if_var.h source code [codebrowser/bsd/net/if_var.h]

1	/*
2	* Copyright (c) 2000-2018 Apple Inc. All rights reserved.
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28	/*
29	* Copyright (c) 1982, 1986, 1989, 1993
30	* The Regents of the University of California. All rights reserved.
31	*
32	* Redistribution and use in source and binary forms, with or without
33	* modification, are permitted provided that the following conditions
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35	* 1. Redistributions of source code must retain the above copyright
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41	* must display the following acknowledgement:
42	* This product includes software developed by the University of
43	* California, Berkeley and its contributors.
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46	* without specific prior written permission.
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48	* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
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51	* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
52	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
53	* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
54	* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
55	* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
56	* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
57	* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
58	* SUCH DAMAGE.
59	*
60	* From: @(#)if.h 8.1 (Berkeley) 6/10/93
61	* $FreeBSD: src/sys/net/if_var.h,v 1.18.2.7 2001/07/24 19:10:18 brooks Exp $
62	*/
63
64	#ifndef _NET_IF_VAR_H_
65	#define _NET_IF_VAR_H_
66
67	#include <sys/appleapiopts.h>
68	#include <stdint.h>
69	#include <sys/types.h>
70	#include <sys/time.h>
71	#include <sys/queue.h> /* get TAILQ macros */
72	#ifdef KERNEL_PRIVATE
73	#include <kern/locks.h>
74	#endif /* KERNEL_PRIVATE */
75	#ifdef PRIVATE
76	#include <net/route.h>
77	#endif
78	#ifdef BSD_KERNEL_PRIVATE
79	#include <sys/eventhandler.h>
80	#endif
81
82	#ifdef KERNEL
83	#include <net/kpi_interface.h>
84	#endif /* KERNEL */
85
86	#ifdef __APPLE__
87	#define APPLE_IF_FAM_LOOPBACK 1
88	#define APPLE_IF_FAM_ETHERNET 2
89	#define APPLE_IF_FAM_SLIP 3
90	#define APPLE_IF_FAM_TUN 4
91	#define APPLE_IF_FAM_VLAN 5
92	#define APPLE_IF_FAM_PPP 6
93	#define APPLE_IF_FAM_PVC 7
94	#define APPLE_IF_FAM_DISC 8
95	#define APPLE_IF_FAM_MDECAP 9
96	#define APPLE_IF_FAM_GIF 10
97	#define APPLE_IF_FAM_FAITH 11 /* deprecated */
98	#define APPLE_IF_FAM_STF 12
99	#define APPLE_IF_FAM_FIREWIRE 13
100	#define APPLE_IF_FAM_BOND 14
101	#endif /* __APPLE__ */
102
103	/*
104	* 72 was chosen below because it is the size of a TCP/IP
105	* header (40) + the minimum mss (32).
106	*/
107	#define IF_MINMTU 72
108	#define IF_MAXMTU 65535
109
110	/*
111	* Structures defining a network interface, providing a packet
112	* transport mechanism (ala level 0 of the PUP protocols).
113	*
114	* Each interface accepts output datagrams of a specified maximum
115	* length, and provides higher level routines with input datagrams
116	* received from its medium.
117	*
118	* Output occurs when the routine if_output is called, with three parameters:
119	* (*ifp->if_output)(ifp, m, dst, rt)
120	* Here m is the mbuf chain to be sent and dst is the destination address.
121	* The output routine encapsulates the supplied datagram if necessary,
122	* and then transmits it on its medium.
123	*
124	* On input, each interface unwraps the data received by it, and either
125	* places it on the input queue of a internetwork datagram routine
126	* and posts the associated software interrupt, or passes the datagram to a raw
127	* packet input routine.
128	*
129	* Routines exist for locating interfaces by their addresses
130	* or for locating a interface on a certain network, as well as more general
131	* routing and gateway routines maintaining information used to locate
132	* interfaces. These routines live in the files if.c and route.c
133	*/
134
135	#define IFNAMSIZ 16
136
137	/ This belongs up in socket.h or socketvar.h, depending on how far the*
138	* event bubbles up.
139	*/
140
141	struct net_event_data {
142	u_int32_t if_family;
143	u_int32_t if_unit;
144	char if_name[IFNAMSIZ];
145	};
146
147	#if defined(__LP64__)
148	#include <sys/_types/_timeval32.h>
149	#define IF_DATA_TIMEVAL timeval32
150	#else
151	#define IF_DATA_TIMEVAL timeval
152	#endif
153
154	#pragma pack(4)
155
156	/*
157	* Structure describing information about an interface
158	* which may be of interest to management entities.
159	*/
160	struct if_data {
161	/ generic interface information /
162	u_char ifi_type; / ethernet, tokenring, etc /
163	u_char ifi_typelen; / Length of frame type id /
164	u_char ifi_physical; / e.g., AUI, Thinnet, 10base-T, etc /
165	u_char ifi_addrlen; / media address length /
166	u_char ifi_hdrlen; / media header length /
167	u_char ifi_recvquota; / polling quota for receive intrs /
168	u_char ifi_xmitquota; / polling quota for xmit intrs /
169	u_char ifi_unused1; / for future use /
170	u_int32_t ifi_mtu; / maximum transmission unit /
171	u_int32_t ifi_metric; / routing metric (external only) /
172	u_int32_t ifi_baudrate; / linespeed /
173	/ volatile statistics /
174	u_int32_t ifi_ipackets; / packets received on interface /
175	u_int32_t ifi_ierrors; / input errors on interface /
176	u_int32_t ifi_opackets; / packets sent on interface /
177	u_int32_t ifi_oerrors; / output errors on interface /
178	u_int32_t ifi_collisions; / collisions on csma interfaces /
179	u_int32_t ifi_ibytes; / total number of octets received /
180	u_int32_t ifi_obytes; / total number of octets sent /
181	u_int32_t ifi_imcasts; / packets received via multicast /
182	u_int32_t ifi_omcasts; / packets sent via multicast /
183	u_int32_t ifi_iqdrops; / dropped on input, this interface /
184	u_int32_t ifi_noproto; / destined for unsupported protocol /
185	u_int32_t ifi_recvtiming; / usec spent receiving when timing /
186	u_int32_t ifi_xmittiming; / usec spent xmitting when timing /
187	struct IF_DATA_TIMEVAL ifi_lastchange; / time of last administrative change /
188	u_int32_t ifi_unused2; / used to be the default_proto /
189	u_int32_t ifi_hwassist; / HW offload capabilities /
190	u_int32_t ifi_reserved1; / for future use /
191	u_int32_t ifi_reserved2; / for future use /
192	};
193
194	/*
195	* Structure describing information about an interface
196	* which may be of interest to management entities.
197	*/
198	struct if_data64 {
199	/ generic interface information /
200	u_char ifi_type; / ethernet, tokenring, etc /
201	u_char ifi_typelen; / Length of frame type id /
202	u_char ifi_physical; / e.g., AUI, Thinnet, 10base-T, etc /
203	u_char ifi_addrlen; / media address length /
204	u_char ifi_hdrlen; / media header length /
205	u_char ifi_recvquota; / polling quota for receive intrs /
206	u_char ifi_xmitquota; / polling quota for xmit intrs /
207	u_char ifi_unused1; / for future use /
208	u_int32_t ifi_mtu; / maximum transmission unit /
209	u_int32_t ifi_metric; / routing metric (external only) /
210	u_int64_t ifi_baudrate; / linespeed /
211	/ volatile statistics /
212	u_int64_t ifi_ipackets; / packets received on interface /
213	u_int64_t ifi_ierrors; / input errors on interface /
214	u_int64_t ifi_opackets; / packets sent on interface /
215	u_int64_t ifi_oerrors; / output errors on interface /
216	u_int64_t ifi_collisions; / collisions on csma interfaces /
217	u_int64_t ifi_ibytes; / total number of octets received /
218	u_int64_t ifi_obytes; / total number of octets sent /
219	u_int64_t ifi_imcasts; / packets received via multicast /
220	u_int64_t ifi_omcasts; / packets sent via multicast /
221	u_int64_t ifi_iqdrops; / dropped on input, this interface /
222	u_int64_t ifi_noproto; / destined for unsupported protocol /
223	u_int32_t ifi_recvtiming; / usec spent receiving when timing /
224	u_int32_t ifi_xmittiming; / usec spent xmitting when timing /
225	struct IF_DATA_TIMEVAL ifi_lastchange; / time of last administrative change /
226	};
227
228	#ifdef PRIVATE
229	struct if_traffic_class {
230	u_int64_t ifi_ibepackets; / TC_BE packets received on interface /
231	u_int64_t ifi_ibebytes; / TC_BE bytes received on interface /
232	u_int64_t ifi_obepackets; / TC_BE packet sent on interface /
233	u_int64_t ifi_obebytes; / TC_BE bytes sent on interface /
234	u_int64_t ifi_ibkpackets; / TC_BK packets received on interface /
235	u_int64_t ifi_ibkbytes; / TC_BK bytes received on interface /
236	u_int64_t ifi_obkpackets; / TC_BK packet sent on interface /
237	u_int64_t ifi_obkbytes; / TC_BK bytes sent on interface /
238	u_int64_t ifi_ivipackets; / TC_VI packets received on interface /
239	u_int64_t ifi_ivibytes; / TC_VI bytes received on interface /
240	u_int64_t ifi_ovipackets; / TC_VI packets sent on interface /
241	u_int64_t ifi_ovibytes; / TC_VI bytes sent on interface /
242	u_int64_t ifi_ivopackets; / TC_VO packets received on interface /
243	u_int64_t ifi_ivobytes; / TC_VO bytes received on interface /
244	u_int64_t ifi_ovopackets; / TC_VO packets sent on interface /
245	u_int64_t ifi_ovobytes; / TC_VO bytes sent on interface /
246	u_int64_t ifi_ipvpackets; / TC priv packets received on interface /
247	u_int64_t ifi_ipvbytes; / TC priv bytes received on interface /
248	u_int64_t ifi_opvpackets; / TC priv packets sent on interface /
249	u_int64_t ifi_opvbytes; / TC priv bytes sent on interface /
250	};
251
252	struct if_data_extended {
253	u_int64_t ifi_alignerrs; / unaligned (32-bit) input pkts /
254	u_int64_t ifi_dt_bytes; / Data threshold counter /
255	u_int64_t ifi_fpackets; / forwarded packets on interface /
256	u_int64_t ifi_fbytes; / forwarded bytes on interface /
257	u_int64_t reserved[`12`]; / for future /
258	};
259
260	struct if_packet_stats {
261	/ TCP /
