blob: 89da1e6971c114c061045536273c357001d2c0b1 [file] [log] [blame]
#include <haproxy/mux_quic.h>
#include <import/eb64tree.h>
#include <haproxy/api.h>
#include <haproxy/connection.h>
#include <haproxy/dynbuf.h>
#include <haproxy/list.h>
#include <haproxy/ncbuf.h>
#include <haproxy/pool.h>
#include <haproxy/qmux_http.h>
#include <haproxy/qmux_trace.h>
#include <haproxy/quic_conn.h>
#include <haproxy/quic_stream.h>
#include <haproxy/quic_tp-t.h>
#include <haproxy/ssl_sock-t.h>
#include <haproxy/stconn.h>
#include <haproxy/trace.h>
DECLARE_POOL(pool_head_qcc, "qcc", sizeof(struct qcc));
DECLARE_POOL(pool_head_qcs, "qcs", sizeof(struct qcs));
/* Emit a CONNECTION_CLOSE with error <err>. This will interrupt all future
* send/receive operations.
*/
static void qcc_emit_cc(struct qcc *qcc, int err)
{
TRACE_ENTER(QMUX_EV_QCC_END, qcc->conn);
TRACE_STATE("set CONNECTION_CLOSE on quic-conn", QMUX_EV_QCC_WAKE, qcc->conn);
quic_set_connection_close(qcc->conn->handle.qc, quic_err_transport(err));
qcc->flags |= QC_CF_CC_EMIT;
tasklet_wakeup(qcc->wait_event.tasklet);
TRACE_LEAVE(QMUX_EV_QCC_END, qcc->conn);
}
/* Allocate a new QUIC streams with id <id> and type <type>. */
static struct qcs *qcs_new(struct qcc *qcc, uint64_t id, enum qcs_type type)
{
struct qcs *qcs;
TRACE_ENTER(QMUX_EV_QCS_NEW, qcc->conn);
qcs = pool_alloc(pool_head_qcs);
if (!qcs) {
TRACE_ERROR("alloc failure", QMUX_EV_QCS_NEW, qcc->conn);
return NULL;
}
qcs->stream = NULL;
qcs->qcc = qcc;
qcs->sd = NULL;
qcs->flags = QC_SF_NONE;
qcs->st = QC_SS_IDLE;
qcs->ctx = NULL;
/* App callback attach may register the stream for http-request wait.
* These fields must be initialed before.
*/
LIST_INIT(&qcs->el_opening);
qcs->start = TICK_ETERNITY;
/* Allocate transport layer stream descriptor. Only needed for TX. */
if (!quic_stream_is_uni(id) || !quic_stream_is_remote(qcc, id)) {
struct quic_conn *qc = qcc->conn->handle.qc;
qcs->stream = qc_stream_desc_new(id, type, qcs, qc);
if (!qcs->stream) {
TRACE_ERROR("qc_stream_desc alloc failure", QMUX_EV_QCS_NEW, qcc->conn, qcs);
goto err;
}
}
qcs->id = qcs->by_id.key = id;
if (qcc->app_ops->attach) {
if (qcc->app_ops->attach(qcs, qcc->ctx)) {
TRACE_ERROR("app proto failure", QMUX_EV_QCS_NEW, qcc->conn, qcs);
goto err;
}
}
/* store transport layer stream descriptor in qcc tree */
eb64_insert(&qcc->streams_by_id, &qcs->by_id);
qcc->strms[type].nb_streams++;
/* If stream is local, use peer remote-limit, or else the opposite. */
if (quic_stream_is_bidi(id)) {
qcs->tx.msd = quic_stream_is_local(qcc, id) ? qcc->rfctl.msd_bidi_r :
qcc->rfctl.msd_bidi_l;
}
else if (quic_stream_is_local(qcc, id)) {
qcs->tx.msd = qcc->rfctl.msd_uni_l;
}
qcs->rx.ncbuf = NCBUF_NULL;
qcs->rx.app_buf = BUF_NULL;
qcs->rx.offset = qcs->rx.offset_max = 0;
if (quic_stream_is_bidi(id)) {
qcs->rx.msd = quic_stream_is_local(qcc, id) ? qcc->lfctl.msd_bidi_l :
qcc->lfctl.msd_bidi_r;
}
else if (quic_stream_is_remote(qcc, id)) {
qcs->rx.msd = qcc->lfctl.msd_uni_r;
}
qcs->rx.msd_init = qcs->rx.msd;
qcs->tx.buf = BUF_NULL;
qcs->tx.offset = 0;
qcs->tx.sent_offset = 0;
qcs->wait_event.tasklet = NULL;
qcs->wait_event.events = 0;
qcs->subs = NULL;
qcs->err = 0;
out:
TRACE_LEAVE(QMUX_EV_QCS_NEW, qcc->conn, qcs);
return qcs;
err:
if (qcs->ctx && qcc->app_ops->detach)
qcc->app_ops->detach(qcs);
qc_stream_desc_release(qcs->stream);
pool_free(pool_head_qcs, qcs);
TRACE_LEAVE(QMUX_EV_QCS_NEW, qcc->conn, qcs);
return NULL;
}
static void qc_free_ncbuf(struct qcs *qcs, struct ncbuf *ncbuf)
{
struct buffer buf;
if (ncb_is_null(ncbuf))
return;
buf = b_make(ncbuf->area, ncbuf->size, 0, 0);
b_free(&buf);
offer_buffers(NULL, 1);
*ncbuf = NCBUF_NULL;
}
/* Free a qcs. This function must only be done to remove a stream on allocation
* error or connection shutdown. Else use qcs_destroy which handle all the
* QUIC connection mechanism.
*/
static void qcs_free(struct qcs *qcs)
{
struct qcc *qcc = qcs->qcc;
TRACE_ENTER(QMUX_EV_QCS_END, qcc->conn, qcs);
qc_free_ncbuf(qcs, &qcs->rx.ncbuf);
b_free(&qcs->tx.buf);
BUG_ON(!qcc->strms[qcs_id_type(qcs->id)].nb_streams);
--qcc->strms[qcs_id_type(qcs->id)].nb_streams;
if (qcs->ctx && qcc->app_ops->detach)
qcc->app_ops->detach(qcs);
qc_stream_desc_release(qcs->stream);
BUG_ON(qcs->sd && !se_fl_test(qcs->sd, SE_FL_ORPHAN));
sedesc_free(qcs->sd);
eb64_delete(&qcs->by_id);
pool_free(pool_head_qcs, qcs);
TRACE_LEAVE(QMUX_EV_QCS_END, qcc->conn);
}
static forceinline struct stconn *qcs_sc(const struct qcs *qcs)
{
return qcs->sd ? qcs->sd->sc : NULL;
}
/* Reset the <qcc> inactivity timeout for http-keep-alive timeout. */
static forceinline void qcc_reset_idle_start(struct qcc *qcc)
{
qcc->idle_start = now_ms;
}
/* Decrement <qcc> sc. */
static forceinline void qcc_rm_sc(struct qcc *qcc)
{
BUG_ON_HOT(!qcc->nb_sc);
--qcc->nb_sc;
/* Reset qcc idle start for http-keep-alive timeout. Timeout will be
* refreshed after this on stream detach.
*/
if (!qcc->nb_sc && !qcc->nb_hreq)
qcc_reset_idle_start(qcc);
}
/* Decrement <qcc> hreq. */
static forceinline void qcc_rm_hreq(struct qcc *qcc)
{
BUG_ON_HOT(!qcc->nb_hreq);
--qcc->nb_hreq;
/* Reset qcc idle start for http-keep-alive timeout. Timeout will be
* refreshed after this on I/O handler.
*/
if (!qcc->nb_sc && !qcc->nb_hreq)
qcc_reset_idle_start(qcc);
}
static inline int qcc_is_dead(const struct qcc *qcc)
{
/* Mux connection is considered dead if :
* - all stream-desc are detached AND
* = connection is on error OR
* = mux timeout has already fired or is unset
*/
if (!qcc->nb_sc && ((qcc->conn->flags & CO_FL_ERROR) || !qcc->task))
return 1;
return 0;
}
/* Return true if the mux timeout should be armed. */
static inline int qcc_may_expire(struct qcc *qcc)
{
return !qcc->nb_sc;
}
/* Refresh the timeout on <qcc> if needed depending on its state. */
static void qcc_refresh_timeout(struct qcc *qcc)
{
const struct proxy *px = qcc->proxy;
TRACE_ENTER(QMUX_EV_QCC_WAKE, qcc->conn);
if (!qcc->task) {
TRACE_DEVEL("already expired", QMUX_EV_QCC_WAKE, qcc->conn);
goto leave;
}
/* Check if upper layer is responsible of timeout management. */
if (!qcc_may_expire(qcc)) {
TRACE_DEVEL("not eligible for timeout", QMUX_EV_QCC_WAKE, qcc->conn);
qcc->task->expire = TICK_ETERNITY;
task_queue(qcc->task);
goto leave;
}
/* TODO if connection is idle on frontend and proxy is disabled, remove
* it with global close_spread delay applied.
*/
/* TODO implement client/server-fin timeout for graceful shutdown */
/* Frontend timeout management
* - detached streams with data left to send -> default timeout
* - stream waiting on incomplete request or no stream yet activated -> timeout http-request
* - idle after stream processing -> timeout http-keep-alive
*/
if (!conn_is_back(qcc->conn)) {
if (qcc->nb_hreq) {
TRACE_DEVEL("one or more requests still in progress", QMUX_EV_QCC_WAKE, qcc->conn);
qcc->task->expire = tick_add_ifset(now_ms, qcc->timeout);
task_queue(qcc->task);
goto leave;
}
if (!LIST_ISEMPTY(&qcc->opening_list) || unlikely(!qcc->largest_bidi_r)) {
int timeout = px->timeout.httpreq;
struct qcs *qcs = NULL;
int base_time;
/* Use start time of first stream waiting on HTTP or
* qcc idle if no stream not yet used.
