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1/*
2 * Copyright (c) 2000 Apple Computer, Inc. All rights reserved.
3 *
4 * @APPLE_LICENSE_HEADER_START@
5 *
6 * The contents of this file constitute Original Code as defined in and
7 * are subject to the Apple Public Source License Version 1.1 (the
8 * "License"). You may not use this file except in compliance with the
9 * License. Please obtain a copy of the License at
10 * http://www.apple.com/publicsource and read it before using this file.
11 *
12 * This Original Code and all software distributed under the License are
13 * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER
14 * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
15 * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
16 * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT. Please see the
17 * License for the specific language governing rights and limitations
18 * under the License.
19 *
20 * @APPLE_LICENSE_HEADER_END@
21 */
22/*
23 * @OSF_COPYRIGHT@
24 *
25 */
26/*
27 * HISTORY
28 *
29 * Revision 1.1.1.1 1998/09/22 21:05:29 wsanchez
30 * Import of Mac OS X kernel (~semeria)
31 *
32 * Revision 1.1.1.1 1998/03/07 02:25:45 wsanchez
33 * Import of OSF Mach kernel (~mburg)
34 *
35 * Revision 1.1.11.1 1996/09/17 16:34:42 bruel
36 * fixed types.
37 * [96/09/17 bruel]
38 *
39 * Revision 1.1.6.1 1995/06/13 18:20:10 sjs
40 * Merged from flipc_shared.
41 * [95/06/07 sjs]
42 *
43 * Revision 1.1.3.14 1995/05/19 00:58:14 sjs
44 * Added send_ready to shared area, used for fast check if there is something
45 * to do (and prevents the cache from getting stirred).
46 * [95/05/18 sjs]
47 *
48 * Revision 1.1.3.13 1995/05/16 20:46:28 randys
49 * Export performance valid information through performance
50 * structure rather than kernel configuration section.
51 * [95/05/16 randys]
52 *
53 * Added performance (FLIPC_PERF) config information to
54 * kernel_configuration section of comm buffer, so that user
55 * programs can find out if this information is being gathered.
56 * [95/05/16 randys]
57 *
58 * Revision 1.1.3.12 1995/05/15 14:26:54 randys
59 * Updated comments on use of acquire pointer (it's completely
60 * ignored if dpb is set) and added macros for testing !dpb and
61 * enabled at the same time.
62 * [95/05/11 randys]
63 *
64 * Change pme_process_ptr ==> sme_process_ptr (since it's being read
65 * by AIL now).
66 * [95/05/11 randys]
67 *
68 * Added private copied of release and process pointers.
69 * [95/05/11 randys]
70 *
71 * Rearrange endpoint structure to separate data with importantly
72 * different access patterns into different cache lines. This
73 * involved duplicating some (effectively constant) entries, and
74 * creating two versions of some macros.
75 * [95/05/11 randys]
76 *
77 * Revision 1.1.3.11 1995/05/08 16:06:33 randys
78 * Added comment explaining that an endpoint bufferlist must always
79 * have valid buffer pointers in all of its entries, to keep
80 * FLIPC_endpoint_buffer_available from going off the deep end. No
81 * code changes.
82 * [95/04/18 randys]
83 *
84 * Revision 1.1.3.10 1995/04/05 21:21:52 randys
85 * Added a field to the buffer control structure holding the
86 * scheduling policy chosen for the allocations lock.
87 * [95/04/05 randys]
88 *
89 * Revision 1.1.3.9 1995/03/23 20:35:19 randys
90 * Added comments indicating duplication of declarations of
91 * flipc_cb_base & flipc_cb_size in this file and in flipc_usermsg.h
92 * Modified declaration of flipc_cb_size to be unsigned long.
93 * [95/03/21 randys]
94 *
95 * Revision 1.1.3.8 1995/02/23 21:32:42 randys
96 * Added space for kernel configuration in communications buffer
97 * control structure.
98 * [95/02/22 randys]
99 *
100 * Revision 1.1.3.7 1995/02/21 17:22:58 randys
101 * Re-indented code to four space indentation
102 * [1995/02/21 16:25:32 randys]
103 *
104 * Revision 1.1.3.6 1995/02/13 22:57:29 randys
105 * Replaced all of NEXT_{ACQUIRE,RELEASE,PROCESS}_PTR macros with a
106 * single NEXT_BUFFERLIST_PTR macro.
107 * [95/02/03 randys]
108 *
109 * Revision 1.1.3.5 1995/01/26 21:01:44 randys
110 * Add performance structure into CB.
111 * [1995/01/24 21:14:31 randys]
112 *
113 * Added flag in epgroup structure to note that epgroup
114 * has a semaphore associated with it.
115 * [1995/01/19 23:02:13 randys]
116 *
117 * Add a space in the comm buffer header for the null_destination
118 * the ME sets up for the AIL. Get rid of
119 * FLIPC_ADDRESS_ENDPOINT_PTR (it isn't used)
120 * [1995/01/19 20:22:30 randys]
121 *
122 * Up the comm buffer size to 1 megabyte
123 * [1995/01/17 22:23:27 randys]
124 *
125 * Revision 1.1.3.4 1995/01/12 21:19:01 randys
126 * Minor commenting changes from dlb
127 * [1995/01/06 18:18:12 randys]
128 *
129 * Revision 1.1.3.3 1994/12/22 16:23:57 randys
130 * Fixed calculation of number of buffers on an endpoint
131 * to take size of buffer pointers into account.
132 * [1994/12/21 16:19:55 randys]
133 *
134 * Revision 1.1.3.2 1994/12/20 19:01:56 randys
135 * Moved definition of flipc_simple_lock to flipc_cb.h
136 * [1994/12/20 17:34:41 randys]
137 *
138 * Added a simple lock in the comm buffer to use for the
139 * allocations lock, along with directions as to how
140 * to use it (not like a normal simple lock).
141 * [1994/12/20 15:27:25 randys]
142 *
143 * Added error log into communications buffer control
144 * structure, and changed FLIPC_ADDRESS_ENDPOINT_PTR to
145 * correctly compute the endpoint pointer based on the
146 * new ctl structure layout.
147 * [1994/12/19 23:47:45 randys]
148 *
149 * Added filename in comment at top of each file
150 * [1994/12/19 20:28:20 randys]
151 *
152 * Add version field to epgroup to check races on buffer acquire
153 * from epgroup.