262	u_int64_t ifi_tcp_badformat;
263	u_int64_t ifi_tcp_unspecv6;
264	u_int64_t ifi_tcp_synfin;
265	u_int64_t ifi_tcp_badformatipsec;
266	u_int64_t ifi_tcp_noconnnolist;
267	u_int64_t ifi_tcp_noconnlist;
268	u_int64_t ifi_tcp_listbadsyn;
269	u_int64_t ifi_tcp_icmp6unreach;
270	u_int64_t ifi_tcp_deprecate6;
271	u_int64_t ifi_tcp_rstinsynrcv;
272	u_int64_t ifi_tcp_ooopacket;
273	u_int64_t ifi_tcp_dospacket;
274	u_int64_t ifi_tcp_cleanup;
275	u_int64_t ifi_tcp_synwindow;
276	u_int64_t reserved[`6`];
277	/ UDP /
278	u_int64_t ifi_udp_port_unreach;
279	u_int64_t ifi_udp_faithprefix;
280	u_int64_t ifi_udp_port0;
281	u_int64_t ifi_udp_badlength;
282	u_int64_t ifi_udp_badchksum;
283	u_int64_t ifi_udp_badmcast;
284	u_int64_t ifi_udp_cleanup;
285	u_int64_t ifi_udp_badipsec;
286	u_int64_t _reserved[`4`];
287	};
288
289	struct if_description {
290	u_int32_t ifd_maxlen; / must be IF_DESCSIZE /
291	u_int32_t ifd_len; / actual ifd_desc length /
292	u_int8_t ifd_desc; /* ptr to desc buffer /
293	};
294
295	struct if_bandwidths {
296	u_int64_t eff_bw; / effective bandwidth /
297	u_int64_t max_bw; / maximum theoretical bandwidth /
298	};
299
300	struct if_latencies {
301	u_int64_t eff_lt; / effective latency /
302	u_int64_t max_lt; / maximum theoretical latency /
303	};
304
305	struct if_rxpoll_stats {
306	u_int32_t ifi_poll_off_req; / total # of POLL_OFF reqs /
307	u_int32_t ifi_poll_off_err; / total # of POLL_OFF errors /
308	u_int32_t ifi_poll_on_req; / total # of POLL_ON reqs /
309	u_int32_t ifi_poll_on_err; / total # of POLL_ON errors /
310
311	u_int32_t ifi_poll_wakeups_avg; / avg # of wakeup reqs /
312	u_int32_t ifi_poll_wakeups_lowat; / wakeups low watermark /
313	u_int32_t ifi_poll_wakeups_hiwat; / wakeups high watermark /
314
315	u_int64_t ifi_poll_packets; / total # of polled packets /
316	u_int32_t ifi_poll_packets_avg; / average polled packets /
317	u_int32_t ifi_poll_packets_min; / smallest polled packets /
318	u_int32_t ifi_poll_packets_max; / largest polled packets /
319	u_int32_t ifi_poll_packets_lowat; / packets low watermark /
320	u_int32_t ifi_poll_packets_hiwat; / packets high watermark /
321
322	u_int64_t ifi_poll_bytes; / total # of polled bytes /
323	u_int32_t ifi_poll_bytes_avg; / average polled bytes /
324	u_int32_t ifi_poll_bytes_min; / smallest polled bytes /
325	u_int32_t ifi_poll_bytes_max; / largest polled bytes /
326	u_int32_t ifi_poll_bytes_lowat; / bytes low watermark /
327	u_int32_t ifi_poll_bytes_hiwat; / bytes high watermark /
328
329	u_int32_t ifi_poll_packets_limit; / max packets per poll call /
330	u_int64_t ifi_poll_interval_time; / poll interval (nsec) /
331	};
332
333	struct if_tcp_ecn_perf_stat {
334	u_int64_t total_txpkts;
335	u_int64_t total_rxmitpkts;
336	u_int64_t total_rxpkts;
337	u_int64_t total_oopkts;
338	u_int64_t total_reorderpkts;
339	u_int64_t rtt_avg;
340	u_int64_t rtt_var;
341	u_int64_t sack_episodes;
342	u_int64_t rxmit_drop;
343	u_int64_t rst_drop;
344	u_int64_t oo_percent;
345	u_int64_t reorder_percent;
346	u_int64_t rxmit_percent;
347	};
348
349	struct if_tcp_ecn_stat {
350	u_int64_t timestamp;
351	u_int64_t ecn_client_setup;
352	u_int64_t ecn_server_setup;
353	u_int64_t ecn_client_success;
354	u_int64_t ecn_server_success;
355	u_int64_t ecn_peer_nosupport;
356	u_int64_t ecn_syn_lost;
357	u_int64_t ecn_synack_lost;
358	u_int64_t ecn_recv_ce;
359	u_int64_t ecn_recv_ece;
360	u_int64_t ecn_conn_recv_ce;
361	u_int64_t ecn_conn_recv_ece;
362	u_int64_t ecn_conn_plnoce;
363	u_int64_t ecn_conn_plce;
364	u_int64_t ecn_conn_noplce;
365	u_int64_t ecn_fallback_synloss;
366	u_int64_t ecn_fallback_reorder;
367	u_int64_t ecn_fallback_ce;
368	u_int64_t ecn_off_conn;
369	u_int64_t ecn_total_conn;
370	u_int64_t ecn_fallback_droprst;
371	u_int64_t ecn_fallback_droprxmt;
372	u_int64_t ecn_fallback_synrst;
373	struct if_tcp_ecn_perf_stat ecn_on;
374	struct if_tcp_ecn_perf_stat ecn_off;
375	};
376
377	struct if_lim_perf_stat {
378	u_int64_t lim_dl_max_bandwidth; / bits per second /
379	u_int64_t lim_ul_max_bandwidth; / bits per second /
380	u_int64_t lim_total_txpkts; / Total transmit packets, count /
381	u_int64_t lim_total_rxpkts; / Total receive packets, count /
382	u_int64_t lim_total_retxpkts; / Total retransmit packets /
383	u_int64_t lim_packet_loss_percent; / Packet loss rate /
384	u_int64_t lim_total_oopkts; / Total out-of-order packets /
385	u_int64_t lim_packet_ooo_percent; / Out-of-order packet rate /
386	u_int64_t lim_rtt_variance; / RTT variance, milliseconds /
387	u_int64_t lim_rtt_average; / RTT average, milliseconds /
388	u_int64_t lim_rtt_min; / RTT minimum, milliseconds /
389	u_int64_t lim_conn_timeouts; / connection timeouts /
390	u_int64_t lim_conn_attempts; / connection attempts /
391	u_int64_t lim_conn_timeout_percent; / Rate of connection timeouts /
392	u_int64_t lim_bk_txpkts; / Transmit packets with BK service class, that use delay based algorithms /
393	u_int64_t lim_dl_detected:`1`, / Low internet /
394	lim_ul_detected:`1`;
395	};
396
397	#define IF_VAR_H_HAS_IFNET_STATS_PER_FLOW 1
398	struct ifnet_stats_per_flow {
399	u_int64_t bk_txpackets;
400	u_int64_t txpackets;
401	u_int64_t rxpackets;
402	u_int32_t txretransmitbytes;
403	u_int32_t rxoutoforderbytes;
404	u_int32_t rxmitpkts;
405	u_int32_t rcvoopack;
406	u_int32_t pawsdrop;
407	u_int32_t sack_recovery_episodes;
408	u_int32_t reordered_pkts;
409	u_int32_t dsack_sent;
410	u_int32_t dsack_recvd;
411	u_int32_t srtt;
412	u_int32_t rttupdated;
413	u_int32_t rttvar;
414	u_int32_t rttmin;
415	u_int32_t bw_sndbw_max;
416	u_int32_t bw_rcvbw_max;
417	u_int32_t ecn_recv_ece;
418	u_int32_t ecn_recv_ce;
419	u_int16_t ecn_flags;
420	u_int16_t ipv4:`1`,
421	local:`1`,
422	connreset:`1`,
423	conntimeout:`1`,
424	rxmit_drop:`1`,
425	ecn_fallback_synloss:`1`,
426	ecn_fallback_droprst:`1`,
427	ecn_fallback_droprxmt:`1`,
428	ecn_fallback_ce:`1`,
429	ecn_fallback_reorder:`1`;
430	};
431
432	/*
433	* Interface link status report -- includes statistics related to
434	* the link layer technology sent by the driver. The driver will monitor
435	* these statistics over an interval (3-4 secs) and will generate a report
436	* to the network stack. This will give first-hand information about the
437	* status of the first hop of the network path. The version and
438	* length values should be correct for the data to be processed correctly.
439	* The definitions are different for different kind of interfaces like
440	* Wifi, Cellular etc,.
441	*/
442	#define IF_CELLULAR_STATUS_REPORT_VERSION_1 1
443	#define IF_WIFI_STATUS_REPORT_VERSION_1 1
444	#define IF_CELLULAR_STATUS_REPORT_CURRENT_VERSION \
445	IF_CELLULAR_STATUS_REPORT_VERSION_1
446	#define IF_WIFI_STATUS_REPORT_CURRENT_VERSION IF_WIFI_STATUS_REPORT_VERSION_1
447	/*
448	* For cellular interface --
449	* There is no way to share common headers between the Baseband and
450	* the kernel. Any changes to this structure will need to be communicated
451	* to the Baseband team. It is better to use reserved space instead of
452	* changing the size or existing fields in the structure.
453	*/
454	struct if_cellular_status_v1 {
455	u_int32_t valid_bitmask; / indicates which fields are valid /
456	#define IF_CELL_LINK_QUALITY_METRIC_VALID 0x1
457	#define IF_CELL_UL_EFFECTIVE_BANDWIDTH_VALID 0x2
458	#define IF_CELL_UL_MAX_BANDWIDTH_VALID 0x4
459	#define IF_CELL_UL_MIN_LATENCY_VALID 0x8
460	#define IF_CELL_UL_EFFECTIVE_LATENCY_VALID 0x10
461	#define IF_CELL_UL_MAX_LATENCY_VALID 0x20
462	#define IF_CELL_UL_RETXT_LEVEL_VALID 0x40
463	#define IF_CELL_UL_BYTES_LOST_VALID 0x80
464	#define IF_CELL_UL_MIN_QUEUE_SIZE_VALID 0x100
465	#define IF_CELL_UL_AVG_QUEUE_SIZE_VALID 0x200
466	#define IF_CELL_UL_MAX_QUEUE_SIZE_VALID 0x400
467	#define IF_CELL_DL_EFFECTIVE_BANDWIDTH_VALID 0x800
468	#define IF_CELL_DL_MAX_BANDWIDTH_VALID 0x1000
469	#define IF_CELL_CONFIG_INACTIVITY_TIME_VALID 0x2000
470	#define IF_CELL_CONFIG_BACKOFF_TIME_VALID 0x4000
471	#define IF_CELL_UL_MSS_RECOMMENDED_VALID 0x8000
472
473	u_int32_t link_quality_metric;
474	u_int32_t ul_effective_bandwidth; / Measured uplink bandwidth based on current activity (bps) /
475	u_int32_t ul_max_bandwidth; / Maximum supported uplink bandwidth (bps) /
476	u_int32_t ul_min_latency; / min expected uplink latency for first hop (ms) /
477	u_int32_t ul_effective_latency; / current expected uplink latency for first hop (ms) /
478	u_int32_t ul_max_latency; / max expected uplink latency first hop (ms) /
479	u_int32_t ul_retxt_level; / Retransmission metric /
480	#define IF_CELL_UL_RETXT_LEVEL_NONE 1
481	#define IF_CELL_UL_RETXT_LEVEL_LOW 2
482	#define IF_CELL_UL_RETXT_LEVEL_MEDIUM 3
483	#define IF_CELL_UL_RETXT_LEVEL_HIGH 4
484	u_int32_t ul_bytes_lost; / % of total bytes lost on uplink in Q10 format /
485	u_int32_t ul_min_queue_size; / minimum bytes in queue /
486	u_int32_t ul_avg_queue_size; / average bytes in queue /
487	u_int32_t ul_max_queue_size; / maximum bytes in queue /
488	u_int32_t dl_effective_bandwidth; / Measured downlink bandwidth based on current activity (bps) /
489	u_int32_t dl_max_bandwidth; / Maximum supported downlink bandwidth (bps) /
490	u_int32_t config_inactivity_time; / ms /
491	u_int32_t config_backoff_time; / new connections backoff time in ms /
492	#define IF_CELL_UL_MSS_RECOMMENDED_NONE 0x0 /* Use default */
493	#define IF_CELL_UL_MSS_RECOMMENDED_MEDIUM 0x1 /* 1200 byte MSS */
494	#define IF_CELL_UL_MSS_RECOMMENDED_LOW 0x2 /* 512 byte MSS */
495	u_int16_t mss_recommended;
496	u_int16_t reserved_1;
497	u_int32_t reserved_2;
498	u_int64_t reserved_3;
499	u_int64_t reserved_4;
500	u_int64_t reserved_5;
501	u_int64_t reserved_6;
502	} __attribute__((packed));
503
504	struct if_cellular_status {
505	union {
506	struct if_cellular_status_v1 if_status_v1;
507	} if_cell_u;
508	};
509
510	/*
511	* These statistics will be provided by the Wifi driver periodically.
