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|
/*
* QUIC socket management.
*
* Copyright 2020 HAProxy Technologies, Frederic Lecaille <flecaille@haproxy.com>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*
*/
#define _GNU_SOURCE /* required for struct in6_pktinfo */
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include <netinet/in.h>
#include <sys/socket.h>
#include <sys/types.h>
#include <haproxy/api.h>
#include <haproxy/buf.h>
#include <haproxy/connection.h>
#include <haproxy/dynbuf.h>
#include <haproxy/fd.h>
#include <haproxy/global-t.h>
#include <haproxy/list.h>
#include <haproxy/listener.h>
#include <haproxy/log.h>
#include <haproxy/pool.h>
#include <haproxy/proto_quic.h>
#include <haproxy/proxy-t.h>
#include <haproxy/quic_cid.h>
#include <haproxy/quic_conn.h>
#include <haproxy/quic_rx.h>
#include <haproxy/quic_sock.h>
#include <haproxy/quic_tp-t.h>
#include <haproxy/quic_trace.h>
#include <haproxy/session.h>
#include <haproxy/stats-t.h>
#include <haproxy/task.h>
#include <haproxy/trace.h>
#include <haproxy/tools.h>
#include <haproxy/trace.h>
/* Log only first EACCES bind() error runtime occurrence. */
static volatile char quic_bind_eacces_warn = 0;
/* Retrieve a connection's source address. Returns -1 on failure. */
int quic_sock_get_src(struct connection *conn, struct sockaddr *addr, socklen_t len)
{
struct quic_conn *qc;
if (!conn || !conn->handle.qc)
return -1;
qc = conn->handle.qc;
if (conn_is_back(conn)) {
/* no source address defined for outgoing connections for now */
return -1;
} else {
/* front connection, return the peer's address */
if (len > sizeof(qc->peer_addr))
len = sizeof(qc->peer_addr);
memcpy(addr, &qc->peer_addr, len);
return 0;
}
}
/* Retrieve a connection's destination address. Returns -1 on failure. */
int quic_sock_get_dst(struct connection *conn, struct sockaddr *addr, socklen_t len)
{
struct quic_conn *qc;
if (!conn || !conn->handle.qc)
return -1;
qc = conn->handle.qc;
if (conn_is_back(conn)) {
/* back connection, return the peer's address */
if (len > sizeof(qc->peer_addr))
len = sizeof(qc->peer_addr);
memcpy(addr, &qc->peer_addr, len);
} else {
struct sockaddr_storage *from;
/* Return listener address if IP_PKTINFO or friends are not
* supported by the socket.
*/
BUG_ON(!qc->li);
from = is_addr(&qc->local_addr) ? &qc->local_addr :
&qc->li->rx.addr;
if (len > sizeof(*from))
len = sizeof(*from);
memcpy(addr, from, len);
}
return 0;
}
/*
* Inspired from session_accept_fd().
* Instantiate a new connection (connection struct) to be attached to <qc>
* QUIC connection of <l> listener.
* Returns 1 if succeeded, 0 if not.
*/
static int new_quic_cli_conn(struct quic_conn *qc, struct listener *l,
struct sockaddr_storage *saddr)
{
struct connection *cli_conn;
if (unlikely((cli_conn = conn_new(&l->obj_type)) == NULL))
goto out;
if (!sockaddr_alloc(&cli_conn->src, saddr, sizeof *saddr))
goto out_free_conn;
cli_conn->flags |= CO_FL_FDLESS;
qc->conn = cli_conn;
cli_conn->handle.qc = qc;
cli_conn->target = &l->obj_type;
return 1;
out_free_conn:
qc->conn = NULL;
conn_stop_tracking(cli_conn);
conn_xprt_close(cli_conn);
conn_free(cli_conn);
out:
return 0;
}
/* Tests if the receiver supports accepting connections. Returns positive on
* success, 0 if not possible
*/
int quic_sock_accepting_conn(const struct receiver *rx)
{
return 1;
}
/* Accept an incoming connection from listener <l>, and return it, as well as
* a CO_AC_* status code into <status> if not null. Null is returned on error.
* <l> must be a valid listener with a valid frontend.
