flow_divert.c source code [codebrowser/bsd/netinet/flow_divert.c]

1	/*
2	* Copyright (c) 2012-2017 Apple Inc. All rights reserved.
3	*
4	* @APPLE_OSREFERENCE_LICENSE_HEADER_START@
5	*
6	* This file contains Original Code and/or Modifications of Original Code
7	* as defined in and that are subject to the Apple Public Source License
8	* Version 2.0 (the 'License'). You may not use this file except in
9	* compliance with the License. The rights granted to you under the License
10	* may not be used to create, or enable the creation or redistribution of,
11	* unlawful or unlicensed copies of an Apple operating system, or to
12	* circumvent, violate, or enable the circumvention or violation of, any
13	* terms of an Apple operating system software license agreement.
14	*
15	* Please obtain a copy of the License at
16	* http://www.opensource.apple.com/apsl/ and read it before using this file.
17	*
18	* The Original Code and all software distributed under the License are
19	* distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
20	* EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
21	* INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
22	* FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
23	* Please see the License for the specific language governing rights and
24	* limitations under the License.
25	*
26	* @APPLE_OSREFERENCE_LICENSE_HEADER_END@
27	*/
28
29	#include <string.h>
30	#include <sys/types.h>
31	#include <sys/syslog.h>
32	#include <sys/queue.h>
33	#include <sys/malloc.h>
34	#include <sys/socket.h>
35	#include <sys/kpi_mbuf.h>
36	#include <sys/mbuf.h>
37	#include <sys/domain.h>
38	#include <sys/protosw.h>
39	#include <sys/socketvar.h>
40	#include <sys/kernel.h>
41	#include <sys/systm.h>
42	#include <sys/kern_control.h>
43	#include <sys/ubc.h>
44	#include <sys/codesign.h>
45	#include <libkern/tree.h>
46	#include <kern/locks.h>
47	#include <kern/debug.h>
48	#include <net/if_var.h>
49	#include <net/route.h>
50	#include <net/flowhash.h>
51	#include <net/ntstat.h>
52	#include <netinet/in.h>
53	#include <netinet/in_var.h>
54	#include <netinet/tcp.h>
55	#include <netinet/tcp_var.h>
56	#include <netinet/tcp_fsm.h>
57	#include <netinet/flow_divert.h>
58	#include <netinet/flow_divert_proto.h>
59	#if INET6
60	#include <netinet6/in6_pcb.h>
61	#include <netinet6/ip6protosw.h>
62	#endif /* INET6 */
63	#include <dev/random/randomdev.h>
64	#include <libkern/crypto/sha1.h>
65	#include <libkern/crypto/crypto_internal.h>
66	#include <os/log.h>
67
68	#define FLOW_DIVERT_CONNECT_STARTED 0x00000001
69	#define FLOW_DIVERT_READ_CLOSED 0x00000002
70	#define FLOW_DIVERT_WRITE_CLOSED 0x00000004
71	#define FLOW_DIVERT_TUNNEL_RD_CLOSED 0x00000008
72	#define FLOW_DIVERT_TUNNEL_WR_CLOSED 0x00000010
73	#define FLOW_DIVERT_TRANSFERRED 0x00000020
74	#define FLOW_DIVERT_HAS_HMAC 0x00000040
75
76	#define FDLOG(level, pcb, format, ...) \
77	os_log_with_type(OS_LOG_DEFAULT, flow_divert_syslog_type_to_oslog_type(level), "(%u): " format "\n", (pcb)->hash, __VA_ARGS__)
78
79	#define FDLOG0(level, pcb, msg) \
80	os_log_with_type(OS_LOG_DEFAULT, flow_divert_syslog_type_to_oslog_type(level), "(%u): " msg "\n", (pcb)->hash)
81
82	#define FDRETAIN(pcb) if ((pcb) != NULL) OSIncrementAtomic(&(pcb)->ref_count)
83	#define FDRELEASE(pcb) \
84	do { \
85	if ((pcb) != NULL && 1 == OSDecrementAtomic(&(pcb)->ref_count)) { \
86	flow_divert_pcb_destroy(pcb); \
87	} \
88	} while (0)
89
90	#define FDLOCK(pcb) lck_mtx_lock(&(pcb)->mtx)
91	#define FDUNLOCK(pcb) lck_mtx_unlock(&(pcb)->mtx)
92
93	#define FD_CTL_SENDBUFF_SIZE (128 * 1024)
94	#define FD_CTL_RCVBUFF_SIZE (128 * 1024)
95
96	#define GROUP_BIT_CTL_ENQUEUE_BLOCKED 0
97
98	#define GROUP_COUNT_MAX 32
99	#define FLOW_DIVERT_MAX_NAME_SIZE 4096
100	#define FLOW_DIVERT_MAX_KEY_SIZE 1024
101	#define FLOW_DIVERT_MAX_TRIE_MEMORY (1024 * 1024)
102
103	struct flow_divert_trie_node
104	{
105	uint16_t start;
106	uint16_t length;
107	uint16_t child_map;
108	};
109
110	#define CHILD_MAP_SIZE 256
111	#define NULL_TRIE_IDX 0xffff
112	#define TRIE_NODE(t, i) ((t)->nodes[(i)])
113	#define TRIE_CHILD(t, i, b) (((t)->child_maps + (CHILD_MAP_SIZE * TRIE_NODE(t, i).child_map))[(b)])
114	#define TRIE_BYTE(t, i) ((t)->bytes[(i)])
115
116	static struct flow_divert_pcb nil_pcb;
117
118	decl_lck_rw_data(static, g_flow_divert_group_lck);
119	static struct flow_divert_group **g_flow_divert_groups = NULL;
120	static uint32_t g_active_group_count = `0`;
121
122	static lck_grp_attr_t *flow_divert_grp_attr = NULL;
123	static lck_attr_t *flow_divert_mtx_attr = NULL;
124	static lck_grp_t *flow_divert_mtx_grp = NULL;
125	static errno_t g_init_result = `0`;
126
127	static kern_ctl_ref g_flow_divert_kctl_ref = NULL;
128
129	static struct protosw g_flow_divert_in_protosw;
130	static struct pr_usrreqs g_flow_divert_in_usrreqs;
131	static struct protosw g_flow_divert_in_udp_protosw;
132	static struct pr_usrreqs g_flow_divert_in_udp_usrreqs;
133	#if INET6
134	static struct ip6protosw g_flow_divert_in6_protosw;
135	static struct pr_usrreqs g_flow_divert_in6_usrreqs;
136	static struct ip6protosw g_flow_divert_in6_udp_protosw;
137	static struct pr_usrreqs g_flow_divert_in6_udp_usrreqs;
138	#endif /* INET6 */
139
140	static struct protosw *g_tcp_protosw = NULL;
141	static struct ip6protosw *g_tcp6_protosw = NULL;
142	static struct protosw *g_udp_protosw = NULL;
143	static struct ip6protosw *g_udp6_protosw = NULL;
144
145	static errno_t
146	flow_divert_dup_addr(sa_family_t family, struct sockaddr addr, struct* sockaddr **dup);
147
148	static errno_t
149	flow_divert_inp_to_sockaddr(const struct inpcb inp, struct* sockaddr **local_socket);
150
151	static boolean_t
152	flow_divert_is_sockaddr_valid(struct sockaddr *addr);
153
154	static int
155	flow_divert_append_target_endpoint_tlv(mbuf_t connect_packet, struct sockaddr *toaddr);
156
157	struct sockaddr *
158	flow_divert_get_buffered_target_address(mbuf_t buffer);
159
160	static boolean_t
161	flow_divert_has_pcb_local_address(const struct inpcb *inp);
162
163	static void
164	flow_divert_disconnect_socket(struct socket *so);
165
166	static inline uint8_t
167	flow_divert_syslog_type_to_oslog_type(int syslog_type)
168	{
169	switch (syslog_type) {
170	case LOG_ERR: return OS_LOG_TYPE_ERROR;
171	case LOG_INFO: return OS_LOG_TYPE_INFO;
172	case LOG_DEBUG: return OS_LOG_TYPE_DEBUG;
173	default: return OS_LOG_TYPE_DEFAULT;
174	}
175	}
176
177	static inline int
178	flow_divert_pcb_cmp(const struct flow_divert_pcb pcb_a, const* struct flow_divert_pcb *pcb_b)
179	{
180	return memcmp(&pcb_a->hash, &pcb_b->hash, sizeof(pcb_a->hash));
181	}
182
183	RB_PROTOTYPE(fd_pcb_tree, flow_divert_pcb, rb_link, flow_divert_pcb_cmp);
184	RB_GENERATE(fd_pcb_tree, flow_divert_pcb, rb_link, flow_divert_pcb_cmp);
185
186	static const char *
187	flow_divert_packet_type2str(uint8_t packet_type)
188	{
189	switch (packet_type) {
190	case FLOW_DIVERT_PKT_CONNECT:
191	return "connect";
192	case FLOW_DIVERT_PKT_CONNECT_RESULT:
193	return "connect result";
194	case FLOW_DIVERT_PKT_DATA:
195	return "data";
196	case FLOW_DIVERT_PKT_CLOSE:
197	return "close";
198	case FLOW_DIVERT_PKT_READ_NOTIFY:
199	return "read notification";
200	case FLOW_DIVERT_PKT_PROPERTIES_UPDATE:
201	return "properties update";
202	case FLOW_DIVERT_PKT_APP_MAP_CREATE:
203	return "app map create";
204	default:
205	return "unknown";
206	}
207	}
208
209	static struct flow_divert_pcb *
210	flow_divert_pcb_lookup(uint32_t hash, struct flow_divert_group *group)
211	{
212	struct flow_divert_pcb key_item;
213	struct flow_divert_pcb *fd_cb = NULL;
214
215	key_item.hash = hash;
216
217	lck_rw_lock_shared(&group->lck);
218	fd_cb = RB_FIND(fd_pcb_tree, &group->pcb_tree, &key_item);
219	FDRETAIN(fd_cb);
220	lck_rw_done(&group->lck);
221
222	return fd_cb;
223	}
224
225	static errno_t
226	flow_divert_pcb_insert(struct flow_divert_pcb *fd_cb, uint32_t ctl_unit)
227	{
228	errno_t error = `0`;
229	struct flow_divert_pcb *exist = NULL;
230	struct flow_divert_group *group;
231	static uint32_t g_nextkey = `1`;
232	static uint32_t g_hash_seed = `0`;
233	int try_count = `0`;
234
235	if (ctl_unit == `0` \|\| ctl_unit >= GROUP_COUNT_MAX) {
236	return EINVAL;
237	}
238
239	socket_unlock(fd_cb->so, `0`);
240	lck_rw_lock_shared(&g_flow_divert_group_lck);
241
242	if (g_flow_divert_groups == NULL \|\| g_active_group_count == `0`) {
243	FDLOG0(LOG_ERR, &nil_pcb, "No active groups, flow divert cannot be used for this socket");
244	error = ENETUNREACH;
245	goto done;
246	}
247
248	group = g_flow_divert_groups[ctl_unit];
249	if (group == NULL) {
250	FDLOG(LOG_ERR, &nil_pcb, "Group for control unit %u is NULL, flow divert cannot be used for this socket", ctl_unit);
251	error = ENETUNREACH;
252	goto done;
253	}
254
255	socket_lock(fd_cb->so, `0`);
256
257	do {
258	uint32_t key[`2`];
259	uint32_t idx;
260
261	key[`0`] = g_nextkey++;
262	key[`1`] = RandomULong();
263
264	if (g_hash_seed == `0`) {
265	g_hash_seed = RandomULong();
266	}
267
268	fd_cb->hash = net_flowhash(key, sizeof(key), g_hash_seed);
269
270	for (idx = `1`; idx < GROUP_COUNT_MAX; idx++) {
271	struct flow_divert_group *curr_group = g_flow_divert_groups[idx];
272	if (curr_group != NULL && curr_group != group) {
273	lck_rw_lock_shared(&curr_group->lck);
274	exist = RB_FIND(fd_pcb_tree, &curr_group->pcb_tree, fd_cb);
275	lck_rw_done(&curr_group->lck);
276	if (exist != NULL) {
277	break;
278	}
279	}
280	}
281
282	if (exist == NULL) {
283	lck_rw_lock_exclusive(&group->lck);
284	exist = RB_INSERT(fd_pcb_tree, &group->pcb_tree, fd_cb);
285	lck_rw_done(&group->lck);
286	}
287	} while (exist != NULL && try_count++ < `3`);
288
289	if (exist == NULL) {
290	fd_cb->group = group;
291	FDRETAIN(fd_cb); / The group now has a reference /
292	} else {
293	fd_cb->hash = `0`;
294	error = EEXIST;
295	}
296
297	socket_unlock(fd_cb->so, `0`);
298
299	done:
300	lck_rw_done(&g_flow_divert_group_lck);
301	socket_lock(fd_cb->so, `0`);
302
303	return error;
304	}
305
306	static struct flow_divert_pcb *
307	flow_divert_pcb_create(socket_t so)
308	{
309	struct flow_divert_pcb *new_pcb = NULL;
310
311	MALLOC_ZONE(new_pcb, struct flow_divert_pcb , sizeof(new_pcb), M_FLOW_DIVERT_PCB, M_WAITOK);
312	if (new_pcb == NULL) {
313	FDLOG0(LOG_ERR, &nil_pcb, "failed to allocate a pcb");
314	return NULL;
315	}
316
317	memset(new_pcb, `0`, sizeof(*new_pcb));
318
319	lck_mtx_init(&new_pcb->mtx, flow_divert_mtx_grp, flow_divert_mtx_attr);
320	new_pcb->so = so;
321	new_pcb->log_level = nil_pcb.log_level;
322
323	FDRETAIN(new_pcb); / Represents the socket's reference /
324
325	return new_pcb;
326	}
327
328	static void
329	flow_divert_pcb_destroy(struct flow_divert_pcb *fd_cb)
330	{
331	FDLOG(LOG_INFO, fd_cb, "Destroying, app tx %u, app rx %u, tunnel tx %u, tunnel rx %u",
332	fd_cb->bytes_written_by_app, fd_cb->bytes_read_by_app, fd_cb->bytes_sent, fd_cb->bytes_received);
333
334	if (fd_cb->local_address != NULL) {
335	FREE(fd_cb->local_address, M_SONAME);
336	}
337	if (fd_cb->remote_address != NULL) {
338	FREE(fd_cb->remote_address, M_SONAME);
339	}
340	if (fd_cb->connect_token != NULL) {
341	mbuf_freem(fd_cb->connect_token);
342	}
343	if (fd_cb->connect_packet != NULL) {
344	mbuf_freem(fd_cb->connect_packet);
345	}
346	if (fd_cb->app_data != NULL) {
347	FREE(fd_cb->app_data, M_TEMP);
348	}
349	FREE_ZONE(fd_cb, sizeof(*fd_cb), M_FLOW_DIVERT_PCB);
350	}
351
352	static void
353	flow_divert_pcb_remove(struct flow_divert_pcb *fd_cb)
354	{
355	if (fd_cb->group != NULL) {
356	struct flow_divert_group *group = fd_cb->group;
357	lck_rw_lock_exclusive(&group->lck);
358	FDLOG(LOG_INFO, fd_cb, "Removing from group %d, ref count = %d", group->ctl_unit, fd_cb->ref_count);
359	RB_REMOVE(fd_pcb_tree, &group->pcb_tree, fd_cb);
360	fd_cb->group = NULL;
361	FDRELEASE(fd_cb); / Release the group's reference /
362	lck_rw_done(&group->lck);
363	}
364	}
365
366	static int
367	flow_divert_packet_init(struct flow_divert_pcb fd_cb, uint8_t packet_type, mbuf_t packet)
368	{
369	struct flow_divert_packet_header hdr;
370	int error = `0`;
371
372	error = mbuf_gethdr(MBUF_DONTWAIT, MBUF_TYPE_HEADER, packet);
373	if (error) {
374	FDLOG(LOG_ERR, fd_cb, "failed to allocate the header mbuf: %d", error);
375	return error;
376	}
377
378	hdr.packet_type = packet_type;
379	hdr.conn_id = htonl(fd_cb->hash);
380
381	/ Lay down the header /
382	error = mbuf_copyback(packet, `0`, sizeof*(hdr), &hdr, MBUF_DONTWAIT);
383	if (error) {
384	FDLOG(LOG_ERR, fd_cb, "mbuf_copyback(hdr) failed: %d", error);
385	mbuf_freem(*packet);
386	*packet = NULL;
387	return error;
388	}
389
390	return `0`;
391	}
392
393	static int
394	flow_divert_packet_append_tlv(mbuf_t packet, uint8_t type, uint32_t length, const void *value)
395	{
396	uint32_t net_length = htonl(length);
397	int error = `0`;
398
399	error = mbuf_copyback(packet, mbuf_pkthdr_len(packet), sizeof(type), &type, MBUF_DONTWAIT);
400	if (error) {
401	FDLOG(LOG_ERR, &nil_pcb, "failed to append the type (%d)", type);
402	return error;
403	}
404
405	error = mbuf_copyback(packet, mbuf_pkthdr_len(packet), sizeof(net_length), &net_length, MBUF_DONTWAIT);
406	if (error) {
407	FDLOG(LOG_ERR, &nil_pcb, "failed to append the length (%u)", length);
408	return error;
409	}
410
411	error = mbuf_copyback(packet, mbuf_pkthdr_len(packet), length, value, MBUF_DONTWAIT);
412	if (error) {
413	FDLOG0(LOG_ERR, &nil_pcb, "failed to append the value");
414	return error;
415	}
416
417	return error;
418	}
419
420	static int
421	flow_divert_packet_find_tlv(mbuf_t packet, int offset, uint8_t type, int err, int* next)
422	{
423	size_t cursor = offset;
424	int error = `0`;
425	uint32_t curr_length;
426	uint8_t curr_type;
427
428	*err = `0`;
429
430	do {
431	if (!next) {
432	error = mbuf_copydata(packet, cursor, sizeof(curr_type), &curr_type);
433	if (error) {
434	*err = ENOENT;
435	return -`1`;
436	}
437	} else {
438	next = `0`;
439	curr_type = FLOW_DIVERT_TLV_NIL;
440	}
441
442	if (curr_type != type) {
443	cursor += sizeof(curr_type);
444	error = mbuf_copydata(packet, cursor, sizeof(curr_length), &curr_length);
445	if (error) {
446	*err = error;
447	return -`1`;
448	}
449
450	cursor += (sizeof(curr_length) + ntohl(curr_length));
451	}
452	} while (curr_type != type);
453
454	return cursor;
455	}
456
457	static int
458	flow_divert_packet_get_tlv(mbuf_t packet, int offset, uint8_t type, size_t buff_len, void buff, uint32_t val_size)
459	{
460	int error = `0`;
461	uint32_t length;
462	int tlv_offset;
463
464	tlv_offset = flow_divert_packet_find_tlv(packet, offset, type, &error, `0`);
465	if (tlv_offset < `0`) {
466	return error;
467	}
468
469	error = mbuf_copydata(packet, tlv_offset + sizeof(type), sizeof(length), &length);
470	if (error) {
471	return error;
472	}
473
474	length = ntohl(length);
475
476	if (val_size != NULL) {
477	*val_size = length;
478	}
479
480	if (buff != NULL && buff_len > `0`) {
481	size_t to_copy = (length < buff_len) ? length : buff_len;
482	error = mbuf_copydata(packet, tlv_offset + sizeof(type) + sizeof(length), to_copy, buff);
483	if (error) {
484	return error;
485	}
486	}
487
488	return `0`;
489	}
490
491	static int
492	flow_divert_packet_compute_hmac(mbuf_t packet, struct flow_divert_group group, uint8_t hmac)
493	{
494	mbuf_t curr_mbuf = packet;
495