512	* After sending each report, the driver should start computing again
513	* for the next report duration so that the values represent the link
514	* status for one report duration.
515	*/
516
517	struct if_wifi_status_v1 {
518	u_int32_t valid_bitmask;
519	#define IF_WIFI_LINK_QUALITY_METRIC_VALID 0x1
520	#define IF_WIFI_UL_EFFECTIVE_BANDWIDTH_VALID 0x2
521	#define IF_WIFI_UL_MAX_BANDWIDTH_VALID 0x4
522	#define IF_WIFI_UL_MIN_LATENCY_VALID 0x8
523	#define IF_WIFI_UL_EFFECTIVE_LATENCY_VALID 0x10
524	#define IF_WIFI_UL_MAX_LATENCY_VALID 0x20
525	#define IF_WIFI_UL_RETXT_LEVEL_VALID 0x40
526	#define IF_WIFI_UL_ERROR_RATE_VALID 0x80
527	#define IF_WIFI_UL_BYTES_LOST_VALID 0x100
528	#define IF_WIFI_DL_EFFECTIVE_BANDWIDTH_VALID 0x200
529	#define IF_WIFI_DL_MAX_BANDWIDTH_VALID 0x400
530	#define IF_WIFI_DL_MIN_LATENCY_VALID 0x800
531	#define IF_WIFI_DL_EFFECTIVE_LATENCY_VALID 0x1000
532	#define IF_WIFI_DL_MAX_LATENCY_VALID 0x2000
533	#define IF_WIFI_DL_ERROR_RATE_VALID 0x4000
534	#define IF_WIFI_CONFIG_FREQUENCY_VALID 0x8000
535	#define IF_WIFI_CONFIG_MULTICAST_RATE_VALID 0x10000
536	#define IF_WIFI_CONFIG_SCAN_COUNT_VALID 0x20000
537	#define IF_WIFI_CONFIG_SCAN_DURATION_VALID 0x40000
538	u_int32_t link_quality_metric; / link quality metric /
539	u_int32_t ul_effective_bandwidth; / Measured uplink bandwidth based on current activity (bps) /
540	u_int32_t ul_max_bandwidth; / Maximum supported uplink bandwidth (bps) /
541	u_int32_t ul_min_latency; / min expected uplink latency for first hop (ms) /
542	u_int32_t ul_effective_latency; / current expected uplink latency for first hop (ms) /
543	u_int32_t ul_max_latency; / max expected uplink latency for first hop (ms) /
544	u_int32_t ul_retxt_level; / Retransmission metric /
545	#define IF_WIFI_UL_RETXT_LEVEL_NONE 1
546	#define IF_WIFI_UL_RETXT_LEVEL_LOW 2
547	#define IF_WIFI_UL_RETXT_LEVEL_MEDIUM 3
548	#define IF_WIFI_UL_RETXT_LEVEL_HIGH 4
549	u_int32_t ul_bytes_lost; / % of total bytes lost on uplink in Q10 format /
550	u_int32_t ul_error_rate; / % of bytes dropped on uplink after many retransmissions in Q10 format /
551	u_int32_t dl_effective_bandwidth; / Measured downlink bandwidth based on current activity (bps) /
552	u_int32_t dl_max_bandwidth; / Maximum supported downlink bandwidth (bps) /
553	/*
554	* The download latency values indicate the time AP may have to wait for the
555	* driver to receive the packet. These values give the range of expected latency
556	* mainly due to co-existence events and channel hopping where the interface
557	* becomes unavailable.
558	*/
559	u_int32_t dl_min_latency; / min expected latency for first hop in ms /
560	u_int32_t dl_effective_latency; / current expected latency for first hop in ms /
561	u_int32_t dl_max_latency; / max expected latency for first hop in ms /
562	u_int32_t dl_error_rate; / % of CRC or other errors in Q10 format /
563	u_int32_t config_frequency; / 2.4 or 5 GHz /
564	#define IF_WIFI_CONFIG_FREQUENCY_2_4_GHZ 1
565	#define IF_WIFI_CONFIG_FREQUENCY_5_0_GHZ 2
566	u_int32_t config_multicast_rate; / bps /
567	u_int32_t scan_count; / scan count during the previous period /
568	u_int32_t scan_duration; / scan duration in ms /
569	u_int64_t reserved_1;
570	u_int64_t reserved_2;
571	u_int64_t reserved_3;
572	u_int64_t reserved_4;
573	} __attribute__((packed));
574
575	struct if_wifi_status {
576	union {
577	struct if_wifi_status_v1 if_status_v1;
578	} if_wifi_u;
579	};
580
581	struct if_link_status {
582	u_int32_t ifsr_version; / version of this report /
583	u_int32_t ifsr_len; / length of the following struct /
584	union {
585	struct if_cellular_status ifsr_cell;
586	struct if_wifi_status ifsr_wifi;
587	} ifsr_u;
588	};
589
590	struct if_interface_state {
591	/*
592	* The bitmask tells which of the fields
593	* to consider:
594	* - When setting, to control which fields
595	* are being modified;
596	* - When getting, it tells which fields are set.
597	*/
598	u_int8_t valid_bitmask;
599	#define IF_INTERFACE_STATE_RRC_STATE_VALID 0x1
600	#define IF_INTERFACE_STATE_LQM_STATE_VALID 0x2
601	#define IF_INTERFACE_STATE_INTERFACE_AVAILABILITY_VALID 0x4
602
603	/*
604	* Valid only for cellular interface
605	*/
606	u_int8_t rrc_state;
607	#define IF_INTERFACE_STATE_RRC_STATE_IDLE 0x0
608	#define IF_INTERFACE_STATE_RRC_STATE_CONNECTED 0x1
609
610	/*
611	* Values normalized to the edge of the following values
612	* that are defined on <net/if.h>:
613	* IFNET_LQM_THRESH_BAD
614	* IFNET_LQM_THRESH_POOR
615	* IFNET_LQM_THRESH_GOOD
616	*/
617	int8_t lqm_state;
618
619	/*
620	* Indicate if the underlying link is currently
621	* available
622	*/
623	u_int8_t interface_availability;
624	#define IF_INTERFACE_STATE_INTERFACE_AVAILABLE 0x0
625	#define IF_INTERFACE_STATE_INTERFACE_UNAVAILABLE 0x1
626	};
627
628	struct chain_len_stats {
629	uint64_t cls_one;
630	uint64_t cls_two;
631	uint64_t cls_three;
632	uint64_t cls_four;
633	uint64_t cls_five_or_more;
634	} __attribute__((__aligned__(sizeof (uint64_t))));
635
636	#endif /* PRIVATE */
637
638	#pragma pack()
639
640	/*
641	* Structure defining a queue for a network interface.
642	*/
643	struct ifqueue {
644	void *ifq_head;
645	void *ifq_tail;
646	int ifq_len;
647	int ifq_maxlen;
648	int ifq_drops;
649	};
650
651	#ifdef BSD_KERNEL_PRIVATE
652	#define IFNETS_MAX 64
653
654	/*
655	* Internal storage of if_data. This is bound to change. Various places in the
656	* stack will translate this data structure in to the externally visible
657	* if_data structure above. Note that during interface attach time, the
658	* embedded if_data structure in ifnet is cleared, with the exception of
659	* some non-statistics related fields.
660	*/
661	struct if_data_internal {
662	/ generic interface information /
663	u_char ifi_type; / ethernet, tokenring, etc /
664	u_char ifi_typelen; / Length of frame type id /
665	u_char ifi_physical; / e.g., AUI, Thinnet, 10base-T, etc /
666	u_char ifi_addrlen; / media address length /
667	u_char ifi_hdrlen; / media header length /
668	u_char ifi_recvquota; / polling quota for receive intrs /
669	u_char ifi_xmitquota; / polling quota for xmit intrs /
670	u_char ifi_unused1; / for future use /
671	u_int32_t ifi_mtu; / maximum transmission unit /
672	u_int32_t ifi_metric; / routing metric (external only) /
673	u_int32_t ifi_baudrate; / linespeed /
674	/ volatile statistics /
675	u_int64_t ifi_ipackets; / packets received on interface /
676	u_int64_t ifi_ierrors; / input errors on interface /
677	u_int64_t ifi_opackets; / packets sent on interface /
678	u_int64_t ifi_oerrors; / output errors on interface /
679	u_int64_t ifi_collisions; / collisions on csma interfaces /
680	u_int64_t ifi_ibytes; / total number of octets received /
681	u_int64_t ifi_obytes; / total number of octets sent /
682	u_int64_t ifi_imcasts; / packets received via multicast /
683	u_int64_t ifi_omcasts; / packets sent via multicast /
684	u_int64_t ifi_iqdrops; / dropped on input, this interface /
685	u_int64_t ifi_noproto; / destined for unsupported protocol /
686	u_int32_t ifi_recvtiming; / usec spent receiving when timing /
687	u_int32_t ifi_xmittiming; / usec spent xmitting when timing /
688	u_int64_t ifi_alignerrs; / unaligned (32-bit) input pkts /
689	u_int64_t ifi_dt_bytes; / Data threshold counter /
690	u_int64_t ifi_fpackets; / forwarded packets on interface /
691	u_int64_t ifi_fbytes; / forwarded bytes on interface /
692	struct timeval ifi_lastchange; / time of last administrative change /
693	struct timeval ifi_lastupdown; / time of last up/down event /
694	u_int32_t ifi_hwassist; / HW offload capabilities /
695	u_int32_t ifi_tso_v4_mtu; / TCP Segment Offload IPv4 maximum segment size /
696	u_int32_t ifi_tso_v6_mtu; / TCP Segment Offload IPv6 maximum segment size /
697	};
698	#endif /* BSD_KERNEL_PRIVATE */
699
700	#ifdef PRIVATE
701	#define if_mtu if_data.ifi_mtu
702	#define if_type if_data.ifi_type
703	#define if_typelen if_data.ifi_typelen
704	#define if_physical if_data.ifi_physical
705	#define if_addrlen if_data.ifi_addrlen
706	#define if_hdrlen if_data.ifi_hdrlen
707	#define if_metric if_data.ifi_metric
708	#define if_baudrate if_data.ifi_baudrate
709	#define if_hwassist if_data.ifi_hwassist
710	#define if_ipackets if_data.ifi_ipackets
711	#define if_ierrors if_data.ifi_ierrors
712	#define if_opackets if_data.ifi_opackets
713	#define if_oerrors if_data.ifi_oerrors
714	#define if_collisions if_data.ifi_collisions
715	#define if_ibytes if_data.ifi_ibytes
716	#define if_obytes if_data.ifi_obytes
717	#define if_imcasts if_data.ifi_imcasts
718	#define if_omcasts if_data.ifi_omcasts
719	#define if_iqdrops if_data.ifi_iqdrops
720	#define if_noproto if_data.ifi_noproto
721	#define if_lastchange if_data.ifi_lastchange
722	#define if_recvquota if_data.ifi_recvquota
723	#define if_xmitquota if_data.ifi_xmitquota
724	#endif /* PRIVATE */
725	#ifdef BSD_KERNEL_PRIVATE
726	#define if_tso_v4_mtu if_data.ifi_tso_v4_mtu
727	#define if_tso_v6_mtu if_data.ifi_tso_v6_mtu
728	#define if_alignerrs if_data.ifi_alignerrs
729	#define if_dt_bytes if_data.ifi_dt_bytes
730	#define if_fpackets if_data.ifi_fpackets
731	#define if_fbytes if_data.ifi_fbytes
732	#define if_lastupdown if_data.ifi_lastupdown
733	#endif /* BSD_KERNEL_PRIVATE */
734
735	#ifdef BSD_KERNEL_PRIVATE
736	/*
737	* Forward structure declarations for function prototypes [sic].