*/
if (likely(!LIST_ISEMPTY(&qcc->opening_list)))
qcs = LIST_ELEM(qcc->opening_list.n, struct qcs *, el_opening);
base_time = qcs ? qcs->start : qcc->idle_start;
TRACE_DEVEL("waiting on http request", QMUX_EV_QCC_WAKE, qcc->conn, qcs);
qcc->task->expire = tick_add_ifset(base_time, timeout);
}
else {
/* Use http-request timeout if keep-alive timeout not set */
int timeout = tick_isset(px->timeout.httpka) ?
px->timeout.httpka : px->timeout.httpreq;
TRACE_DEVEL("at least one request achieved but none currently in progress", QMUX_EV_QCC_WAKE, qcc->conn);
qcc->task->expire = tick_add_ifset(qcc->idle_start, timeout);
}
}
/* fallback to default timeout if frontend specific undefined or for
* backend connections.
*/
if (!tick_isset(qcc->task->expire)) {
TRACE_DEVEL("fallback to default timeout", QMUX_EV_QCC_WAKE, qcc->conn);
qcc->task->expire = tick_add_ifset(now_ms, qcc->timeout);
}
task_queue(qcc->task);
leave:
TRACE_LEAVE(QMUX_EV_QCS_NEW, qcc->conn);
}
/* Mark a stream as open if it was idle. This can be used on every
* successful emission/reception operation to update the stream state.
*/
static void qcs_idle_open(struct qcs *qcs)
{
/* This operation must not be used if the stream is already closed. */
BUG_ON_HOT(qcs->st == QC_SS_CLO);
if (qcs->st == QC_SS_IDLE) {
TRACE_STATE("opening stream", QMUX_EV_QCS_NEW, qcs->qcc->conn, qcs);
qcs->st = QC_SS_OPEN;
}
}
/* Close the local channel of <qcs> instance. */
static void qcs_close_local(struct qcs *qcs)
{
TRACE_STATE("closing stream locally", QMUX_EV_QCS_SEND, qcs->qcc->conn, qcs);
/* The stream must have already been opened. */
BUG_ON_HOT(qcs->st == QC_SS_IDLE);
/* This operation cannot be used multiple times. */
BUG_ON_HOT(qcs->st == QC_SS_HLOC || qcs->st == QC_SS_CLO);
if (quic_stream_is_bidi(qcs->id)) {
qcs->st = (qcs->st == QC_SS_HREM) ? QC_SS_CLO : QC_SS_HLOC;
if (qcs->flags & QC_SF_HREQ_RECV)
qcc_rm_hreq(qcs->qcc);
}
else {
/* Only local uni streams are valid for this operation. */
BUG_ON_HOT(quic_stream_is_remote(qcs->qcc, qcs->id));
qcs->st = QC_SS_CLO;
}
}
/* Close the remote channel of <qcs> instance. */
static void qcs_close_remote(struct qcs *qcs)
{
TRACE_STATE("closing stream remotely", QMUX_EV_QCS_RECV, qcs->qcc->conn, qcs);
/* The stream must have already been opened. */
BUG_ON_HOT(qcs->st == QC_SS_IDLE);
/* This operation cannot be used multiple times. */
BUG_ON_HOT(qcs->st == QC_SS_HREM || qcs->st == QC_SS_CLO);
if (quic_stream_is_bidi(qcs->id)) {
qcs->st = (qcs->st == QC_SS_HLOC) ? QC_SS_CLO : QC_SS_HREM;
}
else {
/* Only remote uni streams are valid for this operation. */
BUG_ON_HOT(quic_stream_is_local(qcs->qcc, qcs->id));
qcs->st = QC_SS_CLO;
}
}
static int qcs_is_close_local(struct qcs *qcs)
{
return qcs->st == QC_SS_HLOC || qcs->st == QC_SS_CLO;
}
static __maybe_unused int qcs_is_close_remote(struct qcs *qcs)
{
return qcs->st == QC_SS_HREM || qcs->st == QC_SS_CLO;
}
struct buffer *qc_get_buf(struct qcs *qcs, struct buffer *bptr)
{
struct buffer *buf = b_alloc(bptr);
BUG_ON(!buf);
return buf;
}
static struct ncbuf *qc_get_ncbuf(struct qcs *qcs, struct ncbuf *ncbuf)
{
struct buffer buf = BUF_NULL;
if (ncb_is_null(ncbuf)) {
b_alloc(&buf);
BUG_ON(b_is_null(&buf));
*ncbuf = ncb_make(buf.area, buf.size, 0);
ncb_init(ncbuf, 0);
}
return ncbuf;
}
/* Notify an eventual subscriber on <qcs> or else wakeup up the stconn layer if
* initialized.
*/
static void qcs_alert(struct qcs *qcs)
{
if (qcs->subs) {
qcs_notify_recv(qcs);
qcs_notify_send(qcs);
}
else if (qcs_sc(qcs) && qcs->sd->sc->app_ops->wake) {
qcs->sd->sc->app_ops->wake(qcs->sd->sc);
}
}
int qcs_subscribe(struct qcs *qcs, int event_type, struct wait_event *es)
{
struct qcc *qcc = qcs->qcc;
TRACE_ENTER(QMUX_EV_STRM_SEND|QMUX_EV_STRM_RECV, qcc->conn, qcs);
BUG_ON(event_type & ~(SUB_RETRY_SEND|SUB_RETRY_RECV));
BUG_ON(qcs->subs && qcs->subs != es);
es->events |= event_type;
qcs->subs = es;
if (event_type & SUB_RETRY_RECV)
TRACE_DEVEL("subscribe(recv)", QMUX_EV_STRM_RECV, qcc->conn, qcs);
if (event_type & SUB_RETRY_SEND)
TRACE_DEVEL("subscribe(send)", QMUX_EV_STRM_SEND, qcc->conn, qcs);
TRACE_LEAVE(QMUX_EV_STRM_SEND|QMUX_EV_STRM_RECV, qcc->conn, qcs);
return 0;
}
void qcs_notify_recv(struct qcs *qcs)
{
if (qcs->subs && qcs->subs->events & SUB_RETRY_RECV) {
tasklet_wakeup(qcs->subs->tasklet);
qcs->subs->events &= ~SUB_RETRY_RECV;
if (!qcs->subs->events)
qcs->subs = NULL;
}
}
void qcs_notify_send(struct qcs *qcs)
{
if (qcs->subs && qcs->subs->events & SUB_RETRY_SEND) {
tasklet_wakeup(qcs->subs->tasklet);
qcs->subs->events &= ~SUB_RETRY_SEND;
if (!qcs->subs->events)
qcs->subs = NULL;
}
}
/* Open a locally initiated stream for the connection <qcc>. Set <bidi> for a
* bidirectional stream, else an unidirectional stream is opened. The next
* available ID on the connection will be used according to the stream type.
*
* Returns the allocated stream instance or NULL on error.
*/
struct qcs *qcc_init_stream_local(struct qcc *qcc, int bidi)
{
struct qcs *qcs;
enum qcs_type type;
uint64_t *next;
TRACE_ENTER(QMUX_EV_QCS_NEW, qcc->conn);
if (bidi) {
next = &qcc->next_bidi_l;
type = conn_is_back(qcc->conn) ? QCS_CLT_BIDI : QCS_SRV_BIDI;
}
else {
next = &qcc->next_uni_l;
type = conn_is_back(qcc->conn) ? QCS_CLT_UNI : QCS_SRV_UNI;
}
/* TODO ensure that we won't overflow remote peer flow control limit on
* streams. Else, we should emit a STREAMS_BLOCKED frame.
*/
qcs = qcs_new(qcc, *next, type);
if (!qcs) {
TRACE_LEAVE(QMUX_EV_QCS_NEW, qcc->conn);
return NULL;
}
TRACE_PROTO("opening local stream", QMUX_EV_QCS_NEW, qcc->conn, qcs);
*next += 4;
TRACE_LEAVE(QMUX_EV_QCS_NEW, qcc->conn, qcs);
return qcs;
}
/* Open a remote initiated stream for the connection <qcc> with ID <id>. The
* caller is responsible to ensure that a stream with the same ID was not
* already opened. This function will also create all intermediaries streams
* with ID smaller than <id> not already opened before.
*
* Returns the allocated stream instance or NULL on error.
*/
static struct qcs *qcc_init_stream_remote(struct qcc *qcc, uint64_t id)
{
struct qcs *qcs = NULL;
enum qcs_type type;
uint64_t *largest, max_id;
TRACE_ENTER(QMUX_EV_QCS_NEW, qcc->conn);
BUG_ON_HOT(quic_stream_is_local(qcc, id));
if (quic_stream_is_bidi(id)) {
largest = &qcc->largest_bidi_r;
type = conn_is_back(qcc->conn) ? QCS_SRV_BIDI : QCS_CLT_BIDI;
}
else {
largest = &qcc->largest_uni_r;
type = conn_is_back(qcc->conn) ? QCS_SRV_UNI : QCS_CLT_UNI;
}
/* RFC 9000 4.6. Controlling Concurrency
*
* An endpoint that receives a frame with a stream ID exceeding the
* limit it has sent MUST treat this as a connection error of type
* STREAM_LIMIT_ERROR
*/
max_id = quic_stream_is_bidi(id) ? qcc->lfctl.ms_bidi * 4 :
qcc->lfctl.ms_uni * 4;
if (id >= max_id) {
TRACE_ERROR("flow control error", QMUX_EV_QCS_NEW|QMUX_EV_PROTO_ERR, qcc->conn);
qcc_emit_cc(qcc, QC_ERR_STREAM_LIMIT_ERROR);
goto err;
}
/* Only stream ID not already opened can be used. */
BUG_ON(id < *largest);
while (id >= *largest) {
const char *str = *largest < id ? "initializing intermediary remote stream" :
"initializing remote stream";
qcs = qcs_new(qcc, *largest, type);
if (!qcs) {
/* TODO emit RESET_STREAM */
TRACE_ERROR("stream fallocation failure", QMUX_EV_QCS_NEW, qcc->conn);
goto err;
}
TRACE_PROTO(str, QMUX_EV_QCS_NEW, qcc->conn, qcs);
*largest += 4;
}
out:
TRACE_LEAVE(QMUX_EV_QCS_NEW, qcc->conn, qcs);
return qcs;
err:
TRACE_LEAVE(QMUX_EV_QCS_NEW, qcc->conn);
return NULL;
}
/* Use this function for a stream <id> which is not in <qcc> stream tree. It
* returns true if the associated stream is closed.
