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git01.mediatek.com / haproxy / be508f158077cab6ed65581cd0e66d5908cf61da / . / src / flt_http_comp.c
blob: 6bbf6a1a14bdf295cc80115150f8bc104e28f6e0 [file] [log] [blame]
/*
* Stream filters related variables and functions.
*
* Copyright (C) 2015 Qualys Inc., Christopher Faulet <cfaulet@qualys.com>
*
* 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 <common/buffer.h>
#include <common/cfgparse.h>
#include <common/mini-clist.h>
#include <common/standard.h>
#include <types/compression.h>
#include <types/filters.h>
#include <types/proto_http.h>
#include <types/proxy.h>
#include <types/sample.h>
#include <proto/compression.h>
#include <proto/filters.h>
#include <proto/hdr_idx.h>
#include <proto/proto_http.h>
#include <proto/sample.h>
#include <proto/stream.h>
static const char *http_comp_flt_id = "compression filter";
struct flt_ops comp_ops;
static struct buffer *tmpbuf = &buf_empty;
static struct buffer *zbuf = &buf_empty;
struct comp_state {
struct comp_ctx *comp_ctx; /* compression context */
struct comp_algo *comp_algo; /* compression algorithm if not NULL */
int hdrs_len;
int tlrs_len;
int consumed;
int initialized;
int finished;
};
static int select_compression_request_header(struct comp_state *st,
struct stream *s,
struct http_msg *msg);
static int select_compression_response_header(struct comp_state *st,
struct stream *s,
struct http_msg *msg);
static int http_compression_buffer_init(struct buffer *in, struct buffer *out);
static int http_compression_buffer_add_data(struct comp_state *st,
struct buffer *in,
struct buffer *out, int sz);
static int http_compression_buffer_end(struct comp_state *st, struct stream *s,
struct buffer **in, struct buffer **out,
int end);
/***********************************************************************/
static int
comp_flt_init(struct proxy *px, struct flt_conf *fconf)
{
if (!tmpbuf->size && b_alloc(&tmpbuf) == NULL)
return -1;
if (!zbuf->size && b_alloc(&zbuf) == NULL)
return -1;
return 0;
}
static void
comp_flt_deinit(struct proxy *px, struct flt_conf *fconf)
{
if (tmpbuf->size)
b_free(&tmpbuf);
if (zbuf->size)
b_free(&zbuf);
}
static int
comp_start_analyze(struct stream *s, struct filter *filter, struct channel *chn)
{
if (filter->ctx == NULL) {
struct comp_state *st;
if (!(st = malloc(sizeof(*st))))
return -1;
st->comp_algo = NULL;
st->comp_ctx = NULL;
st->hdrs_len = 0;
st->tlrs_len = 0;
st->consumed = 0;
st->initialized = 0;
st->finished = 0;
filter->ctx = st;
}
return 1;
}
static int
comp_analyze(struct stream *s, struct filter *filter, struct channel *chn,
unsigned int an_bit)
{
struct comp_state *st = filter->ctx;
if (!strm_fe(s)->comp && !s->be->comp)
goto end;
if (an_bit == AN_FLT_HTTP_HDRS) {
if (!(chn->flags & CF_ISRESP))
select_compression_request_header(st, s, &s->txn->req);
else {
select_compression_response_header(st, s, &s->txn->rsp);
if (st->comp_algo) {
register_data_filter(s, chn, filter);
st->hdrs_len = s->txn->rsp.sov;
}
}
}
end:
return 1;
}
static int
comp_end_analyze(struct stream *s, struct filter *filter, struct channel *chn)
{
struct comp_state *st = filter->ctx;
if (!st || !(chn->flags & CF_ISRESP))
goto end;
if (!st->comp_algo || !s->txn->status)
goto release_ctx;
if (strm_fe(s)->mode == PR_MODE_HTTP)
strm_fe(s)->fe_counters.p.http.comp_rsp++;
if ((s->flags & SF_BE_ASSIGNED) && (s->be->mode == PR_MODE_HTTP))
s->be->be_counters.p.http.comp_rsp++;
/* release any possible compression context */
st->comp_algo->end(&st->comp_ctx);