496	if (g_crypto_funcs == NULL \|\| group->token_key == NULL) {
497	return ENOPROTOOPT;
498	}
499
500	cchmac_di_decl(g_crypto_funcs->ccsha1_di, hmac_ctx);
501	g_crypto_funcs->cchmac_init_fn(g_crypto_funcs->ccsha1_di, hmac_ctx, group->token_key_size, group->token_key);
502
503	while (curr_mbuf != NULL) {
504	g_crypto_funcs->cchmac_update_fn(g_crypto_funcs->ccsha1_di, hmac_ctx, mbuf_len(curr_mbuf), mbuf_data(curr_mbuf));
505	curr_mbuf = mbuf_next(curr_mbuf);
506	}
507
508	g_crypto_funcs->cchmac_final_fn(g_crypto_funcs->ccsha1_di, hmac_ctx, hmac);
509
510	return `0`;
511	}
512
513	static int
514	flow_divert_packet_verify_hmac(mbuf_t packet, uint32_t ctl_unit)
515	{
516	int error = `0`;
517	struct flow_divert_group *group = NULL;
518	int hmac_offset;
519	uint8_t packet_hmac[SHA_DIGEST_LENGTH];
520	uint8_t computed_hmac[SHA_DIGEST_LENGTH];
521	mbuf_t tail;
522
523	lck_rw_lock_shared(&g_flow_divert_group_lck);
524
525	if (g_flow_divert_groups != NULL && g_active_group_count > `0`) {
526	group = g_flow_divert_groups[ctl_unit];
527	}
528
529	if (group == NULL) {
530	lck_rw_done(&g_flow_divert_group_lck);
531	return ENOPROTOOPT;
532	}
533
534	lck_rw_lock_shared(&group->lck);
535
536	if (group->token_key == NULL) {
537	error = ENOPROTOOPT;
538	goto done;
539	}
540
541	hmac_offset = flow_divert_packet_find_tlv(packet, `0`, FLOW_DIVERT_TLV_HMAC, &error, `0`);
542	if (hmac_offset < `0`) {
543	goto done;
544	}
545
546	error = flow_divert_packet_get_tlv(packet, hmac_offset, FLOW_DIVERT_TLV_HMAC, sizeof(packet_hmac), packet_hmac, NULL);
547	if (error) {
548	goto done;
549	}
550
551	/ Chop off the HMAC TLV /
552	error = mbuf_split(packet, hmac_offset, MBUF_WAITOK, &tail);
553	if (error) {
554	goto done;
555	}
556
557	mbuf_free(tail);
558
559	error = flow_divert_packet_compute_hmac(packet, group, computed_hmac);
560	if (error) {
561	goto done;
562	}
563
564	if (memcmp(packet_hmac, computed_hmac, sizeof(packet_hmac))) {
565	FDLOG0(LOG_WARNING, &nil_pcb, "HMAC in token does not match computed HMAC");
566	error = EINVAL;
567	goto done;
568	}
569
570	done:
571	lck_rw_done(&group->lck);
572	lck_rw_done(&g_flow_divert_group_lck);
573	return error;
574	}
575
576	static void
577	flow_divert_add_data_statistics(struct flow_divert_pcb fd_cb, int* data_len, Boolean send)
578	{
579	struct inpcb *inp = NULL;
580	struct ifnet *ifp = NULL;
581	Boolean cell = FALSE;
582	Boolean wifi = FALSE;
583	Boolean wired = FALSE;
584
585	inp = sotoinpcb(fd_cb->so);
586	if (inp == NULL) {
587	return;
588	}
589
590	ifp = inp->inp_last_outifp;
591	if (ifp != NULL) {
592	cell = IFNET_IS_CELLULAR(ifp);
593	wifi = (!cell && IFNET_IS_WIFI(ifp));
594	wired = (!wifi && IFNET_IS_WIRED(ifp));
595	}
596
597	if (send) {
598	INP_ADD_STAT(inp, cell, wifi, wired, txpackets, `1`);
599	INP_ADD_STAT(inp, cell, wifi, wired, txbytes, data_len);
600	} else {
601	INP_ADD_STAT(inp, cell, wifi, wired, rxpackets, `1`);
602	INP_ADD_STAT(inp, cell, wifi, wired, rxbytes, data_len);
603	}
604	inp_set_activity_bitmap(inp);
605	}
606
607	static errno_t
608	flow_divert_check_no_cellular(struct flow_divert_pcb *fd_cb)
609	{
610	struct inpcb *inp = NULL;
611
612	inp = sotoinpcb(fd_cb->so);
613	if (inp && INP_NO_CELLULAR(inp) && inp->inp_last_outifp &&
614	IFNET_IS_CELLULAR(inp->inp_last_outifp))
615	return EHOSTUNREACH;
616
617	return `0`;
618	}
619
620	static errno_t
621	flow_divert_check_no_expensive(struct flow_divert_pcb *fd_cb)
622	{
623	struct inpcb *inp = NULL;
624
625	inp = sotoinpcb(fd_cb->so);
626	if (inp && INP_NO_EXPENSIVE(inp) && inp->inp_last_outifp &&
627	IFNET_IS_EXPENSIVE(inp->inp_last_outifp))
628	return EHOSTUNREACH;
629
630	return `0`;
631	}
632
633	static void
634	flow_divert_update_closed_state(struct flow_divert_pcb fd_cb, int* how, Boolean tunnel)
635	{
636	if (how != SHUT_RD) {
637	fd_cb->flags \|= FLOW_DIVERT_WRITE_CLOSED;
638	if (tunnel \|\| !(fd_cb->flags & FLOW_DIVERT_CONNECT_STARTED)) {
639	fd_cb->flags \|= FLOW_DIVERT_TUNNEL_WR_CLOSED;
640	/ If the tunnel is not accepting writes any more, then flush the send buffer /
641	sbflush(&fd_cb->so->so_snd);
642	}
643	}
644	if (how != SHUT_WR) {
645	fd_cb->flags \|= FLOW_DIVERT_READ_CLOSED;
646	if (tunnel \|\| !(fd_cb->flags & FLOW_DIVERT_CONNECT_STARTED)) {
647	fd_cb->flags \|= FLOW_DIVERT_TUNNEL_RD_CLOSED;
648	}
649	}
650	}
651
652	static uint16_t
653	trie_node_alloc(struct flow_divert_trie *trie)
654	{
655	if (trie->nodes_free_next < trie->nodes_count) {
656	uint16_t node_idx = trie->nodes_free_next++;
657	TRIE_NODE(trie, node_idx).child_map = NULL_TRIE_IDX;
658	return node_idx;
659	} else {
660	return NULL_TRIE_IDX;
661	}
662	}
663
664	static uint16_t
665	trie_child_map_alloc(struct flow_divert_trie *trie)
666	{
667	if (trie->child_maps_free_next < trie->child_maps_count) {
668	return trie->child_maps_free_next++;
669	} else {
670	return NULL_TRIE_IDX;
671	}
672	}
673
674	static uint16_t
675	trie_bytes_move(struct flow_divert_trie *trie, uint16_t bytes_idx, size_t bytes_size)
676	{
677	uint16_t start = trie->bytes_free_next;
678	if (start + bytes_size <= trie->bytes_count) {
679	if (start != bytes_idx) {
680	memmove(&TRIE_BYTE(trie, start), &TRIE_BYTE(trie, bytes_idx), bytes_size);
681	}
682	trie->bytes_free_next += bytes_size;
683	return start;
684	} else {
685	return NULL_TRIE_IDX;
686	}
687	}
688
689	static uint16_t
690	flow_divert_trie_insert(struct flow_divert_trie *trie, uint16_t string_start, size_t string_len)
691	{
692	uint16_t current = trie->root;
693	uint16_t child = trie->root;
694	uint16_t string_end = string_start + string_len;
695	uint16_t string_idx = string_start;
696	uint16_t string_remainder = string_len;
697
698	while (child != NULL_TRIE_IDX) {
699	uint16_t parent = current;
700	uint16_t node_idx;
701	uint16_t current_end;
702
703	current = child;
704	child = NULL_TRIE_IDX;
705
706	current_end = TRIE_NODE(trie, current).start + TRIE_NODE(trie, current).length;
707
708	for (node_idx = TRIE_NODE(trie, current).start;
709	node_idx < current_end &&
710	string_idx < string_end &&
711	TRIE_BYTE(trie, node_idx) == TRIE_BYTE(trie, string_idx);
712	node_idx++, string_idx++);
713
714	string_remainder = string_end - string_idx;
715
716	if (node_idx < (TRIE_NODE(trie, current).start + TRIE_NODE(trie, current).length)) {
717	/*
718	* We did not reach the end of the current node's string.
719	* We need to split the current node into two:
720	* 1. A new node that contains the prefix of the node that matches
721	* the prefix of the string being inserted.
722	* 2. The current node modified to point to the remainder
723	* of the current node's string.
724	*/
725	uint16_t prefix = trie_node_alloc(trie);
726	if (prefix == NULL_TRIE_IDX) {
727	FDLOG0(LOG_ERR, &nil_pcb, "Ran out of trie nodes while splitting an existing node");
728	return NULL_TRIE_IDX;
729	}
730
731	/*
732	* Prefix points to the portion of the current nodes's string that has matched
733	* the input string thus far.
734	*/
735	TRIE_NODE(trie, prefix).start = TRIE_NODE(trie, current).start;
736	TRIE_NODE(trie, prefix).length = (node_idx - TRIE_NODE(trie, current).start);
737
738	/*
739	* Prefix has the current node as the child corresponding to the first byte
740	* after the split.
741	*/
742	TRIE_NODE(trie, prefix).child_map = trie_child_map_alloc(trie);
743	if (TRIE_NODE(trie, prefix).child_map == NULL_TRIE_IDX) {
744	FDLOG0(LOG_ERR, &nil_pcb, "Ran out of child maps while splitting an existing node");
745	return NULL_TRIE_IDX;
746	}
747	TRIE_CHILD(trie, prefix, TRIE_BYTE(trie, node_idx)) = current;
748
749	/ Parent has the prefix as the child correspoding to the first byte in the prefix /
750	TRIE_CHILD(trie, parent, TRIE_BYTE(trie, TRIE_NODE(trie, prefix).start)) = prefix;
751
752	/ Current node is adjusted to point to the remainder /
753	TRIE_NODE(trie, current).start = node_idx;
754	TRIE_NODE(trie, current).length -= TRIE_NODE(trie, prefix).length;
755
756	/ We want to insert the new leaf (if any) as a child of the prefix /
757	current = prefix;
758	}
759
760	if (string_remainder > `0`) {
761	/*
762	* We still have bytes in the string that have not been matched yet.
763	* If the current node has children, iterate to the child corresponding
764	* to the next byte in the string.
765	*/
766	if (TRIE_NODE(trie, current).child_map != NULL_TRIE_IDX) {
767	child = TRIE_CHILD(trie, current, TRIE_BYTE(trie, string_idx));
768	}
769	}
770	} / while (child != NULL_TRIE_IDX) /
771
772	if (string_remainder > `0`) {
773	/ Add a new leaf containing the remainder of the string /
774	uint16_t leaf = trie_node_alloc(trie);
775	if (leaf == NULL_TRIE_IDX) {
776	FDLOG0(LOG_ERR, &nil_pcb, "Ran out of trie nodes while inserting a new leaf");
777	return NULL_TRIE_IDX;
778	}
779
780	TRIE_NODE(trie, leaf).start = trie_bytes_move(trie, string_idx, string_remainder);
781	if (TRIE_NODE(trie, leaf).start == NULL_TRIE_IDX) {
782	FDLOG0(LOG_ERR, &nil_pcb, "Ran out of bytes while inserting a new leaf");
783	return NULL_TRIE_IDX;
784	}
785	TRIE_NODE(trie, leaf).length = string_remainder;
786
787	/ Set the new leaf as the child of the current node /
788	if (TRIE_NODE(trie, current).child_map == NULL_TRIE_IDX) {
789	TRIE_NODE(trie, current).child_map = trie_child_map_alloc(trie);
790	if (TRIE_NODE(trie, current).child_map == NULL_TRIE_IDX) {
791	FDLOG0(LOG_ERR, &nil_pcb, "Ran out of child maps while inserting a new leaf");
792	return NULL_TRIE_IDX;
793	}
794	}
795	TRIE_CHILD(trie, current, TRIE_BYTE(trie, TRIE_NODE(trie, leaf).start)) = leaf;
796	current = leaf;
797	} / else duplicate or this string is a prefix of one of the existing strings /
798
799	return current;
800	}
801
802	#define APPLE_WEBCLIP_ID_PREFIX "com.apple.webapp"
803	static uint16_t
804	flow_divert_trie_search(struct flow_divert_trie trie, uint8_t string_bytes)
805	{
806	uint16_t current = trie->root;
807	uint16_t string_idx = `0`;
808
809	while (current != NULL_TRIE_IDX) {
810	uint16_t next = NULL_TRIE_IDX;
811	uint16_t node_end = TRIE_NODE(trie, current).start + TRIE_NODE(trie, current).length;
812	uint16_t node_idx;
813
814	for (node_idx = TRIE_NODE(trie, current).start;
815	node_idx < node_end && string_bytes[string_idx] != `'\0'` && string_bytes[string_idx] == TRIE_BYTE(trie, node_idx);
816	node_idx++, string_idx++);
817
818	if (node_idx == node_end) {
819	if (string_bytes[string_idx] == `'\0'`) {
820	return current; / Got an exact match /
821	} else if (string_idx == strlen(APPLE_WEBCLIP_ID_PREFIX) &&
822	`0` == strncmp((const char *)string_bytes, APPLE_WEBCLIP_ID_PREFIX, string_idx)) {
823	string_bytes[string_idx] = `'\0'`;
824	return current; / Got an apple webclip id prefix match /
825	} else if (TRIE_NODE(trie, current).child_map != NULL_TRIE_IDX) {
826	next = TRIE_CHILD(trie, current, string_bytes[string_idx]);
827	}
828	}
829	current = next;
830	}
831
832	return NULL_TRIE_IDX;
833	}
834
835	struct uuid_search_info {
836	uuid_t target_uuid;
837	char *found_signing_id;
838	boolean_t found_multiple_signing_ids;
839	proc_t found_proc;
840	};
841
842	static int
843	flow_divert_find_proc_by_uuid_callout(proc_t p, void *arg)
844	{
845	struct uuid_search_info info = (struct* uuid_search_info *)arg;
846	int result = PROC_RETURNED_DONE; / By default, we didn't find the process /
847
848	if (info->found_signing_id != NULL) {
849	if (!info->found_multiple_signing_ids) {
850	/ All processes that were found had the same signing identifier, so just claim this first one and be done. /
851	info->found_proc = p;
852	result = PROC_CLAIMED_DONE;
853	} else {
854	uuid_string_t uuid_str;
855	uuid_unparse(info->target_uuid, uuid_str);
856	FDLOG(LOG_WARNING, &nil_pcb, "Found multiple processes with UUID %s with different signing identifiers", uuid_str);
857	}
858	FREE(info->found_signing_id, M_TEMP);
859	info->found_signing_id = NULL;
860	}
861
862	if (result == PROC_RETURNED_DONE) {
863	uuid_string_t uuid_str;
864	uuid_unparse(info->target_uuid, uuid_str);
865	FDLOG(LOG_WARNING, &nil_pcb, "Failed to find a process with UUID %s", uuid_str);
866	}
867
868	return result;
869	}
870
871	static int
872	flow_divert_find_proc_by_uuid_filter(proc_t p, void *arg)
873	{
874	struct uuid_search_info info = (struct* uuid_search_info *)arg;
875	int include = `0`;
876
877	if (info->found_multiple_signing_ids) {
878	return include;
879	}
880
881	include = (uuid_compare(p->p_uuid, info->target_uuid) == `0`);
882	if (include) {
883	const char *signing_id = cs_identity_get(p);
884	if (signing_id != NULL) {
885	FDLOG(LOG_INFO, &nil_pcb, "Found process %d with signing identifier %s", p->p_pid, signing_id);
886	size_t signing_id_size = strlen(signing_id) + `1`;
887	if (info->found_signing_id == NULL) {
888	MALLOC(info->found_signing_id, char *, signing_id_size, M_TEMP, M_WAITOK);
889	memcpy(info->found_signing_id, signing_id, signing_id_size);
890	} else if (memcmp(signing_id, info->found_signing_id, signing_id_size)) {
891	info->found_multiple_signing_ids = TRUE;
892	}
893	} else {
894	info->found_multiple_signing_ids = TRUE;
895	}
896	include = !info->found_multiple_signing_ids;
897	}
898
899	return include;
900	}
901
902	static proc_t
903	flow_divert_find_proc_by_uuid(uuid_t uuid)
904	{
905	struct uuid_search_info info;
906
907	if (LOG_INFO <= nil_pcb.log_level) {
908	uuid_string_t uuid_str;
909	uuid_unparse(uuid, uuid_str);
910	FDLOG(LOG_INFO, &nil_pcb, "Looking for process with UUID %s", uuid_str);
911	}
912
913	memset(&info, `0`, sizeof(info));
914	info.found_proc = PROC_NULL;
915	uuid_copy(info.target_uuid, uuid);
916
917	proc_iterate(PROC_ALLPROCLIST, flow_divert_find_proc_by_uuid_callout, &info, flow_divert_find_proc_by_uuid_filter, &info);
918
919	return info.found_proc;
920	}
921
922	static int
923	flow_divert_get_src_proc(struct socket so, proc_t proc)
924	{
925	int release = `0`;
926
927	if (so->so_flags & SOF_DELEGATED) {
928	if ((*proc)->p_pid != so->e_pid) {
929	*proc = proc_find(so->e_pid);
930	release = `1`;
931	} else if (uuid_compare((*proc)->p_uuid, so->e_uuid)) {
932	*proc = flow_divert_find_proc_by_uuid(so->e_uuid);
933	release = `1`;
934	}
935	} else if (*proc == PROC_NULL) {
936	*proc = current_proc();
937	}
938
939	if (*proc != PROC_NULL) {
940	if ((*proc)->p_pid == `0`) {
941	if (release) {
942	proc_rele(*proc);
943	}
944	release = `0`;
945	*proc = PROC_NULL;
946	}
947	}
948
949	return release;
950	}
951
952	static int
953	flow_divert_send_packet(struct flow_divert_pcb *fd_cb, mbuf_t packet, Boolean enqueue)
954	{
955	int error;
956
957	if (fd_cb->group == NULL) {
958	fd_cb->so->so_error = ECONNABORTED;
959	flow_divert_disconnect_socket(fd_cb->so);
960	return ECONNABORTED;
961	}
962
963	lck_rw_lock_shared(&fd_cb->group->lck);
964
965	if (MBUFQ_EMPTY(&fd_cb->group->send_queue)) {
966	error = ctl_enqueuembuf(g_flow_divert_kctl_ref, fd_cb->group->ctl_unit, packet, CTL_DATA_EOR);
967	} else {
968	error = ENOBUFS;
969	}
970
971	if (error == ENOBUFS) {
972	if (enqueue) {
973	if (!lck_rw_lock_shared_to_exclusive(&fd_cb->group->lck)) {
974	lck_rw_lock_exclusive(&fd_cb->group->lck);
975	}
976	MBUFQ_ENQUEUE(&fd_cb->group->send_queue, packet);
977	error = `0`;
978	}
979	OSTestAndSet(GROUP_BIT_CTL_ENQUEUE_BLOCKED, &fd_cb->group->atomic_bits);
980	}
981
982	lck_rw_done(&fd_cb->group->lck);
983
984	return error;
985	}
986
987	static int
