, delta);
}
/* keep the link from this header to next one */
old_idx = cur_idx;
} /* end of cookie processing on this header */
}
/* Iterate the same filter through all response headers contained in <rtr>.
* Returns 1 if this filter can be stopped upon return, otherwise 0.
*/
int apply_filter_to_resp_headers(struct session *t, struct buffer *rtr, struct hdr_exp *exp)
{
char term;
char *cur_ptr, *cur_end, *cur_next;
int cur_idx, old_idx, last_hdr;
struct http_txn *txn = &t->txn;
struct hdr_idx_elem *cur_hdr;
int len, delta;
last_hdr = 0;
cur_next = txn->rsp.sol + hdr_idx_first_pos(&txn->hdr_idx);
old_idx = 0;
while (!last_hdr) {
if (unlikely(txn->flags & TX_SVDENY))
return 1;
else if (unlikely(txn->flags & TX_SVALLOW) &&
(exp->action == ACT_ALLOW ||
exp->action == ACT_DENY))
return 0;
cur_idx = txn->hdr_idx.v[old_idx].next;
if (!cur_idx)
break;
cur_hdr = &txn->hdr_idx.v[cur_idx];
cur_ptr = cur_next;
cur_end = cur_ptr + cur_hdr->len;
cur_next = cur_end + cur_hdr->cr + 1;
/* Now we have one header between cur_ptr and cur_end,
* and the next header starts at cur_next.
*/
/* The annoying part is that pattern matching needs
* that we modify the contents to null-terminate all
* strings before testing them.
*/
term = *cur_end;
*cur_end = '\0';
if (regexec(exp->preg, cur_ptr, MAX_MATCH, pmatch, 0) == 0) {
switch (exp->action) {
case ACT_ALLOW:
txn->flags |= TX_SVALLOW;
last_hdr = 1;
break;
case ACT_DENY:
txn->flags |= TX_SVDENY;
last_hdr = 1;
break;
case ACT_REPLACE:
len = exp_replace(trash, cur_ptr, exp->replace, pmatch);
delta = buffer_replace2(rtr, cur_ptr, cur_end, trash, len);
/* FIXME: if the user adds a newline in the replacement, the
* index will not be recalculated for now, and the new line
* will not be counted as a new header.
*/
cur_end += delta;
cur_next += delta;
cur_hdr->len += delta;
http_msg_move_end(&txn->rsp, delta);
break;
case ACT_REMOVE:
delta = buffer_replace2(rtr, cur_ptr, cur_next, NULL, 0);
cur_next += delta;
http_msg_move_end(&txn->rsp, delta);
txn->hdr_idx.v[old_idx].next = cur_hdr->next;
txn->hdr_idx.used--;
cur_hdr->len = 0;
cur_end = NULL; /* null-term has been rewritten */
break;
}
}
if (cur_end)
*cur_end = term; /* restore the string terminator */
/* keep the link from this header to next one in case of later
* removal of next header.
*/
old_idx = cur_idx;
}
return 0;
}
/* Apply the filter to the status line in the response buffer <rtr>.
* Returns 0 if nothing has been done, 1 if the filter has been applied,
* or -1 if a replacement resulted in an invalid status line.
*/
int apply_filter_to_sts_line(struct session *t, struct buffer *rtr, struct hdr_exp *exp)
{
char term;
char *cur_ptr, *cur_end;
int done;
struct http_txn *txn = &t->txn;
int len, delta;
if (unlikely(txn->flags & TX_SVDENY))
return 1;
else if (unlikely(txn->flags & TX_SVALLOW) &&
(exp->action == ACT_ALLOW ||
exp->action == ACT_DENY))
return 0;
else if (exp->action == ACT_REMOVE)
return 0;
done = 0;
cur_ptr = txn->rsp.sol;
cur_end = cur_ptr + txn->rsp.sl.st.l;
/* Now we have the status line between cur_ptr and cur_end */
/* The annoying part is that pattern matching needs
* that we modify the contents to null-terminate all
* strings before testing them.
*/
term = *cur_end;
*cur_end = '\0';
if (regexec(exp->preg, cur_ptr, MAX_MATCH, pmatch, 0) == 0) {
switch (exp->action) {
case ACT_ALLOW:
txn->flags |= TX_SVALLOW;
done = 1;
break;
case ACT_DENY:
txn->flags |= TX_SVDENY;
done = 1;
break;
case ACT_REPLACE:
*cur_end = term; /* restore the string terminator */
len = exp_replace(trash, cur_ptr, exp->replace, pmatch);
delta = buffer_replace2(rtr, cur_ptr, cur_end, trash, len);
/* FIXME: if the user adds a newline in the replacement, the
* index will not be recalculated for now, and the new line
* will not be counted as a new header.
*/
http_msg_move_end(&txn->rsp, delta);
cur_end += delta;
cur_end = (char *)http_parse_stsline(&txn->rsp, rtr->data,
HTTP_MSG_RPVER,
cur_ptr, cur_end + 1,
NULL, NULL);
if (unlikely(!cur_end))
return -1;
/* we have a full respnse and we know that we have either a CR
* or an LF at <ptr>.
*/
txn->status = strl2ui(txn->rsp.sol + txn->rsp.sl.st.c, txn->rsp.sl.st.c_l);
hdr_idx_set_start(&txn->hdr_idx, txn->rsp.sl.st.l, *cur_end == '\r');
/* there is no point trying this regex on headers */
return 1;
}
}
*cur_end = term; /* restore the string terminator */
return done;
}
/*
* Apply all the resp filters of proxy <px> to all headers in buffer <rtr> of session <s>.
* Returns 0 if everything is alright, or -1 in case a replacement lead to an
* unparsable response.
*/
int apply_filters_to_response(struct session *s, struct buffer *rtr, struct proxy *px)
{
struct http_txn *txn = &s->txn;
struct hdr_exp *exp;
for (exp = px->rsp_exp; exp; exp = exp->next) {
int ret;
/*
* The interleaving of transformations and verdicts
* makes it difficult to decide to continue or stop
* the evaluation.
*/
if (txn->flags & TX_SVDENY)
break;
if ((txn->flags & TX_SVALLOW) &&
(exp->action == ACT_ALLOW || exp->action == ACT_DENY ||
exp->action == ACT_PASS)) {
exp = exp->next;
continue;
}
/* if this filter had a condition, evaluate it now and skip to
* next filter if the condition does not match.
*/
if (exp->cond) {
ret = acl_exec_cond(exp->cond, px, s, txn, ACL_DIR_RTR);
ret = acl_pass(ret);
if (((struct acl_cond *)exp->cond)->pol == ACL_COND_UNLESS)
ret = !ret;
if (!ret)
continue;
}
/* Apply the filter to the status line. */
ret = apply_filter_to_sts_line(s, rtr, exp);
if (unlikely(ret < 0))
return -1;
if (likely(ret == 0)) {
/* The filter did not match the response, it can be
* iterated through all headers.