*/
static int qcc_stream_id_is_closed(struct qcc *qcc, uint64_t id)
{
uint64_t *largest;
/* This function must only be used for stream not present in the stream tree. */
BUG_ON_HOT(eb64_lookup(&qcc->streams_by_id, id));
if (quic_stream_is_local(qcc, id)) {
largest = quic_stream_is_uni(id) ? &qcc->next_uni_l :
&qcc->next_bidi_l;
}
else {
largest = quic_stream_is_uni(id) ? &qcc->largest_uni_r :
&qcc->largest_bidi_r;
}
return id < *largest;
}
/* Retrieve the stream instance from <id> ID. This can be used when receiving
* STREAM, STREAM_DATA_BLOCKED, RESET_STREAM, MAX_STREAM_DATA or STOP_SENDING
* frames. Set to false <receive_only> or <send_only> if these particular types
* of streams are not allowed. If the stream instance is found, it is stored in
* <out>.
*
* Returns 0 on success else non-zero. On error, a RESET_STREAM or a
* CONNECTION_CLOSE is automatically emitted. Beware that <out> may be NULL
* on success if the stream has already been closed.
*/
int qcc_get_qcs(struct qcc *qcc, uint64_t id, int receive_only, int send_only,
struct qcs **out)
{
struct eb64_node *node;
TRACE_ENTER(QMUX_EV_QCC_RECV, qcc->conn);
*out = NULL;
if (!receive_only && quic_stream_is_uni(id) && quic_stream_is_remote(qcc, id)) {
TRACE_ERROR("receive-only stream not allowed", QMUX_EV_QCC_RECV|QMUX_EV_QCC_NQCS|QMUX_EV_PROTO_ERR, qcc->conn, NULL, &id);
qcc_emit_cc(qcc, QC_ERR_STREAM_STATE_ERROR);
goto err;
}
if (!send_only && quic_stream_is_uni(id) && quic_stream_is_local(qcc, id)) {
TRACE_ERROR("send-only stream not allowed", QMUX_EV_QCC_RECV|QMUX_EV_QCC_NQCS|QMUX_EV_PROTO_ERR, qcc->conn, NULL, &id);
qcc_emit_cc(qcc, QC_ERR_STREAM_STATE_ERROR);
goto err;
}
/* Search the stream in the connection tree. */
node = eb64_lookup(&qcc->streams_by_id, id);
if (node) {
*out = eb64_entry(node, struct qcs, by_id);
TRACE_DEVEL("using stream from connection tree", QMUX_EV_QCC_RECV, qcc->conn, *out);
goto out;
}
/* Check if stream is already closed. */
if (qcc_stream_id_is_closed(qcc, id)) {
TRACE_DATA("already closed stream", QMUX_EV_QCC_RECV|QMUX_EV_QCC_NQCS, qcc->conn, NULL, &id);
/* Consider this as a success even if <out> is left NULL. */
goto out;
}
/* Create the stream. This is valid only for remote initiated one. A
* local stream must have already been explicitly created by the
* application protocol layer.
*/
if (quic_stream_is_local(qcc, id)) {
/* RFC 9000 19.8. STREAM Frames
*
* An endpoint MUST terminate the connection with error
* STREAM_STATE_ERROR if it receives a STREAM frame for a locally
* initiated stream that has not yet been created, or for a send-only
* stream.
*/
TRACE_ERROR("locally initiated stream not yet created", QMUX_EV_QCC_RECV|QMUX_EV_QCC_NQCS|QMUX_EV_PROTO_ERR, qcc->conn, NULL, &id);
qcc_emit_cc(qcc, QC_ERR_STREAM_STATE_ERROR);
goto err;
}
else {
/* Remote stream not found - try to open it. */
*out = qcc_init_stream_remote(qcc, id);
if (!*out) {
TRACE_ERROR("stream creation error", QMUX_EV_QCC_RECV|QMUX_EV_QCC_NQCS, qcc->conn, NULL, &id);
goto err;
}
}
out:
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn, *out);
return 0;
err:
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 1;
}
/* Simple function to duplicate a buffer */
static inline struct buffer qcs_b_dup(const struct ncbuf *b)
{
return b_make(ncb_orig(b), b->size, b->head, ncb_data(b, 0));
}
/* Remove <bytes> from <qcs> Rx buffer. Flow-control for received offsets may
* be allocated for the peer if needed.
*/
static void qcs_consume(struct qcs *qcs, uint64_t bytes)
{
struct qcc *qcc = qcs->qcc;
struct quic_frame *frm;
struct ncbuf *buf = &qcs->rx.ncbuf;
enum ncb_ret ret;
TRACE_ENTER(QMUX_EV_QCS_RECV, qcc->conn, qcs);
ret = ncb_advance(buf, bytes);
if (ret) {
ABORT_NOW(); /* should not happens because removal only in data */
}
if (ncb_is_empty(buf))
qc_free_ncbuf(qcs, buf);
qcs->rx.offset += bytes;
if (qcs->rx.msd - qcs->rx.offset < qcs->rx.msd_init / 2) {
TRACE_DATA("increase stream credit via MAX_STREAM_DATA", QMUX_EV_QCS_RECV, qcc->conn, qcs);
frm = pool_zalloc(pool_head_quic_frame);
BUG_ON(!frm); /* TODO handle this properly */
qcs->rx.msd = qcs->rx.offset + qcs->rx.msd_init;
LIST_INIT(&frm->reflist);
frm->type = QUIC_FT_MAX_STREAM_DATA;
frm->max_stream_data.id = qcs->id;
frm->max_stream_data.max_stream_data = qcs->rx.msd;
LIST_APPEND(&qcc->lfctl.frms, &frm->list);
tasklet_wakeup(qcc->wait_event.tasklet);
}
qcc->lfctl.offsets_consume += bytes;
if (qcc->lfctl.md - qcc->lfctl.offsets_consume < qcc->lfctl.md_init / 2) {
TRACE_DATA("increase conn credit via MAX_DATA", QMUX_EV_QCS_RECV, qcc->conn, qcs);
frm = pool_zalloc(pool_head_quic_frame);
BUG_ON(!frm); /* TODO handle this properly */
qcc->lfctl.md = qcc->lfctl.offsets_consume + qcc->lfctl.md_init;
LIST_INIT(&frm->reflist);
frm->type = QUIC_FT_MAX_DATA;
frm->max_data.max_data = qcc->lfctl.md;
LIST_APPEND(&qcs->qcc->lfctl.frms, &frm->list);
tasklet_wakeup(qcs->qcc->wait_event.tasklet);
}
TRACE_LEAVE(QMUX_EV_QCS_RECV, qcc->conn, qcs);
}
/* Decode the content of STREAM frames already received on the stream instance
* <qcs>.
*
* Returns 0 on success else non-zero.
*/
static int qcc_decode_qcs(struct qcc *qcc, struct qcs *qcs)
{
struct buffer b;
ssize_t ret;
int fin = 0;
TRACE_ENTER(QMUX_EV_QCS_RECV, qcc->conn, qcs);
b = qcs_b_dup(&qcs->rx.ncbuf);
/* Signal FIN to application if STREAM FIN received with all data. */
if (qcs_is_close_remote(qcs))
fin = 1;
ret = qcc->app_ops->decode_qcs(qcs, &b, fin);
if (ret < 0) {
TRACE_ERROR("decoding error", QMUX_EV_QCS_RECV, qcc->conn, qcs);
goto err;
}
if (ret) {
qcs_consume(qcs, ret);
qcs_notify_recv(qcs);
}
TRACE_LEAVE(QMUX_EV_QCS_RECV, qcc->conn, qcs);
return 0;
err:
TRACE_LEAVE(QMUX_EV_QCS_RECV, qcc->conn, qcs);
return 1;
}
/* Emit a CONNECTION_CLOSE_APP with error <err>. Reserved for application error
* code. To close the connection right away, set <immediate> : this is useful
* when dealing with a connection fatal error. Else a graceful shutdown will be
* conducted : the error-code is only registered. The lower layer is
* responsible to close the connection when deemed suitable. Note that in this
* case the error code might be overwritten if an immediate close is requested
* in the interval.
*/
void qcc_emit_cc_app(struct qcc *qcc, int err, int immediate)
{
TRACE_ENTER(QMUX_EV_QCC_END, qcc->conn);
if (immediate) {
quic_set_connection_close(qcc->conn->handle.qc, quic_err_app(err));
qcc->flags |= QC_CF_CC_EMIT;
tasklet_wakeup(qcc->wait_event.tasklet);
}
else {
/* Only register the error code for graceful shutdown. */
qcc->conn->handle.qc->err = quic_err_app(err);
}
TRACE_LEAVE(QMUX_EV_QCC_END, qcc->conn);
}
/* Prepare for the emission of RESET_STREAM on <qcs> with error code <err>. */
void qcc_reset_stream(struct qcs *qcs, int err)
{
struct qcc *qcc = qcs->qcc;
if ((qcs->flags & QC_SF_TO_RESET) || qcs_is_close_local(qcs))
return;
TRACE_STATE("reset stream", QMUX_EV_QCS_END, qcc->conn, qcs);
qcs->flags |= QC_SF_TO_RESET;
qcs->err = err;
tasklet_wakeup(qcc->wait_event.tasklet);
}
/* Install the <app_ops> applicative layer of a QUIC connection on mux <qcc>.
* Returns 0 on success else non-zero.
*/
int qcc_install_app_ops(struct qcc *qcc, const struct qcc_app_ops *app_ops)
{
TRACE_ENTER(QMUX_EV_QCC_NEW, qcc->conn);
qcc->app_ops = app_ops;
if (qcc->app_ops->init && !qcc->app_ops->init(qcc)) {
TRACE_ERROR("app ops init error", QMUX_EV_QCC_NEW, qcc->conn);
goto err;
}
TRACE_PROTO("application layer initialized", QMUX_EV_QCC_NEW, qcc->conn);
TRACE_LEAVE(QMUX_EV_QCC_NEW, qcc->conn);
return 0;
err:
TRACE_LEAVE(QMUX_EV_QCC_NEW, qcc->conn);
return 1;
}
/* Handle a new STREAM frame for stream with id <id>. Payload is pointed by
* <data> with length <len> and represents the offset <offset>. <fin> is set if
* the QUIC frame FIN bit is set.
*
* Returns 0 on success else non-zero. On error, the received frame should not
* be acknowledged.
