1 /*
2 * Copyright 2022-2024 The OpenSSL Project Authors. All Rights Reserved.
3 *
4 * Licensed under the Apache License 2.0 (the "License"). You may not use
5 * this file except in compliance with the License. You can obtain a copy
6 * in the file LICENSE in the source distribution or at
7 * https://www.openssl.org/source/license.html
8 */
9
10 #ifndef OSSL_QUIC_DEMUX_H
11 # define OSSL_QUIC_DEMUX_H
12
13 # include <openssl/ssl.h>
14 # include "internal/quic_types.h"
15 # include "internal/quic_predef.h"
16 # include "internal/bio_addr.h"
17 # include "internal/time.h"
18 # include "internal/list.h"
19
20 # ifndef OPENSSL_NO_QUIC
21
22 /*
23 * QUIC Demuxer
24 * ============
25 *
26 * The QUIC connection demuxer is the entity responsible for receiving datagrams
27 * from the network via a datagram BIO. It parses the headers of the first
28 * packet in the datagram to determine that packet's DCID and hands off
29 * processing of the entire datagram to a single callback function which can
30 * decide how to handle and route the datagram, for example by looking up
31 * a QRX instance and injecting the URXE into that QRX.
32 *
33 * A QRX will typically be instantiated per QUIC connection and contains the
34 * cryptographic resources needed to decrypt QUIC packets for that connection.
35 * However, it is up to the callback function to handle routing, for example by
36 * consulting a LCIDM instance. Thus the demuxer has no specific knowledge of
37 * any QRX and is not coupled to it. All CID knowledge is also externalised into
38 * a LCIDM or other CID state tracking object, without the DEMUX being coupled
39 * to any particular DCID resolution mechanism.
40 *
41 * URX Queue
42 * ---------
43 *
44 * Since the demuxer must handle the initial reception of datagrams from the OS,
45 * RX queue management for new, unprocessed datagrams is also handled by the
46 * demuxer.
47 *
48 * The demuxer maintains a queue of Unprocessed RX Entries (URXEs), which store
49 * unprocessed (i.e., encrypted, unvalidated) data received from the network.
50 * The URXE queue is designed to allow multiple datagrams to be received in a
51 * single call to BIO_recvmmsg, where supported.
52 *
53 * One URXE is used per received datagram. Each datagram may contain multiple
54 * packets, however, this is not the demuxer's concern. QUIC prohibits different
55 * packets in the same datagram from containing different DCIDs; the demuxer
56 * only considers the DCID of the first packet in a datagram when deciding how
57 * to route a received datagram, and it is the responsibility of the QRX to
58 * enforce this rule. Packets other than the first packet in a datagram are not
59 * examined by the demuxer, and the demuxer does not perform validation of
60 * packet headers other than to the minimum extent necessary to extract the
61 * DCID; further parsing and validation of packet headers is the responsibility
62 * of the QRX.
63 *
64 * Rather than defining an opaque interface, the URXE structure internals
65 * are exposed. Since the demuxer is only exposed to other parts of the QUIC
66 * implementation internals, this poses no problem, and has a number of
67 * advantages:
68 *
69 * - Fields in the URXE can be allocated to support requirements in other
70 * components, like the QRX, which would otherwise have to allocate extra
71 * memory corresponding to each URXE.
72 *
73 * - Other components, like the QRX, can keep the URXE in queues of its own
74 * when it is not being managed by the demuxer.
75 *
76 * URX Queue Structure
77 * -------------------
78 *
79 * The URXE queue is maintained as a simple doubly-linked list. URXE entries are
80 * moved between different lists in their lifecycle (for example, from a free
81 * list to a pending list and vice versa). The buffer into which datagrams are
82 * received immediately follows this URXE header structure and is part of the
83 * same allocation.
84 */
85
86 /* Maximum number of packets we allow to exist in one datagram. */
87 #define QUIC_MAX_PKT_PER_URXE (sizeof(uint64_t) * 8)
88
89 struct quic_urxe_st {
90 OSSL_LIST_MEMBER(urxe, QUIC_URXE);
91
92 /*
93 * The URXE data starts after this structure so we don't need a pointer.
94 * data_len stores the current length (i.e., the length of the received
95 * datagram) and alloc_len stores the allocation length. The URXE will be
96 * reallocated if we need a larger allocation than is available, though this
97 * should not be common as we will have a good idea of worst-case MTUs up
98 * front.
