t7x/deps/curl/lib/vquic/curl_quiche.c
2023-12-06 17:43:39 -05:00

1718 lines
49 KiB
C

/***************************************************************************
* _ _ ____ _
* Project ___| | | | _ \| |
* / __| | | | |_) | |
* | (__| |_| | _ <| |___
* \___|\___/|_| \_\_____|
*
* Copyright (C) Daniel Stenberg, <daniel@haxx.se>, et al.
*
* This software is licensed as described in the file COPYING, which
* you should have received as part of this distribution. The terms
* are also available at https://curl.se/docs/copyright.html.
*
* You may opt to use, copy, modify, merge, publish, distribute and/or sell
* copies of the Software, and permit persons to whom the Software is
* furnished to do so, under the terms of the COPYING file.
*
* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
* SPDX-License-Identifier: curl
*
***************************************************************************/
#include "curl_setup.h"
#ifdef USE_QUICHE
#include <quiche.h>
#include <openssl/err.h>
#include <openssl/ssl.h>
#include "bufq.h"
#include "urldata.h"
#include "cfilters.h"
#include "cf-socket.h"
#include "sendf.h"
#include "strdup.h"
#include "rand.h"
#include "strcase.h"
#include "multiif.h"
#include "connect.h"
#include "progress.h"
#include "strerror.h"
#include "http1.h"
#include "vquic.h"
#include "vquic_int.h"
#include "curl_quiche.h"
#include "transfer.h"
#include "inet_pton.h"
#include "vtls/openssl.h"
#include "vtls/keylog.h"
#include "vtls/vtls.h"
/* The last 3 #include files should be in this order */
#include "curl_printf.h"
#include "curl_memory.h"
#include "memdebug.h"
/* HTTP/3 error values defined in RFC 9114, ch. 8.1 */
#define CURL_H3_NO_ERROR (0x0100)
#define QUIC_MAX_STREAMS (100)
#define H3_STREAM_WINDOW_SIZE (128 * 1024)
#define H3_STREAM_CHUNK_SIZE (16 * 1024)
/* The pool keeps spares around and half of a full stream windows
* seems good. More does not seem to improve performance.
* The benefit of the pool is that stream buffer to not keep
* spares. So memory consumption goes down when streams run empty,
* have a large upload done, etc. */
#define H3_STREAM_POOL_SPARES \
(H3_STREAM_WINDOW_SIZE / H3_STREAM_CHUNK_SIZE ) / 2
/* Receive and Send max number of chunks just follows from the
* chunk size and window size */
#define H3_STREAM_RECV_CHUNKS \
(H3_STREAM_WINDOW_SIZE / H3_STREAM_CHUNK_SIZE)
#define H3_STREAM_SEND_CHUNKS \
(H3_STREAM_WINDOW_SIZE / H3_STREAM_CHUNK_SIZE)
/*
* Store quiche version info in this buffer.
*/
void Curl_quiche_ver(char *p, size_t len)
{
(void)msnprintf(p, len, "quiche/%s", quiche_version());
}
static void keylog_callback(const SSL *ssl, const char *line)
{
(void)ssl;
Curl_tls_keylog_write_line(line);
}
struct cf_quiche_ctx {
struct cf_quic_ctx q;
struct ssl_peer peer;
quiche_conn *qconn;
quiche_config *cfg;
quiche_h3_conn *h3c;
quiche_h3_config *h3config;
uint8_t scid[QUICHE_MAX_CONN_ID_LEN];
SSL_CTX *sslctx;
SSL *ssl;
struct curltime started_at; /* time the current attempt started */
struct curltime handshake_at; /* time connect handshake finished */
struct curltime first_byte_at; /* when first byte was recvd */
struct curltime reconnect_at; /* time the next attempt should start */
struct bufc_pool stream_bufcp; /* chunk pool for streams */
curl_off_t data_recvd;
uint64_t max_idle_ms; /* max idle time for QUIC conn */
BIT(goaway); /* got GOAWAY from server */
BIT(got_first_byte); /* if first byte was received */
BIT(x509_store_setup); /* if x509 store has been set up */
};
#ifdef DEBUG_QUICHE
static void quiche_debug_log(const char *line, void *argp)
{
(void)argp;
fprintf(stderr, "%s\n", line);
}
#endif
static void cf_quiche_ctx_clear(struct cf_quiche_ctx *ctx)
{
if(ctx) {
vquic_ctx_free(&ctx->q);
if(ctx->qconn)
quiche_conn_free(ctx->qconn);
if(ctx->h3config)
quiche_h3_config_free(ctx->h3config);
if(ctx->h3c)
quiche_h3_conn_free(ctx->h3c);
if(ctx->cfg)
quiche_config_free(ctx->cfg);
Curl_bufcp_free(&ctx->stream_bufcp);
Curl_ssl_peer_cleanup(&ctx->peer);
memset(ctx, 0, sizeof(*ctx));
}
}
static CURLcode quic_x509_store_setup(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct ssl_primary_config *conn_config;
conn_config = Curl_ssl_cf_get_primary_config(cf);
if(!conn_config)
return CURLE_FAILED_INIT;
if(!ctx->x509_store_setup) {
if(conn_config->verifypeer) {
const char * const ssl_cafile = conn_config->CAfile;
const char * const ssl_capath = conn_config->CApath;
if(ssl_cafile || ssl_capath) {
SSL_CTX_set_verify(ctx->sslctx, SSL_VERIFY_PEER, NULL);
/* tell OpenSSL where to find CA certificates that are used to verify
the server's certificate. */
if(!SSL_CTX_load_verify_locations(ctx->sslctx, ssl_cafile,
ssl_capath)) {
/* Fail if we insist on successfully verifying the server. */
failf(data, "error setting certificate verify locations:"
" CAfile: %s CApath: %s",
ssl_cafile ? ssl_cafile : "none",
ssl_capath ? ssl_capath : "none");
return CURLE_SSL_CACERT_BADFILE;
}
infof(data, " CAfile: %s", ssl_cafile ? ssl_cafile : "none");
infof(data, " CApath: %s", ssl_capath ? ssl_capath : "none");
}
