xref: /illumos-gate/usr/src/uts/common/io/1394/h1394.c (revision 1f5207b7604fb44407eb4342aff613f7c4508508)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License, Version 1.0 only
6  * (the "License").  You may not use this file except in compliance
7  * with the License.
8  *
9  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
10  * or http://www.opensolaris.org/os/licensing.
11  * See the License for the specific language governing permissions
12  * and limitations under the License.
13  *
14  * When distributing Covered Code, include this CDDL HEADER in each
15  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
16  * If applicable, add the following below this CDDL HEADER, with the
17  * fields enclosed by brackets "[]" replaced with your own identifying
18  * information: Portions Copyright [yyyy] [name of copyright owner]
19  *
20  * CDDL HEADER END
21  */
22 /*
23  * Copyright 2004 Sun Microsystems, Inc.  All rights reserved.
24  * Use is subject to license terms.
25  */
26 
27 #pragma ident	"%Z%%M%	%I%	%E% SMI"
28 
29 /*
30  * h1394.c
31  *    1394 Services Layer HAL Interface
32  *    Contains all of the routines that define the HAL to Services Layer
33  *    interface
34  */
35 
36 #include <sys/conf.h>
37 #include <sys/ddi.h>
38 #include <sys/sunddi.h>
39 #include <sys/modctl.h>
40 #include <sys/sunndi.h>
41 #include <sys/cmn_err.h>
42 #include <sys/types.h>
43 #include <sys/kmem.h>
44 #include <sys/thread.h>
45 #include <sys/proc.h>
46 #include <sys/disp.h>
47 #include <sys/time.h>
48 #include <sys/devctl.h>
49 #include <sys/tnf_probe.h>
50 
51 #include <sys/1394/t1394.h>
52 #include <sys/1394/s1394.h>
53 #include <sys/1394/h1394.h>
54 #include <sys/1394/ieee1394.h>
55 
56 
57 extern struct bus_ops nx1394_busops;
58 extern int nx1394_define_events(s1394_hal_t *hal);
59 extern void nx1394_undefine_events(s1394_hal_t *hal);
60 extern int s1394_ignore_invalid_gap_cnt;
61 
62 /*
63  * Function:    h1394_init()
64  * Input(s):    modlp			The structure containing all of the
65  *					    HAL's relevant information
66  *
67  * Output(s):
68  *
69  * Description:	h1394_init() is called by the HAL's _init function and is
70  *		used to set up the nexus bus ops.
71  */
72 int
73 h1394_init(struct modlinkage *modlp)
74 {
75 	struct dev_ops	*devops;
76 
77 	TNF_PROBE_0_DEBUG(h1394_init_enter, S1394_TNF_SL_STACK, "");
78 
79 	devops = ((struct modldrv *)(modlp->ml_linkage[0]))->drv_dev_ops;
80 	devops->devo_bus_ops = &nx1394_busops;
81 
82 	TNF_PROBE_0_DEBUG(h1394_init_exit, S1394_TNF_SL_STACK, "");
83 	return (0);
84 }
85 
86 /*
87  * Function:    h1394_fini()
88  * Input(s):    modlp			The structure containing all of the
89  *					    HAL's relevant information
90  *
91  * Output(s):
92  *
93  * Description:	h1394_fini() is called by the HAL's _fini function and is
94  *		used to NULL out the nexus bus ops.
95  */
96 void
97 h1394_fini(struct modlinkage *modlp)
98 {
99 	struct dev_ops	*devops;
100 
101 	TNF_PROBE_0_DEBUG(h1394_fini_enter, S1394_TNF_SL_STACK, "");
102 
103 	devops = ((struct modldrv *)(modlp->ml_linkage[0]))->drv_dev_ops;
104 	devops->devo_bus_ops = NULL;
105 
106 	TNF_PROBE_0_DEBUG(h1394_fini_enter, S1394_TNF_SL_STACK, "");
107 }
108 
109 /*
110  * Function:    h1394_attach()
111  * Input(s):    halinfo			The structure containing all of the
112  *					    HAL's relevant information
113  *		cmd			The ddi_attach_cmd_t that tells us
114  *					    if this is a RESUME or a regular
115  *					    attach() call
116  *
117  * Output(s):	sl_private		The HAL "handle" to be used for
118  *					    all subsequent calls into the
119  *					    1394 Software Framework
120  *
121  * Description:	h1394_attach() registers the HAL with the 1394 Software
122  *		Framework.  It returns a HAL "handle" to be used for
123  *		all subsequent calls into the 1394 Software Framework.
124  */
125 int
126 h1394_attach(h1394_halinfo_t *halinfo, ddi_attach_cmd_t cmd, void **sl_private)
127 {
128 	s1394_hal_t	*hal;
129 	int		ret;
130 	char		buf[32];
131 	uint_t		cmd_size;
132 
133 	TNF_PROBE_0_DEBUG(h1394_attach_enter, S1394_TNF_SL_STACK, "");
134 
135 	ASSERT(sl_private != NULL);
136 
137 	/* If this is a DDI_RESUME, return success */
138 	if (cmd == DDI_RESUME) {
139 		hal = (s1394_hal_t *)(*sl_private);
140 		/* If we have a 1394A PHY, then reset the "contender bit" */
141 		if (hal->halinfo.phy == H1394_PHY_1394A)
142 			(void) HAL_CALL(hal).set_contender_bit(
143 			    hal->halinfo.hal_private);
144 		TNF_PROBE_0_DEBUG(h1394_attach_exit, S1394_TNF_SL_STACK,
145 		    "");
146 		return (DDI_SUCCESS);
147 	} else if (cmd != DDI_ATTACH) {
148 		TNF_PROBE_2(h1394_attach_error, S1394_TNF_SL_ERROR, "",
149 		    tnf_string, msg, "Invalid ddi_attach_cmd received",
150 		    tnf_uint, attach_cmd, (uint_t)cmd);
151 		TNF_PROBE_0_DEBUG(h1394_attach_exit, S1394_TNF_SL_STACK,
152 		    "");
153 		return (DDI_FAILURE);
154 	}
155 
156 	/* Allocate space for s1394_hal_t */
157 	hal = kmem_zalloc(sizeof (s1394_hal_t), KM_SLEEP);
158 
159 	/* Setup HAL state */
160 	hal->hal_state = S1394_HAL_INIT;
161 
162 	/* Copy in the halinfo struct */
163 	hal->halinfo = *halinfo;
164 
165 	/* Create the topology tree mutex */
166 	mutex_init(&hal->topology_tree_mutex, NULL, MUTEX_DRIVER,
167 	    hal->halinfo.hw_interrupt);
168 
169 	/* Create the Cycle Mater timer mutex */
170 	mutex_init(&hal->cm_timer_mutex, NULL, MUTEX_DRIVER,
171 	    hal->halinfo.hw_interrupt);
172 
173 	/* Initialize the Isoch CEC list */
174 	hal->isoch_cec_list_head = NULL;
175 	hal->isoch_cec_list_tail = NULL;
176 	mutex_init(&hal->isoch_cec_list_mutex, NULL, MUTEX_DRIVER,
177 	    hal->halinfo.hw_interrupt);
178 
179 	/* Initialize the Bus Manager node ID mutex and cv */
180 	mutex_init(&hal->bus_mgr_node_mutex, NULL, MUTEX_DRIVER,
181 	    hal->halinfo.hw_interrupt);
182 	cv_init(&hal->bus_mgr_node_cv, NULL, CV_DRIVER,
183 	    hal->halinfo.hw_interrupt);
184 
185 	/* Initialize the Bus Manager node ID - "-1" means undetermined */
186 	hal->bus_mgr_node	= -1;
187 	hal->incumbent_bus_mgr	= B_FALSE;
188 
189 	/* Initialize the Target list */
190 	hal->target_head = NULL;
191 	hal->target_tail = NULL;
192 	rw_init(&hal->target_list_rwlock, NULL, RW_DRIVER,
193 	    hal->halinfo.hw_interrupt);
194 
195 	/* Setup Request Q's */
196 	hal->outstanding_q_head	= NULL;
197 	hal->outstanding_q_tail	= NULL;
198 	mutex_init(&hal->outstanding_q_mutex, NULL, MUTEX_DRIVER,
199 	    hal->halinfo.hw_interrupt);
200 	hal->pending_q_head	= NULL;
201 	hal->pending_q_tail	= NULL;
202 	mutex_init(&hal->pending_q_mutex, NULL, MUTEX_DRIVER,
203 	    hal->halinfo.hw_interrupt);
204 
205 	/* Create the kmem_cache for command allocations */
206 	(void) sprintf(buf, "hal%d_cache", ddi_get_instance(hal->halinfo.dip));
207 	cmd_size = sizeof (cmd1394_cmd_t) + sizeof (s1394_cmd_priv_t) +
208 	    hal->halinfo.hal_overhead;
209 
210 	hal->hal_kmem_cachep = kmem_cache_create(buf, cmd_size, 8, NULL, NULL,
211 	    NULL, NULL, NULL, 0);
212 
213 	/* Setup the event stuff */
214 	ret = nx1394_define_events(hal);
215 	if (ret != DDI_SUCCESS) {
216 		/* Clean up before leaving */
217 		s1394_cleanup_for_detach(hal, H1394_CLEANUP_LEVEL0);
218 
219 		TNF_PROBE_1(h1394_attach_error, S1394_TNF_SL_ERROR, "",
220 		    tnf_string, msg, "Unable to define attach events");
221 		TNF_PROBE_0_DEBUG(h1394_attach_exit, S1394_TNF_SL_STACK,
222 		    "");
223 		return (DDI_FAILURE);
224 	}
225 
226 	/* Initialize the mutexes and cv's used by the bus reset thread */
227 	mutex_init(&hal->br_thread_mutex, NULL, MUTEX_DRIVER,
228 	    hal->halinfo.hw_interrupt);
229 	cv_init(&hal->br_thread_cv, NULL, CV_DRIVER, hal->halinfo.hw_interrupt);
230 	mutex_init(&hal->br_cmplq_mutex, NULL, MUTEX_DRIVER,
231 	    hal->halinfo.hw_interrupt);
232 	cv_init(&hal->br_cmplq_cv, NULL, CV_DRIVER, hal->halinfo.hw_interrupt);
233 
234 	/*
235 	 * Create a bus reset thread to handle the device discovery.