*/
apply_filter_to_resp_headers(s, rtr, exp);
}
}
return 0;
}
/*
* Manage server-side cookies. It can impact performance by about 2% so it is
* desirable to call it only when needed.
*/
void manage_server_side_cookies(struct session *t, struct buffer *rtr)
{
struct http_txn *txn = &t->txn;
char *p1, *p2, *p3, *p4;
char *cur_ptr, *cur_end, *cur_next;
int cur_idx, old_idx, delta;
/* Iterate through the headers.
* we start with the start line.
*/
old_idx = 0;
cur_next = txn->rsp.sol + hdr_idx_first_pos(&txn->hdr_idx);
while ((cur_idx = txn->hdr_idx.v[old_idx].next)) {
struct hdr_idx_elem *cur_hdr;
int val;
cur_hdr = &txn->hdr_idx.v[cur_idx];
cur_ptr = cur_next;
cur_end = cur_ptr + cur_hdr->len;
cur_next = cur_end + cur_hdr->cr + 1;
/* We have one full header between cur_ptr and cur_end, and the
* next header starts at cur_next. We're only interested in
* "Cookie:" headers.
*/
val = http_header_match2(cur_ptr, cur_end, "Set-Cookie", 10);
if (!val) {
old_idx = cur_idx;
continue;
}
/* OK, right now we know we have a set-cookie at cur_ptr */
txn->flags |= TX_SCK_ANY;
/* maybe we only wanted to see if there was a set-cookie. Note that
* the cookie capture is declared in the fronend.
*/
if (t->be->cookie_name == NULL &&
t->be->appsession_name == NULL &&
t->fe->capture_name == NULL)
return;
p1 = cur_ptr + val; /* first non-space char after 'Set-Cookie:' */
while (p1 < cur_end) { /* in fact, we'll break after the first cookie */
if (p1 == cur_end || *p1 == ';') /* end of cookie */
break;
/* p1 is at the beginning of the cookie name */
p2 = p1;
while (p2 < cur_end && *p2 != '=' && *p2 != ';')
p2++;
if (p2 == cur_end || *p2 == ';') /* next cookie */
break;
p3 = p2 + 1; /* skip the '=' sign */
if (p3 == cur_end)
break;
p4 = p3;
while (p4 < cur_end && !isspace((unsigned char)*p4) && *p4 != ';')
p4++;
/* here, we have the cookie name between p1 and p2,
* and its value between p3 and p4.
* we can process it.
*/
/* first, let's see if we want to capture it */
if (t->fe->capture_name != NULL &&
txn->srv_cookie == NULL &&
(p4 - p1 >= t->fe->capture_namelen) &&
memcmp(p1, t->fe->capture_name, t->fe->capture_namelen) == 0) {
int log_len = p4 - p1;
if ((txn->srv_cookie = pool_alloc2(pool2_capture)) == NULL) {
Alert("HTTP logging : out of memory.\n");
}
if (log_len > t->fe->capture_len)
log_len = t->fe->capture_len;
memcpy(txn->srv_cookie, p1, log_len);
txn->srv_cookie[log_len] = 0;
}
/* now check if we need to process it for persistence */
if (!(t->flags & SN_IGNORE_PRST) && (p2 - p1 == t->be->cookie_len) && (t->be->cookie_name != NULL) &&
(memcmp(p1, t->be->cookie_name, p2 - p1) == 0)) {
/* Cool... it's the right one */
txn->flags |= TX_SCK_SEEN;
/* If the cookie is in insert mode on a known server, we'll delete
* this occurrence because we'll insert another one later.
* We'll delete it too if the "indirect" option is set and we're in
* a direct access. */
if (((t->srv) && (t->be->options & PR_O_COOK_INS)) ||
((t->flags & SN_DIRECT) && (t->be->options & PR_O_COOK_IND))) {
/* this header must be deleted */
delta = buffer_replace2(rtr, cur_ptr, cur_next, NULL, 0);
txn->hdr_idx.v[old_idx].next = cur_hdr->next;
txn->hdr_idx.used--;
cur_hdr->len = 0;
cur_next += delta;
http_msg_move_end(&txn->rsp, delta);
txn->flags |= TX_SCK_DELETED;
}
else if ((t->srv) && (t->srv->cookie) &&
(t->be->options & PR_O_COOK_RW)) {
/* replace bytes p3->p4 with the cookie name associated
* with this server since we know it.
*/
delta = buffer_replace2(rtr, p3, p4, t->srv->cookie, t->srv->cklen);
cur_hdr->len += delta;
cur_next += delta;
http_msg_move_end(&txn->rsp, delta);
txn->flags |= TX_SCK_INSERTED | TX_SCK_DELETED;
}
else if ((t->srv) && (t->srv->cookie) &&
(t->be->options & PR_O_COOK_PFX)) {
/* insert the cookie name associated with this server
* before existing cookie, and insert a delimitor between them..