#ifdef CURL_CA_FALLBACK
else {
/* verifying the peer without any CA certificates won't work so
use openssl's built-in default as fallback */
SSL_CTX_set_default_verify_paths(ctx->sslctx);
}
#endif
}
ctx->x509_store_setup = TRUE;
}
return CURLE_OK;
}
static CURLcode quic_ssl_setup(struct Curl_cfilter *cf, struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct ssl_primary_config *conn_config;
CURLcode result;
conn_config = Curl_ssl_cf_get_primary_config(cf);
if(!conn_config)
return CURLE_FAILED_INIT;
result = Curl_ssl_peer_init(&ctx->peer, cf);
if(result)
return result;
DEBUGASSERT(!ctx->sslctx);
ctx->sslctx = SSL_CTX_new(TLS_method());
if(!ctx->sslctx)
return CURLE_OUT_OF_MEMORY;
SSL_CTX_set_alpn_protos(ctx->sslctx,
(const uint8_t *)QUICHE_H3_APPLICATION_PROTOCOL,
sizeof(QUICHE_H3_APPLICATION_PROTOCOL) - 1);
SSL_CTX_set_default_verify_paths(ctx->sslctx);
/* Open the file if a TLS or QUIC backend has not done this before. */
Curl_tls_keylog_open();
if(Curl_tls_keylog_enabled()) {
SSL_CTX_set_keylog_callback(ctx->sslctx, keylog_callback);
}
if(conn_config->curves &&
!SSL_CTX_set1_curves_list(ctx->sslctx, conn_config->curves)) {
failf(data, "failed setting curves list for QUIC: '%s'",
conn_config->curves);
return CURLE_SSL_CIPHER;
}
ctx->ssl = SSL_new(ctx->sslctx);
if(!ctx->ssl)
return CURLE_QUIC_CONNECT_ERROR;
SSL_set_app_data(ctx->ssl, cf);
if(ctx->peer.sni) {
if(!SSL_set_tlsext_host_name(ctx->ssl, ctx->peer.sni)) {
failf(data, "Failed set SNI");
SSL_free(ctx->ssl);
ctx->ssl = NULL;
return CURLE_QUIC_CONNECT_ERROR;
}
}
return CURLE_OK;
}
/**
* All about the H3 internals of a stream
*/
struct stream_ctx {
int64_t id; /* HTTP/3 protocol stream identifier */
struct bufq recvbuf; /* h3 response */
struct h1_req_parser h1; /* h1 request parsing */
uint64_t error3; /* HTTP/3 stream error code */
curl_off_t upload_left; /* number of request bytes left to upload */
bool closed; /* TRUE on stream close */
bool reset; /* TRUE on stream reset */
bool send_closed; /* stream is locally closed */
bool resp_hds_complete; /* complete, final response has been received */
bool resp_got_header; /* TRUE when h3 stream has recvd some HEADER */
BIT(quic_flow_blocked); /* stream is blocked by QUIC flow control */
};
#define H3_STREAM_CTX(d) ((struct stream_ctx *)(((d) && (d)->req.p.http)? \
((struct HTTP *)(d)->req.p.http)->h3_ctx \
: NULL))
#define H3_STREAM_LCTX(d) ((struct HTTP *)(d)->req.p.http)->h3_ctx
#define H3_STREAM_ID(d) (H3_STREAM_CTX(d)? \
H3_STREAM_CTX(d)->id : -2)
static void check_resumes(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct Curl_easy *sdata;
struct stream_ctx *stream;
DEBUGASSERT(data->multi);
for(sdata = data->multi->easyp; sdata; sdata = sdata->next) {
if(sdata->conn == data->conn) {
stream = H3_STREAM_CTX(sdata);
if(stream && stream->quic_flow_blocked) {
stream->quic_flow_blocked = FALSE;
Curl_expire(data, 0, EXPIRE_RUN_NOW);
CURL_TRC_CF(data, cf, "[%"PRId64"] unblock", stream->id);
}
}
}
}
static CURLcode h3_data_setup(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct stream_ctx *stream = H3_STREAM_CTX(data);
if(stream)
return CURLE_OK;
stream = calloc(1, sizeof(*stream));
if(!stream)
return CURLE_OUT_OF_MEMORY;
H3_STREAM_LCTX(data) = stream;
stream->id = -1;
Curl_bufq_initp(&stream->recvbuf, &ctx->stream_bufcp,
H3_STREAM_RECV_CHUNKS, BUFQ_OPT_SOFT_LIMIT);
Curl_h1_req_parse_init(&stream->h1, H1_PARSE_DEFAULT_MAX_LINE_LEN);
return CURLE_OK;
}
static void h3_data_done(struct Curl_cfilter *cf, struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct stream_ctx *stream = H3_STREAM_CTX(data);
(void)cf;
if(stream) {
CURL_TRC_CF(data, cf, "[%"PRId64"] easy handle is done", stream->id);
if(ctx->qconn && !stream->closed) {
quiche_conn_stream_shutdown(ctx->qconn, stream->id,
QUICHE_SHUTDOWN_READ, CURL_H3_NO_ERROR);
if(!stream->send_closed) {
quiche_conn_stream_shutdown(ctx->qconn, stream->id,
QUICHE_SHUTDOWN_WRITE, CURL_H3_NO_ERROR);
stream->send_closed = TRUE;
}
stream->closed = TRUE;
}
Curl_bufq_free(&stream->recvbuf);
Curl_h1_req_parse_free(&stream->h1);
free(stream);
H3_STREAM_LCTX(data) = NULL;
}
}
static void drain_stream(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct stream_ctx *stream = H3_STREAM_CTX(data);
unsigned char bits;
(void)cf;
bits = CURL_CSELECT_IN;
if(stream && !stream->send_closed && stream->upload_left)
bits |= CURL_CSELECT_OUT;
if(data->state.dselect_bits != bits) {
data->state.dselect_bits = bits;
Curl_expire(data, 0, EXPIRE_RUN_NOW);
}
}
static struct Curl_easy *get_stream_easy(struct Curl_cfilter *cf,
struct Curl_easy *data,
int64_t stream3_id)
{
struct Curl_easy *sdata;
(void)cf;
if(H3_STREAM_ID(data) == stream3_id) {
return data;
}
else {
DEBUGASSERT(data->multi);
for(sdata = data->multi->easyp; sdata; sdata = sdata->next) {
if((sdata->conn == data->conn) && H3_STREAM_ID(sdata) == stream3_id) {
return sdata;
}
}
}
return NULL;
}
/*
* write_resp_raw() copies response data in raw format to the `data`'s
* receive buffer. If not enough space is available, it appends to the
* `data`'s overflow buffer.
