]> git.saurik.com Git - apple/xnu.git/blob - bsd/sys/kern_control.h
xnu-3248.60.10.tar.gz
[apple/xnu.git] / bsd / sys / kern_control.h
1 /*
2 * Copyright (c) 2000-2004, 2012-2015 Apple Inc. All rights reserved.
3 *
4 * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
5 *
6 * This file contains Original Code and/or Modifications of Original Code
7 * as defined in and that are subject to the Apple Public Source License
8 * Version 2.0 (the 'License'). You may not use this file except in
9 * compliance with the License. The rights granted to you under the License
10 * may not be used to create, or enable the creation or redistribution of,
11 * unlawful or unlicensed copies of an Apple operating system, or to
12 * circumvent, violate, or enable the circumvention or violation of, any
13 * terms of an Apple operating system software license agreement.
14 *
15 * Please obtain a copy of the License at
16 * http://www.opensource.apple.com/apsl/ and read it before using this file.
17 *
18 * The Original Code and all software distributed under the License are
19 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
20 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
21 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
22 * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
23 * Please see the License for the specific language governing rights and
24 * limitations under the License.
25 *
26 * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
27 */
28 /*!
29 @header kern_control.h
30 This header defines an API to communicate between a kernel
31 extension and a process outside of the kernel.
32 */
33
34 #ifndef KPI_KERN_CONTROL_H
35 #define KPI_KERN_CONTROL_H
36
37
38 #include <sys/appleapiopts.h>
39
40 /*
41 * Define Controller event subclass, and associated events.
42 * Subclass of KEV_SYSTEM_CLASS
43 */
44
45 /*!
46 @defined KEV_CTL_SUBCLASS
47 @discussion The kernel event subclass for kernel control events.
48 */
49 #define KEV_CTL_SUBCLASS 2
50
51 /*!
52 @defined KEV_CTL_REGISTERED
53 @discussion The event code indicating a new controller was
54 registered. The data portion will contain a ctl_event_data.
55 */
56 #define KEV_CTL_REGISTERED 1 /* a new controller appears */
57
58 /*!
59 @defined KEV_CTL_DEREGISTERED
60 @discussion The event code indicating a controller was unregistered.
61 The data portion will contain a ctl_event_data.
62 */
63 #define KEV_CTL_DEREGISTERED 2 /* a controller disappears */
64
65 /*!
66 @struct ctl_event_data
67 @discussion This structure is used for KEV_CTL_SUBCLASS kernel
68 events.
69 @field ctl_id The kernel control id.
70 @field ctl_unit The kernel control unit.
71 */
72 struct ctl_event_data {
73 u_int32_t ctl_id; /* Kernel Controller ID */
74 u_int32_t ctl_unit;
75 };
76
77 /*
78 * Controls destined to the Controller Manager.
79 */
80
81 /*!
82 @defined CTLIOCGCOUNT
83 @discussion The CTLIOCGCOUNT ioctl can be used to determine the
84 number of kernel controllers registered.
85 */
86 #define CTLIOCGCOUNT _IOR('N', 2, int) /* get number of control structures registered */
87
88 /*!
89 @defined CTLIOCGINFO
90 @discussion The CTLIOCGINFO ioctl can be used to convert a kernel
91 control name to a kernel control id.
92 */
93 #define CTLIOCGINFO _IOWR('N', 3, struct ctl_info) /* get id from name */
94
95
96 /*!
97 @defined MAX_KCTL_NAME
98 @discussion Kernel control names must be no longer than
99 MAX_KCTL_NAME.
100 */
101 #define MAX_KCTL_NAME 96
102
103 /*
104 * Controls destined to the Controller Manager.
105 */
106
107 /*!
108 @struct ctl_info
109 @discussion This structure is used with the CTLIOCGINFO ioctl to
110 translate from a kernel control name to a control id.
111 @field ctl_id The kernel control id, filled out upon return.
112 @field ctl_name The kernel control name to find.
113 */
114 struct ctl_info {
115 u_int32_t ctl_id; /* Kernel Controller ID */
116 char ctl_name[MAX_KCTL_NAME]; /* Kernel Controller Name (a C string) */
117 };
118
119
120 /*!
121 @struct sockaddr_ctl
122 @discussion The controller address structure is used to establish
123 contact between a user client and a kernel controller. The
124 sc_id/sc_unit uniquely identify each controller. sc_id is a
125 unique identifier assigned to the controller. The identifier can
126 be assigned by the system at registration time or be a 32-bit
127 creator code obtained from Apple Computer. sc_unit is a unit
128 number for this sc_id, and is privately used by the kernel
129 controller to identify several instances of the controller.