988	flow_divert_create_connect_packet(struct flow_divert_pcb fd_cb, struct* sockaddr to, struct* socket so, proc_t p, mbuf_t out_connect_packet)
989	{
990	int error = `0`;
991	int flow_type = `0`;
992	char *signing_id = NULL;
993	int free_signing_id = `0`;
994	mbuf_t connect_packet = NULL;
995	proc_t src_proc = p;
996	int release_proc = `0`;
997
998	error = flow_divert_packet_init(fd_cb, FLOW_DIVERT_PKT_CONNECT, &connect_packet);
999	if (error) {
1000	goto done;
1001	}
1002
1003	error = EPERM;
1004
1005	if (fd_cb->connect_token != NULL && (fd_cb->flags & FLOW_DIVERT_HAS_HMAC)) {
1006	uint32_t sid_size = `0`;
1007	int find_error = flow_divert_packet_get_tlv(fd_cb->connect_token, `0`, FLOW_DIVERT_TLV_SIGNING_ID, `0`, NULL, &sid_size);
1008	if (find_error == `0` && sid_size > `0`) {
1009	MALLOC(signing_id, char *, sid_size + `1`, M_TEMP, M_WAITOK \| M_ZERO);
1010	if (signing_id != NULL) {
1011	flow_divert_packet_get_tlv(fd_cb->connect_token, `0`, FLOW_DIVERT_TLV_SIGNING_ID, sid_size, signing_id, NULL);
1012	FDLOG(LOG_INFO, fd_cb, "Got %s from token", signing_id);
1013	free_signing_id = `1`;
1014	}
1015	}
1016	}
1017
1018	socket_unlock(so, `0`);
1019
1020	if (signing_id == NULL) {
1021	release_proc = flow_divert_get_src_proc(so, &src_proc);
1022	if (src_proc != PROC_NULL) {
1023	proc_lock(src_proc);
1024	if (src_proc->p_csflags & (CS_VALID\|CS_DEBUGGED)) {
1025	const char * cs_id;
1026	cs_id = cs_identity_get(src_proc);
1027	signing_id = __DECONST(char *, cs_id);
1028	} else {
1029	FDLOG0(LOG_WARNING, fd_cb, "Signature is invalid");
1030	}
1031	} else {
1032	FDLOG0(LOG_WARNING, fd_cb, "Failed to determine the current proc");
1033	}
1034	} else {
1035	src_proc = PROC_NULL;
1036	}
1037
1038	if (signing_id != NULL) {
1039	uint16_t result = NULL_TRIE_IDX;
1040	lck_rw_lock_shared(&fd_cb->group->lck);
1041	if (fd_cb->group->flags & FLOW_DIVERT_GROUP_FLAG_NO_APP_MAP) {
1042	result = `1`;
1043	} else {
1044	result = flow_divert_trie_search(&fd_cb->group->signing_id_trie, (uint8_t *)signing_id);
1045	}
1046	lck_rw_done(&fd_cb->group->lck);
1047	if (result != NULL_TRIE_IDX) {
1048	error = `0`;
1049	FDLOG(LOG_INFO, fd_cb, "%s matched", signing_id);
1050
1051	error = flow_divert_packet_append_tlv(connect_packet, FLOW_DIVERT_TLV_SIGNING_ID, strlen(signing_id), signing_id);
1052	if (error == `0`) {
1053	if (src_proc != PROC_NULL) {
1054	unsigned char cdhash[SHA1_RESULTLEN];
1055	error = proc_getcdhash(src_proc, cdhash);
1056	if (error == `0`) {
1057	error = flow_divert_packet_append_tlv(connect_packet, FLOW_DIVERT_TLV_CDHASH, sizeof(cdhash), cdhash);
1058	if (error) {
1059	FDLOG(LOG_ERR, fd_cb, "failed to append the cdhash: %d", error);
1060	}
1061	} else {
1062	FDLOG(LOG_ERR, fd_cb, "failed to get the cdhash: %d", error);
1063	}
1064	}
1065	} else {
1066	FDLOG(LOG_ERR, fd_cb, "failed to append the signing ID: %d", error);
1067	}
1068	} else {
1069	FDLOG(LOG_WARNING, fd_cb, "%s did not match", signing_id);
1070	}
1071	} else {
1072	FDLOG0(LOG_WARNING, fd_cb, "Failed to get the code signing identity");
1073	if (fd_cb->group->flags & FLOW_DIVERT_GROUP_FLAG_NO_APP_MAP) {
1074	error = `0`;
1075	}
1076	}
1077
1078	if (src_proc != PROC_NULL) {
1079	proc_unlock(src_proc);
1080	if (release_proc) {
1081	proc_rele(src_proc);
1082	}
1083	}
1084	socket_lock(so, `0`);
1085
1086	if (free_signing_id) {
1087	FREE(signing_id, M_TEMP);
1088	}
1089
1090	if (error) {
1091	goto done;
1092	}
1093
1094	error = flow_divert_packet_append_tlv(connect_packet,
1095	FLOW_DIVERT_TLV_TRAFFIC_CLASS,
1096	sizeof(fd_cb->so->so_traffic_class),
1097	&fd_cb->so->so_traffic_class);
1098	if (error) {
1099	goto done;
1100	}
1101
1102	if (SOCK_TYPE(fd_cb->so) == SOCK_STREAM) {
1103	flow_type = FLOW_DIVERT_FLOW_TYPE_TCP;
1104	} else if (SOCK_TYPE(fd_cb->so) == SOCK_DGRAM) {
1105	flow_type = FLOW_DIVERT_FLOW_TYPE_UDP;
1106	} else {
1107	error = EINVAL;
1108	goto done;
1109	}
1110	error = flow_divert_packet_append_tlv(connect_packet,
1111	FLOW_DIVERT_TLV_FLOW_TYPE,
1112	sizeof(flow_type),
1113	&flow_type);
1114
1115	if (error) {
1116	goto done;
1117	}
1118
1119	if (fd_cb->so->so_flags & SOF_DELEGATED) {
1120	error = flow_divert_packet_append_tlv(connect_packet,
1121	FLOW_DIVERT_TLV_PID,
1122	sizeof(fd_cb->so->e_pid),
1123	&fd_cb->so->e_pid);
1124	if (error) {
1125	goto done;
1126	}
1127
1128	error = flow_divert_packet_append_tlv(connect_packet,
1129	FLOW_DIVERT_TLV_UUID,
1130	sizeof(fd_cb->so->e_uuid),
1131	&fd_cb->so->e_uuid);
1132	if (error) {
1133	goto done;
1134	}
1135	} else {
1136	error = flow_divert_packet_append_tlv(connect_packet,
1137	FLOW_DIVERT_TLV_PID,
1138	sizeof(fd_cb->so->e_pid),
1139	&fd_cb->so->last_pid);
1140	if (error) {
1141	goto done;
1142	}
1143
1144	error = flow_divert_packet_append_tlv(connect_packet,
1145	FLOW_DIVERT_TLV_UUID,
1146	sizeof(fd_cb->so->e_uuid),
1147	&fd_cb->so->last_uuid);
1148	if (error) {
1149	goto done;
1150	}
1151	}
1152
1153	if (fd_cb->connect_token != NULL) {
1154	unsigned int token_len = m_length(fd_cb->connect_token);
1155	mbuf_concatenate(connect_packet, fd_cb->connect_token);
1156	mbuf_pkthdr_adjustlen(connect_packet, token_len);
1157	fd_cb->connect_token = NULL;
1158	} else {
1159	uint32_t ctl_unit = htonl(fd_cb->control_group_unit);
1160
1161	error = flow_divert_packet_append_tlv(connect_packet, FLOW_DIVERT_TLV_CTL_UNIT, sizeof(ctl_unit), &ctl_unit);
1162	if (error) {
1163	goto done;
1164	}
1165
1166	error = flow_divert_append_target_endpoint_tlv(connect_packet, to);
1167	if (error) {
1168	goto done;
1169	}
1170	}
1171
1172	if (fd_cb->local_address != NULL) {
1173	error = EALREADY;
1174	goto done;
1175	} else {
1176	struct inpcb *inp = sotoinpcb(so);
1177	if (flow_divert_has_pcb_local_address(inp)) {
1178	error = flow_divert_inp_to_sockaddr(inp, &fd_cb->local_address);
1179	if (error) {
1180	FDLOG0(LOG_ERR, fd_cb, "failed to get the local socket address.");
1181	goto done;
1182	}
1183	}
1184	}
1185
1186	if (fd_cb->local_address != NULL) {
1187	/ socket is bound. /
1188	error = flow_divert_packet_append_tlv(connect_packet, FLOW_DIVERT_TLV_LOCAL_ADDR,
1189	sizeof(struct sockaddr_storage), fd_cb->local_address);
1190	if (error) {
1191	goto done;
1192	}
1193	}
1194
1195	if (so->so_flags1 & SOF1_DATA_IDEMPOTENT) {
1196	uint32_t flags = FLOW_DIVERT_TOKEN_FLAG_TFO;
1197	error = flow_divert_packet_append_tlv(connect_packet, FLOW_DIVERT_TLV_FLAGS, sizeof(flags), &flags);
1198	if (error) {
1199	goto done;
1200	}
1201	}
1202
1203	done:
1204	if (!error) {
1205	*out_connect_packet = connect_packet;
1206	} else if (connect_packet != NULL) {
1207	mbuf_freem(connect_packet);
1208	}
1209
1210	return error;
1211	}
1212
1213	static int
1214	flow_divert_send_connect_result(struct flow_divert_pcb *fd_cb)
1215	{
1216	int error = `0`;
1217	mbuf_t packet = NULL;
1218	int rbuff_space = `0`;
1219
1220	error = flow_divert_packet_init(fd_cb, FLOW_DIVERT_PKT_CONNECT_RESULT, &packet);
1221	if (error) {
1222	FDLOG(LOG_ERR, fd_cb, "failed to create a connect result packet: %d", error);
1223	goto done;
1224	}
1225
1226	rbuff_space = fd_cb->so->so_rcv.sb_hiwat;
1227	if (rbuff_space < `0`) {
1228	rbuff_space = `0`;
1229	}
1230	rbuff_space = htonl(rbuff_space);
1231	error = flow_divert_packet_append_tlv(packet,
1232	FLOW_DIVERT_TLV_SPACE_AVAILABLE,
1233	sizeof(rbuff_space),
1234	&rbuff_space);
1235	if (error) {
1236	goto done;
1237	}
1238
1239	error = flow_divert_send_packet(fd_cb, packet, TRUE);
1240	if (error) {
1241	goto done;
1242	}
1243
1244	done:
1245	if (error && packet != NULL) {
1246	mbuf_freem(packet);
1247	}
1248
1249	return error;
1250	}
1251
1252	static int
1253	flow_divert_send_close(struct flow_divert_pcb fd_cb, int* how)
1254	{
1255	int error = `0`;
1256	mbuf_t packet = NULL;
1257	uint32_t zero = `0`;
1258
1259	error = flow_divert_packet_init(fd_cb, FLOW_DIVERT_PKT_CLOSE, &packet);
1260	if (error) {
1261	FDLOG(LOG_ERR, fd_cb, "failed to create a close packet: %d", error);
1262	goto done;
1263	}
1264
1265	error = flow_divert_packet_append_tlv(packet, FLOW_DIVERT_TLV_ERROR_CODE, sizeof(zero), &zero);
1266	if (error) {
1267	FDLOG(LOG_ERR, fd_cb, "failed to add the error code TLV: %d", error);
1268	goto done;
1269	}
1270
1271	how = htonl(how);
1272	error = flow_divert_packet_append_tlv(packet, FLOW_DIVERT_TLV_HOW, sizeof(how), &how);
1273	if (error) {
1274	FDLOG(LOG_ERR, fd_cb, "failed to add the how flag: %d", error);
1275	goto done;
1276	}
1277
1278	error = flow_divert_send_packet(fd_cb, packet, TRUE);
1279	if (error) {
1280	goto done;
1281	}
1282
1283	done:
1284	if (error && packet != NULL) {
1285	mbuf_free(packet);
1286	}
1287
1288	return error;
1289	}
1290
1291	static int
1292	flow_divert_tunnel_how_closed(struct flow_divert_pcb *fd_cb)
1293	{
1294	if ((fd_cb->flags & (FLOW_DIVERT_TUNNEL_RD_CLOSED\|FLOW_DIVERT_TUNNEL_WR_CLOSED)) ==
1295	(FLOW_DIVERT_TUNNEL_RD_CLOSED\|FLOW_DIVERT_TUNNEL_WR_CLOSED))
1296	{
1297	return SHUT_RDWR;
1298	} else if (fd_cb->flags & FLOW_DIVERT_TUNNEL_RD_CLOSED) {
1299	return SHUT_RD;
1300	} else if (fd_cb->flags & FLOW_DIVERT_TUNNEL_WR_CLOSED) {
1301	return SHUT_WR;
1302	}
1303
1304	return -`1`;
1305	}
1306
1307	/*
1308	* Determine what close messages if any need to be sent to the tunnel. Returns TRUE if the tunnel is closed for both reads and
1309	* writes. Returns FALSE otherwise.
1310	*/
1311	static void
1312	flow_divert_send_close_if_needed(struct flow_divert_pcb *fd_cb)
1313	{
1314	int how = -`1`;
1315
1316	/ Do not send any close messages if there is still data in the send buffer /
1317	if (fd_cb->so->so_snd.sb_cc == `0`) {
1318	if ((fd_cb->flags & (FLOW_DIVERT_READ_CLOSED\|FLOW_DIVERT_TUNNEL_RD_CLOSED)) == FLOW_DIVERT_READ_CLOSED) {
1319	/ Socket closed reads, but tunnel did not. Tell tunnel to close reads /
1320	how = SHUT_RD;
1321	}
1322	if ((fd_cb->flags & (FLOW_DIVERT_WRITE_CLOSED\|FLOW_DIVERT_TUNNEL_WR_CLOSED)) == FLOW_DIVERT_WRITE_CLOSED) {
1323	/ Socket closed writes, but tunnel did not. Tell tunnel to close writes /
1324	if (how == SHUT_RD) {
1325	how = SHUT_RDWR;
1326	} else {
1327	how = SHUT_WR;
1328	}
1329	}
1330	}
1331
1332	if (how != -`1`) {
1333	FDLOG(LOG_INFO, fd_cb, "sending close, how = %d", how);
1334	if (flow_divert_send_close(fd_cb, how) != ENOBUFS) {
1335	/ Successfully sent the close packet. Record the ways in which the tunnel has been closed /
1336	if (how != SHUT_RD) {
1337	fd_cb->flags \|= FLOW_DIVERT_TUNNEL_WR_CLOSED;
1338	}
1339	if (how != SHUT_WR) {
1340	fd_cb->flags \|= FLOW_DIVERT_TUNNEL_RD_CLOSED;
1341	}
1342	}
1343	}
1344
1345	if (flow_divert_tunnel_how_closed(fd_cb) == SHUT_RDWR) {
1346	flow_divert_disconnect_socket(fd_cb->so);
1347	}
1348	}
1349
1350	static errno_t
1351	flow_divert_send_data_packet(struct flow_divert_pcb fd_cb, mbuf_t data, size_t data_len, struct* sockaddr *toaddr, Boolean force)
1352	{
1353	mbuf_t packet;
1354	mbuf_t last;
1355	int error = `0`;
1356
1357	error = flow_divert_packet_init(fd_cb, FLOW_DIVERT_PKT_DATA, &packet);
1358	if (error) {
1359	FDLOG(LOG_ERR, fd_cb, "flow_divert_packet_init failed: %d", error);
1360	return error;
1361	}
1362
1363	if (toaddr != NULL) {
1364	error = flow_divert_append_target_endpoint_tlv(packet, toaddr);
1365	if (error) {
1366	FDLOG(LOG_ERR, fd_cb, "flow_divert_append_target_endpoint_tlv() failed: %d", error);
1367	return error;
1368	}
1369	}
1370
1371	if (data_len > `0` && data != NULL) {
1372	last = m_last(packet);
1373	mbuf_setnext(last, data);
1374	mbuf_pkthdr_adjustlen(packet, data_len);
1375	}
1376	error = flow_divert_send_packet(fd_cb, packet, force);
1377
1378	if (error) {
1379	mbuf_setnext(last, NULL);
1380	mbuf_freem(packet);
1381	} else {
1382	fd_cb->bytes_sent += data_len;
1383	flow_divert_add_data_statistics(fd_cb, data_len, TRUE);
1384	}
1385
1386	return error;
1387	}
1388
1389	static void
1390	flow_divert_send_buffered_data(struct flow_divert_pcb *fd_cb, Boolean force)
1391	{
1392	size_t to_send;
1393	size_t sent = `0`;
1394	int error = `0`;
1395	mbuf_t buffer;
1396
1397	to_send = fd_cb->so->so_snd.sb_cc;
1398	buffer = fd_cb->so->so_snd.sb_mb;
1399
1400	if (buffer == NULL && to_send > `0`) {
1401	FDLOG(LOG_ERR, fd_cb, "Send buffer is NULL, but size is supposed to be %lu", to_send);
1402	return;
1403	}
1404
1405	/ Ignore the send window if force is enabled /
1406	if (!force && (to_send > fd_cb->send_window)) {
1407	to_send = fd_cb->send_window;
1408	}
1409
1410	if (SOCK_TYPE(fd_cb->so) == SOCK_STREAM) {
1411	while (sent < to_send) {
1412	mbuf_t data;
1413	size_t data_len;
1414
1415	data_len = to_send - sent;
1416	if (data_len > FLOW_DIVERT_CHUNK_SIZE) {
1417	data_len = FLOW_DIVERT_CHUNK_SIZE;
1418	}
1419
1420	error = mbuf_copym(buffer, sent, data_len, MBUF_DONTWAIT, &data);
1421	if (error) {
1422	FDLOG(LOG_ERR, fd_cb, "mbuf_copym failed: %d", error);
1423	break;
1424	}
1425
1426	error = flow_divert_send_data_packet(fd_cb, data, data_len, NULL, force);
1427	if (error) {
1428	mbuf_freem(data);
1429	break;
1430	}
1431
1432	sent += data_len;
1433	}
1434	sbdrop(&fd_cb->so->so_snd, sent);
1435	sowwakeup(fd_cb->so);
1436	} else if (SOCK_TYPE(fd_cb->so) == SOCK_DGRAM) {
1437	mbuf_t data;
1438	mbuf_t m;
1439	size_t data_len;
1440
1441	while(buffer) {
1442	struct sockaddr *toaddr = flow_divert_get_buffered_target_address(buffer);
1443
1444	m = buffer;
1445	if (toaddr != NULL) {
1446	/ look for data in the chain /
1447	do {
1448	m = m->m_next;
1449	if (m != NULL && m->m_type == MT_DATA) {
1450	break;
1451	}
1452	} while(m);
1453	if (m == NULL) {
1454	/ unexpected /
1455	FDLOG0(LOG_ERR, fd_cb, "failed to find type MT_DATA in the mbuf chain.");
1456	goto move_on;
1457	}
1458	}
1459	data_len = mbuf_pkthdr_len(m);
1460	if (data_len > `0`) {
1461	FDLOG(LOG_DEBUG, fd_cb, "mbuf_copym() data_len = %lu", data_len);
1462	error = mbuf_copym(m, `0`, data_len, MBUF_DONTWAIT, &data);
1463	if (error) {
1464	FDLOG(LOG_ERR, fd_cb, "mbuf_copym failed: %d", error);
1465	break;
1466	}
1467	} else {
1468	data = NULL;
1469	}
1470	error = flow_divert_send_data_packet(fd_cb, data, data_len, toaddr, force);
1471	if (error) {
1472	mbuf_freem(data);
1473	break;
1474	}
1475	sent += data_len;
1476	move_on:
1477	buffer = buffer->m_nextpkt;
1478	(void) sbdroprecord(&(fd_cb->so->so_snd));
1479	}
1480	}
1481
1482	if (sent > `0`) {
1483	FDLOG(LOG_DEBUG, fd_cb, "sent %lu bytes of buffered data", sent);
1484	if (fd_cb->send_window >= sent) {
1485	fd_cb->send_window -= sent;
1486	} else {
1487	fd_cb->send_window = `0`;
1488	}
1489	}
1490	}
1491
1492	static int
1493	flow_divert_send_app_data(struct flow_divert_pcb fd_cb, mbuf_t data, struct* sockaddr *toaddr)
1494	{
1495	size_t to_send = mbuf_pkthdr_len(data);
1496	int error = `0`;
1497
1498	if (to_send > fd_cb->send_window) {
1499	to_send = fd_cb->send_window;
1500	}
1501
1502	if (fd_cb->so->so_snd.sb_cc > `0`) {
1503	to_send = `0`; / If the send buffer is non-empty, then we can't send anything /
1504	}
1505
1506	if (SOCK_TYPE(fd_cb->so) == SOCK_STREAM) {
1507	size_t sent = `0`;
1508	mbuf_t remaining_data = data;
1509	mbuf_t pkt_data = NULL;
1510	while (sent < to_send && remaining_data != NULL) {
1511	size_t pkt_data_len;
1512
1513	pkt_data = remaining_data;
1514
1515	if ((to_send - sent) > FLOW_DIVERT_CHUNK_SIZE) {
1516	pkt_data_len = FLOW_DIVERT_CHUNK_SIZE;
1517	} else {
1518	pkt_data_len = to_send - sent;
1519	}
1520