*/
int qcc_recv(struct qcc *qcc, uint64_t id, uint64_t len, uint64_t offset,
char fin, char *data)
{
struct qcs *qcs;
enum ncb_ret ret;
TRACE_ENTER(QMUX_EV_QCC_RECV, qcc->conn);
if (qcc->flags & QC_CF_CC_EMIT) {
TRACE_DATA("connection closed", QMUX_EV_QCC_RECV, qcc->conn);
goto err;
}
/* RFC 9000 19.8. STREAM Frames
*
* An endpoint MUST terminate the connection with error
* STREAM_STATE_ERROR if it receives a STREAM frame for a locally
* initiated stream that has not yet been created, or for a send-only
* stream.
*/
if (qcc_get_qcs(qcc, id, 1, 0, &qcs)) {
TRACE_DATA("qcs retrieval error", QMUX_EV_QCC_RECV, qcc->conn);
goto err;
}
if (!qcs) {
TRACE_DATA("already closed stream", QMUX_EV_QCC_RECV, qcc->conn);
goto out;
}
/* RFC 9000 4.5. Stream Final Size
*
* Once a final size for a stream is known, it cannot change. If a
* RESET_STREAM or STREAM frame is received indicating a change in the
* final size for the stream, an endpoint SHOULD respond with an error
* of type FINAL_SIZE_ERROR; see Section 11 for details on error
* handling.
*/
if (qcs->flags & QC_SF_SIZE_KNOWN &&
(offset + len > qcs->rx.offset_max || (fin && offset + len < qcs->rx.offset_max))) {
TRACE_ERROR("final size error", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV|QMUX_EV_PROTO_ERR, qcc->conn, qcs);
qcc_emit_cc(qcc, QC_ERR_FINAL_SIZE_ERROR);
goto err;
}
if (offset + len <= qcs->rx.offset) {
/* TODO offset may have been received without FIN first and now
* with it. In this case, it must be notified to be able to
* close the stream.
*/
TRACE_DATA("already received offset", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV, qcc->conn, qcs);
goto out;
}
TRACE_PROTO("receiving STREAM", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV, qcc->conn, qcs);
qcs_idle_open(qcs);
if (offset + len > qcs->rx.offset_max) {
uint64_t diff = offset + len - qcs->rx.offset_max;
qcs->rx.offset_max = offset + len;
qcc->lfctl.offsets_recv += diff;
if (offset + len > qcs->rx.msd ||
qcc->lfctl.offsets_recv > qcc->lfctl.md) {
/* RFC 9000 4.1. Data Flow Control
*
* A receiver MUST close the connection with an error
* of type FLOW_CONTROL_ERROR if the sender violates
* the advertised connection or stream data limits
*/
TRACE_ERROR("flow control error", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV|QMUX_EV_PROTO_ERR,
qcc->conn, qcs);
qcc_emit_cc(qcc, QC_ERR_FLOW_CONTROL_ERROR);
goto err;
}
}
if (!qc_get_ncbuf(qcs, &qcs->rx.ncbuf) || ncb_is_null(&qcs->rx.ncbuf)) {
/* TODO should mark qcs as full */
ABORT_NOW();
return 1;
}
TRACE_DATA("newly received offset", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV, qcc->conn, qcs);
if (offset < qcs->rx.offset) {
size_t diff = qcs->rx.offset - offset;
len -= diff;
data += diff;
offset = qcs->rx.offset;
}
ret = ncb_add(&qcs->rx.ncbuf, offset - qcs->rx.offset, data, len, NCB_ADD_COMPARE);
if (ret != NCB_RET_OK) {
if (ret == NCB_RET_DATA_REJ) {
/* RFC 9000 2.2. Sending and Receiving Data
*
* An endpoint could receive data for a stream at the
* same stream offset multiple times. Data that has
* already been received can be discarded. The data at
* a given offset MUST NOT change if it is sent
* multiple times; an endpoint MAY treat receipt of
* different data at the same offset within a stream as
* a connection error of type PROTOCOL_VIOLATION.
*/
TRACE_ERROR("overlapping data rejected", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV|QMUX_EV_PROTO_ERR,
qcc->conn, qcs);
qcc_emit_cc(qcc, QC_ERR_PROTOCOL_VIOLATION);
}
else if (ret == NCB_RET_GAP_SIZE) {
TRACE_DATA("cannot bufferize frame due to gap size limit", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV,
qcc->conn, qcs);
}
return 1;
}
if (fin)
qcs->flags |= QC_SF_SIZE_KNOWN;
if (qcs->flags & QC_SF_SIZE_KNOWN &&
qcs->rx.offset_max == qcs->rx.offset + ncb_data(&qcs->rx.ncbuf, 0)) {
qcs_close_remote(qcs);
}
if (ncb_data(&qcs->rx.ncbuf, 0) && !(qcs->flags & QC_SF_DEM_FULL)) {
qcc_decode_qcs(qcc, qcs);
qcc_refresh_timeout(qcc);
}
if (qcs->flags & QC_SF_READ_ABORTED) {
/* TODO should send a STOP_SENDING */
qcs_free(qcs);
}
out:
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 0;
err:
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 1;
}
/* Handle a new MAX_DATA frame. <max> must contains the maximum data field of
* the frame.
*
* Returns 0 on success else non-zero.
*/
int qcc_recv_max_data(struct qcc *qcc, uint64_t max)
{
TRACE_ENTER(QMUX_EV_QCC_RECV, qcc->conn);
TRACE_PROTO("receiving MAX_DATA", QMUX_EV_QCC_RECV, qcc->conn);
if (qcc->rfctl.md < max) {
qcc->rfctl.md = max;
TRACE_DEVEL("increase remote max-data", QMUX_EV_QCC_RECV, qcc->conn);
if (qcc->flags & QC_CF_BLK_MFCTL) {
qcc->flags &= ~QC_CF_BLK_MFCTL;
tasklet_wakeup(qcc->wait_event.tasklet);
}
}
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 0;
}
/* Handle a new MAX_STREAM_DATA frame. <max> must contains the maximum data
* field of the frame and <id> is the identifier of the QUIC stream.
*
* Returns 0 on success else non-zero. On error, the received frame should not
* be acknowledged.
*/
int qcc_recv_max_stream_data(struct qcc *qcc, uint64_t id, uint64_t max)
{
struct qcs *qcs;
TRACE_ENTER(QMUX_EV_QCC_RECV, qcc->conn);
/* RFC 9000 19.10. MAX_STREAM_DATA Frames
*
* Receiving a MAX_STREAM_DATA frame for a locally
* initiated stream that has not yet been created MUST be treated as a
* connection error of type STREAM_STATE_ERROR. An endpoint that
* receives a MAX_STREAM_DATA frame for a receive-only stream MUST
* terminate the connection with error STREAM_STATE_ERROR.
*/
if (qcc_get_qcs(qcc, id, 0, 1, &qcs)) {
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 1;
}
if (qcs) {
TRACE_PROTO("receiving MAX_STREAM_DATA", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV, qcc->conn, qcs);
if (max > qcs->tx.msd) {
qcs->tx.msd = max;
TRACE_DEVEL("increase remote max-stream-data", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV, qcc->conn, qcs);
if (qcs->flags & QC_SF_BLK_SFCTL) {
qcs->flags &= ~QC_SF_BLK_SFCTL;
tasklet_wakeup(qcc->wait_event.tasklet);
}
}
}
if (qcc_may_expire(qcc) && !qcc->nb_hreq)
qcc_refresh_timeout(qcc);
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 0;
}
/* Handle a new STOP_SENDING frame for stream ID <id>. The error code should be
* specified in <err>.
*
* Returns 0 on success else non-zero. On error, the received frame should not
* be acknowledged.
*/
int qcc_recv_stop_sending(struct qcc *qcc, uint64_t id, uint64_t err)
{
struct qcs *qcs;
TRACE_ENTER(QMUX_EV_QCC_RECV, qcc->conn);
/* RFC 9000 19.5. STOP_SENDING Frames
*
* Receiving a STOP_SENDING frame for a
* locally initiated stream that has not yet been created MUST be
* treated as a connection error of type STREAM_STATE_ERROR. An
* endpoint that receives a STOP_SENDING frame for a receive-only stream
* MUST terminate the connection with error STREAM_STATE_ERROR.
*/
if (qcc_get_qcs(qcc, id, 0, 1, &qcs)) {
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 1;
}
if (!qcs)
goto out;
TRACE_PROTO("receiving STOP_SENDING", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV, qcc->conn, qcs);
/* RFC 9000 3.5. Solicited State Transitions
*
* An endpoint is expected to send another STOP_SENDING frame if a
* packet containing a previous STOP_SENDING is lost. However, once
* either all stream data or a RESET_STREAM frame has been received for
* the stream -- that is, the stream is in any state other than "Recv"
* or "Size Known" -- sending a STOP_SENDING frame is unnecessary.
*/
/* TODO thanks to previous RFC clause, STOP_SENDING is ignored if current stream
* has already been closed locally. This is useful to not emit multiple
* RESET_STREAM for a single stream. This is functional if stream is
* locally closed due to all data transmitted, but in this case the RFC
* advices to use an explicit RESET_STREAM.
*/
if (qcs_is_close_local(qcs)) {
TRACE_STATE("ignoring STOP_SENDING", QMUX_EV_QCC_RECV|QMUX_EV_QCS_RECV, qcc->conn, qcs);
goto out;
}
qcs_idle_open(qcs);
/* RFC 9000 3.5. Solicited State Transitions
*
* An endpoint that receives a STOP_SENDING frame
* MUST send a RESET_STREAM frame if the stream is in the "Ready" or
* "Send" state. If the stream is in the "Data Sent" state, the
* endpoint MAY defer sending the RESET_STREAM frame until the packets
* containing outstanding data are acknowledged or declared lost. If
* any outstanding data is declared lost, the endpoint SHOULD send a
* RESET_STREAM frame instead of retransmitting the data.
*
* An endpoint SHOULD copy the error code from the STOP_SENDING frame to
* the RESET_STREAM frame it sends, but it can use any application error
* code.
*/
qcc_reset_stream(qcs, err);
if (qcc_may_expire(qcc) && !qcc->nb_hreq)
qcc_refresh_timeout(qcc);
out:
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 0;
}
/* Signal the closing of remote stream with id <id>. Flow-control for new
* streams may be allocated for the peer if needed.