*/
static CURLcode write_resp_raw(struct Curl_cfilter *cf,
struct Curl_easy *data,
const void *mem, size_t memlen)
{
struct stream_ctx *stream = H3_STREAM_CTX(data);
CURLcode result = CURLE_OK;
ssize_t nwritten;
(void)cf;
if(!stream)
return CURLE_RECV_ERROR;
nwritten = Curl_bufq_write(&stream->recvbuf, mem, memlen, &result);
if(nwritten < 0)
return result;
if((size_t)nwritten < memlen) {
/* This MUST not happen. Our recbuf is dimensioned to hold the
* full max_stream_window and then some for this very reason. */
DEBUGASSERT(0);
return CURLE_RECV_ERROR;
}
return result;
}
struct cb_ctx {
struct Curl_cfilter *cf;
struct Curl_easy *data;
};
static int cb_each_header(uint8_t *name, size_t name_len,
uint8_t *value, size_t value_len,
void *argp)
{
struct cb_ctx *x = argp;
struct stream_ctx *stream = H3_STREAM_CTX(x->data);
CURLcode result;
if(!stream)
return CURLE_OK;
if((name_len == 7) && !strncmp(HTTP_PSEUDO_STATUS, (char *)name, 7)) {
CURL_TRC_CF(x->data, x->cf, "[%" PRId64 "] status: %.*s",
stream->id, (int)value_len, value);
result = write_resp_raw(x->cf, x->data, "HTTP/3 ", sizeof("HTTP/3 ") - 1);
if(!result)
result = write_resp_raw(x->cf, x->data, value, value_len);
if(!result)
result = write_resp_raw(x->cf, x->data, " \r\n", 3);
}
else {
CURL_TRC_CF(x->data, x->cf, "[%" PRId64 "] header: %.*s: %.*s",
stream->id, (int)name_len, name,
(int)value_len, value);
result = write_resp_raw(x->cf, x->data, name, name_len);
if(!result)
result = write_resp_raw(x->cf, x->data, ": ", 2);
if(!result)
result = write_resp_raw(x->cf, x->data, value, value_len);
if(!result)
result = write_resp_raw(x->cf, x->data, "\r\n", 2);
}
if(result) {
CURL_TRC_CF(x->data, x->cf, "[%"PRId64"] on header error %d",
stream->id, result);
}
return result;
}
static ssize_t stream_resp_read(void *reader_ctx,
unsigned char *buf, size_t len,
CURLcode *err)
{
struct cb_ctx *x = reader_ctx;
struct cf_quiche_ctx *ctx = x->cf->ctx;
struct stream_ctx *stream = H3_STREAM_CTX(x->data);
ssize_t nread;
if(!stream) {
*err = CURLE_RECV_ERROR;
return -1;
}
nread = quiche_h3_recv_body(ctx->h3c, ctx->qconn, stream->id,
buf, len);
if(nread >= 0) {
*err = CURLE_OK;
return nread;
}
else {
*err = CURLE_AGAIN;
return -1;
}
}
static CURLcode cf_recv_body(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct stream_ctx *stream = H3_STREAM_CTX(data);
ssize_t nwritten;
struct cb_ctx cb_ctx;
CURLcode result = CURLE_OK;
if(!stream)
return CURLE_RECV_ERROR;
if(!stream->resp_hds_complete) {
result = write_resp_raw(cf, data, "\r\n", 2);
if(result)
return result;
stream->resp_hds_complete = TRUE;
}
cb_ctx.cf = cf;
cb_ctx.data = data;
nwritten = Curl_bufq_slurp(&stream->recvbuf,
stream_resp_read, &cb_ctx, &result);
if(nwritten < 0 && result != CURLE_AGAIN) {
CURL_TRC_CF(data, cf, "[%"PRId64"] recv_body error %zd",
stream->id, nwritten);
failf(data, "Error %d in HTTP/3 response body for stream[%"PRId64"]",
result, stream->id);
stream->closed = TRUE;
stream->reset = TRUE;
stream->send_closed = TRUE;
streamclose(cf->conn, "Reset of stream");
return result;
}
return CURLE_OK;
}
#ifdef DEBUGBUILD
static const char *cf_ev_name(quiche_h3_event *ev)
{
switch(quiche_h3_event_type(ev)) {
case QUICHE_H3_EVENT_HEADERS:
return "HEADERS";
case QUICHE_H3_EVENT_DATA:
return "DATA";
case QUICHE_H3_EVENT_RESET:
return "RESET";
case QUICHE_H3_EVENT_FINISHED:
return "FINISHED";
case QUICHE_H3_EVENT_GOAWAY:
return "GOAWAY";
default:
return "Unknown";
}
}
#else
#define cf_ev_name(x) ""
#endif
static CURLcode h3_process_event(struct Curl_cfilter *cf,
struct Curl_easy *data,
int64_t stream3_id,
quiche_h3_event *ev)
{
struct stream_ctx *stream = H3_STREAM_CTX(data);
struct cb_ctx cb_ctx;
CURLcode result = CURLE_OK;
int rc;
if(!stream)
return CURLE_OK;
DEBUGASSERT(stream3_id == stream->id);
switch(quiche_h3_event_type(ev)) {
case QUICHE_H3_EVENT_HEADERS:
stream->resp_got_header = TRUE;
cb_ctx.cf = cf;
cb_ctx.data = data;
rc = quiche_h3_event_for_each_header(ev, cb_each_header, &cb_ctx);
if(rc) {
failf(data, "Error %d in HTTP/3 response header for stream[%"PRId64"]",
rc, stream3_id);
return CURLE_RECV_ERROR;
}
CURL_TRC_CF(data, cf, "[%"PRId64"] <- [HEADERS]", stream3_id);
break;
case QUICHE_H3_EVENT_DATA:
if(!stream->closed) {
result = cf_recv_body(cf, data);
}
break;
case QUICHE_H3_EVENT_RESET:
CURL_TRC_CF(data, cf, "[%"PRId64"] RESET", stream3_id);
stream->closed = TRUE;
stream->reset = TRUE;
stream->send_closed = TRUE;
streamclose(cf->conn, "Reset of stream");
break;
case QUICHE_H3_EVENT_FINISHED:
CURL_TRC_CF(data, cf, "[%"PRId64"] CLOSED", stream3_id);
if(!stream->resp_hds_complete) {
result = write_resp_raw(cf, data, "\r\n", 2);
if(result)
return result;
stream->resp_hds_complete = TRUE;
}
stream->closed = TRUE;
streamclose(cf->conn, "End of stream");
break;
case QUICHE_H3_EVENT_GOAWAY:
CURL_TRC_CF(data, cf, "[%"PRId64"] <- [GOAWAY]", stream3_id);
break;
default:
CURL_TRC_CF(data, cf, "[%"PRId64"] recv, unhandled event %d",
stream3_id, quiche_h3_event_type(ev));
break;
}
return result;
}
static CURLcode cf_poll_events(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct stream_ctx *stream = H3_STREAM_CTX(data);
struct Curl_easy *sdata;
quiche_h3_event *ev;
CURLcode result;
/* Take in the events and distribute them to the transfers. */
while(ctx->h3c) {
int64_t stream3_id = quiche_h3_conn_poll(ctx->h3c, ctx->qconn, &ev);
if(stream3_id == QUICHE_H3_ERR_DONE) {
break;
}
else if(stream3_id < 0) {
CURL_TRC_CF(data, cf, "[%"PRId64"] error poll: %"PRId64,
stream? stream->id : -1, stream3_id);
return CURLE_HTTP3;
}
sdata = get_stream_easy(cf, data, stream3_id);
if(!sdata) {
CURL_TRC_CF(data, cf, "[%"PRId64"] discard event %s for "
"unknown [%"PRId64"]",