738	*/
739	struct proc;
740	struct rtentry;
741	struct socket;
742	struct ifnet_filter;
743	struct mbuf;
744	struct ifaddr;
745	struct tqdummy;
746	struct proto_hash_entry;
747	struct dlil_threading_info;
748	struct tcpstat_local;
749	struct udpstat_local;
750	#if PF
751	struct pfi_kif;
752	#endif /* PF */
753
754	/ we use TAILQs so that the order of instantiation is preserved in the list /
755	TAILQ_HEAD(ifnethead, ifnet);
756	TAILQ_HEAD(ifaddrhead, ifaddr);
757	LIST_HEAD(ifmultihead, ifmultiaddr);
758	TAILQ_HEAD(tailq_head, tqdummy);
759	TAILQ_HEAD(ifnet_filter_head, ifnet_filter);
760	TAILQ_HEAD(ddesc_head_name, dlil_demux_desc);
761
762	extern boolean_t intcoproc_unrestricted;
763	#endif /* BSD_KERNEL_PRIVATE */
764
765	#ifdef PRIVATE
766	/*
767	* All of the following IF_HWASSIST_* flags are defined in kpi_interface.h as
768	* IFNET_* flags. These are redefined here as constants to avoid failures to
769	* build user level programs that can not include kpi_interface.h. It is
770	* important to keep this in sync with the definitions in kpi_interface.h.
771	* The corresponding constant for each definition is mentioned in the comment.
772	*
773	* Bottom 16 bits reserved for hardware checksum
774	*/
775	#define IF_HWASSIST_CSUM_IP 0x0001 /* will csum IP, IFNET_CSUM_IP */
776	#define IF_HWASSIST_CSUM_TCP 0x0002 /* will csum TCP, IFNET_CSUM_TCP */
777	#define IF_HWASSIST_CSUM_UDP 0x0004 /* will csum UDP, IFNET_CSUM_UDP */
778	#define IF_HWASSIST_CSUM_IP_FRAGS 0x0008 /* will csum IP fragments, IFNET_CSUM_FRAGMENT */
779	#define IF_HWASSIST_CSUM_FRAGMENT 0x0010 /* will do IP fragmentation, IFNET_IP_FRAGMENT */
780	#define IF_HWASSIST_CSUM_TCPIPV6 0x0020 /* will csum TCPv6, IFNET_CSUM_TCPIPV6 */
781	#define IF_HWASSIST_CSUM_UDPIPV6 0x0040 /* will csum UDPv6, IFNET_CSUM_UDP */
782	#define IF_HWASSIST_CSUM_FRAGMENT_IPV6 0x0080 /* will do IPv6 fragmentation, IFNET_IPV6_FRAGMENT */
783	#define IF_HWASSIST_CSUM_PARTIAL 0x1000 /* simple Sum16 computation, IFNET_CSUM_PARTIAL */
784	#define IF_HWASSIST_CSUM_ZERO_INVERT 0x2000 /* capable of inverting csum of 0 to -0 (0xffff) */
785	#define IF_HWASSIST_CSUM_MASK 0xffff
786	#define IF_HWASSIST_CSUM_FLAGS(hwassist) ((hwassist) & IF_HWASSIST_CSUM_MASK)
787
788	/ VLAN support /
789	#define IF_HWASSIST_VLAN_TAGGING 0x00010000 /* supports VLAN tagging, IFNET_VLAN_TAGGING */
790	#define IF_HWASSIST_VLAN_MTU 0x00020000 /* supports VLAN MTU-sized packet (for software VLAN), IFNET_VLAN_MTU */
791
792	/ TCP Segment Offloading support /
793
794	#define IF_HWASSIST_TSO_V4 0x00200000 /* will do TCP Segment offload for IPv4, IFNET_TSO_IPV4 */
795	#define IF_HWASSIST_TSO_V6 0x00400000 /* will do TCP Segment offload for IPv6, IFNET_TSO_IPV6 */
796	#endif /* PRIVATE */
797
798	#ifdef PRIVATE
799	#define IFXNAMSIZ (IFNAMSIZ + 8) /* external name (name + unit) */
800	#endif
801
802	#ifdef BSD_KERNEL_PRIVATE
803	/*
804	* ifnet is private to BSD portion of kernel
805	*/
806	#include <sys/mcache.h>
807	#include <sys/tree.h>
808	#include <netinet/in.h>
809	#include <net/if_dl.h>
810	#include <net/classq/if_classq.h>
811	#include <net/if_types.h>
812
813	RB_HEAD(ll_reach_tree, if_llreach); / define struct ll_reach_tree /
814
815
816	typedef errno_t (*dlil_input_func)(ifnet_t ifp, mbuf_t m_head,
817	mbuf_t m_tail, const struct ifnet_stat_increment_param *s,
818	boolean_t poll, struct thread *tp);
819	typedef errno_t (*dlil_output_func)(ifnet_t interface, mbuf_t data);
820
821	#define if_name(ifp) ifp->if_xname
822	/*
823	* Structure defining a network interface.
824	*
825	* (Would like to call this struct ``if'', but C isn't PL/1.)
826	*/
827	struct ifnet {
828	/*
829	* Lock (RW or mutex) to protect this data structure (static storage.)
830	*/
831	decl_lck_rw_data(, if_lock);
832	void if_softc; /* pointer to driver state /
833	const char if_name; /* name, e.g. ``en'' or ``lo'' /
834	const char if_xname; /* external name (name + unit) /
835	struct if_description if_desc; / extended description /
836	TAILQ_ENTRY(ifnet) if_link; / all struct ifnets are chained /
837	TAILQ_ENTRY(ifnet) if_detaching_link; / list of detaching ifnets /
838	TAILQ_ENTRY(ifnet) if_ordered_link; / list of ordered ifnets /
839
840	decl_lck_mtx_data(, if_ref_lock)
841	u_int32_t if_refflags; / see IFRF flags below /
842	u_int32_t if_refio; / number of io ops to the underlying driver /
843
844	#define if_list if_link
845	struct ifaddrhead if_addrhead; / linked list of addresses per if /
846	#define if_addrlist if_addrhead
847	struct ifaddr if_lladdr; /* link address (first/permanent) /
848
849	u_int32_t if_qosmarking_mode; / generation to use with NECP clients /
850
851	int if_pcount; / number of promiscuous listeners /
852	struct bpf_if if_bpf; /* packet filter structure /
853	u_short if_index; / numeric abbreviation for this if /
854	short if_unit; / sub-unit for lower level driver /
855	short if_timer; / time 'til if_watchdog called /
856	short if_flags; / up/down, broadcast, etc. /
857	u_int32_t if_eflags; / see <net/if.h> /
858	u_int32_t if_xflags; / see <net/if.h> /
859
860	int if_capabilities; / interface features & capabilities /
861	int if_capenable; / enabled features & capabilities /
862
863	void if_linkmib; /* link-type-specific MIB data /
864	size_t if_linkmiblen; / length of above data /
865
866	struct if_data_internal if_data __attribute__((aligned(`8`)));
867
868	ifnet_family_t if_family; / value assigned by Apple /
869	ifnet_subfamily_t if_subfamily; / value assigned by Apple /
870	uintptr_t if_family_cookie;
871	volatile dlil_input_func if_input_dlil;
872	volatile dlil_output_func if_output_dlil;
873	volatile ifnet_start_func if_start;
874	ifnet_output_func if_output;
875	ifnet_pre_enqueue_func if_pre_enqueue;
876	ifnet_ctl_func if_output_ctl;
877	ifnet_input_poll_func if_input_poll;
878	ifnet_ctl_func if_input_ctl;
879	ifnet_ioctl_func if_ioctl;
880	ifnet_set_bpf_tap if_set_bpf_tap;
881	ifnet_detached_func if_free;
882	ifnet_demux_func if_demux;
883	ifnet_event_func if_event;
884	ifnet_framer_func if_framer_legacy;
885	ifnet_framer_extended_func if_framer;
886	ifnet_add_proto_func if_add_proto;
887	ifnet_del_proto_func if_del_proto;
888	ifnet_check_multi if_check_multi;
889	struct proto_hash_entry *if_proto_hash;
890	void *if_kpi_storage;
891
892	u_int32_t if_flowhash; / interface flow control ID /
893
894	decl_lck_mtx_data(, if_start_lock);
895	u_int32_t if_start_flags; / see IFSF flags below /
896	u_int32_t if_start_req;
897	u_int16_t if_start_active; / output is active /
898	u_int16_t if_start_delayed;
899	u_int16_t if_start_delay_qlen;
900	u_int16_t if_start_delay_idle;
901	u_int64_t if_start_delay_swin;
902	u_int32_t if_start_delay_cnt;
903	u_int32_t if_start_delay_timeout; / nanoseconds /
904	struct timespec if_start_cycle; / restart interval /
905	struct thread *if_start_thread;
906
907	struct ifclassq if_snd; / transmit queue /
908	u_int32_t if_output_sched_model; / tx sched model /
909
910	struct if_bandwidths if_output_bw;
911	struct if_bandwidths if_input_bw;
912
913	struct if_latencies if_output_lt;
914	struct if_latencies if_input_lt;
915
916	decl_lck_mtx_data(, if_flt_lock)
917	u_int32_t if_flt_busy;
918	u_int32_t if_flt_waiters;
919	struct ifnet_filter_head if_flt_head;
920
921	struct ifmultihead if_multiaddrs; / multicast addresses /
922	u_int32_t if_updatemcasts; / mcast addrs need updating /
923	int if_amcount; / # of all-multicast reqs /
924	decl_lck_mtx_data(, if_addrconfig_lock); / for serializing addr config /
925	struct in_multi if_allhostsinm; /* store all-hosts inm for this ifp /
926
927	decl_lck_mtx_data(, if_poll_lock);
928	u_int16_t if_poll_req;
929	u_int16_t if_poll_update; / link update /
930	u_int32_t if_poll_active; / polling is active /
931	struct timespec if_poll_cycle; / poll interval /
932	struct thread *if_poll_thread;
933
934	struct dlil_threading_info *if_inp;
935
936	/ allocated once along with dlil_ifnet and is never freed /
937	thread_call_t if_dt_tcall;
938
939	struct {
940	u_int32_t length;
941	union {
942	u_char buffer[`8`];
943	u_char *ptr;
944	} u;
945	} if_broadcast;
946	#if CONFIG_MACF_NET