*/
static int qcc_release_remote_stream(struct qcc *qcc, uint64_t id)
{
struct quic_frame *frm;
TRACE_ENTER(QMUX_EV_QCS_END, qcc->conn);
if (quic_stream_is_bidi(id)) {
++qcc->lfctl.cl_bidi_r;
if (qcc->lfctl.cl_bidi_r > qcc->lfctl.ms_bidi_init / 2) {
TRACE_DATA("increase max stream limit with MAX_STREAMS_BIDI", QMUX_EV_QCC_SEND, qcc->conn);
frm = pool_zalloc(pool_head_quic_frame);
BUG_ON(!frm); /* TODO handle this properly */
LIST_INIT(&frm->reflist);
frm->type = QUIC_FT_MAX_STREAMS_BIDI;
frm->max_streams_bidi.max_streams = qcc->lfctl.ms_bidi +
qcc->lfctl.cl_bidi_r;
LIST_APPEND(&qcc->lfctl.frms, &frm->list);
tasklet_wakeup(qcc->wait_event.tasklet);
qcc->lfctl.ms_bidi += qcc->lfctl.cl_bidi_r;
qcc->lfctl.cl_bidi_r = 0;
}
}
else {
/* TODO in HTTP/3 unidirectional streams cannot be closed or a
* H3_CLOSED_CRITICAL_STREAM will be triggered before
* entering here. If a new application protocol is supported it
* might be necessary to implement MAX_STREAMS_UNI emission.
*/
ABORT_NOW();
}
TRACE_LEAVE(QMUX_EV_QCS_END, qcc->conn);
return 0;
}
/* detaches the QUIC stream from its QCC and releases it to the QCS pool. */
static void qcs_destroy(struct qcs *qcs)
{
struct connection *conn = qcs->qcc->conn;
const uint64_t id = qcs->id;
TRACE_ENTER(QMUX_EV_QCS_END, conn, qcs);
if (quic_stream_is_remote(qcs->qcc, id))
qcc_release_remote_stream(qcs->qcc, id);
qcs_free(qcs);
TRACE_LEAVE(QMUX_EV_QCS_END, conn);
}
/* Transfer as much as possible data on <qcs> from <in> to <out>. This is done
* in respect with available flow-control at stream and connection level.
*
* Returns the total bytes of transferred data.
*/
static int qcs_xfer_data(struct qcs *qcs, struct buffer *out, struct buffer *in)
{
struct qcc *qcc = qcs->qcc;
int left, to_xfer;
int total = 0;
TRACE_ENTER(QMUX_EV_QCS_SEND, qcc->conn, qcs);
qc_get_buf(qcs, out);
/*
* QCS out buffer diagram
* head left to_xfer
* -------------> ----------> ----->
* --------------------------------------------------
* |...............|xxxxxxxxxxx|<<<<<
* --------------------------------------------------
* ^ ack-off ^ sent-off ^ off
*
* STREAM frame
* ^ ^
* |xxxxxxxxxxxxxxxxx|
*/
BUG_ON_HOT(qcs->tx.sent_offset < qcs->stream->ack_offset);
BUG_ON_HOT(qcs->tx.offset < qcs->tx.sent_offset);
BUG_ON_HOT(qcc->tx.offsets < qcc->tx.sent_offsets);
left = qcs->tx.offset - qcs->tx.sent_offset;
to_xfer = QUIC_MIN(b_data(in), b_room(out));
BUG_ON_HOT(qcs->tx.offset > qcs->tx.msd);
/* do not exceed flow control limit */
if (qcs->tx.offset + to_xfer > qcs->tx.msd)
to_xfer = qcs->tx.msd - qcs->tx.offset;
BUG_ON_HOT(qcc->tx.offsets > qcc->rfctl.md);
/* do not overcome flow control limit on connection */
if (qcc->tx.offsets + to_xfer > qcc->rfctl.md)
to_xfer = qcc->rfctl.md - qcc->tx.offsets;
if (!left && !to_xfer)
goto out;
total = b_force_xfer(out, in, to_xfer);
out:
{
struct qcs_xfer_data_trace_arg arg = {
.prep = b_data(out), .xfer = total,
};
TRACE_LEAVE(QMUX_EV_QCS_SEND|QMUX_EV_QCS_XFER_DATA,
qcc->conn, qcs, &arg);
}
return total;
}
/* Prepare a STREAM frame for <qcs> instance using <out> as payload. The frame
* is appended in <frm_list>. Set <fin> if this is supposed to be the last
* stream frame.
*
* Returns the length of the STREAM frame or a negative error code.
*/
static int qcs_build_stream_frm(struct qcs *qcs, struct buffer *out, char fin,
struct list *frm_list)
{
struct qcc *qcc = qcs->qcc;
struct quic_frame *frm;
int head, total;
uint64_t base_off;
TRACE_ENTER(QMUX_EV_QCS_SEND, qcc->conn, qcs);
/* if ack_offset < buf_offset, it points to an older buffer. */
base_off = MAX(qcs->stream->buf_offset, qcs->stream->ack_offset);
BUG_ON(qcs->tx.sent_offset < base_off);
head = qcs->tx.sent_offset - base_off;
total = b_data(out) - head;
BUG_ON(total < 0);
if (!total && !fin) {
/* No need to send anything if total is NULL and no FIN to signal. */
TRACE_LEAVE(QMUX_EV_QCS_SEND, qcc->conn, qcs);
return 0;
}
BUG_ON((!total && qcs->tx.sent_offset > qcs->tx.offset) ||
(total && qcs->tx.sent_offset >= qcs->tx.offset));
BUG_ON(qcs->tx.sent_offset + total > qcs->tx.offset);
BUG_ON(qcc->tx.sent_offsets + total > qcc->rfctl.md);
TRACE_PROTO("sending STREAM frame", QMUX_EV_QCS_SEND, qcc->conn, qcs);
frm = pool_zalloc(pool_head_quic_frame);
if (!frm) {
TRACE_ERROR("frame alloc failure", QMUX_EV_QCS_SEND, qcc->conn, qcs);
goto err;
}
LIST_INIT(&frm->reflist);
frm->type = QUIC_FT_STREAM_8;
frm->stream.stream = qcs->stream;
frm->stream.id = qcs->id;
frm->stream.buf = out;
frm->stream.data = (unsigned char *)b_peek(out, head);
/* FIN is positioned only when the buffer has been totally emptied. */
if (fin)
frm->type |= QUIC_STREAM_FRAME_TYPE_FIN_BIT;
if (qcs->tx.sent_offset) {
frm->type |= QUIC_STREAM_FRAME_TYPE_OFF_BIT;
frm->stream.offset.key = qcs->tx.sent_offset;
}
frm->type |= QUIC_STREAM_FRAME_TYPE_LEN_BIT;
frm->stream.len = total;
LIST_APPEND(frm_list, &frm->list);
out:
{
struct qcs_build_stream_trace_arg arg = {
.len = frm->stream.len, .fin = fin,
.offset = frm->stream.offset.key,
};
TRACE_LEAVE(QMUX_EV_QCS_SEND|QMUX_EV_QCS_BUILD_STRM,
qcc->conn, qcs, &arg);
}
return total;
err:
TRACE_LEAVE(QMUX_EV_QCS_SEND, qcc->conn, qcs);
return -1;
}
/* Check after transferring data from qcs.tx.buf if FIN must be set on the next
* STREAM frame for <qcs>.
*
* Returns true if FIN must be set else false.
*/
static int qcs_stream_fin(struct qcs *qcs)
{
return qcs->flags & QC_SF_FIN_STREAM && !b_data(&qcs->tx.buf);
}
/* This function must be called by the upper layer to inform about the sending
* of a STREAM frame for <qcs> instance. The frame is of <data> length and on
* <offset>.
*/
void qcc_streams_sent_done(struct qcs *qcs, uint64_t data, uint64_t offset)
{
struct qcc *qcc = qcs->qcc;
uint64_t diff;
TRACE_ENTER(QMUX_EV_QCS_SEND, qcc->conn, qcs);
BUG_ON(offset > qcs->tx.sent_offset);
BUG_ON(offset + data > qcs->tx.offset);
/* check if the STREAM frame has already been notified. It can happen
* for retransmission.
*/
if (offset + data < qcs->tx.sent_offset) {
TRACE_DEVEL("offset already notified", QMUX_EV_QCS_SEND, qcc->conn, qcs);
goto out;
}
qcs_idle_open(qcs);
diff = offset + data - qcs->tx.sent_offset;
if (diff) {
/* increase offset sum on connection */
qcc->tx.sent_offsets += diff;
BUG_ON_HOT(qcc->tx.sent_offsets > qcc->rfctl.md);
if (qcc->tx.sent_offsets == qcc->rfctl.md)
qcc->flags |= QC_CF_BLK_MFCTL;
/* increase offset on stream */
qcs->tx.sent_offset += diff;
BUG_ON_HOT(qcs->tx.sent_offset > qcs->tx.msd);
BUG_ON_HOT(qcs->tx.sent_offset > qcs->tx.offset);
if (qcs->tx.sent_offset == qcs->tx.msd)
qcs->flags |= QC_SF_BLK_SFCTL;
if (qcs->tx.offset == qcs->tx.sent_offset &&
b_full(&qcs->stream->buf->buf)) {
qc_stream_buf_release(qcs->stream);
/* prepare qcs for immediate send retry if data to send */
if (b_data(&qcs->tx.buf))
LIST_APPEND(&qcc->send_retry_list, &qcs->el);
}
}
if (qcs->tx.offset == qcs->tx.sent_offset && !b_data(&qcs->tx.buf) &&
qcs->flags & (QC_SF_FIN_STREAM|QC_SF_DETACH)) {
/* Close stream locally. */
qcs_close_local(qcs);
/* Reset flag to not emit multiple FIN STREAM frames. */
qcs->flags &= ~QC_SF_FIN_STREAM;
}
out:
TRACE_LEAVE(QMUX_EV_QCS_SEND, qcc->conn, qcs);
}
/* Wrapper for send on transport layer. Send a list of frames <frms> for the
* connection <qcc>.
*
* Returns 0 if all data sent with success else non-zero.
*/
static int qc_send_frames(struct qcc *qcc, struct list *frms)
{
TRACE_ENTER(QMUX_EV_QCC_SEND, qcc->conn);
if (LIST_ISEMPTY(frms)) {
TRACE_DEVEL("no frames to send", QMUX_EV_QCC_SEND, qcc->conn);
goto err;
}
LIST_INIT(&qcc->send_retry_list);
if (!qc_send_mux(qcc->conn->handle.qc, frms))
goto err;
/* If there is frames left at this stage, transport layer is blocked.