1521	if (pkt_data_len < mbuf_pkthdr_len(pkt_data)) {
1522	error = mbuf_split(pkt_data, pkt_data_len, MBUF_DONTWAIT, &remaining_data);
1523	if (error) {
1524	FDLOG(LOG_ERR, fd_cb, "mbuf_split failed: %d", error);
1525	pkt_data = NULL;
1526	break;
1527	}
1528	} else {
1529	remaining_data = NULL;
1530	}
1531
1532	error = flow_divert_send_data_packet(fd_cb, pkt_data, pkt_data_len, NULL, FALSE);
1533
1534	if (error) {
1535	break;
1536	}
1537
1538	pkt_data = NULL;
1539	sent += pkt_data_len;
1540	}
1541
1542	fd_cb->send_window -= sent;
1543
1544	error = `0`;
1545
1546	if (pkt_data != NULL) {
1547	if (sbspace(&fd_cb->so->so_snd) > `0`) {
1548	if (!sbappendstream(&fd_cb->so->so_snd, pkt_data)) {
1549	FDLOG(LOG_ERR, fd_cb, "sbappendstream failed with pkt_data, send buffer size = %u, send_window = %u\n",
1550	fd_cb->so->so_snd.sb_cc, fd_cb->send_window);
1551	}
1552	} else {
1553	error = ENOBUFS;
1554	}
1555	}
1556
1557	if (remaining_data != NULL) {
1558	if (sbspace(&fd_cb->so->so_snd) > `0`) {
1559	if (!sbappendstream(&fd_cb->so->so_snd, remaining_data)) {
1560	FDLOG(LOG_ERR, fd_cb, "sbappendstream failed with remaining_data, send buffer size = %u, send_window = %u\n",
1561	fd_cb->so->so_snd.sb_cc, fd_cb->send_window);
1562	}
1563	} else {
1564	error = ENOBUFS;
1565	}
1566	}
1567	} else if (SOCK_TYPE(fd_cb->so) == SOCK_DGRAM) {
1568	if (to_send \|\| mbuf_pkthdr_len(data) == `0`) {
1569	error = flow_divert_send_data_packet(fd_cb, data, to_send, toaddr, FALSE);
1570	if (error) {
1571	FDLOG(LOG_ERR, fd_cb, "flow_divert_send_data_packet failed. send data size = %lu", to_send);
1572	} else {
1573	fd_cb->send_window -= to_send;
1574	}
1575	} else {
1576	/ buffer it /
1577	if (sbspace(&fd_cb->so->so_snd) >= (int)mbuf_pkthdr_len(data)) {
1578	if (toaddr != NULL) {
1579	if (!sbappendaddr(&fd_cb->so->so_snd, toaddr, data, NULL, &error)) {
1580	FDLOG(LOG_ERR, fd_cb,
1581	"sbappendaddr failed. send buffer size = %u, send_window = %u, error = %d\n",
1582	fd_cb->so->so_snd.sb_cc, fd_cb->send_window, error);
1583	}
1584	} else {
1585	if (!sbappendrecord(&fd_cb->so->so_snd, data)) {
1586	FDLOG(LOG_ERR, fd_cb,
1587	"sbappendrecord failed. send buffer size = %u, send_window = %u, error = %d\n",
1588	fd_cb->so->so_snd.sb_cc, fd_cb->send_window, error);
1589	}
1590	}
1591	} else {
1592	error = ENOBUFS;
1593	}
1594	}
1595	}
1596
1597	return error;
1598	}
1599
1600	static int
1601	flow_divert_send_read_notification(struct flow_divert_pcb *fd_cb, uint32_t read_count)
1602	{
1603	int error = `0`;
1604	mbuf_t packet = NULL;
1605	uint32_t net_read_count = htonl(read_count);
1606
1607	error = flow_divert_packet_init(fd_cb, FLOW_DIVERT_PKT_READ_NOTIFY, &packet);
1608	if (error) {
1609	FDLOG(LOG_ERR, fd_cb, "failed to create a read notification packet: %d", error);
1610	goto done;
1611	}
1612
1613	error = flow_divert_packet_append_tlv(packet, FLOW_DIVERT_TLV_READ_COUNT, sizeof(net_read_count), &net_read_count);
1614	if (error) {
1615	FDLOG(LOG_ERR, fd_cb, "failed to add the read count: %d", error);
1616	goto done;
1617	}
1618
1619	error = flow_divert_send_packet(fd_cb, packet, TRUE);
1620	if (error) {
1621	goto done;
1622	}
1623
1624	done:
1625	if (error && packet != NULL) {
1626	mbuf_free(packet);
1627	}
1628
1629	return error;
1630	}
1631
1632	static int
1633	flow_divert_send_traffic_class_update(struct flow_divert_pcb fd_cb, int* traffic_class)
1634	{
1635	int error = `0`;
1636	mbuf_t packet = NULL;
1637
1638	error = flow_divert_packet_init(fd_cb, FLOW_DIVERT_PKT_PROPERTIES_UPDATE, &packet);
1639	if (error) {
1640	FDLOG(LOG_ERR, fd_cb, "failed to create a properties update packet: %d", error);
1641	goto done;
1642	}
1643
1644	error = flow_divert_packet_append_tlv(packet, FLOW_DIVERT_TLV_TRAFFIC_CLASS, sizeof(traffic_class), &traffic_class);
1645	if (error) {
1646	FDLOG(LOG_ERR, fd_cb, "failed to add the traffic class: %d", error);
1647	goto done;
1648	}
1649
1650	error = flow_divert_send_packet(fd_cb, packet, TRUE);
1651	if (error) {
1652	goto done;
1653	}
1654
1655	done:
1656	if (error && packet != NULL) {
1657	mbuf_free(packet);
1658	}
1659
1660	return error;
1661	}
1662
1663	static void
1664	flow_divert_handle_connect_result(struct flow_divert_pcb fd_cb, mbuf_t packet, int* offset)
1665	{
1666	uint32_t connect_error;
1667	uint32_t ctl_unit = `0`;
1668	int error = `0`;
1669	struct flow_divert_group *grp = NULL;
1670	struct sockaddr_storage local_address;
1671	int out_if_index = `0`;
1672	struct sockaddr_storage remote_address;
1673	uint32_t send_window;
1674	uint32_t app_data_length = `0`;
1675
1676	memset(&local_address, `0`, sizeof(local_address));
1677	memset(&remote_address, `0`, sizeof(remote_address));
1678
1679	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_ERROR_CODE, sizeof(connect_error), &connect_error, NULL);
1680	if (error) {
1681	FDLOG(LOG_ERR, fd_cb, "failed to get the connect result: %d", error);
1682	return;
1683	}
1684
1685	FDLOG(LOG_INFO, fd_cb, "received connect result %u", connect_error);
1686
1687	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_SPACE_AVAILABLE, sizeof(send_window), &send_window, NULL);
1688	if (error) {
1689	FDLOG(LOG_ERR, fd_cb, "failed to get the send window: %d", error);
1690	return;
1691	}
1692
1693	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_CTL_UNIT, sizeof(ctl_unit), &ctl_unit, NULL);
1694	if (error) {
1695	FDLOG0(LOG_INFO, fd_cb, "No control unit provided in the connect result");
1696	}
1697
1698	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_LOCAL_ADDR, sizeof(local_address), &local_address, NULL);
1699	if (error) {
1700	FDLOG0(LOG_INFO, fd_cb, "No local address provided");
1701	}
1702
1703	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_REMOTE_ADDR, sizeof(remote_address), &remote_address, NULL);
1704	if (error) {
1705	FDLOG0(LOG_INFO, fd_cb, "No remote address provided");
1706	}
1707
1708	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_OUT_IF_INDEX, sizeof(out_if_index), &out_if_index, NULL);
1709	if (error) {
1710	FDLOG0(LOG_INFO, fd_cb, "No output if index provided");
1711	}
1712
1713	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_APP_DATA, `0`, NULL, &app_data_length);
1714	if (error) {
1715	FDLOG0(LOG_INFO, fd_cb, "No application data provided in connect result");
1716	}
1717
1718	error = `0`;
1719	connect_error = ntohl(connect_error);
1720	ctl_unit = ntohl(ctl_unit);
1721
1722	lck_rw_lock_shared(&g_flow_divert_group_lck);
1723
1724	if (connect_error == `0` && ctl_unit > `0`) {
1725	if (ctl_unit >= GROUP_COUNT_MAX) {
1726	FDLOG(LOG_ERR, fd_cb, "Connect result contains an invalid control unit: %u", ctl_unit);
1727	error = EINVAL;
1728	} else if (g_flow_divert_groups == NULL \|\| g_active_group_count == `0`) {
1729	FDLOG0(LOG_ERR, fd_cb, "No active groups, dropping connection");
1730	error = EINVAL;
1731	} else {
1732	grp = g_flow_divert_groups[ctl_unit];
1733	if (grp == NULL) {
1734	error = ECONNRESET;
1735	}
1736	}
1737	}
1738
1739	FDLOCK(fd_cb);
1740	if (fd_cb->so != NULL) {
1741	struct inpcb *inp = NULL;
1742	struct ifnet *ifp = NULL;
1743	struct flow_divert_group *old_group;
1744
1745	socket_lock(fd_cb->so, `0`);
1746
1747	if (!(fd_cb->so->so_state & SS_ISCONNECTING)) {
1748	goto done;
1749	}
1750
1751	inp = sotoinpcb(fd_cb->so);
1752
1753	if (connect_error \|\| error) {
1754	goto set_socket_state;
1755	}
1756
1757	if (local_address.ss_family == `0` && fd_cb->local_address == NULL) {
1758	error = EINVAL;
1759	goto set_socket_state;
1760	}
1761	if (local_address.ss_family != `0` && fd_cb->local_address == NULL) {
1762	if (local_address.ss_len > sizeof(local_address)) {
1763	local_address.ss_len = sizeof(local_address);
1764	}
1765	fd_cb->local_address = dup_sockaddr((struct sockaddr *)&local_address, `1`);
1766	}
1767
1768	if (remote_address.ss_family != `0`) {
1769	if (remote_address.ss_len > sizeof(remote_address)) {
1770	remote_address.ss_len = sizeof(remote_address);
1771	}
1772	fd_cb->remote_address = dup_sockaddr((struct sockaddr *)&remote_address, `1`);
1773	} else {
1774	error = EINVAL;
1775	goto set_socket_state;
1776	}
1777
1778	if (app_data_length > `0`) {
1779	uint8_t *app_data = NULL;
1780	MALLOC(app_data, uint8_t *, app_data_length, M_TEMP, M_WAITOK);
1781	if (app_data != NULL) {
1782	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_APP_DATA, app_data_length, app_data, NULL);
1783	if (error == `0`) {
1784	FDLOG(LOG_INFO, fd_cb, "Got %u bytes of app data from the connect result", app_data_length);
1785	if (fd_cb->app_data != NULL) {
1786	FREE(fd_cb->app_data, M_TEMP);
1787	}
1788	fd_cb->app_data = app_data;
1789	fd_cb->app_data_length = app_data_length;
1790	} else {
1791	FDLOG(LOG_ERR, fd_cb, "Failed to copy %u bytes of application data from the connect result packet", app_data_length);
1792	FREE(app_data, M_TEMP);
1793	}
1794	} else {
1795	FDLOG(LOG_ERR, fd_cb, "Failed to allocate a buffer of size %u to hold the application data from the connect result", app_data_length);
1796	}
1797	}
1798
1799	ifnet_head_lock_shared();
1800	if (out_if_index > `0` && out_if_index <= if_index) {
1801	ifp = ifindex2ifnet[out_if_index];
1802	}
1803
1804	if (ifp != NULL) {
1805	inp->inp_last_outifp = ifp;
1806	} else {
1807	error = EINVAL;
1808	}
1809	ifnet_head_done();
1810
1811	if (error) {
1812	goto set_socket_state;
1813	}
1814
1815	if (fd_cb->group == NULL) {
1816	error = EINVAL;
1817	goto set_socket_state;
1818	}
1819
1820	if (grp != NULL) {
1821	old_group = fd_cb->group;
1822
1823	lck_rw_lock_exclusive(&old_group->lck);
1824	lck_rw_lock_exclusive(&grp->lck);
1825
1826	RB_REMOVE(fd_pcb_tree, &old_group->pcb_tree, fd_cb);
1827	if (RB_INSERT(fd_pcb_tree, &grp->pcb_tree, fd_cb) != NULL) {
1828	panic("group with unit %u already contains a connection with hash %u", grp->ctl_unit, fd_cb->hash);
1829	}
1830
1831	fd_cb->group = grp;
1832
1833	lck_rw_done(&grp->lck);
1834	lck_rw_done(&old_group->lck);
1835	}
1836
1837	fd_cb->send_window = ntohl(send_window);
1838
1839	set_socket_state:
1840	if (!connect_error && !error) {
1841	FDLOG0(LOG_INFO, fd_cb, "sending connect result");
1842	error = flow_divert_send_connect_result(fd_cb);
1843	}
1844
1845	if (connect_error \|\| error) {
1846	if (!connect_error) {
1847	flow_divert_update_closed_state(fd_cb, SHUT_RDWR, FALSE);
1848	fd_cb->so->so_error = error;
1849	flow_divert_send_close_if_needed(fd_cb);
1850	} else {
1851	flow_divert_update_closed_state(fd_cb, SHUT_RDWR, TRUE);
1852	fd_cb->so->so_error = connect_error;
1853	}
1854	flow_divert_disconnect_socket(fd_cb->so);
1855	} else {
1856	flow_divert_send_buffered_data(fd_cb, FALSE);
1857	soisconnected(fd_cb->so);
1858	}
1859
1860	done:
1861	socket_unlock(fd_cb->so, `0`);
1862	}
1863	FDUNLOCK(fd_cb);
1864
1865	lck_rw_done(&g_flow_divert_group_lck);
1866	}
1867
1868	static void
1869	flow_divert_handle_close(struct flow_divert_pcb fd_cb, mbuf_t packet, int* offset)
1870	{
1871	uint32_t close_error;
1872	int error = `0`;
1873	int how;
1874
1875	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_ERROR_CODE, sizeof(close_error), &close_error, NULL);
1876	if (error) {
1877	FDLOG(LOG_ERR, fd_cb, "failed to get the close error: %d", error);
1878	return;
1879	}
1880
1881	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_HOW, sizeof(how), &how, NULL);
1882	if (error) {
1883	FDLOG(LOG_ERR, fd_cb, "failed to get the close how flag: %d", error);
1884	return;
1885	}
1886
1887	how = ntohl(how);
1888
1889	FDLOG(LOG_INFO, fd_cb, "close received, how = %d", how);
1890
1891	FDLOCK(fd_cb);
1892	if (fd_cb->so != NULL) {
1893	socket_lock(fd_cb->so, `0`);
1894
1895	fd_cb->so->so_error = ntohl(close_error);
1896
1897	flow_divert_update_closed_state(fd_cb, how, TRUE);
1898
1899	how = flow_divert_tunnel_how_closed(fd_cb);
1900	if (how == SHUT_RDWR) {
1901	flow_divert_disconnect_socket(fd_cb->so);
1902	} else if (how == SHUT_RD) {
1903	socantrcvmore(fd_cb->so);
1904	} else if (how == SHUT_WR) {
1905	socantsendmore(fd_cb->so);
1906	}
1907
1908	socket_unlock(fd_cb->so, `0`);
1909	}
1910	FDUNLOCK(fd_cb);
1911	}
1912
1913	static mbuf_t
1914	flow_divert_get_control_mbuf(struct flow_divert_pcb *fd_cb)
1915	{
1916	struct inpcb *inp = sotoinpcb(fd_cb->so);
1917	if (inp->inp_vflag & INP_IPV4 && inp->inp_flags & INP_RECVDSTADDR) {
1918	struct sockaddr_in sin = (struct* sockaddr_in )(void* *)fd_cb->local_address;
1919
1920	return sbcreatecontrol((caddr_t) &sin->sin_addr, sizeof(struct in_addr), IP_RECVDSTADDR, IPPROTO_IP);
1921	} else if (inp->inp_vflag & INP_IPV6 && (inp->inp_flags & IN6P_PKTINFO) != `0`) {
1922	struct sockaddr_in6 sin6 = (struct* sockaddr_in6 )(void* *)fd_cb->local_address;
1923	struct in6_pktinfo pi6;
1924
1925	bcopy(&sin6->sin6_addr, &pi6.ipi6_addr, sizeof (struct in6_addr));
1926	pi6.ipi6_ifindex = `0`;
1927	return sbcreatecontrol((caddr_t)&pi6, sizeof (struct in6_pktinfo), IPV6_PKTINFO, IPPROTO_IPV6);
1928	}
1929	return (NULL);
1930	}
1931
1932	static void
1933	flow_divert_handle_data(struct flow_divert_pcb *fd_cb, mbuf_t packet, size_t offset)
1934	{
1935	FDLOCK(fd_cb);
1936	if (fd_cb->so != NULL) {
1937	int error = `0`;
1938	mbuf_t data = NULL;
1939	size_t data_size;
1940	struct sockaddr_storage remote_address;
1941	boolean_t got_remote_sa = FALSE;
1942
1943	socket_lock(fd_cb->so, `0`);
1944
1945	if (SOCK_TYPE(fd_cb->so) == SOCK_DGRAM) {
1946	uint32_t val_size = `0`;
1947
1948	/ check if we got remote address with data /
1949	memset(&remote_address, `0`, sizeof(remote_address));
1950	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_REMOTE_ADDR, sizeof(remote_address), &remote_address, &val_size);
1951	if (error \|\| val_size > sizeof(remote_address)) {
1952	FDLOG0(LOG_INFO, fd_cb, "No remote address provided");
1953	error = `0`;
1954	} else {
1955	/ validate the address /
1956	if (flow_divert_is_sockaddr_valid((struct sockaddr *)&remote_address)) {
1957	got_remote_sa = TRUE;
1958	}
1959	offset += (sizeof(uint8_t) + sizeof(uint32_t) + val_size);
1960	}
1961	}
1962
1963	data_size = (mbuf_pkthdr_len(packet) - offset);
1964
1965	FDLOG(LOG_DEBUG, fd_cb, "received %lu bytes of data", data_size);
1966
1967	error = mbuf_split(packet, offset, MBUF_DONTWAIT, &data);
1968	if (error \|\| data == NULL) {
1969	FDLOG(LOG_ERR, fd_cb, "mbuf_split failed: %d", error);
1970	} else {
1971	if (flow_divert_check_no_cellular(fd_cb) \|\|
1972	flow_divert_check_no_expensive(fd_cb))
1973	{
1974	flow_divert_update_closed_state(fd_cb, SHUT_RDWR, TRUE);
1975	flow_divert_send_close(fd_cb, SHUT_RDWR);
1976	flow_divert_disconnect_socket(fd_cb->so);
1977	} else if (!(fd_cb->so->so_state & SS_CANTRCVMORE)) {
1978	if (SOCK_TYPE(fd_cb->so) == SOCK_STREAM) {
1979	if (sbappendstream(&fd_cb->so->so_rcv, data)) {
1980	fd_cb->bytes_received += data_size;
1981	flow_divert_add_data_statistics(fd_cb, data_size, FALSE);
1982	fd_cb->sb_size = fd_cb->so->so_rcv.sb_cc;
1983	sorwakeup(fd_cb->so);
1984	data = NULL;
1985	} else {
1986	FDLOG0(LOG_ERR, fd_cb, "received data, but appendstream failed");
1987	}
1988	} else if (SOCK_TYPE(fd_cb->so) == SOCK_DGRAM) {
1989	struct sockaddr *append_sa;
1990	mbuf_t mctl;
1991
1992	if (got_remote_sa == TRUE) {
1993	error = flow_divert_dup_addr(fd_cb->so->so_proto->pr_domain->dom_family,
1994	(struct sockaddr *)&remote_address, &append_sa);
1995	} else {
1996	error = flow_divert_dup_addr(fd_cb->so->so_proto->pr_domain->dom_family,