release_ctx:
free(st);
filter->ctx = NULL;
end:
return 1;
}
static int
comp_http_data(struct stream *s, struct filter *filter, struct http_msg *msg)
{
struct comp_state *st = filter->ctx;
struct buffer *buf = msg->chn->buf;
unsigned int *nxt = &flt_rsp_nxt(filter);
unsigned int len;
int ret;
len = MIN(msg->chunk_len + msg->next, buf->i) - *nxt;
if (!len)
return len;
if (!st->initialized) {
unsigned int fwd = flt_rsp_fwd(filter) + st->hdrs_len;
b_reset(tmpbuf);
b_adv(buf, fwd);
ret = http_compression_buffer_init(buf, zbuf);
b_rew(buf, fwd);
if (ret < 0) {
msg->chn->flags |= CF_WAKE_WRITE;
return 0;
}
}
if (msg->flags & HTTP_MSGF_TE_CHNK) {
int block = bi_contig_data(buf);
len = MIN(tmpbuf->size - buffer_len(tmpbuf), len);
if (len > block) {
memcpy(bi_end(tmpbuf), b_ptr(buf, *nxt), block);
memcpy(bi_end(tmpbuf)+block, buf->data, len - block);
}
else
memcpy(bi_end(tmpbuf), b_ptr(buf, *nxt), len);
tmpbuf->i += len;
ret = len;
}
else {
b_adv(buf, *nxt);
ret = http_compression_buffer_add_data(st, buf, zbuf, len);
b_rew(buf, *nxt);
if (ret < 0)
return ret;
}
st->initialized = 1;
msg->next += ret;
msg->chunk_len -= ret;
*nxt = msg->next;
return 0;
}
static int
comp_http_chunk_trailers(struct stream *s, struct filter *filter,
struct http_msg *msg)
{
struct comp_state *st = filter->ctx;
if (!st->initialized) {
if (!st->finished) {
struct buffer *buf = msg->chn->buf;
unsigned int fwd = flt_rsp_fwd(filter) + st->hdrs_len;
b_reset(tmpbuf);
b_adv(buf, fwd);
http_compression_buffer_init(buf, zbuf);
b_rew(buf, fwd);
st->initialized = 1;
}
}
st->tlrs_len = msg->sol;
return 1;
}
static int
comp_http_forward_data(struct stream *s, struct filter *filter,
struct http_msg *msg, unsigned int len)
{
struct comp_state *st = filter->ctx;
int ret;
/* To work, previous filters MUST forward all data */
if (flt_rsp_fwd(filter) + len != flt_rsp_nxt(filter)) {
Warning("HTTP compression failed: unexpected behavior of previous filters\n");
return -1;
}
if (!st->initialized) {
if (!len) {
/* Nothing to foward */
ret = len;
}
else if (st->hdrs_len > len) {
/* Forward part of headers */
ret = len;
st->hdrs_len -= len;
}
else if (st->hdrs_len > 0) {
/* Forward remaining headers */
ret = st->hdrs_len;
st->hdrs_len = 0;
}
else if (msg->msg_state < HTTP_MSG_TRAILERS) {
/* Do not forward anything for now. This only happens
* with chunk-encoded responses. Waiting data are part
* of the chunk envelope (the chunk size or the chunk
* CRLF). These data will be skipped during the
* compression. */
ret = 0;
}
else {
/* Forward trailers data */
ret = len;
}
return ret;
}
if (msg->flags & HTTP_MSGF_TE_CHNK) {
ret = http_compression_buffer_add_data(st, tmpbuf, zbuf, tmpbuf->i);
if (ret != tmpbuf->i) {
Warning("HTTP compression failed: Must consume %d bytes but only %d bytes consumed\n",
tmpbuf->i, ret);
return -1;
}
}
st->consumed = len - st->hdrs_len - st->tlrs_len;
b_adv(msg->chn->buf, flt_rsp_fwd(filter) + st->hdrs_len);
ret = http_compression_buffer_end(st, s, &msg->chn->buf, &zbuf, msg->msg_state >= HTTP_MSG_TRAILERS);
b_rew(msg->chn->buf, flt_rsp_fwd(filter) + st->hdrs_len);
if (ret < 0)
return ret;
flt_change_forward_size(filter, msg->chn, ret - st->consumed);
msg->next += (ret - st->consumed);
ret += st->hdrs_len + st->tlrs_len;
st->initialized = 0;
st->finished = (msg->msg_state >= HTTP_MSG_TRAILERS);
st->hdrs_len = 0;
st->tlrs_len = 0;
return ret;
}
/***********************************************************************/
/*
* Selects a compression algorithm depending on the client request.