*/
delta = buffer_replace2(rtr, p3, p3, t->srv->cookie, t->srv->cklen + 1);
cur_hdr->len += delta;
cur_next += delta;
http_msg_move_end(&txn->rsp, delta);
p3[t->srv->cklen] = COOKIE_DELIM;
txn->flags |= TX_SCK_INSERTED | TX_SCK_DELETED;
}
}
/* next, let's see if the cookie is our appcookie, unless persistence must be ignored */
else if (!(t->flags & SN_IGNORE_PRST) && (t->be->appsession_name != NULL)) {
int cmp_len, value_len;
char *value_begin;
if (t->be->options2 & PR_O2_AS_PFX) {
cmp_len = MIN(p4 - p1, t->be->appsession_name_len);
value_begin = p1 + t->be->appsession_name_len;
value_len = MIN(t->be->appsession_len, p4 - p1 - t->be->appsession_name_len);
} else {
cmp_len = p2 - p1;
value_begin = p3;
value_len = MIN(t->be->appsession_len, p4 - p3);
}
if ((cmp_len == t->be->appsession_name_len) &&
(memcmp(p1, t->be->appsession_name, t->be->appsession_name_len) == 0)) {
/* Cool... it's the right one */
if (txn->sessid != NULL) {
/* free previously allocated memory as we don't need it anymore */
pool_free2(apools.sessid, txn->sessid);
}
/* Store the sessid in the session for future use */
if ((txn->sessid = pool_alloc2(apools.sessid)) == NULL) {
Alert("Not enough Memory process_srv():asession->sessid:malloc().\n");
send_log(t->be, LOG_ALERT, "Not enough Memory process_srv():asession->sessid:malloc().\n");
return;
}
memcpy(txn->sessid, value_begin, value_len);
txn->sessid[value_len] = 0;
}
} /* end if ((t->be->appsession_name != NULL) ... */
break; /* we don't want to loop again since there cannot be another cookie on the same line */
} /* we're now at the end of the cookie value */
/* keep the link from this header to next one */
old_idx = cur_idx;
} /* end of cookie processing on this header */
if (txn->sessid != NULL) {
appsess *asession = NULL;
/* only do insert, if lookup fails */
asession = appsession_hash_lookup(&(t->be->htbl_proxy), txn->sessid);
if (asession == NULL) {
size_t server_id_len;
if ((asession = pool_alloc2(pool2_appsess)) == NULL) {
Alert("Not enough Memory process_srv():asession:calloc().\n");
send_log(t->be, LOG_ALERT, "Not enough Memory process_srv():asession:calloc().\n");
return;
}
if ((asession->sessid = pool_alloc2(apools.sessid)) == NULL) {
Alert("Not enough Memory process_srv():asession->sessid:malloc().\n");
send_log(t->be, LOG_ALERT, "Not enough Memory process_srv():asession->sessid:malloc().\n");
t->be->htbl_proxy.destroy(asession);
return;
}
memcpy(asession->sessid, txn->sessid, t->be->appsession_len);
asession->sessid[t->be->appsession_len] = 0;
server_id_len = strlen(t->srv->id) + 1;
if ((asession->serverid = pool_alloc2(apools.serverid)) == NULL) {
Alert("Not enough Memory process_srv():asession->sessid:malloc().\n");
send_log(t->be, LOG_ALERT, "Not enough Memory process_srv():asession->sessid:malloc().\n");
t->be->htbl_proxy.destroy(asession);
return;
}
asession->serverid[0] = '\0';
memcpy(asession->serverid, t->srv->id, server_id_len);
asession->request_count = 0;
appsession_hash_insert(&(t->be->htbl_proxy), asession);
}
asession->expire = tick_add_ifset(now_ms, t->be->timeout.appsession);
asession->request_count++;
}
#if defined(DEBUG_HASH)
if (t->be->appsession_name) {
Alert("manage_server_side_cookies\n");
appsession_hash_dump(&(t->be->htbl_proxy));
}
#endif
}
/*
* Check if response is cacheable or not. Updates t->flags.
*/
void check_response_for_cacheability(struct session *t, struct buffer *rtr)
{
struct http_txn *txn = &t->txn;
char *p1, *p2;
char *cur_ptr, *cur_end, *cur_next;
int cur_idx;
if (!(txn->flags & TX_CACHEABLE))
return;
/* Iterate through the headers.
* we start with the start line.
*/
cur_idx = 0;
cur_next = txn->rsp.sol + hdr_idx_first_pos(&txn->hdr_idx);
while ((cur_idx = txn->hdr_idx.v[cur_idx].next)) {
struct hdr_idx_elem *cur_hdr;
int val;
cur_hdr = &txn->hdr_idx.v[cur_idx];
cur_ptr = cur_next;
cur_end = cur_ptr + cur_hdr->len;
cur_next = cur_end + cur_hdr->cr + 1;
/* We have one full header between cur_ptr and cur_end, and the
* next header starts at cur_next. We're only interested in
* "Cookie:" headers.
*/
val = http_header_match2(cur_ptr, cur_end, "Pragma", 6);
if (val) {
if ((cur_end - (cur_ptr + val) >= 8) &&
strncasecmp(cur_ptr + val, "no-cache", 8) == 0) {
txn->flags &= ~TX_CACHEABLE & ~TX_CACHE_COOK;
return;
}
}
val = http_header_match2(cur_ptr, cur_end, "Cache-control", 13);
if (!val)
continue;
/* OK, right now we know we have a cache-control header at cur_ptr */
p1 = cur_ptr + val; /* first non-space char after 'cache-control:' */
if (p1 >= cur_end) /* no more info */
continue;
/* p1 is at the beginning of the value */
p2 = p1;
while (p2 < cur_end && *p2 != '=' && *p2 != ',' && !isspace((unsigned char)*p2))
p2++;
/* we have a complete value between p1 and p2 */
if (p2 < cur_end && *p2 == '=') {
/* we have something of the form no-cache="set-cookie" */
if ((cur_end - p1 >= 21) &&
strncasecmp(p1, "no-cache=\"set-cookie", 20) == 0
&& (p1[20] == '"' || p1[20] == ','))
txn->flags &= ~TX_CACHE_COOK;
continue;
}
/* OK, so we know that either p2 points to the end of string or to a comma */
if (((p2 - p1 == 7) && strncasecmp(p1, "private", 7) == 0) ||
((p2 - p1 == 8) && strncasecmp(p1, "no-store", 8) == 0) ||
((p2 - p1 == 9) && strncasecmp(p1, "max-age=0", 9) == 0) ||
((p2 - p1 == 10) && strncasecmp(p1, "s-maxage=0", 10) == 0)) {
txn->flags &= ~TX_CACHEABLE & ~TX_CACHE_COOK;
return;
}
if ((p2 - p1 == 6) && strncasecmp(p1, "public", 6) == 0) {
txn->flags |= TX_CACHEABLE | TX_CACHE_COOK;
continue;
}
}
}
/*
* Try to retrieve a known appsession in the URI, then the associated server.
* If the server is found, it's assigned to the session.
*/
void get_srv_from_appsession(struct session *t, const char *begin, int len)
{
char *end_params, *first_param, *cur_param, *next_param;
char separator;
int value_len;
int mode = t->be->options2 & PR_O2_AS_M_ANY;
if (t->be->appsession_name == NULL ||
(t->txn.meth != HTTP_METH_GET && t->txn.meth != HTTP_METH_POST && t->txn.meth != HTTP_METH_HEAD)) {
return;
}
first_param = NULL;
switch (mode) {
case PR_O2_AS_M_PP:
first_param = memchr(begin, ';', len);
break;
case PR_O2_AS_M_QS:
first_param = memchr(begin, '?', len);
break;
}
if (first_param == NULL) {
return;
}
switch (mode) {
case PR_O2_AS_M_PP:
if ((end_params = memchr(first_param, '?', len - (begin - first_param))) == NULL) {
end_params = (char *) begin + len;
}
separator = ';';
break;
case PR_O2_AS_M_QS:
end_params = (char *) begin + len;
separator = '&';
break;
default:
/* unknown mode, shouldn't happen */
return;
}
cur_param = next_param = end_params;
while (cur_param > first_param) {
cur_param--;
if ((cur_param[0] == separator) || (cur_param == first_param)) {
/* let's see if this is the appsession parameter */
if ((cur_param + t->be->appsession_name_len + 1 < next_param) &&
((t->be->options2 & PR_O2_AS_PFX) || cur_param[t->be->appsession_name_len + 1] == '=') &&
(strncasecmp(cur_param + 1, t->be->appsession_name, t->be->appsession_name_len) == 0)) {
/* Cool... it's the right one */
cur_param += t->be->appsession_name_len + (t->be->options2 & PR_O2_AS_PFX ? 1 : 2);
value_len = MIN(t->be->appsession_len, next_param - cur_param);
if (value_len > 0) {
manage_client_side_appsession(t, cur_param, value_len);
}
break;
}
next_param = cur_param;
}
}
#if defined(DEBUG_HASH)
Alert("get_srv_from_appsession\n");
appsession_hash_dump(&(t->be->htbl_proxy));
#endif
}
/*
* In a GET or HEAD request, check if the requested URI matches the stats uri
* for the current backend.