1997	fd_cb->remote_address, &append_sa);
1998	}
1999	if (error) {
2000	FDLOG0(LOG_ERR, fd_cb, "failed to dup the socket address.");
2001	}
2002
2003	mctl = flow_divert_get_control_mbuf(fd_cb);
2004	if (sbappendaddr(&fd_cb->so->so_rcv, append_sa, data, mctl, NULL)) {
2005	fd_cb->bytes_received += data_size;
2006	flow_divert_add_data_statistics(fd_cb, data_size, FALSE);
2007	fd_cb->sb_size = fd_cb->so->so_rcv.sb_cc;
2008	sorwakeup(fd_cb->so);
2009	data = NULL;
2010	} else {
2011	FDLOG0(LOG_ERR, fd_cb, "received data, but sbappendaddr failed");
2012	}
2013	if (!error) {
2014	FREE(append_sa, M_TEMP);
2015	}
2016	}
2017	}
2018	}
2019	socket_unlock(fd_cb->so, `0`);
2020
2021	if (data != NULL) {
2022	mbuf_freem(data);
2023	}
2024	}
2025	FDUNLOCK(fd_cb);
2026	}
2027
2028	static void
2029	flow_divert_handle_read_notification(struct flow_divert_pcb fd_cb, mbuf_t packet, int* offset)
2030	{
2031	uint32_t read_count;
2032	int error = `0`;
2033
2034	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_READ_COUNT, sizeof(read_count), &read_count, NULL);
2035	if (error) {
2036	FDLOG(LOG_ERR, fd_cb, "failed to get the read count: %d", error);
2037	return;
2038	}
2039
2040	FDLOG(LOG_DEBUG, fd_cb, "received a read notification for %u bytes", ntohl(read_count));
2041
2042	FDLOCK(fd_cb);
2043	if (fd_cb->so != NULL) {
2044	socket_lock(fd_cb->so, `0`);
2045	fd_cb->send_window += ntohl(read_count);
2046	flow_divert_send_buffered_data(fd_cb, FALSE);
2047	socket_unlock(fd_cb->so, `0`);
2048	}
2049	FDUNLOCK(fd_cb);
2050	}
2051
2052	static void
2053	flow_divert_handle_group_init(struct flow_divert_group group, mbuf_t packet, int* offset)
2054	{
2055	int error = `0`;
2056	uint32_t key_size = `0`;
2057	int log_level;
2058	uint32_t flags = `0`;
2059
2060	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_TOKEN_KEY, `0`, NULL, &key_size);
2061	if (error) {
2062	FDLOG(LOG_ERR, &nil_pcb, "failed to get the key size: %d", error);
2063	return;
2064	}
2065
2066	if (key_size == `0` \|\| key_size > FLOW_DIVERT_MAX_KEY_SIZE) {
2067	FDLOG(LOG_ERR, &nil_pcb, "Invalid key size: %u", key_size);
2068	return;
2069	}
2070
2071	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_LOG_LEVEL, sizeof(log_level), &log_level, NULL);
2072	if (!error) {
2073	nil_pcb.log_level = log_level;
2074	}
2075
2076	lck_rw_lock_exclusive(&group->lck);
2077
2078	MALLOC(group->token_key, uint8_t *, key_size, M_TEMP, M_WAITOK);
2079	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_TOKEN_KEY, key_size, group->token_key, NULL);
2080	if (error) {
2081	FDLOG(LOG_ERR, &nil_pcb, "failed to get the token key: %d", error);
2082	FREE(group->token_key, M_TEMP);
2083	group->token_key = NULL;
2084	lck_rw_done(&group->lck);
2085	return;
2086	}
2087
2088	group->token_key_size = key_size;
2089
2090	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_FLAGS, sizeof(flags), &flags, NULL);
2091	if (!error) {
2092	group->flags = flags;
2093	}
2094
2095	lck_rw_done(&group->lck);
2096	}
2097
2098	static void
2099	flow_divert_handle_properties_update(struct flow_divert_pcb fd_cb, mbuf_t packet, int* offset)
2100	{
2101	int error = `0`;
2102	struct sockaddr_storage local_address;
2103	int out_if_index = `0`;
2104	struct sockaddr_storage remote_address;
2105	uint32_t app_data_length = `0`;
2106
2107	FDLOG0(LOG_INFO, fd_cb, "received a properties update");
2108
2109	memset(&local_address, `0`, sizeof(local_address));
2110	memset(&remote_address, `0`, sizeof(remote_address));
2111
2112	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_LOCAL_ADDR, sizeof(local_address), &local_address, NULL);
2113	if (error) {
2114	FDLOG0(LOG_INFO, fd_cb, "No local address provided in properties update");
2115	}
2116
2117	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_REMOTE_ADDR, sizeof(remote_address), &remote_address, NULL);
2118	if (error) {
2119	FDLOG0(LOG_INFO, fd_cb, "No remote address provided in properties update");
2120	}
2121
2122	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_OUT_IF_INDEX, sizeof(out_if_index), &out_if_index, NULL);
2123	if (error) {
2124	FDLOG0(LOG_INFO, fd_cb, "No output if index provided in properties update");
2125	}
2126
2127	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_APP_DATA, `0`, NULL, &app_data_length);
2128	if (error) {
2129	FDLOG0(LOG_INFO, fd_cb, "No application data provided in properties update");
2130	}
2131
2132	FDLOCK(fd_cb);
2133	if (fd_cb->so != NULL) {
2134	socket_lock(fd_cb->so, `0`);
2135
2136	if (local_address.ss_family != `0`) {
2137	if (local_address.ss_len > sizeof(local_address)) {
2138	local_address.ss_len = sizeof(local_address);
2139	}
2140	if (fd_cb->local_address != NULL) {
2141	FREE(fd_cb->local_address, M_SONAME);
2142	fd_cb->local_address = NULL;
2143	}
2144	fd_cb->local_address = dup_sockaddr((struct sockaddr *)&local_address, `1`);
2145	}
2146
2147	if (remote_address.ss_family != `0`) {
2148	if (remote_address.ss_len > sizeof(remote_address)) {
2149	remote_address.ss_len = sizeof(remote_address);
2150	}
2151	if (fd_cb->remote_address != NULL) {
2152	FREE(fd_cb->remote_address, M_SONAME);
2153	fd_cb->remote_address = NULL;
2154	}
2155	fd_cb->remote_address = dup_sockaddr((struct sockaddr *)&remote_address, `1`);
2156	}
2157
2158	if (out_if_index > `0`) {
2159	struct inpcb *inp = NULL;
2160	struct ifnet *ifp = NULL;
2161
2162	inp = sotoinpcb(fd_cb->so);
2163
2164	ifnet_head_lock_shared();
2165	if (out_if_index <= if_index) {
2166	ifp = ifindex2ifnet[out_if_index];
2167	}
2168
2169	if (ifp != NULL) {
2170	inp->inp_last_outifp = ifp;
2171	}
2172	ifnet_head_done();
2173	}
2174
2175	if (app_data_length > `0`) {
2176	uint8_t *app_data = NULL;
2177	MALLOC(app_data, uint8_t *, app_data_length, M_TEMP, M_WAITOK);
2178	if (app_data != NULL) {
2179	error = flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_APP_DATA, app_data_length, app_data, NULL);
2180	if (error == `0`) {
2181	if (fd_cb->app_data != NULL) {
2182	FREE(fd_cb->app_data, M_TEMP);
2183	}
2184	fd_cb->app_data = app_data;
2185	fd_cb->app_data_length = app_data_length;
2186	} else {
2187	FDLOG(LOG_ERR, fd_cb, "Failed to copy %u bytes of application data from the properties update packet", app_data_length);
2188	FREE(app_data, M_TEMP);
2189	}
2190	} else {
2191	FDLOG(LOG_ERR, fd_cb, "Failed to allocate a buffer of size %u to hold the application data from the properties update", app_data_length);
2192	}
2193	}
2194
2195	socket_unlock(fd_cb->so, `0`);
2196	}
2197	FDUNLOCK(fd_cb);
2198	}
2199
2200	static void
2201	flow_divert_handle_app_map_create(struct flow_divert_group group, mbuf_t packet, int* offset)
2202	{
2203	size_t bytes_mem_size;
2204	size_t child_maps_mem_size;
2205	int cursor;
2206	int error = `0`;
2207	struct flow_divert_trie new_trie;
2208	int insert_error = `0`;
2209	size_t nodes_mem_size;
2210	int prefix_count = `0`;
2211	int signing_id_count = `0`;
2212	size_t trie_memory_size = `0`;
2213
2214	lck_rw_lock_exclusive(&group->lck);
2215
2216	/ Re-set the current trie /
2217	if (group->signing_id_trie.memory != NULL) {
2218	FREE(group->signing_id_trie.memory, M_TEMP);
2219	}
2220	memset(&group->signing_id_trie, `0`, sizeof(group->signing_id_trie));
2221	group->signing_id_trie.root = NULL_TRIE_IDX;
2222
2223	memset(&new_trie, `0`, sizeof(new_trie));
2224
2225	/ Get the number of shared prefixes in the new set of signing ID strings /
2226	flow_divert_packet_get_tlv(packet, offset, FLOW_DIVERT_TLV_PREFIX_COUNT, sizeof(prefix_count), &prefix_count, NULL);
2227
2228	if (prefix_count < `0`) {
2229	lck_rw_done(&group->lck);
2230	return;
2231	}
2232
2233	/ Compute the number of signing IDs and the total amount of bytes needed to store them /
2234	for (cursor = flow_divert_packet_find_tlv(packet, offset, FLOW_DIVERT_TLV_SIGNING_ID, &error, `0`);
2235	cursor >= `0`;
2236	cursor = flow_divert_packet_find_tlv(packet, cursor, FLOW_DIVERT_TLV_SIGNING_ID, &error, `1`))
2237	{
2238	uint32_t sid_size = `0`;
2239	flow_divert_packet_get_tlv(packet, cursor, FLOW_DIVERT_TLV_SIGNING_ID, `0`, NULL, &sid_size);
2240	new_trie.bytes_count += sid_size;
2241	signing_id_count++;
2242	}
2243
2244	if (signing_id_count == `0`) {
2245	lck_rw_done(&group->lck);
2246	return;
2247	}
2248
2249	new_trie.nodes_count = (prefix_count + signing_id_count + `1`); / + 1 for the root node /
2250	new_trie.child_maps_count = (prefix_count + `1`); / + 1 for the root node /
2251
2252	FDLOG(LOG_INFO, &nil_pcb, "Nodes count = %lu, child maps count = %lu, bytes_count = %lu",
2253	new_trie.nodes_count, new_trie.child_maps_count, new_trie.bytes_count);
2254
2255	nodes_mem_size = (sizeof(new_trie.nodes) new_trie.nodes_count);
2256	child_maps_mem_size = (sizeof(new_trie.child_maps) CHILD_MAP_SIZE * new_trie.child_maps_count);
2257	bytes_mem_size = (sizeof(new_trie.bytes) new_trie.bytes_count);
2258
2259	trie_memory_size = nodes_mem_size + child_maps_mem_size + bytes_mem_size;
2260	if (trie_memory_size > FLOW_DIVERT_MAX_TRIE_MEMORY) {
2261	FDLOG(LOG_ERR, &nil_pcb, "Trie memory size (%lu) is too big (maximum is %u)", trie_memory_size, FLOW_DIVERT_MAX_TRIE_MEMORY);
2262	lck_rw_done(&group->lck);
2263	return;
2264	}
2265
2266	MALLOC(new_trie.memory, void *, trie_memory_size, M_TEMP, M_WAITOK);
2267	if (new_trie.memory == NULL) {
2268	FDLOG(LOG_ERR, &nil_pcb, "Failed to allocate %lu bytes of memory for the signing ID trie",
2269	nodes_mem_size + child_maps_mem_size + bytes_mem_size);
2270	lck_rw_done(&group->lck);
2271	return;
2272	}
2273
2274	/ Initialize the free lists /
2275	new_trie.nodes = (struct flow_divert_trie_node *)new_trie.memory;
2276	new_trie.nodes_free_next = `0`;
2277	memset(new_trie.nodes, `0`, nodes_mem_size);
2278
2279	new_trie.child_maps = (uint16_t )(void* )((uint8_t )new_trie.memory + nodes_mem_size);
2280	new_trie.child_maps_free_next = `0`;
2281	memset(new_trie.child_maps, `0xff`, child_maps_mem_size);
2282
2283	new_trie.bytes = (uint8_t )(void* )((uint8_t )new_trie.memory + nodes_mem_size + child_maps_mem_size);
2284	new_trie.bytes_free_next = `0`;
2285
2286	/ The root is an empty node /
2287	new_trie.root = trie_node_alloc(&new_trie);
2288
2289	/ Add each signing ID to the trie /
2290	for (cursor = flow_divert_packet_find_tlv(packet, offset, FLOW_DIVERT_TLV_SIGNING_ID, &error, `0`);
2291	cursor >= `0`;
2292	cursor = flow_divert_packet_find_tlv(packet, cursor, FLOW_DIVERT_TLV_SIGNING_ID, &error, `1`))
2293	{
2294	uint32_t sid_size = `0`;
2295	flow_divert_packet_get_tlv(packet, cursor, FLOW_DIVERT_TLV_SIGNING_ID, `0`, NULL, &sid_size);
2296	if (new_trie.bytes_free_next + sid_size <= new_trie.bytes_count) {
2297	uint16_t new_node_idx;
2298	flow_divert_packet_get_tlv(packet, cursor, FLOW_DIVERT_TLV_SIGNING_ID, sid_size, &TRIE_BYTE(&new_trie, new_trie.bytes_free_next), NULL);
2299	new_node_idx = flow_divert_trie_insert(&new_trie, new_trie.bytes_free_next, sid_size);
2300	if (new_node_idx == NULL_TRIE_IDX) {
2301	insert_error = EINVAL;
2302	break;
2303	}
2304	} else {
2305	FDLOG0(LOG_ERR, &nil_pcb, "No place to put signing ID for insertion");
2306	insert_error = ENOBUFS;
2307	break;
2308	}
2309	}
2310
2311	if (!insert_error) {
2312	group->signing_id_trie = new_trie;
2313	} else {
2314	FREE(new_trie.memory, M_TEMP);
2315	}
2316
2317	lck_rw_done(&group->lck);
2318	}
2319
2320	static int
2321	flow_divert_input(mbuf_t packet, struct flow_divert_group *group)
2322	{
2323	struct flow_divert_packet_header hdr;
2324	int error = `0`;
2325	struct flow_divert_pcb *fd_cb;
2326
2327	if (mbuf_pkthdr_len(packet) < sizeof(hdr)) {
2328	FDLOG(LOG_ERR, &nil_pcb, "got a bad packet, length (%lu) < sizeof hdr (%lu)", mbuf_pkthdr_len(packet), sizeof(hdr));
2329	error = EINVAL;
2330	goto done;
2331	}
2332
2333	if (mbuf_pkthdr_len(packet) > FD_CTL_RCVBUFF_SIZE) {
2334	FDLOG(LOG_ERR, &nil_pcb, "got a bad packet, length (%lu) > %d", mbuf_pkthdr_len(packet), FD_CTL_RCVBUFF_SIZE);
2335	error = EINVAL;
2336	goto done;
2337	}
2338
2339	error = mbuf_copydata(packet, `0`, sizeof(hdr), &hdr);
2340	if (error) {
2341	FDLOG(LOG_ERR, &nil_pcb, "mbuf_copydata failed for the header: %d", error);
2342	error = ENOBUFS;
2343	goto done;
2344	}
2345
2346	hdr.conn_id = ntohl(hdr.conn_id);
2347
2348	if (hdr.conn_id == `0`) {
2349	switch (hdr.packet_type) {
2350	case FLOW_DIVERT_PKT_GROUP_INIT:
2351	flow_divert_handle_group_init(group, packet, sizeof(hdr));
2352	break;
2353	case FLOW_DIVERT_PKT_APP_MAP_CREATE:
2354	flow_divert_handle_app_map_create(group, packet, sizeof(hdr));
2355	break;
2356	default:
2357	FDLOG(LOG_WARNING, &nil_pcb, "got an unknown message type: %d", hdr.packet_type);
2358	break;
2359	}
2360	goto done;
2361	}
2362
2363	fd_cb = flow_divert_pcb_lookup(hdr.conn_id, group); / This retains the PCB /
2364	if (fd_cb == NULL) {
2365	if (hdr.packet_type != FLOW_DIVERT_PKT_CLOSE && hdr.packet_type != FLOW_DIVERT_PKT_READ_NOTIFY) {
2366	FDLOG(LOG_NOTICE, &nil_pcb, "got a %s message from group %d for an unknown pcb: %u", flow_divert_packet_type2str(hdr.packet_type), group->ctl_unit, hdr.conn_id);
2367	}
2368	goto done;
2369	}
2370
2371	switch (hdr.packet_type) {
2372	case FLOW_DIVERT_PKT_CONNECT_RESULT:
2373	flow_divert_handle_connect_result(fd_cb, packet, sizeof(hdr));
2374	break;
2375	case FLOW_DIVERT_PKT_CLOSE:
2376	flow_divert_handle_close(fd_cb, packet, sizeof(hdr));
2377	break;
2378	case FLOW_DIVERT_PKT_DATA:
2379	flow_divert_handle_data(fd_cb, packet, sizeof(hdr));
2380	break;
2381	case FLOW_DIVERT_PKT_READ_NOTIFY:
2382	flow_divert_handle_read_notification(fd_cb, packet, sizeof(hdr));
2383	break;
2384	case FLOW_DIVERT_PKT_PROPERTIES_UPDATE:
2385	flow_divert_handle_properties_update(fd_cb, packet, sizeof(hdr));
2386	break;
2387	default:
2388	FDLOG(LOG_WARNING, fd_cb, "got an unknown message type: %d", hdr.packet_type);
2389	break;
2390	}
2391
2392	FDRELEASE(fd_cb);
2393
2394	done:
2395	mbuf_freem(packet);
2396	return error;
2397	}
2398
2399	static void
2400	flow_divert_close_all(struct flow_divert_group *group)
2401	{
2402	struct flow_divert_pcb *fd_cb;
2403	SLIST_HEAD(, flow_divert_pcb) tmp_list;
2404
2405	SLIST_INIT(&tmp_list);
2406
2407	lck_rw_lock_exclusive(&group->lck);
2408
2409	MBUFQ_DRAIN(&group->send_queue);
2410
2411	RB_FOREACH(fd_cb, fd_pcb_tree, &group->pcb_tree) {
2412	FDRETAIN(fd_cb);
2413	SLIST_INSERT_HEAD(&tmp_list, fd_cb, tmp_list_entry);
2414	}
2415
2416	lck_rw_done(&group->lck);
2417
2418	while (!SLIST_EMPTY(&tmp_list)) {
2419	fd_cb = SLIST_FIRST(&tmp_list);
2420	FDLOCK(fd_cb);
2421	SLIST_REMOVE_HEAD(&tmp_list, tmp_list_entry);
2422	if (fd_cb->so != NULL) {
2423	socket_lock(fd_cb->so, `0`);
2424	flow_divert_pcb_remove(fd_cb);
2425	flow_divert_update_closed_state(fd_cb, SHUT_RDWR, TRUE);
2426	fd_cb->so->so_error = ECONNABORTED;
2427	flow_divert_disconnect_socket(fd_cb->so);
2428	socket_unlock(fd_cb->so, `0`);
2429	}
2430	FDUNLOCK(fd_cb);
2431	FDRELEASE(fd_cb);
2432	}
2433	}
2434
2435	void
2436	flow_divert_detach(struct socket *so)
2437	{
2438	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2439
2440	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
2441
2442	so->so_flags &= ~SOF_FLOW_DIVERT;
2443	so->so_fd_pcb = NULL;
2444
2445	FDLOG(LOG_INFO, fd_cb, "Detaching, ref count = %d", fd_cb->ref_count);
2446
2447	if (fd_cb->group != NULL) {
2448	/ Last-ditch effort to send any buffered data /