stream? stream->id : -1, cf_ev_name(ev), stream3_id);
}
else {
result = h3_process_event(cf, sdata, stream3_id, ev);
drain_stream(cf, sdata);
if(result) {
CURL_TRC_CF(data, cf, "[%"PRId64"] error processing event %s "
"for [%"PRId64"] -> %d",
stream? stream->id : -1, cf_ev_name(ev),
stream3_id, result);
if(data == sdata) {
/* Only report this error to the caller if it is about the
* transfer we were called with. Otherwise we fail a transfer
* due to a problem in another one. */
quiche_h3_event_free(ev);
return result;
}
}
quiche_h3_event_free(ev);
}
}
return CURLE_OK;
}
struct recv_ctx {
struct Curl_cfilter *cf;
struct Curl_easy *data;
int pkts;
};
static CURLcode recv_pkt(const unsigned char *pkt, size_t pktlen,
struct sockaddr_storage *remote_addr,
socklen_t remote_addrlen, int ecn,
void *userp)
{
struct recv_ctx *r = userp;
struct cf_quiche_ctx *ctx = r->cf->ctx;
quiche_recv_info recv_info;
ssize_t nread;
(void)ecn;
++r->pkts;
recv_info.to = (struct sockaddr *)&ctx->q.local_addr;
recv_info.to_len = ctx->q.local_addrlen;
recv_info.from = (struct sockaddr *)remote_addr;
recv_info.from_len = remote_addrlen;
nread = quiche_conn_recv(ctx->qconn, (unsigned char *)pkt, pktlen,
&recv_info);
if(nread < 0) {
if(QUICHE_ERR_DONE == nread) {
CURL_TRC_CF(r->data, r->cf, "ingress, quiche is DONE");
return CURLE_OK;
}
else if(QUICHE_ERR_TLS_FAIL == nread) {
long verify_ok = SSL_get_verify_result(ctx->ssl);
if(verify_ok != X509_V_OK) {
failf(r->data, "SSL certificate problem: %s",
X509_verify_cert_error_string(verify_ok));
return CURLE_PEER_FAILED_VERIFICATION;
}
}
else {
failf(r->data, "quiche_conn_recv() == %zd", nread);
return CURLE_RECV_ERROR;
}
}
else if((size_t)nread < pktlen) {
CURL_TRC_CF(r->data, r->cf, "ingress, quiche only read %zd/%zu bytes",
nread, pktlen);
}
return CURLE_OK;
}
static CURLcode cf_process_ingress(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct recv_ctx rctx;
CURLcode result;
DEBUGASSERT(ctx->qconn);
result = quic_x509_store_setup(cf, data);
if(result)
return result;
rctx.cf = cf;
rctx.data = data;
rctx.pkts = 0;
result = vquic_recv_packets(cf, data, &ctx->q, 1000, recv_pkt, &rctx);
if(result)
return result;
if(rctx.pkts > 0) {
/* quiche digested ingress packets. It might have opened flow control
* windows again. */
check_resumes(cf, data);
}
return cf_poll_events(cf, data);
}
struct read_ctx {
struct Curl_cfilter *cf;
struct Curl_easy *data;
quiche_send_info send_info;
};
static ssize_t read_pkt_to_send(void *userp,
unsigned char *buf, size_t buflen,
CURLcode *err)
{
struct read_ctx *x = userp;
struct cf_quiche_ctx *ctx = x->cf->ctx;
ssize_t nwritten;
nwritten = quiche_conn_send(ctx->qconn, buf, buflen, &x->send_info);
if(nwritten == QUICHE_ERR_DONE) {
*err = CURLE_AGAIN;
return -1;
}
if(nwritten < 0) {
failf(x->data, "quiche_conn_send returned %zd", nwritten);
*err = CURLE_SEND_ERROR;
return -1;
}
*err = CURLE_OK;
return nwritten;
}
/*
* flush_egress drains the buffers and sends off data.
* Calls failf() on errors.
*/
static CURLcode cf_flush_egress(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
ssize_t nread;
CURLcode result;
int64_t expiry_ns;
int64_t timeout_ns;
struct read_ctx readx;
size_t pkt_count, gsolen;
expiry_ns = quiche_conn_timeout_as_nanos(ctx->qconn);
if(!expiry_ns) {
quiche_conn_on_timeout(ctx->qconn);
if(quiche_conn_is_closed(ctx->qconn)) {
failf(data, "quiche_conn_on_timeout closed the connection");
return CURLE_SEND_ERROR;
}
}
result = vquic_flush(cf, data, &ctx->q);
if(result) {
if(result == CURLE_AGAIN) {
Curl_expire(data, 1, EXPIRE_QUIC);
return CURLE_OK;
}
return result;
}
readx.cf = cf;
readx.data = data;
memset(&readx.send_info, 0, sizeof(readx.send_info));
pkt_count = 0;
gsolen = quiche_conn_max_send_udp_payload_size(ctx->qconn);
for(;;) {
/* add the next packet to send, if any, to our buffer */
nread = Curl_bufq_sipn(&ctx->q.sendbuf, 0,
read_pkt_to_send, &readx, &result);
if(nread < 0) {
if(result != CURLE_AGAIN)
return result;
/* Nothing more to add, flush and leave */
result = vquic_send(cf, data, &ctx->q, gsolen);
if(result) {
if(result == CURLE_AGAIN) {
Curl_expire(data, 1, EXPIRE_QUIC);
return CURLE_OK;
}
return result;
}
goto out;
}
++pkt_count;
if((size_t)nread < gsolen || pkt_count >= MAX_PKT_BURST) {
result = vquic_send(cf, data, &ctx->q, gsolen);
if(result) {
if(result == CURLE_AGAIN) {
Curl_expire(data, 1, EXPIRE_QUIC);
return CURLE_OK;
}
goto out;
}
pkt_count = 0;
}
}
out:
timeout_ns = quiche_conn_timeout_as_nanos(ctx->qconn);
if(timeout_ns % 1000000)
timeout_ns += 1000000;
/* expire resolution is milliseconds */
Curl_expire(data, (timeout_ns / 1000000), EXPIRE_QUIC);
return result;
}
static ssize_t recv_closed_stream(struct Curl_cfilter *cf,
struct Curl_easy *data,
CURLcode *err)
{
struct stream_ctx *stream = H3_STREAM_CTX(data);
ssize_t nread = -1;
DEBUGASSERT(stream);
if(stream->reset) {
failf(data,
"HTTP/3 stream %" PRId64 " reset by server", stream->id);
*err = stream->resp_got_header? CURLE_PARTIAL_FILE : CURLE_RECV_ERROR;
CURL_TRC_CF(data, cf, "[%" PRId64 "] cf_recv, was reset -> %d",
stream->id, *err);
}
else if(!stream->resp_got_header) {
failf(data,
"HTTP/3 stream %" PRId64 " was closed cleanly, but before getting"
" all response header fields, treated as error",
stream->id);
/* *err = CURLE_PARTIAL_FILE; */
*err = CURLE_RECV_ERROR;
CURL_TRC_CF(data, cf, "[%" PRId64 "] cf_recv, closed incomplete"
" -> %d", stream->id, *err);
}
else {
*err = CURLE_OK;
nread = 0;
}
return nread;
}
static ssize_t cf_quiche_recv(struct Curl_cfilter *cf, struct Curl_easy *data,
char *buf, size_t len, CURLcode *err)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct stream_ctx *stream = H3_STREAM_CTX(data);
ssize_t nread = -1;
CURLcode result;
