mbuf.h source code [codebrowser/bsd/sys/mbuf.h]

1	/*
2	* Copyright (c) 1999-2018 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	/ Copyright (c) 1998, 1999 Apple Computer, Inc. All Rights Reserved /
29	/ Copyright (c) 1995 NeXT Computer, Inc. All Rights Reserved /
30	/*
31	* Mach Operating System
32	* Copyright (c) 1987 Carnegie-Mellon University
33	* All rights reserved. The CMU software License Agreement specifies
34	* the terms and conditions for use and redistribution.
35	*/
36	/*
37	* Copyright (c) 1994 NeXT Computer, Inc. All rights reserved.
38	*
39	* Copyright (c) 1982, 1986, 1988 Regents of the University of California.
40	* All rights reserved.
41	*
42	* Redistribution and use in source and binary forms, with or without
43	* modification, are permitted provided that the following conditions
44	* are met:
45	* 1. Redistributions of source code must retain the above copyright
46	* notice, this list of conditions and the following disclaimer.
47	* 2. Redistributions in binary form must reproduce the above copyright
48	* notice, this list of conditions and the following disclaimer in the
49	* documentation and/or other materials provided with the distribution.
50	* 3. All advertising materials mentioning features or use of this software
51	* must display the following acknowledgement:
52	* This product includes software developed by the University of
53	* California, Berkeley and its contributors.
54	* 4. Neither the name of the University nor the names of its contributors
55	* may be used to endorse or promote products derived from this software
56	* without specific prior written permission.
57	*
58	* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
59	* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
60	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
61	* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
62	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
63	* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
64	* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
65	* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
66	* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
67	* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
68	* SUCH DAMAGE.
69	*
70	* @(#)mbuf.h 8.3 (Berkeley) 1/21/94
71	*/
72	/*
73	* NOTICE: This file was modified by SPARTA, Inc. in 2005 to introduce
74	* support for mandatory and extensible security protections. This notice
75	* is included in support of clause 2.2 (b) of the Apple Public License,
76	* Version 2.0.
77	*/
78
79	#ifndef _SYS_MBUF_H_
80	#define _SYS_MBUF_H_
81
82	#include <sys/appleapiopts.h>
83	#include <sys/cdefs.h>
84	#include <sys/_types/_u_int32_t.h> /* u_int32_t */
85	#include <sys/_types/_u_int64_t.h> /* u_int64_t */
86	#include <sys/_types/_u_short.h> /* u_short */
87
88	#ifdef KERNEL
89	#include <sys/kpi_mbuf.h>
90	#endif
91
92	#ifdef XNU_KERNEL_PRIVATE
93	#include <sys/lock.h>
94	#include <sys/queue.h>
95	#include <machine/endian.h>
96	/*
97	* Mbufs are of a single size, MSIZE (machine/param.h), which
98	* includes overhead. An mbuf may add a single "mbuf cluster" of size
99	* MCLBYTES/MBIGCLBYTES/M16KCLBYTES (also in machine/param.h), which has
100	* no additional overhead and is used instead of the internal data area;
101	* this is done when at least MINCLSIZE of data must be stored.
102	*/
103
104	/*
105	* The following _MLEN and _MHLEN macros are private to xnu. Private code
106	* that are outside of xnu must use the mbuf_get_{mlen,mhlen} routines since
107	* the sizes of the structures are dependent upon specific xnu configs.
108	*/
109	#define _MLEN (MSIZE - sizeof(struct m_hdr)) /* normal data len */
110	#define _MHLEN (_MLEN - sizeof(struct pkthdr)) /* data len w/pkthdr */
111
112	#define NMBPGSHIFT (PAGE_SHIFT - MSIZESHIFT)
113	#define NMBPG (1 << NMBPGSHIFT) /* # of mbufs per page */
114
115	#define NCLPGSHIFT (PAGE_SHIFT - MCLSHIFT)
116	#define NCLPG (1 << NCLPGSHIFT) /* # of cl per page */
117
118	#define NBCLPGSHIFT (PAGE_SHIFT - MBIGCLSHIFT)
119	#define NBCLPG (1 << NBCLPGSHIFT) /* # of big cl per page */
120
121	#define NMBPCLSHIFT (MCLSHIFT - MSIZESHIFT)
122	#define NMBPCL (1 << NMBPCLSHIFT) /* # of mbufs per cl */
123
124	#define NCLPJCLSHIFT (M16KCLSHIFT - MCLSHIFT)
125	#define NCLPJCL (1 << NCLPJCLSHIFT) /* # of cl per jumbo cl */
126
127	#define NCLPBGSHIFT (MBIGCLSHIFT - MCLSHIFT)
128	#define NCLPBG (1 << NCLPBGSHIFT) /* # of cl per big cl */
129
130	#define NMBPBGSHIFT (MBIGCLSHIFT - MSIZESHIFT)
131	#define NMBPBG (1 << NMBPBGSHIFT) /* # of mbufs per big cl */
132
133	/*
134	* Macros for type conversion
135	* mtod(m,t) - convert mbuf pointer to data pointer of correct type
136	* mtodo(m, o) -- Same as above but with offset 'o' into data.
137	* dtom(x) - convert data pointer within mbuf to mbuf pointer (XXX)
138	*/
139	#define mtod(m, t) ((t)m_mtod(m))
140	#define mtodo(m, o) ((void )(mtod(m, uint8_t ) + (o)))
141	#define dtom(x) m_dtom(x)
142
143	/ header at beginning of each mbuf: /
144	struct m_hdr {
145	struct mbuf mh_next; /* next buffer in chain /
146	struct mbuf mh_nextpkt; /* next chain in queue/record /
147	caddr_t mh_data; / location of data /
148	int32_t mh_len; / amount of data in this mbuf /
149	u_int16_t mh_type; / type of data in this mbuf /
150	u_int16_t mh_flags; / flags; see below /
151	#if __arm__ && (__BIGGEST_ALIGNMENT__ > 4)
152	/ This is needed because of how _MLEN is defined and used. Ideally, _MLEN*
153	* should be defined using the offsetof(struct mbuf, M_dat), since there is
154	* no guarantee that mbuf.M_dat will start where mbuf.m_hdr ends. The compiler
155	* may (and does in the armv7k case) insert padding between m_hdr and M_dat in
156	* mbuf. We cannot easily use offsetof, however, since _MLEN is referenced
157	* in the definition of mbuf.
158	*/
159	} __attribute__((aligned(`8`)));
160	#else
161	};
162	#endif
163
164	/*
165	* Packet tag structure (see below for details).
166	*/
167	struct m_tag {
168	u_int64_t m_tag_cookie; / Error checking /
169	#ifndef __LP64__
170	u_int32_t pad; / For structure alignment /
171	#endif /* !__LP64__ */
172	SLIST_ENTRY(m_tag) m_tag_link; / List of packet tags /
173	u_int16_t m_tag_type; / Module specific type /
174	u_int16_t m_tag_len; / Length of data /
175	u_int32_t m_tag_id; / Module ID /
176	};
177
178	#define M_TAG_ALIGN(len) \
179	(P2ROUNDUP(len, sizeof (u_int64_t)) + sizeof (struct m_tag))
180
181	#define M_TAG_VALID_PATTERN 0xfeedfacefeedfaceULL
182	#define M_TAG_FREE_PATTERN 0xdeadbeefdeadbeefULL
183
184	/*
185	* Packet tag header structure (at the top of mbuf). Pointers are
186	* 32-bit in ILP32; m_tag needs 64-bit alignment, hence padded.
187	*/
188	struct m_taghdr {
189	#ifndef __LP64__
190	u_int32_t pad; / For structure alignment /
191	#endif /* !__LP64__ */
192	u_int64_t refcnt; / Number of tags in this mbuf /
193	};
194
195	/*
196	* Driver auxiliary metadata tag (KERNEL_TAG_TYPE_DRVAUX).