* Subscribe on it to retry later.
*/
if (!LIST_ISEMPTY(frms)) {
TRACE_DEVEL("remaining frames to send, subscribing", QMUX_EV_QCC_SEND, qcc->conn);
qcc->conn->xprt->subscribe(qcc->conn, qcc->conn->xprt_ctx,
SUB_RETRY_SEND, &qcc->wait_event);
goto err;
}
TRACE_LEAVE(QMUX_EV_QCC_SEND, qcc->conn);
return 0;
err:
TRACE_LEAVE(QMUX_EV_QCC_SEND, qcc->conn);
return 1;
}
/* Emit a RESET_STREAM on <qcs>.
*
* Returns 0 if the frame has been successfully sent else non-zero.
*/
static int qcs_send_reset(struct qcs *qcs)
{
struct list frms = LIST_HEAD_INIT(frms);
struct quic_frame *frm;
TRACE_ENTER(QMUX_EV_QCS_SEND, qcs->qcc->conn, qcs);
frm = pool_zalloc(pool_head_quic_frame);
if (!frm) {
TRACE_LEAVE(QMUX_EV_QCS_SEND, qcs->qcc->conn, qcs);
return 1;
}
LIST_INIT(&frm->reflist);
frm->type = QUIC_FT_RESET_STREAM;
frm->reset_stream.id = qcs->id;
frm->reset_stream.app_error_code = qcs->err;
frm->reset_stream.final_size = qcs->tx.sent_offset;
LIST_APPEND(&frms, &frm->list);
if (qc_send_frames(qcs->qcc, &frms)) {
pool_free(pool_head_quic_frame, frm);
TRACE_DEVEL("cannot send RESET_STREAM", QMUX_EV_QCS_SEND, qcs->qcc->conn, qcs);
return 1;
}
if (qcs_sc(qcs)) {
se_fl_set_error(qcs->sd);
qcs_alert(qcs);
}
qcs_close_local(qcs);
qcs->flags &= ~QC_SF_TO_RESET;
TRACE_LEAVE(QMUX_EV_QCS_SEND, qcs->qcc->conn, qcs);
return 0;
}
/* Used internally by qc_send function. Proceed to send for <qcs>. This will
* transfer data from qcs buffer to its quic_stream counterpart. A STREAM frame
* is then generated and inserted in <frms> list.
*
* Returns the total bytes transferred between qcs and quic_stream buffers. Can
* be null if out buffer cannot be allocated.
*/
static int _qc_send_qcs(struct qcs *qcs, struct list *frms)
{
struct qcc *qcc = qcs->qcc;
struct buffer *buf = &qcs->tx.buf;
struct buffer *out = qc_stream_buf_get(qcs->stream);
int xfer = 0;
char fin = 0;
/* Allocate <out> buffer if necessary. */
if (!out) {
if (qcc->flags & QC_CF_CONN_FULL)
return 0;
out = qc_stream_buf_alloc(qcs->stream, qcs->tx.offset);
if (!out) {
qcc->flags |= QC_CF_CONN_FULL;
return 0;
}
}
/* Transfer data from <buf> to <out>. */
if (b_data(buf)) {
xfer = qcs_xfer_data(qcs, out, buf);
if (xfer > 0) {
qcs_notify_send(qcs);
qcs->flags &= ~QC_SF_BLK_MROOM;
}
qcs->tx.offset += xfer;
BUG_ON_HOT(qcs->tx.offset > qcs->tx.msd);
qcc->tx.offsets += xfer;
BUG_ON_HOT(qcc->tx.offsets > qcc->rfctl.md);
}
/* out buffer cannot be emptied if qcs offsets differ. */
BUG_ON(!b_data(out) && qcs->tx.sent_offset != qcs->tx.offset);
/* FIN is set if all incoming data were transferred. */
fin = qcs_stream_fin(qcs);
/* Build a new STREAM frame with <out> buffer. */
if (qcs->tx.sent_offset != qcs->tx.offset || fin) {
int ret;
ret = qcs_build_stream_frm(qcs, out, fin, frms);
if (ret < 0) { ABORT_NOW(); /* TODO handle this properly */ }
}
return xfer;
}
/* Proceed to sending. Loop through all available streams for the <qcc>
* instance and try to send as much as possible.
*
* Returns the total of bytes sent to the transport layer.
*/
static int qc_send(struct qcc *qcc)
{
struct list frms = LIST_HEAD_INIT(frms);
struct eb64_node *node;
struct qcs *qcs, *qcs_tmp;
int total = 0, tmp_total = 0;
TRACE_ENTER(QMUX_EV_QCC_SEND, qcc->conn);
if (qcc->conn->flags & CO_FL_SOCK_WR_SH || qcc->flags & QC_CF_CC_EMIT) {
qcc->conn->flags |= CO_FL_ERROR;
TRACE_DEVEL("connection on error", QMUX_EV_QCC_SEND, qcc->conn);
goto err;
}
if (!LIST_ISEMPTY(&qcc->lfctl.frms)) {
if (qc_send_frames(qcc, &qcc->lfctl.frms)) {
TRACE_DEVEL("flow-control frames rejected by transport, aborting send", QMUX_EV_QCC_SEND, qcc->conn);
goto out;
}
}
if (qcc->flags & QC_CF_BLK_MFCTL)
return 0;
if (!(qcc->flags & QC_CF_APP_FINAL) && !eb_is_empty(&qcc->streams_by_id) &&
qcc->app_ops->finalize) {
/* Finalize the application layer before sending any stream.
* For h3 this consists in preparing the control stream data (SETTINGS h3).
*/
qcc->app_ops->finalize(qcc->ctx);
qcc->flags |= QC_CF_APP_FINAL;
}
/* loop through all streams, construct STREAM frames if data available.
* TODO optimize the loop to favor streams which are not too heavy.
*/
node = eb64_first(&qcc->streams_by_id);
while (node) {
int ret;
uint64_t id;
qcs = eb64_entry(node, struct qcs, by_id);
id = qcs->id;
if (quic_stream_is_uni(id) && quic_stream_is_remote(qcc, id)) {
node = eb64_next(node);
continue;
}
if (qcs->flags & QC_SF_TO_RESET) {
qcs_send_reset(qcs);
node = eb64_next(node);
continue;
}
if (qcs_is_close_local(qcs)) {
node = eb64_next(node);
continue;
}
if (qcs->flags & QC_SF_BLK_SFCTL) {
node = eb64_next(node);
continue;
}
if (!b_data(&qcs->tx.buf) && !qc_stream_buf_get(qcs->stream)) {
node = eb64_next(node);
continue;
}
ret = _qc_send_qcs(qcs, &frms);
total += ret;
node = eb64_next(node);
}
if (qc_send_frames(qcc, &frms)) {
/* data rejected by transport layer, do not retry. */
goto out;
}
retry:
tmp_total = 0;
list_for_each_entry_safe(qcs, qcs_tmp, &qcc->send_retry_list, el) {
int ret;
BUG_ON(!b_data(&qcs->tx.buf));
BUG_ON(qc_stream_buf_get(qcs->stream));
ret = _qc_send_qcs(qcs, &frms);
tmp_total += ret;
LIST_DELETE(&qcs->el);
}
total += tmp_total;
if (!qc_send_frames(qcc, &frms) && !LIST_ISEMPTY(&qcc->send_retry_list))
goto retry;
out:
/* Deallocate frames that the transport layer has rejected. */
if (!LIST_ISEMPTY(&frms)) {
struct quic_frame *frm, *frm2;
list_for_each_entry_safe(frm, frm2, &frms, list) {
LIST_DELETE(&frm->list);
pool_free(pool_head_quic_frame, frm);
}
}
TRACE_LEAVE(QMUX_EV_QCC_SEND, qcc->conn);
return total;
err:
TRACE_LEAVE(QMUX_EV_QCC_SEND, qcc->conn);
return 0;
}
/* Proceed on receiving. Loop through all streams from <qcc> and use decode_qcs
* operation.
*
* Returns 0 on success else non-zero.
*/
static int qc_recv(struct qcc *qcc)
{
struct eb64_node *node;
struct qcs *qcs;
TRACE_ENTER(QMUX_EV_QCC_RECV, qcc->conn);
if (qcc->flags & QC_CF_CC_EMIT) {
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 0;
}
node = eb64_first(&qcc->streams_by_id);
while (node) {
uint64_t id;
qcs = eb64_entry(node, struct qcs, by_id);
id = qcs->id;
if (!ncb_data(&qcs->rx.ncbuf, 0) || (qcs->flags & QC_SF_DEM_FULL)) {
node = eb64_next(node);
continue;
}
if (quic_stream_is_uni(id) && quic_stream_is_local(qcc, id)) {
node = eb64_next(node);
continue;
}
qcc_decode_qcs(qcc, qcs);
node = eb64_next(node);
if (qcs->flags & QC_SF_READ_ABORTED) {
/* TODO should send a STOP_SENDING */
qcs_free(qcs);
}
}
TRACE_LEAVE(QMUX_EV_QCC_RECV, qcc->conn);
return 0;
}
/* Release all streams which have their transfer operation achieved.
*
* Returns true if at least one stream is released.
*/
static int qc_purge_streams(struct qcc *qcc)
{
struct eb64_node *node;
int release = 0;
TRACE_ENTER(QMUX_EV_QCC_WAKE, qcc->conn);
node = eb64_first(&qcc->streams_by_id);
while (node) {
struct qcs *qcs = eb64_entry(node, struct qcs, by_id);
node = eb64_next(node);
/* Release not attached closed streams. */
if (qcs->st == QC_SS_CLO && !qcs_sc(qcs)) {
TRACE_STATE("purging closed stream", QMUX_EV_QCC_WAKE, qcs->qcc->conn, qcs);
qcs_destroy(qcs);
release = 1;
continue;
}
/* Release detached streams with empty buffer. */
if (qcs->flags & QC_SF_DETACH) {
if (qcs_is_close_local(qcs)) {
TRACE_STATE("purging detached stream", QMUX_EV_QCC_WAKE, qcs->qcc->conn, qcs);
qcs_destroy(qcs);
release = 1;
continue;
}
qcc->conn->xprt->subscribe(qcc->conn, qcc->conn->xprt_ctx,
SUB_RETRY_SEND, &qcc->wait_event);
}
}
TRACE_LEAVE(QMUX_EV_QCC_WAKE, qcc->conn);
return release;
}
/* release function. This one should be called to free all resources allocated
* to the mux.