154 * [1994/12/19 18:05:04 randys]
155 *
156 * Revision 1.1.3.1 1994/12/12 17:46:12 randys
157 * Putting initial flipc implementation under flipc_shared
158 * [1994/12/12 16:27:46 randys]
159 *
160 * Revision 1.1.1.2 1994/12/11 23:11:18 randys
161 * Initial flipc code checkin
162 *
163 * $EndLog$
164 */
165
166/*
167 * mach/flipc_cb.h
168 *
169 * This file is intended to be the data structure layout for the flipc
170 * communcations buffer, both for the KKT implementation and
171 * for the eventual paragon implementation. This file should include
172 * all of the information necessary for either humans or machines to
173 * understand the data structure layout.
174 *
175 * The communications buffer is the wired section of memory used for
176 * communication between the flipc applications interface layer and
177 * the flipc message engine. No structure in it are visible to the
178 * user; the applications interface layer mediates all user access to
179 * the CB.
180 */
181
182#ifndef _MACH_FLIPC_CB_H_
183#define _MACH_FLIPC_CB_H_
184
185#include <mach/flipc_types.h>
186
187/*
188 * Flipc naming and argument ordering conventions (this applies mainly to
189 * user-interface.h, but seems inappropriate in a user-visible header file):
190 *
191 * All objects prefixed with "flipc"; uppercase for user-visible
192 * objects, lower case for internal ones.
193 *
194 * Types created with typedef will have _t suffixes.
195 *
196 * Words will be separated by '_'.
197 *
198 * Macro definitions will be all in caps.
199 *
200 * Enum members will have their initial letter (after Flipc) capitalized.
201 *
202 *
203 * For user-visible routines:
204 *
205 * The first word following the "flipc" will be the flipc object type that
206 * that routine operates on (specifically "domain", "epgroup",
207 * "endpoint", or "buffer").
208 *
209 * The object named by the first word of the call will, if an argument
210 * to the call, be the first argument.
211 *
212 * Output variables passed as pointers in the arglist will come last.
213 */
214
215/*
216 * The kinds of objects that exist in the communications buffer are:
217 *
218 * Endpoints -- Used for sending or receiving.
219 * Buffers -- Composed of a buffer header and buffer data.
220 * Endpoint groups -- Used for collecting multiple numbers of endpoints
221 * together for a select like operation.
222 */
223
224/*
225 * We can't use general pointers inside the communications buffer,
226 * since the address space on either side of the interface is
227 * different. The places where we could use pointers are:
228 *
229 * *) From endpoint sets to endpoints.
230 * *) From endpoints to buffers.
231 *
232 * The kinds of pointers we could use are:
233 * *) Byte offset from the beginning of the comm buffer. This
234 * is simple, but has the disadvantage of allowing the user to
235 * play games with pointing endpoint buffer pointers into data
236 * space, & etc.
237 * *) Rigid arrays of each type of object, with the object
238 * "pointer" being an index into the array. This avoids the
239 * above problem, but complicates memory allocation (forces
240 * allocation to be contiguous, which may force pre-deciding
241 * how much space each of the above types will take).
242 *
243 * Though we appear to be going for the rigid allocation for each type
244 * of data structure, I'm still going to do the "simple offset"
245 * solution to maintain maximum flexibility into the future.
246 * The single exception to this is that FLIPC addresses will be composed of
247 * node number and endpoint number, where the endpoint number will be
248 * the index into the endpoint array.
249 */
250
251typedef unsigned long flipc_cb_ptr;
252/* Define a null value, which doesn't point anywhere into the CB. */
253#define FLIPC_CBPTR_NULL ((flipc_cb_ptr) -1)
254
255/*
256 * Synchronization between message engine and application.
257 *
258 * In general, it isn't reasonable to allow locking and unlocking of
259 * data structures between message engine and communications buffer,
260 * as this requires the message engine to trust arbitrary user
261 * threads. The solution is to arrange all data structures so that
262 * they may be accessed by both parties without locking. The way that
263 * this is usually done is that specific variables are considered to
264 * be owned by one of the ME or the AIL, and the other party is
265 * allowed to read the variable but not to modify it. With this
266 * arrangement, implementing things like producer/consumer circular
267 * queues is possible; each agent (ME or AIL) goes around the list
268 * doing its thing, and avoids passing the pointer showing where the
269 * other agent is working.
270 *
271 * Following the above, we may divide structure members into five
272 * classes, and define prefixes for these five classes.
273 *
274 * Description Prefix
275 * -------------------------------
276 * Private to AIL pail_
277 * Private to ME pme_
278 * AIL owned, read by ME sail_
279 * ME owned, read by AIL sme_
280 * Shared in other way shrd_
281 *
282 * Shared variables may change their ownership based on their own
283 * or someone elses value (these variables may be thought of as
284 * being handed back and forth between the two entities) or on a
285 * configuration option of the structure (not handed back and forth,
286 * but still based on another variables value).
287 *
288 * In addition, I am going to put variables that are set at endpoint
289 * allocation and cleared at deallocation (but read by both sides) in
290 * a separate class; they are "AIL owned, read by ME" but are
291 * effectively constant over the synchronization protocols we care
292 * about.
293 *
294 * Constant after allocation const_
295 *
296 * Note that this ignores memory consistency issues (when the two
297 * agents are actually on two separate processors). These issues need
298 * to be explored in more detail; for now suffice it to say that the
299 * above methods work given a sequentially consistent memory model or
300 * a processor consistent memory model.
301 *
302 * Also note that an optimizing compiler may reorder our memory
303 * accesses, playing merry hell with the inter-node synchronization
304 * protocols (the compiler doesn't know about the other node, after
305 * all). To avoid this, all structure members used for
306 * synchronization will be marked volatile; this will force the
307 * compiler to keep the order and number of accesses intact. This
308 * will also force the compiler *not* to optimize way accesses to
309 * these variables, so it is wise to explicitly load the variable into
310 * a temporary once if you need to do multiple computations with it,
311 * and store it back afterwards when you are done.
312 */
313
314/*
315 * Memory allocation:
316 *
317 * For maximum simplicity in the first implementation, we need to know
318 * at comm buffer allocation time how many endpoints, endpoint_sets,
319 * and buffers we will want total, until the end of time. This
320 * masively simplifies memory allocation; there will be a single array
321 * of each type of data and the communication buffer will be taken up
322 * by the concatenation of these arrays (with some fiddling to make
323 * sure that no data crosses a page boundary).