*
* It is assumed that the request is either a HEAD or GET and that the
* t->be->uri_auth field is valid.
*
* Returns 1 if stats should be provided, otherwise 0.
*/
int stats_check_uri(struct session *t, struct proxy *backend)
{
struct http_txn *txn = &t->txn;
struct uri_auth *uri_auth = backend->uri_auth;
char *h;
if (!uri_auth)
return 0;
if (txn->meth != HTTP_METH_GET && txn->meth != HTTP_METH_HEAD)
return 0;
memset(&t->data_ctx.stats, 0, sizeof(t->data_ctx.stats));
/* check URI size */
if (uri_auth->uri_len > txn->req.sl.rq.u_l)
return 0;
h = txn->req.sol + txn->req.sl.rq.u;
/* the URI is in h */
if (memcmp(h, uri_auth->uri_prefix, uri_auth->uri_len) != 0)
return 0;
h += uri_auth->uri_len;
while (h <= txn->req.sol + txn->req.sl.rq.u + txn->req.sl.rq.u_l - 3) {
if (memcmp(h, ";up", 3) == 0) {
t->data_ctx.stats.flags |= STAT_HIDE_DOWN;
break;
}
h++;
}
if (uri_auth->refresh) {
h = txn->req.sol + txn->req.sl.rq.u + uri_auth->uri_len;
while (h <= txn->req.sol + txn->req.sl.rq.u + txn->req.sl.rq.u_l - 10) {
if (memcmp(h, ";norefresh", 10) == 0) {
t->data_ctx.stats.flags |= STAT_NO_REFRESH;
break;
}
h++;
}
}
h = txn->req.sol + txn->req.sl.rq.u + uri_auth->uri_len;
while (h <= txn->req.sol + txn->req.sl.rq.u + txn->req.sl.rq.u_l - 4) {
if (memcmp(h, ";csv", 4) == 0) {
t->data_ctx.stats.flags |= STAT_FMT_CSV;
break;
}
h++;
}
t->data_ctx.stats.flags |= STAT_SHOW_STAT | STAT_SHOW_INFO;
return 1;
}
/*
* Capture a bad request or response and archive it in the proxy's structure.
* WARNING: it's unlikely that we've reached HTTP_MSG_BODY here so we must not
* assume that msg->sol = buf->data + msg->som.
*/
void http_capture_bad_message(struct error_snapshot *es, struct session *s,
struct buffer *buf, struct http_msg *msg,
struct proxy *other_end)
{
es->len = buf->r - (buf->data + msg->som);
memcpy(es->buf, buf->data + msg->som, MIN(es->len, sizeof(es->buf)));
if (msg->err_pos >= 0)
es->pos = msg->err_pos - msg->som;
else
es->pos = buf->lr - (buf->data + msg->som);
es->when = date; // user-visible date
es->sid = s->uniq_id;
es->srv = s->srv;
es->oe = other_end;
es->src = s->cli_addr;
}
/* return the IP address pointed to by occurrence <occ> of header <hname> in
* HTTP message <msg> indexed in <idx>. If <occ> is strictly positive, the
* occurrence number corresponding to this value is returned. If <occ> is
* strictly negative, the occurrence number before the end corresponding to
* this value is returned. If <occ> is null, any value is returned, so it is
* not recommended to use it that way. Negative occurrences are limited to
* a small value because it is required to keep them in memory while scanning.
* IP address 0.0.0.0 is returned if no match is found.
*/
unsigned int get_ip_from_hdr2(struct http_msg *msg, const char *hname, int hlen, struct hdr_idx *idx, int occ)
{
struct hdr_ctx ctx;
unsigned int hdr_hist[MAX_HDR_HISTORY];
unsigned int hist_ptr;
int found = 0;
ctx.idx = 0;
if (occ >= 0) {
while (http_find_header2(hname, hlen, msg->sol, idx, &ctx)) {
occ--;
if (occ <= 0) {
found = 1;
break;
}
}
if (!found)
return 0;
return inetaddr_host_lim(ctx.line+ctx.val, ctx.line+ctx.val+ctx.vlen);
}
/* negative occurrence, we scan all the list then walk back */
if (-occ > MAX_HDR_HISTORY)
return 0;
hist_ptr = 0;
hdr_hist[hist_ptr] = 0;
while (http_find_header2(hname, hlen, msg->sol, idx, &ctx)) {
hdr_hist[hist_ptr++] = inetaddr_host_lim(ctx.line+ctx.val, ctx.line+ctx.val+ctx.vlen);
if (hist_ptr >= MAX_HDR_HISTORY)
hist_ptr = 0;
found++;
}
if (-occ > found)
return 0;
/* OK now we have the last occurrence in [hist_ptr-1], and we need to
* find occurrence -occ, so we have to check [hist_ptr+occ].
*/
hist_ptr += occ;
if (hist_ptr >= MAX_HDR_HISTORY)
hist_ptr -= MAX_HDR_HISTORY;
return hdr_hist[hist_ptr];
}
/*
* Print a debug line with a header
*/
void debug_hdr(const char *dir, struct session *t, const char *start, const char *end)
{
int len, max;
len = sprintf(trash, "%08x:%s.%s[%04x:%04x]: ", t->uniq_id, t->be->id,
dir, (unsigned short)t->req->prod->fd, (unsigned short)t->req->cons->fd);
max = end - start;
UBOUND(max, sizeof(trash) - len - 1);
len += strlcpy2(trash + len, start, max + 1);
trash[len++] = '\n';
write(1, trash, len);
}
/*
* Initialize a new HTTP transaction for session <s>. It is assumed that all
* the required fields are properly allocated and that we only need to (re)init
* them. This should be used before processing any new request.