*/
int
select_compression_request_header(struct comp_state *st, struct stream *s,
struct http_msg *msg)
{
struct http_txn *txn = s->txn;
struct buffer *req = msg->chn->buf;
struct hdr_ctx ctx;
struct comp_algo *comp_algo = NULL;
struct comp_algo *comp_algo_back = NULL;
/* Disable compression for older user agents announcing themselves as "Mozilla/4"
* unless they are known good (MSIE 6 with XP SP2, or MSIE 7 and later).
* See http://zoompf.com/2012/02/lose-the-wait-http-compression for more details.
*/
ctx.idx = 0;
if (http_find_header2("User-Agent", 10, req->p, &txn->hdr_idx, &ctx) &&
ctx.vlen >= 9 &&
memcmp(ctx.line + ctx.val, "Mozilla/4", 9) == 0 &&
(ctx.vlen < 31 ||
memcmp(ctx.line + ctx.val + 25, "MSIE ", 5) != 0 ||
ctx.line[ctx.val + 30] < '6' ||
(ctx.line[ctx.val + 30] == '6' &&
(ctx.vlen < 54 || memcmp(ctx.line + 51, "SV1", 3) != 0)))) {
st->comp_algo = NULL;
return 0;
}
/* search for the algo in the backend in priority or the frontend */
if ((s->be->comp && (comp_algo_back = s->be->comp->algos)) ||
(strm_fe(s)->comp && (comp_algo_back = strm_fe(s)->comp->algos))) {
int best_q = 0;
ctx.idx = 0;
while (http_find_header2("Accept-Encoding", 15, req->p, &txn->hdr_idx, &ctx)) {
const char *qval;
int q;
int toklen;
/* try to isolate the token from the optional q-value */
toklen = 0;
while (toklen < ctx.vlen && http_is_token[(unsigned char)*(ctx.line + ctx.val + toklen)])
toklen++;
qval = ctx.line + ctx.val + toklen;
while (1) {
while (qval < ctx.line + ctx.val + ctx.vlen && http_is_lws[(unsigned char)*qval])
qval++;
if (qval >= ctx.line + ctx.val + ctx.vlen || *qval != ';') {
qval = NULL;
break;
}
qval++;
while (qval < ctx.line + ctx.val + ctx.vlen && http_is_lws[(unsigned char)*qval])
qval++;
if (qval >= ctx.line + ctx.val + ctx.vlen) {
qval = NULL;
break;
}
if (strncmp(qval, "q=", MIN(ctx.line + ctx.val + ctx.vlen - qval, 2)) == 0)
break;
while (qval < ctx.line + ctx.val + ctx.vlen && *qval != ';')
qval++;
}
/* here we have qval pointing to the first "q=" attribute or NULL if not found */
q = qval ? parse_qvalue(qval + 2, NULL) : 1000;
if (q <= best_q)
continue;
for (comp_algo = comp_algo_back; comp_algo; comp_algo = comp_algo->next) {
if (*(ctx.line + ctx.val) == '*' ||
word_match(ctx.line + ctx.val, toklen, comp_algo->ua_name, comp_algo->ua_name_len)) {
st->comp_algo = comp_algo;
best_q = q;
break;
}
}
}
}
/* remove all occurrences of the header when "compression offload" is set */
if (st->comp_algo) {
if ((s->be->comp && s->be->comp->offload) ||
(strm_fe(s)->comp && strm_fe(s)->comp->offload)) {
http_remove_header2(msg, &txn->hdr_idx, &ctx);
ctx.idx = 0;
while (http_find_header2("Accept-Encoding", 15, req->p, &txn->hdr_idx, &ctx)) {
http_remove_header2(msg, &txn->hdr_idx, &ctx);
}
}
return 1;
}
/* identity is implicit does not require headers */
if ((s->be->comp && (comp_algo_back = s->be->comp->algos)) ||
(strm_fe(s)->comp && (comp_algo_back = strm_fe(s)->comp->algos))) {
for (comp_algo = comp_algo_back; comp_algo; comp_algo = comp_algo->next) {
if (comp_algo->cfg_name_len == 8 && memcmp(comp_algo->cfg_name, "identity", 8) == 0) {
st->comp_algo = comp_algo;
return 1;
}
}
}
st->comp_algo = NULL;
return 0;
}
/*
* Selects a comression algorithm depending of the server response.