324 *
325 * For each data type there will be a free list to which pieces of
326 * data will be added to or removed from as needed. Each data type
327 * will have a pointer in it to allow it to be linked onto the free
328 * list.
329 */
330
331/*
332 * Multiple thread access to data structures:
333 *
334 * There are several points in the communications buffer (notably
335 * endpoint accesses) when multiple application threads will be
336 * attempting operations on data structures at the same time. To
337 * multiplex these operations, we need a per-data structure lock.
338 * Lock attributes:
339 * *) This lock will not be kernel based, as such a lock would be
340 * too heavyweight to use for arbitrary sending and receiving
341 * operations).
342 * *) Because it is not kernel based, it may not be used to
343 * multiplex accesses from threads at different kernel
344 * priority levels. Deadlock would result if a low-priority
345 * thread gained the lock and then was prempted by a
346 * high-priority thread that wanted to acquire it.
347 * *) Architecture-dependent interfaces need to be designed to
348 * atomically lock and unlock this data structure.
349 *
350 * These are "simple locks" and are defined in flipc_dep.h.
351 */
352
353/*
354 * Lock type. This placement (in flipc_cb.h) is a little bit of a
355 * hack, as it really should be defined with the machine dependent lock
356 * macros. But then the machine independent lock macros have problems
357 * because they have to include it both before and after the prototypes.
358 * So rather than split the machine dependent stuff into multiple
359 * files, I'll define it here and hope that this definition works for
360 * whatever architectures we're on.
361 */
362typedef unsigned long flipc_simple_lock;
363
364/*
365 * Ownership of data structures.
366 *
367 * Please note that this is a can of worms, and that I (Randys)
368 * consider this (and it's interactions with endpoint group membership)
369 * the likeliest place for design bugs in FLIPC. Any and all should
370 * take this as an open invitation and challenge to find bugs in what
371 * follows.
372 *
373 * Rules:
374 *
375 * *) If you've disabled a structure and synched with the
376 * appropriate side of the ME, the ME won't touch it.
377 *
378 * *) If you've taken a send endpoint off of the send endpoint
379 * list and sync'd with the ME, the ME won't touch it.
380 *
381 *[The rest of this applies to the AIL only; the above rules are the
382 * only ones the ME respects. ]
383 *
384 * *) Within the AIL, a disabled structure is owned by:
385 * *) The routine that disabled it, before it is put on
386 * the free list.
387 * *) The routine that dequeued it from the free list,
388 * before it is enabled.
389 * Taking of the simple lock is not required for ownership in
390 * these cases. Taking of the simple lock is not required for
391 * the act of *enabling* the structure (you have ownership and
392 * are giving it away), however it is required for the act of
393 * disabling the structure (since it is the only valid way to
394 * take ownership of an enabled structure, and you can't
395 * modify the enabled bit without having ownership).
396 *
397 * *) The simple lock in a structure always needs to be valid, as
398 * simple locks may be taken while the structure is in any
399 * state. Simiarly, the enabled bit must always be valid,
400 * both because it's what the ME checks, and because it may be
401 * checked by the AIL while the structure is free.
402 *
403 * *) Holding the simple lock on an enabled structure imparts
404 * ownership of that structure. You are allowed to take the
405 * simple lock of a disabled structure, but ownership is not
406 * gained by doing so.
407 *
408 * *) You are allowed to read the enabled/disabled bit without
409 * owning the structure (if the structure is disabled, there
410 * may be no way to gain the ownership).
411 *
412 * *) Owning a structure allows you to do what you want with it,
413 * except:
414 * *) As mentioned above, the simple lock and
415 * enabled/disabled bit must always be valid.
416 * *) The ownership of the endpoint group related members
417 * of an endpoint structure is special; see below.
418 * *) The allocations lock must be held to manipulate the
419 * next send endpoint field of any endpoint.
420 *
421 * *) If an endpoint is on an endpoint group, the ownership of
422 * the the endpoint group related members of the structure
423 * (sail_endpoint_group and pail_next_eg_endpoint) go with the
424 * owndership of the endpoint group, not the endpoint. For
425 * this purpose only, membership is defined atomically as the
426 * sail_endpoint_group pointer being set to an endpoint group.
427 * Thus one may remove an endpoint from an endpoint group
428 * without owning the endpoint (change the sail_endpoint_group
429 * pointer last). One requires both locks to add an endpoint
430 * to an endpoint group, however.
431 *
432 * (Part of the motivation for this is that removal and
433 * addition of endpoints to endpoint groups requires
434 * modifications of pointers in other endpoint structures).
435 *
436 * *) No structure may be put on the free list if marked with any
437 * association to any other structure. Specifically, endpoint
438 * groups may have no endpoints belonging to them, and
439 * endpoints may not belong to an endpoint group or have
440 * buffers belonging to them.
441 *
442 * *) One consequence of the above is that endpoint groups may
443 * not be marked as disabled while they have any endpoints on
444 * them, as freeing an endpoint requires it to be removed from
445 * its endpoint group, and if ownership of the endpoint group
446 * cannot be gained, that is impossible.
447 *
448 * *) In theory, endpoints *may* be marked disabled while they
449 * are still on endpoint groups. In practice, they are not.
450 * This is relied on by the code which frees endpoint groups,
451 * in a non-obvious way. Specifically, that code assumes that
452 * there is no way that a call to free endpoint will return
453 * with the endpoint still on the endpoint group. Since the
454 * only way for free endpoint to fail is if the endpoint is
455 * inactive, and since the endpoint is set inactive only after
456 * free endpoint (presumably a different one) confirms that it
457 * isn't on any endpoint group, this assumption is true.
458 *
459 * Got that? Take home lesson: don't allow endpoints to be
460 * marked disabled while still on endpoint groups until you
461 * *do* get that, and are willing to take the responsibility
462 * of changing it so that it works under your new scheme.
463 *
464 * *) Ownership of the freelist(s) are gained by holding the
465 * allocations lock for the buffer, and *only* in that way.
466 * No modification of freelist, send endpoint list, or send
467 * side ME sync bits is valid without holding the allocations
468 * lock. In other words, while you can read things in the
469 * main communications buffer control structure at will, you
470 * may not change them without owning the allocations lock.