130 @field sc_len The length of the structure.
131 @field sc_family AF_SYSTEM.
132 @field ss_sysaddr AF_SYS_KERNCONTROL.
133 @field sc_id Controller unique identifier.
134 @field sc_unit Kernel controller private unit number.
135 @field sc_reserved Reserved, must be set to zero.
136 */
137 struct sockaddr_ctl {
138 u_char sc_len; /* depends on size of bundle ID string */
139 u_char sc_family; /* AF_SYSTEM */
140 u_int16_t ss_sysaddr; /* AF_SYS_KERNCONTROL */
141 u_int32_t sc_id; /* Controller unique identifier */
142 u_int32_t sc_unit; /* Developer private unit number */
143 u_int32_t sc_reserved[5];
144 };
145
146 #ifdef PRIVATE
147
148 struct xkctl_reg {
149 u_int32_t xkr_len;
150 u_int32_t xkr_kind;
151 u_int32_t xkr_id;
152 u_int32_t xkr_reg_unit;
153 u_int32_t xkr_flags;
154 u_int64_t xkr_kctlref;
155 u_int32_t xkr_recvbufsize;
156 u_int32_t xkr_sendbufsize;
157 u_int32_t xkr_lastunit;
158 u_int32_t xkr_pcbcount;
159 u_int64_t xkr_connect;
160 u_int64_t xkr_disconnect;
161 u_int64_t xkr_send;
162 u_int64_t xkr_send_list;
163 u_int64_t xkr_setopt;
164 u_int64_t xkr_getopt;
165 u_int64_t xkr_rcvd;
166 char xkr_name[MAX_KCTL_NAME];
167 };
168
169 struct xkctlpcb {
170 u_int32_t xkp_len;
171 u_int32_t xkp_kind;
172 u_int64_t xkp_kctpcb;
173 u_int32_t xkp_unit;
174 u_int32_t xkp_kctlid;
175 u_int64_t xkp_kctlref;
176 char xkp_kctlname[MAX_KCTL_NAME];
177 };
178
179 struct kctlstat {
180 u_int64_t kcs_reg_total __attribute__((aligned(8)));
181 u_int64_t kcs_reg_count __attribute__((aligned(8)));
182 u_int64_t kcs_pcbcount __attribute__((aligned(8)));
183 u_int64_t kcs_gencnt __attribute__((aligned(8)));
184 u_int64_t kcs_connections __attribute__((aligned(8)));
185 u_int64_t kcs_conn_fail __attribute__((aligned(8)));
186 u_int64_t kcs_send_fail __attribute__((aligned(8)));
187 u_int64_t kcs_send_list_fail __attribute__((aligned(8)));
188 u_int64_t kcs_enqueue_fail __attribute__((aligned(8)));
189 u_int64_t kcs_enqueue_fullsock __attribute__((aligned(8)));
190 u_int64_t kcs_bad_kctlref __attribute__((aligned(8)));
191 };
192
193 #endif /* PRIVATE */
194
195 #ifdef KERNEL
196
197 #include <sys/kpi_mbuf.h>
198
199 /*!
200 @typedef kern_ctl_ref
201 @discussion A control reference is used to track an attached kernel
202 control. Registering a kernel control will create a kernel
203 control reference. This reference is required for sending data
204 or removing the kernel control. This reference will be passed to
205 callbacks for that kernel control.
206 */
207 typedef void * kern_ctl_ref;
208
209 /*!
210 @defined CTL_FLAG_PRIVILEGED
211 @discussion The CTL_FLAG_PRIVILEGED flag is passed in ctl_flags. If
212 this flag is set, only privileged processes may attach to this
213 kernel control.
214 */
215 #define CTL_FLAG_PRIVILEGED 0x1
216 /*!
217 @defined CTL_FLAG_REG_ID_UNIT
218 @discussion The CTL_FLAG_REG_ID_UNIT flag is passed to indicate that
219 the ctl_id specified should be used. If this flag is not
220 present, a unique ctl_id will be dynamically assigned to your
221 kernel control. The CTLIOCGINFO ioctl can be used by the client
222 to find the dynamically assigned id based on the control name
223 specified in ctl_name.
224 */
225 #define CTL_FLAG_REG_ID_UNIT 0x2
226 /*!