236 	 *    It should take the default stack sizes, it should run
237 	 *    the s1394_br_thread() routine at the start, passing the
238 	 *    HAL pointer as its argument.  The thread should be put
239 	 *    on processor p0, its state should be set to runnable,
240 	 *    but not yet on a processor, and its scheduling priority
241 	 *    should be the minimum level of any system class.
242 	 */
243 	hal->br_thread = thread_create((caddr_t)NULL, 0, s1394_br_thread,
244 	    hal, 0, &p0, TS_RUN, minclsyspri);
245 
246 	/* Until we see a bus reset this HAL has no nodes */
247 	hal->number_of_nodes = 0;
248 	hal->num_bus_reset_till_fail = NUM_BR_FAIL;
249 
250 	/* Initialize the SelfID Info */
251 	hal->current_buffer = 0;
252 	hal->selfid_buf0 = kmem_zalloc(S1394_SELFID_BUF_SIZE, KM_SLEEP);
253 	hal->selfid_buf1 = kmem_zalloc(S1394_SELFID_BUF_SIZE, KM_SLEEP);
254 
255 	/* Initialize kstat structures */
256 	ret = s1394_kstat_init(hal);
257 	if (ret != DDI_SUCCESS) {
258 		/* Clean up before leaving */
259 		s1394_cleanup_for_detach(hal, H1394_CLEANUP_LEVEL3);
260 
261 		TNF_PROBE_1(h1394_attach_error, S1394_TNF_SL_ERROR, "",
262 		    tnf_string, msg, "Failure in s1394_kstat_init");
263 		TNF_PROBE_0_DEBUG(h1394_attach_exit, S1394_TNF_SL_STACK,
264 		    "");
265 		return (DDI_FAILURE);
266 	}
267 	hal->hal_kstats->guid = hal->halinfo.guid;
268 
269 	/* Setup the node tree pointers */
270 	hal->old_tree	   = &hal->last_valid_tree[0];
271 	hal->topology_tree = &hal->current_tree[0];
272 
273 	/* Initialize the local Config ROM entry */
274 	ret = s1394_init_local_config_rom(hal);
275 	if (ret != DDI_SUCCESS) {
276 		/* Clean up before leaving */
277 		s1394_cleanup_for_detach(hal, H1394_CLEANUP_LEVEL4);
278 
279 		TNF_PROBE_1(h1394_attach_error, S1394_TNF_SL_ERROR, "",
280 		    tnf_string, msg, "Failure in s1394_init_local_config_rom");
281 		TNF_PROBE_0_DEBUG(h1394_attach_exit, S1394_TNF_SL_STACK, "");
282 		return (DDI_FAILURE);
283 	}
284 
285 	/* Initialize 1394 Address Space */
286 	ret = s1394_init_addr_space(hal);
287 	if (ret != DDI_SUCCESS) {
288 		/* Clean up before leaving */
289 		s1394_cleanup_for_detach(hal, H1394_CLEANUP_LEVEL5);
290 
291 		TNF_PROBE_1(h1394_attach_error, S1394_TNF_SL_ERROR, "",
292 		    tnf_string, msg, "Invalid 1394 address space");
293 		TNF_PROBE_0_DEBUG(h1394_attach_exit, S1394_TNF_SL_STACK,
294 		    "");
295 		return (DDI_FAILURE);
296 	}
297 
298 	/* Initialize FCP subsystem */
299 	ret = s1394_fcp_hal_init(hal);
300 	if (ret != DDI_SUCCESS) {
301 		/* Clean up before leaving */
302 		s1394_cleanup_for_detach(hal, H1394_CLEANUP_LEVEL6);
303 
304 		TNF_PROBE_1(h1394_attach_error, S1394_TNF_SL_ERROR, "",
305 		    tnf_string, msg, "FCP initialization failure");
306 		TNF_PROBE_0_DEBUG(h1394_attach_exit, S1394_TNF_SL_STACK,
307 		    "");
308 		return (DDI_FAILURE);
309 	}
310 
311 	/* Initialize the IRM node ID - "-1" means invalid, undetermined */
312 	hal->IRM_node = -1;
313 
314 	/* If we have a 1394A PHY, then set the "contender bit" */
315 	if (hal->halinfo.phy == H1394_PHY_1394A)
316 		(void) HAL_CALL(hal).set_contender_bit(
317 		    hal->halinfo.hal_private);
318 
319 	/* Add into linked list */
320 	mutex_enter(&s1394_statep->hal_list_mutex);
321 	if ((s1394_statep->hal_head == NULL) &&
322 	    (s1394_statep->hal_tail == NULL)) {
323 		s1394_statep->hal_head = hal;
324 		s1394_statep->hal_tail = hal;
325 	} else {
326 		s1394_statep->hal_tail->hal_next = hal;
327 		hal->hal_prev = s1394_statep->hal_tail;
328 		s1394_statep->hal_tail = hal;
329 	}
330 	mutex_exit(&s1394_statep->hal_list_mutex);
331 
332 	/* Fill in services layer private info */
333 	*sl_private = (void *)hal;
334 
335 	TNF_PROBE_0_DEBUG(h1394_attach_exit, S1394_TNF_SL_STACK, "");
336 	return (DDI_SUCCESS);
337 }
338 
339 /*
340  * Function:    h1394_detach()
341  * Input(s):    sl_private		The HAL "handle" returned by
342  *					    h1394_attach()
343  *		cmd			The ddi_detach_cmd_t that tells us
344  *					    if this is a SUSPEND or a regular
345  *					    detach() call
346  *
347  * Output(s):	DDI_SUCCESS		HAL successfully detached
348  *		DDI_FAILURE		HAL failed to detach
349  *
350  * Description:	h1394_detach() unregisters the HAL from the 1394 Software
351  *		Framework.  It can be called during a SUSPEND operation or
352  *		for a real detach() event.
353  */
354 int
355 h1394_detach(void **sl_private, ddi_detach_cmd_t cmd)
356 {
357 	s1394_hal_t	*hal;
358 
359 	TNF_PROBE_0_DEBUG(h1394_detach_enter, S1394_TNF_SL_STACK, "");
360 
361 	hal = (s1394_hal_t *)(*sl_private);
362 
363 	switch (cmd) {
364 	case DDI_DETACH:
365 		/* Clean up before leaving */
366 		s1394_cleanup_for_detach(hal, H1394_CLEANUP_LEVEL7);
367 		/* NULL out the HAL "handle" */
368 		*sl_private = NULL;
369 		break;
370 
371 	case DDI_SUSPEND:
372 		/* Turn off any timers that might be set */
373 		s1394_destroy_timers(hal);
374 		/* Set the hal_was_suspended bit */
375 		hal->hal_was_suspended = B_TRUE;
376 		break;
377 
378 	default:
379 		TNF_PROBE_2(h1394_attach_error, S1394_TNF_SL_ERROR, "",
380 		    tnf_string, msg, "Invalid ddi_detach_cmd_t type specified",
381 		    tnf_uint, detach_cmd, (uint_t)cmd);
382 		TNF_PROBE_0_DEBUG(h1394_detach_exit, S1394_TNF_SL_STACK, "");
383 		return (DDI_FAILURE);
384 	}
385 
386 	TNF_PROBE_0_DEBUG(h1394_detach_exit, S1394_TNF_SL_STACK, "");
387 	return (DDI_SUCCESS);
388 }
389 
390 /*
391  * Function:    h1394_alloc_cmd()
392  * Input(s):    sl_private		The HAL "handle" returned by
393  *					    h1394_attach()
394  *		flags			The flags parameter is described below
395  *
396  * Output(s):	cmdp			Pointer to the newly allocated command
397  *		hal_priv_ptr		Offset into the command, points to
398  *					    the HAL's private area
399  *
400  * Description:	h1394_alloc_cmd() allocates a command for use with the
401  *		h1394_read_request(), h1394_write_request(), or
402  *		h1394_lock_request() interfaces of the 1394 Software Framework.
403  *		By default, h1394_alloc_cmd() may sleep while allocating
404  *		memory for the command structure.  If this is undesirable,
405  *		the HAL may set the H1394_ALLOC_CMD_NOSLEEP bit in the flags
406  *		parameter.
407  */
408 int
409 h1394_alloc_cmd(void *sl_private, uint_t flags, cmd1394_cmd_t **cmdp,
410     h1394_cmd_priv_t **hal_priv_ptr)
411 {
412 	s1394_hal_t	 *hal;
413 	s1394_cmd_priv_t *s_priv;
414 
415 	TNF_PROBE_0_DEBUG(h1394_alloc_cmd_enter, S1394_TNF_SL_ARREQ_STACK,
416 	    "");
417 
418 	hal = (s1394_hal_t *)sl_private;
419 
420 	if (s1394_alloc_cmd(hal, flags, cmdp) != DDI_SUCCESS) {
421 		TNF_PROBE_1(h1394_alloc_cmd_error, S1394_TNF_SL_ARREQ_ERROR, "",
422 		    tnf_string, msg, "Failed to allocate command structure");
423 		TNF_PROBE_0_DEBUG(h1394_alloc_cmd_exit,
424 		    S1394_TNF_SL_ARREQ_STACK, "");
425 		return (DDI_FAILURE);
426 	}
427 
428 	/* Get the Services Layer private area */
429 	s_priv = S1394_GET_CMD_PRIV(*cmdp);
430 
431 	*hal_priv_ptr = &s_priv->hal_cmd_private;
432 
433 	TNF_PROBE_0_DEBUG(h1394_alloc_cmd_exit, S1394_TNF_SL_ARREQ_STACK,
434 	    "");
435 	return (DDI_SUCCESS);
436 }
437 
438 /*
439  * Function:    h1394_free_cmd()
440  * Input(s):    sl_private		The HAL "handle" returned by
441  *					    h1394_attach()
442  *		cmdp			Pointer to the command to be freed
443  *
444  * Output(s):	DDI_SUCCESS		HAL successfully freed command
445  *		DDI_FAILURE		HAL failed to free command
446  *
447  * Description:	h1394_free_cmd() attempts to free a command that has previously
448  *		been allocated by the HAL.  It is possible for h1394_free_cmd()
449  *		to fail because the command is currently in-use by the 1394
450  *		Software Framework.