471 *
472 * *) The state where a structure is disabled but off of the
473 * freelist may be valid as an intermediate (while an AIL
474 * routine is orchestrating a transition) but is not a valid
475 * static state. This state must not survive the return to
476 * application code of the thread that disabled the structure.
477 */
478
479/*
480 * Flipc data buffer management.
481 *
482 * A buffer (whether being used for sending or receiving) may be in
483 * one of three states:
484 *
485 * READY -- Buffer held by application.
486 * PROCESSING -- Buffer held by endpoint, unprocessed. For receive endpoints,
487 * this means that the buffer is empty, waiting to be filled by
488 * an incoming message. For send endpoints, this means tht the
489 * buffer is full, waiting to be sent out.
490 * COMPLETED -- Buffer held by the endpoint, processed. For receive
491 * endpoints, this means that the buffer is full, with newly
492 * received data in it. For send endpoints, this means that the
493 * buffer is empty (*), with it's data having been sent out.
494 *
495 * (*) In point of fact the data hasn't been touched, though bits
496 * may have been fiddled with in the header data structure. But
497 * it's been sent.
498 * FREE -- The buffer is in the pool of free buffers, and may be
499 * allocated to any newly created endpoint.
500 *
501 * The transition diagram between these states is relatively simple:
502 *
503 *
504 * release
505 * /-----------------\|
506 * +----------+ -+----------+
507 * | READY | |PROCESSING|<- - - - - -
508 * +----------+_ +----------+ \
509 * ^ |\ - - - - - - - - / | | \endpoint allocate
510 * | (processed) \endpoint \
511 * | | \ free |
512 * | acquire / ------\
513 * | \ |
514 * | / (processed) >+----------+
515 * +----------+ | FREE |
516 * |COMPLETED |< - - - - - - - - - - +----------+
517 * +----------+ endpoint allocate / ^
518 * | ^- - - - - - - - - - - - - - - - - - - - - - - |
519 * | /
520 * \ endpoint free /
521 * ------------------------------------------------------/
522 *
523 * (If it doesn't look simple, imagine it without the FREE state; that
524 * state doesn't enter into almost any buffer manipulations)
525 *
526 * For send buffers, release==send, acquire==allocate, and
527 * processed==the sending done by the message engine. For receive buffers,
528 * release==release, acquire==receive, and process==the actual
529 * arrival of the message handled by the messaging engine.
530 *
531 * The choice of path from the PROCESSING state is an endpoint
532 * specific configuration option; a particular endpoint may leave a
533 * processed buffer on the endpoint, or it may release it back to the
534 * application by dropping it from the endpoint.
535 *
536 * Buffers are assigned the PROCESSING state on a newly allocated
537 * receive endpoint (to be ready to receive messages) and the
538 * COMPLETED state on a newly allocated send endpoint.
539 *
540 * The state (other than FREE) that a particular buffer is in is
541 * determined by its place on a circular queue of buffer pointers that
542 * is part of the endpoint structure. Buffers owned by the
543 * application (READY) are not pointed to by pointers on this queue.
544 * The buffer is released to the message engine by placement of a
545 * pointer to it on this queue. When the message engine is done
546 * processing the buffer, it sets a flag in the buffer header. If the
547 * endpoint is so configured, it then removes the buffer pointer from
548 * the queue; otherwise the AIL acquires the buffer (and removes the
549 * pointer from the queue) when it chooses.
550 *
551 * . . . . . .
552 * . .
553 * . .
554 * . . AIL releasing
555 * . . ^
556 * . +-------+--/
557 * . | |
558 * . |Buffers|
559 * . | to be |
560 * . |Sent or|
561 * . |Receivd|
562 * . | Into | ^ ME processing
563 * . +-------+ --/
564 * . | |
565 * . AIL | Sent | (These buffers have a flag set to indicate
566 * .Acquiring| or | that they have been processed. This
567 * . |Filled | section is optional; the endpoint may be
568 * . |buffers| configured to drop buffers after processing)
569 * . ^ | |
570 * . \--+-------+
571 * . .
572 * . .
573 * . . . . . .
574 *
575 *
576 * The AIL will refuse to acquire a buffer that has not yet been
577 * processed by the ME. Acquire will not work at all on endpoints
578 * that have been configured to drop buffers on completion.
579 *
580 * The buffer_available primitive is coded to avoid doing a
581 * (potentially costly) acquiring of the endpoint flipc lock. Since
582 * telling where there is a buffer available requires two operations
583 * (comparison of the acquire and release pointers to see if there are
584 * any buffers on the endpoint, and then indirection of the acquire
585 * pointer to see if that buffer has bee processed yet), there is a
586 * potential race that will admit the possibility of indirecting
587 * through an invalid pointer. For this reason, for the life of an
588 * endpoint, it is a requirement that all buffer pointers on the
589 * bufferlist point *somewhere* (ie. to some existing buffer), so that
590 * this indirection will not cause an access error. The
591 * buffer_available primitive may return the wrong result, but (as
592 * long as the incorrectness is transitory), this is acceptable.
593 */
594
595/* Set up the states so that FLIPC_buffer_processed can just do an
596 & and a test. */
597typedef enum {
598 flipc_Free = 0x0, flipc_Processing = 0x1,
599 flipc_Completed = 0x2, flipc_Ready = 0x3
600} flipc_buffer_state_t;
601#define FLIPC_BUFFER_PROCESSED_P(state) ((state) & 0x2)
602
603/*
604 * Data header/buffer layout.
605 *
606 * For this implementation, and probably for all time, the header
607 * immediately precedes the data in memory, and the mesaging engine
608 * will send both header and data. Our priority is message dispatch
609 * speed rather than raw bandwidth (this is the small message side of
610 * a transfer mechanism), so we don't mind that we are throwing away
611 * some bandwidth by taking up transferred space with header data.
612 *
613 * The data size will be the maximum size allowed by the underlying
614 * transport, minus the header size (available at run time). The user
615 * will be given a pointer to the data buffer, and will use this both
616 * for copying data in and out, and as an argument to the underlying
617 * flipc routines. The flipc routines will access appropriately.
618 *
619 * The header structure follows; the user data type will be offset and
620 * cast appropriately to access this.