*/
void http_init_txn(struct session *s)
{
struct http_txn *txn = &s->txn;
struct proxy *fe = s->fe;
txn->flags = 0;
txn->status = -1;
txn->req.sol = txn->req.eol = NULL;
txn->req.som = txn->req.eoh = 0; /* relative to the buffer */
txn->rsp.sol = txn->rsp.eol = NULL;
txn->rsp.som = txn->rsp.eoh = 0; /* relative to the buffer */
txn->req.hdr_content_len = 0LL;
txn->rsp.hdr_content_len = 0LL;
txn->req.msg_state = HTTP_MSG_RQBEFORE; /* at the very beginning of the request */
txn->rsp.msg_state = HTTP_MSG_RPBEFORE; /* at the very beginning of the response */
txn->auth.method = HTTP_AUTH_UNKNOWN;
txn->req.err_pos = txn->rsp.err_pos = -2; /* block buggy requests/responses */
if (fe->options2 & PR_O2_REQBUG_OK)
txn->req.err_pos = -1; /* let buggy requests pass */
if (txn->req.cap)
memset(txn->req.cap, 0, fe->nb_req_cap * sizeof(void *));
if (txn->rsp.cap)
memset(txn->rsp.cap, 0, fe->nb_rsp_cap * sizeof(void *));
if (txn->hdr_idx.v)
hdr_idx_init(&txn->hdr_idx);
}
/* to be used at the end of a transaction */
void http_end_txn(struct session *s)
{
struct http_txn *txn = &s->txn;
/* these ones will have been dynamically allocated */
pool_free2(pool2_requri, txn->uri);
pool_free2(pool2_capture, txn->cli_cookie);
pool_free2(pool2_capture, txn->srv_cookie);
pool_free2(apools.sessid, txn->sessid);
txn->sessid = NULL;
txn->uri = NULL;
txn->srv_cookie = NULL;
txn->cli_cookie = NULL;
if (txn->req.cap) {
struct cap_hdr *h;
for (h = s->fe->req_cap; h; h = h->next)
pool_free2(h->pool, txn->req.cap[h->index]);
memset(txn->req.cap, 0, s->fe->nb_req_cap * sizeof(void *));
}
if (txn->rsp.cap) {
struct cap_hdr *h;
for (h = s->fe->rsp_cap; h; h = h->next)
pool_free2(h->pool, txn->rsp.cap[h->index]);
memset(txn->rsp.cap, 0, s->fe->nb_rsp_cap * sizeof(void *));
}
}
/* to be used at the end of a transaction to prepare a new one */
void http_reset_txn(struct session *s)
{
http_end_txn(s);
http_init_txn(s);
s->be = s->fe;
s->req->analysers = s->listener->analysers;
s->logs.logwait = s->fe->to_log;
s->srv = s->prev_srv = s->srv_conn = NULL;
/* re-init store persistence */
s->store_count = 0;
s->pend_pos = NULL;
s->req->flags |= BF_READ_DONTWAIT; /* one read is usually enough */
/* We must trim any excess data from the response buffer, because we
* may have blocked an invalid response from a server that we don't
* want to accidentely forward once we disable the analysers, nor do
* we want those data to come along with next response. A typical
* example of such data would be from a buggy server responding to
* a HEAD with some data, or sending more than the advertised
* content-length.
*/
if (unlikely(s->rep->l > s->rep->send_max)) {
s->rep->l = s->rep->send_max;
s->rep->r = s->rep->w + s->rep->l;
if (s->rep->r >= s->rep->data + s->rep->size)
s->rep->r -= s->rep->size;
}
s->req->rto = s->fe->timeout.client;
s->req->wto = TICK_ETERNITY;
s->rep->rto = TICK_ETERNITY;
s->rep->wto = s->fe->timeout.client;
s->req->rex = TICK_ETERNITY;
s->req->wex = TICK_ETERNITY;
s->req->analyse_exp = TICK_ETERNITY;
s->rep->rex = TICK_ETERNITY;
s->rep->wex = TICK_ETERNITY;
s->rep->analyse_exp = TICK_ETERNITY;
}
/************************************************************************/
/* The code below is dedicated to ACL parsing and matching */
/************************************************************************/
/* 1. Check on METHOD
* We use the pre-parsed method if it is known, and store its number as an
* integer. If it is unknown, we use the pointer and the length.
*/
static int acl_parse_meth(const char **text, struct acl_pattern *pattern, int *opaque)
{
int len, meth;
len = strlen(*text);
meth = find_http_meth(*text, len);
pattern->val.i = meth;
if (meth == HTTP_METH_OTHER) {
pattern->ptr.str = strdup(*text);
if (!pattern->ptr.str)
return 0;
pattern->len = len;
}
return 1;
}
static int
acl_fetch_meth(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
int meth;
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
meth = txn->meth;
test->i = meth;
if (meth == HTTP_METH_OTHER) {
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
test->len = txn->req.sl.rq.m_l;
test->ptr = txn->req.sol;
}
test->flags = ACL_TEST_F_READ_ONLY | ACL_TEST_F_VOL_1ST;
return 1;
}
static int acl_match_meth(struct acl_test *test, struct acl_pattern *pattern)
{
int icase;
if (test->i != pattern->val.i)
return ACL_PAT_FAIL;
if (test->i != HTTP_METH_OTHER)
return ACL_PAT_PASS;
/* Other method, we must compare the strings */
if (pattern->len != test->len)
return ACL_PAT_FAIL;
icase = pattern->flags & ACL_PAT_F_IGNORE_CASE;
if ((icase && strncasecmp(pattern->ptr.str, test->ptr, test->len) != 0) ||
(!icase && strncmp(pattern->ptr.str, test->ptr, test->len) != 0))
return ACL_PAT_FAIL;
return ACL_PAT_PASS;
}
/* 2. Check on Request/Status Version
* We simply compare strings here.