451  */
452 int
453 h1394_free_cmd(void *sl_private, cmd1394_cmd_t **cmdp)
454 {
455 	s1394_hal_t	 *hal;
456 	s1394_cmd_priv_t *s_priv;
457 
458 	TNF_PROBE_0_DEBUG(h1394_free_cmd_enter, S1394_TNF_SL_ARREQ_STACK,
459 	    "");
460 
461 	hal = (s1394_hal_t *)sl_private;
462 
463 	/* Get the Services Layer private area */
464 	s_priv = S1394_GET_CMD_PRIV(*cmdp);
465 
466 	/* Check that command isn't in use */
467 	if (s_priv->cmd_in_use == B_TRUE) {
468 		TNF_PROBE_1(h1394_free_cmd_error, S1394_TNF_SL_ARREQ_ERROR, "",
469 		    tnf_string, msg,  "Attempted to free an in-use command");
470 		TNF_PROBE_0_DEBUG(h1394_free_cmd_exit, S1394_TNF_SL_ARREQ_STACK,
471 		    "");
472 		ASSERT(s_priv->cmd_in_use == B_FALSE);
473 		return (DDI_FAILURE);
474 	}
475 
476 	kmem_cache_free(hal->hal_kmem_cachep, *cmdp);
477 
478 	/* Command pointer is set to NULL before returning */
479 	*cmdp = NULL;
480 
481 	/* kstats - number of cmds freed */
482 	hal->hal_kstats->cmd_free++;
483 
484 	TNF_PROBE_0_DEBUG(h1394_free_cmd_exit, S1394_TNF_SL_ARREQ_STACK,
485 	    "");
486 	return (DDI_SUCCESS);
487 }
488 
489 /*
490  * Function:    h1394_cmd_is_complete()
491  * Input(s):    sl_private		The HAL "handle" returned by
492  *					    h1394_attach()
493  *		command_id		Pointer to the command that has
494  *					    just completed
495  *		cmd_type		AT_RESP => AT response or ATREQ =
496  *					    AT request
497  *		status			Command's completion status
498  *
499  * Output(s):	None
500  *
501  * Description:	h1394_cmd_is_complete() is called by the HAL whenever an
502  *		outstanding command has completed (successfully or otherwise).
503  *		After determining whether it was an AT request or and AT
504  *		response that we are handling, the command is dispatched to
505  *		the appropriate handler in the 1394 Software Framework.
506  */
507 void
508 h1394_cmd_is_complete(void *sl_private, cmd1394_cmd_t *command_id,
509     uint32_t cmd_type, int status)
510 {
511 	s1394_hal_t	*hal;
512 	dev_info_t	*dip;
513 
514 	TNF_PROBE_0_DEBUG(h1394_cmd_is_complete_enter,
515 	    S1394_TNF_SL_ATREQ_ATRESP_STACK, "");
516 
517 	hal = (s1394_hal_t *)sl_private;
518 
519 	/* Is it AT_RESP or AT_REQ? */
520 	switch (cmd_type) {
521 	case H1394_AT_REQ:
522 		s1394_atreq_cmd_complete(hal, command_id, status);
523 		break;
524 
525 	case H1394_AT_RESP:
526 		s1394_atresp_cmd_complete(hal, command_id, status);
527 		break;
528 
529 	default:
530 		dip = hal->halinfo.dip;
531 
532 		/* An unexpected error in the HAL */
533 		cmn_err(CE_WARN, HALT_ERROR_MESSAGE,
534 		    ddi_node_name(dip), ddi_get_instance(dip));
535 
536 		/* Disable the HAL */
537 		s1394_hal_shutdown(hal, B_TRUE);
538 
539 		TNF_PROBE_1(h1394_cmd_is_complete_error,
540 		    S1394_TNF_SL_ATREQ_ATRESP_ERROR, "",
541 		    tnf_string, msg, "Invalid command type specified");
542 		break;
543 	}
544 
545 	TNF_PROBE_0_DEBUG(h1394_cmd_is_complete_exit,
546 	    S1394_TNF_SL_ATREQ_ATRESP_STACK, "");
547 }
548 
549 /*
550  * Function:    h1394_bus_reset()
551  * Input(s):    sl_private		The HAL "handle" returned by
552  *					    h1394_attach()
553  *
554  * Output(s):	selfid_buf_addr		The pointer to a buffer into which
555  *					    any Self ID packets should be put
556  *
557  * Description:	h1394_bus_reset() is called whenever a 1394 bus reset event
558  *		is detected by the HAL.  This routine simply prepares for
559  *		the subsequent Self ID packets.
560  */
561 void
562 h1394_bus_reset(void *sl_private, void **selfid_buf_addr)
563 {
564 	s1394_hal_t	*hal;
565 
566 	TNF_PROBE_0_DEBUG(h1394_bus_reset_enter, S1394_TNF_SL_BR_STACK, "");
567 
568 	hal = (s1394_hal_t *)sl_private;
569 
570 	mutex_enter(&hal->topology_tree_mutex);
571 
572 	/* Update the HAL's state */
573 	if (hal->hal_state != S1394_HAL_SHUTDOWN) {
574 		hal->hal_state = S1394_HAL_RESET;
575 	} else {
576 		mutex_exit(&hal->topology_tree_mutex);
577 		return;
578 	}
579 
580 	if (hal->initiated_bus_reset == B_TRUE) {
581 		hal->initiated_bus_reset = B_FALSE;
582 		if (hal->num_bus_reset_till_fail > 0) {
583 			hal->num_bus_reset_till_fail--;
584 		} else {
585 			TNF_PROBE_2(h1394_bus_reset_error,
586 			    S1394_TNF_SL_BR_ERROR, "",
587 			    tnf_string, msg, "Bus reset fail (too many resets)",
588 			    tnf_uint, br_type, hal->initiated_br_reason);
589 		}
590 	} else {
591 		hal->num_bus_reset_till_fail = NUM_BR_FAIL;
592 	}
593 
594 	/* Reset the IRM node ID */
595 	hal->IRM_node = -1;
596 
597 	/* Slowest node defaults to IEEE1394_S400 */
598 	hal->slowest_node_speed = IEEE1394_S400;
599 
600 	/* Pick a SelfID buffer to give */
601 	if (hal->current_buffer == 0) {
602 		*selfid_buf_addr = (void *)hal->selfid_buf1;
603 		hal->current_buffer = 1;
604 	} else {
605 		*selfid_buf_addr = (void *)hal->selfid_buf0;
606 		hal->current_buffer = 0;
607 	}
608 
609 	/* Disable the CSR topology_map (temporarily) */
610 	s1394_CSR_topology_map_disable(hal);
611 
612 	mutex_exit(&hal->topology_tree_mutex);
613 
614 	/* Reset the Bus Manager node ID */
615 	mutex_enter(&hal->bus_mgr_node_mutex);
616 	hal->bus_mgr_node = -1;
617 	mutex_exit(&hal->bus_mgr_node_mutex);
618 
619 	TNF_PROBE_0_DEBUG(h1394_bus_reset_exit, S1394_TNF_SL_BR_STACK, "");
620 }
621 
622 /*
623  * Function:    h1394_self_ids()
624  * Input(s):    sl_private		The HAL "handle" returned by
625  *					    h1394_attach()
626  *		selfid_buf_addr		Pointer to the Self ID buffer
627  *		selfid_size		The size of the filled part of the
628  *					    Self ID buffer
629  *		node_id			The local (host) node ID for the
630  *					    current generation
631  *		generation_count	The current generation number
632  *
633  * Output(s):	None
634  *
635  * Description:	h1394_self_ids() does alot of the work at bus reset.  It
636  *		takes the Self ID packets and parses them, builds a topology
637  *		tree representation of them, calculates gap count, IRM, speed
638  *		map, does any node matching that's possible, and then wakes
639  *		up the br_thread.
640  */
641 void
642 h1394_self_ids(void *sl_private, void *selfid_buf_addr, uint32_t selfid_size,
643     uint32_t node_id, uint32_t generation_count)
644 {
645 	s1394_hal_t	*hal;
646 	int		diameter;
647 	uint_t		gen_diff, gen_rollover;
648 	boolean_t	tree_copied = B_FALSE;
649 	ushort_t	saved_number_of_nodes;
650 
651 	/*
652 	 * NOTE: current topology tree is referred to as topology_tree
653 	 * and the old topology tree is referred to as old_tree.
654 	 * tree_valid indicates selfID buffer checked out OK and we were
655 	 * able to build the topology tree.
656 	 * tree_processed indicates we read the config ROMs as needed.
657 	 */
658 	TNF_PROBE_1_DEBUG(h1394_self_ids_enter, S1394_TNF_SL_BR_STACK, "",
659 	    tnf_uint, hal_generation, generation_count);
660 
661 	hal = (s1394_hal_t *)sl_private;
662 
663 	/* Lock the topology tree */
664 	mutex_enter(&hal->topology_tree_mutex);
665 	if (hal->hal_state == S1394_HAL_SHUTDOWN) {
666 		mutex_exit(&hal->topology_tree_mutex);
667 		TNF_PROBE_0_DEBUG(h1394_self_ids_exit, S1394_TNF_SL_BR_STACK,
668 		    "");
669 		return;
670 	}
671 
672 	/* kstats - number of selfid completes */
673 	hal->hal_kstats->selfid_complete++;
674 
675 	if (generation_count > hal->generation_count) {
676 		gen_diff = generation_count - hal->generation_count;
677 		hal->hal_kstats->bus_reset += gen_diff;
678 	} else {
679 		gen_diff = hal->generation_count - generation_count;
680 		/* Use max_generation to determine how many bus resets */
681 		hal->hal_kstats->bus_reset +=
682 		    (hal->halinfo.max_generation - gen_diff);
683 	}
684 
685 	/*
686 	 * If the current tree has a valid topology tree (selfids
687 	 * checked out OK etc) and config roms read as needed,
688 	 * then make it the old tree before building a new one.