621 */
622
623typedef struct flipc_data_buffer {
624 union {
625 FLIPC_address_t destination; /* For sending. */
626 flipc_cb_ptr free; /* Link for header free list. */
627 } u;
628
629 /* ME owned if flipc_Processing, AIL owned otherwise. May not ever
630 assume the state flipc_Ready in an optimized implementation. */
631 volatile flipc_buffer_state_t shrd_state;
632} *flipc_data_buffer_t;
633
634/*
635 * Endpoint structure.
636 *
637 * An endpoint is the data structure used for communicating buffers,
638 * either send or receive. Note that all actual circular lists of
639 * buffer pointers on the endpoints are in their own array that gets
640 * partitioned out to the various endpoints. This is because we want
641 * the endpoint structures themselves to be fixed size for easy
642 * indexing upon receit of a message. This large scale array will be
643 * of size (max_buffers_per_endpoint) * (number_of_endpoints). Both
644 * of these values are set during the domain initialization call.
645 *
646 * Note that the pointers contained in the buffer lists are pointers to
647 * buffer *headers*, not to the data.
648 */
649
650/*
651 * This structure is divided into four cache lines, separated by their
652 * usage type:
653 *
654 * *) Private data that the AIL scribbles on.
655 * *) Data the AIL writes (regularly) that the ME reads
656 * (occaisionally). The canonical example is the release pointer.
657 * *) Private data that the ME scribbles on.
658 * *) Data the ME writes (regularly) that the AIL reads (occaisionally).
659 * The canonical example is the process pointer.
660 *
661 * There are a couple of other categories of stuff, that can be shoehorned
662 * into the above:
663 * *) Constant data that both sides read regularly. This can be
664 * duplicated in the two private areas (actually, it can be
665 * duplicated in any two areas that stay in the cache of the
666 * respective processors).
667 * *) Stuff that is not accessed on the critical path; it can go
668 * almost anywhere (probably in one of the two ping-ponging
669 * cache lines).
670 * *) Stuff that is read-only for a single processor goes in that
671 * processors private data section.
672 *
673 * Duplicate entries have a "p" or a "a" suffixed to the name to
674 * indicate that fact. Note that these will usually, but not always,
675 * be "const" variables--they may be "const" variables only from the
676 * critical path viewpoint.
677 *
678 * We take cache line length as being 8 * sizeof(int).
679 */
680
681typedef struct flipc_endpoint {
682
683 /* ===Private AIL data=== */
684 /* Type of endpoint (send, recv, etc). Duplicated in private
685 ME section. */
686 FLIPC_endpoint_type_t constda_type;
687
688 /* This next value is two variables squeezed into a single word to
689 * save on memory accesses (since they are almost always read at
690 * the same time. The two variables are:
691 *
692 * const_drop_processed_buffers -- Should the message engine drop
693 * buffers after processing them (as opposed to leaving them on
694 * the endpoint)?
695 *
696 * sail_enabled (volatile) -- Is the endpoint enabled? This isn't
697 * marked constant because it is used for synchronization on
698 * endpoint deallocation.
699 *
700 * Note that to reduce test and branches, we these two variables
701 * are represented by two bits in the word (bit 0 and bit 16). It
702 * is illegal to have bits other than 0 and 16 set in this word.
703 * This assumption is used in ENABLED_AND_NOT_DPB_P, and is enforced
704 * in DOE_CONSTRUCT (assumed to not be performance critical) below.
705 *
706 * Duplicated in private ME section.
707 */
708
709 volatile unsigned long sailda_dpb_or_enabled;
710
711#define EXTRACT_DPB(dpb_or_enabled) ((dpb_or_enabled) >> 16)
712#define EXTRACT_ENABLED(dpb_or_enabled) ((dpb_or_enabled) & 0xffff)
713#define DISABLED_OR_DPB_P(dpb_or_enabled) ((dpb_or_enabled) ^ 0x1)
714#define DOE_CONSTRUCT(dpb, enabled) \
715 (((dpb) ? 0x10000 : 0) | ((enabled) ? 0x1 : 0))
716
717 flipc_simple_lock pail_lock; /* Simple lock for serializing
718 multiple thread access to
719 structure. AIL owned. */
720 /* First element in buffer list array that is ours. Constant
721 from communications buffer initialization. */
722 flipc_cb_ptr constda_my_buffer_list;
723 /* First element after my_buffer_list that is *not* in my buffer
724 list. Constant from communications buffer initialization. */
725 flipc_cb_ptr constda_next_buffer_list;
726
727 /* First location that has a valid buffer pointer in it. This may
728 contain a pointer to a buffer available for acquisition, or it
729 may contain a pointer to a buffer that is still being
730 processed; the buffer header or process_ptr needs to be checked
731 to be sure. This location is AIL owned. It is ignored by all
732 (including the ME and initialization code) if
733 drop_processed_buffers, above, is set. */
734 volatile flipc_cb_ptr shrd_acquire_ptr;
735
736 /* AIL private copy of process pointer. This hopefully means that
737 the AIL won't need to read the real process pointer (and fault
738 in a cache line) very often. */
739 flipc_cb_ptr pail_process_ptr;
740
741 unsigned int pad_pail_7;
742
743 /* ===End of cache line===*/
744 /* ===AIL writes, ME occaisionally reads=== */
745
746 /* Next location at which the AIL may insert a buffer pointer. */
747 volatile flipc_cb_ptr sail_release_ptr;
748 unsigned int pad_sail_1;
749 unsigned int pad_sail_2;
750 unsigned int pad_sail_3;
751 unsigned int pad_sail_4;
752 unsigned int pad_sail_5;
753 unsigned int pad_sail_6;
754 unsigned int pad_sail_7;
755
756 /* ===End of cache line===*/
757 /* ===Private ME data=== */
758 /* See above comments (in private ail section). */
759
760 FLIPC_endpoint_type_t constdm_type;
761 volatile unsigned long saildm_dpb_or_enabled;
762
763 volatile unsigned long sme_overruns; /* For a receive endpoint, counter for
764 the number of messages that have
765 arrived when there hasn't been
766 space. ME owned. */
767 unsigned long pail_overruns_seen; /* A count of the number of overruns
768 that the AIL has noted and doesn't
769 want to be bothered with again.
770 The user only sees the difference
771 between the previous count and this. */
772
773 /*
774 * For send endpoints; linked into a list that is used by the ME
775 * to find stuff to do. Also used for endpoint free list.
776 * Null if at end of list. Not "const" because it's used as a
777 * synchronization variable during setup and teardown
778 * of send endpoints.