*/
struct connection *quic_sock_accept_conn(struct listener *l, int *status)
{
struct quic_conn *qc;
struct li_per_thread *lthr = &l->per_thr[ti->ltid];
qc = MT_LIST_POP(<hr->quic_accept.conns, struct quic_conn *, accept_list);
if (!qc || qc->flags & (QUIC_FL_CONN_CLOSING|QUIC_FL_CONN_DRAINING))
goto done;
if (!new_quic_cli_conn(qc, l, &qc->peer_addr))
goto err;
done:
*status = CO_AC_DONE;
if (qc) {
BUG_ON(l->rx.quic_curr_accept <= 0);
HA_ATOMIC_DEC(&l->rx.quic_curr_accept);
return qc->conn;
}
else {
return NULL;
}
err:
/* in case of error reinsert the element to process it later. */
MT_LIST_INSERT(<hr->quic_accept.conns, &qc->accept_list);
*status = CO_AC_PAUSE;
return NULL;
}
/* QUIC datagrams handler task. */
struct task *quic_lstnr_dghdlr(struct task *t, void *ctx, unsigned int state)
{
struct quic_dghdlr *dghdlr = ctx;
struct quic_dgram *dgram;
int max_dgrams = global.tune.maxpollevents;
TRACE_ENTER(QUIC_EV_CONN_LPKT);
while ((dgram = MT_LIST_POP(&dghdlr->dgrams, typeof(dgram), handler_list))) {
if (quic_dgram_parse(dgram, NULL, dgram->owner)) {
/* TODO should we requeue the datagram ? */
break;
}
if (--max_dgrams <= 0)
goto stop_here;
}
TRACE_LEAVE(QUIC_EV_CONN_LPKT);
return t;
stop_here:
/* too much work done at once, come back here later */
if (!MT_LIST_ISEMPTY(&dghdlr->dgrams))
tasklet_wakeup((struct tasklet *)t);
TRACE_LEAVE(QUIC_EV_CONN_LPKT);
return t;
}
/* Retrieve the DCID from a QUIC datagram or packet at <pos> position,
* <end> being at one byte past the end of this datagram.
* Returns 1 if succeeded, 0 if not.
*/
static int quic_get_dgram_dcid(unsigned char *pos, const unsigned char *end,
unsigned char **dcid, size_t *dcid_len)
{
int ret = 0, long_header;
size_t minlen, skip;
TRACE_ENTER(QUIC_EV_CONN_RXPKT);
if (!(*pos & QUIC_PACKET_FIXED_BIT)) {
TRACE_PROTO("fixed bit not set", QUIC_EV_CONN_RXPKT);
goto err;
}
long_header = *pos & QUIC_PACKET_LONG_HEADER_BIT;
minlen = long_header ? QUIC_LONG_PACKET_MINLEN :
QUIC_SHORT_PACKET_MINLEN + QUIC_HAP_CID_LEN + QUIC_TLS_TAG_LEN;
skip = long_header ? QUIC_LONG_PACKET_DCID_OFF : QUIC_SHORT_PACKET_DCID_OFF;
if (end - pos < minlen)
goto err;
pos += skip;
*dcid_len = long_header ? *pos++ : QUIC_HAP_CID_LEN;
if (*dcid_len > QUIC_CID_MAXLEN || end - pos <= *dcid_len)
goto err;
*dcid = pos;
ret = 1;
leave:
TRACE_LEAVE(QUIC_EV_CONN_RXPKT);
return ret;
err:
TRACE_PROTO("wrong datagram", QUIC_EV_CONN_RXPKT);
goto leave;
}
/* Retrieve the DCID from the datagram found at <pos> position and deliver it to the
* correct datagram handler.
* Return 1 if a correct datagram could be found, 0 if not.
*/
static int quic_lstnr_dgram_dispatch(unsigned char *pos, size_t len, void *owner,
struct sockaddr_storage *saddr,
struct sockaddr_storage *daddr,
struct quic_dgram *new_dgram, struct list *dgrams)
{
struct quic_dgram *dgram;
unsigned char *dcid;
size_t dcid_len;
int cid_tid;
if (!len || !quic_get_dgram_dcid(pos, pos + len, &dcid, &dcid_len))
goto err;
dgram = new_dgram ? new_dgram : pool_alloc(pool_head_quic_dgram);
if (!dgram)
goto err;
if ((cid_tid = quic_get_cid_tid(dcid, dcid_len, saddr, pos, len)) < 0) {
/* Use the current thread if CID not found. If a clients opens
* a connection with multiple packets, it is possible that
* several threads will deal with datagrams sharing the same
* CID. For this reason, the CID tree insertion will be
* conducted as an atomic operation and the datagram ultimately
* redispatch by the late thread.