197	*/
198	struct m_drvaux_tag {
199	u_int32_t da_family; / IFNET_FAMILY values /
200	u_int32_t da_subfamily; / IFNET_SUBFAMILY values /
201	u_int32_t da_reserved; / for future /
202	u_int32_t da_length; / length of following data /
203	};
204
205	/ Values for pftag_flags (16-bit wide) /
206	#define PF_TAG_GENERATED 0x1 /* pkt generated by PF */
207	#define PF_TAG_FRAGCACHE 0x2
208	#define PF_TAG_TRANSLATE_LOCALHOST 0x4
209	#if PF_ECN
210	#define PF_TAG_HDR_INET 0x8 /* hdr points to IPv4 */
211	#define PF_TAG_HDR_INET6 0x10 /* hdr points to IPv6 */
212	#endif /* PF_ECN */
213	/*
214	* PF mbuf tag
215	*/
216	struct pf_mtag {
217	u_int16_t pftag_flags; / PF_TAG flags /
218	u_int16_t pftag_rtableid; / alternate routing table id /
219	u_int16_t pftag_tag;
220	u_int16_t pftag_routed;
221	#if PF_ECN
222	void pftag_hdr; /* saved hdr pos in mbuf, for ECN /
223	#endif /* PF_ECN */
224	};
225
226	/*
227	* TCP mbuf tag
228	*/
229	struct tcp_pktinfo {
230	union {
231	struct {
232	u_int32_t segsz; / segment size (actual MSS) /
233	u_int32_t start_seq; / start seq of this packet /
234	pid_t pid;
235	pid_t e_pid;
236	} __tx;
237	struct {
238	u_int16_t lro_pktlen; / max seg size encountered /
239	u_int8_t lro_npkts; / # of coalesced TCP pkts /
240	u_int8_t lro_timediff; / time spent in LRO /
241	} __rx;
242	} __offload;
243	union {
244	u_int32_t pri; / send msg priority /
245	u_int32_t seq; / recv msg sequence # /
246	} __msgattr;
247	#define tso_segsz proto_mtag.__pr_u.tcp.tm_tcp.__offload.__tx.segsz
248	#define tx_start_seq proto_mtag.__pr_u.tcp.tm_tcp.__offload.__tx.start_seq
249	#define tx_tcp_pid proto_mtag.__pr_u.tcp.tm_tcp.__offload.__tx.pid
250	#define tx_tcp_e_pid proto_mtag.__pr_u.tcp.tm_tcp.__offload.__tx.e_pid
251	#define lro_pktlen proto_mtag.__pr_u.tcp.tm_tcp.__offload.__rx.lro_pktlen
252	#define lro_npkts proto_mtag.__pr_u.tcp.tm_tcp.__offload.__rx.lro_npkts
253	#define lro_elapsed proto_mtag.__pr_u.tcp.tm_tcp.__offload.__rx.lro_timediff
254	#define msg_pri proto_mtag.__pr_u.tcp.tm_tcp.__msgattr.pri
255	#define msg_seq proto_mtag.__pr_u.tcp.tm_tcp.__msgattr.seq
256	};
257
258	/*
259	* MPTCP mbuf tag
260	*/
261	struct mptcp_pktinfo {
262	u_int64_t mtpi_dsn; / MPTCP Data Sequence Number /
263	u_int32_t mtpi_rel_seq; / Relative Seq Number /
264	u_int16_t mtpi_length; / Length of mapping /
265	u_int16_t mtpi_csum;
266	#define mp_dsn proto_mtag.__pr_u.tcp.tm_mptcp.mtpi_dsn
267	#define mp_rseq proto_mtag.__pr_u.tcp.tm_mptcp.mtpi_rel_seq
268	#define mp_rlen proto_mtag.__pr_u.tcp.tm_mptcp.mtpi_length
269	#define mp_csum proto_mtag.__pr_u.tcp.tm_mptcp.mtpi_csum
270	};
271
272	/*
273	* TCP specific mbuf tag. Note that the current implementation uses
274	* MPTCP metadata strictly between MPTCP and the TCP subflow layers,
275	* hence tm_tcp and tm_mptcp are mutually exclusive. This also means
276	* that TCP messages functionality is currently incompatible with MPTCP.
277	*/
278	struct tcp_mtag {
279	union {
280	struct tcp_pktinfo tm_tcp; / TCP and below /
281	struct mptcp_pktinfo tm_mptcp; / MPTCP-TCP only /
282	};
283	};
284
285	struct udp_mtag {
286	pid_t _pid;
287	pid_t _e_pid;
288	#define tx_udp_pid proto_mtag.__pr_u.udp._pid
289	#define tx_udp_e_pid proto_mtag.__pr_u.udp._e_pid
290	};
291
292	struct rawip_mtag {
293	pid_t _pid;
294	pid_t _e_pid;
295	#define tx_rawip_pid proto_mtag.__pr_u.rawip._pid
296	#define tx_rawip_e_pid proto_mtag.__pr_u.rawip._e_pid
297	};
298
299	struct driver_mtag_ {
300	uintptr_t _drv_tx_compl_arg;
301	uintptr_t _drv_tx_compl_data;
302	kern_return_t _drv_tx_status;
303	uint16_t _drv_flowid;
304	#define drv_tx_compl_arg builtin_mtag._drv_mtag._drv_tx_compl_arg
305	#define drv_tx_compl_data builtin_mtag._drv_mtag._drv_tx_compl_data
306	#define drv_tx_status builtin_mtag._drv_mtag._drv_tx_status
307	#define drv_flowid builtin_mtag._drv_mtag._drv_flowid
308	};
309
310	/*
311	* Protocol specific mbuf tag (at most one protocol metadata per mbuf).
312	*
313	* Care must be taken to ensure that they are mutually exclusive, e.g.
314	* IPSec policy ID implies no TCP segment offload (which is fine given
315	* that the former is used on the virtual ipsec interface that does
316	* not advertise the TSO capability.)
317	*/
318	struct proto_mtag_ {
319	union {
320	struct tcp_mtag tcp; / TCP specific /
321	struct udp_mtag udp; / UDP specific /
322	struct rawip_mtag rawip; / raw IPv4/IPv6 specific /
323	} __pr_u;
324	};
325
326	/*
327	* NECP specific mbuf tag.
328	*/
329	struct necp_mtag_ {
330	u_int32_t necp_policy_id;
331	u_int32_t necp_skip_policy_id;
332	u_int32_t necp_route_rule_id;
333	u_int16_t necp_last_interface_index;
334	u_int16_t necp_app_id;
335	};
336
337	union builtin_mtag {
338	struct {
339	struct proto_mtag_ _proto_mtag; / built-in protocol-specific tag /
340	struct pf_mtag _pf_mtag; / built-in PF tag /
341	struct necp_mtag_ _necp_mtag; / built-in NECP tag /
342	} _net_mtag;
343	struct driver_mtag_ _drv_mtag;
344	#define necp_mtag builtin_mtag._net_mtag._necp_mtag
345	#define proto_mtag builtin_mtag._net_mtag._proto_mtag
346	#define driver_mtag builtin_mtag._drv_mtag
347	};
348
349	/*
350	* Record/packet header in first mbuf of chain; valid only if M_PKTHDR set.
351	*/
352	struct pkthdr {
353	struct ifnet rcvif; /* rcv interface /
354	/ variables for ip and tcp reassembly /
355	void pkt_hdr; /* pointer to packet header /
356	int32_t len; / total packet length /
357	/ variables for hardware checksum /
358	/ Note: csum_flags is used for hardware checksum and VLAN /
359	u_int32_t csum_flags; / flags regarding checksum /
360	union {
361	struct {
362	u_int16_t val; / checksum value /
363	u_int16_t start; / checksum start offset /
364	} _csum_rx;
365	#define csum_rx_val _csum_rx.val
366	#define csum_rx_start _csum_rx.start
367	struct {
368	u_int16_t start; / checksum start offset /
369	u_int16_t stuff; / checksum stuff offset /
370	} _csum_tx;
371	#define csum_tx_start _csum_tx.start
372	#define csum_tx_stuff _csum_tx.stuff
373	/*
374	* Generic data field used by csum routines.
375	* It gets used differently in different contexts.
376	*/
377	u_int32_t csum_data;
378	};
379	u_int16_t vlan_tag; / VLAN tag, host byte order /
380	/*
381	* Packet classifier info
382	*
383	* PKTF_FLOW_ID set means valid flow ID. A non-zero flow ID value
384	* means the packet has been classified by one of the flow sources.
385	* It is also a prerequisite for flow control advisory, which is
386	* enabled by additionally setting PKTF_FLOW_ADV.
387	*
388	* The protocol value is a best-effort representation of the payload.
389	* It is opportunistically updated and used only for optimization.
390	* It is not a substitute for parsing the protocol header(s); use it
391	* only as a hint.
392	*
393	* If PKTF_IFAINFO is set, pkt_ifainfo contains one or both of the
394	* indices of interfaces which own the source and/or destination
395	* addresses of the packet. For the local/loopback case (PKTF_LOOP),
396	* both should be valid, and thus allows for the receiving end to
397	* quickly determine the actual interfaces used by the the addresses;
398	* they may not necessarily be the same or refer to the loopback
399	* interface. Otherwise, in the non-local/loopback case, the indices
400	* are opportunistically set, and because of that only one may be set
401	* (0 means the index has not been determined.) In addition, the
402	* interface address flags are also recorded. This allows us to avoid
403	* storing the corresponding {in,in6}_ifaddr in an mbuf tag. Ideally
404	* this would be a superset of {ia,ia6}_flags, but the namespaces are
405	* overlapping at present, so we'll need a new set of values in future
406	* to achieve this. For now, we will just rely on the address family
407	* related code paths examining this mbuf to interpret the flags.
408	*/
409	u_int8_t pkt_proto; / IPPROTO value /
410	u_int8_t pkt_flowsrc; / FLOWSRC values /
411	u_int32_t pkt_flowid; / flow ID /
412	u_int32_t pkt_flags; / PKTF flags (see below) /
413	u_int32_t pkt_svc; / MBUF_SVC value /
414
415	u_int32_t pkt_compl_context; / Packet completion context /
416
417	union {
418	struct {
419	u_int16_t src; / ifindex of src addr i/f /
420	u_int16_t src_flags; / src PKT_IFAIFF flags /
421	u_int16_t dst; / ifindex of dst addr i/f /
422	u_int16_t dst_flags; / dst PKT_IFAIFF flags /
423	} _pkt_iaif;
424	#define src_ifindex _pkt_iaif.src
425	#define src_iff _pkt_iaif.src_flags
426	#define dst_ifindex _pkt_iaif.dst
427	#define dst_iff _pkt_iaif.dst_flags
428	u_int64_t pkt_ifainfo; / data field used by ifainfo /
429	struct {
430	u_int32_t if_data; / bytes in interface queue /
431	u_int32_t sndbuf_data; / bytes in socket buffer /
432	} _pkt_bsr; / Buffer status report used by cellular interface /
433	#define bufstatus_if _pkt_bsr.if_data
434	#define bufstatus_sndbuf _pkt_bsr.sndbuf_data
435	};
436	u_int64_t pkt_timestamp; / enqueue time /
437
438	/*
439	* Tags (external and built-in)
440	*/
441	SLIST_HEAD(packet_tags, m_tag) tags; / list of external tags /
442	union builtin_mtag builtin_mtag;
443	/*
444	* Module private scratch space (32-bit aligned), currently 16-bytes
445	* large. Anything stored here is not guaranteed to survive across
446	* modules. The AQM layer (outbound) uses all 16-bytes for both
447	* packet scheduling and flow advisory information.