779 */
780 volatile flipc_cb_ptr sail_next_send_endpoint;
781
782 /* Constant buffer lsit pointers for ME. See private ail comments. */
783 flipc_cb_ptr constdm_my_buffer_list;
784 flipc_cb_ptr constdm_next_buffer_list;
785
786 /* Private ME copy of release pointer. This hopefully means that
787 the ME won't have to read (and fault in a cache line) the
788 release pointer very often. */
789
790 flipc_cb_ptr pme_release_ptr;
791 /* ===End of cache line===*/
792
793 /* ===ME writes, AIL occaisionally reads=== */
794 /*
795 * For endpoint group membership.
796 */
797 flipc_cb_ptr pail_next_eg_endpoint; /* Next endpoint in endpoint group.
798 AIL owned. */
799 flipc_cb_ptr sail_epgroup; /* Direct pointer to endpoint group that
800 we are part of. FLIPC_CBPTR_NULL
801 if none. AIL owned. */
802
803 /* First location that has a buffer pointer available for
804 processing. If this value is equal to the release_ptr there are no
805 buffers available for processing. */
806 volatile flipc_cb_ptr sme_process_ptr;
807 unsigned int pad_sme_3;
808 unsigned int pad_sme_4;
809 unsigned int pad_sme_5;
810 unsigned int pad_sme_6;
811 unsigned int pad_sme_7;
812
813 /* ===End of cache line===*/
814 /* ===END=== */
815
816 /* The following macros may have possible performance loss in
817 multiple accesses (or indirection, but a good compiler will get
818 around that). We need to have versions for each processor so
819 that the constant reads are done from the right copy. */
820
821 /* General bufferlist pointer increment macro, with versions
822 for ME and AIL. */
823
824#define NEXT_BUFFERLIST_PTR(bufferlist_ptr, endpoint, suf) \
825 (((bufferlist_ptr) + sizeof(flipc_data_buffer_t) \
826 == ((endpoint)->const ## suf ## _next_buffer_list)) ? \
827 ((endpoint)->const ## suf ## _my_buffer_list) : \
828 (bufferlist_ptr) + sizeof(flipc_data_buffer_t))
829#define NEXT_BUFFERLIST_PTR_ME(bufferlist_ptr, endpoint) \
830 NEXT_BUFFERLIST_PTR(bufferlist_ptr, endpoint, dm)
831#define NEXT_BUFFERLIST_PTR_AIL(bufferlist_ptr, endpoint) \
832 NEXT_BUFFERLIST_PTR(bufferlist_ptr, endpoint, da)
833
834 /* Macros for each of "can I release onto this buffer?" "Can I
835 acquire from this buffer?" and "Can I process an element on
836 this buffer?" The first two presume they are being executed on
837 the main procesor, the third on the co-processor.
838 All have three arguments:
839 *) A variable which will be set to the release, acquire, or
840 process pointer after the macro *if* the operation is ok.
841 *) A temporary variable used inside the function.
842 *) The endpoint.
843
844 We presume the acquire macro won't be called if drop processed
845 buffers is enabled; the process and release macros deal
846 appropriately with that issue. */
847
848 /* In general these macros will:
849 *) Not read a volatile structure member more than once.
850 *) If a variables owner is the other processor, these macros
851 will check a local copy of the variable first before checking
852 the other processors.
853 *) Will only update the local copy if the remote copy really is
854 different from the local one.
855 */
856
857/* This macro implements the synchronization check; local cbptr is
858 the pointer owned by the local processor which we want to compare
859 with a pointer on the remote processor which we have a copy
860 of locally. Reads the remote pointer zero or one times; other
861 reads are as necessary.
862
863 The algorithm is:
864 *) If the local copy says our pointer and the remote value aren't equal,
865 we're done.
866 *) Otherwise, check the remote copy. If it says the values aren't
867 equal, update the local copy. */
868
869#define ENDPOINT_SYNCNE_CHECK(local_cbptr, copy_rmt_cbptr, \
870 rmt_cbptr, tmp_cbptr) \
871 ((local_cbptr) != (copy_rmt_cbptr) \
872 || ((((tmp_cbptr) = (rmt_cbptr)) != (local_cbptr)) \
873 && (((copy_rmt_cbptr) = (tmp_cbptr)), 1)))
874
875#define ENDPOINT_ACQUIRE_OK(acquire_cbptr, tmp_cbptr, endpoint) \
876 ((acquire_cbptr) = (endpoint)->shrd_acquire_ptr, \
877 ENDPOINT_SYNCNE_CHECK(acquire_cbptr, (endpoint)->pail_process_ptr, \
878 (endpoint)->sme_process_ptr, tmp_cbptr))
879
880#define ENDPOINT_PROCESS_OK(process_cbptr, tmp_cbptr, endpoint) \
881 ((process_cbptr) = (endpoint)->sme_process_ptr, \
882 ENDPOINT_SYNCNE_CHECK(process_cbptr, (endpoint)->pme_release_ptr, \
883 (endpoint)->sail_release_ptr, tmp_cbptr))
884
885#define NODPB_ENDPOINT_RELEASE_OK(release_cbptr, tmp_cbptr, endpoint) \
886 ((release_cbptr) = (endpoint)->sail_release_ptr, \
887 (tmp_cbptr) = (endpoint)->shrd_acquire_ptr, \
888 (NEXT_BUFFERLIST_PTR_AIL(release_cbptr, endpoint) \
889 != (tmp_cbptr)))
890
891/* Don't use NEXT_BUFFERLIST_PTR here to save a temporary variable. */
892#define DPB_ENDPOINT_RELEASE_OK(release_cbptr, tmp_cbptr, endpoint) \
893 (release_cbptr = (endpoint)->sail_release_ptr, \
894 ((release_cbptr + sizeof(flipc_data_buffer_t) == \
895 (endpoint)->constda_next_buffer_list) \
896 ? ENDPOINT_SYNCNE_CHECK((endpoint)->constda_my_buffer_list, \
897 (endpoint)->pail_process_ptr, \
898 (endpoint)->sme_process_ptr, \
899 tmp_cbptr) \
900 : ENDPOINT_SYNCNE_CHECK(release_cbptr + sizeof(flipc_data_buffer_t), \
901 (endpoint)->pail_process_ptr, \
902 (endpoint)->sme_process_ptr, \
903 tmp_cbptr)))
904
905 /* This next is tricky; remember that acquire_ptr points
906 to an actual bufferptr on the list, whereas release_ptr does
907 not. This macro is only used in FLIPC_endpoint_query, and so
908 doesn't need to have an ME version. */
909
910#define BUFFERS_ON_ENDPOINT_AIL(acquire_ptr, release_ptr, endpoint) \
911 ((release_ptr) > (acquire_ptr) \
912 ? ((release_ptr) - (acquire_ptr)) / sizeof(flipc_cb_ptr) \
913 : ((((release_ptr) - (endpoint)->constda_my_buffer_list) \
914 + ((endpoint)->constda_next_buffer_list - acquire_ptr)) \
915 / sizeof(flipc_cb_ptr)))
916} *flipc_endpoint_t;
917
918
919/*
920 * Endpoint groups.