*/
cid_tid = tid;
}
/* All the members must be initialized! */
dgram->owner = owner;
dgram->buf = pos;
dgram->len = len;
dgram->dcid = dcid;
dgram->dcid_len = dcid_len;
dgram->saddr = *saddr;
dgram->daddr = *daddr;
dgram->qc = NULL;
/* Attached datagram to its quic_receiver_buf and quic_dghdlrs. */
LIST_APPEND(dgrams, &dgram->recv_list);
MT_LIST_APPEND(&quic_dghdlrs[cid_tid].dgrams, &dgram->handler_list);
/* typically quic_lstnr_dghdlr() */
tasklet_wakeup(quic_dghdlrs[cid_tid].task);
return 1;
err:
pool_free(pool_head_quic_dgram, new_dgram);
return 0;
}
/* This function is responsible to remove unused datagram attached in front of
* <buf>. Each instances will be freed until a not yet consumed datagram is
* found or end of the list is hit. The last unused datagram found is not freed
* and is instead returned so that the caller can reuse it if needed.
*
* Returns the last unused datagram or NULL if no occurrence found.
*/
static struct quic_dgram *quic_rxbuf_purge_dgrams(struct quic_receiver_buf *rbuf)
{
struct quic_dgram *cur, *prev = NULL;
while (!LIST_ISEMPTY(&rbuf->dgram_list)) {
cur = LIST_ELEM(rbuf->dgram_list.n, struct quic_dgram *, recv_list);
/* Loop until a not yet consumed datagram is found. */
if (HA_ATOMIC_LOAD(&cur->buf))
break;
/* Clear buffer of current unused datagram. */
LIST_DELETE(&cur->recv_list);
b_del(&rbuf->buf, cur->len);
/* Free last found unused datagram. */
pool_free(pool_head_quic_dgram, prev);
prev = cur;
}
/* Return last unused datagram found. */
return prev;
}
/* Receive data from datagram socket <fd>. Data are placed in <out> buffer of
* length <len>.
*
* Datagram addresses will be returned via the next arguments. <from> will be
* the peer address and <to> the reception one. Note that <to> can only be
* retrieved if the socket supports IP_PKTINFO or affiliated options. If not,
* <to> will be set as AF_UNSPEC. The caller must specify <to_port> to ensure
* that <to> address is completely filled.
*
* Returns value from recvmsg syscall.
*/
static ssize_t quic_recv(int fd, void *out, size_t len,
struct sockaddr *from, socklen_t from_len,
struct sockaddr *to, socklen_t to_len,
uint16_t dst_port)
{
union pktinfo {
#ifdef IP_PKTINFO
struct in_pktinfo in;
#else /* !IP_PKTINFO */
struct in_addr addr;
#endif
#ifdef IPV6_RECVPKTINFO
struct in6_pktinfo in6;
#endif
};
char cdata[CMSG_SPACE(sizeof(union pktinfo))];
struct msghdr msg;
struct iovec vec;
struct cmsghdr *cmsg;
ssize_t ret;
vec.iov_base = out;
vec.iov_len = len;
memset(&msg, 0, sizeof(msg));
msg.msg_name = from;
msg.msg_namelen = from_len;
msg.msg_iov = &vec;
msg.msg_iovlen = 1;
msg.msg_control = &cdata;
msg.msg_controllen = sizeof(cdata);
clear_addr((struct sockaddr_storage *)to);
do {
ret = recvmsg(fd, &msg, 0);
} while (ret < 0 && errno == EINTR);
/* TODO handle errno. On EAGAIN/EWOULDBLOCK use fd_cant_recv() if
* using dedicated connection socket.
*/
if (ret < 0)
goto end;
for (cmsg = CMSG_FIRSTHDR(&msg); cmsg; cmsg = CMSG_NXTHDR(&msg, cmsg)) {
switch (cmsg->cmsg_level) {
case IPPROTO_IP:
#if defined(IP_PKTINFO)
if (cmsg->cmsg_type == IP_PKTINFO) {
struct sockaddr_in *in = (struct sockaddr_in *)to;
struct in_pktinfo *info = (struct in_pktinfo *)CMSG_DATA(cmsg);
if (to_len >= sizeof(struct sockaddr_in)) {
in->sin_family = AF_INET;
in->sin_addr = info->ipi_addr;
in->sin_port = dst_port;
}
}
#elif defined(IP_RECVDSTADDR)
if (cmsg->cmsg_type == IP_RECVDSTADDR) {
struct sockaddr_in *in = (struct sockaddr_in *)to;
struct in_addr *info = (struct in_addr *)CMSG_DATA(cmsg);
if (to_len >= sizeof(struct sockaddr_in)) {
in->sin_family = AF_INET;
in->sin_addr.s_addr = info->s_addr;
in->sin_port = dst_port;
}
}
#endif /* IP_PKTINFO || IP_RECVDSTADDR */
break;
case IPPROTO_IPV6:
#ifdef IPV6_RECVPKTINFO
if (cmsg->cmsg_type == IPV6_PKTINFO) {
struct sockaddr_in6 *in6 = (struct sockaddr_in6 *)to;
struct in6_pktinfo *info6 = (struct in6_pktinfo *)CMSG_DATA(cmsg);
if (to_len >= sizeof(struct sockaddr_in6)) {
in6->sin6_family = AF_INET6;
memcpy(&in6->sin6_addr, &info6->ipi6_addr, sizeof(in6->sin6_addr));
in6->sin6_port = dst_port;
}
}
#endif
break;
}
}
end:
return ret;
}
/* Function called on a read event from a listening socket. It tries
* to handle as many connections as possible.