448	*/
449	struct {
450	union {
451	u_int8_t __mpriv8[`16`];
452	u_int16_t __mpriv16[`8`];
453	struct {
454	union {
455	u_int8_t __val8[`4`];
456	u_int16_t __val16[`2`];
457	u_int32_t __val32;
458	} __mpriv32_u;
459	} __mpriv32[`4`];
460	u_int64_t __mpriv64[`2`];
461	} __mpriv_u;
462	} pkt_mpriv __attribute__((aligned(`4`)));
463	#define pkt_mpriv_hash pkt_mpriv.__mpriv_u.__mpriv32[0].__mpriv32_u.__val32
464	#define pkt_mpriv_flags pkt_mpriv.__mpriv_u.__mpriv32[1].__mpriv32_u.__val32
465	#define pkt_mpriv_srcid pkt_mpriv.__mpriv_u.__mpriv32[2].__mpriv32_u.__val32
466	#define pkt_mpriv_fidx pkt_mpriv.__mpriv_u.__mpriv32[3].__mpriv32_u.__val32
467
468	u_int32_t redzone; / red zone /
469	u_int32_t pkt_compl_callbacks; / Packet completion callbacks /
470	};
471
472	/*
473	* Flow data source type. A data source module is responsible for generating
474	* a unique flow ID and associating it to each data flow as pkt_flowid.
475	* This is required for flow control/advisory, as it allows the output queue
476	* to identify the data source object and inform that it can resume its
477	* transmission (in the event it was flow controlled.)
478	*/
479	#define FLOWSRC_INPCB 1 /* flow ID generated by INPCB */
480	#define FLOWSRC_IFNET 2 /* flow ID generated by interface */
481	#define FLOWSRC_PF 3 /* flow ID generated by PF */
482	#define FLOWSRC_CHANNEL 4 /* flow ID generated by channel */
483
484	/*
485	* Packet flags. Unlike m_flags, all packet flags are copied along when
486	* copying m_pkthdr, i.e. no equivalent of M_COPYFLAGS here. These flags
487	* (and other classifier info) will be cleared during DLIL input.
488	*
489	* Some notes about M_LOOP and PKTF_LOOP:
490	*
491	* - M_LOOP flag is overloaded, and its use is discouraged. Historically,
492	* that flag was used by the KAME implementation for allowing certain
493	* certain exceptions to be made in the IP6_EXTHDR_CHECK() logic; this
494	* was originally meant to be set as the packet is looped back to the
495	* system, and in some circumstances temporarily set in ip6_output().
496	* Over time, this flag was used by the pre-output routines to indicate
497	* to the DLIL frameout and output routines, that the packet may be
498	* looped back to the system under the right conditions. In addition,
499	* this is an mbuf flag rather than an mbuf packet header flag.
500	*
501	* - PKTF_LOOP is an mbuf packet header flag, which is set if and only
502	* if the packet was looped back to the system. This flag should be
503	* used instead for newer code.
504	*/
505	#define PKTF_FLOW_ID 0x1 /* pkt has valid flowid value */
506	#define PKTF_FLOW_ADV 0x2 /* pkt triggers local flow advisory */
507	#define PKTF_FLOW_LOCALSRC 0x4 /* pkt is locally originated */
508	#define PKTF_FLOW_RAWSOCK 0x8 /* pkt locally generated by raw sock */
509	#define PKTF_PRIO_PRIVILEGED 0x10 /* packet priority is privileged */
510	#define PKTF_PROXY_DST 0x20 /* processed but not locally destined */
511	#define PKTF_INET_RESOLVE 0x40 /* IPv4 resolver packet */
512	#define PKTF_INET6_RESOLVE 0x80 /* IPv6 resolver packet */
513	#define PKTF_RESOLVE_RTR 0x100 /* pkt is for resolving router */
514	#define PKTF_SW_LRO_PKT 0x200 /* pkt is a large coalesced pkt */
515	#define PKTF_SW_LRO_DID_CSUM 0x400 /* IP and TCP checksums done by LRO */
516	#define PKTF_MPTCP 0x800 /* TCP with MPTCP metadata */
517	#define PKTF_MPSO 0x1000 /* MPTCP socket meta data */
518	#define PKTF_LOOP 0x2000 /* loopbacked packet */
519	#define PKTF_IFAINFO 0x4000 /* pkt has valid interface addr info */
520	#define PKTF_SO_BACKGROUND 0x8000 /* data is from background source */
521	#define PKTF_FORWARDED 0x10000 /* pkt was forwarded from another i/f */
522	#define PKTF_PRIV_GUARDED 0x20000 /* pkt_mpriv area guard enabled */
523	#define PKTF_KEEPALIVE 0x40000 /* pkt is kernel-generated keepalive */
524	#define PKTF_SO_REALTIME 0x80000 /* data is realtime traffic */
525	#define PKTF_VALID_UNSENT_DATA 0x100000 /* unsent data is valid */
526	#define PKTF_TCP_REXMT 0x200000 /* packet is TCP retransmission */
527	#define PKTF_REASSEMBLED 0x400000 /* Packet was reassembled */
528	#define PKTF_TX_COMPL_TS_REQ 0x800000 /* tx completion timestamp requested */
529	#define PKTF_TS_VALID 0x1000000 /* pkt timestamp is valid */
530	#define PKTF_DRIVER_MTAG 0x2000000 /* driver mbuf tags fields inited */
531	#define PKTF_NEW_FLOW 0x4000000 /* Data from a new flow */
532	#define PKTF_START_SEQ 0x8000000 /* valid start sequence */
533	#define PKTF_LAST_PKT 0x10000000 /* last packet in the flow */
534	#define PKTF_MPTCP_REINJ 0x20000000 /* Packet has been reinjected for MPTCP */
535	#define PKTF_MPTCP_DFIN 0x40000000 /* Packet is a data-fin */
536	#define PKTF_HBH_CHKED 0x80000000 /* HBH option is checked */
537
538	/ flags related to flow control/advisory and identification /
539	#define PKTF_FLOW_MASK \
540	(PKTF_FLOW_ID \| PKTF_FLOW_ADV \| PKTF_FLOW_LOCALSRC \| PKTF_FLOW_RAWSOCK)
541
542	/*
543	* Description of external storage mapped into mbuf, valid only if M_EXT set.
544	*/
545	typedef void (*m_ext_free_func_t)(caddr_t, u_int, caddr_t);
546	struct m_ext {
547	caddr_t ext_buf; / start of buffer /
548	m_ext_free_func_t ext_free; / free routine if not the usual /
549	u_int ext_size; / size of buffer, for ext_free /
550	caddr_t ext_arg; / additional ext_free argument /
551	struct ext_ref {
552	struct mbuf *paired;
553	u_int16_t minref;
554	u_int16_t refcnt;
555	u_int16_t prefcnt;
556	u_int16_t flags;
557	u_int32_t priv;
558	uintptr_t ext_token;
559	} *ext_refflags;
560	};
561
562	/ define m_ext to a type since it gets redefined below /
563	typedef struct m_ext _m_ext_t;
564
565	/*
566	* The mbuf object
567	*/
568	struct mbuf {
569	struct m_hdr m_hdr;
570	union {
571	struct {
572	struct pkthdr MH_pkthdr; / M_PKTHDR set /
573	union {
574	struct m_ext MH_ext; / M_EXT set /
575	char MH_databuf[_MHLEN];
576	} MH_dat;
577	} MH;
578	char M_databuf[_MLEN]; / !M_PKTHDR, !M_EXT /
579	} M_dat;
580	};
581
582	#define m_next m_hdr.mh_next
583	#define m_len m_hdr.mh_len
584	#define m_data m_hdr.mh_data
585	#define m_type m_hdr.mh_type
586	#define m_flags m_hdr.mh_flags
587	#define m_nextpkt m_hdr.mh_nextpkt
588	#define m_act m_nextpkt
589	#define m_pkthdr M_dat.MH.MH_pkthdr
590	#define m_ext M_dat.MH.MH_dat.MH_ext
591	#define m_pktdat M_dat.MH.MH_dat.MH_databuf
592	#define m_dat M_dat.M_databuf
593	#define m_pktlen(_m) ((_m)->m_pkthdr.len)
594	#define m_pftag(_m) (&(_m)->m_pkthdr.builtin_mtag._net_mtag._pf_mtag)
595
596	/ mbuf flags (private) /
597	#define M_EXT 0x0001 /* has associated external storage */
598	#define M_PKTHDR 0x0002 /* start of record */
599	#define M_EOR 0x0004 /* end of record */
600	#define M_PROTO1 0x0008 /* protocol-specific */
601	#define M_PROTO2 0x0010 /* protocol-specific */
602	#define M_PROTO3 0x0020 /* protocol-specific */
603	#define M_LOOP 0x0040 /* packet is looped back (also see PKTF_LOOP) */
604	#define M_PROTO5 0x0080 /* protocol-specific */
605
606	/ mbuf pkthdr flags, also in m_flags (private) /
607	#define M_BCAST 0x0100 /* send/received as link-level broadcast */
608	#define M_MCAST 0x0200 /* send/received as link-level multicast */
609	#define M_FRAG 0x0400 /* packet is a fragment of a larger packet */
610	#define M_FIRSTFRAG 0x0800 /* packet is first fragment */
611	#define M_LASTFRAG 0x1000 /* packet is last fragment */
612	#define M_PROMISC 0x2000 /* packet is promiscuous (shouldn't go to stack) */
613	#define M_HASFCS 0x4000 /* packet has FCS */
614	#define M_TAGHDR 0x8000 /* m_tag hdr structure at top of mbuf data */
615
616	/*
617	* Flags to purge when crossing layers.