2449	flow_divert_send_buffered_data(fd_cb, TRUE);
2450
2451	flow_divert_update_closed_state(fd_cb, SHUT_RDWR, FALSE);
2452	flow_divert_send_close_if_needed(fd_cb);
2453	/ Remove from the group /
2454	flow_divert_pcb_remove(fd_cb);
2455	}
2456
2457	socket_unlock(so, `0`);
2458	FDLOCK(fd_cb);
2459	fd_cb->so = NULL;
2460	FDUNLOCK(fd_cb);
2461	socket_lock(so, `0`);
2462
2463	FDRELEASE(fd_cb); / Release the socket's reference /
2464	}
2465
2466	static int
2467	flow_divert_close(struct socket *so)
2468	{
2469	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2470
2471	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
2472
2473	FDLOG0(LOG_INFO, fd_cb, "Closing");
2474
2475	if (SOCK_TYPE(so) == SOCK_STREAM) {
2476	soisdisconnecting(so);
2477	sbflush(&so->so_rcv);
2478	}
2479
2480	flow_divert_send_buffered_data(fd_cb, TRUE);
2481	flow_divert_update_closed_state(fd_cb, SHUT_RDWR, FALSE);
2482	flow_divert_send_close_if_needed(fd_cb);
2483
2484	/ Remove from the group /
2485	flow_divert_pcb_remove(fd_cb);
2486
2487	return `0`;
2488	}
2489
2490	static int
2491	flow_divert_disconnectx(struct socket *so, sae_associd_t aid,
2492	sae_connid_t cid __unused)
2493	{
2494	if (aid != SAE_ASSOCID_ANY && aid != SAE_ASSOCID_ALL) {
2495	return (EINVAL);
2496	}
2497
2498	return (flow_divert_close(so));
2499	}
2500
2501	static int
2502	flow_divert_shutdown(struct socket *so)
2503	{
2504	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2505
2506	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
2507
2508	FDLOG0(LOG_INFO, fd_cb, "Can't send more");
2509
2510	socantsendmore(so);
2511
2512	flow_divert_update_closed_state(fd_cb, SHUT_WR, FALSE);
2513	flow_divert_send_close_if_needed(fd_cb);
2514
2515	return `0`;
2516	}
2517
2518	static int
2519	flow_divert_rcvd(struct socket so, int* flags __unused)
2520	{
2521	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2522	uint32_t latest_sb_size;
2523	uint32_t read_count;
2524
2525	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
2526
2527	latest_sb_size = fd_cb->so->so_rcv.sb_cc;
2528
2529	if (fd_cb->sb_size < latest_sb_size) {
2530	panic("flow divert rcvd event handler (%u): saved rcv buffer size (%u) is less than latest rcv buffer size (%u)",
2531	fd_cb->hash, fd_cb->sb_size, latest_sb_size);
2532	}
2533
2534	read_count = fd_cb->sb_size - latest_sb_size;
2535
2536	FDLOG(LOG_DEBUG, fd_cb, "app read %u bytes", read_count);
2537
2538	if (read_count > `0` && flow_divert_send_read_notification(fd_cb, read_count) == `0`) {
2539	fd_cb->bytes_read_by_app += read_count;
2540	fd_cb->sb_size = latest_sb_size;
2541	}
2542
2543	return `0`;
2544	}
2545
2546	static int
2547	flow_divert_append_target_endpoint_tlv(mbuf_t connect_packet, struct sockaddr *toaddr)
2548	{
2549	int error = `0`;
2550	int port = `0`;
2551
2552	error = flow_divert_packet_append_tlv(connect_packet, FLOW_DIVERT_TLV_TARGET_ADDRESS, toaddr->sa_len, toaddr);
2553	if (error) {
2554	goto done;
2555	}
2556
2557	if (toaddr->sa_family == AF_INET) {
2558	port = ntohs((satosin(toaddr))->sin_port);
2559	}
2560	#if INET6
2561	else {
2562	port = ntohs((satosin6(toaddr))->sin6_port);
2563	}
2564	#endif
2565
2566	error = flow_divert_packet_append_tlv(connect_packet, FLOW_DIVERT_TLV_TARGET_PORT, sizeof(port), &port);
2567	if (error) {
2568	goto done;
2569	}
2570
2571	done:
2572	return error;
2573	}
2574
2575	struct sockaddr *
2576	flow_divert_get_buffered_target_address(mbuf_t buffer)
2577	{
2578	if (buffer != NULL && buffer->m_type == MT_SONAME) {
2579	struct sockaddr toaddr = mtod(buffer, struct* sockaddr *);
2580	if (toaddr != NULL && flow_divert_is_sockaddr_valid(toaddr)) {
2581	return toaddr;
2582	}
2583	}
2584	return NULL;
2585	}
2586
2587	static boolean_t
2588	flow_divert_is_sockaddr_valid(struct sockaddr *addr)
2589	{
2590	switch(addr->sa_family)
2591	{
2592	case AF_INET:
2593	if (addr->sa_len != sizeof(struct sockaddr_in)) {
2594	return FALSE;
2595	}
2596	break;
2597	#if INET6
2598	case AF_INET6:
2599	if (addr->sa_len != sizeof(struct sockaddr_in6)) {
2600	return FALSE;
2601	}
2602	break;
2603	#endif /* INET6 */
2604	default:
2605	return FALSE;
2606	}
2607	return TRUE;
2608	}
2609
2610	static errno_t
2611	flow_divert_inp_to_sockaddr(const struct inpcb inp, struct* sockaddr **local_socket)
2612	{
2613	int error = `0`;
2614	union sockaddr_in_4_6 sin46;
2615
2616	bzero(&sin46, sizeof(sin46));
2617	if (inp->inp_vflag & INP_IPV4) {
2618	struct sockaddr_in *sin = &sin46.sin;
2619
2620	sin->sin_family = AF_INET;
2621	sin->sin_len = sizeof(*sin);
2622	sin->sin_port = inp->inp_lport;
2623	sin->sin_addr = inp->inp_laddr;
2624	} else if (inp->inp_vflag & INP_IPV6) {
2625	struct sockaddr_in6 *sin6 = &sin46.sin6;
2626
2627	sin6->sin6_len = sizeof(*sin6);
2628	sin6->sin6_family = AF_INET6;
2629	sin6->sin6_port = inp->inp_lport;
2630	sin6->sin6_addr = inp->in6p_laddr;
2631	}
2632	local_socket = dup_sockaddr((struct* sockaddr *)&sin46, `1`);
2633	if (*local_socket == NULL) {
2634	error = ENOBUFS;
2635	}
2636	return (error);
2637	}
2638
2639	static boolean_t
2640	flow_divert_has_pcb_local_address(const struct inpcb *inp)
2641	{
2642	return (inp->inp_lport != `0`
2643	&& (inp->inp_laddr.s_addr != INADDR_ANY \|\| !IN6_IS_ADDR_UNSPECIFIED(&inp->in6p_laddr)));
2644	}
2645
2646	static errno_t
2647	flow_divert_dup_addr(sa_family_t family, struct sockaddr *addr,
2648	struct sockaddr **dup)
2649	{
2650	int error = `0`;
2651	struct sockaddr *result;
2652	struct sockaddr_storage ss;
2653
2654	if (addr != NULL) {
2655	result = addr;
2656	} else {
2657	memset(&ss, `0`, sizeof(ss));
2658	ss.ss_family = family;
2659	if (ss.ss_family == AF_INET) {
2660	ss.ss_len = sizeof(struct sockaddr_in);
2661	}
2662	#if INET6
2663	else if (ss.ss_family == AF_INET6) {
2664	ss.ss_len = sizeof(struct sockaddr_in6);
2665	}
2666	#endif /* INET6 */
2667	else {
2668	error = EINVAL;
2669	}
2670	result = (struct sockaddr *)&ss;
2671	}
2672
2673	if (!error) {
2674	*dup = dup_sockaddr(result, `1`);
2675	if (*dup == NULL) {
2676	error = ENOBUFS;
2677	}
2678	}
2679
2680	return error;
2681	}
2682
2683	static void
2684	flow_divert_disconnect_socket(struct socket *so)
2685	{
2686	soisdisconnected(so);
2687	if (SOCK_TYPE(so) == SOCK_DGRAM) {
2688	struct inpcb *inp = NULL;
2689
2690	inp = sotoinpcb(so);
2691	if (inp != NULL) {
2692	#if INET6
2693	if (SOCK_CHECK_DOM(so, PF_INET6))
2694	in6_pcbdetach(inp);
2695	else
2696	#endif /* INET6 */
2697	in_pcbdetach(inp);
2698	}
2699	}
2700	}
2701
2702	static errno_t
2703	flow_divert_getpeername(struct socket so, struct* sockaddr **sa)
2704	{
2705	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2706
2707	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
2708
2709	return flow_divert_dup_addr(so->so_proto->pr_domain->dom_family,
2710	fd_cb->remote_address,
2711	sa);
2712	}
2713
2714	static errno_t
2715	flow_divert_getsockaddr(struct socket so, struct* sockaddr **sa)
2716	{
2717	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2718
2719	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
2720
2721	return flow_divert_dup_addr(so->so_proto->pr_domain->dom_family,
2722	fd_cb->local_address,
2723	sa);
2724	}
2725
2726	static errno_t
2727	flow_divert_ctloutput(struct socket so, struct* sockopt *sopt)
2728	{
2729	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2730
2731	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
2732
2733	if (sopt->sopt_name == SO_TRAFFIC_CLASS) {
2734	if (sopt->sopt_dir == SOPT_SET && fd_cb->flags & FLOW_DIVERT_CONNECT_STARTED) {
2735	flow_divert_send_traffic_class_update(fd_cb, so->so_traffic_class);
2736	}
2737	}
2738
2739	if (SOCK_DOM(so) == PF_INET) {
2740	return g_tcp_protosw->pr_ctloutput(so, sopt);
2741	}
2742	#if INET6
2743	else if (SOCK_DOM(so) == PF_INET6) {
2744	return g_tcp6_protosw->pr_ctloutput(so, sopt);
2745	}
2746	#endif
2747	return `0`;
2748	}
2749
2750	errno_t
2751	flow_divert_connect_out(struct socket so, struct* sockaddr *to, proc_t p)
2752	{
2753	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2754	int error = `0`;
2755	struct inpcb *inp = sotoinpcb(so);
2756	struct sockaddr_in *sinp;
2757	mbuf_t connect_packet = NULL;
2758	int do_send = `1`;
2759
2760	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
2761
2762	if (fd_cb->group == NULL) {
2763	error = ENETUNREACH;
2764	goto done;
2765	}
2766
2767	if (inp == NULL) {
2768	error = EINVAL;
2769	goto done;
2770	} else if (inp->inp_state == INPCB_STATE_DEAD) {
2771	if (so->so_error) {
2772	error = so->so_error;
2773	so->so_error = `0`;
2774	} else {
2775	error = EINVAL;
2776	}
2777	goto done;
2778	}
2779
2780	if ((fd_cb->flags & FLOW_DIVERT_CONNECT_STARTED) && !(fd_cb->flags & FLOW_DIVERT_TRANSFERRED)) {
2781	error = EALREADY;
2782	goto done;
2783	}
2784
2785	if (fd_cb->flags & FLOW_DIVERT_TRANSFERRED) {
2786	FDLOG0(LOG_INFO, fd_cb, "fully transferred");
2787	fd_cb->flags &= ~FLOW_DIVERT_TRANSFERRED;
2788	if (fd_cb->remote_address != NULL) {
2789	soisconnected(fd_cb->so);
2790	goto done;
2791	}
2792	}
2793
2794	FDLOG0(LOG_INFO, fd_cb, "Connecting");
2795
2796	if (fd_cb->connect_packet == NULL) {
2797	if (to == NULL) {
2798	FDLOG0(LOG_ERR, fd_cb, "No destination address available when creating connect packet");
2799	error = EINVAL;
2800	goto done;
2801	}
2802
2803	sinp = (struct sockaddr_in )(void* *)to;
2804	if (sinp->sin_family == AF_INET && IN_MULTICAST(ntohl(sinp->sin_addr.s_addr))) {
2805	error = EAFNOSUPPORT;
2806	goto done;
2807	}
2808
2809	error = flow_divert_create_connect_packet(fd_cb, to, so, p, &connect_packet);
2810	if (error) {
2811	goto done;
2812	}
2813
2814	if (so->so_flags1 & SOF1_PRECONNECT_DATA) {
2815	FDLOG0(LOG_INFO, fd_cb, "Delaying sending the connect packet until send or receive");
2816	do_send = `0`;
2817	}
2818	} else {
2819	FDLOG0(LOG_INFO, fd_cb, "Sending saved connect packet");
2820	connect_packet = fd_cb->connect_packet;
2821	fd_cb->connect_packet = NULL;
2822	}
2823
2824	if (do_send) {
2825	error = flow_divert_send_packet(fd_cb, connect_packet, TRUE);
2826	if (error) {
2827	goto done;
2828	}
2829
2830	fd_cb->flags \|= FLOW_DIVERT_CONNECT_STARTED;
2831	} else {
2832	fd_cb->connect_packet = connect_packet;
2833	connect_packet = NULL;
2834	}
2835
2836	soisconnecting(so);
2837
2838	done:
2839	if (error && connect_packet != NULL) {
2840	mbuf_freem(connect_packet);
2841	}
2842	return error;
2843	}
2844
2845	static int
2846	flow_divert_connectx_out_common(struct socket so, struct* sockaddr *dst,
2847	struct proc p, sae_connid_t pcid, struct uio auio, user_ssize_t bytes_written)
2848	{
2849	struct inpcb *inp = sotoinpcb(so);
2850	int error;
2851
2852	if (inp == NULL) {
2853	return (EINVAL);
2854	}
2855
2856	VERIFY(dst != NULL);
2857
2858	error = flow_divert_connect_out(so, dst, p);
2859
2860	if (error != `0`) {
2861	return error;
2862	}
2863
2864	/ if there is data, send it /
2865	if (auio != NULL) {
2866	user_ssize_t datalen = `0`;
2867
2868	socket_unlock(so, `0`);
2869
2870	VERIFY(bytes_written != NULL);
2871
2872	datalen = uio_resid(auio);
2873	error = so->so_proto->pr_usrreqs->pru_sosend(so, NULL, (uio_t)auio, NULL, NULL, `0`);
2874	socket_lock(so, `0`);
2875
2876	if (error == `0` \|\| error == EWOULDBLOCK) {
2877	*bytes_written = datalen - uio_resid(auio);
2878	}
2879
2880	/*
2881	* sosend returns EWOULDBLOCK if it's a non-blocking
2882	* socket or a timeout occured (this allows to return
2883	* the amount of queued data through sendit()).
2884	*
2885	* However, connectx() returns EINPROGRESS in case of a
2886	* blocking socket. So we change the return value here.
2887	*/
2888	if (error == EWOULDBLOCK) {
2889	error = EINPROGRESS;
2890	}
2891	}
2892
2893	if (error == `0` && pcid != NULL) {
2894	pcid = `1`; /* there is only 1 connection for a TCP /
2895	}
2896
2897	return (error);
2898	}
2899
2900	static int
2901	flow_divert_connectx_out(struct socket so, struct* sockaddr *src __unused,
2902	struct sockaddr dst, struct* proc *p, uint32_t ifscope __unused,
2903	sae_associd_t aid __unused, sae_connid_t pcid, uint32_t flags __unused, void* *arg __unused,
2904	uint32_t arglen __unused, struct uio uio, user_ssize_t bytes_written)
2905	{
2906	return (flow_divert_connectx_out_common(so, dst, p, pcid, uio, bytes_written));
2907	}
2908
2909	#if INET6
2910	static int
2911	flow_divert_connectx6_out(struct socket so, struct* sockaddr *src __unused,
2912	struct sockaddr dst, struct* proc *p, uint32_t ifscope __unused,
2913	sae_associd_t aid __unused, sae_connid_t pcid, uint32_t flags __unused, void* *arg __unused,
2914	uint32_t arglen __unused, struct uio uio, user_ssize_t bytes_written)
2915	{
2916	return (flow_divert_connectx_out_common(so, dst, p, pcid, uio, bytes_written));
2917	}
2918	#endif /* INET6 */
2919
2920	static int
2921	flow_divert_getconninfo(struct socket so, sae_connid_t cid, uint32_t flags,
2922	uint32_t ifindex, int32_t soerror, user_addr_t src, socklen_t *src_len,
2923	user_addr_t dst, socklen_t dst_len, uint32_t aux_type,
2924	user_addr_t aux_data __unused, uint32_t *aux_len)
2925	{
2926	int error = `0`;
2927	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
2928	struct ifnet *ifp = NULL;
2929	struct inpcb *inp = sotoinpcb(so);
2930
2931	VERIFY((so->so_flags & SOF_FLOW_DIVERT));
2932
2933	if (so->so_fd_pcb == NULL \|\| inp == NULL) {
2934	error = EINVAL;
2935	goto out;
2936	}
2937
2938	if (cid != SAE_CONNID_ANY && cid != SAE_CONNID_ALL && cid != `1`) {
2939	error = EINVAL;
2940	goto out;
2941	}
2942
2943	ifp = inp->inp_last_outifp;
2944	*ifindex = ((ifp != NULL) ? ifp->if_index : `0`);
2945	*soerror = so->so_error;
2946	*flags = `0`;
2947
2948	if (so->so_state & SS_ISCONNECTED) {
2949	*flags \|= (CIF_CONNECTED \| CIF_PREFERRED);
2950	}
2951
2952	if (fd_cb->local_address == NULL) {
2953	struct sockaddr_in sin;
2954	bzero(&sin, sizeof(sin));
2955	sin.sin_len = sizeof(sin);
2956	sin.sin_family = AF_INET;
2957	*src_len = sin.sin_len;
2958	if (src != USER_ADDR_NULL) {
2959	error = copyout(&sin, src, sin.sin_len);
2960	if (error != `0`) {
2961	goto out;
2962	}
2963	}
2964	} else {
2965	*src_len = fd_cb->local_address->sa_len;
2966	if (src != USER_ADDR_NULL) {
2967	error = copyout(fd_cb->local_address, src, fd_cb->local_address->sa_len);
2968	if (error != `0`) {
2969	goto out;
2970	}
2971	}
2972	}
2973
2974	if (fd_cb->remote_address == NULL) {
2975	struct sockaddr_in sin;
2976	bzero(&sin, sizeof(sin));
2977	sin.sin_len = sizeof(sin);
2978	sin.sin_family = AF_INET;
2979	*dst_len = sin.sin_len;
2980	if (dst != USER_ADDR_NULL) {
2981	error = copyout(&sin, dst, sin.sin_len);
2982	if (error != `0`) {
2983	goto out;
2984	}
2985	}
2986	} else {
2987	*dst_len = fd_cb->remote_address->sa_len;
2988	if (dst != USER_ADDR_NULL) {
2989	error = copyout(fd_cb->remote_address, dst, fd_cb->remote_address->sa_len);
2990	if (error != `0`) {
2991	goto out;
2992	}
2993	}
2994	}
2995
2996	*aux_type = `0`;
2997	*aux_len = `0`;
2998
2999	out:
3000	return error;
3001	}
3002
3003	static int
3004	flow_divert_control(struct socket so, u_long cmd, caddr_t data, struct* ifnet ifp __unused, struct* proc *p __unused)
3005	{
3006	int error = `0`;
3007
3008	switch (cmd) {
3009	case SIOCGCONNINFO32: {
3010	struct so_cinforeq32 cifr;
3011	bcopy(data, &cifr, sizeof (cifr));
3012	error = flow_divert_getconninfo(so, cifr.scir_cid, &cifr.scir_flags,