*/
void quic_lstnr_sock_fd_iocb(int fd)
{
ssize_t ret;
struct quic_receiver_buf *rxbuf;
struct buffer *buf;
struct listener *l = objt_listener(fdtab[fd].owner);
struct quic_transport_params *params;
/* Source address */
struct sockaddr_storage saddr = {0}, daddr = {0};
size_t max_sz, cspace;
struct quic_dgram *new_dgram;
unsigned char *dgram_buf;
int max_dgrams;
BUG_ON(!l);
new_dgram = NULL;
if (!l)
return;
if (!(fdtab[fd].state & FD_POLL_IN) || !fd_recv_ready(fd))
return;
rxbuf = MT_LIST_POP(&l->rx.rxbuf_list, typeof(rxbuf), rxbuf_el);
if (!rxbuf)
goto out;
buf = &rxbuf->buf;
max_dgrams = global.tune.maxpollevents;
start:
/* Try to reuse an existing dgram. Note that there is always at
* least one datagram to pick, except the first time we enter
* this function for this <rxbuf> buffer.
*/
new_dgram = quic_rxbuf_purge_dgrams(rxbuf);
params = &l->bind_conf->quic_params;
max_sz = params->max_udp_payload_size;
cspace = b_contig_space(buf);
if (cspace < max_sz) {
struct proxy *px = l->bind_conf->frontend;
struct quic_counters *prx_counters = EXTRA_COUNTERS_GET(px->extra_counters_fe, &quic_stats_module);
struct quic_dgram *dgram;
/* Do no mark <buf> as full, and do not try to consume it
* if the contiguous remaining space is not at the end
*/
if (b_tail(buf) + cspace < b_wrap(buf)) {
HA_ATOMIC_INC(&prx_counters->rxbuf_full);
goto out;
}
/* Allocate a fake datagram, without data to locate
* the end of the RX buffer (required during purging).
*/
dgram = pool_alloc(pool_head_quic_dgram);
if (!dgram)
goto out;
/* Initialize only the useful members of this fake datagram. */
dgram->buf = NULL;
dgram->len = cspace;
/* Append this datagram only to the RX buffer list. It will
* not be treated by any datagram handler.
*/
LIST_APPEND(&rxbuf->dgram_list, &dgram->recv_list);
/* Consume the remaining space */
b_add(buf, cspace);
if (b_contig_space(buf) < max_sz) {
HA_ATOMIC_INC(&prx_counters->rxbuf_full);
goto out;
}
}
dgram_buf = (unsigned char *)b_tail(buf);
ret = quic_recv(fd, dgram_buf, max_sz,
(struct sockaddr *)&saddr, sizeof(saddr),
(struct sockaddr *)&daddr, sizeof(daddr),
get_net_port(&l->rx.addr));
if (ret <= 0)
goto out;
b_add(buf, ret);
if (!quic_lstnr_dgram_dispatch(dgram_buf, ret, l, &saddr, &daddr,
new_dgram, &rxbuf->dgram_list)) {
/* If wrong, consume this datagram */
b_sub(buf, ret);
}
new_dgram = NULL;
if (--max_dgrams > 0)
goto start;
out:
pool_free(pool_head_quic_dgram, new_dgram);
MT_LIST_APPEND(&l->rx.rxbuf_list, &rxbuf->rxbuf_el);
}
/* FD-owned quic-conn socket callback. */
void quic_conn_sock_fd_iocb(int fd)
{
struct quic_conn *qc = fdtab[fd].owner;
TRACE_ENTER(QUIC_EV_CONN_RCV, qc);
if (fd_send_active(fd) && fd_send_ready(fd)) {
TRACE_DEVEL("send ready", QUIC_EV_CONN_RCV, qc);
fd_stop_send(fd);
tasklet_wakeup_after(NULL, qc->wait_event.tasklet);
qc_notify_send(qc);
}
if (fd_recv_ready(fd)) {
TRACE_DEVEL("recv ready", QUIC_EV_CONN_RCV, qc);
tasklet_wakeup_after(NULL, qc->wait_event.tasklet);
fd_stop_recv(fd);
}
TRACE_LEAVE(QUIC_EV_CONN_RCV, qc);
}
/* Send a datagram stored into <buf> buffer with <sz> as size.