99 */
100 size_t data_len, alloc_len;
101
102 /*
103 * Bitfields per packet. processed indicates the packet has been processed
104 * and must not be processed again, hpr_removed indicates header protection
105 * has already been removed. Used by QRX only; not used by the demuxer.
106 */
107 uint64_t processed, hpr_removed;
108
109 /*
110 * This monotonically increases with each datagram received. It is used for
111 * diagnostic purposes only.
112 */
113 uint64_t datagram_id;
114
115 /*
116 * Address of peer we received the datagram from, and the local interface
117 * address we received it on. If local address support is not enabled, local
118 * is zeroed.
119 */
120 BIO_ADDR peer, local;
121
122 /*
123 * Time at which datagram was received (or ossl_time_zero()) if a now
124 * function was not provided).
125 */
126 OSSL_TIME time;
127
128 /*
129 * Used by the QRX to mark whether a datagram has been deferred. Used by the
130 * QRX only; not used by the demuxer.
131 */
132 char deferred;
133
134 /*
135 * Used by the DEMUX to track if a URXE has been handed out. Used primarily
136 * for debugging purposes.
137 */
138 char demux_state;
139 };
140
141 /* Accessors for URXE buffer. */
142 static ossl_unused ossl_inline unsigned char *
ossl_quic_urxe_data(const QUIC_URXE * e)143 ossl_quic_urxe_data(const QUIC_URXE *e)
144 {
145 return (unsigned char *)&e[1];
146 }
147
148 static ossl_unused ossl_inline unsigned char *
ossl_quic_urxe_data_end(const QUIC_URXE * e)149 ossl_quic_urxe_data_end(const QUIC_URXE *e)
150 {
151 return ossl_quic_urxe_data(e) + e->data_len;
152 }
153
154 /* List structure tracking a queue of URXEs. */
155 DEFINE_LIST_OF(urxe, QUIC_URXE);
156 typedef OSSL_LIST(urxe) QUIC_URXE_LIST;
157
158 /*
159 * List management helpers. These are used by the demuxer but can also be used
160 * by users of the demuxer to manage URXEs.
161 */
162 void ossl_quic_urxe_remove(QUIC_URXE_LIST *l, QUIC_URXE *e);
163 void ossl_quic_urxe_insert_head(QUIC_URXE_LIST *l, QUIC_URXE *e);
164 void ossl_quic_urxe_insert_tail(QUIC_URXE_LIST *l, QUIC_URXE *e);
165
166 /*
167 * Called when a datagram is received for a given connection ID.
168 *
169 * e is a URXE containing the datagram payload. It is permissible for the callee
170 * to mutate this buffer; once the demuxer calls this callback, it will never
171 * read the buffer again.
172 *
173 * If a DCID was identified for the datagram, dcid is non-NULL; otherwise
174 * it is NULL.
175 *
176 * The callee must arrange for ossl_quic_demux_release_urxe or
177 * ossl_quic_demux_reinject_urxe to be called on the URXE at some point in the
178 * future (this need not be before the callback returns).
179 *
180 * At the time the callback is made, the URXE will not be in any queue,
181 * therefore the callee can use the prev and next fields as it wishes.
182 */
183 typedef void (ossl_quic_demux_cb_fn)(QUIC_URXE *e, void *arg,
184 const QUIC_CONN_ID *dcid);
185
186 /*
187 * Creates a new demuxer. The given BIO is used to receive datagrams from the
188 * network using BIO_recvmmsg. short_conn_id_len is the length of destination
189 * connection IDs used in RX'd packets; it must have the same value for all
190 * connections used on a socket. default_urxe_alloc_len is the buffer size to
191 * receive datagrams into; it should be a value large enough to contain any
192 * received datagram according to local MTUs, etc.
193 *
194 * now is an optional function used to determine the time a datagram was
195 * received. now_arg is an opaque argument passed to the function. If now is
196 * NULL, ossl_time_zero() is used as the datagram reception time.
197 */
198 QUIC_DEMUX *ossl_quic_demux_new(BIO *net_bio,
199 size_t short_conn_id_len,
200 OSSL_TIME (*now)(void *arg),
201 void *now_arg);
202
203 /*
204 * Destroy a demuxer. All URXEs must have been released back to the demuxer
205 * before calling this. No-op if demux is NULL.