689 	 */
690 	if ((hal->topology_tree_valid == B_TRUE) &&
691 	    (hal->topology_tree_processed == B_TRUE)) {
692 		TNF_PROBE_0_DEBUG(h1394_self_ids_tree_copy,
693 		    S1394_TNF_SL_BR_STACK, "");
694 		/* Trees are switched after the copy completes */
695 		s1394_copy_old_tree(hal);
696 		tree_copied = B_TRUE;
697 	}
698 
699 	/* Set the new generation and node id */
700 	hal->node_id = node_id;
701 	hal->generation_count = generation_count;
702 
703 	/* Invalidate the current topology tree */
704 	hal->topology_tree_valid = B_FALSE;
705 	hal->topology_tree_processed = B_FALSE;
706 	hal->cfgroms_being_read = 0;
707 
708 	TNF_PROBE_0_DEBUG(h1394_self_ids_parse_selfid, S1394_TNF_SL_BR_STACK,
709 	    "");
710 
711 	/*
712 	 * Save the number of nodes prior to parsing the self id buffer.
713 	 * We need this saved value while initializing the topology tree
714 	 * (for non-copy case).
715 	 */
716 	saved_number_of_nodes = hal->number_of_nodes;
717 
718 	/* Parse the SelfID buffer */
719 	if (s1394_parse_selfid_buffer(hal, selfid_buf_addr, selfid_size) !=
720 	    DDI_SUCCESS) {
721 		/* Unlock the topology tree */
722 		mutex_exit(&hal->topology_tree_mutex);
723 		TNF_PROBE_1(h1394_self_ids_error, S1394_TNF_SL_BR_ERROR, "",
724 		    tnf_string, msg, "Unable to parse selfID buffer");
725 		TNF_PROBE_0_DEBUG(h1394_self_ids_exit, S1394_TNF_SL_BR_STACK,
726 		    "");
727 
728 		/* kstats - SelfID buffer error */
729 		hal->hal_kstats->selfid_buffer_error++;
730 		return;		/* Error parsing SelfIDs */
731 	}
732 
733 	/* Sort the SelfID packets by node number (if it's a 1995 PHY) */
734 	if (hal->halinfo.phy == H1394_PHY_1995) {
735 		TNF_PROBE_0_DEBUG(h1394_self_ids_sort, S1394_TNF_SL_BR_STACK,
736 		    "");
737 		s1394_sort_selfids(hal);
738 	}
739 
740 	/*
741 	 * Update the cycle master timer - if the timer is set and
742 	 * we were the root but we are not anymore, then disable it.
743 	 */
744 	mutex_enter(&hal->cm_timer_mutex);
745 	if ((hal->cm_timer_set == B_TRUE) &&
746 	    ((hal->old_number_of_nodes - 1) ==
747 		IEEE1394_NODE_NUM(hal->old_node_id)) &&
748 	    ((hal->number_of_nodes - 1) !=
749 		IEEE1394_NODE_NUM(hal->node_id))) {
750 		mutex_exit(&hal->cm_timer_mutex);
751 		(void) untimeout(hal->cm_timer);
752 	} else {
753 		mutex_exit(&hal->cm_timer_mutex);
754 	}
755 
756 	TNF_PROBE_0_DEBUG(h1394_self_ids_init_topology, S1394_TNF_SL_BR_STACK,
757 	    "");
758 	s1394_init_topology_tree(hal, tree_copied, saved_number_of_nodes);
759 
760 	/* Determine the 1394 bus gap count */
761 	hal->gap_count = s1394_get_current_gap_count(hal);
762 	/* If gap counts are inconsistent, reset */
763 	if (hal->gap_count == -1) {
764 		/* Unlock the topology tree */
765 		mutex_exit(&hal->topology_tree_mutex);
766 		TNF_PROBE_1(h1394_self_ids_error, S1394_TNF_SL_BR_ERROR, "",
767 		    tnf_string, msg, "Invalid gap counts in SelfID pkts");
768 		TNF_PROBE_0_DEBUG(h1394_self_ids_exit, S1394_TNF_SL_BR_STACK,
769 		    "");
770 
771 		/* kstats - SelfID buffer error (invalid gap counts) */
772 		hal->hal_kstats->selfid_buffer_error++;
773 
774 		if (s1394_ignore_invalid_gap_cnt == 1) {
775 			/* Lock the topology tree again */
776 			mutex_enter(&hal->topology_tree_mutex);
777 			hal->gap_count = 0x3F;
778 		} else {
779 			return;	/* Invalid gap counts in SelfID buffer */
780 		}
781 	}
782 
783 	TNF_PROBE_1_DEBUG(h1394_self_ids_get_gap_count, S1394_TNF_SL_BR_STACK,
784 	    "", tnf_uint, gap_count, hal->gap_count);
785 
786 	/* Determine the Isoch Resource Manager */
787 	hal->IRM_node = s1394_get_isoch_rsrc_mgr(hal);
788 
789 	TNF_PROBE_1_DEBUG(h1394_self_ids_IRM_node, S1394_TNF_SL_BR_STACK, "",
790 	    tnf_int, IRM_node, hal->IRM_node);
791 
792 	TNF_PROBE_0_DEBUG(h1394_self_ids_build_topology_tree,
793 	    S1394_TNF_SL_BR_STACK, "");
794 
795 	/* Build the topology tree */
796 	if (s1394_topology_tree_build(hal) != DDI_SUCCESS) {
797 		/* Unlock the topology tree */
798 		mutex_exit(&hal->topology_tree_mutex);
799 		TNF_PROBE_1(h1394_self_ids_error, S1394_TNF_SL_BR_ERROR, "",
800 		    tnf_string, msg, "Error building the topology tree");
801 		TNF_PROBE_0_DEBUG(h1394_self_ids_exit, S1394_TNF_SL_BR_STACK,
802 		    "");
803 
804 		/* kstats - SelfID buffer error (Invalid topology tree) */
805 		hal->hal_kstats->selfid_buffer_error++;
806 		return;		/* Error building topology tree from SelfIDs */
807 	}
808 
809 	TNF_PROBE_0_DEBUG(h1394_self_ids_topology_CSRs, S1394_TNF_SL_BR_STACK,
810 	    "");
811 
812 	/* Update the CSR topology_map */
813 	s1394_CSR_topology_map_update(hal);
814 
815 	/* Calculate the diameter */
816 	diameter = s1394_topology_tree_calculate_diameter(hal);
817 
818 	/* Determine the optimum gap count */
819 	hal->optimum_gap_count = s1394_gap_count_optimize(diameter);
820 
821 	TNF_PROBE_1_DEBUG(h1394_self_ids_diameter_and_gap_count,
822 	    S1394_TNF_SL_BR_STACK, "",
823 	    tnf_uint, optimum_gap, hal->optimum_gap_count);
824 
825 	TNF_PROBE_0_DEBUG(h1394_self_ids_speed_map, S1394_TNF_SL_BR_STACK, "");
826 
827 	/* Fill in the speed map */
828 	s1394_speed_map_fill(hal);
829 
830 	/* Initialize the two trees (for tree walking) */
831 	s1394_topology_tree_mark_all_unvisited(hal);
832 	s1394_old_tree_mark_all_unvisited(hal);
833 	s1394_old_tree_mark_all_unmatched(hal);
834 
835 	/* Are both trees (old and new) valid? */
836 	if ((hal->old_tree_valid == B_TRUE) &&
837 	    (hal->topology_tree_valid == B_TRUE)) {
838 		/* If HAL was in a suspended state, then do no matching */
839 		if (hal->hal_was_suspended == B_TRUE) {
840 		    hal->hal_was_suspended = B_FALSE;
841 		} else {
842 			gen_rollover = hal->halinfo.max_generation + 1;
843 			/* If only one bus reset occurred, match the trees */
844 			if (((hal->old_generation_count + 1) % gen_rollover) ==
845 			    generation_count) {
846 				TNF_PROBE_0_DEBUG(h1394_self_ids_tree_matching,
847 				    S1394_TNF_SL_BR_STACK, "");
848 				s1394_match_tree_nodes(hal);
849 			}
850 		}
851 	}
852 
853 	/* Unlock the topology tree */
854 	mutex_exit(&hal->topology_tree_mutex);
855 
856 	/* Wake up the bus reset processing thread */
857 	s1394_tickle_bus_reset_thread(hal);
858 
859 	TNF_PROBE_0_DEBUG(h1394_self_ids_exit,
860 	    S1394_TNF_SL_BR_STACK, "");
861 }
862 
863 /*
864  * Function:    h1394_read_request()
865  * Input(s):    sl_private		The HAL "handle" returned by
866  *					    h1394_attach()
867  *		req			The incoming AR request
868  *
869  * Output(s):	None
870  *
871  * Description:	h1394_read_request() receives incoming AR requests.  These
872  *		asynchronous read requests are dispatched to the appropriate
873  *		target (if one has registered) or are handled by the 1394
874  *		Software Framework, which will send out an appropriate
875  *		response.