* The caller must ensure there is at least <sz> bytes in this buffer.
*
* Returns the total bytes sent over the socket. 0 is returned if a transient
* error is encountered which allows send to be retry later. A negative value
* is used for a fatal error which guarantee that all future send operation for
* this connection will fail.
*
* TODO standardize this function for a generic UDP sendto wrapper. This can be
* done by removing the <qc> arg and replace it with address/port.
*/
int qc_snd_buf(struct quic_conn *qc, const struct buffer *buf, size_t sz,
int flags)
{
ssize_t ret;
do {
if (qc_test_fd(qc)) {
if (!fd_send_ready(qc->fd))
return 0;
ret = send(qc->fd, b_peek(buf, b_head_ofs(buf)), sz,
MSG_DONTWAIT | MSG_NOSIGNAL);
}
#if defined(IP_PKTINFO) || defined(IP_RECVDSTADDR) || defined(IPV6_RECVPKTINFO)
else if (is_addr(&qc->local_addr)) {
struct msghdr msg = { 0 };
struct iovec vec;
struct cmsghdr *cmsg;
#ifdef IP_PKTINFO
struct in_pktinfo in;
#endif /* IP_PKTINFO */
#ifdef IPV6_RECVPKTINFO
struct in6_pktinfo in6;
#endif /* IPV6_RECVPKTINFO */
union {
#ifdef IP_PKTINFO
char buf[CMSG_SPACE(sizeof(in))];
#endif /* IP_PKTINFO */
#ifdef IPV6_RECVPKTINFO
char buf6[CMSG_SPACE(sizeof(in6))];
#endif /* IPV6_RECVPKTINFO */
char bufaddr[CMSG_SPACE(sizeof(struct in_addr))];
struct cmsghdr align;
} u;
vec.iov_base = b_peek(buf, b_head_ofs(buf));
vec.iov_len = sz;
msg.msg_name = &qc->peer_addr;
msg.msg_namelen = get_addr_len(&qc->peer_addr);
msg.msg_iov = &vec;
msg.msg_iovlen = 1;
switch (qc->local_addr.ss_family) {
case AF_INET:
#if defined(IP_PKTINFO)
memset(&in, 0, sizeof(in));
memcpy(&in.ipi_spec_dst,
&((struct sockaddr_in *)&qc->local_addr)->sin_addr,
sizeof(struct in_addr));
msg.msg_control = u.buf;
msg.msg_controllen = sizeof(u.buf);
cmsg = CMSG_FIRSTHDR(&msg);
cmsg->cmsg_level = IPPROTO_IP;
cmsg->cmsg_type = IP_PKTINFO;
cmsg->cmsg_len = CMSG_LEN(sizeof(struct in_pktinfo));
memcpy(CMSG_DATA(cmsg), &in, sizeof(in));
#elif defined(IP_RECVDSTADDR)
msg.msg_control = u.bufaddr;
msg.msg_controllen = sizeof(u.bufaddr);
cmsg = CMSG_FIRSTHDR(&msg);
cmsg->cmsg_level = IPPROTO_IP;
cmsg->cmsg_type = IP_SENDSRCADDR;
cmsg->cmsg_len = CMSG_LEN(sizeof(struct in_addr));
memcpy(CMSG_DATA(cmsg),
&((struct sockaddr_in *)&qc->local_addr)->sin_addr,
sizeof(struct in_addr));
#endif /* IP_PKTINFO || IP_RECVDSTADDR */
break;
case AF_INET6:
#ifdef IPV6_RECVPKTINFO
memset(&in6, 0, sizeof(in6));
memcpy(&in6.ipi6_addr,
&((struct sockaddr_in6 *)&qc->local_addr)->sin6_addr,
sizeof(struct in6_addr));
msg.msg_control = u.buf6;
msg.msg_controllen = sizeof(u.buf6);
cmsg = CMSG_FIRSTHDR(&msg);
cmsg->cmsg_level = IPPROTO_IPV6;
cmsg->cmsg_type = IPV6_PKTINFO;
cmsg->cmsg_len = CMSG_LEN(sizeof(struct in6_pktinfo));
memcpy(CMSG_DATA(cmsg), &in6, sizeof(in6));
#endif /* IPV6_RECVPKTINFO */
break;
default:
break;
}
ret = sendmsg(qc->li->rx.fd, &msg,
MSG_DONTWAIT|MSG_NOSIGNAL);
}