618	*/
619	#define M_PROTOFLAGS \
620	(M_PROTO1\|M_PROTO2\|M_PROTO3\|M_PROTO5)
621
622	/ flags copied when copying m_pkthdr /
623	#define M_COPYFLAGS \
624	(M_PKTHDR\|M_EOR\|M_PROTO1\|M_PROTO2\|M_PROTO3 \| \
625	M_LOOP\|M_PROTO5\|M_BCAST\|M_MCAST\|M_FRAG \| \
626	M_FIRSTFRAG\|M_LASTFRAG\|M_PROMISC\|M_HASFCS)
627
628	/ flags indicating hw checksum support and sw checksum requirements /
629	#define CSUM_IP 0x0001 /* will csum IP */
630	#define CSUM_TCP 0x0002 /* will csum TCP */
631	#define CSUM_UDP 0x0004 /* will csum UDP */
632	#define CSUM_IP_FRAGS 0x0008 /* will csum IP fragments */
633	#define CSUM_FRAGMENT 0x0010 /* will do IP fragmentation */
634	#define CSUM_TCPIPV6 0x0020 /* will csum TCP for IPv6 */
635	#define CSUM_UDPIPV6 0x0040 /* will csum UDP for IPv6 */
636	#define CSUM_FRAGMENT_IPV6 0x0080 /* will do IPv6 fragmentation */
637
638	#define CSUM_IP_CHECKED 0x0100 /* did csum IP */
639	#define CSUM_IP_VALID 0x0200 /* ... the csum is valid */
640	#define CSUM_DATA_VALID 0x0400 /* csum_data field is valid */
641	#define CSUM_PSEUDO_HDR 0x0800 /* csum_data has pseudo hdr */
642	#define CSUM_PARTIAL 0x1000 /* simple Sum16 computation */
643	#define CSUM_ZERO_INVERT 0x2000 /* invert 0 to -0 (0xffff) */
644
645	#define CSUM_DELAY_DATA (CSUM_TCP \| CSUM_UDP)
646	#define CSUM_DELAY_IP (CSUM_IP) /* IPv4 only: no IPv6 IP cksum */
647	#define CSUM_DELAY_IPV6_DATA (CSUM_TCPIPV6 \| CSUM_UDPIPV6)
648	#define CSUM_DATA_IPV6_VALID CSUM_DATA_VALID /* csum_data field is valid */
649
650	#define CSUM_TX_FLAGS \
651	(CSUM_DELAY_IP \| CSUM_DELAY_DATA \| CSUM_DELAY_IPV6_DATA \| \
652	CSUM_DATA_VALID \| CSUM_PARTIAL \| CSUM_ZERO_INVERT)
653
654	#define CSUM_RX_FLAGS \
655	(CSUM_IP_CHECKED \| CSUM_IP_VALID \| CSUM_PSEUDO_HDR \| \
656	CSUM_DATA_VALID \| CSUM_PARTIAL)
657
658	/*
659	* Note: see also IF_HWASSIST_CSUM defined in <net/if_var.h>
660	*/
661
662	/ VLAN tag present /
663	#define CSUM_VLAN_TAG_VALID 0x10000 /* vlan_tag field is valid */
664
665	/ TCP Segment Offloading requested on this mbuf /
666	#define CSUM_TSO_IPV4 0x100000 /* This mbuf needs to be segmented by the NIC */
667	#define CSUM_TSO_IPV6 0x200000 /* This mbuf needs to be segmented by the NIC */
668
669	#define TSO_IPV4_OK(_ifp, _m) \
670	(((_ifp)->if_hwassist & IFNET_TSO_IPV4) && \
671	((_m)->m_pkthdr.csum_flags & CSUM_TSO_IPV4)) \
672
673	#define TSO_IPV4_NOTOK(_ifp, _m) \
674	(!((_ifp)->if_hwassist & IFNET_TSO_IPV4) && \
675	((_m)->m_pkthdr.csum_flags & CSUM_TSO_IPV4)) \
676
677	#define TSO_IPV6_OK(_ifp, _m) \
678	(((_ifp)->if_hwassist & IFNET_TSO_IPV6) && \
679	((_m)->m_pkthdr.csum_flags & CSUM_TSO_IPV6)) \
680
681	#define TSO_IPV6_NOTOK(_ifp, _m) \
682	(!((_ifp)->if_hwassist & IFNET_TSO_IPV6) && \
683	((_m)->m_pkthdr.csum_flags & CSUM_TSO_IPV6)) \
684
685	#endif /* XNU_KERNEL_PRIVATE */
686
687	/ mbuf types /
688	#define MT_FREE 0 /* should be on free list */
689	#define MT_DATA 1 /* dynamic (data) allocation */
690	#define MT_HEADER 2 /* packet header */
691	#define MT_SOCKET 3 /* socket structure */
692	#define MT_PCB 4 /* protocol control block */
693	#define MT_RTABLE 5 /* routing tables */
694	#define MT_HTABLE 6 /* IMP host tables */
695	#define MT_ATABLE 7 /* address resolution tables */
696	#define MT_SONAME 8 /* socket name */
697	#define MT_SOOPTS 10 /* socket options */
698	#define MT_FTABLE 11 /* fragment reassembly header */
699	#define MT_RIGHTS 12 /* access rights */
700	#define MT_IFADDR 13 /* interface address */
701	#define MT_CONTROL 14 /* extra-data protocol message */
702	#define MT_OOBDATA 15 /* expedited data */
703	#define MT_TAG 16 /* volatile metadata associated to pkts */
704	#define MT_MAX 32 /* enough? */
705
706	#ifdef XNU_KERNEL_PRIVATE
707	/*
708	* mbuf allocation/deallocation macros:
709	*
710	* MGET(struct mbuf *m, int how, int type)
711	* allocates an mbuf and initializes it to contain internal data.
712	*
713	* MGETHDR(struct mbuf *m, int how, int type)
714	* allocates an mbuf and initializes it to contain a packet header
715	* and internal data.
716	*/
717
718	#if 1
719	#define MCHECK(m) m_mcheck(m)
720	#else
721	#define MCHECK(m)
722	#endif
723
724	#define MGET(m, how, type) ((m) = m_get((how), (type)))
725
726	#define MGETHDR(m, how, type) ((m) = m_gethdr((how), (type)))
727
728	/*
729	* Mbuf cluster macros.
730	* MCLALLOC(caddr_t p, int how) allocates an mbuf cluster.
731	* MCLGET adds such clusters to a normal mbuf;
732	* the flag M_EXT is set upon success.
733	* MCLFREE releases a reference to a cluster allocated by MCLALLOC,
734	* freeing the cluster if the reference count has reached 0.
735	*
736	* Normal mbuf clusters are normally treated as character arrays
737	* after allocation, but use the first word of the buffer as a free list
738	* pointer while on the free list.
739	*/
740	union mcluster {
741	union mcluster *mcl_next;
742	char mcl_buf[MCLBYTES];
743	};
744
745	#define MCLALLOC(p, how) ((p) = m_mclalloc(how))
746
747	#define MCLFREE(p) m_mclfree(p)
748
749	#define MCLGET(m, how) ((m) = m_mclget(m, how))
750
751	/*
752	* Mbuf big cluster
753	*/
754	union mbigcluster {
755	union mbigcluster *mbc_next;
756	char mbc_buf[MBIGCLBYTES];
757	};
758
759	/*
760	* Mbuf jumbo cluster
761	*/
762	union m16kcluster {
763	union m16kcluster *m16kcl_next;
764	char m16kcl_buf[M16KCLBYTES];
765	};
766
767	#define MCLHASREFERENCE(m) m_mclhasreference(m)
768
769	/*
770	* MFREE(struct mbuf m, struct mbuf n)
771	* Free a single mbuf and associated external storage.
772	* Place the successor, if any, in n.
773	*/
774
775	#define MFREE(m, n) ((n) = m_free(m))
776
777	/*
778	* Copy mbuf pkthdr from from to to.
779	* from must have M_PKTHDR set, and to must be empty.
780	* aux pointer will be moved to `to'.
781	*/
782	#define M_COPY_PKTHDR(to, from) m_copy_pkthdr(to, from)
783
784	#define M_COPY_PFTAG(to, from) m_copy_pftag(to, from)
785
786	#define M_COPY_CLASSIFIER(to, from) m_copy_classifier(to, from)
787
788	/*
789	* Evaluate TRUE if it's safe to write to the mbuf m's data region (this can
790	* be both the local data payload, or an external buffer area, depending on
791	* whether M_EXT is set).
792	*/
793	#define M_WRITABLE(m) (((m)->m_flags & M_EXT) == 0 \|\| !MCLHASREFERENCE(m))
794
795	/*
796	* These macros are mapped to the appropriate KPIs, so that private code
797	* can be simply recompiled in order to be forward-compatible with future
798	* changes toward the struture sizes.
799	*/
800	#define MLEN mbuf_get_mlen() /* normal mbuf data len */
801	#define MHLEN mbuf_get_mhlen() /* data len in an mbuf w/pkthdr */
802	#define MINCLSIZE mbuf_get_minclsize() /* cluster usage threshold */
803	/*
804	* Return the address of the start of the buffer associated with an mbuf,
805	* handling external storage, packet-header mbufs, and regular data mbufs.
806	*/
807	#define M_START(m) \
808	(((m)->m_flags & M_EXT) ? (m)->m_ext.ext_buf : \
809	((m)->m_flags & M_PKTHDR) ? &(m)->m_pktdat[0] : \
810	&(m)->m_dat[0])
811
812	/*
813	* Return the size of the buffer associated with an mbuf, handling external
814	* storage, packet-header mbufs, and regular data mbufs.