921 *
922 * Used to represent a group of endpoints, for linking sending/receiving
923 * with semaphores & etc. Note that there needs to be a private data
924 * structure kept by the kernel that associates with each epgroup
925 * a semaphore to be used for wakeups on that endpoint set.
926 */
927
928typedef struct flipc_epgroup {
929 flipc_simple_lock pail_lock; /* Lock to synchronize threads (at the
930 same priority level) accessing this
931 structure. */
932 volatile unsigned long sail_enabled; /* Set if structure is active. */
933 unsigned long const_semaphore_associated; /* Flag to indicate whether or not
934 there is a semaphore associated
935 with this endpoint group in the
936 kernel flipc routines. */
937 volatile unsigned long sail_wakeup_req; /* Incremented when a thread wants to
938 be woken. */
939 volatile unsigned long pme_wakeup_del; /* Incremented when the ME delivers a
940 wakeup. */
941 unsigned long pail_version; /* Incremented when epgroup membership
942 is changed; checked when retrieving
943 a buffer from an epgroup. */
944 unsigned long sail_msgs_per_wakeup; /* How many messages need to arrive
945 before the ME delivers a wakeup. */
946 unsigned long pme_msgs_since_wakeup; /* How many messages have arrived
947 since the last wakeup. ME
948 owned. */
949
950 flipc_cb_ptr pail_first_endpoint; /* First endpoint in the group. The
951 other endpoints are linked along
952 behind him. AIL owned. */
953 flipc_cb_ptr pail_free; /* Used to link this endpoint onto
954 the freelist. */
955} *flipc_epgroup_t;
956
957/*
958 * Communication buffer control structure.
959 *
960 * This is in the communications buffer itself. Note that any changes
961 * in this structure require it to be locked with the allocation lock,
962 * as access to this structure is shared by all threads using the CB.
963 */
964
965/*
966 * Individual data type layout.
967 *
968 * All we need here is a pointer to the start of each type of data
969 * struct, the number of those data structures in the communications
970 * buffer, and a pointer to the beginning of the freelist for that data
971 * structure.
972 *
973 * Note that the composite buffer list doesn't have a freelist associated
974 * with it, since each section of the buffer list is tightly bound to an
975 * endpoint, and is allocated and freed with that endpoint. We still
976 * need the start and number information, though.
977 */
978struct flipc_cb_type_ctl {
979 flipc_cb_ptr start; /* Where there array of this type of
980 data structure starts. */
981 unsigned long number; /* How many of them we've got. */
982 flipc_cb_ptr free; /* Where the beginning of the freelist
983 is. */
984};
985
986/*
987 * Synchronization with message engine.
988 *
989 * At certain times (specifically during structure allocation/free or
990 * additions to the send list) you want to know that the messaging
991 * engine has picked up your changes. However, the message engine has
992 * (effectively) two threads, one for each of the send and receive
993 * sides. The mechanisms used for synchronizations with the two sides
994 * differ. In an eventual co-processor implementation (with a single
995 * thread), only the send side mechanism will be used.
996 *
997 * To request a cached state flush by the send side of the mesasging
998 * engine, you flip the request_sync bit and it responds by flipping
999 * the response_sync bit. The send ME checks this bit once every trip
1000 * through the send endpoints.
1001 *
1002 * On the receive side, since receives take very little time and do
1003 * not block (unlike sends) when we want to make sure the ME is
1004 * holding no cached receive side state, we simply spin until we see
1005 * that the ME receive side is no longer operating. It sets a
1006 * variable whenever it is in the process of receiving a message.
1007 */
1008
1009/*
1010 * Proper manipulation of the send endpoint list.
1011 *
1012 * Note that synchronizing with the message engine over access to the
1013 * send endpoint list is especially tricky. There is no problem with
1014 * writing new values in all of the locations required to take a send
1015 * endpoint off of the list. However, we must be very sure before
1016 * modifying the pointer *in* the send endpoint that the ME isn't
1017 * currently working in that send endpoint (else it could be sent off
1018 * into the void). Two options here:
1019 *
1020 * *) Synchronize (using the below variables) for each send
1021 * endpoint removed, after the removal but before the
1022 * modification of the data in the internal structure.
1023 * *) If we can always be sure that the send endpoint link in the
1024 * endpoint structure has a valid value, we can simply let the
1025 * chips fall where they may. It will be null while free, and
1026 * have a value that points back into the send buffer list
1027 * when reallocated. I'm not going to do this; it's sleezy
1028 * and will partially mess up fairness based on ME send
1029 * endpoint round-robinning.
1030 */
1031
1032/*
1033 * This entire structure is protected by an kernel level lock so there
1034 * is no conflict between threads accessing it. See flipc_kfr.c for
1035 * details on this lock; how it is implemented and used depends on what
1036 * kernel base we are on.
1037 */
1038
1039/*
1040 * Note that the last element of this structure is variable sized, so this
1041 * structure itself is also variable sized.
1042 */
1043typedef struct flipc_comm_buffer_ctl {
1044 /* Kernel flipc configuration that the user must match in order to
1045 work with this kernel. Checked as soon as the comm buffer is
1046 mapped. */
1047 struct {
1048 unsigned int real_time_primitives:1;
1049 unsigned int message_engine_in_kernel:1;
1050 unsigned int no_bus_locking:1; /* One way check -- if the kernel doesn't
1051 have this and the user does, that's
1052 an error. */
1053 } kernel_configuration;
1054 volatile unsigned long send_ready; /* A send(s) is ready to go */
1055
1056 /* These first three structures are constant after communications buffer
1057 initialization. */
1058 unsigned long data_buffer_size; /* Size of the data buffers. */
1059 unsigned long local_node_address; /* Local node number. */
1060 FLIPC_address_t null_destination; /* Local null destination value. */
1061
1062#if REAL_TIME_PRIMITIVES
1063 /* The scheduling policy used by the task initializing flipc for
1064 the allocations lock. */
1065 int allocations_lock_policy;
1066#else
1067 /* A poor substitute for a kernel level allocations lock.