206 */
207 void ossl_quic_demux_free(QUIC_DEMUX *demux);
208
209 /*
210 * Changes the BIO which the demuxer reads from. This also sets the MTU if the
211 * BIO supports querying the MTU.
212 */
213 void ossl_quic_demux_set_bio(QUIC_DEMUX *demux, BIO *net_bio);
214
215 /*
216 * Changes the MTU in bytes we use to receive datagrams.
217 */
218 int ossl_quic_demux_set_mtu(QUIC_DEMUX *demux, unsigned int mtu);
219
220 /*
221 * Set the default packet handler. This is used for incoming packets which don't
222 * match a registered DCID. This is only needed for servers. If a default packet
223 * handler is not set, a packet which doesn't match a registered DCID is
224 * silently dropped. A default packet handler may be unset by passing NULL.
225 *
226 * The handler is responsible for ensuring that ossl_quic_demux_reinject_urxe or
227 * ossl_quic_demux_release_urxe is called on the passed packet at some point in
228 * the future, which may or may not be before the handler returns.
229 */
230 void ossl_quic_demux_set_default_handler(QUIC_DEMUX *demux,
231 ossl_quic_demux_cb_fn *cb,
232 void *cb_arg);
233
234 /*
235 * Releases a URXE back to the demuxer. No reference must be made to the URXE or
236 * its buffer after calling this function. The URXE must not be in any queue;
237 * that is, its prev and next pointers must be NULL.
238 */
239 void ossl_quic_demux_release_urxe(QUIC_DEMUX *demux,
240 QUIC_URXE *e);
241
242 /*
243 * Reinjects a URXE which was issued to a registered DCID callback or the
244 * default packet handler callback back into the pending queue. This is useful
245 * when a packet has been handled by the default packet handler callback such
246 * that a DCID has now been registered and can be dispatched normally by DCID.
247 * Once this has been called, the caller must not touch the URXE anymore and
248 * must not also call ossl_quic_demux_release_urxe().
249 *
250 * The URXE is reinjected at the head of the queue, so it will be reprocessed
251 * immediately.
252 */
253 void ossl_quic_demux_reinject_urxe(QUIC_DEMUX *demux,
254 QUIC_URXE *e);
255
256 /*
257 * Process any unprocessed RX'd datagrams, by calling registered callbacks by
258 * connection ID, reading more datagrams from the BIO if necessary.
259 *
260 * Returns one of the following values:
261 *
262 * QUIC_DEMUX_PUMP_RES_OK
263 * At least one incoming datagram was processed.
264 *
265 * QUIC_DEMUX_PUMP_RES_TRANSIENT_FAIL
266 * No more incoming datagrams are currently available.
267 * Call again later.
268 *
269 * QUIC_DEMUX_PUMP_RES_PERMANENT_FAIL
270 * Either the network read BIO has failed in a non-transient fashion, or
271 * the QUIC implementation has encountered an internal state, assertion
272 * or allocation error. The caller should tear down the connection
273 * similarly to in the case of a protocol violation.
274 *
275 */
276 #define QUIC_DEMUX_PUMP_RES_OK 1
277 #define QUIC_DEMUX_PUMP_RES_TRANSIENT_FAIL (-1)
278 #define QUIC_DEMUX_PUMP_RES_PERMANENT_FAIL (-2)
279
280 int ossl_quic_demux_pump(QUIC_DEMUX *demux);
281
282 /*
283 * Artificially inject a packet into the demuxer for testing purposes. The
284 * buffer must not exceed the URXE size being used by the demuxer.
285 *
286 * If peer or local are NULL, their respective fields are zeroed in the injected
287 * URXE.
288 *
289 * Returns 1 on success or 0 on failure.
290 */
291 int ossl_quic_demux_inject(QUIC_DEMUX *demux,
292 const unsigned char *buf,
293 size_t buf_len,
294 const BIO_ADDR *peer,
295 const BIO_ADDR *local);
296
297 /*
298 * Returns 1 if there are any pending URXEs.
299 */
300 int ossl_quic_demux_has_pending(const QUIC_DEMUX *demux);
301
302 # endif
303
304 #endif
305