*/
static int acl_parse_ver(const char **text, struct acl_pattern *pattern, int *opaque)
{
pattern->ptr.str = strdup(*text);
if (!pattern->ptr.str)
return 0;
pattern->len = strlen(*text);
return 1;
}
static int
acl_fetch_rqver(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
char *ptr;
int len;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
len = txn->req.sl.rq.v_l;
ptr = txn->req.sol + txn->req.sl.rq.v;
while ((len-- > 0) && (*ptr++ != '/'));
if (len <= 0)
return 0;
test->ptr = ptr;
test->len = len;
test->flags = ACL_TEST_F_READ_ONLY | ACL_TEST_F_VOL_1ST;
return 1;
}
static int
acl_fetch_stver(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
char *ptr;
int len;
if (!txn)
return 0;
if (txn->rsp.msg_state < HTTP_MSG_BODY)
return 0;
len = txn->rsp.sl.st.v_l;
ptr = txn->rsp.sol;
while ((len-- > 0) && (*ptr++ != '/'));
if (len <= 0)
return 0;
test->ptr = ptr;
test->len = len;
test->flags = ACL_TEST_F_READ_ONLY | ACL_TEST_F_VOL_1ST;
return 1;
}
/* 3. Check on Status Code. We manipulate integers here. */
static int
acl_fetch_stcode(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
char *ptr;
int len;
if (!txn)
return 0;
if (txn->rsp.msg_state < HTTP_MSG_BODY)
return 0;
len = txn->rsp.sl.st.c_l;
ptr = txn->rsp.sol + txn->rsp.sl.st.c;
test->i = __strl2ui(ptr, len);
test->flags = ACL_TEST_F_VOL_1ST;
return 1;
}
/* 4. Check on URL/URI. A pointer to the URI is stored. */
static int
acl_fetch_url(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
test->len = txn->req.sl.rq.u_l;
test->ptr = txn->req.sol + txn->req.sl.rq.u;
/* we do not need to set READ_ONLY because the data is in a buffer */
test->flags = ACL_TEST_F_VOL_1ST;
return 1;
}
static int
acl_fetch_url_ip(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
/* Parse HTTP request */
url2sa(txn->req.sol + txn->req.sl.rq.u, txn->req.sl.rq.u_l, &l4->srv_addr);
test->ptr = (void *)&((struct sockaddr_in *)&l4->srv_addr)->sin_addr;
test->i = AF_INET;
/*
* If we are parsing url in frontend space, we prepare backend stage
* to not parse again the same url ! optimization lazyness...
*/
if (px->options & PR_O_HTTP_PROXY)
l4->flags |= SN_ADDR_SET;
test->flags = ACL_TEST_F_READ_ONLY;
return 1;
}
static int
acl_fetch_url_port(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
/* Same optimization as url_ip */
url2sa(txn->req.sol + txn->req.sl.rq.u, txn->req.sl.rq.u_l, &l4->srv_addr);
test->i = ntohs(((struct sockaddr_in *)&l4->srv_addr)->sin_port);
if (px->options & PR_O_HTTP_PROXY)
l4->flags |= SN_ADDR_SET;
test->flags = ACL_TEST_F_READ_ONLY;
return 1;
}
/* 5. Check on HTTP header. A pointer to the beginning of the value is returned.
* This generic function is used by both acl_fetch_chdr() and acl_fetch_shdr().
*/
static int
acl_fetch_hdr(struct proxy *px, struct session *l4, void *l7, char *sol,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
struct hdr_idx *idx = &txn->hdr_idx;
struct hdr_ctx *ctx = (struct hdr_ctx *)test->ctx.a;
if (!txn)
return 0;
if (!(test->flags & ACL_TEST_F_FETCH_MORE))
/* search for header from the beginning */
ctx->idx = 0;
if (http_find_header2(expr->arg.str, expr->arg_len, sol, idx, ctx)) {
test->flags |= ACL_TEST_F_FETCH_MORE;
test->flags |= ACL_TEST_F_VOL_HDR;
test->len = ctx->vlen;
test->ptr = (char *)ctx->line + ctx->val;
return 1;
}
test->flags &= ~ACL_TEST_F_FETCH_MORE;
test->flags |= ACL_TEST_F_VOL_HDR;
return 0;
}
static int
acl_fetch_chdr(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
return acl_fetch_hdr(px, l4, txn, txn->req.sol, expr, test);
}
static int
acl_fetch_shdr(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->rsp.msg_state < HTTP_MSG_BODY)
return 0;
return acl_fetch_hdr(px, l4, txn, txn->rsp.sol, expr, test);
}
/* 6. Check on HTTP header count. The number of occurrences is returned.
* This generic function is used by both acl_fetch_chdr* and acl_fetch_shdr*.
*/
static int
acl_fetch_hdr_cnt(struct proxy *px, struct session *l4, void *l7, char *sol,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
struct hdr_idx *idx = &txn->hdr_idx;
struct hdr_ctx ctx;
int cnt;
if (!txn)
return 0;
ctx.idx = 0;
cnt = 0;
while (http_find_header2(expr->arg.str, expr->arg_len, sol, idx, &ctx))
cnt++;
test->i = cnt;
test->flags = ACL_TEST_F_VOL_HDR;
return 1;
}
static int
acl_fetch_chdr_cnt(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
return acl_fetch_hdr_cnt(px, l4, txn, txn->req.sol, expr, test);
}
static int
acl_fetch_shdr_cnt(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->rsp.msg_state < HTTP_MSG_BODY)
return 0;
return acl_fetch_hdr_cnt(px, l4, txn, txn->rsp.sol, expr, test);
}
/* 7. Check on HTTP header's integer value. The integer value is returned.
* FIXME: the type is 'int', it may not be appropriate for everything.
* This generic function is used by both acl_fetch_chdr* and acl_fetch_shdr*.
*/
static int
acl_fetch_hdr_val(struct proxy *px, struct session *l4, void *l7, char *sol,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
struct hdr_idx *idx = &txn->hdr_idx;
struct hdr_ctx *ctx = (struct hdr_ctx *)test->ctx.a;
if (!txn)
return 0;
if (!(test->flags & ACL_TEST_F_FETCH_MORE))
/* search for header from the beginning */
ctx->idx = 0;
if (http_find_header2(expr->arg.str, expr->arg_len, sol, idx, ctx)) {
test->flags |= ACL_TEST_F_FETCH_MORE;
test->flags |= ACL_TEST_F_VOL_HDR;
test->i = strl2ic((char *)ctx->line + ctx->val, ctx->vlen);
return 1;
}
test->flags &= ~ACL_TEST_F_FETCH_MORE;
test->flags |= ACL_TEST_F_VOL_HDR;
return 0;
}
static int
acl_fetch_chdr_val(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
return acl_fetch_hdr_val(px, l4, txn, txn->req.sol, expr, test);
}
static int
acl_fetch_shdr_val(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->rsp.msg_state < HTTP_MSG_BODY)
return 0;
return acl_fetch_hdr_val(px, l4, txn, txn->rsp.sol, expr, test);
}
/* 7. Check on HTTP header's IPv4 address value. The IPv4 address is returned.
* This generic function is used by both acl_fetch_chdr* and acl_fetch_shdr*.