vquic_ctx_update_time(&ctx->q);
if(!stream) {
*err = CURLE_RECV_ERROR;
return -1;
}
if(!Curl_bufq_is_empty(&stream->recvbuf)) {
nread = Curl_bufq_read(&stream->recvbuf,
(unsigned char *)buf, len, err);
CURL_TRC_CF(data, cf, "[%" PRId64 "] read recvbuf(len=%zu) "
"-> %zd, %d", stream->id, len, nread, *err);
if(nread < 0)
goto out;
}
if(cf_process_ingress(cf, data)) {
CURL_TRC_CF(data, cf, "cf_recv, error on ingress");
*err = CURLE_RECV_ERROR;
nread = -1;
goto out;
}
/* recvbuf had nothing before, maybe after progressing ingress? */
if(nread < 0 && !Curl_bufq_is_empty(&stream->recvbuf)) {
nread = Curl_bufq_read(&stream->recvbuf,
(unsigned char *)buf, len, err);
CURL_TRC_CF(data, cf, "[%" PRId64 "] read recvbuf(len=%zu) "
"-> %zd, %d", stream->id, len, nread, *err);
if(nread < 0)
goto out;
}
if(nread > 0) {
if(stream->closed)
drain_stream(cf, data);
}
else {
if(stream->closed) {
nread = recv_closed_stream(cf, data, err);
goto out;
}
else if(quiche_conn_is_draining(ctx->qconn)) {
failf(data, "QUIC connection is draining");
*err = CURLE_HTTP3;
nread = -1;
goto out;
}
*err = CURLE_AGAIN;
nread = -1;
}
out:
result = cf_flush_egress(cf, data);
if(result) {
CURL_TRC_CF(data, cf, "cf_recv, flush egress failed");
*err = result;
nread = -1;
}
if(nread > 0)
ctx->data_recvd += nread;
CURL_TRC_CF(data, cf, "[%"PRId64"] cf_recv(total=%"
CURL_FORMAT_CURL_OFF_T ") -> %zd, %d",
stream->id, ctx->data_recvd, nread, *err);
return nread;
}
/* Index where :authority header field will appear in request header
field list. */
#define AUTHORITY_DST_IDX 3
static ssize_t h3_open_stream(struct Curl_cfilter *cf,
struct Curl_easy *data,
const void *buf, size_t len,
CURLcode *err)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct stream_ctx *stream = H3_STREAM_CTX(data);
size_t nheader, i;
int64_t stream3_id;
struct dynhds h2_headers;
quiche_h3_header *nva = NULL;
ssize_t nwritten;
if(!stream) {
*err = h3_data_setup(cf, data);
if(*err) {
return -1;
}
stream = H3_STREAM_CTX(data);
DEBUGASSERT(stream);
}
Curl_dynhds_init(&h2_headers, 0, DYN_HTTP_REQUEST);
DEBUGASSERT(stream);
nwritten = Curl_h1_req_parse_read(&stream->h1, buf, len, NULL, 0, err);
if(nwritten < 0)
goto out;
if(!stream->h1.done) {
/* need more data */
goto out;
}
DEBUGASSERT(stream->h1.req);
*err = Curl_http_req_to_h2(&h2_headers, stream->h1.req, data);
if(*err) {
nwritten = -1;
goto out;
}
/* no longer needed */
Curl_h1_req_parse_free(&stream->h1);
nheader = Curl_dynhds_count(&h2_headers);
nva = malloc(sizeof(quiche_h3_header) * nheader);
if(!nva) {
*err = CURLE_OUT_OF_MEMORY;
nwritten = -1;
goto out;
}
for(i = 0; i < nheader; ++i) {
struct dynhds_entry *e = Curl_dynhds_getn(&h2_headers, i);
nva[i].name = (unsigned char *)e->name;
nva[i].name_len = e->namelen;
nva[i].value = (unsigned char *)e->value;
nva[i].value_len = e->valuelen;
}
switch(data->state.httpreq) {
case HTTPREQ_POST:
case HTTPREQ_POST_FORM:
case HTTPREQ_POST_MIME:
case HTTPREQ_PUT:
if(data->state.infilesize != -1)
stream->upload_left = data->state.infilesize;
else
/* data sending without specifying the data amount up front */
stream->upload_left = -1; /* unknown */
break;
default:
stream->upload_left = 0; /* no request body */
break;
}
if(stream->upload_left == 0)
stream->send_closed = TRUE;
stream3_id = quiche_h3_send_request(ctx->h3c, ctx->qconn, nva, nheader,
stream->send_closed);
if(stream3_id < 0) {
if(QUICHE_H3_ERR_STREAM_BLOCKED == stream3_id) {
/* quiche seems to report this error if the connection window is
* exhausted. Which happens frequently and intermittent. */
CURL_TRC_CF(data, cf, "[%"PRId64"] blocked", stream->id);
stream->quic_flow_blocked = TRUE;
*err = CURLE_AGAIN;
nwritten = -1;
goto out;
}
else {
CURL_TRC_CF(data, cf, "send_request(%s) -> %" PRId64,
data->state.url, stream3_id);
}
*err = CURLE_SEND_ERROR;
nwritten = -1;
goto out;
}
DEBUGASSERT(stream->id == -1);
*err = CURLE_OK;
stream->id = stream3_id;
stream->closed = FALSE;
stream->reset = FALSE;
if(Curl_trc_is_verbose(data)) {
infof(data, "[HTTP/3] [%" PRId64 "] OPENED stream for %s",
stream->id, data->state.url);
for(i = 0; i < nheader; ++i) {
infof(data, "[HTTP/3] [%" PRId64 "] [%.*s: %.*s]", stream->id,
(int)nva[i].name_len, nva[i].name,
(int)nva[i].value_len, nva[i].value);
}
}
out:
free(nva);
Curl_dynhds_free(&h2_headers);
return nwritten;
}
static ssize_t cf_quiche_send(struct Curl_cfilter *cf, struct Curl_easy *data,
const void *buf, size_t len, CURLcode *err)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct stream_ctx *stream = H3_STREAM_CTX(data);
CURLcode result;
ssize_t nwritten;
vquic_ctx_update_time(&ctx->q);
*err = cf_process_ingress(cf, data);
if(*err) {
nwritten = -1;
goto out;
}
if(!stream || stream->id < 0) {
nwritten = h3_open_stream(cf, data, buf, len, err);
if(nwritten < 0)
goto out;
stream = H3_STREAM_CTX(data);
}
else {
bool eof = (stream->upload_left >= 0 &&
(curl_off_t)len >= stream->upload_left);
nwritten = quiche_h3_send_body(ctx->h3c, ctx->qconn, stream->id,
(uint8_t *)buf, len, eof);
if(nwritten == QUICHE_H3_ERR_DONE || (nwritten == 0 && len > 0)) {
/* TODO: we seem to be blocked on flow control and should HOLD
* sending. But when do we open again? */
if(!quiche_conn_stream_writable(ctx->qconn, stream->id, len)) {
CURL_TRC_CF(data, cf, "[%" PRId64 "] send_body(len=%zu) "
"-> window exhausted", stream->id, len);
stream->quic_flow_blocked = TRUE;
}
*err = CURLE_AGAIN;
nwritten = -1;
goto out;
}
else if(nwritten == QUICHE_H3_TRANSPORT_ERR_INVALID_STREAM_STATE &&
stream->closed && stream->resp_hds_complete) {
/* sending request body on a stream that has been closed by the
* server. If the server has send us a final response, we should
* silently discard the send data.