947	struct label if_label; /* interface MAC label /
948	#endif
949
950	#if PF
951	struct pfi_kif *if_pf_kif;
952	#endif /* PF */
953
954	decl_lck_mtx_data(, if_cached_route_lock);
955	u_int32_t if_fwd_cacheok;
956	struct route if_fwd_route; / cached forwarding route /
957	struct route if_src_route; / cached ipv4 source route /
958	struct route_in6 if_src_route6; / cached ipv6 source route /
959
960	decl_lck_rw_data(, if_llreach_lock);
961	struct ll_reach_tree if_ll_srcs; / source link-layer tree /
962
963	void if_bridge; /* bridge glue /
964
965	u_int32_t if_want_aggressive_drain;
966	u_int32_t if_idle_flags; / idle flags /
967	u_int32_t if_idle_new_flags; / temporary idle flags /
968	u_int32_t if_idle_new_flags_mask; / temporary mask /
969	u_int32_t if_route_refcnt; / idle: route ref count /
970	u_int32_t if_rt_sendts; / last of a real time packet /
971
972	struct if_traffic_class if_tc __attribute__((aligned(`8`)));
973	#if INET
974	struct igmp_ifinfo if_igi; /* for IGMPv3 /
975	#endif /* INET */
976	#if INET6
977	struct mld_ifinfo if_mli; /* for MLDv2 /
978	#endif /* INET6 */
979
980	struct tcpstat_local if_tcp_stat; /* TCP specific stats /
981	struct udpstat_local if_udp_stat; /* UDP specific stats /
982
983	struct {
984	int32_t level; / cached logging level /
985	u_int32_t flags; / cached logging flags /
986	int32_t category; / cached category /
987	int32_t subcategory; / cached subcategory /
988	} if_log;
989
990	struct {
991	struct ifnet ifp; /* delegated ifp /
992	u_int32_t type; / delegated i/f type /
993	u_int32_t family; / delegated i/f family /
994	u_int32_t subfamily; / delegated i/f sub-family /
995	uint32_t expensive:`1`; / delegated i/f expensive? /
996	} if_delegated;
997
998	uuid_t if_agentids; /* network agents attached to interface /
999	u_int32_t if_agentcount;
1000
1001	volatile uint32_t if_low_power_gencnt;
1002
1003	u_int32_t if_generation; / generation to use with NECP clients /
1004	u_int32_t if_fg_sendts; / last send on a fg socket in seconds /
1005
1006	u_int64_t if_data_threshold;
1007
1008	/ Total bytes in send socket buffer /
1009	int64_t if_sndbyte_total __attribute__ ((aligned(`8`)));
1010	/ Total unsent bytes in send socket buffer /
1011	int64_t if_sndbyte_unsent __attribute__ ((aligned(`8`)));
1012	/ count of times, when there was data to send when sleep is impending /
1013	uint32_t if_unsent_data_cnt;
1014
1015	#if INET
1016	decl_lck_rw_data(, if_inetdata_lock);
1017	void *if_inetdata;
1018	#endif /* INET */
1019	#if INET6
1020	decl_lck_rw_data(, if_inet6data_lock);
1021	void *if_inet6data;
1022	#endif
1023	decl_lck_rw_data(, if_link_status_lock);
1024	struct if_link_status *if_link_status;
1025	struct if_interface_state if_interface_state;
1026	struct if_tcp_ecn_stat *if_ipv4_stat;
1027	struct if_tcp_ecn_stat *if_ipv6_stat;
1028
1029	struct if_lim_perf_stat if_lim_stat;
1030	};
1031
1032	/ Interface event handling declarations /
1033	extern struct eventhandler_lists_ctxt ifnet_evhdlr_ctxt;
1034
1035	typedef enum {
1036	INTF_EVENT_CODE_CREATED,
1037	INTF_EVENT_CODE_REMOVED,
1038	INTF_EVENT_CODE_STATUS_UPDATE,
1039	INTF_EVENT_CODE_IPADDR_ATTACHED,
1040	INTF_EVENT_CODE_IPADDR_DETACHED,
1041	INTF_EVENT_CODE_LLADDR_UPDATE,
1042	INTF_EVENT_CODE_MTU_CHANGED,
1043	INTF_EVENT_CODE_LOW_POWER_UPDATE,
1044	} intf_event_code_t;
1045
1046	typedef void (ifnet_event_fn)(struct* eventhandler_entry_arg, struct ifnet , struct* sockaddr *, intf_event_code_t);
1047	EVENTHANDLER_DECLARE(ifnet_event, ifnet_event_fn);
1048
1049	#define IF_TCP_STATINC(_ifp, _s) do { \
1050	if ((_ifp)->if_tcp_stat != NULL) \
1051	atomic_add_64(&(_ifp)->if_tcp_stat->_s, 1); \
1052	} while (0);
1053
1054	#define IF_UDP_STATINC(_ifp, _s) do { \
1055	if ((_ifp)->if_udp_stat != NULL) \
1056	atomic_add_64(&(_ifp)->if_udp_stat->_s, 1); \
1057	} while (0);
1058
1059	/*
1060	* Valid values for if_refflags
1061	*/
1062	#define IFRF_EMBRYONIC 0x1 /* ifnet is allocated; awaiting attach */
1063	#define IFRF_ATTACHED 0x2 /* ifnet attach is completely done */
1064	#define IFRF_DETACHING 0x4 /* detach has been requested */
1065	#define IFRF_ATTACH_MASK \
1066	(IFRF_EMBRYONIC\|IFRF_ATTACHED\|IFRF_DETACHING)
1067
1068	#define IF_FULLY_ATTACHED(_ifp) \
1069	(((_ifp)->if_refflags & IFRF_ATTACH_MASK) == IFRF_ATTACHED)
1070	/*
1071	* Valid values for if_start_flags
1072	*/
1073	#define IFSF_FLOW_CONTROLLED 0x1 /* flow controlled */
1074
1075	/*
1076	* Structure describing a `cloning' interface.
1077	*/
1078	struct if_clone {
1079	LIST_ENTRY(if_clone) ifc_list; / on list of cloners /
1080	decl_lck_mtx_data(, ifc_mutex); / To serialize clone create/delete /
1081	const char ifc_name; /* name of device, e.g. `vlan' /
1082	size_t ifc_namelen; / length of name /
1083	u_int32_t ifc_minifs; / minimum number of interfaces /
1084	u_int32_t ifc_maxunit; / maximum unit number /
1085	unsigned char ifc_units; /* bitmap to handle units /
1086	u_int32_t ifc_bmlen; / bitmap length /
1087	u_int32_t ifc_zone_max_elem; / Max elements for this zone type /
1088	u_int32_t ifc_softc_size; / size of softc for the device /
1089	struct zone ifc_zone; /* if_clone allocation zone /
1090	int (ifc_create)(struct* if_clone , u_int32_t, void* *);
1091	int (ifc_destroy)(struct* ifnet *);
1092	};
1093
1094	#define IF_CLONE_INITIALIZER(name, create, destroy, minifs, maxunit, zone_max_elem, softc_size) { \
1095	.ifc_list = { NULL, NULL }, \
1096	.ifc_mutex = {}, \
1097	.ifc_name = name, \
1098	.ifc_namelen = (sizeof (name) - 1), \
1099	.ifc_minifs = minifs, \
1100	.ifc_maxunit = maxunit, \
1101	.ifc_units = NULL, \
1102	.ifc_bmlen = 0, \
1103	.ifc_zone_max_elem = zone_max_elem, \
1104	.ifc_softc_size = softc_size, \
1105	.ifc_zone = NULL, \
1106	.ifc_create = create, \
1107	.ifc_destroy = destroy \
1108	}
1109
1110	#define M_CLONE M_IFADDR
1111
1112	/*
1113	* Macros to manipulate ifqueue. Users of these macros are responsible
1114	* for serialization, by holding whatever lock is appropriate for the
1115	* corresponding structure that is referring the ifqueue.
1116	*/
1117	#define IF_QFULL(ifq) ((ifq)->ifq_len >= (ifq)->ifq_maxlen)
1118	#define IF_DROP(ifq) ((ifq)->ifq_drops++)
1119
1120	#define IF_ENQUEUE(ifq, m) do { \
1121	(m)->m_nextpkt = NULL; \
1122	if ((ifq)->ifq_tail == NULL) \
1123	(ifq)->ifq_head = m; \
1124	else \
1125	((struct mbuf*)(ifq)->ifq_tail)->m_nextpkt = m; \
1126	(ifq)->ifq_tail = m; \
1127	(ifq)->ifq_len++; \
1128	} while (0)
1129
1130	#define IF_PREPEND(ifq, m) do { \
1131	(m)->m_nextpkt = (ifq)->ifq_head; \
1132	if ((ifq)->ifq_tail == NULL) \
1133	(ifq)->ifq_tail = (m); \
1134	(ifq)->ifq_head = (m); \
1135	(ifq)->ifq_len++; \
1136	} while (0)
1137
1138	#define IF_DEQUEUE(ifq, m) do { \
1139	(m) = (ifq)->ifq_head; \
1140	if (m != NULL) { \
1141	if (((ifq)->ifq_head = (m)->m_nextpkt) == NULL) \
1142	(ifq)->ifq_tail = NULL; \
1143	(m)->m_nextpkt = NULL; \
1144	(ifq)->ifq_len--; \
1145	} \
1146	} while (0)
1147
1148	#define IF_REMQUEUE(ifq, m) do { \
1149	struct mbuf *_p = (ifq)->ifq_head; \
1150	struct mbuf *_n = (m)->m_nextpkt; \
1151	if ((m) == _p) \
1152	_p = NULL; \
1153	while (_p != NULL) { \
1154	if (_p->m_nextpkt == (m)) \
1155	break; \
1156	_p = _p->m_nextpkt; \
1157	} \
1158	VERIFY(_p != NULL \|\| ((m) == (ifq)->ifq_head)); \
1159	if ((m) == (ifq)->ifq_head) \
1160	(ifq)->ifq_head = _n; \
1161	if ((m) == (ifq)->ifq_tail) \
1162	(ifq)->ifq_tail = _p; \
1163	VERIFY((ifq)->ifq_tail != NULL \|\| (ifq)->ifq_head == NULL); \
1164	VERIFY((ifq)->ifq_len != 0); \
1165	--(ifq)->ifq_len; \
1166	if (_p != NULL) \
1167	_p->m_nextpkt = _n; \
1168	(m)->m_nextpkt = NULL; \
1169	} while (0)
1170
1171	#define IF_DRAIN(ifq) do { \
1172	struct mbuf *_m; \
1173	for (;;) { \
1174	IF_DEQUEUE(ifq, _m); \
1175	if (_m == NULL) \
1176	break; \
1177	m_freem(_m); \
1178	} \
1179	} while (0)
1180
1181	/*
1182	* The ifaddr structure contains information about one address
1183	* of an interface. They are maintained by the different address families,
1184	* are allocated and attached when an address is set, and are linked
1185	* together so all addresses for an interface can be located.