#endif /* IP_PKTINFO || IP_RECVDSTADDR || IPV6_RECVPKTINFO */
else {
ret = sendto(qc->li->rx.fd, b_peek(buf, b_head_ofs(buf)), sz,
MSG_DONTWAIT|MSG_NOSIGNAL,
(struct sockaddr *)&qc->peer_addr,
get_addr_len(&qc->peer_addr));
}
} while (ret < 0 && errno == EINTR);
if (ret < 0) {
if (errno == EAGAIN || errno == EWOULDBLOCK ||
errno == ENOTCONN || errno == EINPROGRESS) {
/* transient error */
if (errno == EAGAIN || errno == EWOULDBLOCK)
qc->cntrs.socket_full++;
else
qc->cntrs.sendto_err++;
if (qc_test_fd(qc)) {
fd_want_send(qc->fd);
fd_cant_send(qc->fd);
}
TRACE_PRINTF(TRACE_LEVEL_USER, QUIC_EV_CONN_SPPKTS, qc, 0, 0, 0,
"UDP send failure errno=%d (%s)", errno, strerror(errno));
return 0;
}
else {
/* unrecoverable error */
qc->cntrs.sendto_err_unknown++;
TRACE_PRINTF(TRACE_LEVEL_USER, QUIC_EV_CONN_SPPKTS, qc, 0, 0, 0,
"UDP send failure errno=%d (%s)", errno, strerror(errno));
return -1;
}
}
if (ret != sz)
return 0;
return ret;
}
/* Receive datagram on <qc> FD-owned socket.
*
* Returns the total number of bytes read or a negative value on error.
*/
int qc_rcv_buf(struct quic_conn *qc)
{
struct sockaddr_storage saddr = {0}, daddr = {0};
struct quic_transport_params *params;
struct quic_dgram *new_dgram = NULL;
struct buffer buf = BUF_NULL;
size_t max_sz;
unsigned char *dgram_buf;
struct listener *l;
ssize_t ret = 0;
/* Do not call this if quic-conn FD is uninitialized. */
BUG_ON(qc->fd < 0);
TRACE_ENTER(QUIC_EV_CONN_RCV, qc);
l = qc->li;
params = &l->bind_conf->quic_params;
max_sz = params->max_udp_payload_size;
do {
if (!b_alloc(&buf))
break; /* TODO subscribe for memory again available. */
b_reset(&buf);
BUG_ON(b_contig_space(&buf) < max_sz);
/* Allocate datagram on first loop or after requeuing. */
if (!new_dgram && !(new_dgram = pool_alloc(pool_head_quic_dgram)))
break; /* TODO subscribe for memory again available. */
dgram_buf = (unsigned char *)b_tail(&buf);
ret = quic_recv(qc->fd, dgram_buf, max_sz,
(struct sockaddr *)&saddr, sizeof(saddr),
(struct sockaddr *)&daddr, sizeof(daddr),
get_net_port(&qc->local_addr));
if (ret <= 0) {
/* Subscribe FD for future reception. */
if (errno == EAGAIN || errno == EWOULDBLOCK || errno == ENOTCONN)
fd_want_recv(qc->fd);
/* TODO handle other error codes as fatal on the connection. */
break;
}
b_add(&buf, ret);
new_dgram->buf = dgram_buf;
new_dgram->len = ret;
new_dgram->dcid_len = 0;
new_dgram->dcid = NULL;
new_dgram->saddr = saddr;
new_dgram->daddr = daddr;
new_dgram->qc = NULL; /* set later via quic_dgram_parse() */
TRACE_DEVEL("read datagram", QUIC_EV_CONN_RCV, qc, new_dgram);
if (!quic_get_dgram_dcid(new_dgram->buf,
new_dgram->buf + new_dgram->len,
&new_dgram->dcid, &new_dgram->dcid_len)) {
continue;
}
if (!qc_check_dcid(qc, new_dgram->dcid, new_dgram->dcid_len)) {
/* Datagram received by error on the connection FD, dispatch it
* to its associated quic-conn.
*
* TODO count redispatch datagrams.