876  */
877 void
878 h1394_read_request(void *sl_private, cmd1394_cmd_t *req)
879 {
880 	s1394_hal_t		*hal;
881 	s1394_cmd_priv_t	*s_priv;
882 	s1394_addr_space_blk_t  *addr_blk;
883 	dev_info_t		*dip;
884 	uint64_t		end_of_request;
885 	uint32_t		offset;
886 	size_t			cmd_length;
887 	uchar_t			*bufp_addr;
888 	uchar_t			*begin_ptr;
889 	uchar_t			*end_ptr;
890 	uchar_t			*tmp_ptr;
891 	void (*recv_read_req)(cmd1394_cmd_t *);
892 
893 	TNF_PROBE_0_DEBUG(h1394_read_request_enter, S1394_TNF_SL_ARREQ_STACK,
894 	    "");
895 
896 	hal = (s1394_hal_t *)sl_private;
897 
898 	/* Get the Services Layer private area */
899 	s_priv = S1394_GET_CMD_PRIV(req);
900 
901 	s_priv->cmd_priv_xfer_type = S1394_CMD_READ;
902 
903 	switch (req->cmd_type) {
904 	case CMD1394_ASYNCH_RD_QUAD:
905 		cmd_length = IEEE1394_QUADLET;
906 		hal->hal_kstats->arreq_quad_rd++;
907 		break;
908 
909 	case CMD1394_ASYNCH_RD_BLOCK:
910 		cmd_length = req->cmd_u.b.blk_length;
911 		hal->hal_kstats->arreq_blk_rd++;
912 		break;
913 
914 	default:
915 		dip = hal->halinfo.dip;
916 
917 		/* An unexpected error in the HAL */
918 		cmn_err(CE_WARN, HALT_ERROR_MESSAGE,
919 		    ddi_node_name(dip), ddi_get_instance(dip));
920 
921 		/* Disable the HAL */
922 		s1394_hal_shutdown(hal, B_TRUE);
923 
924 		TNF_PROBE_1(h1394_read_request_error,
925 		    S1394_TNF_SL_ARREQ_ERROR, "",
926 		    tnf_string, msg, "Invalid command type specified");
927 		TNF_PROBE_0_DEBUG(h1394_read_request_exit,
928 		    S1394_TNF_SL_ARREQ_STACK, "");
929 		return;
930 	}
931 
932 	/* Lock the "used" tree */
933 	mutex_enter(&hal->addr_space_used_mutex);
934 
935 	/* Has the 1394 address been allocated? */
936 	addr_blk = s1394_used_tree_search(hal, req->cmd_addr);
937 
938 	TNF_PROBE_0_DEBUG(h1394_read_request_addr_search,
939 	    S1394_TNF_SL_ARREQ_STACK, "");
940 
941 	/* If it wasn't found, it isn't owned... */
942 	if (addr_blk == NULL) {
943 		/* Unlock the "used" tree */
944 		mutex_exit(&hal->addr_space_used_mutex);
945 		req->cmd_result = IEEE1394_RESP_ADDRESS_ERROR;
946 		(void) s1394_send_response(hal, req);
947 		TNF_PROBE_0_DEBUG(h1394_read_request_exit,
948 		    S1394_TNF_SL_ARREQ_STACK, "");
949 		return;
950 	}
951 
952 	/* Does the WHOLE request fit in the allocated block? */
953 	end_of_request = (req->cmd_addr + cmd_length) - 1;
954 	if (end_of_request > addr_blk->addr_hi) {
955 		/* Unlock the "used" tree */
956 		mutex_exit(&hal->addr_space_used_mutex);
957 		req->cmd_result = IEEE1394_RESP_ADDRESS_ERROR;
958 		(void) s1394_send_response(hal, req);
959 		TNF_PROBE_0_DEBUG(h1394_read_request_exit,
960 		    S1394_TNF_SL_ARREQ_STACK, "");
961 		return;
962 	}
963 
964 	/* Is a read request valid for this address space? */
965 	if (!(addr_blk->addr_enable & T1394_ADDR_RDENBL)) {
966 		/* Unlock the "used" tree */
967 		mutex_exit(&hal->addr_space_used_mutex);
968 		req->cmd_result = IEEE1394_RESP_TYPE_ERROR;
969 		(void) s1394_send_response(hal, req);
970 		TNF_PROBE_0_DEBUG(h1394_read_request_exit,
971 		    S1394_TNF_SL_ARREQ_STACK, "");
972 		return;
973 	}
974 
975 	/* Make sure quadlet requests are quadlet-aligned */
976 	offset = req->cmd_addr - addr_blk->addr_lo;
977 	if ((req->cmd_type == CMD1394_ASYNCH_RD_QUAD) &&
978 	    ((offset & 0x3) != 0)) {
979 		/* Unlock the "used" tree */
980 		mutex_exit(&hal->addr_space_used_mutex);
981 		req->cmd_result = IEEE1394_RESP_TYPE_ERROR;
982 		(void) s1394_send_response(hal, req);
983 		TNF_PROBE_0_DEBUG(h1394_read_request_exit,
984 		    S1394_TNF_SL_ARREQ_STACK, "");
985 		return;
986 	}
987 
988 	/* Fill in the backing store if necessary */
989 	if (addr_blk->kmem_bufp != NULL) {
990 		offset = req->cmd_addr - addr_blk->addr_lo;
991 		bufp_addr = (uchar_t *)addr_blk->kmem_bufp + offset;
992 
993 		switch (req->cmd_type) {
994 		case CMD1394_ASYNCH_RD_QUAD:
995 			bcopy((void *)bufp_addr,
996 			    (void *)&(req->cmd_u.q.quadlet_data), cmd_length);
997 			break;
998 
999 		case CMD1394_ASYNCH_RD_BLOCK:
1000 			begin_ptr = req->cmd_u.b.data_block->b_wptr;
1001 			end_ptr	  = begin_ptr + cmd_length;
1002 			tmp_ptr	  = req->cmd_u.b.data_block->b_datap->db_lim;
1003 			if (end_ptr <= tmp_ptr) {
1004 				bcopy((void *)bufp_addr, (void *)begin_ptr,
1005 				    cmd_length);
1006 				/* Update b_wptr to refelect the new data */
1007 				req->cmd_u.b.data_block->b_wptr = end_ptr;
1008 			} else {
1009 				dip = hal->halinfo.dip;
1010 
1011 				/* An unexpected error in the HAL */
1012 				cmn_err(CE_WARN, HALT_ERROR_MESSAGE,
1013 				    ddi_node_name(dip), ddi_get_instance(dip));
1014 
1015 				/* Unlock the "used" tree */
1016 				mutex_exit(&hal->addr_space_used_mutex);
1017 
1018 				/* Disable the HAL */
1019 				s1394_hal_shutdown(hal, B_TRUE);
1020 
1021 				TNF_PROBE_1(h1394_read_request_error,
1022 				    S1394_TNF_SL_ARREQ_ERROR, "", tnf_string,
1023 				    msg, "Error - mblk too small for request");
1024 				TNF_PROBE_0_DEBUG(h1394_read_request_exit,
1025 				    S1394_TNF_SL_ARREQ_STACK, "");
1026 				return;
1027 			}
1028 			break;
1029 
1030 		default:
1031 			dip = hal->halinfo.dip;
1032 
1033 			/* An unexpected error in the HAL */
1034 			cmn_err(CE_WARN, HALT_ERROR_MESSAGE,
1035 			    ddi_node_name(dip), ddi_get_instance(dip));
1036 
1037 			/* Unlock the "used" tree */
1038 			mutex_exit(&hal->addr_space_used_mutex);
1039 
1040 			/* Disable the HAL */
1041 			s1394_hal_shutdown(hal, B_TRUE);
1042 
1043 			TNF_PROBE_1(h1394_read_request_error,
1044 			    S1394_TNF_SL_ARREQ_ERROR, "", tnf_string, msg,
1045 			    "Invalid command type specified");
1046 			TNF_PROBE_0_DEBUG(h1394_read_request_exit,
1047 			    S1394_TNF_SL_ARREQ_STACK, "");
1048 			return;
1049 		}
1050 	}
1051 
1052 	/* Fill in the rest of the info in the request */
1053 	s_priv->arreq_valid_addr = B_TRUE;
1054 	req->cmd_callback_arg	 = addr_blk->addr_arg;
1055 	recv_read_req		 = addr_blk->addr_events.recv_read_request;
1056 
1057 	/* Unlock the "used" tree */
1058 	mutex_exit(&hal->addr_space_used_mutex);
1059 
1060 	/*
1061 	 * Add no code that modifies the command after the target
1062 	 * callback is called or after the response is sent to the
1063 	 * HAL.
1064 	 */
1065 	if (recv_read_req != NULL) {
1066 		TNF_PROBE_0_DEBUG(h1394_read_request_do_callback,
1067 		    S1394_TNF_SL_ARREQ_STACK, "");
1068 		recv_read_req(req);
1069 	} else {
1070 		req->cmd_result = IEEE1394_RESP_COMPLETE;
1071 		(void) s1394_send_response(hal, req);
1072 		TNF_PROBE_0_DEBUG(h1394_read_request_exit,
1073 		    S1394_TNF_SL_ARREQ_STACK, "");
1074 		return;
1075 	}
1076 
1077 	TNF_PROBE_0_DEBUG(h1394_read_request_exit, S1394_TNF_SL_ARREQ_STACK,
1078 	    "");
1079 }
1080 
1081 /*
1082  * Function:    h1394_write_request()
1083  * Input(s):    sl_private		The HAL "handle" returned by
1084  *					    h1394_attach()
1085  *		req			The incoming AR request
1086  *
1087  * Output(s):	None
1088  *
1089  * Description:	h1394_write_request() receives incoming AR requests.  These
1090  *		asynchronous write requests are dispatched to the appropriate
1091  *		target (if one has registered) or are handled by the 1394
1092  *		Software Framework, which will send out an appropriate
1093  *		response.