*/
static void qc_release(struct qcc *qcc)
{
struct connection *conn = qcc->conn;
struct eb64_node *node;
TRACE_ENTER(QMUX_EV_QCC_END, conn);
if (qcc->app_ops && qcc->app_ops->shutdown) {
/* Application protocol with dedicated connection closing
* procedure.
*/
qcc->app_ops->shutdown(qcc->ctx);
/* useful if application protocol should emit some closing
* frames. For example HTTP/3 GOAWAY frame.
*/
qc_send(qcc);
}
else {
qcc_emit_cc_app(qcc, QC_ERR_NO_ERROR, 0);
}
if (qcc->task) {
task_destroy(qcc->task);
qcc->task = NULL;
}
if (qcc->wait_event.tasklet)
tasklet_free(qcc->wait_event.tasklet);
if (conn && qcc->wait_event.events) {
conn->xprt->unsubscribe(conn, conn->xprt_ctx,
qcc->wait_event.events,
&qcc->wait_event);
}
/* liberate remaining qcs instances */
node = eb64_first(&qcc->streams_by_id);
while (node) {
struct qcs *qcs = eb64_entry(node, struct qcs, by_id);
node = eb64_next(node);
qcs_free(qcs);
}
while (!LIST_ISEMPTY(&qcc->lfctl.frms)) {
struct quic_frame *frm = LIST_ELEM(qcc->lfctl.frms.n, struct quic_frame *, list);
LIST_DELETE(&frm->list);
pool_free(pool_head_quic_frame, frm);
}
if (qcc->app_ops && qcc->app_ops->release)
qcc->app_ops->release(qcc->ctx);
TRACE_PROTO("application layer released", QMUX_EV_QCC_END, conn);
pool_free(pool_head_qcc, qcc);
if (conn) {
LIST_DEL_INIT(&conn->stopping_list);
conn->handle.qc->conn = NULL;
conn->mux = NULL;
conn->ctx = NULL;
TRACE_DEVEL("freeing conn", QMUX_EV_QCC_END, conn);
conn_stop_tracking(conn);
conn_full_close(conn);
if (conn->destroy_cb)
conn->destroy_cb(conn);
conn_free(conn);
}
TRACE_LEAVE(QMUX_EV_QCC_END);
}
struct task *qc_io_cb(struct task *t, void *ctx, unsigned int status)
{
struct qcc *qcc = ctx;
TRACE_ENTER(QMUX_EV_QCC_WAKE, qcc->conn);
qc_send(qcc);
if (qc_purge_streams(qcc)) {
if (qcc_is_dead(qcc)) {
TRACE_STATE("releasing dead connection", QMUX_EV_QCC_WAKE, qcc->conn);
goto release;
}
}
qc_recv(qcc);
/* TODO check if qcc proxy is disabled. If yes, use graceful shutdown
* to close the connection.
*/
qcc_refresh_timeout(qcc);
end:
TRACE_LEAVE(QMUX_EV_QCC_WAKE, qcc->conn);
return NULL;
release:
qc_release(qcc);
TRACE_LEAVE(QMUX_EV_QCC_WAKE);
return NULL;
}
static struct task *qc_timeout_task(struct task *t, void *ctx, unsigned int state)
{
struct qcc *qcc = ctx;
int expired = tick_is_expired(t->expire, now_ms);
TRACE_ENTER(QMUX_EV_QCC_WAKE, qcc ? qcc->conn : NULL);
if (qcc) {
if (!expired) {
TRACE_DEVEL("not expired", QMUX_EV_QCC_WAKE, qcc->conn);
goto requeue;
}
if (!qcc_may_expire(qcc)) {
TRACE_DEVEL("cannot expired", QMUX_EV_QCC_WAKE, qcc->conn);
t->expire = TICK_ETERNITY;
goto requeue;
}
}
task_destroy(t);
if (!qcc) {
TRACE_DEVEL("no more qcc", QMUX_EV_QCC_WAKE);
goto out;
}
qcc->task = NULL;
/* TODO depending on the timeout condition, different shutdown mode
* should be used. For http keep-alive or disabled proxy, a graceful
* shutdown should occurs. For all other cases, an immediate close
* seems legitimate.
*/
if (qcc_is_dead(qcc)) {
TRACE_STATE("releasing dead connection", QMUX_EV_QCC_WAKE, qcc->conn);
qc_release(qcc);
}
out:
TRACE_LEAVE(QMUX_EV_QCC_WAKE);
return NULL;
requeue:
TRACE_LEAVE(QMUX_EV_QCC_WAKE);
return t;
}
static int qc_init(struct connection *conn, struct proxy *prx,
struct session *sess, struct buffer *input)
{
struct qcc *qcc;
struct quic_transport_params *lparams, *rparams;
TRACE_ENTER(QMUX_EV_QCC_NEW);
qcc = pool_alloc(pool_head_qcc);
if (!qcc) {
TRACE_ERROR("alloc failure", QMUX_EV_QCC_NEW);
goto fail_no_qcc;
}
qcc->conn = conn;
conn->ctx = qcc;
qcc->nb_hreq = qcc->nb_sc = 0;
qcc->flags = 0;
qcc->app_ops = NULL;
if (qcc_install_app_ops(qcc, conn->handle.qc->app_ops)) {
TRACE_PROTO("Cannot install app layer", QMUX_EV_QCC_NEW, qcc->conn);
/* prepare a CONNECTION_CLOSE frame */
quic_set_connection_close(conn->handle.qc, quic_err_transport(QC_ERR_APPLICATION_ERROR));
goto fail_no_tasklet;
}
qcc->streams_by_id = EB_ROOT_UNIQUE;
/* Server parameters, params used for RX flow control. */
lparams = &conn->handle.qc->rx.params;
qcc->rx.max_data = lparams->initial_max_data;
qcc->tx.sent_offsets = qcc->tx.offsets = 0;
/* Client initiated streams must respect the server flow control. */
qcc->strms[QCS_CLT_BIDI].max_streams = lparams->initial_max_streams_bidi;
qcc->strms[QCS_CLT_BIDI].nb_streams = 0;
qcc->strms[QCS_CLT_BIDI].rx.max_data = 0;
qcc->strms[QCS_CLT_BIDI].tx.max_data = lparams->initial_max_stream_data_bidi_remote;
qcc->strms[QCS_CLT_UNI].max_streams = lparams->initial_max_streams_uni;
qcc->strms[QCS_CLT_UNI].nb_streams = 0;
qcc->strms[QCS_CLT_UNI].rx.max_data = 0;
qcc->strms[QCS_CLT_UNI].tx.max_data = lparams->initial_max_stream_data_uni;
/* Server initiated streams must respect the server flow control. */
qcc->strms[QCS_SRV_BIDI].max_streams = 0;
qcc->strms[QCS_SRV_BIDI].nb_streams = 0;
qcc->strms[QCS_SRV_BIDI].rx.max_data = lparams->initial_max_stream_data_bidi_local;
qcc->strms[QCS_SRV_BIDI].tx.max_data = 0;
qcc->strms[QCS_SRV_UNI].max_streams = 0;
qcc->strms[QCS_SRV_UNI].nb_streams = 0;
qcc->strms[QCS_SRV_UNI].rx.max_data = lparams->initial_max_stream_data_uni;
qcc->strms[QCS_SRV_UNI].tx.max_data = 0;
LIST_INIT(&qcc->lfctl.frms);
qcc->lfctl.ms_bidi = qcc->lfctl.ms_bidi_init = lparams->initial_max_streams_bidi;
qcc->lfctl.ms_uni = lparams->initial_max_streams_uni;
qcc->lfctl.msd_bidi_l = lparams->initial_max_stream_data_bidi_local;
qcc->lfctl.msd_bidi_r = lparams->initial_max_stream_data_bidi_remote;
qcc->lfctl.msd_uni_r = lparams->initial_max_stream_data_uni;
qcc->lfctl.cl_bidi_r = 0;
qcc->lfctl.md = qcc->lfctl.md_init = lparams->initial_max_data;
qcc->lfctl.offsets_recv = qcc->lfctl.offsets_consume = 0;
rparams = &conn->handle.qc->tx.params;
qcc->rfctl.md = rparams->initial_max_data;
qcc->rfctl.msd_bidi_l = rparams->initial_max_stream_data_bidi_local;
qcc->rfctl.msd_bidi_r = rparams->initial_max_stream_data_bidi_remote;
qcc->rfctl.msd_uni_l = rparams->initial_max_stream_data_uni;
if (conn_is_back(conn)) {
qcc->next_bidi_l = 0x00;
qcc->largest_bidi_r = 0x01;
qcc->next_uni_l = 0x02;
qcc->largest_uni_r = 0x03;
}
else {
qcc->largest_bidi_r = 0x00;
qcc->next_bidi_l = 0x01;
qcc->largest_uni_r = 0x02;
qcc->next_uni_l = 0x03;
}
qcc->wait_event.tasklet = tasklet_new();
if (!qcc->wait_event.tasklet) {
TRACE_ERROR("taslket alloc failure", QMUX_EV_QCC_NEW);
goto fail_no_tasklet;
}
LIST_INIT(&qcc->send_retry_list);
qcc->wait_event.tasklet->process = qc_io_cb;
qcc->wait_event.tasklet->context = qcc;
qcc->wait_event.events = 0;
qcc->proxy = prx;
/* haproxy timeouts */
qcc->task = NULL;
qcc->timeout = conn_is_back(qcc->conn) ? prx->timeout.server :
prx->timeout.client;
if (tick_isset(qcc->timeout)) {
qcc->task = task_new_here();
if (!qcc->task) {
TRACE_ERROR("timeout task alloc failure", QMUX_EV_QCC_NEW);
goto fail_no_timeout_task;
}
qcc->task->process = qc_timeout_task;
qcc->task->context = qcc;
qcc->task->expire = tick_add(now_ms, qcc->timeout);
}
qcc_reset_idle_start(qcc);
LIST_INIT(&qcc->opening_list);
if (!conn_is_back(conn)) {
if (!LIST_INLIST(&conn->stopping_list)) {
LIST_APPEND(&mux_stopping_data[tid].list,
&conn->stopping_list);
}
}
HA_ATOMIC_STORE(&conn->handle.qc->qcc, qcc);
/* init read cycle */
tasklet_wakeup(qcc->wait_event.tasklet);
TRACE_LEAVE(QMUX_EV_QCC_NEW, qcc->conn);
return 0;
fail_no_timeout_task:
tasklet_free(qcc->wait_event.tasklet);
fail_no_tasklet:
if (qcc->app_ops && qcc->app_ops->release)
qcc->app_ops->release(qcc->ctx);
pool_free(pool_head_qcc, qcc);
fail_no_qcc:
TRACE_LEAVE(QMUX_EV_QCC_NEW);
return -1;
}
static void qc_destroy(void *ctx)
{
struct qcc *qcc = ctx;
TRACE_ENTER(QMUX_EV_QCC_END, qcc->conn);
qc_release(qcc);
TRACE_LEAVE(QMUX_EV_QCC_END);
}
static void qc_detach(struct sedesc *sd)
{
struct qcs *qcs = sd->se;
struct qcc *qcc = qcs->qcc;
TRACE_ENTER(QMUX_EV_STRM_END, qcc->conn, qcs);
/* TODO this BUG_ON_HOT() is not correct as the stconn layer may detach
* from the stream even if it is not closed remotely at the QUIC layer.