227 @defined CTL_FLAG_REG_SOCK_STREAM
228 @discussion Use the CTL_FLAG_REG_SOCK_STREAM flag when client need to open
229 socket of type SOCK_STREAM to communicate with the kernel control.
230 By default kernel control sockets are of type SOCK_DGRAM.
231 */
232 #define CTL_FLAG_REG_SOCK_STREAM 0x4
233
234 #ifdef KERNEL_PRIVATE
235 /*!
236 @defined CTL_FLAG_REG_EXTENDED
237 @discussion This flag indicates that this kernel control utilizes the
238 the extended fields within the kern_ctl_reg structure.
239 */
240 #define CTL_FLAG_REG_EXTENDED 0x8
241
242 /*!
243 @defined CTL_FLAG_REG_CRIT
244 @discussion This flag indicates that this kernel control utilizes the
245 the extended fields within the kern_ctl_reg structure.
246 */
247 #define CTL_FLAG_REG_CRIT 0x10
248 #endif /* KERNEL_PRIVATE */
249
250 /* Data flags for controllers */
251 /*!
252 @defined CTL_DATA_NOWAKEUP
253 @discussion The CTL_DATA_NOWAKEUP flag can be used for the enqueue
254 data and enqueue mbuf functions to indicate that the process
255 should not be woken up yet. This is useful when you want to
256 enqueue data using more than one call but only want to wake up
257 the client after all of the data has been enqueued.
258 */
259 #define CTL_DATA_NOWAKEUP 0x1
260
261 /*!
262 @defined CTL_DATA_EOR
263 @discussion The CTL_DATA_EOR flag can be used for the enqueue
264 data and enqueue mbuf functions to mark the end of a record.
265 */
266 #define CTL_DATA_EOR 0x2
267
268 #ifdef KERNEL_PRIVATE
269 /*!
270 @defined CTL_DATA_CRIT
271 @discussion This flag indicates the data is critical to the client
272 and that it needs to be forced into the socket buffer
273 by resizing it if needed.
274 */
275 #define CTL_DATA_CRIT 0x4
276 #endif /* KERNEL_PRIVATE */
277
278 __BEGIN_DECLS
279
280 /*!
281 @typedef ctl_connect_func
282 @discussion The ctl_connect_func is used to receive
283 notification of a client connecting to the kernel control.
284 @param kctlref The control ref for the kernel control the client is
285 connecting to.
286 @param sac The address used to connect to this control. The field sc_unit
287 contains the unit number of the kernel control instance the client is
288 connecting to. If CTL_FLAG_REG_ID_UNIT was set when the kernel control
289 was registered, sc_unit is the ctl_unit of the kern_ctl_reg structure.
290 If CTL_FLAG_REG_ID_UNIT was not set when the kernel control was
291 registered, sc_unit is the dynamically allocated unit number of
292 the new kernel control instance that is used for this connection.
293 @param unitinfo A placeholder for a pointer to the optional user-defined
294 private data associated with this kernel control instance. This
295 opaque info will be provided to the user when the rest of the
296 callback routines are executed. For example, it can be used
297 to pass a pointer to an instance-specific data structure in
298 order for the user to keep track of the states related to this
299 kernel control instance.
300 */
301 typedef errno_t (*ctl_connect_func)(kern_ctl_ref kctlref,
302 struct sockaddr_ctl *sac,
303 void **unitinfo);
304
305 /*!
306 @typedef ctl_disconnect_func
307 @discussion The ctl_disconnect_func is used to receive notification
308 that a client has disconnected from the kernel control. This
309 usually happens when the socket is closed. If this is the last
310 socket attached to your kernel control, you may unregister your
311 kernel control from this callback.
312 @param kctlref The control ref for the kernel control instance the client has
313 disconnected from.
314 @param unit The unit number of the kernel control instance the client has
315 disconnected from.
316 @param unitinfo The user-defined private data initialized by the
317 ctl_connect_func callback.
318 */
319 typedef errno_t (*ctl_disconnect_func)(kern_ctl_ref kctlref, u_int32_t unit, void *unitinfo);
320
321 /*!
322 @typedef ctl_send_func
323 @discussion The ctl_send_func is used to receive data sent from
324 the client to the kernel control.
325 @param kctlref The control ref of the kernel control.
326 @param unit The unit number of the kernel control instance the client has
327 connected to.
328 @param unitinfo The user-defined private data initialized by the
329 ctl_connect_func callback.
330 @param m The data sent by the client to the kernel control in an
331 mbuf chain. Your function is responsible for releasing the
332 mbuf chain.