*/
static int
select_compression_response_header(struct comp_state *st, struct stream *s, struct http_msg *msg)
{
struct http_txn *txn = s->txn;
struct buffer *res = msg->chn->buf;
struct hdr_ctx ctx;
struct comp_type *comp_type;
/* no common compression algorithm was found in request header */
if (st->comp_algo == NULL)
goto fail;
/* HTTP < 1.1 should not be compressed */
if (!(msg->flags & HTTP_MSGF_VER_11) || !(txn->req.flags & HTTP_MSGF_VER_11))
goto fail;
if (txn->meth == HTTP_METH_HEAD)
goto fail;
/* compress 200,201,202,203 responses only */
if ((txn->status != 200) &&
(txn->status != 201) &&
(txn->status != 202) &&
(txn->status != 203))
goto fail;
/* Content-Length is null */
if (!(msg->flags & HTTP_MSGF_TE_CHNK) && msg->body_len == 0)
goto fail;
/* content is already compressed */
ctx.idx = 0;
if (http_find_header2("Content-Encoding", 16, res->p, &txn->hdr_idx, &ctx))
goto fail;
/* no compression when Cache-Control: no-transform is present in the message */
ctx.idx = 0;
while (http_find_header2("Cache-Control", 13, res->p, &txn->hdr_idx, &ctx)) {
if (word_match(ctx.line + ctx.val, ctx.vlen, "no-transform", 12))
goto fail;
}
comp_type = NULL;
/* we don't want to compress multipart content-types, nor content-types that are
* not listed in the "compression type" directive if any. If no content-type was
* found but configuration requires one, we don't compress either. Backend has
* the priority.
*/
ctx.idx = 0;
if (http_find_header2("Content-Type", 12, res->p, &txn->hdr_idx, &ctx)) {
if (ctx.vlen >= 9 && strncasecmp("multipart", ctx.line+ctx.val, 9) == 0)
goto fail;
if ((s->be->comp && (comp_type = s->be->comp->types)) ||
(strm_fe(s)->comp && (comp_type = strm_fe(s)->comp->types))) {
for (; comp_type; comp_type = comp_type->next) {
if (ctx.vlen >= comp_type->name_len &&
strncasecmp(ctx.line+ctx.val, comp_type->name, comp_type->name_len) == 0)
/* this Content-Type should be compressed */
break;
}
/* this Content-Type should not be compressed */
if (comp_type == NULL)
goto fail;
}
}
else { /* no content-type header */
if ((s->be->comp && s->be->comp->types) ||
(strm_fe(s)->comp && strm_fe(s)->comp->types))
goto fail; /* a content-type was required */
}
/* limit compression rate */
if (global.comp_rate_lim > 0)
if (read_freq_ctr(&global.comp_bps_in) > global.comp_rate_lim)
goto fail;
/* limit cpu usage */
if (idle_pct < compress_min_idle)
goto fail;
/* initialize compression */
if (st->comp_algo->init(&st->comp_ctx, global.tune.comp_maxlevel) < 0)
goto fail;
/* remove Content-Length header */
ctx.idx = 0;
if ((msg->flags & HTTP_MSGF_CNT_LEN) && http_find_header2("Content-Length", 14, res->p, &txn->hdr_idx, &ctx))
http_remove_header2(msg, &txn->hdr_idx, &ctx);
/* add Transfer-Encoding header */
if (!(msg->flags & HTTP_MSGF_TE_CHNK))
http_header_add_tail2(&txn->rsp, &txn->hdr_idx, "Transfer-Encoding: chunked", 26);
/*
* Add Content-Encoding header when it's not identity encoding.
* RFC 2616 : Identity encoding: This content-coding is used only in the
* Accept-Encoding header, and SHOULD NOT be used in the Content-Encoding
* header.