815	*/
816	#define M_SIZE(m) \
817	(((m)->m_flags & M_EXT) ? (m)->m_ext.ext_size : \
818	((m)->m_flags & M_PKTHDR) ? MHLEN : \
819	MLEN)
820
821	#define M_ALIGN(m, len) m_align(m, len)
822	#define MH_ALIGN(m, len) m_align(m, len)
823	#define MEXT_ALIGN(m, len) m_align(m, len)
824
825	/*
826	* Compute the amount of space available before the current start of data in
827	* an mbuf.
828	*
829	* The M_WRITABLE() is a temporary, conservative safety measure: the burden
830	* of checking writability of the mbuf data area rests solely with the caller.
831	*/
832	#define M_LEADINGSPACE(m) \
833	(M_WRITABLE(m) ? ((m)->m_data - M_START(m)) : 0)
834
835	/*
836	* Compute the amount of space available after the end of data in an mbuf.
837	*
838	* The M_WRITABLE() is a temporary, conservative safety measure: the burden
839	* of checking writability of the mbuf data area rests solely with the caller.
840	*/
841	#define M_TRAILINGSPACE(m) \
842	(M_WRITABLE(m) ? \
843	((M_START(m) + M_SIZE(m)) - ((m)->m_data + (m)->m_len)) : 0)
844
845	/*
846	* Arrange to prepend space of size plen to mbuf m.
847	* If a new mbuf must be allocated, how specifies whether to wait.
848	* If how is M_DONTWAIT and allocation fails, the original mbuf chain
849	* is freed and m is set to NULL.
850	*/
851	#define M_PREPEND(m, plen, how, align) \
852	((m) = m_prepend_2((m), (plen), (how), (align)))
853
854	/ change mbuf to new type /
855	#define MCHTYPE(m, t) m_mchtype(m, t)
856
857	/ compatiblity with 4.3 /
858	#define m_copy(m, o, l) m_copym((m), (o), (l), M_DONTWAIT)
859
860	#define MBSHIFT 20 /* 1MB */
861	#define MBSIZE (1 << MBSHIFT)
862	#define GBSHIFT 30 /* 1GB */
863	#define GBSIZE (1 << GBSHIFT)
864
865	/*
866	* M_STRUCT_GET ensures that intermediate protocol header (from "off" to
867	* "off+len") is located in single mbuf, on contiguous memory region.
868	* The pointer to the region will be returned to pointer variable "val",
869	* with type "typ".
870	*
871	* M_STRUCT_GET0 does the same, except that it aligns the structure at
872	* very top of mbuf. GET0 is likely to make memory copy than GET.
873	*/
874	#define M_STRUCT_GET(val, typ, m, off, len) \
875	do { \
876	struct mbuf *t; \
877	int tmp; \
878	\
879	if ((m)->m_len >= (off) + (len)) { \
880	(val) = (typ)(mtod((m), caddr_t) + (off)); \
881	} else { \
882	t = m_pulldown((m), (off), (len), &tmp); \
883	if (t != NULL) { \
884	if (t->m_len < tmp + (len)) \
885	panic("m_pulldown malfunction"); \
886	(val) = (typ)(mtod(t, caddr_t) + tmp); \
887	} else { \
888	(val) = (typ)NULL; \
889	(m) = NULL; \
890	} \
891	} \
892	} while (0)
893
894	#define M_STRUCT_GET0(val, typ, m, off, len) \
895	do { \
896	struct mbuf *t; \
897	\
898	if ((off) == 0 && ((m)->m_len >= (len))) { \
899	(val) = (typ)(void *)mtod(m, caddr_t); \
900	} else { \
901	t = m_pulldown((m), (off), (len), NULL); \
902	if (t != NULL) { \
903	if (t->m_len < (len)) \
904	panic("m_pulldown malfunction"); \
905	(val) = (typ)(void *)mtod(t, caddr_t); \
906	} else { \
907	(val) = (typ)NULL; \
908	(m) = NULL; \
909	} \
910	} \
911	} while (0)
912
913	#define MBUF_INPUT_CHECK(m, rcvif) \
914	do { \
915	if (!(m->m_flags & MBUF_PKTHDR) \|\| \
916	m->m_len < 0 \|\| \
917	m->m_len > ((njcl > 0) ? njclbytes : MBIGCLBYTES) \|\| \
918	m->m_type == MT_FREE \|\| \
919	((m->m_flags & M_EXT) != 0 && m->m_ext.ext_buf == NULL)) { \
920	panic_plain("Failed mbuf validity check: mbuf %p len %d " \
921	"type %d flags 0x%x data %p rcvif %s ifflags 0x%x", \
922	m, m->m_len, m->m_type, m->m_flags, \
923	((m->m_flags & M_EXT) ? m->m_ext.ext_buf : m->m_data), \
924	if_name(rcvif), \
925	(rcvif->if_flags & 0xffff)); \
926	} \
927	} while (0)
928
929	/*
930	* Simple mbuf queueing system
931	*
932	* This is basically a SIMPLEQ adapted to mbuf use (i.e. using
933	* m_nextpkt instead of field.sqe_next).
934	*
935	* m_next is ignored, so queueing chains of mbufs is possible
936	*/
937	#define MBUFQ_HEAD(name) \
938	struct name { \
939	struct mbuf mq_first; / first packet */ \
940	struct mbuf *mq_last; / addr of last next packet */ \
941	}
942
943	#define MBUFQ_INIT(q) do { \
944	MBUFQ_FIRST(q) = NULL; \
945	(q)->mq_last = &MBUFQ_FIRST(q); \
946	} while (0)
947
948	#define MBUFQ_PREPEND(q, m) do { \
949	if ((MBUFQ_NEXT(m) = MBUFQ_FIRST(q)) == NULL) \
950	(q)->mq_last = &MBUFQ_NEXT(m); \
951	MBUFQ_FIRST(q) = (m); \
952	} while (0)
953
954	#define MBUFQ_ENQUEUE(q, m) do { \
955	MBUFQ_NEXT(m) = NULL; \
956	*(q)->mq_last = (m); \
957	(q)->mq_last = &MBUFQ_NEXT(m); \
958	} while (0)
959
960	#define MBUFQ_ENQUEUE_MULTI(q, m, n) do { \
961	MBUFQ_NEXT(n) = NULL; \
962	*(q)->mq_last = (m); \
963	(q)->mq_last = &MBUFQ_NEXT(n); \
964	} while (0)
965
966	#define MBUFQ_DEQUEUE(q, m) do { \
967	if (((m) = MBUFQ_FIRST(q)) != NULL) { \
968	if ((MBUFQ_FIRST(q) = MBUFQ_NEXT(m)) == NULL) \
969	(q)->mq_last = &MBUFQ_FIRST(q); \
970	else \
971	MBUFQ_NEXT(m) = NULL; \
972	} \
973	} while (0)
974
975	#define MBUFQ_REMOVE(q, m) do { \
976	if (MBUFQ_FIRST(q) == (m)) { \
977	MBUFQ_DEQUEUE(q, m); \
978	} else { \
979	struct mbuf *_m = MBUFQ_FIRST(q); \
980	while (MBUFQ_NEXT(_m) != (m)) \
981	_m = MBUFQ_NEXT(_m); \
982	if ((MBUFQ_NEXT(_m) = \
983	MBUFQ_NEXT(MBUFQ_NEXT(_m))) == NULL) \
984	(q)->mq_last = &MBUFQ_NEXT(_m); \
985	} \
986	} while (0)
987
988	#define MBUFQ_DRAIN(q) do { \
989	struct mbuf *__m0; \
990	while ((__m0 = MBUFQ_FIRST(q)) != NULL) { \
991	MBUFQ_FIRST(q) = MBUFQ_NEXT(__m0); \
992	MBUFQ_NEXT(__m0) = NULL; \
993	m_freem(__m0); \
994	} \
995	(q)->mq_last = &MBUFQ_FIRST(q); \
996	} while (0)
997
998	#define MBUFQ_FOREACH(m, q) \
999	for ((m) = MBUFQ_FIRST(q); \
1000	(m); \
1001	(m) = MBUFQ_NEXT(m))
1002
1003	#define MBUFQ_FOREACH_SAFE(m, q, tvar) \
1004	for ((m) = MBUFQ_FIRST(q); \
1005	(m) && ((tvar) = MBUFQ_NEXT(m), 1); \
1006	(m) = (tvar))
1007
1008	#define MBUFQ_EMPTY(q) ((q)->mq_first == NULL)
1009	#define MBUFQ_FIRST(q) ((q)->mq_first)
1010	#define MBUFQ_NEXT(m) ((m)->m_nextpkt)
1011	/*
1012	* mq_last is initialized to point to mq_first, so check if they're
1013	* equal and return NULL when the list is empty. Otherwise, we need
1014	* to subtract the offset of MBUQ_NEXT (i.e. m_nextpkt field) to get
1015	* to the base mbuf address to return to caller.
1016	*/
1017	#define MBUFQ_LAST(head) \
1018	(((head)->mq_last == &MBUFQ_FIRST(head)) ? NULL : \
1019	((struct mbuf )(void )((char *)(head)->mq_last - \
1020	(size_t)(&MBUFQ_NEXT((struct mbuf *)0)))))
1021
1022	#define max_linkhdr P2ROUNDUP(_max_linkhdr, sizeof (u_int32_t))
1023	#define max_protohdr P2ROUNDUP(_max_protohdr, sizeof (u_int32_t))
1024	#endif /* XNU_KERNEL_PRIVATE */
1025
1026	/*
1027	* Mbuf statistics (legacy).