3013	&cifr.scir_ifindex, &cifr.scir_error, cifr.scir_src,
3014	&cifr.scir_src_len, cifr.scir_dst, &cifr.scir_dst_len,
3015	&cifr.scir_aux_type, cifr.scir_aux_data,
3016	&cifr.scir_aux_len);
3017	if (error == `0`) {
3018	bcopy(&cifr, data, sizeof (cifr));
3019	}
3020	break;
3021	}
3022
3023	case SIOCGCONNINFO64: {
3024	struct so_cinforeq64 cifr;
3025	bcopy(data, &cifr, sizeof (cifr));
3026	error = flow_divert_getconninfo(so, cifr.scir_cid, &cifr.scir_flags,
3027	&cifr.scir_ifindex, &cifr.scir_error, cifr.scir_src,
3028	&cifr.scir_src_len, cifr.scir_dst, &cifr.scir_dst_len,
3029	&cifr.scir_aux_type, cifr.scir_aux_data,
3030	&cifr.scir_aux_len);
3031	if (error == `0`) {
3032	bcopy(&cifr, data, sizeof (cifr));
3033	}
3034	break;
3035	}
3036
3037	default:
3038	error = EOPNOTSUPP;
3039	}
3040
3041	return error;
3042	}
3043
3044	static int
3045	flow_divert_in_control(struct socket so, u_long cmd, caddr_t data, struct* ifnet ifp, struct* proc *p)
3046	{
3047	int error = flow_divert_control(so, cmd, data, ifp, p);
3048
3049	if (error == EOPNOTSUPP) {
3050	error = in_control(so, cmd, data, ifp, p);
3051	}
3052
3053	return error;
3054	}
3055
3056	static int
3057	flow_divert_in6_control(struct socket so, u_long cmd, caddr_t data, struct* ifnet ifp, struct* proc *p)
3058	{
3059	int error = flow_divert_control(so, cmd, data, ifp, p);
3060
3061	if (error == EOPNOTSUPP) {
3062	error = in6_control(so, cmd, data, ifp, p);
3063	}
3064
3065	return error;
3066	}
3067
3068	static errno_t
3069	flow_divert_data_out(struct socket so, int* flags, mbuf_t data, struct sockaddr to, mbuf_t control, struct* proc *p)
3070	{
3071	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
3072	int error = `0`;
3073	struct inpcb *inp;
3074
3075	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
3076
3077	inp = sotoinpcb(so);
3078	if (inp == NULL \|\| inp->inp_state == INPCB_STATE_DEAD) {
3079	error = ECONNRESET;
3080	goto done;
3081	}
3082
3083	if (control && mbuf_len(control) > `0`) {
3084	error = EINVAL;
3085	goto done;
3086	}
3087
3088	if (flags & MSG_OOB) {
3089	error = EINVAL;
3090	goto done; / We don't support OOB data /
3091	}
3092
3093	error = flow_divert_check_no_cellular(fd_cb) \|\|
3094	flow_divert_check_no_expensive(fd_cb);
3095	if (error) {
3096	goto done;
3097	}
3098
3099	/ Implicit connect /
3100	if (!(fd_cb->flags & FLOW_DIVERT_CONNECT_STARTED)) {
3101	FDLOG0(LOG_INFO, fd_cb, "implicit connect");
3102	error = flow_divert_connect_out(so, to, p);
3103	if (error) {
3104	goto done;
3105	}
3106
3107	if (so->so_flags1 & SOF1_DATA_IDEMPOTENT) {
3108	/ Open up the send window so that the data will get sent right away /
3109	fd_cb->send_window = mbuf_pkthdr_len(data);
3110	}
3111	}
3112
3113	FDLOG(LOG_DEBUG, fd_cb, "app wrote %lu bytes", mbuf_pkthdr_len(data));
3114
3115	fd_cb->bytes_written_by_app += mbuf_pkthdr_len(data);
3116	error = flow_divert_send_app_data(fd_cb, data, to);
3117	if (error) {
3118	goto done;
3119	}
3120
3121	data = NULL;
3122
3123	if (flags & PRUS_EOF) {
3124	flow_divert_shutdown(so);
3125	}
3126
3127	done:
3128	if (data) {
3129	mbuf_freem(data);
3130	}
3131	if (control) {
3132	mbuf_free(control);
3133	}
3134	return error;
3135	}
3136
3137	static int
3138	flow_divert_preconnect(struct socket *so)
3139	{
3140	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
3141	int error = `0`;
3142
3143	if (!(fd_cb->flags & FLOW_DIVERT_CONNECT_STARTED) && fd_cb->connect_packet != NULL) {
3144	FDLOG0(LOG_INFO, fd_cb, "Pre-connect read: sending saved connect packet");
3145	mbuf_t connect_packet = fd_cb->connect_packet;
3146	fd_cb->connect_packet = NULL;
3147
3148	error = flow_divert_send_packet(fd_cb, connect_packet, TRUE);
3149	if (error) {
3150	mbuf_freem(connect_packet);
3151	}
3152
3153	fd_cb->flags \|= FLOW_DIVERT_CONNECT_STARTED;
3154	}
3155
3156	soclearfastopen(so);
3157
3158	return error;
3159	}
3160
3161	static void
3162	flow_divert_set_protosw(struct socket *so)
3163	{
3164	so->so_flags \|= SOF_FLOW_DIVERT;
3165	if (SOCK_DOM(so) == PF_INET) {
3166	so->so_proto = &g_flow_divert_in_protosw;
3167	}
3168	#if INET6
3169	else {
3170	so->so_proto = (struct protosw *)&g_flow_divert_in6_protosw;
3171	}
3172	#endif /* INET6 */
3173	}
3174
3175	static void
3176	flow_divert_set_udp_protosw(struct socket *so)
3177	{
3178	so->so_flags \|= SOF_FLOW_DIVERT;
3179	if (SOCK_DOM(so) == PF_INET) {
3180	so->so_proto = &g_flow_divert_in_udp_protosw;
3181	}
3182	#if INET6
3183	else {
3184	so->so_proto = (struct protosw *)&g_flow_divert_in6_udp_protosw;
3185	}
3186	#endif /* INET6 */
3187	}
3188
3189	static errno_t
3190	flow_divert_attach(struct socket *so, uint32_t flow_id, uint32_t ctl_unit)
3191	{
3192	int error = `0`;
3193	struct flow_divert_pcb *fd_cb = NULL;
3194	struct ifnet *ifp = NULL;
3195	struct inpcb *inp = NULL;
3196	struct socket *old_so;
3197	mbuf_t recv_data = NULL;
3198
3199	socket_unlock(so, `0`);
3200
3201	FDLOG(LOG_INFO, &nil_pcb, "Attaching socket to flow %u", flow_id);
3202
3203	/ Find the flow divert control block /
3204	lck_rw_lock_shared(&g_flow_divert_group_lck);
3205	if (g_flow_divert_groups != NULL && g_active_group_count > `0`) {
3206	struct flow_divert_group *group = g_flow_divert_groups[ctl_unit];
3207	if (group != NULL) {
3208	fd_cb = flow_divert_pcb_lookup(flow_id, group);
3209	}
3210	}
3211	lck_rw_done(&g_flow_divert_group_lck);
3212
3213	if (fd_cb == NULL) {
3214	error = ENOENT;
3215	goto done;
3216	}
3217
3218	FDLOCK(fd_cb);
3219
3220	/ Dis-associate the flow divert control block from its current socket /
3221	old_so = fd_cb->so;
3222
3223	inp = sotoinpcb(old_so);
3224
3225	VERIFY(inp != NULL);
3226
3227	socket_lock(old_so, `0`);
3228	flow_divert_disconnect_socket(old_so);
3229	old_so->so_flags &= ~SOF_FLOW_DIVERT;
3230	old_so->so_fd_pcb = NULL;
3231	if (SOCK_TYPE(old_so) == SOCK_STREAM) {
3232	old_so->so_proto = pffindproto(SOCK_DOM(old_so), IPPROTO_TCP, SOCK_STREAM);
3233	} else if (SOCK_TYPE(old_so) == SOCK_DGRAM) {
3234	old_so->so_proto = pffindproto(SOCK_DOM(old_so), IPPROTO_UDP, SOCK_DGRAM);
3235	}
3236	fd_cb->so = NULL;
3237	/ Save the output interface /
3238	ifp = inp->inp_last_outifp;
3239	if (old_so->so_rcv.sb_cc > `0`) {
3240	error = mbuf_dup(old_so->so_rcv.sb_mb, MBUF_DONTWAIT, &recv_data);
3241	sbflush(&old_so->so_rcv);
3242	}
3243	socket_unlock(old_so, `0`);
3244
3245	/ Associate the new socket with the flow divert control block /
3246	socket_lock(so, `0`);
3247	so->so_fd_pcb = fd_cb;
3248	inp = sotoinpcb(so);
3249	inp->inp_last_outifp = ifp;
3250	if (recv_data != NULL) {
3251	if (sbappendstream(&so->so_rcv, recv_data)) {
3252	sorwakeup(so);
3253	}
3254	}
3255	flow_divert_set_protosw(so);
3256	socket_unlock(so, `0`);
3257
3258	fd_cb->so = so;
3259	fd_cb->flags \|= FLOW_DIVERT_TRANSFERRED;
3260
3261	FDUNLOCK(fd_cb);
3262
3263	done:
3264	socket_lock(so, `0`);
3265
3266	if (fd_cb != NULL) {
3267	FDRELEASE(fd_cb); / Release the reference obtained via flow_divert_pcb_lookup /
3268	}
3269
3270	return error;
3271	}
3272
3273	errno_t
3274	flow_divert_implicit_data_out(struct socket so, int* flags, mbuf_t data, struct sockaddr to, mbuf_t control, struct* proc *p)
3275	{
3276	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
3277	struct inpcb *inp;
3278	int error = `0`;
3279
3280	inp = sotoinpcb(so);
3281	if (inp == NULL) {
3282	return (EINVAL);
3283	}
3284
3285	if (fd_cb == NULL) {
3286	uint32_t fd_ctl_unit = necp_socket_get_flow_divert_control_unit(inp);
3287	if (fd_ctl_unit > `0`) {
3288	error = flow_divert_pcb_init(so, fd_ctl_unit);
3289	fd_cb = so->so_fd_pcb;
3290	if (error != `0` \|\| fd_cb == NULL) {
3291	goto done;
3292	}
3293	} else {
3294	error = ENETDOWN;
3295	goto done;
3296	}
3297	}
3298	return flow_divert_data_out(so, flags, data, to, control, p);
3299
3300	done:
3301	if (data) {
3302	mbuf_freem(data);
3303	}
3304	if (control) {
3305	mbuf_free(control);
3306	}
3307
3308	return error;
3309	}
3310
3311	errno_t
3312	flow_divert_pcb_init(struct socket *so, uint32_t ctl_unit)
3313	{
3314	errno_t error = `0`;
3315	struct flow_divert_pcb *fd_cb;
3316
3317	if (so->so_flags & SOF_FLOW_DIVERT) {
3318	return EALREADY;
3319	}
3320
3321	fd_cb = flow_divert_pcb_create(so);
3322	if (fd_cb != NULL) {
3323	error = flow_divert_pcb_insert(fd_cb, ctl_unit);
3324	if (error) {
3325	FDLOG(LOG_ERR, fd_cb, "pcb insert failed: %d", error);
3326	FDRELEASE(fd_cb);
3327	} else {
3328	fd_cb->control_group_unit = ctl_unit;
3329	so->so_fd_pcb = fd_cb;
3330
3331	if (SOCK_TYPE(so) == SOCK_STREAM) {
3332	flow_divert_set_protosw(so);
3333	} else if (SOCK_TYPE(so) == SOCK_DGRAM) {
3334	flow_divert_set_udp_protosw(so);
3335	}
3336
3337	FDLOG0(LOG_INFO, fd_cb, "Created");
3338	}
3339	} else {
3340	error = ENOMEM;
3341	}
3342
3343	return error;
3344	}
3345
3346	errno_t
3347	flow_divert_token_set(struct socket so, struct* sockopt *sopt)
3348	{
3349	uint32_t ctl_unit = `0`;
3350	uint32_t key_unit = `0`;
3351	uint32_t flow_id = `0`;
3352	int error = `0`;
3353	int hmac_error = `0`;
3354	mbuf_t token = NULL;
3355
3356	if (so->so_flags & SOF_FLOW_DIVERT) {
3357	error = EALREADY;
3358	goto done;
3359	}
3360
3361	if (g_init_result) {
3362	FDLOG(LOG_ERR, &nil_pcb, "flow_divert_init failed (%d), cannot use flow divert", g_init_result);
3363	error = ENOPROTOOPT;
3364	goto done;
3365	}
3366
3367	if ((SOCK_TYPE(so) != SOCK_STREAM && SOCK_TYPE(so) != SOCK_DGRAM) \|\|
3368	(SOCK_PROTO(so) != IPPROTO_TCP && SOCK_PROTO(so) != IPPROTO_UDP) \|\|
3369	(SOCK_DOM(so) != PF_INET
3370	#if INET6
3371	&& SOCK_DOM(so) != PF_INET6
3372	#endif
3373	))
3374	{
3375	error = EINVAL;
3376	goto done;
3377	} else {
3378	if (SOCK_TYPE(so) == SOCK_STREAM && SOCK_PROTO(so) == IPPROTO_TCP) {
3379	struct tcpcb *tp = sototcpcb(so);
3380	if (tp == NULL \|\| tp->t_state != TCPS_CLOSED) {
3381	error = EINVAL;
3382	goto done;
3383	}
3384	}
3385	}
3386
3387	error = soopt_getm(sopt, &token);
3388	if (error) {
3389	token = NULL;
3390	goto done;
3391	}
3392
3393	error = soopt_mcopyin(sopt, token);
3394	if (error) {
3395	token = NULL;
3396	goto done;
3397	}
3398
3399	error = flow_divert_packet_get_tlv(token, `0`, FLOW_DIVERT_TLV_KEY_UNIT, sizeof(key_unit), (void *)&key_unit, NULL);
3400	if (!error) {
3401	key_unit = ntohl(key_unit);
3402	if (key_unit >= GROUP_COUNT_MAX) {
3403	key_unit = `0`;
3404	}
3405	} else if (error != ENOENT) {
3406	FDLOG(LOG_ERR, &nil_pcb, "Failed to get the key unit from the token: %d", error);
3407	goto done;
3408	} else {
3409	key_unit = `0`;
3410	}
3411
3412	error = flow_divert_packet_get_tlv(token, `0`, FLOW_DIVERT_TLV_CTL_UNIT, sizeof(ctl_unit), (void *)&ctl_unit, NULL);
3413	if (error) {
3414	FDLOG(LOG_ERR, &nil_pcb, "Failed to get the control socket unit from the token: %d", error);
3415	goto done;
3416	}
3417
3418	/ A valid kernel control unit is required /
3419	ctl_unit = ntohl(ctl_unit);
3420	if (ctl_unit == `0` \|\| ctl_unit >= GROUP_COUNT_MAX) {
3421	FDLOG(LOG_ERR, &nil_pcb, "Got an invalid control socket unit: %u", ctl_unit);
3422	error = EINVAL;
3423	goto done;
3424	}
3425
3426	socket_unlock(so, `0`);
3427	hmac_error = flow_divert_packet_verify_hmac(token, (key_unit != `0` ? key_unit : ctl_unit));
3428	socket_lock(so, `0`);
3429
3430	if (hmac_error && hmac_error != ENOENT) {
3431	FDLOG(LOG_ERR, &nil_pcb, "HMAC verfication failed: %d", hmac_error);
3432	error = hmac_error;
3433	goto done;
3434	}
3435
3436	error = flow_divert_packet_get_tlv(token, `0`, FLOW_DIVERT_TLV_FLOW_ID, sizeof(flow_id), (void *)&flow_id, NULL);
3437	if (error && error != ENOENT) {
3438	FDLOG(LOG_ERR, &nil_pcb, "Failed to get the flow ID from the token: %d", error);
3439	goto done;
3440	}
3441
3442	if (flow_id == `0`) {
3443	error = flow_divert_pcb_init(so, ctl_unit);
3444	if (error == `0`) {
3445	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
3446	int log_level = LOG_NOTICE;
3447
3448	error = flow_divert_packet_get_tlv(token, `0`, FLOW_DIVERT_TLV_LOG_LEVEL,
3449	sizeof(log_level), &log_level, NULL);
3450	if (error == `0`) {
3451	fd_cb->log_level = log_level;
3452	}
3453	error = `0`;
3454
3455	fd_cb->connect_token = token;
3456	token = NULL;
3457	}
3458	} else {
3459	error = flow_divert_attach(so, flow_id, ctl_unit);
3460	}
3461
3462	if (hmac_error == `0`) {
3463	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
3464	if (fd_cb != NULL) {
3465	fd_cb->flags \|= FLOW_DIVERT_HAS_HMAC;
3466	}
3467	}
3468
3469	done:
3470	if (token != NULL) {
3471	mbuf_freem(token);
3472	}
3473
3474	return error;
3475	}
3476
3477	errno_t
3478	flow_divert_token_get(struct socket so, struct* sockopt *sopt)
3479	{
3480	uint32_t ctl_unit;
3481	int error = `0`;
3482	uint8_t hmac[SHA_DIGEST_LENGTH];
3483	struct flow_divert_pcb *fd_cb = so->so_fd_pcb;
3484	mbuf_t token = NULL;
3485	struct flow_divert_group *control_group = NULL;
3486
3487	if (!(so->so_flags & SOF_FLOW_DIVERT)) {
3488	error = EINVAL;
3489	goto done;
3490	}
3491
3492	VERIFY((so->so_flags & SOF_FLOW_DIVERT) && so->so_fd_pcb != NULL);
3493
3494	if (fd_cb->group == NULL) {
3495	error = EINVAL;
3496	goto done;
3497	}
3498
3499	error = mbuf_gethdr(MBUF_DONTWAIT, MBUF_TYPE_HEADER, &token);
3500	if (error) {
3501	FDLOG(LOG_ERR, fd_cb, "failed to allocate the header mbuf: %d", error);
3502	goto done;
3503	}
3504
3505	ctl_unit = htonl(fd_cb->group->ctl_unit);
3506
3507	error = flow_divert_packet_append_tlv(token, FLOW_DIVERT_TLV_CTL_UNIT, sizeof(ctl_unit), &ctl_unit);
3508	if (error) {
3509	goto done;
3510	}
3511
3512	error = flow_divert_packet_append_tlv(token, FLOW_DIVERT_TLV_FLOW_ID, sizeof(fd_cb->hash), &fd_cb->hash);
3513	if (error) {
3514	goto done;
3515	}
3516
3517	if (fd_cb->app_data != NULL) {
3518	error = flow_divert_packet_append_tlv(token, FLOW_DIVERT_TLV_APP_DATA, fd_cb->app_data_length, fd_cb->app_data);
3519	if (error) {
3520	goto done;
3521	}
3522	}
3523
3524	socket_unlock(so, `0`);
3525	lck_rw_lock_shared(&g_flow_divert_group_lck);
3526
3527	if (g_flow_divert_groups != NULL && g_active_group_count > `0` &&
3528	fd_cb->control_group_unit > `0` && fd_cb->control_group_unit < GROUP_COUNT_MAX)
3529	{
3530	control_group = g_flow_divert_groups[fd_cb->control_group_unit];
3531	}
3532
3533	if (control_group != NULL) {
3534	lck_rw_lock_shared(&control_group->lck);
3535	ctl_unit = htonl(control_group->ctl_unit);
3536	error = flow_divert_packet_append_tlv(token, FLOW_DIVERT_TLV_KEY_UNIT, sizeof(ctl_unit), &ctl_unit);
3537	if (!error) {
3538	error = flow_divert_packet_compute_hmac(token, control_group, hmac);
3539	}
3540	lck_rw_done(&control_group->lck);
3541	} else {
3542	error = ENOPROTOOPT;
3543	}
3544
3545	lck_rw_done(&g_flow_divert_group_lck);
3546	socket_lock(so, `0`);
3547
3548	if (error) {
3549	goto done;
3550	}
3551
3552	error = flow_divert_packet_append_tlv(token, FLOW_DIVERT_TLV_HMAC, sizeof(hmac), hmac);
3553	if (error) {
3554	goto done;
3555	}
3556
3557	if (sopt->sopt_val == USER_ADDR_NULL) {
3558	/ If the caller passed NULL to getsockopt, just set the size of the token and return /
3559	sopt->sopt_valsize = mbuf_pkthdr_len(token);
3560	goto done;
3561	}
3562
3563	error = soopt_mcopyout(sopt, token);
3564	if (error) {
3565	token = NULL; / For some reason, soopt_mcopyout() frees the mbuf if it fails /
3566	goto done;
3567	}
3568
3569	done:
3570	if (token != NULL) {
3571	mbuf_freem(token);
3572	}
3573