333 @param flags The flags specified by the client when calling
334 send/sendto/sendmsg (MSG_OOB/MSG_DONTROUTE).
335 */
336 typedef errno_t (*ctl_send_func)(kern_ctl_ref kctlref, u_int32_t unit, void *unitinfo,
337 mbuf_t m, int flags);
338
339 /*!
340 @typedef ctl_setopt_func
341 @discussion The ctl_setopt_func is used to handle set socket option
342 calls for the SYSPROTO_CONTROL option level.
343 @param kctlref The control ref of the kernel control.
344 @param unit The unit number of the kernel control instance.
345 @param unitinfo The user-defined private data initialized by the
346 ctl_connect_func callback.
347 @param opt The socket option.
348 @param data A pointer to the socket option data. The data has
349 already been copied in to the kernel for you.
350 @param len The length of the socket option data.
351 */
352 typedef errno_t (*ctl_setopt_func)(kern_ctl_ref kctlref, u_int32_t unit, void *unitinfo,
353 int opt, void *data, size_t len);
354
355 /*!
356 @typedef ctl_getopt_func
357 @discussion The ctl_getopt_func is used to handle client get socket
358 option requests for the SYSPROTO_CONTROL option level. A buffer
359 is allocated for storage and passed to your function. The length
360 of that buffer is also passed. Upon return, you should set *len
361 to length of the buffer used. In some cases, data may be NULL.
362 When this happens, *len should be set to the length you would
363 have returned had data not been NULL. If the buffer is too small,
364 return an error.
365 @param kctlref The control ref of the kernel control.
366 @param unit The unit number of the kernel control instance.
367 @param unitinfo The user-defined private data initialized by the
368 ctl_connect_func callback.
369 @param opt The socket option.
370 @param data A buffer to copy the results in to. May be NULL, see
371 discussion.
372 @param len A pointer to the length of the buffer. This should be set
373 to the length of the buffer used before returning.
374 */
375 typedef errno_t (*ctl_getopt_func)(kern_ctl_ref kctlref, u_int32_t unit, void *unitinfo,
376 int opt, void *data, size_t *len);
377
378 #ifdef KERNEL_PRIVATE
379 /*!
380 @typedef ctl_rcvd_func
381 @discussion The ctl_rcvd_func is called when the client reads data from
382 the kernel control socket. The kernel control can use this callback
383 in combination with ctl_getenqueuespace() to avoid overflowing
384 the socket's receive buffer. When ctl_getenqueuespace() returns
385 0 or ctl_enqueuedata()/ctl_enqueuembuf() return ENOBUFS, the
386 kernel control can wait until this callback is called before
387 trying to enqueue the data again.
388 @param kctlref The control ref of the kernel control.
389 @param unit The unit number of the kernel control instance.
390 @param unitinfo The user-defined private data initialized by the
391 ctl_connect_func callback.
392 @param flags The recv flags. See the recv(2) man page.
393 */
394 typedef void (*ctl_rcvd_func)(kern_ctl_ref kctlref, u_int32_t unit, void *unitinfo,
395 int flags);
396
397 /*!
398 @typedef ctl_send_list_func
399 @discussion The ctl_send_list_func is used to receive data sent from
400 the client to the kernel control.
401 @param kctlref The control ref of the kernel control.
402 @param unit The unit number of the kernel control instance the client has
403 connected to.
404 @param unitinfo The user-defined private data initialized by the
405 ctl_connect_func callback.
406 @param m The data sent by the client to the kernel control in an
407 mbuf packet chain. Your function is responsible for releasing
408 mbuf packet chain.
409 @param flags The flags specified by the client when calling
410 send/sendto/sendmsg (MSG_OOB/MSG_DONTROUTE).
411 */
412 typedef errno_t (*ctl_send_list_func)(kern_ctl_ref kctlref, u_int32_t unit, void *unitinfo,
413 mbuf_t m, int flags);
414 #endif /* KERNEL_PRIVATE */
415
416 /*!
417 @struct kern_ctl_reg
418 @discussion This structure defines the properties of a kernel
419 control being registered.
420 @field ctl_name A Bundle ID string of up to MAX_KCTL_NAME bytes (including the ending zero).
421 This string should not be empty.
422 @field ctl_id The control ID may be dynamically assigned or it can be a
423 32-bit creator code assigned by DTS.
424 For a DTS assigned creator code the CTL_FLAG_REG_ID_UNIT flag must be set.
425 For a dynamically assigned control ID, do not set the CTL_FLAG_REG_ID_UNIT flag.
426 The value of the dynamically assigned control ID is set to this field
427 when the registration succeeds.