1186	*/
1187	struct ifaddr {
1188	decl_lck_mtx_data(, ifa_lock); / lock for ifaddr /
1189	uint32_t ifa_refcnt; / ref count, use IFA_{ADD,REM}REF /
1190	uint32_t ifa_debug; / debug flags /
1191	struct sockaddr ifa_addr; /* address of interface /
1192	struct sockaddr ifa_dstaddr; /* other end of p-to-p link /
1193	#define ifa_broadaddr ifa_dstaddr /* broadcast address interface */
1194	struct sockaddr ifa_netmask; /* used to determine subnet /
1195	struct ifnet ifa_ifp; /* back-pointer to interface /
1196	TAILQ_ENTRY(ifaddr) ifa_link; / queue macro glue /
1197	void (ifa_rtrequest) /* check or clean routes (+ or -)'d /
1198	(int, struct rtentry , struct* sockaddr *);
1199	uint32_t ifa_flags; / mostly rt_flags for cloning /
1200	int32_t ifa_metric; / cost of going out this interface /
1201	void (ifa_free)(struct* ifaddr ); /* callback fn for freeing /
1202	void (ifa_trace) /* callback fn for tracing refs /
1203	(struct ifaddr , int*);
1204	void (ifa_attached)(struct* ifaddr ); /* callback fn for attaching /
1205	void (ifa_detached)(struct* ifaddr ); /* callback fn for detaching /
1206	#if __arm__ && (__BIGGEST_ALIGNMENT__ > 4)
1207	/ For the newer ARMv7k ABI where 64-bit types are 64-bit aligned, but pointers*
1208	* are 32-bit:
1209	* Align to 64-bit since we cast to this to struct in6_ifaddr, which is
1210	* 64-bit aligned
1211	*/
1212	} __attribute__ ((aligned(`8`)));
1213	#else
1214	};
1215	#endif
1216
1217
1218	/*
1219	* Valid values for ifa_flags
1220	*/
1221	#define IFA_ROUTE RTF_UP /* route installed (0x1) */
1222	#define IFA_CLONING RTF_CLONING /* (0x100) */
1223
1224	/*
1225	* Valid values for ifa_debug
1226	*/
1227	#define IFD_ATTACHED 0x1 /* attached to list */
1228	#define IFD_ALLOC 0x2 /* dynamically allocated */
1229	#define IFD_DEBUG 0x4 /* has debugging info */
1230	#define IFD_LINK 0x8 /* link address */
1231	#define IFD_TRASHED 0x10 /* in trash list */
1232	#define IFD_DETACHING 0x20 /* detach is in progress */
1233	#define IFD_NOTREADY 0x40 /* embryonic; not yet ready */
1234
1235	#define IFA_LOCK_ASSERT_HELD(_ifa) \
1236	LCK_MTX_ASSERT(&(_ifa)->ifa_lock, LCK_MTX_ASSERT_OWNED)
1237
1238	#define IFA_LOCK_ASSERT_NOTHELD(_ifa) \
1239	LCK_MTX_ASSERT(&(_ifa)->ifa_lock, LCK_MTX_ASSERT_NOTOWNED)
1240
1241	#define IFA_LOCK(_ifa) \
1242	lck_mtx_lock(&(_ifa)->ifa_lock)
1243
1244	#define IFA_LOCK_SPIN(_ifa) \
1245	lck_mtx_lock_spin(&(_ifa)->ifa_lock)
1246
1247	#define IFA_CONVERT_LOCK(_ifa) do { \
1248	IFA_LOCK_ASSERT_HELD(_ifa); \
1249	lck_mtx_convert_spin(&(_ifa)->ifa_lock); \
1250	} while (0)
1251
1252	#define IFA_UNLOCK(_ifa) \
1253	lck_mtx_unlock(&(_ifa)->ifa_lock)
1254
1255	#define IFA_ADDREF(_ifa) \
1256	ifa_addref(_ifa, 0)
1257
1258	#define IFA_ADDREF_LOCKED(_ifa) \
1259	ifa_addref(_ifa, 1)
1260
1261	#define IFA_REMREF(_ifa) do { \
1262	(void) ifa_remref(_ifa, 0); \
1263	} while (0)
1264
1265	#define IFA_REMREF_LOCKED(_ifa) \
1266	ifa_remref(_ifa, 1)
1267
1268	/*
1269	* Multicast address structure. This is analogous to the ifaddr
1270	* structure except that it keeps track of multicast addresses.
1271	* Also, the request count here is a count of requests for this
1272	* address, not a count of pointers to this structure; anonymous
1273	* membership(s) holds one outstanding request count.
1274	*/
1275	struct ifmultiaddr {
1276	decl_lck_mtx_data(, ifma_lock);
1277	u_int32_t ifma_refcount; / reference count /
1278	u_int32_t ifma_anoncnt; / # of anonymous requests /
1279	u_int32_t ifma_reqcnt; / total requests for this address /
1280	u_int32_t ifma_debug; / see ifa_debug flags /
1281	u_int32_t ifma_flags; / see below /
1282	LIST_ENTRY(ifmultiaddr) ifma_link; / queue macro glue /
1283	struct sockaddr ifma_addr; /* address this membership is for /
1284	struct ifmultiaddr ifma_ll; /* link-layer translation, if any /
1285	struct ifnet ifma_ifp; /* back-pointer to interface /
1286	void ifma_protospec; /* protocol-specific state, if any /
1287	void (ifma_trace) /* callback fn for tracing refs /
1288	(struct ifmultiaddr , int*);
1289	};
1290
1291	/*
1292	* Values for ifma_flags
1293	*/
1294	#define IFMAF_ANONYMOUS 0x1 /* has anonymous request ref(s) held */
1295
1296	#define IFMA_LOCK_ASSERT_HELD(_ifma) \
1297	LCK_MTX_ASSERT(&(_ifma)->ifma_lock, LCK_MTX_ASSERT_OWNED)
1298
1299	#define IFMA_LOCK_ASSERT_NOTHELD(_ifma) \
1300	LCK_MTX_ASSERT(&(_ifma)->ifma_lock, LCK_MTX_ASSERT_NOTOWNED)
1301
1302	#define IFMA_LOCK(_ifma) \
1303	lck_mtx_lock(&(_ifma)->ifma_lock)
1304
1305	#define IFMA_LOCK_SPIN(_ifma) \
1306	lck_mtx_lock_spin(&(_ifma)->ifma_lock)
1307
1308	#define IFMA_CONVERT_LOCK(_ifma) do { \
1309	IFMA_LOCK_ASSERT_HELD(_ifma); \
1310	lck_mtx_convert_spin(&(_ifma)->ifma_lock); \
1311	} while (0)
1312
1313	#define IFMA_UNLOCK(_ifma) \
1314	lck_mtx_unlock(&(_ifma)->ifma_lock)
1315
1316	#define IFMA_ADDREF(_ifma) \
1317	ifma_addref(_ifma, 0)
1318
1319	#define IFMA_ADDREF_LOCKED(_ifma) \
1320	ifma_addref(_ifma, 1)
1321
1322	#define IFMA_REMREF(_ifma) \
1323	ifma_remref(_ifma)
1324
1325	/*
1326	* Indicate whether or not the immediate interface, or the interface delegated
1327	* by it, is a cellular interface (IFT_CELLULAR). Delegated interface type is
1328	* set/cleared along with the delegated ifp; we cache the type for performance
1329	* to avoid dereferencing delegated ifp each time.
1330	*
1331	* Note that this is meant to be used only for accounting and policy purposes;
1332	* certain places need to explicitly know the immediate interface type, and
1333	* this macro should not be used there.
1334	*
1335	* The test is done against IFT_CELLULAR instead of IFNET_FAMILY_CELLULAR to
1336	* handle certain cases where the family isn't set to the latter.
1337	*/
1338	#define IFNET_IS_CELLULAR(_ifp) \
1339	((_ifp)->if_type == IFT_CELLULAR \|\| \
1340	(_ifp)->if_delegated.type == IFT_CELLULAR)
1341
1342	/*
1343	* Indicate whether or not the immediate interface, or the interface delegated
1344	* by it, is an ETHERNET interface.
1345	*/
1346	#define IFNET_IS_ETHERNET(_ifp) \
1347	((_ifp)->if_family == IFNET_FAMILY_ETHERNET \|\| \
1348	(_ifp)->if_delegated.family == IFNET_FAMILY_ETHERNET)
1349	/*
1350	* Indicate whether or not the immediate interface, or the interface delegated
1351	* by it, is a Wi-Fi interface (IFNET_SUBFAMILY_WIFI). Delegated interface
1352	* subfamily is set/cleared along with the delegated ifp; we cache the subfamily
1353	* for performance to avoid dereferencing delegated ifp each time.
1354	*
1355	* Note that this is meant to be used only for accounting and policy purposes;
1356	* certain places need to explicitly know the immediate interface type, and
1357	* this macro should not be used there.
1358	*
1359	* The test is done against IFNET_SUBFAMILY_WIFI as the family may be set to
1360	* IFNET_FAMILY_ETHERNET (as well as type to IFT_ETHER) which is too generic.
1361	*/
1362	#define IFNET_IS_WIFI(_ifp) \
1363	((_ifp)->if_subfamily == IFNET_SUBFAMILY_WIFI \|\| \
1364	(_ifp)->if_delegated.subfamily == IFNET_SUBFAMILY_WIFI)
1365
1366	/*
1367	* Indicate whether or not the immediate interface, or the interface delegated
1368	* by it, is a Wired interface (several families). Delegated interface
1369	* family is set/cleared along with the delegated ifp; we cache the family
1370	* for performance to avoid dereferencing delegated ifp each time.
1371	*
1372	* Note that this is meant to be used only for accounting and policy purposes;
1373	* certain places need to explicitly know the immediate interface type, and
1374	* this macro should not be used there.