3574	return error;
3575	}
3576
3577	static errno_t
3578	flow_divert_kctl_connect(kern_ctl_ref kctlref __unused, struct sockaddr_ctl sac, void* **unitinfo)
3579	{
3580	struct flow_divert_group *new_group = NULL;
3581	int error = `0`;
3582
3583	if (sac->sc_unit >= GROUP_COUNT_MAX) {
3584	error = EINVAL;
3585	goto done;
3586	}
3587
3588	*unitinfo = NULL;
3589
3590	MALLOC_ZONE(new_group, struct flow_divert_group , sizeof(new_group), M_FLOW_DIVERT_GROUP, M_WAITOK);
3591	if (new_group == NULL) {
3592	error = ENOBUFS;
3593	goto done;
3594	}
3595
3596	memset(new_group, `0`, sizeof(*new_group));
3597
3598	lck_rw_init(&new_group->lck, flow_divert_mtx_grp, flow_divert_mtx_attr);
3599	RB_INIT(&new_group->pcb_tree);
3600	new_group->ctl_unit = sac->sc_unit;
3601	MBUFQ_INIT(&new_group->send_queue);
3602	new_group->signing_id_trie.root = NULL_TRIE_IDX;
3603
3604	lck_rw_lock_exclusive(&g_flow_divert_group_lck);
3605
3606	if (g_flow_divert_groups == NULL) {
3607	MALLOC(g_flow_divert_groups,
3608	struct flow_divert_group **,
3609	GROUP_COUNT_MAX * sizeof(struct flow_divert_group *),
3610	M_TEMP,
3611	M_WAITOK \| M_ZERO);
3612	}
3613
3614	if (g_flow_divert_groups == NULL) {
3615	error = ENOBUFS;
3616	} else if (g_flow_divert_groups[sac->sc_unit] != NULL) {
3617	error = EALREADY;
3618	} else {
3619	g_flow_divert_groups[sac->sc_unit] = new_group;
3620	g_active_group_count++;
3621	}
3622
3623	lck_rw_done(&g_flow_divert_group_lck);
3624
3625	*unitinfo = new_group;
3626
3627	done:
3628	if (error != `0` && new_group != NULL) {
3629	FREE_ZONE(new_group, sizeof(*new_group), M_FLOW_DIVERT_GROUP);
3630	}
3631	return error;
3632	}
3633
3634	static errno_t
3635	flow_divert_kctl_disconnect(kern_ctl_ref kctlref __unused, uint32_t unit, void *unitinfo)
3636	{
3637	struct flow_divert_group *group = NULL;
3638	errno_t error = `0`;
3639
3640	if (unit >= GROUP_COUNT_MAX) {
3641	return EINVAL;
3642	}
3643
3644	FDLOG(LOG_INFO, &nil_pcb, "disconnecting group %d", unit);
3645
3646	lck_rw_lock_exclusive(&g_flow_divert_group_lck);
3647
3648	if (g_flow_divert_groups == NULL \|\| g_active_group_count == `0`) {
3649	panic("flow divert group %u is disconnecting, but no groups are active (groups = %p, active count = %u", unit,
3650	g_flow_divert_groups, g_active_group_count);
3651	}
3652
3653	group = g_flow_divert_groups[unit];
3654
3655	if (group != (struct flow_divert_group *)unitinfo) {
3656	panic("group with unit %d (%p) != unit info (%p)", unit, group, unitinfo);
3657	}
3658
3659	if (group != NULL) {
3660	flow_divert_close_all(group);
3661	if (group->token_key != NULL) {
3662	memset(group->token_key, `0`, group->token_key_size);
3663	FREE(group->token_key, M_TEMP);
3664	group->token_key = NULL;
3665	group->token_key_size = `0`;
3666	}
3667
3668	/ Re-set the current trie /
3669	if (group->signing_id_trie.memory != NULL) {
3670	FREE(group->signing_id_trie.memory, M_TEMP);
3671	}
3672	memset(&group->signing_id_trie, `0`, sizeof(group->signing_id_trie));
3673	group->signing_id_trie.root = NULL_TRIE_IDX;
3674
3675	FREE_ZONE(group, sizeof(*group), M_FLOW_DIVERT_GROUP);
3676	g_flow_divert_groups[unit] = NULL;
3677	g_active_group_count--;
3678	} else {
3679	error = EINVAL;
3680	}
3681
3682	if (g_active_group_count == `0`) {
3683	FREE(g_flow_divert_groups, M_TEMP);
3684	g_flow_divert_groups = NULL;
3685	}
3686
3687	lck_rw_done(&g_flow_divert_group_lck);
3688
3689	return error;
3690	}
3691
3692	static errno_t
3693	flow_divert_kctl_send(kern_ctl_ref kctlref __unused, uint32_t unit __unused, void unitinfo, mbuf_t m, int* flags __unused)
3694	{
3695	return flow_divert_input(m, (struct flow_divert_group *)unitinfo);
3696	}
3697
3698	static void
3699	flow_divert_kctl_rcvd(kern_ctl_ref kctlref __unused, uint32_t unit __unused, void unitinfo, int* flags __unused)
3700	{
3701	struct flow_divert_group group = (struct* flow_divert_group *)unitinfo;
3702
3703	if (!OSTestAndClear(GROUP_BIT_CTL_ENQUEUE_BLOCKED, &group->atomic_bits)) {
3704	struct flow_divert_pcb *fd_cb;
3705	SLIST_HEAD(, flow_divert_pcb) tmp_list;
3706
3707	lck_rw_lock_shared(&g_flow_divert_group_lck);
3708	lck_rw_lock_exclusive(&group->lck);
3709
3710	while (!MBUFQ_EMPTY(&group->send_queue)) {
3711	mbuf_t next_packet;
3712	FDLOG0(LOG_DEBUG, &nil_pcb, "trying ctl_enqueuembuf again");
3713	next_packet = MBUFQ_FIRST(&group->send_queue);
3714	int error = ctl_enqueuembuf(g_flow_divert_kctl_ref, group->ctl_unit, next_packet, CTL_DATA_EOR);
3715	if (error) {
3716	FDLOG(LOG_DEBUG, &nil_pcb, "ctl_enqueuembuf returned an error: %d", error);
3717	OSTestAndSet(GROUP_BIT_CTL_ENQUEUE_BLOCKED, &group->atomic_bits);
3718	lck_rw_done(&group->lck);
3719	lck_rw_done(&g_flow_divert_group_lck);
3720	return;
3721	}
3722	MBUFQ_DEQUEUE(&group->send_queue, next_packet);
3723	}
3724
3725	SLIST_INIT(&tmp_list);
3726
3727	RB_FOREACH(fd_cb, fd_pcb_tree, &group->pcb_tree) {
3728	FDRETAIN(fd_cb);
3729	SLIST_INSERT_HEAD(&tmp_list, fd_cb, tmp_list_entry);
3730	}
3731
3732	lck_rw_done(&group->lck);
3733
3734	SLIST_FOREACH(fd_cb, &tmp_list, tmp_list_entry) {
3735	FDLOCK(fd_cb);
3736	if (fd_cb->so != NULL) {
3737	socket_lock(fd_cb->so, `0`);
3738	if (fd_cb->group != NULL) {
3739	flow_divert_send_buffered_data(fd_cb, FALSE);
3740	}
3741	socket_unlock(fd_cb->so, `0`);
3742	}
3743	FDUNLOCK(fd_cb);
3744	FDRELEASE(fd_cb);
3745	}
3746
3747	lck_rw_done(&g_flow_divert_group_lck);
3748	}
3749	}
3750
3751	static int
3752	flow_divert_kctl_init(void)
3753	{
3754	struct kern_ctl_reg ctl_reg;
3755	int result;
3756
3757	memset(&ctl_reg, `0`, sizeof(ctl_reg));
3758
3759	strlcpy(ctl_reg.ctl_name, FLOW_DIVERT_CONTROL_NAME, sizeof(ctl_reg.ctl_name));
3760	ctl_reg.ctl_name[sizeof(ctl_reg.ctl_name)-`1`] = `'\0'`;
3761	ctl_reg.ctl_flags = CTL_FLAG_PRIVILEGED \| CTL_FLAG_REG_EXTENDED;
3762	ctl_reg.ctl_sendsize = FD_CTL_SENDBUFF_SIZE;
3763	ctl_reg.ctl_recvsize = FD_CTL_RCVBUFF_SIZE;
3764
3765	ctl_reg.ctl_connect = flow_divert_kctl_connect;
3766	ctl_reg.ctl_disconnect = flow_divert_kctl_disconnect;
3767	ctl_reg.ctl_send = flow_divert_kctl_send;
3768	ctl_reg.ctl_rcvd = flow_divert_kctl_rcvd;
3769
3770	result = ctl_register(&ctl_reg, &g_flow_divert_kctl_ref);
3771
3772	if (result) {
3773	FDLOG(LOG_ERR, &nil_pcb, "flow_divert_kctl_init - ctl_register failed: %d\n", result);
3774	return result;
3775	}
3776
3777	return `0`;
3778	}
3779
3780	void
3781	flow_divert_init(void)
3782	{
3783	memset(&nil_pcb, `0`, sizeof(nil_pcb));
3784	nil_pcb.log_level = LOG_NOTICE;
3785
3786	g_tcp_protosw = pffindproto(AF_INET, IPPROTO_TCP, SOCK_STREAM);
3787
3788	VERIFY(g_tcp_protosw != NULL);
3789
3790	memcpy(&g_flow_divert_in_protosw, g_tcp_protosw, sizeof(g_flow_divert_in_protosw));
3791	memcpy(&g_flow_divert_in_usrreqs, g_tcp_protosw->pr_usrreqs, sizeof(g_flow_divert_in_usrreqs));
3792
3793	g_flow_divert_in_usrreqs.pru_connect = flow_divert_connect_out;
3794	g_flow_divert_in_usrreqs.pru_connectx = flow_divert_connectx_out;
3795	g_flow_divert_in_usrreqs.pru_control = flow_divert_in_control;
3796	g_flow_divert_in_usrreqs.pru_disconnect = flow_divert_close;
3797	g_flow_divert_in_usrreqs.pru_disconnectx = flow_divert_disconnectx;
3798	g_flow_divert_in_usrreqs.pru_peeraddr = flow_divert_getpeername;
3799	g_flow_divert_in_usrreqs.pru_rcvd = flow_divert_rcvd;
3800	g_flow_divert_in_usrreqs.pru_send = flow_divert_data_out;
3801	g_flow_divert_in_usrreqs.pru_shutdown = flow_divert_shutdown;
3802	g_flow_divert_in_usrreqs.pru_sockaddr = flow_divert_getsockaddr;
3803	g_flow_divert_in_usrreqs.pru_preconnect = flow_divert_preconnect;
3804
3805	g_flow_divert_in_protosw.pr_usrreqs = &g_flow_divert_in_usrreqs;
3806	g_flow_divert_in_protosw.pr_ctloutput = flow_divert_ctloutput;
3807
3808	/*
3809	* Socket filters shouldn't attach/detach to/from this protosw
3810	* since pr_protosw is to be used instead, which points to the
3811	* real protocol; if they do, it is a bug and we should panic.
3812	*/
3813	g_flow_divert_in_protosw.pr_filter_head.tqh_first =
3814	(struct socket_filter *)(uintptr_t)`0xdeadbeefdeadbeef`;
3815	g_flow_divert_in_protosw.pr_filter_head.tqh_last =
3816	(struct socket_filter **)(uintptr_t)`0xdeadbeefdeadbeef`;
3817
3818	/ UDP /
3819	g_udp_protosw = pffindproto(AF_INET, IPPROTO_UDP, SOCK_DGRAM);
3820	VERIFY(g_udp_protosw != NULL);
3821
3822	memcpy(&g_flow_divert_in_udp_protosw, g_udp_protosw, sizeof(g_flow_divert_in_udp_protosw));
3823	memcpy(&g_flow_divert_in_udp_usrreqs, g_udp_protosw->pr_usrreqs, sizeof(g_flow_divert_in_udp_usrreqs));
3824
3825	g_flow_divert_in_udp_usrreqs.pru_connect = flow_divert_connect_out;
3826	g_flow_divert_in_udp_usrreqs.pru_connectx = flow_divert_connectx_out;
3827	g_flow_divert_in_udp_usrreqs.pru_control = flow_divert_in_control;
3828	g_flow_divert_in_udp_usrreqs.pru_disconnect = flow_divert_close;
3829	g_flow_divert_in_udp_usrreqs.pru_disconnectx = flow_divert_disconnectx;
3830	g_flow_divert_in_udp_usrreqs.pru_peeraddr = flow_divert_getpeername;
3831	g_flow_divert_in_udp_usrreqs.pru_rcvd = flow_divert_rcvd;
3832	g_flow_divert_in_udp_usrreqs.pru_send = flow_divert_data_out;
3833	g_flow_divert_in_udp_usrreqs.pru_shutdown = flow_divert_shutdown;
3834	g_flow_divert_in_udp_usrreqs.pru_sockaddr = flow_divert_getsockaddr;
3835	g_flow_divert_in_udp_usrreqs.pru_sosend_list = pru_sosend_list_notsupp;
3836	g_flow_divert_in_udp_usrreqs.pru_soreceive_list = pru_soreceive_list_notsupp;
3837	g_flow_divert_in_udp_usrreqs.pru_preconnect = flow_divert_preconnect;
3838
3839	g_flow_divert_in_udp_protosw.pr_usrreqs = &g_flow_divert_in_usrreqs;
3840	g_flow_divert_in_udp_protosw.pr_ctloutput = flow_divert_ctloutput;
3841
3842	/*
3843	* Socket filters shouldn't attach/detach to/from this protosw
3844	* since pr_protosw is to be used instead, which points to the
3845	* real protocol; if they do, it is a bug and we should panic.
3846	*/
3847	g_flow_divert_in_udp_protosw.pr_filter_head.tqh_first =
3848	(struct socket_filter *)(uintptr_t)`0xdeadbeefdeadbeef`;
3849	g_flow_divert_in_udp_protosw.pr_filter_head.tqh_last =
3850	(struct socket_filter **)(uintptr_t)`0xdeadbeefdeadbeef`;
3851
3852	#if INET6
3853	g_tcp6_protosw = (struct ip6protosw *)pffindproto(AF_INET6, IPPROTO_TCP, SOCK_STREAM);
3854
3855	VERIFY(g_tcp6_protosw != NULL);
3856
3857	memcpy(&g_flow_divert_in6_protosw, g_tcp6_protosw, sizeof(g_flow_divert_in6_protosw));
3858	memcpy(&g_flow_divert_in6_usrreqs, g_tcp6_protosw->pr_usrreqs, sizeof(g_flow_divert_in6_usrreqs));
3859
3860	g_flow_divert_in6_usrreqs.pru_connect = flow_divert_connect_out;
3861	g_flow_divert_in6_usrreqs.pru_connectx = flow_divert_connectx6_out;
3862	g_flow_divert_in6_usrreqs.pru_control = flow_divert_in6_control;
3863	g_flow_divert_in6_usrreqs.pru_disconnect = flow_divert_close;
3864	g_flow_divert_in6_usrreqs.pru_disconnectx = flow_divert_disconnectx;
3865	g_flow_divert_in6_usrreqs.pru_peeraddr = flow_divert_getpeername;
3866	g_flow_divert_in6_usrreqs.pru_rcvd = flow_divert_rcvd;
3867	g_flow_divert_in6_usrreqs.pru_send = flow_divert_data_out;
3868	g_flow_divert_in6_usrreqs.pru_shutdown = flow_divert_shutdown;
3869	g_flow_divert_in6_usrreqs.pru_sockaddr = flow_divert_getsockaddr;
3870	g_flow_divert_in6_usrreqs.pru_preconnect = flow_divert_preconnect;
3871
3872	g_flow_divert_in6_protosw.pr_usrreqs = &g_flow_divert_in6_usrreqs;
3873	g_flow_divert_in6_protosw.pr_ctloutput = flow_divert_ctloutput;
3874	/*
3875	* Socket filters shouldn't attach/detach to/from this protosw
3876	* since pr_protosw is to be used instead, which points to the
3877	* real protocol; if they do, it is a bug and we should panic.
3878	*/
3879	g_flow_divert_in6_protosw.pr_filter_head.tqh_first =
3880	(struct socket_filter *)(uintptr_t)`0xdeadbeefdeadbeef`;
3881	g_flow_divert_in6_protosw.pr_filter_head.tqh_last =
3882	(struct socket_filter **)(uintptr_t)`0xdeadbeefdeadbeef`;
3883
3884	/ UDP6 /
3885	g_udp6_protosw = (struct ip6protosw *)pffindproto(AF_INET6, IPPROTO_UDP, SOCK_DGRAM);
3886
3887	VERIFY(g_udp6_protosw != NULL);
3888
3889	memcpy(&g_flow_divert_in6_udp_protosw, g_udp6_protosw, sizeof(g_flow_divert_in6_udp_protosw));
3890	memcpy(&g_flow_divert_in6_udp_usrreqs, g_udp6_protosw->pr_usrreqs, sizeof(g_flow_divert_in6_udp_usrreqs));
3891
3892	g_flow_divert_in6_udp_usrreqs.pru_connect = flow_divert_connect_out;
3893	g_flow_divert_in6_udp_usrreqs.pru_connectx = flow_divert_connectx6_out;
3894	g_flow_divert_in6_udp_usrreqs.pru_control = flow_divert_in6_control;
3895	g_flow_divert_in6_udp_usrreqs.pru_disconnect = flow_divert_close;
3896	g_flow_divert_in6_udp_usrreqs.pru_disconnectx = flow_divert_disconnectx;
3897	g_flow_divert_in6_udp_usrreqs.pru_peeraddr = flow_divert_getpeername;
3898	g_flow_divert_in6_udp_usrreqs.pru_rcvd = flow_divert_rcvd;
3899	g_flow_divert_in6_udp_usrreqs.pru_send = flow_divert_data_out;
3900	g_flow_divert_in6_udp_usrreqs.pru_shutdown = flow_divert_shutdown;
3901	g_flow_divert_in6_udp_usrreqs.pru_sockaddr = flow_divert_getsockaddr;
3902	g_flow_divert_in6_udp_usrreqs.pru_sosend_list = pru_sosend_list_notsupp;
3903	g_flow_divert_in6_udp_usrreqs.pru_soreceive_list = pru_soreceive_list_notsupp;
3904	g_flow_divert_in6_udp_usrreqs.pru_preconnect = flow_divert_preconnect;
3905
3906	g_flow_divert_in6_udp_protosw.pr_usrreqs = &g_flow_divert_in6_udp_usrreqs;
3907	g_flow_divert_in6_udp_protosw.pr_ctloutput = flow_divert_ctloutput;
3908	/*
3909	* Socket filters shouldn't attach/detach to/from this protosw
3910	* since pr_protosw is to be used instead, which points to the
3911	* real protocol; if they do, it is a bug and we should panic.
3912	*/
3913	g_flow_divert_in6_udp_protosw.pr_filter_head.tqh_first =
3914	(struct socket_filter *)(uintptr_t)`0xdeadbeefdeadbeef`;
3915	g_flow_divert_in6_udp_protosw.pr_filter_head.tqh_last =
3916	(struct socket_filter **)(uintptr_t)`0xdeadbeefdeadbeef`;
3917	#endif /* INET6 */
3918
3919	flow_divert_grp_attr = lck_grp_attr_alloc_init();
3920	if (flow_divert_grp_attr == NULL) {
3921	FDLOG0(LOG_ERR, &nil_pcb, "lck_grp_attr_alloc_init failed");
3922	g_init_result = ENOMEM;
3923	goto done;
3924	}
3925
3926	flow_divert_mtx_grp = lck_grp_alloc_init(FLOW_DIVERT_CONTROL_NAME, flow_divert_grp_attr);
3927	if (flow_divert_mtx_grp == NULL) {
3928	FDLOG0(LOG_ERR, &nil_pcb, "lck_grp_alloc_init failed");
3929	g_init_result = ENOMEM;
3930	goto done;
3931	}
3932
3933	flow_divert_mtx_attr = lck_attr_alloc_init();
3934	if (flow_divert_mtx_attr == NULL) {
3935	FDLOG0(LOG_ERR, &nil_pcb, "lck_attr_alloc_init failed");
3936	g_init_result = ENOMEM;
3937	goto done;
3938	}
3939
3940	g_init_result = flow_divert_kctl_init();
3941	if (g_init_result) {
3942	goto done;
3943	}
3944
3945	lck_rw_init(&g_flow_divert_group_lck, flow_divert_mtx_grp, flow_divert_mtx_attr);
3946
3947	done:
3948	if (g_init_result != `0`) {
3949	if (flow_divert_mtx_attr != NULL) {
3950	lck_attr_free(flow_divert_mtx_attr);
3951	flow_divert_mtx_attr = NULL;
3952	}
3953	if (flow_divert_mtx_grp != NULL) {
3954	lck_grp_free(flow_divert_mtx_grp);
3955	flow_divert_mtx_grp = NULL;
3956	}
3957	if (flow_divert_grp_attr != NULL) {
3958	lck_grp_attr_free(flow_divert_grp_attr);
3959	flow_divert_grp_attr = NULL;
3960	}
3961
3962	if (g_flow_divert_kctl_ref != NULL) {
3963	ctl_deregister(g_flow_divert_kctl_ref);
3964	g_flow_divert_kctl_ref = NULL;
3965	}
3966	}
3967	}
3968

Browse the source code of codebrowser/bsd/netinet/flow_divert.c