*/
if (st->comp_algo->cfg_name_len != 8 || memcmp(st->comp_algo->cfg_name, "identity", 8) != 0) {
trash.len = 18;
memcpy(trash.str, "Content-Encoding: ", trash.len);
memcpy(trash.str + trash.len, st->comp_algo->ua_name, st->comp_algo->ua_name_len);
trash.len += st->comp_algo->ua_name_len;
trash.str[trash.len] = '\0';
http_header_add_tail2(&txn->rsp, &txn->hdr_idx, trash.str, trash.len);
}
msg->flags |= HTTP_MSGF_COMPRESSING;
return 1;
fail:
st->comp_algo = NULL;
return 0;
}
/***********************************************************************/
/* emit the chunksize followed by a CRLF on the output and return the number of
* bytes written. It goes backwards and starts with the byte before <end>. It
* returns the number of bytes written which will not exceed 10 (8 digits, CR,
* and LF). The caller is responsible for ensuring there is enough room left in
* the output buffer for the string.
*/
static int
http_emit_chunk_size(char *end, unsigned int chksz)
{
char *beg = end;
*--beg = '\n';
*--beg = '\r';
do {
*--beg = hextab[chksz & 0xF];
} while (chksz >>= 4);
return end - beg;
}
/*
* Init HTTP compression
*/
static int
http_compression_buffer_init(struct buffer *in, struct buffer *out)
{
/* output stream requires at least 10 bytes for the gzip header, plus
* at least 8 bytes for the gzip trailer (crc+len), plus a possible
* plus at most 5 bytes per 32kB block and 2 bytes to close the stream.
*/
if (in->size - buffer_len(in) < 20 + 5 * ((in->i + 32767) >> 15))
return -1;
/* prepare an empty output buffer in which we reserve enough room for
* copying the output bytes from <in>, plus 10 extra bytes to write
* the chunk size. We don't copy the bytes yet so that if we have to
* cancel the operation later, it's cheap.
*/
b_reset(out);
out->o = in->o;
out->p += out->o;
out->i = 10;
return 0;
}
/*
* Add data to compress
*/
static int
http_compression_buffer_add_data(struct comp_state *st, struct buffer *in,
struct buffer *out, int sz)
{
int consumed_data = 0;
int data_process_len;
int block1, block2;
if (!sz)
goto end;
/* select the smallest size between the announced chunk size, the input
* data, and the available output buffer size. The compressors are
* assumed to be able to process all the bytes we pass to them at
* once. */
data_process_len = MIN(out->size - buffer_len(out), sz);
block1 = data_process_len;
if (block1 > bi_contig_data(in))
block1 = bi_contig_data(in);
block2 = data_process_len - block1;
/* compressors return < 0 upon error or the amount of bytes read */
consumed_data = st->comp_algo->add_data(st->comp_ctx, bi_ptr(in), block1, out);
if (consumed_data != block1 || !block2)
goto end;
consumed_data = st->comp_algo->add_data(st->comp_ctx, in->data, block2, out);
if (consumed_data < 0)
goto end;
consumed_data += block1;
end:
return consumed_data;
}
/*
* Flush data in process, and write the header and footer of the chunk. Upon
* success, in and out buffers are swapped to avoid a copy.
*/
static int
http_compression_buffer_end(struct comp_state *st, struct stream *s,
struct buffer **in, struct buffer **out,
int end)
{
struct buffer *ib = *in, *ob = *out;
char *tail;
int to_forward, left;
#if defined(USE_SLZ) || defined(USE_ZLIB)
int ret;
/* flush data here */
if (end)
ret = st->comp_algo->finish(st->comp_ctx, ob); /* end of data */
else
ret = st->comp_algo->flush(st->comp_ctx, ob); /* end of buffer */
if (ret < 0)
return -1; /* flush failed */
#endif /* USE_ZLIB */
if (ob->i == 10) {
/* No data were appended, let's drop the output buffer and
* keep the input buffer unchanged.
*/
return 0;
}
/* OK so at this stage, we have an output buffer <ob> looking like this :
*
* <-- o --> <------ i ----->
* +---------+---+------------+-----------+
* | out | c | comp_in | empty |
* +---------+---+------------+-----------+
* data p size
*
* <out> is the room reserved to copy ib->o. It starts at ob->data and
* has not yet been filled. <c> is the room reserved to write the chunk
* size (10 bytes). <comp_in> is the compressed equivalent of the data
* part of ib->i. <empty> is the amount of empty bytes at the end of
* the buffer, into which we may have to copy the remaining bytes from
* ib->i after the data (chunk size, trailers, ...).