* This happens for example on redirects where the server, instead
* of reading the full request body just closed the stream after
* sending the 30x response.
* This is sort of a race: had the transfer loop called recv first,
* it would see the response and stop/discard sending on its own- */
CURL_TRC_CF(data, cf, "[%" PRId64 "] discarding data"
"on closed stream with response", stream->id);
*err = CURLE_OK;
nwritten = (ssize_t)len;
goto out;
}
else if(nwritten == QUICHE_H3_TRANSPORT_ERR_FINAL_SIZE) {
CURL_TRC_CF(data, cf, "[%" PRId64 "] send_body(len=%zu) "
"-> exceeds size", stream->id, len);
*err = CURLE_SEND_ERROR;
nwritten = -1;
goto out;
}
else if(nwritten < 0) {
CURL_TRC_CF(data, cf, "[%" PRId64 "] send_body(len=%zu) "
"-> quiche err %zd", stream->id, len, nwritten);
*err = CURLE_SEND_ERROR;
nwritten = -1;
goto out;
}
else {
/* quiche accepted all or at least a part of the buf */
if(stream->upload_left > 0) {
stream->upload_left = (nwritten < stream->upload_left)?
(stream->upload_left - nwritten) : 0;
}
if(stream->upload_left == 0)
stream->send_closed = TRUE;
CURL_TRC_CF(data, cf, "[%" PRId64 "] send body(len=%zu, "
"left=%" CURL_FORMAT_CURL_OFF_T ") -> %zd",
stream->id, len, stream->upload_left, nwritten);
*err = CURLE_OK;
}
}
out:
result = cf_flush_egress(cf, data);
if(result) {
*err = result;
nwritten = -1;
}
CURL_TRC_CF(data, cf, "[%" PRId64 "] cf_send(len=%zu) -> %zd, %d",
stream? stream->id : -1, len, nwritten, *err);
return nwritten;
}
static bool stream_is_writeable(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct stream_ctx *stream = H3_STREAM_CTX(data);
return stream && (quiche_conn_stream_writable(ctx->qconn,
(uint64_t)stream->id, 1) > 0);
}
static void cf_quiche_adjust_pollset(struct Curl_cfilter *cf,
struct Curl_easy *data,
struct easy_pollset *ps)
{
struct cf_quiche_ctx *ctx = cf->ctx;
bool want_recv = CURL_WANT_RECV(data);
bool want_send = CURL_WANT_SEND(data);
if(ctx->qconn && (want_recv || want_send)) {
struct stream_ctx *stream = H3_STREAM_CTX(data);
bool c_exhaust, s_exhaust;
c_exhaust = FALSE; /* Have not found any call in quiche that tells
us if the connection itself is blocked */
s_exhaust = stream && stream->id >= 0 &&
(stream->quic_flow_blocked || !stream_is_writeable(cf, data));
want_recv = (want_recv || c_exhaust || s_exhaust);
want_send = (!s_exhaust && want_send) ||
!Curl_bufq_is_empty(&ctx->q.sendbuf);
Curl_pollset_set(data, ps, ctx->q.sockfd, want_recv, want_send);
}
}
/*
* Called from transfer.c:data_pending to know if we should keep looping
* to receive more data from the connection.
*/
static bool cf_quiche_data_pending(struct Curl_cfilter *cf,
const struct Curl_easy *data)
{
const struct stream_ctx *stream = H3_STREAM_CTX(data);
(void)cf;
return stream && !Curl_bufq_is_empty(&stream->recvbuf);
}
static CURLcode h3_data_pause(struct Curl_cfilter *cf,
struct Curl_easy *data,
bool pause)
{
/* TODO: there seems right now no API in quiche to shrink/enlarge
* the streams windows. As we do in HTTP/2. */
if(!pause) {
drain_stream(cf, data);
Curl_expire(data, 0, EXPIRE_RUN_NOW);
}
return CURLE_OK;
}
static CURLcode cf_quiche_data_event(struct Curl_cfilter *cf,
struct Curl_easy *data,
int event, int arg1, void *arg2)
{
CURLcode result = CURLE_OK;
(void)arg1;
(void)arg2;
switch(event) {
case CF_CTRL_DATA_SETUP:
break;
case CF_CTRL_DATA_PAUSE:
result = h3_data_pause(cf, data, (arg1 != 0));
break;
case CF_CTRL_DATA_DETACH:
h3_data_done(cf, data);
break;
case CF_CTRL_DATA_DONE:
h3_data_done(cf, data);
break;
case CF_CTRL_DATA_DONE_SEND: {
struct stream_ctx *stream = H3_STREAM_CTX(data);
if(stream && !stream->send_closed) {
unsigned char body[1];
ssize_t sent;
stream->send_closed = TRUE;
stream->upload_left = 0;
body[0] = 'X';
sent = cf_quiche_send(cf, data, body, 0, &result);
CURL_TRC_CF(data, cf, "[%"PRId64"] DONE_SEND -> %zd, %d",
stream->id, sent, result);
}
break;
}
case CF_CTRL_DATA_IDLE: {
struct stream_ctx *stream = H3_STREAM_CTX(data);
if(stream && !stream->closed) {
result = cf_flush_egress(cf, data);
if(result)
CURL_TRC_CF(data, cf, "data idle, flush egress -> %d", result);
}
break;
}
default:
break;
}
return result;
}
static CURLcode cf_verify_peer(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
struct ssl_primary_config *conn_config;
CURLcode result = CURLE_OK;
conn_config = Curl_ssl_cf_get_primary_config(cf);
if(!conn_config)
return CURLE_FAILED_INIT;
cf->conn->bits.multiplex = TRUE; /* at least potentially multiplexed */
cf->conn->httpversion = 30;
cf->conn->bundle->multiuse = BUNDLE_MULTIPLEX;
if(conn_config->verifyhost) {
X509 *server_cert;
server_cert = SSL_get_peer_certificate(ctx->ssl);
if(!server_cert) {
result = CURLE_PEER_FAILED_VERIFICATION;
goto out;
}
result = Curl_ossl_verifyhost(data, cf->conn, &ctx->peer, server_cert);
X509_free(server_cert);
if(result)
goto out;
}
else
CURL_TRC_CF(data, cf, "Skipped certificate verification");
ctx->h3config = quiche_h3_config_new();
if(!ctx->h3config) {
result = CURLE_OUT_OF_MEMORY;
goto out;
}
/* Create a new HTTP/3 connection on the QUIC connection. */