1028	*/
1029	struct mbstat {
1030	u_int32_t m_mbufs; / mbufs obtained from page pool /
1031	u_int32_t m_clusters; / clusters obtained from page pool /
1032	u_int32_t m_spare; / spare field /
1033	u_int32_t m_clfree; / free clusters /
1034	u_int32_t m_drops; / times failed to find space /
1035	u_int32_t m_wait; / times waited for space /
1036	u_int32_t m_drain; / times drained protocols for space /
1037	u_short m_mtypes[`256`]; / type specific mbuf allocations /
1038	u_int32_t m_mcfail; / times m_copym failed /
1039	u_int32_t m_mpfail; / times m_pullup failed /
1040	u_int32_t m_msize; / length of an mbuf /
1041	u_int32_t m_mclbytes; / length of an mbuf cluster /
1042	u_int32_t m_minclsize; / min length of data to allocate a cluster /
1043	u_int32_t m_mlen; / length of data in an mbuf /
1044	u_int32_t m_mhlen; / length of data in a header mbuf /
1045	u_int32_t m_bigclusters; / clusters obtained from page pool /
1046	u_int32_t m_bigclfree; / free clusters /
1047	u_int32_t m_bigmclbytes; / length of an mbuf cluster /
1048	};
1049
1050	/ Compatibillity with 10.3 /
1051	struct ombstat {
1052	u_int32_t m_mbufs; / mbufs obtained from page pool /
1053	u_int32_t m_clusters; / clusters obtained from page pool /
1054	u_int32_t m_spare; / spare field /
1055	u_int32_t m_clfree; / free clusters /
1056	u_int32_t m_drops; / times failed to find space /
1057	u_int32_t m_wait; / times waited for space /
1058	u_int32_t m_drain; / times drained protocols for space /
1059	u_short m_mtypes[`256`]; / type specific mbuf allocations /
1060	u_int32_t m_mcfail; / times m_copym failed /
1061	u_int32_t m_mpfail; / times m_pullup failed /
1062	u_int32_t m_msize; / length of an mbuf /
1063	u_int32_t m_mclbytes; / length of an mbuf cluster /
1064	u_int32_t m_minclsize; / min length of data to allocate a cluster /
1065	u_int32_t m_mlen; / length of data in an mbuf /
1066	u_int32_t m_mhlen; / length of data in a header mbuf /
1067	};
1068
1069	/*
1070	* mbuf class statistics.
1071	*/
1072	#define MAX_MBUF_CNAME 15
1073
1074	#if defined(XNU_KERNEL_PRIVATE)
1075	/ For backwards compatibility with 32-bit userland process /
1076	struct omb_class_stat {
1077	char mbcl_cname[MAX_MBUF_CNAME + `1`]; / class name /
1078	u_int32_t mbcl_size; / buffer size /
1079	u_int32_t mbcl_total; / # of buffers created /
1080	u_int32_t mbcl_active; / # of active buffers /
1081	u_int32_t mbcl_infree; / # of available buffers /
1082	u_int32_t mbcl_slab_cnt; / # of available slabs /
1083	u_int64_t mbcl_alloc_cnt; / # of times alloc is called /
1084	u_int64_t mbcl_free_cnt; / # of times free is called /
1085	u_int64_t mbcl_notified; / # of notified wakeups /
1086	u_int64_t mbcl_purge_cnt; / # of purges so far /
1087	u_int64_t mbcl_fail_cnt; / # of allocation failures /
1088	u_int32_t mbcl_ctotal; / total only for this class /
1089	u_int32_t mbcl_release_cnt; / amount of memory returned /
1090	/*
1091	* Cache layer statistics
1092	*/
1093	u_int32_t mbcl_mc_state; / cache state (see below) /
1094	u_int32_t mbcl_mc_cached; / # of cached buffers /
1095	u_int32_t mbcl_mc_waiter_cnt; / # waiters on the cache /
1096	u_int32_t mbcl_mc_wretry_cnt; / # of wait retries /
1097	u_int32_t mbcl_mc_nwretry_cnt; / # of no-wait retry attempts /
1098	u_int64_t mbcl_reserved[`4`]; / for future use /
1099	} __attribute__((__packed__));
1100	#endif /* XNU_KERNEL_PRIVATE */
1101
1102	typedef struct mb_class_stat {
1103	char mbcl_cname[MAX_MBUF_CNAME + `1`]; / class name /
1104	u_int32_t mbcl_size; / buffer size /
1105	u_int32_t mbcl_total; / # of buffers created /
1106	u_int32_t mbcl_active; / # of active buffers /
1107	u_int32_t mbcl_infree; / # of available buffers /
1108	u_int32_t mbcl_slab_cnt; / # of available slabs /
1109	#if defined(KERNEL) \|\| defined(__LP64__)
1110	u_int32_t mbcl_pad; / padding /
1111	#endif /* KERNEL \|\| __LP64__ */
1112	u_int64_t mbcl_alloc_cnt; / # of times alloc is called /
1113	u_int64_t mbcl_free_cnt; / # of times free is called /
1114	u_int64_t mbcl_notified; / # of notified wakeups /
1115	u_int64_t mbcl_purge_cnt; / # of purges so far /
1116	u_int64_t mbcl_fail_cnt; / # of allocation failures /
1117	u_int32_t mbcl_ctotal; / total only for this class /
1118	u_int32_t mbcl_release_cnt; / amount of memory returned /
1119	/*
1120	* Cache layer statistics
1121	*/
1122	u_int32_t mbcl_mc_state; / cache state (see below) /
1123	u_int32_t mbcl_mc_cached; / # of cached buffers /
1124	u_int32_t mbcl_mc_waiter_cnt; / # waiters on the cache /
1125	u_int32_t mbcl_mc_wretry_cnt; / # of wait retries /
1126	u_int32_t mbcl_mc_nwretry_cnt; / # of no-wait retry attempts /
1127	u_int32_t mbcl_peak_reported; / last usage peak reported /
1128	u_int32_t mbcl_reserved[`7`]; / for future use /
1129	} mb_class_stat_t;
1130
1131	#define MCS_DISABLED 0 /* cache is permanently disabled */
1132	#define MCS_ONLINE 1 /* cache is online */
1133	#define MCS_PURGING 2 /* cache is being purged */
1134	#define MCS_OFFLINE 3 /* cache is offline (resizing) */
1135
1136	#if defined(XNU_KERNEL_PRIVATE)
1137	/ For backwards compatibility with 32-bit userland process /
1138	struct omb_stat {
1139	u_int32_t mbs_cnt; / number of classes /
1140	struct omb_class_stat mbs_class[`1`]; / class array /
1141	} __attribute__((__packed__));
1142	#endif /* XNU_KERNEL_PRIVATE */
1143
1144	typedef struct mb_stat {
1145	u_int32_t mbs_cnt; / number of classes /
1146	#if defined(KERNEL) \|\| defined(__LP64__)
1147	u_int32_t mbs_pad; / padding /
1148	#endif /* KERNEL \|\| __LP64__ */
1149	mb_class_stat_t mbs_class[`1`]; / class array /
1150	} mb_stat_t;
1151
1152	#ifdef PRIVATE
1153	#define MLEAK_STACK_DEPTH 16 /* Max PC stack depth */
1154
1155	typedef struct mleak_trace_stat {
1156	u_int64_t mltr_collisions;
1157	u_int64_t mltr_hitcount;
1158	u_int64_t mltr_allocs;
1159	u_int64_t mltr_depth;
1160	u_int64_t mltr_addr[MLEAK_STACK_DEPTH];
1161	} mleak_trace_stat_t;
1162
1163	typedef struct mleak_stat {
1164	u_int32_t ml_isaddr64; / 64-bit KVA? /
1165	u_int32_t ml_cnt; / number of traces /
1166	mleak_trace_stat_t ml_trace[`1`]; / trace array /
1167	} mleak_stat_t;
1168
1169	struct mleak_table {
1170	u_int32_t mleak_capture; / sampling capture counter /
1171	u_int32_t mleak_sample_factor; / sample factor /
1172
1173	/ Times two active records want to occupy the same spot /
1174	u_int64_t alloc_collisions;
1175	u_int64_t trace_collisions;
1176
1177	/ Times new record lands on spot previously occupied by freed alloc /
1178	u_int64_t alloc_overwrites;
1179	u_int64_t trace_overwrites;
1180
1181	/ Times a new alloc or trace is put into the hash table /
1182	u_int64_t alloc_recorded;
1183	u_int64_t trace_recorded;
1184
1185	/ Total number of outstanding allocs /
1186	u_int64_t outstanding_allocs;
1187
1188	/ Times mleak_log returned false because couldn't acquire the lock /
1189	u_int64_t total_conflicts;
1190	};
1191	#endif /* PRIVATE */
1192
1193	#ifdef KERNEL_PRIVATE
1194	__BEGIN_DECLS
1195
1196	/*
1197	* Exported (private)
1198	*/
1199
1200	extern struct mbstat mbstat; / statistics /
1201
1202	__END_DECLS
1203	#endif /* KERNEL_PRIVATE */
1204
1205	#ifdef XNU_KERNEL_PRIVATE
1206	__BEGIN_DECLS
1207
1208	/*
1209	* Not exported (xnu private)
1210	*/
1211
1212	/ flags to m_get/MGET /
1213	/ Need to include malloc.h to get right options for malloc /
1214	#include <sys/malloc.h>
1215
1216	struct mbuf;
1217
1218	/ length to m_copy to copy all /
1219	#define M_COPYALL 1000000000
1220
1221	#define M_DONTWAIT M_NOWAIT
1222	#define M_WAIT M_WAITOK
1223
1224	/ modes for m_copym and variants /
1225	#define M_COPYM_NOOP_HDR 0 /* don't copy/move pkthdr contents */
1226	#define M_COPYM_COPY_HDR 1 /* copy pkthdr from old to new */
1227	#define M_COPYM_MOVE_HDR 2 /* move pkthdr from old to new */
1228	#define M_COPYM_MUST_COPY_HDR 3 /* MUST copy pkthdr from old to new */
1229	#define M_COPYM_MUST_MOVE_HDR 4 /* MUST move pkthdr from old to new */
1230
1231	extern void m_freem(struct mbuf *);
1232	extern u_int64_t mcl_to_paddr(char *);
1233	extern void m_adj(struct mbuf , int*);
1234	extern void m_cat(struct mbuf , struct* mbuf *);
1235	extern void m_copydata(struct mbuf , int, int, void* *);
1236	extern struct mbuf m_copym(struct* mbuf , int, int, int*);
1237	extern struct mbuf m_copym_mode(struct* mbuf , int, int, int*, uint32_t);
1238	extern struct mbuf m_get(int, int*);
1239	extern struct mbuf m_gethdr(int, int*);
1240	extern struct mbuf m_getpacket(void*);
1241	extern struct mbuf m_getpackets(int, int, int*);
1242	extern struct mbuf m_mclget(struct* mbuf , int*);
1243	extern void m_mtod(struct* mbuf *);
1244	extern struct mbuf m_prepend_2(struct* mbuf , int, int, int*);
1245	extern struct mbuf m_pullup(struct* mbuf , int*);
1246	extern struct mbuf m_split(struct* mbuf , int, int*);
1247	extern void m_mclfree(caddr_t p);
1248
1249	/*
1250	* On platforms which require strict alignment (currently for anything but
1251	* i386 or x86_64), this macro checks whether the data pointer of an mbuf
1252	* is 32-bit aligned (this is the expected minimum alignment for protocol
1253	* headers), and assert otherwise.