1375	*/
1376	#define IFNET_IS_WIRED(_ifp) \
1377	((_ifp)->if_family == IFNET_FAMILY_ETHERNET \|\| \
1378	(_ifp)->if_delegated.family == IFNET_FAMILY_ETHERNET \|\| \
1379	(_ifp)->if_family == IFNET_FAMILY_FIREWIRE \|\| \
1380	(_ifp)->if_delegated.family == IFNET_FAMILY_FIREWIRE)
1381
1382	/*
1383	* Indicate whether or not the immediate WiFi interface is on an infrastructure
1384	* network
1385	*/
1386	#define IFNET_IS_WIFI_INFRA(_ifp) \
1387	((_ifp)->if_family == IFNET_FAMILY_ETHERNET && \
1388	(_ifp)->if_subfamily == IFNET_SUBFAMILY_WIFI && \
1389	!((_ifp)->if_eflags & IFEF_AWDL))
1390
1391	/*
1392	* Indicate whether or not the immediate interface, or the interface delegated
1393	* by it, is marked as expensive. The delegated interface is set/cleared
1394	* along with the delegated ifp; we cache the flag for performance to avoid
1395	* dereferencing delegated ifp each time.
1396	*
1397	* Note that this is meant to be used only for policy purposes.
1398	*/
1399	#define IFNET_IS_EXPENSIVE(_ifp) \
1400	((_ifp)->if_eflags & IFEF_EXPENSIVE \|\| \
1401	(_ifp)->if_delegated.expensive)
1402
1403	#define IFNET_IS_LOW_POWER(_ifp) \
1404	(if_low_power_restricted != 0 && \
1405	((_ifp)->if_xflags & IFXF_LOW_POWER) \|\| \
1406	((_ifp)->if_delegated.ifp != NULL && \
1407	((_ifp)->if_delegated.ifp->if_xflags & IFXF_LOW_POWER)))
1408
1409	/*
1410	* We don't support AWDL interface delegation.
1411	*/
1412	#define IFNET_IS_AWDL_RESTRICTED(_ifp) \
1413	(((_ifp)->if_eflags & (IFEF_AWDL\|IFEF_AWDL_RESTRICTED)) == \
1414	(IFEF_AWDL\|IFEF_AWDL_RESTRICTED))
1415
1416	#define IFNET_IS_INTCOPROC(_ifp) \
1417	((_ifp)->if_family == IFNET_FAMILY_ETHERNET && \
1418	(_ifp)->if_subfamily == IFNET_SUBFAMILY_INTCOPROC)
1419
1420	extern struct ifnethead ifnet_head;
1421	extern struct ifnethead ifnet_ordered_head;
1422	extern struct ifnet **ifindex2ifnet;
1423	extern u_int32_t if_sndq_maxlen;
1424	extern u_int32_t if_rcvq_maxlen;
1425	extern int if_index;
1426	extern struct ifaddr **ifnet_addrs;
1427	extern lck_attr_t *ifa_mtx_attr;
1428	extern lck_grp_t *ifa_mtx_grp;
1429	extern lck_grp_t *ifnet_lock_group;
1430	extern lck_attr_t *ifnet_lock_attr;
1431	extern ifnet_t lo_ifp;
1432
1433	extern int if_addmulti(struct ifnet , const* struct sockaddr *,
1434	struct ifmultiaddr **);
1435	extern int if_addmulti_anon(struct ifnet , const* struct sockaddr *,
1436	struct ifmultiaddr **);
1437	extern int if_allmulti(struct ifnet , int*);
1438	extern int if_delmulti(struct ifnet , const* struct sockaddr *);
1439	extern int if_delmulti_ifma(struct ifmultiaddr *);
1440	extern int if_delmulti_anon(struct ifnet , const* struct sockaddr *);
1441	extern void if_down(struct ifnet *);
1442	extern int if_down_all(void);
1443	extern void if_up(struct ifnet *);
1444	__private_extern__ void if_updown(struct ifnet ifp, int* up);
1445	extern int ifioctl(struct socket , u_long, caddr_t, struct* proc *);
1446	extern int ifioctllocked(struct socket , u_long, caddr_t, struct* proc *);
1447	extern struct ifnet ifunit(const* char *);
1448	extern struct ifnet ifunit_ref(const* char *);
1449	extern int ifunit_extract(const char src, char* dst, size_t dstlen, int* *unit);
1450	extern struct ifnet if_withname(struct* sockaddr *);
1451	extern void if_qflush(struct ifnet , int*);
1452	extern void if_qflush_sc(struct ifnet *, mbuf_svc_class_t, u_int32_t,
1453	u_int32_t , u_int32_t , int);
1454
1455	extern struct if_clone if_clone_lookup(const* char , u_int32_t );
1456	extern int if_clone_attach(struct if_clone *);
1457	extern void if_clone_detach(struct if_clone *);
1458	extern void if_clone_softc_allocate(const* struct if_clone *);
1459	extern void if_clone_softc_deallocate(const struct if_clone , void* *);
1460	extern u_int32_t if_functional_type(struct ifnet *, bool);
1461
1462	extern errno_t if_mcasts_update(struct ifnet *);
1463
1464	typedef enum {
1465	IFNET_LCK_ASSERT_EXCLUSIVE, / RW: held as writer /
1466	IFNET_LCK_ASSERT_SHARED, / RW: held as reader /
1467	IFNET_LCK_ASSERT_OWNED, / RW: writer/reader, MTX: held /
1468	IFNET_LCK_ASSERT_NOTOWNED / not held /
1469	} ifnet_lock_assert_t;
1470
1471	#define IF_LLADDR(_ifp) \
1472	(LLADDR(SDL(((_ifp)->if_lladdr)->ifa_addr)))
1473
1474	#define IF_INDEX_IN_RANGE(_ind_) ((_ind_) > 0 && \
1475	(unsigned int)(_ind_) <= (unsigned int)if_index)
1476
1477	__private_extern__ void ifnet_lock_assert(struct ifnet *, ifnet_lock_assert_t);
1478	__private_extern__ void ifnet_lock_shared(struct ifnet *ifp);
1479	__private_extern__ void ifnet_lock_exclusive(struct ifnet *ifp);
1480	__private_extern__ void ifnet_lock_done(struct ifnet *ifp);
1481
1482	#if INET
1483	__private_extern__ void if_inetdata_lock_shared(struct ifnet *ifp);
1484	__private_extern__ void if_inetdata_lock_exclusive(struct ifnet *ifp);
1485	__private_extern__ void if_inetdata_lock_done(struct ifnet *ifp);
1486	#endif
1487
1488	#if INET6
1489	__private_extern__ void if_inet6data_lock_shared(struct ifnet *ifp);
1490	__private_extern__ void if_inet6data_lock_exclusive(struct ifnet *ifp);
1491	__private_extern__ void if_inet6data_lock_done(struct ifnet *ifp);
1492	#endif
1493
1494	__private_extern__ void ifnet_head_lock_shared(void);
1495	__private_extern__ void ifnet_head_lock_exclusive(void);
1496	__private_extern__ void ifnet_head_done(void);
1497	__private_extern__ void ifnet_head_assert_exclusive(void);
1498
1499	__private_extern__ errno_t ifnet_set_idle_flags_locked(ifnet_t, u_int32_t,
1500	u_int32_t);
1501	__private_extern__ int ifnet_is_attached(struct ifnet , int* refio);
1502	__private_extern__ void ifnet_incr_iorefcnt(struct ifnet *);
1503	__private_extern__ void ifnet_decr_iorefcnt(struct ifnet *);
1504	__private_extern__ void ifnet_set_start_cycle(struct ifnet *,
1505	struct timespec *);
1506	__private_extern__ void ifnet_set_poll_cycle(struct ifnet *,
1507	struct timespec *);
1508
1509	__private_extern__ void if_attach_ifa(struct ifnet , struct* ifaddr *);
1510	__private_extern__ void if_attach_link_ifa(struct ifnet , struct* ifaddr *);
1511	__private_extern__ void if_detach_ifa(struct ifnet , struct* ifaddr *);
1512	__private_extern__ void if_detach_link_ifa(struct ifnet , struct* ifaddr *);
1513
1514	__private_extern__ void dlil_if_lock(void);
1515	__private_extern__ void dlil_if_unlock(void);
1516	__private_extern__ void dlil_if_lock_assert(void);
1517
1518	extern struct ifaddr ifa_ifwithaddr(const* struct sockaddr *);
1519	extern struct ifaddr ifa_ifwithaddr_locked(const* struct sockaddr *);
1520	extern struct ifaddr ifa_ifwithaddr_scoped(const* struct sockaddr *,
1521	unsigned int);
1522	extern struct ifaddr ifa_ifwithaddr_scoped_locked(const* struct sockaddr *,
1523	unsigned int);
1524	extern struct ifaddr ifa_ifwithdstaddr(const* struct sockaddr *);
1525	extern struct ifaddr ifa_ifwithnet(const* struct sockaddr *);
1526	extern struct ifaddr ifa_ifwithnet_scoped(const* struct sockaddr *,
1527	unsigned int);
1528	extern struct ifaddr ifa_ifwithroute(int, const* struct sockaddr *,
1529	const struct sockaddr *);
1530	extern struct ifaddr ifa_ifwithroute_locked(int, const* struct sockaddr *,
1531	const struct sockaddr *);
1532	extern struct ifaddr ifa_ifwithroute_scoped_locked(int*,
1533	const struct sockaddr , const* struct sockaddr , unsigned* int);
1534	extern struct ifaddr ifaof_ifpforaddr_select(const* struct sockaddr , struct* ifnet *);
1535	extern struct ifaddr ifaof_ifpforaddr(const* struct sockaddr , struct* ifnet *);
1536	__private_extern__ struct ifaddr ifa_ifpgetprimary(struct* ifnet , int*);
1537	extern void ifa_addref(struct ifaddr , int*);
1538	extern struct ifaddr ifa_remref(struct* ifaddr , int*);
1539	extern void ifa_lock_init(struct ifaddr *);
1540	extern void ifa_lock_destroy(struct ifaddr *);
1541	extern void ifma_addref(struct ifmultiaddr , int*);
1542	extern void ifma_remref(struct ifmultiaddr *);
1543
1544	extern void ifa_init(void);
1545
1546	__private_extern__ struct in_ifaddr ifa_foraddr(unsigned* int);
1547	__private_extern__ struct in_ifaddr ifa_foraddr_scoped(unsigned* int,
1548	unsigned int);
1549
1550	struct ifreq;
1551	extern errno_t ifnet_getset_opportunistic(struct ifnet *, u_long,
1552	struct ifreq , struct* proc *);
1553	extern int ifnet_get_throttle(struct ifnet , u_int32_t );
1554	extern int ifnet_set_throttle(struct ifnet *, u_int32_t);
1555	extern errno_t ifnet_getset_log(struct ifnet *, u_long,
1556	struct ifreq , struct* proc *);
1557	extern int ifnet_set_log(struct ifnet *, int32_t, uint32_t, int32_t, int32_t);
1558	extern int ifnet_get_log(struct ifnet , int32_t , uint32_t , int32_t ,
1559	int32_t *);