ctx->h3c = quiche_h3_conn_new_with_transport(ctx->qconn, ctx->h3config);
if(!ctx->h3c) {
result = CURLE_OUT_OF_MEMORY;
goto out;
}
if(data->set.ssl.certinfo)
/* asked to gather certificate info */
(void)Curl_ossl_certchain(data, ctx->ssl);
out:
if(result) {
if(ctx->h3config) {
quiche_h3_config_free(ctx->h3config);
ctx->h3config = NULL;
}
if(ctx->h3c) {
quiche_h3_conn_free(ctx->h3c);
ctx->h3c = NULL;
}
}
return result;
}
static CURLcode cf_connect_start(struct Curl_cfilter *cf,
struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
int rv;
CURLcode result;
const struct Curl_sockaddr_ex *sockaddr;
DEBUGASSERT(ctx->q.sockfd != CURL_SOCKET_BAD);
#ifdef DEBUG_QUICHE
/* initialize debug log callback only once */
static int debug_log_init = 0;
if(!debug_log_init) {
quiche_enable_debug_logging(quiche_debug_log, NULL);
debug_log_init = 1;
}
#endif
ctx->max_idle_ms = CURL_QUIC_MAX_IDLE_MS;
Curl_bufcp_init(&ctx->stream_bufcp, H3_STREAM_CHUNK_SIZE,
H3_STREAM_POOL_SPARES);
ctx->data_recvd = 0;
result = vquic_ctx_init(&ctx->q);
if(result)
return result;
ctx->cfg = quiche_config_new(QUICHE_PROTOCOL_VERSION);
if(!ctx->cfg) {
failf(data, "can't create quiche config");
return CURLE_FAILED_INIT;
}
quiche_config_enable_pacing(ctx->cfg, false);
quiche_config_set_max_idle_timeout(ctx->cfg, ctx->max_idle_ms * 1000);
quiche_config_set_initial_max_data(ctx->cfg, (1 * 1024 * 1024)
/* (QUIC_MAX_STREAMS/2) * H3_STREAM_WINDOW_SIZE */);
quiche_config_set_initial_max_streams_bidi(ctx->cfg, QUIC_MAX_STREAMS);
quiche_config_set_initial_max_streams_uni(ctx->cfg, QUIC_MAX_STREAMS);
quiche_config_set_initial_max_stream_data_bidi_local(ctx->cfg,
H3_STREAM_WINDOW_SIZE);
quiche_config_set_initial_max_stream_data_bidi_remote(ctx->cfg,
H3_STREAM_WINDOW_SIZE);
quiche_config_set_initial_max_stream_data_uni(ctx->cfg,
H3_STREAM_WINDOW_SIZE);
quiche_config_set_disable_active_migration(ctx->cfg, TRUE);
quiche_config_set_max_connection_window(ctx->cfg,
10 * QUIC_MAX_STREAMS * H3_STREAM_WINDOW_SIZE);
quiche_config_set_max_stream_window(ctx->cfg, 10 * H3_STREAM_WINDOW_SIZE);
quiche_config_set_application_protos(ctx->cfg,
(uint8_t *)
QUICHE_H3_APPLICATION_PROTOCOL,
sizeof(QUICHE_H3_APPLICATION_PROTOCOL)
- 1);
DEBUGASSERT(!ctx->ssl);
DEBUGASSERT(!ctx->sslctx);
result = quic_ssl_setup(cf, data);
if(result)
return result;
result = Curl_rand(data, ctx->scid, sizeof(ctx->scid));
if(result)
return result;
Curl_cf_socket_peek(cf->next, data, &ctx->q.sockfd,
&sockaddr, NULL, NULL, NULL, NULL);
ctx->q.local_addrlen = sizeof(ctx->q.local_addr);
rv = getsockname(ctx->q.sockfd, (struct sockaddr *)&ctx->q.local_addr,
&ctx->q.local_addrlen);
if(rv == -1)
return CURLE_QUIC_CONNECT_ERROR;
ctx->qconn = quiche_conn_new_with_tls((const uint8_t *)ctx->scid,
sizeof(ctx->scid), NULL, 0,
(struct sockaddr *)&ctx->q.local_addr,
ctx->q.local_addrlen,
&sockaddr->sa_addr, sockaddr->addrlen,
ctx->cfg, ctx->ssl, false);
if(!ctx->qconn) {
failf(data, "can't create quiche connection");
return CURLE_OUT_OF_MEMORY;
}
/* Known to not work on Windows */
#if !defined(_WIN32) && defined(HAVE_QUICHE_CONN_SET_QLOG_FD)
{
int qfd;
(void)Curl_qlogdir(data, ctx->scid, sizeof(ctx->scid), &qfd);
if(qfd != -1)
quiche_conn_set_qlog_fd(ctx->qconn, qfd,
"qlog title", "curl qlog");
}
#endif
result = cf_flush_egress(cf, data);
if(result)
return result;
{
unsigned char alpn_protocols[] = QUICHE_H3_APPLICATION_PROTOCOL;
unsigned alpn_len, offset = 0;
/* Replace each ALPN length prefix by a comma. */
while(offset < sizeof(alpn_protocols) - 1) {
alpn_len = alpn_protocols[offset];
alpn_protocols[offset] = ',';
offset += 1 + alpn_len;
}
CURL_TRC_CF(data, cf, "Sent QUIC client Initial, ALPN: %s",
alpn_protocols + 1);
}
return CURLE_OK;
}
static CURLcode cf_quiche_connect(struct Curl_cfilter *cf,
struct Curl_easy *data,
bool blocking, bool *done)
{
struct cf_quiche_ctx *ctx = cf->ctx;
CURLcode result = CURLE_OK;
if(cf->connected) {
*done = TRUE;
return CURLE_OK;
}
/* Connect the UDP filter first */
if(!cf->next->connected) {
result = Curl_conn_cf_connect(cf->next, data, blocking, done);
if(result || !*done)
return result;
}
*done = FALSE;
vquic_ctx_update_time(&ctx->q);
if(ctx->reconnect_at.tv_sec &&
Curl_timediff(ctx->q.last_op, ctx->reconnect_at) < 0) {
/* Not time yet to attempt the next connect */
CURL_TRC_CF(data, cf, "waiting for reconnect time");
goto out;
}
if(!ctx->qconn) {
result = cf_connect_start(cf, data);
if(result)
goto out;
ctx->started_at = ctx->q.last_op;
result = cf_flush_egress(cf, data);
/* we do not expect to be able to recv anything yet */
goto out;
}
result = cf_process_ingress(cf, data);
if(result)
goto out;
result = cf_flush_egress(cf, data);
if(result)
goto out;
if(quiche_conn_is_established(ctx->qconn)) {
ctx->handshake_at = ctx->q.last_op;
CURL_TRC_CF(data, cf, "handshake complete after %dms",
(int)Curl_timediff(ctx->handshake_at, ctx->started_at));
result = cf_verify_peer(cf, data);
if(!result) {
CURL_TRC_CF(data, cf, "peer verified");
cf->connected = TRUE;
cf->conn->alpn = CURL_HTTP_VERSION_3;
*done = TRUE;
connkeep(cf->conn, "HTTP/3 default");