*/
static int
acl_fetch_hdr_ip(struct proxy *px, struct session *l4, void *l7, char *sol,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
struct hdr_idx *idx = &txn->hdr_idx;
struct hdr_ctx *ctx = (struct hdr_ctx *)test->ctx.a;
if (!txn)
return 0;
if (!(test->flags & ACL_TEST_F_FETCH_MORE))
/* search for header from the beginning */
ctx->idx = 0;
if (http_find_header2(expr->arg.str, expr->arg_len, sol, idx, ctx)) {
test->flags |= ACL_TEST_F_FETCH_MORE;
test->flags |= ACL_TEST_F_VOL_HDR;
/* Same optimization as url_ip */
memset(&l4->srv_addr.sin_addr, 0, sizeof(l4->srv_addr.sin_addr));
url2ip((char *)ctx->line + ctx->val, &l4->srv_addr.sin_addr);
test->ptr = (void *)&l4->srv_addr.sin_addr;
test->i = AF_INET;
return 1;
}
test->flags &= ~ACL_TEST_F_FETCH_MORE;
test->flags |= ACL_TEST_F_VOL_HDR;
return 0;
}
static int
acl_fetch_chdr_ip(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
return acl_fetch_hdr_ip(px, l4, txn, txn->req.sol, expr, test);
}
static int
acl_fetch_shdr_ip(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
if (!txn)
return 0;
if (txn->rsp.msg_state < HTTP_MSG_BODY)
return 0;
return acl_fetch_hdr_ip(px, l4, txn, txn->rsp.sol, expr, test);
}
/* 8. Check on URI PATH. A pointer to the PATH is stored. The path starts at
* the first '/' after the possible hostname, and ends before the possible '?'.
*/
static int
acl_fetch_path(struct proxy *px, struct session *l4, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct http_txn *txn = l7;
char *ptr, *end;
if (!txn)
return 0;
if (txn->req.msg_state < HTTP_MSG_BODY)
return 0;
if (txn->rsp.msg_state != HTTP_MSG_RPBEFORE)
/* ensure the indexes are not affected */
return 0;
end = txn->req.sol + txn->req.sl.rq.u + txn->req.sl.rq.u_l;
ptr = http_get_path(txn);
if (!ptr)
return 0;
/* OK, we got the '/' ! */
test->ptr = ptr;
while (ptr < end && *ptr != '?')
ptr++;
test->len = ptr - test->ptr;
/* we do not need to set READ_ONLY because the data is in a buffer */
test->flags = ACL_TEST_F_VOL_1ST;
return 1;
}
static int
acl_fetch_proto_http(struct proxy *px, struct session *s, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
struct buffer *req = s->req;
struct http_txn *txn = &s->txn;
struct http_msg *msg = &txn->req;
/* Note: hdr_idx.v cannot be NULL in this ACL because the ACL is tagged
* as a layer7 ACL, which involves automatic allocation of hdr_idx.
*/
if (!s || !req)
return 0;
if (unlikely(msg->msg_state >= HTTP_MSG_BODY)) {
/* Already decoded as OK */
test->flags |= ACL_TEST_F_SET_RES_PASS;
return 1;
}
/* Try to decode HTTP request */
if (likely(req->lr < req->r))
http_msg_analyzer(req, msg, &txn->hdr_idx);
if (unlikely(msg->msg_state < HTTP_MSG_BODY)) {
if ((msg->msg_state == HTTP_MSG_ERROR) || (req->flags & BF_FULL)) {
test->flags |= ACL_TEST_F_SET_RES_FAIL;
return 1;
}
/* wait for final state */
test->flags |= ACL_TEST_F_MAY_CHANGE;
return 0;
}
/* OK we got a valid HTTP request. We have some minor preparation to
* perform so that further checks can rely on HTTP tests.
*/
txn->meth = find_http_meth(msg->sol, msg->sl.rq.m_l);
if (txn->meth == HTTP_METH_GET || txn->meth == HTTP_METH_HEAD)
s->flags |= SN_REDIRECTABLE;
if (unlikely(msg->sl.rq.v_l == 0) && !http_upgrade_v09_to_v10(req, msg, txn)) {
test->flags |= ACL_TEST_F_SET_RES_FAIL;
return 1;
}
test->flags |= ACL_TEST_F_SET_RES_PASS;
return 1;
}
static int
acl_fetch_http_auth(struct proxy *px, struct session *s, void *l7, int dir,
struct acl_expr *expr, struct acl_test *test)
{
if (!s)
return 0;
if (!get_http_auth(s))
return 0;
test->ctx.a[0] = expr->arg.ul;
test->ctx.a[1] = s->txn.auth.user;
test->ctx.a[2] = s->txn.auth.pass;
test->flags |= ACL_TEST_F_READ_ONLY | ACL_TEST_F_NULL_MATCH;
return 1;
}
/************************************************************************/
/* All supported keywords must be declared here. */
/************************************************************************/
/* Note: must not be declared <const> as its list will be overwritten */
static struct acl_kw_list acl_kws = {{ },{
{ "req_proto_http", acl_parse_nothing, acl_fetch_proto_http, acl_match_nothing, ACL_USE_L7REQ_PERMANENT },
{ "method", acl_parse_meth, acl_fetch_meth, acl_match_meth, ACL_USE_L7REQ_PERMANENT },
{ "req_ver", acl_parse_ver, acl_fetch_rqver, acl_match_str, ACL_USE_L7REQ_VOLATILE|ACL_MAY_LOOKUP },
{ "resp_ver", acl_parse_ver, acl_fetch_stver, acl_match_str, ACL_USE_L7RTR_VOLATILE|ACL_MAY_LOOKUP },
{ "status", acl_parse_int, acl_fetch_stcode, acl_match_int, ACL_USE_L7RTR_PERMANENT },
{ "url", acl_parse_str, acl_fetch_url, acl_match_str, ACL_USE_L7REQ_VOLATILE|ACL_MAY_LOOKUP },
{ "url_beg", acl_parse_str, acl_fetch_url, acl_match_beg, ACL_USE_L7REQ_VOLATILE },
{ "url_end", acl_parse_str, acl_fetch_url, acl_match_end, ACL_USE_L7REQ_VOLATILE },
{ "url_sub", acl_parse_str, acl_fetch_url, acl_match_sub, ACL_USE_L7REQ_VOLATILE },
{ "url_dir", acl_parse_str, acl_fetch_url, acl_match_dir, ACL_USE_L7REQ_VOLATILE },
{ "url_dom", acl_parse_str, acl_fetch_url, acl_match_dom, ACL_USE_L7REQ_VOLATILE },
{ "url_reg", acl_parse_reg, acl_fetch_url, acl_match_reg, ACL_USE_L7REQ_VOLATILE },
{ "url_ip", acl_parse_ip, acl_fetch_url_ip, acl_match_ip, ACL_USE_L7REQ_VOLATILE|ACL_MAY_LOOKUP },