*/
struct quic_receiver_buf *rxbuf;
struct quic_dgram *tmp_dgram;
unsigned char *rxbuf_tail;
size_t cspace;
TRACE_STATE("datagram for other connection on quic-conn socket, requeue it", QUIC_EV_CONN_RCV, qc);
rxbuf = MT_LIST_POP(&l->rx.rxbuf_list, typeof(rxbuf), rxbuf_el);
ALREADY_CHECKED(rxbuf);
cspace = b_contig_space(&rxbuf->buf);
tmp_dgram = quic_rxbuf_purge_dgrams(rxbuf);
pool_free(pool_head_quic_dgram, tmp_dgram);
/* Insert a fake datagram if space wraps to consume it. */
if (cspace < new_dgram->len && b_space_wraps(&rxbuf->buf)) {
struct quic_dgram *fake_dgram = pool_alloc(pool_head_quic_dgram);
if (!fake_dgram) {
/* TODO count lost datagrams */
MT_LIST_APPEND(&l->rx.rxbuf_list, &rxbuf->rxbuf_el);
continue;
}
fake_dgram->buf = NULL;
fake_dgram->len = cspace;
LIST_APPEND(&rxbuf->dgram_list, &fake_dgram->recv_list);
b_add(&rxbuf->buf, cspace);
}
/* Recheck contig space after fake datagram insert. */
if (b_contig_space(&rxbuf->buf) < new_dgram->len) {
/* TODO count lost datagrams */
MT_LIST_APPEND(&l->rx.rxbuf_list, &rxbuf->rxbuf_el);
continue;
}
rxbuf_tail = (unsigned char *)b_tail(&rxbuf->buf);
__b_putblk(&rxbuf->buf, (char *)dgram_buf, new_dgram->len);
if (!quic_lstnr_dgram_dispatch(rxbuf_tail, ret, l, &saddr, &daddr,
new_dgram, &rxbuf->dgram_list)) {
/* TODO count lost datagrams. */
b_sub(&buf, ret);
}
else {
/* datagram must not be freed as it was requeued. */
new_dgram = NULL;
}
MT_LIST_APPEND(&l->rx.rxbuf_list, &rxbuf->rxbuf_el);
continue;
}
quic_dgram_parse(new_dgram, qc, qc->li);
/* A datagram must always be consumed after quic_parse_dgram(). */
BUG_ON(new_dgram->buf);
} while (ret > 0);
pool_free(pool_head_quic_dgram, new_dgram);
if (b_size(&buf)) {
b_free(&buf);
offer_buffers(NULL, 1);
}
TRACE_LEAVE(QUIC_EV_CONN_RCV, qc);
return ret;
}
/* Allocate a socket file-descriptor specific for QUIC connection <qc>.
* Endpoint addresses are specified by the two following arguments : <src> is
* the local address and <dst> is the remote one.
*
* Return the socket FD or a negative error code. On error, socket is marked as
* uninitialized.
*/
void qc_alloc_fd(struct quic_conn *qc, const struct sockaddr_storage *src,
const struct sockaddr_storage *dst)
{
struct bind_conf *bc = qc->li->bind_conf;
struct proxy *p = bc->frontend;
int fd = -1;
int ret;
/* Must not happen. */
BUG_ON(src->ss_family != dst->ss_family);
qc_init_fd(qc);
fd = socket(src->ss_family, SOCK_DGRAM, 0);
if (fd < 0)
goto err;
if (fd >= global.maxsock) {
send_log(p, LOG_EMERG,
"Proxy %s reached the configured maximum connection limit. Please check the global 'maxconn' value.\n",
p->id);
goto err;
}
ret = setsockopt(fd, SOL_SOCKET, SO_REUSEADDR, &one, sizeof(one));
if (ret < 0)
goto err;
switch (src->ss_family) {
case AF_INET:
#if defined(IP_PKTINFO)
ret = setsockopt(fd, IPPROTO_IP, IP_PKTINFO, &one, sizeof(one));
#elif defined(IP_RECVDSTADDR)
ret = setsockopt(fd, IPPROTO_IP, IP_RECVDSTADDR, &one, sizeof(one));
#endif /* IP_PKTINFO || IP_RECVDSTADDR */
break;
case AF_INET6:
#ifdef IPV6_RECVPKTINFO
ret = setsockopt(fd, IPPROTO_IPV6, IPV6_RECVPKTINFO, &one, sizeof(one));
#endif
break;
}
if (ret < 0)
goto err;
ret = bind(fd, (struct sockaddr *)src, get_addr_len(src));
if (ret < 0) {
if (errno == EACCES) {
if (!quic_bind_eacces_warn) {
send_log(p, LOG_WARNING,
"Permission error on QUIC socket binding for proxy %s. Consider using setcap cap_net_bind_service (Linux only) or running as root.\n",
p->id);
quic_bind_eacces_warn = 1;
}
/* Fallback to listener socket for this receiver instance. */
HA_ATOMIC_STORE(&qc->li->rx.quic_mode, QUIC_SOCK_MODE_LSTNR);
}
goto err;
}
ret = connect(fd, (struct sockaddr *)dst, get_addr_len(dst));
if (ret < 0)
goto err;
qc->fd = fd;
fd_set_nonblock(fd);
fd_insert(fd, qc, quic_conn_sock_fd_iocb, tgid, ti->ltid_bit);
fd_want_recv(fd);
return;
err:
if (fd >= 0)
close(fd);
}
/* Release socket file-descriptor specific for QUIC connection <qc>. Set
* <reinit> if socket should be reinitialized after address migration.