}
}
else if(quiche_conn_is_draining(ctx->qconn)) {
/* When a QUIC server instance is shutting down, it may send us a
* CONNECTION_CLOSE right away. Our connection then enters the DRAINING
* state. The CONNECT may work in the near future again. Indicate
* that as a "weird" reply. */
result = CURLE_WEIRD_SERVER_REPLY;
}
out:
#ifndef CURL_DISABLE_VERBOSE_STRINGS
if(result && result != CURLE_AGAIN) {
const char *r_ip;
int r_port;
Curl_cf_socket_peek(cf->next, data, NULL, NULL,
&r_ip, &r_port, NULL, NULL);
infof(data, "connect to %s port %u failed: %s",
r_ip, r_port, curl_easy_strerror(result));
}
#endif
return result;
}
static void cf_quiche_close(struct Curl_cfilter *cf, struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
if(ctx) {
if(ctx->qconn) {
vquic_ctx_update_time(&ctx->q);
(void)quiche_conn_close(ctx->qconn, TRUE, 0, NULL, 0);
/* flushing the egress is not a failsafe way to deliver all the
outstanding packets, but we also don't want to get stuck here... */
(void)cf_flush_egress(cf, data);
}
cf_quiche_ctx_clear(ctx);
}
}
static void cf_quiche_destroy(struct Curl_cfilter *cf, struct Curl_easy *data)
{
struct cf_quiche_ctx *ctx = cf->ctx;
(void)data;
cf_quiche_ctx_clear(ctx);
free(ctx);
cf->ctx = NULL;
}
static CURLcode cf_quiche_query(struct Curl_cfilter *cf,
struct Curl_easy *data,
int query, int *pres1, void *pres2)
{
struct cf_quiche_ctx *ctx = cf->ctx;
switch(query) {
case CF_QUERY_MAX_CONCURRENT: {
uint64_t max_streams = CONN_INUSE(cf->conn);
if(!ctx->goaway) {
max_streams += quiche_conn_peer_streams_left_bidi(ctx->qconn);
}
*pres1 = (max_streams > INT_MAX)? INT_MAX : (int)max_streams;
CURL_TRC_CF(data, cf, "query: MAX_CONCURRENT -> %d", *pres1);
return CURLE_OK;
}
case CF_QUERY_CONNECT_REPLY_MS:
if(ctx->got_first_byte) {
timediff_t ms = Curl_timediff(ctx->first_byte_at, ctx->started_at);
*pres1 = (ms < INT_MAX)? (int)ms : INT_MAX;
}
else
*pres1 = -1;
return CURLE_OK;
case CF_QUERY_TIMER_CONNECT: {
struct curltime *when = pres2;
if(ctx->got_first_byte)
*when = ctx->first_byte_at;
return CURLE_OK;
}
case CF_QUERY_TIMER_APPCONNECT: {
struct curltime *when = pres2;
if(cf->connected)
*when = ctx->handshake_at;
return CURLE_OK;
}
default:
break;
}
return cf->next?
cf->next->cft->query(cf->next, data, query, pres1, pres2) :
CURLE_UNKNOWN_OPTION;
}
static bool cf_quiche_conn_is_alive(struct Curl_cfilter *cf,
struct Curl_easy *data,
bool *input_pending)
{
struct cf_quiche_ctx *ctx = cf->ctx;
bool alive = TRUE;
*input_pending = FALSE;
if(!ctx->qconn)
return FALSE;
/* Both sides of the QUIC connection announce they max idle times in
* the transport parameters. Look at the minimum of both and if
* we exceed this, regard the connection as dead. The other side
* may have completely purged it and will no longer respond
* to any packets from us. */
{
quiche_transport_params qpeerparams;
timediff_t idletime;
uint64_t idle_ms = ctx->max_idle_ms;
if(quiche_conn_peer_transport_params(ctx->qconn, &qpeerparams) &&
qpeerparams.peer_max_idle_timeout &&
qpeerparams.peer_max_idle_timeout < idle_ms)
idle_ms = qpeerparams.peer_max_idle_timeout;
idletime = Curl_timediff(Curl_now(), cf->conn->lastused);
if(idletime > 0 && (uint64_t)idletime > idle_ms)
return FALSE;
}
if(!cf->next || !cf->next->cft->is_alive(cf->next, data, input_pending))
return FALSE;
if(*input_pending) {
/* This happens before we've sent off a request and the connection is
not in use by any other transfer, there shouldn't be any data here,
only "protocol frames" */
*input_pending = FALSE;
if(cf_process_ingress(cf, data))
alive = FALSE;
else {
alive = TRUE;
}
}
return alive;
}
struct Curl_cftype Curl_cft_http3 = {
"HTTP/3",
CF_TYPE_IP_CONNECT | CF_TYPE_SSL | CF_TYPE_MULTIPLEX,
0,
cf_quiche_destroy,
cf_quiche_connect,
cf_quiche_close,
Curl_cf_def_get_host,
cf_quiche_adjust_pollset,
cf_quiche_data_pending,
cf_quiche_send,
cf_quiche_recv,
cf_quiche_data_event,
cf_quiche_conn_is_alive,
Curl_cf_def_conn_keep_alive,
cf_quiche_query,
};
CURLcode Curl_cf_quiche_create(struct Curl_cfilter **pcf,
struct Curl_easy *data,
struct connectdata *conn,
const struct Curl_addrinfo *ai)
{
struct cf_quiche_ctx *ctx = NULL;
struct Curl_cfilter *cf = NULL, *udp_cf = NULL;
CURLcode result;
(void)data;
(void)conn;
ctx = calloc(1, sizeof(*ctx));
if(!ctx) {
result = CURLE_OUT_OF_MEMORY;
goto out;
}
result = Curl_cf_create(&cf, &Curl_cft_http3, ctx);
if(result)
goto out;
result = Curl_cf_udp_create(&udp_cf, data, conn, ai, TRNSPRT_QUIC);
if(result)
goto out;
udp_cf->conn = cf->conn;
udp_cf->sockindex = cf->sockindex;
cf->next = udp_cf;
out:
*pcf = (!result)? cf : NULL;
if(result) {
if(udp_cf)
Curl_conn_cf_discard_sub(cf, udp_cf, data, TRUE);
Curl_safefree(cf);
Curl_safefree(ctx);
}
return result;
}
bool Curl_conn_is_quiche(const struct Curl_easy *data,
const struct connectdata *conn,
int sockindex)
{
struct Curl_cfilter *cf = conn? conn->cfilter[sockindex] : NULL;
(void)data;
for(; cf; cf = cf->next) {
if(cf->cft == &Curl_cft_http3)
return TRUE;
if(cf->cft->flags & CF_TYPE_IP_CONNECT)
return FALSE;
}
return FALSE;
}
#endif