1094  */
1095 void
1096 h1394_write_request(void *sl_private, cmd1394_cmd_t *req)
1097 {
1098 	s1394_hal_t		*hal;
1099 	s1394_cmd_priv_t	*s_priv;
1100 	h1394_cmd_priv_t	*h_priv;
1101 	s1394_addr_space_blk_t	*addr_blk;
1102 	dev_info_t		*dip;
1103 	uint32_t		offset;
1104 	size_t			cmd_length;
1105 	uchar_t			*bufp_addr;
1106 	uchar_t			*begin_ptr;
1107 	uchar_t			*end_ptr;
1108 	uchar_t			*tmp_ptr;
1109 	uint64_t		end_of_request;
1110 	boolean_t		posted_write = B_FALSE;
1111 	boolean_t		write_error = B_FALSE;
1112 	void (*recv_write_req)(cmd1394_cmd_t *);
1113 
1114 	TNF_PROBE_0_DEBUG(h1394_write_request_enter, S1394_TNF_SL_ARREQ_STACK,
1115 	    "");
1116 
1117 	hal = (s1394_hal_t *)sl_private;
1118 
1119 	/* Get the Services Layer private area */
1120 	s_priv = S1394_GET_CMD_PRIV(req);
1121 
1122 	s_priv->cmd_priv_xfer_type = S1394_CMD_WRITE;
1123 
1124 	switch (req->cmd_type) {
1125 	case CMD1394_ASYNCH_WR_QUAD:
1126 		cmd_length = IEEE1394_QUADLET;
1127 		hal->hal_kstats->arreq_quad_wr++;
1128 		break;
1129 
1130 	case CMD1394_ASYNCH_WR_BLOCK:
1131 		cmd_length = req->cmd_u.b.blk_length;
1132 		hal->hal_kstats->arreq_blk_wr++;
1133 		hal->hal_kstats->arreq_blk_wr_size += cmd_length;
1134 		break;
1135 
1136 	default:
1137 		dip = hal->halinfo.dip;
1138 
1139 		/* An unexpected error in the HAL */
1140 		cmn_err(CE_WARN, HALT_ERROR_MESSAGE,
1141 		    ddi_node_name(dip), ddi_get_instance(dip));
1142 
1143 		/* Disable the HAL */
1144 		s1394_hal_shutdown(hal, B_TRUE);
1145 
1146 		TNF_PROBE_1(h1394_write_request_error,
1147 		    S1394_TNF_SL_ARREQ_ERROR, "", tnf_string, msg,
1148 		    "Invalid command type specified");
1149 		TNF_PROBE_0_DEBUG(h1394_write_request_exit,
1150 		    S1394_TNF_SL_ARREQ_STACK, "");
1151 		return;
1152 	}
1153 
1154 	/* Lock the "used" tree */
1155 	mutex_enter(&hal->addr_space_used_mutex);
1156 
1157 	/* Has the 1394 address been allocated? */
1158 	addr_blk = s1394_used_tree_search(hal, req->cmd_addr);
1159 
1160 	TNF_PROBE_0_DEBUG(h1394_write_request_addr_search,
1161 	    S1394_TNF_SL_ARREQ_STACK, "");
1162 
1163 	/* Is this a posted write request? */
1164 	posted_write = s1394_is_posted_write(hal, req->cmd_addr);
1165 
1166 	/* If it wasn't found, it isn't owned... */
1167 	if (addr_blk == NULL) {
1168 		req->cmd_result = IEEE1394_RESP_ADDRESS_ERROR;
1169 		write_error	= B_TRUE;
1170 		goto write_error_check;
1171 	}
1172 
1173 	/* Does the WHOLE request fit in the allocated block? */
1174 	end_of_request = (req->cmd_addr + cmd_length) - 1;
1175 	if (end_of_request > addr_blk->addr_hi) {
1176 		req->cmd_result = IEEE1394_RESP_ADDRESS_ERROR;
1177 		write_error	= B_TRUE;
1178 		goto write_error_check;
1179 	}
1180 
1181 	/* Is a write request valid for this address space? */
1182 	if (!(addr_blk->addr_enable & T1394_ADDR_WRENBL)) {
1183 		req->cmd_result = IEEE1394_RESP_TYPE_ERROR;
1184 		write_error	= B_TRUE;
1185 		goto write_error_check;
1186 	}
1187 
1188 	/* Make sure quadlet request is quadlet aligned */
1189 	offset = req->cmd_addr - addr_blk->addr_lo;
1190 	if ((req->cmd_type == CMD1394_ASYNCH_WR_QUAD) &&
1191 	    ((offset & 0x3) != 0)) {
1192 		req->cmd_result = IEEE1394_RESP_TYPE_ERROR;
1193 		write_error	= B_TRUE;
1194 		goto write_error_check;
1195 	}
1196 
1197 write_error_check:
1198 	/* Check if posted-write when sending error responses */
1199 	if (write_error == B_TRUE) {
1200 		/* Unlock the "used" tree */
1201 		mutex_exit(&hal->addr_space_used_mutex);
1202 
1203 		if (posted_write == B_TRUE) {
1204 			/* Get a pointer to the HAL private struct */
1205 			h_priv = (h1394_cmd_priv_t *)&s_priv->hal_cmd_private;
1206 			hal->hal_kstats->arreq_posted_write_error++;
1207 			/* Free the command - Pass it back to the HAL */
1208 			HAL_CALL(hal).response_complete(
1209 			    hal->halinfo.hal_private, req, h_priv);
1210 			TNF_PROBE_0_DEBUG(h1394_write_request_exit,
1211 			    S1394_TNF_SL_ARREQ_STACK, "");
1212 			return;
1213 		} else {
1214 			(void) s1394_send_response(hal, req);
1215 			TNF_PROBE_0_DEBUG(h1394_write_request_exit,
1216 			    S1394_TNF_SL_ARREQ_STACK, "");
1217 			return;
1218 		}
1219 	}
1220 
1221 	/* Fill in the backing store if necessary */
1222 	if (addr_blk->kmem_bufp != NULL) {
1223 		offset = req->cmd_addr - addr_blk->addr_lo;
1224 		bufp_addr = (uchar_t *)addr_blk->kmem_bufp + offset;
1225 		switch (req->cmd_type) {
1226 		case CMD1394_ASYNCH_WR_QUAD:
1227 			bcopy((void *)&(req->cmd_u.q.quadlet_data),
1228 			    (void *)bufp_addr, cmd_length);
1229 			break;
1230 
1231 		case CMD1394_ASYNCH_WR_BLOCK:
1232 			begin_ptr = req->cmd_u.b.data_block->b_rptr;
1233 			end_ptr = begin_ptr + cmd_length;
1234 			tmp_ptr = req->cmd_u.b.data_block->b_wptr;
1235 			if (end_ptr <= tmp_ptr) {
1236 				bcopy((void *)begin_ptr, (void *)bufp_addr,
1237 				    cmd_length);
1238 			} else {
1239 				dip = hal->halinfo.dip;
1240 
1241 				/* An unexpected error in the HAL */
1242 				cmn_err(CE_WARN, HALT_ERROR_MESSAGE,
1243 				    ddi_node_name(dip), ddi_get_instance(dip));
1244 
1245 				/* Unlock the "used" tree */
1246 				mutex_exit(&hal->addr_space_used_mutex);
1247 
1248 				/* Disable the HAL */
1249 				s1394_hal_shutdown(hal, B_TRUE);
1250 
1251 				TNF_PROBE_1(h1394_write_request_error,
1252 				    S1394_TNF_SL_ARREQ_ERROR, "", tnf_string,
1253 				    msg, "Error - mblk too small for request");
1254 				TNF_PROBE_0_DEBUG(h1394_write_request_exit,
1255 				    S1394_TNF_SL_ARREQ_STACK, "");
1256 				return;
1257 			}
1258 			break;
1259 
1260 		default:
1261 			dip = hal->halinfo.dip;
1262 
1263 			/* An unexpected error in the HAL */
1264 			cmn_err(CE_WARN, HALT_ERROR_MESSAGE,
1265 			    ddi_node_name(dip), ddi_get_instance(dip));
1266 
1267 			/* Unlock the "used" tree */
1268 			mutex_exit(&hal->addr_space_used_mutex);
1269 
1270 			/* Disable the HAL */
1271 			s1394_hal_shutdown(hal, B_TRUE);
1272 
1273 			TNF_PROBE_1(h1394_write_request_error,
1274 			    S1394_TNF_SL_ARREQ_ERROR, "", tnf_string, msg,
1275 			    "Invalid command type specified");
1276 			TNF_PROBE_0_DEBUG(h1394_write_request_exit,
1277 			    S1394_TNF_SL_ARREQ_STACK, "");
1278 			return;
1279 		}
1280 	}
1281 
1282 	/* Fill in the rest of the info in the request */
1283 	if (addr_blk->addr_type == T1394_ADDR_POSTED_WRITE)
1284 		s_priv->posted_write = B_TRUE;
1285 
1286 	s_priv->arreq_valid_addr = B_TRUE;
1287 	req->cmd_callback_arg	 = addr_blk->addr_arg;
1288 	recv_write_req		 = addr_blk->addr_events.recv_write_request;
1289 
1290 	/* Unlock the "used" tree */
1291 	mutex_exit(&hal->addr_space_used_mutex);
1292 
1293 	/*
1294 	 * Add no code that modifies the command after the target
1295 	 * callback is called or after the response is sent to the
1296 	 * HAL.
1297 	 */
1298 	if (recv_write_req != NULL) {
1299 		TNF_PROBE_0_DEBUG(h1394_write_request_do_callback,
1300 		    S1394_TNF_SL_ARREQ_STACK, "");
1301 		recv_write_req(req);
1302 	} else {
1303 		req->cmd_result = IEEE1394_RESP_COMPLETE;
1304 		(void) s1394_send_response(hal, req);
1305 		TNF_PROBE_0_DEBUG(h1394_write_request_exit,
1306 		    S1394_TNF_SL_ARREQ_STACK, "");
1307 		return;
1308 	}
1309 
1310 	TNF_PROBE_0_DEBUG(h1394_write_request_exit,
1311 	    S1394_TNF_SL_ARREQ_STACK, "");
1312 }
1313 
1314 /*
1315  * Function:    h1394_lock_request()
1316  * Input(s):    sl_private		The HAL "handle" returned by
1317  *					    h1394_attach()
1318  *		req			The incoming AR request
1319  *
1320  * Output(s):	None
1321  *
1322  * Description:	h1394_lock_request() receives incoming AR requests.  These
1323  *		asynchronous lock requests are dispatched to the appropriate
1324  *		target (if one has registered) or are handled by the 1394
1325  *		Software Framework, which will send out an appropriate
1326  *		response.