*/
/* Write real size at the begining of the chunk, no need of wrapping.
* We write the chunk using a dynamic length and adjust ob->p and ob->i
* accordingly afterwards. That will move <out> away from <data>.
*/
left = 10 - http_emit_chunk_size(ob->p + 10, ob->i - 10);
ob->p += left;
ob->i -= left;
/* Copy previous data from ib->o into ob->o */
if (ib->o > 0) {
left = bo_contig_data(ib);
memcpy(ob->p - ob->o, bo_ptr(ib), left);
if (ib->o - left) /* second part of the buffer */
memcpy(ob->p - ob->o + left, ib->data, ib->o - left);
}
/* chunked encoding requires CRLF after data */
tail = ob->p + ob->i;
*tail++ = '\r';
*tail++ = '\n';
/* At the end of data, we must write the empty chunk 0<CRLF>,
* and terminate the trailers section with a last <CRLF>. If
* we're forwarding a chunked-encoded response, we'll have a
* trailers section after the empty chunk which needs to be
* forwarded and which will provide the last CRLF. Otherwise
* we write it ourselves.
*/
if (end) {
struct http_msg *msg = &s->txn->rsp;
memcpy(tail, "0\r\n", 3);
tail += 3;
if (!(msg->flags & HTTP_MSGF_TE_CHNK)) {
memcpy(tail, "\r\n", 2);
tail += 2;
}
}
ob->i = tail - ob->p;
to_forward = ob->i;
/* update input rate */
if (st->comp_ctx && st->comp_ctx->cur_lvl > 0) {
update_freq_ctr(&global.comp_bps_in, st->consumed);
strm_fe(s)->fe_counters.comp_in += st->consumed;
s->be->be_counters.comp_in += st->consumed;
} else {
strm_fe(s)->fe_counters.comp_byp += st->consumed;
s->be->be_counters.comp_byp += st->consumed;
}
/* copy the remaining data in the tmp buffer. */
b_adv(ib, st->consumed);
if (ib->i > 0) {
left = bi_contig_data(ib);
memcpy(ob->p + ob->i, bi_ptr(ib), left);
ob->i += left;
if (ib->i - left) {
memcpy(ob->p + ob->i, ib->data, ib->i - left);
ob->i += ib->i - left;
}
}
/* swap the buffers */
*in = ob;
*out = ib;
if (st->comp_ctx && st->comp_ctx->cur_lvl > 0) {
update_freq_ctr(&global.comp_bps_out, to_forward);
strm_fe(s)->fe_counters.comp_out += to_forward;
s->be->be_counters.comp_out += to_forward;
}
return to_forward;
}
/***********************************************************************/
struct flt_ops comp_ops = {
.init = comp_flt_init,
.deinit = comp_flt_deinit,
.channel_start_analyze = comp_start_analyze,
.channel_analyze = comp_analyze,
.channel_end_analyze = comp_end_analyze,
.http_data = comp_http_data,
.http_chunk_trailers = comp_http_chunk_trailers,
.http_forward_data = comp_http_forward_data,
};
static int
parse_compression_options(char **args, int section, struct proxy *proxy,
struct proxy *defpx, const char *file, int line,
char **err)
{
struct comp *comp;
if (proxy->comp == NULL) {
comp = calloc(1, sizeof(struct comp));
proxy->comp = comp;
}
else
comp = proxy->comp;
if (!strcmp(args[1], "algo")) {
struct comp_ctx *ctx;
int cur_arg = 2;
if (!*args[cur_arg]) {
memprintf(err, "parsing [%s:%d] : '%s' expects <algorithm>\n",
file, line, args[0]);
return -1;
}
while (*(args[cur_arg])) {
if (comp_append_algo(comp, args[cur_arg]) < 0) {
memprintf(err, "'%s' : '%s' is not a supported algorithm.\n",
args[0], args[cur_arg]);
return -1;
}
if (proxy->comp->algos->init(&ctx, 9) == 0)
proxy->comp->algos->end(&ctx);
else {
memprintf(err, "'%s' : Can't init '%s' algorithm.\n",
args[0], args[cur_arg]);
return -1;
}
cur_arg++;
continue;
}
}
else if (!strcmp(args[1], "offload"))
comp->offload = 1;