428 @field ctl_unit A separate unit number to register multiple units that
429 share the same control ID with DTS assigned creator code when
430 the CTL_FLAG_REG_ID_UNIT flag is set.
431 This field is ignored for a dynamically assigned control ID.
432 @field ctl_flags CTL_FLAG_PRIVILEGED and/or CTL_FLAG_REG_ID_UNIT.
433 @field ctl_sendsize Override the default send size. If set to zero,
434 the default send size will be used, and this default value
435 is set to this field to be retrieved by the caller.
436 @field ctl_recvsize Override the default receive size. If set to
437 zero, the default receive size will be used, and this default value
438 is set to this field to be retrieved by the caller.
439 @field ctl_connect Specify the function to be called whenever a client
440 connects to the kernel control. This field must be specified.
441 @field ctl_disconnect Specify a function to be called whenever a
442 client disconnects from the kernel control.
443 @field ctl_send Specify a function to handle data send from the
444 client to the kernel control.
445 @field ctl_setopt Specify a function to handle set socket option
446 operations for the kernel control.
447 @field ctl_getopt Specify a function to handle get socket option
448 operations for the kernel control.
449 */
450 struct kern_ctl_reg
451 {
452 /* control information */
453 char ctl_name[MAX_KCTL_NAME];
454 u_int32_t ctl_id;
455 u_int32_t ctl_unit;
456
457 /* control settings */
458 u_int32_t ctl_flags;
459 u_int32_t ctl_sendsize;
460 u_int32_t ctl_recvsize;
461
462 /* Dispatch functions */
463 ctl_connect_func ctl_connect;
464 ctl_disconnect_func ctl_disconnect;
465 ctl_send_func ctl_send;
466 ctl_setopt_func ctl_setopt;
467 ctl_getopt_func ctl_getopt;
468 #ifdef KERNEL_PRIVATE
469 ctl_rcvd_func ctl_rcvd; /* Only valid if CTL_FLAG_REG_EXTENDED is set */
470 ctl_send_list_func ctl_send_list; /* Only valid if CTL_FLAG_REG_EXTENDED is set */
471 #endif /* KERNEL_PRIVATE */
472 };
473
474 /*!
475 @function ctl_register
476 @discussion Register a kernel control. This will enable clients to
477 connect to the kernel control using a PF_SYSTEM socket.
478 @param userkctl A structure defining the kernel control to be
479 attached. The ctl_connect callback must be specified, the other callbacks
480 are optional. If ctl_connect is set to zero, ctl_register fails with
481 the error code EINVAL.
482 @param kctlref Upon successful return, the kctlref will contain a
483 reference to the attached kernel control. This reference is used
484 to unregister the kernel control. This reference will also be
485 passed in to the callbacks each time they are called.
486 @result 0 - Kernel control was registered.
487 EINVAL - The registration structure was not valid.
488 ENOMEM - There was insufficient memory.
489 EEXIST - A controller with that id/unit is already registered.
490 */
491 errno_t
492 ctl_register(struct kern_ctl_reg *userkctl, kern_ctl_ref *kctlref);
493
494 /*!
495 @function ctl_deregister
496 @discussion Unregister a kernel control. A kernel extension must
497 unregister it's kernel control(s) before unloading. If a kernel
498 control has clients attached, this call will fail.
499 @param kctlref The control reference of the control to unregister.
500 @result 0 - Kernel control was unregistered.
501 EINVAL - The kernel control reference was invalid.
502 EBUSY - The kernel control has clients still attached.
503 */
504 errno_t
505 ctl_deregister(kern_ctl_ref kctlref);
506
507 /*!
508 @function ctl_enqueuedata
509 @discussion Send data from the kernel control to the client.
510 @param kctlref The control reference of the kernel control.
511 @param unit The unit number of the kernel control instance.
512 @param data A pointer to the data to send.
513 @param len The length of data to send.
514 @param flags Send flags. CTL_DATA_NOWAKEUP and CTL_DATA_EOR are currently
515 the only supported flags.
516 @result 0 - Data was enqueued to be read by the client.
517 EINVAL - Invalid parameters.
518 EMSGSIZE - The buffer is too large.
519 ENOBUFS - The queue is full or there are no free mbufs.
520 */
521 errno_t
522 ctl_enqueuedata(kern_ctl_ref kctlref, u_int32_t unit, void *data, size_t len, u_int32_t flags);
523
524 /*!