1560	extern int ifnet_notify_address(struct ifnet , int*);
1561	extern void ifnet_notify_data_threshold(struct ifnet *);
1562
1563	#define IF_AFDATA_RLOCK if_afdata_rlock
1564	#define IF_AFDATA_RUNLOCK if_afdata_unlock
1565	#define IF_AFDATA_WLOCK if_afdata_wlock
1566	#define IF_AFDATA_WUNLOCK if_afdata_unlock
1567	#define IF_AFDATA_WLOCK_ASSERT if_afdata_wlock_assert
1568	#define IF_AFDATA_LOCK_ASSERT if_afdata_lock_assert
1569	#define IF_AFDATA_UNLOCK_ASSERT if_afdata_unlock_assert
1570
1571	static inline void
1572	if_afdata_rlock (struct ifnet ifp, int* af)
1573	{
1574	switch (af) {
1575	#if INET
1576	case AF_INET:
1577	lck_rw_lock_shared(&ifp->if_inetdata_lock);
1578	break;
1579	#endif
1580	#if INET6
1581	case AF_INET6:
1582	lck_rw_lock_shared(&ifp->if_inet6data_lock);
1583	break;
1584	#endif
1585	default:
1586	VERIFY(`0`);
1587	/ NOTREACHED /
1588	}
1589	return;
1590	}
1591
1592	static inline void
1593	if_afdata_runlock (struct ifnet ifp, int* af)
1594	{
1595	switch (af) {
1596	#if INET
1597	case AF_INET:
1598	lck_rw_done(&ifp->if_inetdata_lock);
1599	break;
1600	#endif
1601	#if INET6
1602	case AF_INET6:
1603	lck_rw_done(&ifp->if_inet6data_lock);
1604	break;
1605	#endif
1606	default:
1607	VERIFY(`0`);
1608	/ NOTREACHED /
1609	}
1610	return;
1611	}
1612
1613	static inline void
1614	if_afdata_wlock (struct ifnet ifp, int* af)
1615	{
1616	switch (af) {
1617	#if INET
1618	case AF_INET:
1619	lck_rw_lock_exclusive(&ifp->if_inetdata_lock);
1620	break;
1621	#endif
1622	#if INET6
1623	case AF_INET6:
1624	lck_rw_lock_exclusive(&ifp->if_inet6data_lock);
1625	break;
1626	#endif
1627	default:
1628	VERIFY(`0`);
1629	/ NOTREACHED /
1630	}
1631	return;
1632	}
1633
1634	static inline void
1635	if_afdata_unlock (struct ifnet ifp, int* af)
1636	{
1637	switch (af) {
1638	#if INET
1639	case AF_INET:
1640	lck_rw_done(&ifp->if_inetdata_lock);
1641	break;
1642	#endif
1643	#if INET6
1644	case AF_INET6:
1645	lck_rw_done(&ifp->if_inet6data_lock);
1646	break;
1647	#endif
1648	default:
1649	VERIFY(`0`);
1650	/ NOTREACHED /
1651	}
1652	return;
1653	}
1654
1655	static inline void
1656	if_afdata_wlock_assert (struct ifnet ifp, int* af)
1657	{
1658	#if !MACH_ASSERT
1659	#pragma unused(ifp)
1660	#endif
1661	switch (af) {
1662	#if INET
1663	case AF_INET:
1664	LCK_RW_ASSERT(&ifp->if_inetdata_lock, LCK_RW_ASSERT_EXCLUSIVE);
1665	break;
1666	#endif
1667	#if INET6
1668	case AF_INET6:
1669	LCK_RW_ASSERT(&ifp->if_inet6data_lock, LCK_RW_ASSERT_EXCLUSIVE);
1670	break;
1671	#endif
1672	default:
1673	VERIFY(`0`);
1674	/ NOTREACHED /
1675	}
1676	return;
1677	}
1678
1679	static inline void
1680	if_afdata_unlock_assert (struct ifnet ifp, int* af)
1681	{
1682	#if !MACH_ASSERT
1683	#pragma unused(ifp)
1684	#endif
1685	switch (af) {
1686	#if INET
1687	case AF_INET:
1688	LCK_RW_ASSERT(&ifp->if_inetdata_lock, LCK_RW_ASSERT_NOTHELD);
1689	break;
1690	#endif
1691	#if INET6
1692	case AF_INET6:
1693	LCK_RW_ASSERT(&ifp->if_inet6data_lock, LCK_RW_ASSERT_NOTHELD);
1694	break;
1695	#endif
1696	default:
1697	VERIFY(`0`);
1698	/ NOTREACHED /
1699	}
1700	return;
1701	}
1702
1703	static inline void
1704	if_afdata_lock_assert (struct ifnet ifp, int* af)
1705	{
1706	#if !MACH_ASSERT
1707	#pragma unused(ifp)
1708	#endif
1709	switch (af) {
1710	#if INET
1711	case AF_INET:
1712	LCK_RW_ASSERT(&ifp->if_inetdata_lock, LCK_RW_ASSERT_HELD);
1713	break;
1714	#endif
1715	#if INET6
1716	case AF_INET6:
1717	LCK_RW_ASSERT(&ifp->if_inet6data_lock, LCK_RW_ASSERT_HELD);
1718	break;
1719	#endif
1720	default:
1721	VERIFY(`0`);
1722	/ NOTREACHED /
1723	}
1724	return;
1725	}
1726
1727	#if INET6
1728	struct in6_addr;
1729	__private_extern__ struct in6_ifaddr ifa_foraddr6(struct* in6_addr *);
1730	__private_extern__ struct in6_ifaddr ifa_foraddr6_scoped(struct* in6_addr *,
1731	unsigned int);
1732	#endif /* INET6 */
1733
1734	__private_extern__ void if_data_internal_to_if_data(struct ifnet *ifp,
1735	const struct if_data_internal if_data_int, struct* if_data *if_data);
1736	__private_extern__ void if_data_internal_to_if_data64(struct ifnet *ifp,
1737	const struct if_data_internal if_data_int, struct* if_data64 *if_data64);
1738	__private_extern__ void if_copy_traffic_class(struct ifnet *ifp,
1739	struct if_traffic_class *if_tc);
1740	__private_extern__ void if_copy_data_extended(struct ifnet *ifp,
1741	struct if_data_extended *if_de);
1742	__private_extern__ void if_copy_packet_stats(struct ifnet *ifp,
1743	struct if_packet_stats *if_ps);
1744	__private_extern__ void if_copy_rxpoll_stats(struct ifnet *ifp,
1745	struct if_rxpoll_stats *if_rs);
1746
1747	__private_extern__ struct rtentry ifnet_cached_rtlookup_inet(struct* ifnet *,
1748	struct in_addr);
1749	#if INET6
1750	__private_extern__ struct rtentry ifnet_cached_rtlookup_inet6(struct* ifnet *,
1751	struct in6_addr *);
1752	#endif /* INET6 */
1753
1754	__private_extern__ u_int32_t if_get_protolist(struct ifnet * ifp,
1755	u_int32_t *protolist, u_int32_t count);
1756	__private_extern__ void if_free_protolist(u_int32_t *list);
1757	__private_extern__ errno_t if_state_update(struct ifnet *,
1758	struct if_interface_state *);
1759	__private_extern__ void if_get_state(struct ifnet *,
1760	struct if_interface_state *);
1761	__private_extern__ errno_t if_probe_connectivity(struct ifnet *ifp,
1762	u_int32_t conn_probe);
1763	__private_extern__ void if_lqm_update(struct ifnet , int32_t, int*);
1764	__private_extern__ void ifnet_update_sndq(struct ifclassq *, cqev_t);
1765	__private_extern__ void ifnet_update_rcv(struct ifnet *, cqev_t);
1766
1767	__private_extern__ void ifnet_flowadv(uint32_t);
1768
1769	__private_extern__ errno_t ifnet_set_input_bandwidths(struct ifnet *,
1770	struct if_bandwidths *);
1771	__private_extern__ errno_t ifnet_set_output_bandwidths(struct ifnet *,
1772	struct if_bandwidths *, boolean_t);
1773	__private_extern__ u_int64_t ifnet_output_linkrate(struct ifnet *);
1774	__private_extern__ u_int64_t ifnet_input_linkrate(struct ifnet *);
1775
1776	__private_extern__ errno_t ifnet_set_input_latencies(struct ifnet *,
1777	struct if_latencies *);
1778	__private_extern__ errno_t ifnet_set_output_latencies(struct ifnet *,
1779	struct if_latencies *, boolean_t);
1780
1781	__private_extern__ void ifnet_clear_netagent(uuid_t);
1782
1783	__private_extern__ int ifnet_set_netsignature(struct ifnet *, uint8_t,
1784	uint8_t, uint16_t, uint8_t *);
1785	__private_extern__ int ifnet_get_netsignature(struct ifnet *, uint8_t,
1786	uint8_t , uint16_t , uint8_t *);
1787
1788	#if INET6
1789	struct ipv6_prefix;
1790	__private_extern__ int ifnet_set_nat64prefix(struct ifnet *,
1791	struct ipv6_prefix *);
1792	__private_extern__ int ifnet_get_nat64prefix(struct ifnet *,
1793	struct ipv6_prefix *);
1794	#endif
1795
1796	/ Required exclusive ifnet_head lock /
1797	__private_extern__ void ifnet_remove_from_ordered_list(struct ifnet *);
1798
1799	__private_extern__ void ifnet_increment_generation(struct ifnet *);
1800	__private_extern__ u_int32_t ifnet_get_generation(struct ifnet *);
1801
1802	/ Adding and deleting netagents will take ifnet lock /
1803	__private_extern__ int if_add_netagent(struct ifnet *, uuid_t);
1804	__private_extern__ int if_delete_netagent(struct ifnet *, uuid_t);
1805	__private_extern__ boolean_t if_check_netagent(struct ifnet *, uuid_t);
1806
1807
1808	extern int if_set_qosmarking_mode(struct ifnet *, u_int32_t);
1809	__private_extern__ uint32_t ifnet_mbuf_packetpreamblelen(struct ifnet *);
1810	__private_extern__ void intf_event_enqueue_nwk_wq_entry(struct ifnet *ifp,
1811	struct sockaddr *addrp, uint32_t intf_event_code);
1812	__private_extern__ void ifnet_update_stats_per_flow(struct ifnet_stats_per_flow *,
1813	struct ifnet *);
1814	#if !CONFIG_EMBEDDED
1815	__private_extern__ errno_t ifnet_framer_stub(struct ifnet , struct* mbuf **,
1816	const struct sockaddr , const* char , const* char , u_int32_t ,
1817	u_int32_t *);
1818	#endif /* !CONFIG_EMBEDDED */
1819	__private_extern__ void ifnet_enqueue_multi_setup(struct ifnet *, uint16_t,
1820	uint16_t);
1821	__private_extern__ errno_t ifnet_enqueue_mbuf(struct ifnet , struct* mbuf *,
1822	boolean_t, boolean_t *);
1823
1824	extern int if_low_power_verbose;
1825	extern int if_low_power_restricted;
1826	extern void if_low_power_evhdlr_init(void);
1827	extern int if_set_low_power(struct ifnet *, bool);
1828
1829	#endif /* BSD_KERNEL_PRIVATE */
1830	#ifdef XNU_KERNEL_PRIVATE
1831	/ for uuid.c /
1832	__private_extern__ int uuid_get_ethernet(u_int8_t *);
1833	#endif /* XNU_KERNEL_PRIVATE */
1834	#endif /* !_NET_IF_VAR_H_ */
1835

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