1254	*/
1255	#if defined(__i386__) \|\| defined(__x86_64__)
1256	#define MBUF_STRICT_DATA_ALIGNMENT_CHECK_32(_m)
1257	#else /* !__i386__ && !__x86_64__ */
1258	#define MBUF_STRICT_DATA_ALIGNMENT_CHECK_32(_m) do { \
1259	if (!IS_P2ALIGNED((_m)->m_data, sizeof (u_int32_t))) { \
1260	if (((_m)->m_flags & M_PKTHDR) && \
1261	(_m)->m_pkthdr.rcvif != NULL) { \
1262	panic_plain("\n%s: mbuf %p data ptr %p is not " \
1263	"32-bit aligned [%s: alignerrs=%lld]\n", \
1264	__func__, (_m), (_m)->m_data, \
1265	if_name((_m)->m_pkthdr.rcvif), \
1266	(_m)->m_pkthdr.rcvif->if_alignerrs); \
1267	} else { \
1268	panic_plain("\n%s: mbuf %p data ptr %p is not " \
1269	"32-bit aligned\n", \
1270	__func__, (_m), (_m)->m_data); \
1271	} \
1272	} \
1273	} while (0)
1274	#endif /* !__i386__ && !__x86_64__ */
1275
1276	/ Maximum number of MBUF_SC values (excluding MBUF_SC_UNSPEC) /
1277	#define MBUF_SC_MAX_CLASSES 10
1278
1279	/*
1280	* These conversion macros rely on the corresponding MBUF_SC and
1281	* MBUF_TC values in order to establish the following mapping:
1282	*
1283	* MBUF_SC_BK_SYS ] ==> MBUF_TC_BK
1284	* MBUF_SC_BK ]
1285	*
1286	* MBUF_SC_BE ] ==> MBUF_TC_BE
1287	* MBUF_SC_RD ]
1288	* MBUF_SC_OAM ]
1289	*
1290	* MBUF_SC_AV ] ==> MBUF_TC_VI
1291	* MBUF_SC_RV ]
1292	* MBUF_SC_VI ]
1293	* MBUF_SC_SIG ]
1294	*
1295	* MBUF_SC_VO ] ==> MBUF_TC_VO
1296	* MBUF_SC_CTL ]
1297	*
1298	* The values assigned to each service class allows for a fast mapping to
1299	* the corresponding MBUF_TC traffic class values, as well as to retrieve the
1300	* assigned index; therefore care must be taken when comparing against these
1301	* values. Use the corresponding class and index macros to retrieve the
1302	* corresponding portion, and never assume that a higher class corresponds
1303	* to a higher index.
1304	*/
1305	#define MBUF_SCVAL(x) ((x) & 0xffff)
1306	#define MBUF_SCIDX(x) ((((x) >> 16) & 0xff) >> 3)
1307	#define MBUF_SC2TC(_sc) (MBUF_SCVAL(_sc) >> 7)
1308	#define MBUF_TC2SCVAL(_tc) ((_tc) << 7)
1309	#define IS_MBUF_SC_BACKGROUND(_sc) (((_sc) == MBUF_SC_BK_SYS) \|\| \
1310	((_sc) == MBUF_SC_BK))
1311	#define IS_MBUF_SC_REALTIME(_sc) ((_sc) >= MBUF_SC_AV && (_sc) <= MBUF_SC_VO)
1312	#define IS_MBUF_SC_BESTEFFORT(_sc) ((_sc) == MBUF_SC_BE \|\| \
1313	(_sc) == MBUF_SC_RD \|\| (_sc) == MBUF_SC_OAM)
1314
1315	#define SCIDX_BK_SYS MBUF_SCIDX(MBUF_SC_BK_SYS)
1316	#define SCIDX_BK MBUF_SCIDX(MBUF_SC_BK)
1317	#define SCIDX_BE MBUF_SCIDX(MBUF_SC_BE)
1318	#define SCIDX_RD MBUF_SCIDX(MBUF_SC_RD)
1319	#define SCIDX_OAM MBUF_SCIDX(MBUF_SC_OAM)
1320	#define SCIDX_AV MBUF_SCIDX(MBUF_SC_AV)
1321	#define SCIDX_RV MBUF_SCIDX(MBUF_SC_RV)
1322	#define SCIDX_VI MBUF_SCIDX(MBUF_SC_VI)
1323	#define SCIDX_SIG MBUF_SCIDX(MBUF_SC_SIG)
1324	#define SCIDX_VO MBUF_SCIDX(MBUF_SC_VO)
1325	#define SCIDX_CTL MBUF_SCIDX(MBUF_SC_CTL)
1326
1327	#define SCVAL_BK_SYS MBUF_SCVAL(MBUF_SC_BK_SYS)
1328	#define SCVAL_BK MBUF_SCVAL(MBUF_SC_BK)
1329	#define SCVAL_BE MBUF_SCVAL(MBUF_SC_BE)
1330	#define SCVAL_RD MBUF_SCVAL(MBUF_SC_RD)
1331	#define SCVAL_OAM MBUF_SCVAL(MBUF_SC_OAM)
1332	#define SCVAL_AV MBUF_SCVAL(MBUF_SC_AV)
1333	#define SCVAL_RV MBUF_SCVAL(MBUF_SC_RV)
1334	#define SCVAL_VI MBUF_SCVAL(MBUF_SC_VI)
1335	#define SCVAL_SIG MBUF_SCVAL(MBUF_SC_SIG)
1336	#define SCVAL_VO MBUF_SCVAL(MBUF_SC_VO)
1337	#define SCVAL_CTL MBUF_SCVAL(MBUF_SC_CTL)
1338
1339	#define MBUF_VALID_SC(c) \
1340	(c == MBUF_SC_BK_SYS \|\| c == MBUF_SC_BK \|\| c == MBUF_SC_BE \|\| \
1341	c == MBUF_SC_RD \|\| c == MBUF_SC_OAM \|\| c == MBUF_SC_AV \|\| \
1342	c == MBUF_SC_RV \|\| c == MBUF_SC_VI \|\| c == MBUF_SC_SIG \|\| \
1343	c == MBUF_SC_VO \|\| c == MBUF_SC_CTL)
1344
1345	#define MBUF_VALID_SCIDX(c) \
1346	(c == SCIDX_BK_SYS \|\| c == SCIDX_BK \|\| c == SCIDX_BE \|\| \
1347	c == SCIDX_RD \|\| c == SCIDX_OAM \|\| c == SCIDX_AV \|\| \
1348	c == SCIDX_RV \|\| c == SCIDX_VI \|\| c == SCIDX_SIG \|\| \
1349	c == SCIDX_VO \|\| c == SCIDX_CTL)
1350
1351	#define MBUF_VALID_SCVAL(c) \
1352	(c == SCVAL_BK_SYS \|\| c == SCVAL_BK \|\| c == SCVAL_BE \|\| \
1353	c == SCVAL_RD \|\| c == SCVAL_OAM \|\| c == SCVAL_AV \|\| \
1354	c == SCVAL_RV \|\| c == SCVAL_VI \|\| c == SCVAL_SIG \|\| \
1355	c == SCVAL_VO \|\| SCVAL_CTL)
1356
1357	extern unsigned char mbutl; /* start VA of mbuf pool /
1358	extern unsigned char embutl; /* end VA of mbuf pool /
1359	extern unsigned int nmbclusters; / number of mapped clusters /
1360	extern int njcl; / # of jumbo clusters /
1361	extern int njclbytes; / size of a jumbo cluster /
1362	extern int max_hdr; / largest link+protocol header /
1363	extern int max_datalen; / MHLEN - max_hdr /
1364
1365	/ Use max_linkhdr instead of _max_linkhdr /
1366	extern int _max_linkhdr; / largest link-level header /
1367
1368	/ Use max_protohdr instead of _max_protohdr /
1369	extern int _max_protohdr; / largest protocol header /
1370
1371	__private_extern__ unsigned int mbuf_default_ncl(int, u_int64_t);
1372	__private_extern__ void mbinit(void);
1373	__private_extern__ struct mbuf m_clattach(struct* mbuf , int*, caddr_t,
1374	void ()(caddr_t, u_int, caddr_t), u_int, caddr_t, int, int*);
1375	__private_extern__ caddr_t m_bigalloc(int);
1376	__private_extern__ void m_bigfree(caddr_t, u_int, caddr_t);
1377	__private_extern__ struct mbuf m_mbigget(struct* mbuf , int*);
1378	__private_extern__ caddr_t m_16kalloc(int);
1379	__private_extern__ void m_16kfree(caddr_t, u_int, caddr_t);
1380	__private_extern__ struct mbuf m_m16kget(struct* mbuf , int*);
1381	__private_extern__ int m_reinit(struct mbuf , int*);
1382	__private_extern__ struct mbuf m_free(struct* mbuf *);
1383	__private_extern__ struct mbuf m_getclr(int, int*);
1384	__private_extern__ struct mbuf m_getptr(struct* mbuf , int, int* *);
1385	__private_extern__ unsigned int m_length(struct mbuf *);
1386	__private_extern__ unsigned int m_length2(struct mbuf , struct* mbuf **);
1387	__private_extern__ unsigned int m_fixhdr(struct mbuf *);
1388	__private_extern__ struct mbuf m_defrag(struct* mbuf , int*);
1389	__private_extern__ struct mbuf m_defrag_offset(struct* mbuf , u_int32_t, int*);
1390	__private_extern__ struct mbuf m_prepend(struct* mbuf , int, int*);
1391	__private_extern__ struct mbuf m_copyup(struct* mbuf , int, int*);
1392	__private_extern__ struct mbuf m_retry(int, int*);
1393	__private_extern__ struct mbuf m_retryhdr(int, int*);
1394	__private_extern__ int m_freem_list(struct mbuf *);
1395	__private_extern__ int m_append(struct mbuf , int*, caddr_t);
1396	__private_extern__ struct mbuf m_last(struct* mbuf *);