* This happens for example when a stream must be closed due to a
* rejected request. To better handle these cases, it will be required
* to implement shutr/shutw MUX operations. Once this is done, this
* BUG_ON_HOT() statement can be adjusted.
*/
//BUG_ON_HOT(!qcs_is_close_remote(qcs));
qcc_rm_sc(qcc);
if (!qcs_is_close_local(qcs) && !(qcc->conn->flags & CO_FL_ERROR)) {
TRACE_STATE("remaining data, detaching qcs", QMUX_EV_STRM_END, qcc->conn, qcs);
qcs->flags |= QC_SF_DETACH;
qcc_refresh_timeout(qcc);
TRACE_LEAVE(QMUX_EV_STRM_END, qcc->conn, qcs);
return;
}
qcs_destroy(qcs);
if (qcc_is_dead(qcc)) {
TRACE_STATE("killing dead connection", QMUX_EV_STRM_END, qcc->conn);
goto release;
}
else if (qcc->task) {
TRACE_DEVEL("refreshing connection's timeout", QMUX_EV_STRM_END, qcc->conn);
qcc_refresh_timeout(qcc);
}
else {
TRACE_DEVEL("completed", QMUX_EV_STRM_END, qcc->conn);
}
TRACE_LEAVE(QMUX_EV_STRM_END, qcc->conn);
return;
release:
qc_release(qcc);
TRACE_LEAVE(QMUX_EV_STRM_END);
return;
}
/* Called from the upper layer, to receive data */
static size_t qc_recv_buf(struct stconn *sc, struct buffer *buf,
size_t count, int flags)
{
struct qcs *qcs = __sc_mux_strm(sc);
size_t ret = 0;
char fin = 0;
TRACE_ENTER(QMUX_EV_STRM_RECV, qcs->qcc->conn, qcs);
ret = qcs_http_rcv_buf(qcs, buf, count, &fin);
if (b_data(&qcs->rx.app_buf)) {
se_fl_set(qcs->sd, SE_FL_RCV_MORE | SE_FL_WANT_ROOM);
}
else {
se_fl_clr(qcs->sd, SE_FL_RCV_MORE | SE_FL_WANT_ROOM);
if (se_fl_test(qcs->sd, SE_FL_ERR_PENDING))
se_fl_set(qcs->sd, SE_FL_ERROR);
/* Set end-of-input if FIN received and all data extracted. */
if (fin)
se_fl_set(qcs->sd, SE_FL_EOI);
if (b_size(&qcs->rx.app_buf)) {
b_free(&qcs->rx.app_buf);
offer_buffers(NULL, 1);
}
}
if (ret) {
qcs->flags &= ~QC_SF_DEM_FULL;
tasklet_wakeup(qcs->qcc->wait_event.tasklet);
}
TRACE_LEAVE(QMUX_EV_STRM_RECV, qcs->qcc->conn, qcs);
return ret;
}
static size_t qc_send_buf(struct stconn *sc, struct buffer *buf,
size_t count, int flags)
{
struct qcs *qcs = __sc_mux_strm(sc);
size_t ret;
char fin;
TRACE_ENTER(QMUX_EV_STRM_SEND, qcs->qcc->conn, qcs);
/* stream layer has been detached so no transfer must occur after. */
BUG_ON_HOT(qcs->flags & QC_SF_DETACH);
if (qcs_is_close_local(qcs) || (qcs->flags & QC_SF_TO_RESET)) {
ret = qcs_http_reset_buf(qcs, buf, count);
goto end;
}
ret = qcs_http_snd_buf(qcs, buf, count, &fin);
if (fin)
qcs->flags |= QC_SF_FIN_STREAM;
if (ret) {
if (!(qcs->qcc->wait_event.events & SUB_RETRY_SEND))
tasklet_wakeup(qcs->qcc->wait_event.tasklet);
}
end:
TRACE_LEAVE(QMUX_EV_STRM_SEND, qcs->qcc->conn, qcs);
return ret;
}
/* Called from the upper layer, to subscribe <es> to events <event_type>. The
* event subscriber <es> is not allowed to change from a previous call as long
* as at least one event is still subscribed. The <event_type> must only be a
* combination of SUB_RETRY_RECV and SUB_RETRY_SEND. It always returns 0.
*/
static int qc_subscribe(struct stconn *sc, int event_type,
struct wait_event *es)
{
return qcs_subscribe(__sc_mux_strm(sc), event_type, es);
}
/* Called from the upper layer, to unsubscribe <es> from events <event_type>.
* The <es> pointer is not allowed to differ from the one passed to the
* subscribe() call. It always returns zero.
*/
static int qc_unsubscribe(struct stconn *sc, int event_type, struct wait_event *es)
{
struct qcs *qcs = __sc_mux_strm(sc);
BUG_ON(event_type & ~(SUB_RETRY_SEND|SUB_RETRY_RECV));
BUG_ON(qcs->subs && qcs->subs != es);
es->events &= ~event_type;
if (!es->events)
qcs->subs = NULL;
return 0;
}
/* Loop through all qcs from <qcc>. If CO_FL_ERROR is set on the connection,
* report SE_FL_ERR_PENDING|SE_FL_ERROR on the attached stream connectors and
* wake them.
*/
static int qc_wake_some_streams(struct qcc *qcc)
{
struct qcs *qcs;
struct eb64_node *node;
for (node = eb64_first(&qcc->streams_by_id); node;
node = eb64_next(node)) {
qcs = eb64_entry(node, struct qcs, by_id);
if (!qcs_sc(qcs))
continue;
if (qcc->conn->flags & CO_FL_ERROR) {
se_fl_set(qcs->sd, SE_FL_ERR_PENDING);
if (se_fl_test(qcs->sd, SE_FL_EOS))
se_fl_set(qcs->sd, SE_FL_ERROR);
qcs_alert(qcs);
}
}
return 0;
}
static int qc_wake(struct connection *conn)
{
struct qcc *qcc = conn->ctx;
struct proxy *prx = conn->handle.qc->li->bind_conf->frontend;
TRACE_ENTER(QMUX_EV_QCC_WAKE, conn);
/* Check if a soft-stop is in progress.
*
* TODO this is relevant for frontend connections only.
*
* TODO Client should be notified with a H3 GOAWAY and then a
* CONNECTION_CLOSE. However, quic-conn uses the listener socket for
* sending which at this stage is already closed.
*/
if (unlikely(prx->flags & (PR_FL_DISABLED|PR_FL_STOPPED)))
qcc->conn->flags |= (CO_FL_SOCK_RD_SH|CO_FL_SOCK_WR_SH);
if (conn->handle.qc->flags & QUIC_FL_CONN_NOTIFY_CLOSE)
qcc->conn->flags |= (CO_FL_SOCK_RD_SH|CO_FL_SOCK_WR_SH);
qc_send(qcc);
qc_wake_some_streams(qcc);
if (qcc_is_dead(qcc))
goto release;
qcc_refresh_timeout(qcc);
TRACE_LEAVE(QMUX_EV_QCC_WAKE, conn);
return 0;
release:
TRACE_STATE("releasing dead connection", QMUX_EV_QCC_WAKE, qcc->conn);
qc_release(qcc);
TRACE_LEAVE(QMUX_EV_QCC_WAKE);
return 1;
}
/* for debugging with CLI's "show sess" command. May emit multiple lines, each
* new one being prefixed with <pfx>, if <pfx> is not NULL, otherwise a single
* line is used. Each field starts with a space so it's safe to print it after
* existing fields.
*/
static int qc_show_sd(struct buffer *msg, struct sedesc *sd, const char *pfx)
{
struct qcs *qcs = sd->se;
struct qcc *qcc;
int ret = 0;
if (!qcs)
return ret;
chunk_appendf(msg, " qcs=%p .flg=%#x .id=%llu .st=%s .ctx=%p, .err=%#llx",
qcs, qcs->flags, (ull)qcs->id, qcs_st_to_str(qcs->st), qcs->ctx, (ull)qcs->err);
if (pfx)
chunk_appendf(msg, "\n%s", pfx);
qcc = qcs->qcc;
chunk_appendf(msg, " qcc=%p .flg=%#x .nbsc=%llu .nbhreq=%llu, .task=%p",
qcc, qcc->flags, (ull)qcc->nb_sc, (ull)qcc->nb_hreq, qcc->task);
return ret;
}
static const struct mux_ops qc_ops = {
.init = qc_init,
.destroy = qc_destroy,
.detach = qc_detach,
.rcv_buf = qc_recv_buf,
.snd_buf = qc_send_buf,
.subscribe = qc_subscribe,
.unsubscribe = qc_unsubscribe,
.wake = qc_wake,
.show_sd = qc_show_sd,
.flags = MX_FL_HTX|MX_FL_NO_UPG|MX_FL_FRAMED,
.name = "QUIC",
};
static struct mux_proto_list mux_proto_quic =
{ .token = IST("quic"), .mode = PROTO_MODE_HTTP, .side = PROTO_SIDE_FE, .mux = &qc_ops };
INITCALL1(STG_REGISTER, register_mux_proto, &mux_proto_quic);