*/
void qc_release_fd(struct quic_conn *qc, int reinit)
{
if (qc_test_fd(qc)) {
fd_delete(qc->fd);
qc->fd = DEAD_FD_MAGIC;
if (reinit)
qc_init_fd(qc);
}
}
/* Wrapper for fd_want_recv(). Safe even if connection does not used its owned
* socket.
*/
void qc_want_recv(struct quic_conn *qc)
{
if (qc_test_fd(qc))
fd_want_recv(qc->fd);
}
/*********************** QUIC accept queue management ***********************/
/* per-thread accept queues */
struct quic_accept_queue *quic_accept_queues;
/* Install <qc> on the queue ready to be accepted. The queue task is then woken
* up. If <qc> accept is already scheduled or done, nothing is done.
*/
void quic_accept_push_qc(struct quic_conn *qc)
{
struct quic_accept_queue *queue = &quic_accept_queues[tid];
struct li_per_thread *lthr = &qc->li->per_thr[ti->ltid];
/* early return if accept is already in progress/done for this
* connection
*/
if (qc->flags & QUIC_FL_CONN_ACCEPT_REGISTERED)
return;
BUG_ON(MT_LIST_INLIST(&qc->accept_list));
HA_ATOMIC_INC(&qc->li->rx.quic_curr_accept);
qc->flags |= QUIC_FL_CONN_ACCEPT_REGISTERED;
/* 1. insert the listener in the accept queue
*
* Use TRY_APPEND as there is a possible race even with INLIST if
* multiple threads try to add the same listener instance from several
* quic_conn.
*/
if (!MT_LIST_INLIST(&(lthr->quic_accept.list)))
MT_LIST_TRY_APPEND(&queue->listeners, &(lthr->quic_accept.list));
/* 2. insert the quic_conn in the listener per-thread queue. */
MT_LIST_APPEND(<hr->quic_accept.conns, &qc->accept_list);
/* 3. wake up the queue tasklet */
tasklet_wakeup(quic_accept_queues[tid].tasklet);
}
/* Tasklet handler to accept QUIC connections. Call listener_accept on every
* listener instances registered in the accept queue.
*/
struct task *quic_accept_run(struct task *t, void *ctx, unsigned int i)
{
struct li_per_thread *lthr;
struct mt_list *elt1, elt2;
struct quic_accept_queue *queue = &quic_accept_queues[tid];
mt_list_for_each_entry_safe(lthr, &queue->listeners, quic_accept.list, elt1, elt2) {
listener_accept(lthr->li);
if (!MT_LIST_ISEMPTY(<hr->quic_accept.conns))
tasklet_wakeup((struct tasklet*)t);
else
MT_LIST_DELETE_SAFE(elt1);
}
return NULL;
}
/* Returns the maximum number of QUIC connections waiting for handshake to
* complete in parallel on listener <l> instance. This is directly based on
* listener backlog value.
*/
int quic_listener_max_handshake(const struct listener *l)
{
return listener_backlog(l) / 2;
}
/* Returns the value which is considered as the maximum number of QUIC
* connections waiting to be accepted for listener <l> instance. This is
* directly based on listener backlog value.
*/
int quic_listener_max_accept(const struct listener *l)
{
return listener_backlog(l) / 2;
}
static int quic_alloc_accept_queues(void)
{
int i;
quic_accept_queues = calloc(global.nbthread,
sizeof(*quic_accept_queues));
if (!quic_accept_queues) {
ha_alert("Failed to allocate the quic accept queues.\n");
return 0;
}
for (i = 0; i < global.nbthread; ++i) {
struct tasklet *task;
if (!(task = tasklet_new())) {
ha_alert("Failed to allocate the quic accept queue on thread %d.\n", i);
return 0;
}
tasklet_set_tid(task, i);
task->process = quic_accept_run;
quic_accept_queues[i].tasklet = task;
MT_LIST_INIT(&quic_accept_queues[i].listeners);
}
return 1;
}
REGISTER_POST_CHECK(quic_alloc_accept_queues);
static int quic_deallocate_accept_queues(void)
{
int i;
if (quic_accept_queues) {
for (i = 0; i < global.nbthread; ++i)
tasklet_free(quic_accept_queues[i].tasklet);
free(quic_accept_queues);
}
return 1;
}
REGISTER_POST_DEINIT(quic_deallocate_accept_queues);
|