1397	__private_extern__ struct mbuf m_devget(char* , int, int, struct* ifnet *,
1398	void ()(const* void , void* *, size_t));
1399	__private_extern__ struct mbuf m_pulldown(struct* mbuf , int, int, int* *);
1400
1401	__private_extern__ struct mbuf m_getcl(int, int, int*);
1402	__private_extern__ caddr_t m_mclalloc(int);
1403	__private_extern__ int m_mclhasreference(struct mbuf *);
1404	__private_extern__ void m_copy_pkthdr(struct mbuf , struct* mbuf *);
1405	__private_extern__ void m_copy_pftag(struct mbuf , struct* mbuf *);
1406	__private_extern__ void m_copy_classifier(struct mbuf , struct* mbuf *);
1407
1408	__private_extern__ struct mbuf m_dtom(void* *);
1409	__private_extern__ int m_mtocl(void *);
1410	__private_extern__ union mcluster m_cltom(int*);
1411
1412	__private_extern__ void m_align(struct mbuf , int*);
1413
1414	__private_extern__ struct mbuf m_normalize(struct* mbuf *m);
1415	__private_extern__ void m_mchtype(struct mbuf m, int* t);
1416	__private_extern__ void m_mcheck(struct mbuf *);
1417
1418	__private_extern__ void m_copyback(struct mbuf , int, int, const* void *);
1419	__private_extern__ struct mbuf m_copyback_cow(struct* mbuf , int, int*,
1420	const void , int*);
1421	__private_extern__ int m_makewritable(struct mbuf *, int, int, int*);
1422	__private_extern__ struct mbuf m_dup(struct* mbuf m, int* how);
1423	__private_extern__ struct mbuf m_copym_with_hdrs(struct* mbuf , int, int, int*,
1424	struct mbuf *, int* *, uint32_t);
1425	__private_extern__ struct mbuf m_getpackethdrs(int, int*);
1426	__private_extern__ struct mbuf m_getpacket_how(int*);
1427	__private_extern__ struct mbuf m_getpackets_internal(unsigned* int , int*,
1428	int, int, size_t);
1429	__private_extern__ struct mbuf m_allocpacket_internal(unsigned* int *, size_t,
1430	unsigned int , int, int*, size_t);
1431
1432	__private_extern__ int m_ext_set_prop(struct mbuf *, uint32_t, uint32_t);
1433	__private_extern__ uint32_t m_ext_get_prop(struct mbuf *);
1434	__private_extern__ int m_ext_paired_is_active(struct mbuf *);
1435	__private_extern__ void m_ext_paired_activate(struct mbuf *);
1436
1437	__private_extern__ void mbuf_drain(boolean_t);
1438
1439	/*
1440	* Packets may have annotations attached by affixing a list of "packet
1441	* tags" to the pkthdr structure. Packet tags are dynamically allocated
1442	* semi-opaque data structures that have a fixed header (struct m_tag)
1443	* that specifies the size of the memory block and an <id,type> pair that
1444	* identifies it. The id identifies the module and the type identifies the
1445	* type of data for that module. The id of zero is reserved for the kernel.
1446	*
1447	* Note that the packet tag returned by m_tag_allocate has the default
1448	* memory alignment implemented by malloc. To reference private data one
1449	* can use a construct like:
1450	*
1451	* struct m_tag *mtag = m_tag_allocate(...);
1452	* struct foo p = (struct foo )(mtag+1);
1453	*
1454	* if the alignment of struct m_tag is sufficient for referencing members
1455	* of struct foo. Otherwise it is necessary to embed struct m_tag within
1456	* the private data structure to insure proper alignment; e.g.
1457	*
1458	* struct foo {
1459	* struct m_tag tag;
1460	* ...
1461	* };
1462	* struct foo p = (struct foo ) m_tag_allocate(...);
1463	* struct m_tag *mtag = &p->tag;
1464	*/
1465
1466	#define KERNEL_MODULE_TAG_ID 0
1467
1468	enum {
1469	KERNEL_TAG_TYPE_NONE = `0`,
1470	KERNEL_TAG_TYPE_DUMMYNET = `1`,
1471	KERNEL_TAG_TYPE_DIVERT = `2`,
1472	KERNEL_TAG_TYPE_IPFORWARD = `3`,
1473	KERNEL_TAG_TYPE_IPFILT = `4`,
1474	KERNEL_TAG_TYPE_MACLABEL = `5`,
1475	KERNEL_TAG_TYPE_MAC_POLICY_LABEL = `6`,
1476	KERNEL_TAG_TYPE_ENCAP = `8`,
1477	KERNEL_TAG_TYPE_INET6 = `9`,
1478	KERNEL_TAG_TYPE_IPSEC = `10`,
1479	KERNEL_TAG_TYPE_DRVAUX = `11`,
1480	KERNEL_TAG_TYPE_CFIL_UDP = `13`,
1481	};
1482
1483	/ Packet tag routines /
1484	__private_extern__ struct m_tag m_tag_alloc(u_int32_t, u_int16_t, int, int*);
1485	__private_extern__ struct m_tag m_tag_create(u_int32_t, u_int16_t, int, int*,
1486	struct mbuf *);
1487	__private_extern__ void m_tag_free(struct m_tag *);
1488	__private_extern__ void m_tag_prepend(struct mbuf , struct* m_tag *);
1489	__private_extern__ void m_tag_unlink(struct mbuf , struct* m_tag *);
1490	__private_extern__ void m_tag_delete(struct mbuf , struct* m_tag *);
1491	__private_extern__ void m_tag_delete_chain(struct mbuf , struct* m_tag *);
1492	__private_extern__ struct m_tag m_tag_locate(struct* mbuf *, u_int32_t,
1493	u_int16_t, struct m_tag *);
1494	__private_extern__ struct m_tag m_tag_copy(struct* m_tag , int*);
1495	__private_extern__ int m_tag_copy_chain(struct mbuf , struct* mbuf , int*);
1496	__private_extern__ void m_tag_init(struct mbuf , int*);
1497	__private_extern__ struct m_tag m_tag_first(struct* mbuf *);
1498	__private_extern__ struct m_tag m_tag_next(struct* mbuf , struct* m_tag *);
1499
1500	__private_extern__ void m_scratch_init(struct mbuf *);
1501	__private_extern__ u_int32_t m_scratch_get(struct mbuf , u_int8_t *);
1502
1503	__private_extern__ void m_classifier_init(struct mbuf *, uint32_t);
1504
1505	__private_extern__ int m_set_service_class(struct mbuf *, mbuf_svc_class_t);
1506	__private_extern__ mbuf_svc_class_t m_get_service_class(struct mbuf *);
1507	__private_extern__ mbuf_svc_class_t m_service_class_from_idx(u_int32_t);
1508	__private_extern__ mbuf_svc_class_t m_service_class_from_val(u_int32_t);
1509	__private_extern__ int m_set_traffic_class(struct mbuf *, mbuf_traffic_class_t);
1510	__private_extern__ mbuf_traffic_class_t m_get_traffic_class(struct mbuf *);
1511
1512	#define ADDCARRY(_x) do { \
1513	while (((_x) >> 16) != 0) \
1514	(_x) = ((_x) >> 16) + ((_x) & 0xffff); \
1515	} while (0)
1516
1517	__private_extern__ u_int16_t m_adj_sum16(struct mbuf *, u_int32_t,
1518	u_int32_t, u_int32_t, u_int32_t);
1519	__private_extern__ u_int16_t m_sum16(struct mbuf *, u_int32_t, u_int32_t);
1520
1521	__private_extern__ void m_set_ext(struct mbuf , struct* ext_ref *,
1522	m_ext_free_func_t, caddr_t);
1523	__private_extern__ struct ext_ref m_get_rfa(struct* mbuf *);
1524	__private_extern__ m_ext_free_func_t m_get_ext_free(struct mbuf *);
1525	__private_extern__ caddr_t m_get_ext_arg(struct mbuf *);
1526
1527	__private_extern__ void m_do_tx_compl_callback(struct mbuf , struct* ifnet *);
1528	__private_extern__ mbuf_tx_compl_func m_get_tx_compl_callback(u_int32_t);
1529
1530	__END_DECLS
1531	#endif /* XNU_KERNEL_PRIVATE */
1532	#endif /* !_SYS_MBUF_H_ */
1533

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