else if (!strcmp(args[1], "type")) {
int cur_arg = 2;
if (!*args[cur_arg]) {
memprintf(err, "'%s' expects <type>\n", args[0]);
return -1;
}
while (*(args[cur_arg])) {
comp_append_type(comp, args[cur_arg]);
cur_arg++;
continue;
}
}
else {
memprintf(err, "'%s' expects 'algo', 'type' or 'offload'\n",
args[0]);
return -1;
}
return 0;
}
static int
parse_http_comp_flt(char **args, int *cur_arg, struct proxy *px,
struct flt_conf *fconf, char **err)
{
struct flt_conf *fc, *back;
list_for_each_entry_safe(fc, back, &px->filter_configs, list) {
if (fc->id == http_comp_flt_id) {
memprintf(err, "%s: Proxy supports only one compression filter\n", px->id);
return -1;
}
}
fconf->id = http_comp_flt_id;
fconf->conf = NULL;
fconf->ops = &comp_ops;
(*cur_arg)++;
return 0;
}
int
check_legacy_http_comp_flt(struct proxy *proxy)
{
struct flt_conf *fconf;
int err = 0;
if (proxy->comp == NULL)
goto end;
if (!LIST_ISEMPTY(&proxy->filter_configs)) {
list_for_each_entry(fconf, &proxy->filter_configs, list) {
if (fconf->id == http_comp_flt_id)
goto end;
}
Alert("config: %s '%s': require an explicit filter declaration to use HTTP compression\n",
proxy_type_str(proxy), proxy->id);
err++;
goto end;
}
fconf = calloc(1, sizeof(*fconf));
if (!fconf) {
Alert("config: %s '%s': out of memory\n",
proxy_type_str(proxy), proxy->id);
err++;
goto end;
}
fconf->id = http_comp_flt_id;
fconf->conf = NULL;
fconf->ops = &comp_ops;
LIST_ADDQ(&proxy->filter_configs, &fconf->list);
end:
return err;
}
/*
* boolean, returns true if compression is used (either gzip or deflate) in the
* response.
*/
static int
smp_fetch_res_comp(const struct arg *args, struct sample *smp, const char *kw,
void *private)
{
struct http_txn *txn = smp->strm ? smp->strm->txn : NULL;
smp->data.type = SMP_T_BOOL;
smp->data.u.sint = (txn && (txn->rsp.flags & HTTP_MSGF_COMPRESSING));
return 1;
}
/*
* string, returns algo
*/
static int
smp_fetch_res_comp_algo(const struct arg *args, struct sample *smp,
const char *kw, void *private)
{
struct http_txn *txn = smp->strm ? smp->strm->txn : NULL;
struct filter *filter;
struct comp_state *st;
if (!(txn || !(txn->rsp.flags & HTTP_MSGF_COMPRESSING)))
return 0;
list_for_each_entry(filter, &strm_flt(smp->strm)->filters, list) {
if (FLT_ID(filter) != http_comp_flt_id)
continue;
if (!(st = filter->ctx))
break;
smp->data.type = SMP_T_STR;
smp->flags = SMP_F_CONST;
smp->data.u.str.str = st->comp_algo->cfg_name;
smp->data.u.str.len = st->comp_algo->cfg_name_len;
return 1;
}
return 0;
}
/* Declare the config parser for "compression" keyword */
static struct cfg_kw_list cfg_kws = {ILH, {
{ CFG_LISTEN, "compression", parse_compression_options },
{ 0, NULL, NULL },
}
};
/* Declare the filter parser for "compression" keyword */
static struct flt_kw_list filter_kws = { "COMP", { }, {
{ "compression", parse_http_comp_flt },
{ NULL, NULL },
}
};
/* Note: must not be declared <const> as its list will be overwritten */
static struct sample_fetch_kw_list sample_fetch_keywords = {ILH, {
{ "res.comp", smp_fetch_res_comp, 0, NULL, SMP_T_BOOL, SMP_USE_HRSHP },
{ "res.comp_algo", smp_fetch_res_comp_algo, 0, NULL, SMP_T_STR, SMP_USE_HRSHP },
{ /* END */ },
}
};
__attribute__((constructor))
static void
__flt_http_comp_init(void)
{
cfg_register_keywords(&cfg_kws);
flt_register_keywords(&filter_kws);
sample_register_fetches(&sample_fetch_keywords);
}