{ "url_port", acl_parse_int, acl_fetch_url_port, acl_match_int, ACL_USE_L7REQ_VOLATILE },
/* note: we should set hdr* to use ACL_USE_HDR_VOLATILE, and chdr* to use L7REQ_VOLATILE */
{ "hdr", acl_parse_str, acl_fetch_chdr, acl_match_str, ACL_USE_L7REQ_VOLATILE|ACL_MAY_LOOKUP },
{ "hdr_reg", acl_parse_reg, acl_fetch_chdr, acl_match_reg, ACL_USE_L7REQ_VOLATILE },
{ "hdr_beg", acl_parse_str, acl_fetch_chdr, acl_match_beg, ACL_USE_L7REQ_VOLATILE },
{ "hdr_end", acl_parse_str, acl_fetch_chdr, acl_match_end, ACL_USE_L7REQ_VOLATILE },
{ "hdr_sub", acl_parse_str, acl_fetch_chdr, acl_match_sub, ACL_USE_L7REQ_VOLATILE },
{ "hdr_dir", acl_parse_str, acl_fetch_chdr, acl_match_dir, ACL_USE_L7REQ_VOLATILE },
{ "hdr_dom", acl_parse_str, acl_fetch_chdr, acl_match_dom, ACL_USE_L7REQ_VOLATILE },
{ "hdr_cnt", acl_parse_int, acl_fetch_chdr_cnt,acl_match_int, ACL_USE_L7REQ_VOLATILE },
{ "hdr_val", acl_parse_int, acl_fetch_chdr_val,acl_match_int, ACL_USE_L7REQ_VOLATILE },
{ "hdr_ip", acl_parse_ip, acl_fetch_chdr_ip, acl_match_ip, ACL_USE_L7REQ_VOLATILE|ACL_MAY_LOOKUP },
{ "shdr", acl_parse_str, acl_fetch_shdr, acl_match_str, ACL_USE_L7RTR_VOLATILE|ACL_MAY_LOOKUP },
{ "shdr_reg", acl_parse_reg, acl_fetch_shdr, acl_match_reg, ACL_USE_L7RTR_VOLATILE },
{ "shdr_beg", acl_parse_str, acl_fetch_shdr, acl_match_beg, ACL_USE_L7RTR_VOLATILE },
{ "shdr_end", acl_parse_str, acl_fetch_shdr, acl_match_end, ACL_USE_L7RTR_VOLATILE },
{ "shdr_sub", acl_parse_str, acl_fetch_shdr, acl_match_sub, ACL_USE_L7RTR_VOLATILE },
{ "shdr_dir", acl_parse_str, acl_fetch_shdr, acl_match_dir, ACL_USE_L7RTR_VOLATILE },
{ "shdr_dom", acl_parse_str, acl_fetch_shdr, acl_match_dom, ACL_USE_L7RTR_VOLATILE },
{ "shdr_cnt", acl_parse_int, acl_fetch_shdr_cnt,acl_match_int, ACL_USE_L7RTR_VOLATILE },
{ "shdr_val", acl_parse_int, acl_fetch_shdr_val,acl_match_int, ACL_USE_L7RTR_VOLATILE },
{ "shdr_ip", acl_parse_ip, acl_fetch_shdr_ip, acl_match_ip, ACL_USE_L7RTR_VOLATILE|ACL_MAY_LOOKUP },
{ "path", acl_parse_str, acl_fetch_path, acl_match_str, ACL_USE_L7REQ_VOLATILE|ACL_MAY_LOOKUP },
{ "path_reg", acl_parse_reg, acl_fetch_path, acl_match_reg, ACL_USE_L7REQ_VOLATILE },
{ "path_beg", acl_parse_str, acl_fetch_path, acl_match_beg, ACL_USE_L7REQ_VOLATILE },
{ "path_end", acl_parse_str, acl_fetch_path, acl_match_end, ACL_USE_L7REQ_VOLATILE },
{ "path_sub", acl_parse_str, acl_fetch_path, acl_match_sub, ACL_USE_L7REQ_VOLATILE },
{ "path_dir", acl_parse_str, acl_fetch_path, acl_match_dir, ACL_USE_L7REQ_VOLATILE },
{ "path_dom", acl_parse_str, acl_fetch_path, acl_match_dom, ACL_USE_L7REQ_VOLATILE },
#if 0
{ "line", acl_parse_str, acl_fetch_line, acl_match_str },
{ "line_reg", acl_parse_reg, acl_fetch_line, acl_match_reg },
{ "line_beg", acl_parse_str, acl_fetch_line, acl_match_beg },
{ "line_end", acl_parse_str, acl_fetch_line, acl_match_end },
{ "line_sub", acl_parse_str, acl_fetch_line, acl_match_sub },
{ "line_dir", acl_parse_str, acl_fetch_line, acl_match_dir },
{ "line_dom", acl_parse_str, acl_fetch_line, acl_match_dom },
{ "cook", acl_parse_str, acl_fetch_cook, acl_match_str },
{ "cook_reg", acl_parse_reg, acl_fetch_cook, acl_match_reg },
{ "cook_beg", acl_parse_str, acl_fetch_cook, acl_match_beg },
{ "cook_end", acl_parse_str, acl_fetch_cook, acl_match_end },
{ "cook_sub", acl_parse_str, acl_fetch_cook, acl_match_sub },
{ "cook_dir", acl_parse_str, acl_fetch_cook, acl_match_dir },
{ "cook_dom", acl_parse_str, acl_fetch_cook, acl_match_dom },
{ "cook_pst", acl_parse_none, acl_fetch_cook, acl_match_pst },
#endif
{ "http_auth", acl_parse_nothing, acl_fetch_http_auth, acl_match_auth },
{ "http_auth_group", acl_parse_strcat, acl_fetch_http_auth, acl_match_auth },
{ NULL, NULL, NULL, NULL },
}};
/************************************************************************/
/* The code below is dedicated to pattern fetching and matching */
/************************************************************************/
/* extract the IP address from the last occurrence of specified header. Note
* that we should normally first extract the string then convert it to IP,
* but right now we have all the functions to do this seemlessly, and we will
* be able to change that later without touching the configuration.
*/
static int
pattern_fetch_hdr_ip(struct proxy *px, struct session *l4, void *l7, int dir,
const char *arg, int arg_len, union pattern_data *data)
{
struct http_txn *txn = l7;
data->ip.s_addr = htonl(get_ip_from_hdr2(&txn->req, arg, arg_len, &txn->hdr_idx, -1));
return data->ip.s_addr != 0;
}
/************************************************************************/
/* All supported keywords must be declared here. */
/************************************************************************/
/* Note: must not be declared <const> as its list will be overwritten */
static struct pattern_fetch_kw_list pattern_fetch_keywords = {{ },{
{ "hdr", pattern_fetch_hdr_ip, PATTERN_TYPE_IP, PATTERN_FETCH_REQ },
{ NULL, NULL, 0, 0 },
}};
__attribute__((constructor))
static void __http_protocol_init(void)
{
acl_register_keywords(&acl_kws);
pattern_register_fetches(&pattern_fetch_keywords);
}
/*
* Local variables:
* c-indent-level: 8
* c-basic-offset: 8
* End:
*/