1327  */
1328 void
1329 h1394_lock_request(void *sl_private, cmd1394_cmd_t *req)
1330 {
1331 	s1394_hal_t		*hal;
1332 	s1394_cmd_priv_t	*s_priv;
1333 	s1394_addr_space_blk_t	*addr_blk;
1334 	dev_info_t		*dip;
1335 	uint64_t		end_of_request;
1336 	uint32_t		offset;
1337 	uchar_t			*bufp_addr;
1338 	cmd1394_lock_type_t	lock_type;
1339 	void (*recv_lock_req)(cmd1394_cmd_t *);
1340 
1341 	TNF_PROBE_0_DEBUG(h1394_lock_request_enter,
1342 	    S1394_TNF_SL_ARREQ_STACK, "");
1343 
1344 	hal = (s1394_hal_t *)sl_private;
1345 
1346 	/* Get the Services Layer private area */
1347 	s_priv = S1394_GET_CMD_PRIV(req);
1348 
1349 	s_priv->cmd_priv_xfer_type = S1394_CMD_LOCK;
1350 
1351 	/* Lock the "used" tree */
1352 	mutex_enter(&hal->addr_space_used_mutex);
1353 
1354 	/* Has the 1394 address been allocated? */
1355 	addr_blk = s1394_used_tree_search(hal, req->cmd_addr);
1356 
1357 	/* If it wasn't found, it isn't owned... */
1358 	if (addr_blk == NULL) {
1359 		/* Unlock the "used" tree */
1360 		mutex_exit(&hal->addr_space_used_mutex);
1361 		req->cmd_result = IEEE1394_RESP_ADDRESS_ERROR;
1362 		(void) s1394_send_response(hal, req);
1363 		TNF_PROBE_0_DEBUG(h1394_lock_request_exit,
1364 		    S1394_TNF_SL_ARREQ_STACK, "");
1365 		return;
1366 	}
1367 
1368 	/* Does the WHOLE request fit in the allocated block? */
1369 	switch (req->cmd_type) {
1370 	case CMD1394_ASYNCH_LOCK_32:
1371 		end_of_request = (req->cmd_addr + IEEE1394_QUADLET) - 1;
1372 		/* kstats - 32-bit lock request */
1373 		hal->hal_kstats->arreq_lock32++;
1374 		break;
1375 
1376 	case CMD1394_ASYNCH_LOCK_64:
1377 		end_of_request = (req->cmd_addr + IEEE1394_OCTLET) - 1;
1378 		/* kstats - 64-bit lock request */
1379 		hal->hal_kstats->arreq_lock64++;
1380 		break;
1381 
1382 	default:
1383 		/* Unlock the "used" tree */
1384 		mutex_exit(&hal->addr_space_used_mutex);
1385 
1386 		dip = hal->halinfo.dip;
1387 
1388 		/* An unexpected error in the HAL */
1389 		cmn_err(CE_WARN, HALT_ERROR_MESSAGE,
1390 		    ddi_node_name(dip), ddi_get_instance(dip));
1391 
1392 		/* Disable the HAL */
1393 		s1394_hal_shutdown(hal, B_TRUE);
1394 
1395 		TNF_PROBE_1(h1394_lock_request_error,
1396 		    S1394_TNF_SL_ARREQ_ERROR, "", tnf_string, msg,
1397 		    "Invalid command type specified");
1398 		TNF_PROBE_0_DEBUG(h1394_lock_request_exit,
1399 		    S1394_TNF_SL_ARREQ_STACK, "");
1400 		return;
1401 	}
1402 
1403 	if (end_of_request > addr_blk->addr_hi) {
1404 		/* Unlock the "used" tree */
1405 		mutex_exit(&hal->addr_space_used_mutex);
1406 		req->cmd_result = IEEE1394_RESP_ADDRESS_ERROR;
1407 		(void) s1394_send_response(hal, req);
1408 		TNF_PROBE_0_DEBUG(h1394_lock_request_exit,
1409 		    S1394_TNF_SL_ARREQ_STACK, "");
1410 		return;
1411 	}
1412 
1413 	/* Is a lock request valid for this address space? */
1414 	if (!(addr_blk->addr_enable & T1394_ADDR_LKENBL)) {
1415 		/* Unlock the "used" tree */
1416 		mutex_exit(&hal->addr_space_used_mutex);
1417 		req->cmd_result = IEEE1394_RESP_TYPE_ERROR;
1418 		(void) s1394_send_response(hal, req);
1419 		TNF_PROBE_0_DEBUG(h1394_lock_request_exit,
1420 		    S1394_TNF_SL_ARREQ_STACK, "");
1421 		return;
1422 	}
1423 
1424 	/* Fill in the backing store if necessary */
1425 	if (addr_blk->kmem_bufp != NULL) {
1426 		offset = req->cmd_addr - addr_blk->addr_lo;
1427 		bufp_addr = (uchar_t *)addr_blk->kmem_bufp + offset;
1428 
1429 		if (req->cmd_type == CMD1394_ASYNCH_LOCK_32) {
1430 			uint32_t	old_value;
1431 			uint32_t	arg_value;
1432 			uint32_t	data_value;
1433 			uint32_t	new_value;
1434 
1435 			arg_value	= req->cmd_u.l32.arg_value;
1436 			data_value	= req->cmd_u.l32.data_value;
1437 			lock_type	= req->cmd_u.l32.lock_type;
1438 			bcopy((void *)bufp_addr, (void *)&old_value,
1439 			    IEEE1394_QUADLET);
1440 
1441 			switch (lock_type) {
1442 			case CMD1394_LOCK_MASK_SWAP:
1443 				/* Mask-Swap (see P1394A - Table 1.7) */
1444 				new_value = (data_value & arg_value) |
1445 				    (old_value & ~arg_value);
1446 				/* Copy new_value into backing store */
1447 				bcopy((void *)&new_value, (void *)bufp_addr,
1448 				    IEEE1394_QUADLET);
1449 				req->cmd_u.l32.old_value = old_value;
1450 				break;
1451 
1452 			case CMD1394_LOCK_COMPARE_SWAP:
1453 				/* Compare-Swap */
1454 				if (old_value == arg_value) {
1455 					new_value = data_value;
1456 					/* Copy new_value into backing store */
1457 					bcopy((void *)&new_value,
1458 					    (void *)bufp_addr,
1459 					    IEEE1394_QUADLET);
1460 				}
1461 				req->cmd_u.l32.old_value = old_value;
1462 				break;
1463 
1464 			case CMD1394_LOCK_FETCH_ADD:
1465 				/* Fetch-Add (see P1394A - Table 1.7) */
1466 				old_value = T1394_DATA32(old_value);
1467 				new_value = old_value + data_value;
1468 				new_value = T1394_DATA32(new_value);
1469 				/* Copy new_value into backing store */
1470 				bcopy((void *)&new_value, (void *)bufp_addr,
1471 				    IEEE1394_QUADLET);
1472 				req->cmd_u.l32.old_value = old_value;
1473 				break;
1474 
1475 			case CMD1394_LOCK_LITTLE_ADD:
1476 				/* Little-Add (see P1394A - Table 1.7) */
1477 				old_value = T1394_DATA32(old_value);
1478 				new_value = old_value + data_value;
1479 				new_value = T1394_DATA32(new_value);
1480 				/* Copy new_value into backing store */
1481 				bcopy((void *)&new_value, (void *)bufp_addr,
1482 				    IEEE1394_QUADLET);
1483 				req->cmd_u.l32.old_value = old_value;
1484 				break;
1485 
1486 			case CMD1394_LOCK_BOUNDED_ADD:
1487 				/* Bounded-Add (see P1394A - Table 1.7) */
1488 				old_value = T1394_DATA32(old_value);
1489 				if (old_value != arg_value) {
1490 					new_value = old_value + data_value;
1491 					new_value = T1394_DATA32(new_value);
1492 					/* Copy new_value into backing store */
1493 					bcopy((void *)&new_value,
1494 					    (void *)bufp_addr,
1495 					    IEEE1394_QUADLET);
1496 				}
1497 				req->cmd_u.l32.old_value = old_value;
1498 				break;
1499 
1500 			case CMD1394_LOCK_WRAP_ADD:
1501 				/* Wrap-Add (see P1394A - Table 1.7) */
1502 				old_value = T1394_DATA32(old_value);
1503 				if (old_value != arg_value) {
1504 					new_value = old_value + data_value;
1505 				} else {
1506 					new_value = data_value;
1507 				}
1508 				new_value = T1394_DATA32(new_value);
1509 				/* Copy new_value into backing store */
1510 				bcopy((void *)&new_value, (void *)bufp_addr,
1511 				    IEEE1394_QUADLET);
1512 				req->cmd_u.l32.old_value = old_value;
1513 				break;
1514 
1515 			default:
1516 				/* Unlock the "used" tree */
1517 				mutex_exit(&hal->addr_space_used_mutex);
1518 				req->cmd_result = IEEE1394_RESP_TYPE_ERROR;
1519 				(void) s1394_send_response(hal, req);
1520 				TNF_PROBE_1(h1394_lock_request_error,
1521 				    S1394_TNF_SL_ARREQ_ERROR, "", tnf_string,
1522 				    msg, "Invalid lock_type");
1523 				TNF_PROBE_0_DEBUG(h1394_lock_request_exit,
1524 				    S1394_TNF_SL_ARREQ_STACK, "");
1525 				return;
1526 			}
1527 		} else {
1528 			/* Handling for the 8-byte (64-bit) lock requests */
1529 			uint64_t	old_value;
1530 			uint64_t	arg_value;
1531 			uint64_t	data_value;
1532 			uint64_t	new_value;
1533 
1534 			arg_value	= req->cmd_u.l64.arg_value;
1535 			data_value	= req->cmd_u.l64.data_value;
1536 			lock_type	= req->cmd_u.l64.lock_type;
1537 			bcopy((void *)bufp_addr, (void *)&old_value,
1538 			    IEEE1394_OCTLET);
1539 
1540 			switch (lock_type) {
1541 			case CMD1394_LOCK_MASK_SWAP:
1542 				/* Mask-Swap (see P1394A - Table 1.7) */
1543 				new_value = (data_value & arg_value) |
1544 				    (old_value & ~arg_value);
1545 				/* Copy new_value into backing store */
1546 				bcopy((void *)&new_value, (void *)bufp_addr,
1547 				    IEEE1394_OCTLET);
1548 				req->cmd_u.l64.old_value = old_value;
1549 				break;
1550 
1551 			case CMD1394_LOCK_COMPARE_SWAP:
1552 				/* Compare-Swap */
1553 				if (old_value == arg_value) {
1554 					new_value = data_value;
1555 					/* Copy new_value into backing store */
1556 					bcopy((void *)&new_value,
1557 					    (void *)bufp_addr,
1558 					    IEEE1394_OCTLET);
1559 				}
1560 				req->cmd_u.l64.old_value = old_value;
1561 				break;
1562 
1563 			case CMD1394_LOCK_FETCH_ADD:
1564 				/* Fetch-Add (see P1394A - Table 1.7) */
1565 				old_value = T1394_DATA64(old_value);
1566 				new_value = old_value + data_value;
1567 				new_value = T1394_DATA64(new_value);
1568 				/* Copy new_value into backing store */
1569 				bcopy((void *)&new_value, (void *)bufp_addr,
1570 				    IEEE1394_OCTLET);
1571 				req->cmd_u.l64.old_value = old_value;
1572 				break;
1573 
1574 			case CMD1394_LOCK_LITTLE_ADD:
1575 				/* Little-Add (see P1394A - Table 1.7) */
1576 				old_value = T1394_DATA64(old_value);
1577 				new_value = old_value + data_value;
1578 				new_value = T1394_DATA64(new_value);
1579 				/* Copy new_value into backing store */
1580 				bcopy((void *)&new_value, (void *)bufp_addr,
1581 				    IEEE1394_OCTLET);
1582 				req->cmd_u.l64.old_value = old_value;
1583 				break;
1584 
1585 			case CMD1394_LOCK_BOUNDED_ADD:
1586 				/* Bounded-Add (see P1394A - Table 1.7) */
1587 				old_value = T1394_DATA64(old_value);
1588 				if (old_value != arg_value) {
1589 					new_value = old_value + data_value;
1590 					new_value = T1394_DATA64(new_value);
1591 					/* Copy new_value into backing store */
1592 					bcopy((void *)&new_value,
1593 					    (void *)bufp_addr,
1594 					    IEEE1394_OCTLET);
1595 				}
1596 				req->cmd_u.l64.old_value = old_value;
1597 				break;
1598 
1599 			case CMD1394_LOCK_WRAP_ADD:
1600 				/* Wrap-Add (see P1394A - Table 1.7) */
1601 				old_value = T1394_DATA64(old_value);
1602 				if (old_value != arg_value) {
1603 					new_value = old_value + data_value;
1604 				} else {
1605 					new_value = data_value;
1606 				}
1607 				new_value = T1394_DATA64(new_value);
1608 				/* Copy new_value into backing store */
1609 				bcopy((void *)&new_value, (void *)bufp_addr,
1610 				    IEEE1394_OCTLET);
1611 				req->cmd_u.l64.old_value = old_value;
1612 				break;
1613 
1614 			default:
1615 				/* Unlock the "used" tree */
1616 				mutex_exit(&hal->addr_space_used_mutex);
1617 				req->cmd_result = IEEE1394_RESP_TYPE_ERROR;
1618 				(void) s1394_send_response(hal, req);
1619 				TNF_PROBE_1(h1394_lock_request_error,
1620 				    S1394_TNF_SL_ARREQ_ERROR, "", tnf_string,
1621 				    msg, "Invalid lock_type");
1622 				TNF_PROBE_0_DEBUG(h1394_lock_request_exit,
1623 				    S1394_TNF_SL_ARREQ_STACK, "");
1624 				return;
1625 			}
1626 		}
1627 	}
1628 
1629 	/* Fill in the rest of the info in the request */
1630 	s_priv->arreq_valid_addr = B_TRUE;
1631 	req->cmd_callback_arg	 = addr_blk->addr_arg;
1632 	recv_lock_req		 = addr_blk->addr_events.recv_lock_request;
1633 
1634 	/* Unlock the "used" tree */
1635 	mutex_exit(&hal->addr_space_used_mutex);
1636 
1637 	/*
1638 	 * Add no code that modifies the command after the target
1639 	 * callback is called or after the response is sent to the
1640 	 * HAL.