525 @function ctl_enqueuembuf
526 @discussion Send data stored in an mbuf chain from the kernel
527 control to the client. The caller is responsible for freeing
528 the mbuf chain if ctl_enqueuembuf returns an error.
529 @param kctlref The control reference of the kernel control.
530 @param unit The unit number of the kernel control instance.
531 @param m An mbuf chain containing the data to send to the client.
532 @param flags Send flags. CTL_DATA_NOWAKEUP and CTL_DATA_EOR are currently
533 the only supported flags.
534 @result 0 - Data was enqueued to be read by the client.
535 EINVAL - Invalid parameters.
536 ENOBUFS - The queue is full.
537 */
538 errno_t
539 ctl_enqueuembuf(kern_ctl_ref kctlref, u_int32_t unit, mbuf_t m, u_int32_t flags);
540
541 #ifdef PRIVATE
542 /*!
543 @function ctl_enqueuembuf_list
544 @discussion Send data stored in an mbuf packet chain from the kernel
545 control to the client. The caller is responsible for freeing
546 the mbuf chain if ctl_enqueuembuf returns an error.
547 Not valid if ctl_flags contains CTL_FLAG_REG_SOCK_STREAM.
548 @param kctlref The control reference of the kernel control.
549 @param unit The unit number of the kernel control instance.
550 @param m An mbuf chain containing the data to send to the client.
551 @param flags Send flags. CTL_DATA_NOWAKEUP is
552 the only supported flags.
553 @param m_remain A pointer to the list of mbuf packets in the chain that
554 could not be enqueued.
555 @result 0 - Data was enqueued to be read by the client.
556 EINVAL - Invalid parameters.
557 ENOBUFS - The queue is full.
558 */
559 errno_t
560 ctl_enqueuembuf_list(kern_ctl_ref kctlref, u_int32_t unit, mbuf_t m_list,
561 u_int32_t flags, mbuf_t *m_remain);
562
563 /*!
564 @function ctl_getenqueuepacketcount
565 @discussion Retrieve the number of packets in the socket
566 receive buffer.
567 @param kctlref The control reference of the kernel control.
568 @param unit The unit number of the kernel control instance.
569 @param pcnt The address where to return the current count.
570 @result 0 - Success; the packet count is returned to caller.
571 EINVAL - Invalid parameters.
572 */
573 errno_t
574 ctl_getenqueuepacketcount(kern_ctl_ref kctlref, u_int32_t unit, u_int32_t *pcnt);
575
576 #endif /* PRIVATE */
577
578 /*!
579 @function ctl_getenqueuespace
580 @discussion Retrieve the amount of space currently available for data to be sent
581 from the kernel control to the client.
582 @param kctlref The control reference of the kernel control.
583 @param unit The unit number of the kernel control instance.
584 @param space The address where to return the current space available
585 @result 0 - Success; the amount of space is returned to caller.
586 EINVAL - Invalid parameters.
587 */
588 errno_t
589 ctl_getenqueuespace(kern_ctl_ref kctlref, u_int32_t unit, size_t *space);
590
591 /*!
592 @function ctl_getenqueuereadable
593 @discussion Retrieve the difference between enqueued bytes and
594 low-water mark for the socket receive buffer.
595 @param kctlref The control reference of the kernel control.
596 @param unit The unit number of the kernel control instance.
597 @param u_int32_t The address at which to return the current difference
598 between the low-water mark for the socket and the number of bytes
599 enqueued. 0 indicates that the socket is readable by the client
600 (the number of bytes in the buffer is above the low-water mark).
601 @result 0 - Success; the difference is returned to caller.
602 EINVAL - Invalid parameters.
603 */
604 errno_t
605 ctl_getenqueuereadable(kern_ctl_ref kctlref, u_int32_t unit, u_int32_t *difference);
606
607 #ifdef KERNEL_PRIVATE
608
609 #include <sys/queue.h>
610 #include <libkern/locks.h>
611
612 /*
613 * internal structure maintained for each register controller
614 */
615 struct ctl_cb;
616 struct kctl;
617 struct socket;
618 struct socket_info;
619
620 void kctl_fill_socketinfo(struct socket *, struct socket_info *);
621
622 u_int32_t ctl_id_by_name(const char *name);
623 errno_t ctl_name_by_id(u_int32_t id, char *out_name, size_t maxsize);
624 #endif /* KERNEL_PRIVATE */
625
626 __END_DECLS
627 #endif /* KERNEL */
628
629 #endif /* KPI_KERN_CONTROL_H */
630