1068 Note that this *cannot* be used as a regular simple lock;
1069 instead, try to acquire it, call sleep(1), try again, etc.
1070 Spinning on this lock will probably waste lots of cycles. */
1071 flipc_simple_lock pail_alloc_lock;
1072#endif
1073
1074 /* All of the members of these structures except for the free pointer
1075 are constant after initialization. The free pointer is ail owned
1076 and private. */
1077 struct flipc_cb_type_ctl endpoint;
1078 struct flipc_cb_type_ctl epgroup;
1079 struct flipc_cb_type_ctl bufferlist;
1080 struct flipc_cb_type_ctl data_buffer;
1081
1082 /* Global synchronization with the message engine. On the KKT
1083 implementation we need one synchronizer for each thread. */
1084
1085 /* Send side: */
1086 volatile unsigned long sail_request_sync; /* request_sync = !request_sync when the
1087 AIL wants to synchronize with the
1088 CB. */
1089 volatile unsigned long sme_respond_sync; /* respond_sync = !respond_sync when
1090 the ME has noticed the sync
1091 request. By responding to the
1092 sync, the ME is stating that it has
1093 no communications buffer state that
1094 was cached previous to it noticing
1095 the sync. */
1096
1097 /* Receive side. */
1098 volatile unsigned long sme_receive_in_progress; /* Set by the ME before it looks at
1099 any data structures; cleared
1100 afterwards. A simple spin in
1101 the user space on this
1102 variable will suffice, as the
1103 time that the message
1104 engine could be receiving
1105 is low. */
1106
1107 /* Send endpoint list starts here. */
1108 volatile flipc_cb_ptr sail_send_endpoint_list; /* Null if no send endpoints.
1109 */
1110
1111 /* Keep track of whatever performance information we choose. */
1112 struct FLIPC_domain_performance_info performance;
1113
1114 /* Keep track of various kinds of error information here. */
1115 struct FLIPC_domain_errors sme_error_log;
1116
1117} *flipc_comm_buffer_ctl_t;
1118
1119
1120/*
1121 * The communications buffer.
1122 *
1123 * The only restriction on the layout of the communications buffer is
1124 * that the buffers themselves may not cross page boundaries. So we
1125 * will place the data buffers at the end of the communications
1126 * buffer, and the other objects at the beginning, and there may be a
1127 * little bit of extra space in the middle.
1128 *
1129 * Note that this layout may change in future versions of FLIPC.
1130 *
1131 * +---------------------------+
1132 * | flipc_comm_buffer_ctl |
1133 * +---------------------------+
1134 * | |
1135 * | Endpoints |
1136 * | |
1137 * +---------------------------+
1138 * | |
1139 * | Endpoint Groups |
1140 * | |
1141 * +---------------------------+
1142 * | |
1143 * | Combined Buffer Lists |
1144 * | |
1145 * +---------------------------+
1146 * | |
1147 * | (Possible empty space) |
1148 * | |
1149 * +---------------------------+
1150 * | |
1151 * | Data Buffers |
1152 * | |
1153 * +---------------------------+
1154 */
1155
1156/* The number of pages that the kernel will reserve for the comm
1157 buffer. The AIL needs to know this to know how much to map. */
1158#define COMM_BUFFER_SIZE 0x100000
1159
1160/*
1161 * These variables are set, in a per-address space context, to the base
1162 * and length of the communications buffer. The ME needs to do bounds
1163 * checking to make sure it isn't overrunning anything. Note that the
1164 * existence of these variables implies that an application will only
1165 * open a single domain.
1166 *
1167 * These declarations are duplicated in flipc/flipc_usermsg.h, and
1168 * should be kept in sync with that file.
1169 */
1170unsigned char *flipc_cb_base;
1171unsigned long flipc_cb_length; /* In bytes. */
1172
1173/*
1174 * Following is a set of macros to convert back and forth between
1175 * real address pointers and flipc_cb_ptr's for each data type. They
1176 * rely on the flipc_cb_base being set correctly.
1177 *
1178 * A possible future improvement might be to have bounds checking occur
1179 * inside these macros, but I'm not sure what I'd do if it failed.
1180 */
1181
1182/* Easy going one way. */
1183#define FLIPC_CBPTR(ptr) \
1184(((unsigned char *) (ptr)) - flipc_cb_base)
1185
1186/* Need to get the right types going the other way. */
1187#define FLIPC_ENDPOINT_PTR(cb_ptr) \
1188((flipc_endpoint_t) ((cb_ptr) + flipc_cb_base))
1189#define FLIPC_EPGROUP_PTR(cb_ptr) \
1190((flipc_epgroup_t) ((cb_ptr) + flipc_cb_base))
1191#define FLIPC_DATA_BUFFER_PTR(cb_ptr) \
1192((flipc_data_buffer_t) ((cb_ptr) + flipc_cb_base))
1193#define FLIPC_BUFFERLIST_PTR(cb_ptr) \
1194((flipc_cb_ptr *) ((cb_ptr) + flipc_cb_base))
1195
1196
1197/*
1198 * Flipc addresses.
1199 *
1200 * The addresses used by flipc for communication are defined in the
1201 * user visible header file as unsigned longs. These macros pull that
1202 * information apart for use of the FLIPC internal routines.
1203 *
1204 * I assume in the following that endpoints immediately follow the
1205 * comm buffer control structure, because that makes indexing into
1206 * them much easier.
1207 */
1208
1209#define FLIPC_CREATE_ADDRESS(node, endpoint_idx) \
1210((node << 16) | (endpoint_idx))
1211#define FLIPC_ADDRESS_NODE(addr) (((unsigned long) (addr)) >> 16)
1212#define FLIPC_ADDRESS_ENDPOINT(addr) (((unsigned long) (addr)) & 0xffff)
1213
1214#endif /* _MACH_FLIPC_CB_H_ */