1641 	 */
1642 	if (recv_lock_req != NULL) {
1643 		TNF_PROBE_0_DEBUG(h1394_lock_request_do_callback,
1644 		    S1394_TNF_SL_ARREQ_STACK, "");
1645 		recv_lock_req(req);
1646 	} else {
1647 		req->cmd_result = IEEE1394_RESP_COMPLETE;
1648 		(void) s1394_send_response(hal, req);
1649 		TNF_PROBE_0_DEBUG(h1394_lock_request_exit,
1650 		    S1394_TNF_SL_ARREQ_STACK, "");
1651 		return;
1652 	}
1653 
1654 	TNF_PROBE_0_DEBUG(h1394_lock_request_exit,
1655 	    S1394_TNF_SL_ARREQ_STACK, "");
1656 }
1657 
1658 /*
1659  * Function:    h1394_ioctl()
1660  * Input(s):    sl_private		The HAL "handle" returned by
1661  *					    h1394_attach()
1662  *		cmd			ioctl cmd
1663  *		arg			argument for the ioctl cmd
1664  *		mode			mode bits (see ioctl(9e))
1665  *		cred_p			cred structure pointer
1666  *		rval_p			pointer to return value (see ioctl(9e))
1667  *
1668  * Output(s):	EINVAL if not a DEVCTL ioctl, else return value from s1394_ioctl
1669  *
1670  * Description:	h1394_ioctl() implements non-HAL specific ioctls. Currently,
1671  *		DEVCTL ioctls are the only generic ioctls supported.
1672  */
1673 int
1674 h1394_ioctl(void *sl_private, int cmd, intptr_t arg, int mode, cred_t *cred_p,
1675     int *rval_p)
1676 {
1677 	int	status;
1678 
1679 	TNF_PROBE_0_DEBUG(h1394_ioctl_enter, S1394_TNF_SL_IOCTL_STACK, "");
1680 
1681 	if ((cmd & DEVCTL_IOC) != DEVCTL_IOC)
1682 		return (EINVAL);
1683 
1684 	status = s1394_ioctl((s1394_hal_t *)sl_private, cmd, arg, mode,
1685 	    cred_p, rval_p);
1686 
1687 	TNF_PROBE_1_DEBUG(h1394_ioctl_exit, S1394_TNF_SL_IOCTL_STACK, "",
1688 	    tnf_int, status, status);
1689 	return (status);
1690 }
1691 
1692 /*
1693  * Function:    h1394_phy_packet()
1694  * Input(s):    sl_private		The HAL "handle" returned by
1695  *					    h1394_attach()
1696  *		packet_data		Pointer to a buffer of packet data
1697  *		quadlet_count		Length of the buffer
1698  *		timestamp		Timestamp indicating time of arrival
1699  *
1700  * Output(s):	None
1701  *
1702  * Description:	h1394_phy_packet() is not implemented currently, but would
1703  *		be used to process the responses to PHY ping packets in P1394A
1704  *		When one is sent out, a timestamp is given indicating its time
1705  *		of departure. Comparing that old timestamp with this new
1706  *		timestamp, we can determine the time of flight and can use
1707  *		those times to optimize the gap count.
1708  */
1709 /* ARGSUSED */
1710 void
1711 h1394_phy_packet(void *sl_private, uint32_t *packet_data, uint_t quadlet_count,
1712 	uint_t timestamp)
1713 {
1714 	TNF_PROBE_0_DEBUG(h1394_phy_packet_enter, S1394_TNF_SL_STACK, "");
1715 
1716 	/* This interface is not yet implemented */
1717 	TNF_PROBE_1_DEBUG(h1394_phy_packet, S1394_TNF_SL_STACK, "",
1718 	    tnf_string, msg, "h1394_phy_packet: Received");
1719 
1720 	TNF_PROBE_0_DEBUG(h1394_phy_packet_exit, S1394_TNF_SL_STACK, "");
1721 }
1722 
1723 /*
1724  * Function:    h1394_error_detected()
1725  * Input(s):    sl_private		The HAL "handle" returned by
1726  *					    h1394_attach()
1727  *		type			The type of error the HAL detected
1728  *		arg			Pointer to any extra information
1729  *
1730  * Output(s):	None
1731  *
1732  * Description:	h1394_error_detected() is used by the HAL to report errors
1733  *		to the 1394 Software Framework.
1734  */
1735 void
1736 h1394_error_detected(void *sl_private, h1394_error_t type, void *arg)
1737 {
1738 	s1394_hal_t	*hal;
1739 	uint_t		hal_node_num;
1740 	uint_t		IRM_node_num;
1741 
1742 	TNF_PROBE_0_DEBUG(h1394_error_detected_enter, S1394_TNF_SL_STACK, "");
1743 
1744 	hal = (s1394_hal_t *)sl_private;
1745 
1746 	switch (type) {
1747 	case H1394_LOCK_RESP_ERR:
1748 		TNF_PROBE_1(h1394_error_detected, S1394_TNF_SL_ERROR, "",
1749 		    tnf_string, msg, "Lock response error");
1750 		/* If we are the IRM, then initiate a bus reset */
1751 		mutex_enter(&hal->topology_tree_mutex);
1752 		hal_node_num = IEEE1394_NODE_NUM(hal->node_id);
1753 		IRM_node_num = hal->IRM_node;
1754 		mutex_exit(&hal->topology_tree_mutex);
1755 		if (IRM_node_num == hal_node_num)
1756 			s1394_initiate_hal_reset(hal, NON_CRITICAL);
1757 		break;
1758 
1759 	case H1394_POSTED_WR_ERR:
1760 		TNF_PROBE_2(h1394_error_detected, S1394_TNF_SL_ERROR, "",
1761 		    tnf_string, msg, "Posted write error detected",
1762 		    tnf_opaque, addr, ((h1394_posted_wr_err_t *)arg)->addr);
1763 		break;
1764 
1765 	case H1394_SELF_INITIATED_SHUTDOWN:
1766 		TNF_PROBE_1(h1394_error_detected, S1394_TNF_SL_ERROR, "",
1767 		    tnf_string, msg, "HAL self-initiated shutdown");
1768 		s1394_hal_shutdown(hal, B_FALSE);
1769 		break;
1770 
1771 	case H1394_CYCLE_TOO_LONG:
1772 		/* Set a timer to become cycle master after 1 second */
1773 		mutex_enter(&hal->cm_timer_mutex);
1774 		hal->cm_timer_set = B_TRUE;
1775 		mutex_exit(&hal->cm_timer_mutex);
1776 		hal->cm_timer = timeout(s1394_cycle_too_long_callback, hal,
1777 		    drv_usectohz(CYCLE_MASTER_TIMER * 1000));
1778 
1779 		TNF_PROBE_1(h1394_error_detected, S1394_TNF_SL_ERROR, "",
1780 		    tnf_string, msg, "Isochronous cycle too long error");
1781 		break;
1782 
1783 	default:
1784 		TNF_PROBE_2(h1394_error_detected, S1394_TNF_SL_ERROR, "",
1785 		    tnf_string, msg, "Unknown error type received",
1786 		    tnf_uint, type, type);
1787 		break;
1788 	}
1789 
1790 	TNF_PROBE_0_DEBUG(h1394_error_detected_exit, S1394_TNF_SL_STACK, "");
1791 }
1792