| blob | 1962b6a6ff7c76aee6a82b06ef5e805d3a81db26 |
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 (the "License").
6 * You may not use this file except in compliance with the License.
7 *
8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 * or http://www.opensolaris.org/os/licensing.
10 * See the License for the specific language governing permissions
11 * and limitations under the License.
12 *
13 * When distributing Covered Code, include this CDDL HEADER in each
14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 * If applicable, add the following below this CDDL HEADER, with the
16 * fields enclosed by brackets "[]" replaced with your own identifying
17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 *
19 * CDDL HEADER END
20 */
21 /*
22 * Copyright (c) 2007, 2010, Oracle and/or its affiliates. All rights reserved.
23 */
25 #include <sys/mutex.h>
26 #include <sys/debug.h>
27 #include <sys/types.h>
28 #include <sys/param.h>
29 #include <sys/kmem.h>
30 #include <sys/thread.h>
31 #include <sys/id_space.h>
32 #include <sys/avl.h>
33 #include <sys/list.h>
34 #include <sys/sysmacros.h>
35 #include <sys/proc.h>
36 #include <sys/contract.h>
37 #include <sys/contract_impl.h>
38 #include <sys/contract/device.h>
39 #include <sys/contract/device_impl.h>
40 #include <sys/cmn_err.h>
41 #include <sys/nvpair.h>
42 #include <sys/policy.h>
43 #include <sys/ddi_impldefs.h>
44 #include <sys/ddi_implfuncs.h>
45 #include <sys/systm.h>
46 #include <sys/stat.h>
47 #include <sys/sunddi.h>
48 #include <sys/esunddi.h>
49 #include <sys/ddi.h>
50 #include <sys/fs/dv_node.h>
51 #include <sys/sunndi.h>
54 /*
55 * Device Contracts
56 * -----------------
57 * This file contains the core code for the device contracts framework.
58 * A device contract is an agreement or a contract between a process and
59 * the kernel regarding the state of the device. A device contract may be
60 * created when a relationship is formed between a device and a process
61 * i.e. at open(2) time, or it may be created at some point after the device
62 * has been opened. A device contract once formed may be broken by either party.
63 * A device contract can be broken by the process by an explicit abandon of the
64 * contract or by an implicit abandon when the process exits. A device contract
65 * can be broken by the kernel either asynchronously (without negotiation) or
66 * synchronously (with negotiation). Exactly which happens depends on the device
67 * state transition. The following state diagram shows the transitions between
68 * device states. Only device state transitions currently supported by device
69 * contracts is shown.
70 *
71 * <-- A -->
72 * /-----------------> DEGRADED
73 * | |
74 * | |
75 * | | S
76 * | | |
77 * | | v
78 * v S --> v
79 * ONLINE ------------> OFFLINE
80 *
81 *
82 * In the figure above, the arrows indicate the direction of transition. The
83 * letter S refers to transitions which are inherently synchronous i.e.
84 * require negotiation and the letter A indicates transitions which are
85 * asynchronous i.e. are done without contract negotiations. A good example
86 * of a synchronous transition is the ONLINE -> OFFLINE transition. This
87 * transition cannot happen as long as there are consumers which have the
88 * device open. Thus some form of negotiation needs to happen between the
89 * consumers and the kernel to ensure that consumers either close devices
90 * or disallow the move to OFFLINE. Certain other transitions such as
91 * ONLINE --> DEGRADED for example, are inherently asynchronous i.e.
92 * non-negotiable. A device that suffers a fault that degrades its
93 * capabilities will become degraded irrespective of what consumers it has,
94 * so a negotiation in this case is pointless.
95 *
96 * The following device states are currently defined for device contracts:
97 *
98 * CT_DEV_EV_ONLINE
99 * The device is online and functioning normally
100 * CT_DEV_EV_DEGRADED
101 * The device is online but is functioning in a degraded capacity
102 * CT_DEV_EV_OFFLINE
103 * The device is offline and is no longer configured
104 *
105 * A typical consumer of device contracts starts out with a contract
106 * template and adds terms to that template. These include the
107 * "acceptable set" (A-set) term, which is a bitset of device states which
108 * are guaranteed by the contract. If the device moves out of a state in
109 * the A-set, the contract is broken. The breaking of the contract can
110 * be asynchronous in which case a critical contract event is sent to the
111 * contract holder but no negotiations take place. If the breaking of the
112 * contract is synchronous, negotations are opened between the affected
113 * consumer and the kernel. The kernel does this by sending a critical
114 * event to the consumer with the CTE_NEG flag set indicating that this
115 * is a negotiation event. The consumer can accept this change by sending
116 * a ACK message to the kernel. Alternatively, if it has the necessary
117 * privileges, it can send a NACK message to the kernel which will block
118 * the device state change. To NACK a negotiable event, a process must
119 * have the {PRIV_SYS_DEVICES} privilege asserted in its effective set.
120 *
121 * Other terms include the "minor path" term, specified explicitly if the
122 * contract is not being created at open(2) time or specified implicitly
123 * if the contract is being created at open time via an activated template.
124 *
125 * A contract event is sent on any state change to which the contract
126 * owner has subscribed via the informative or critical event sets. Only
127 * critical events are guaranteed to be delivered. Since all device state
128 * changes are controlled by the kernel and cannot be arbitrarily generated
129 * by a non-privileged user, the {PRIV_CONTRACT_EVENT} privilege does not
130 * need to be asserted in a process's effective set to designate an event as
131 * critical. To ensure privacy, a process must either have the same effective
132 * userid as the contract holder or have the {PRIV_CONTRACT_OBSERVER} privilege
133 * asserted in its effective set in order to observe device contract events
134 * off the device contract type specific endpoint.
135 *
136 * Yet another term available with device contracts is the "non-negotiable"
137 * term. This term is used to pre-specify a NACK to any contract negotiation.
138 * This term is ignored for asynchronous state changes. For example, a
139 * provcess may have the A-set {ONLINE|DEGRADED} and make the contract
140 * non-negotiable. In this case, the device contract framework assumes a
141 * NACK for any transition to OFFLINE and blocks the offline. If the A-set
142 * is {ONLINE} and the non-negotiable term is set, transitions to OFFLINE
143 * are NACKed but transitions to DEGRADE succeed.
144 *
145 * The OFFLINE negotiation (if OFFLINE state is not in the A-set for a contract)
146 * happens just before the I/O framework attempts to offline a device
147 * (i.e. detach a device and set the offline flag so that it cannot be
148 * reattached). A device contract holder is expected to either NACK the offline
149 * (if privileged) or release the device and allow the offline to proceed.
150 *
151 * The DEGRADE contract event (if DEGRADE is not in the A-set for a contract)
152 * is generated just before the I/O framework transitions the device state
153 * to "degraded" (i.e. DEVI_DEVICE_DEGRADED in I/O framework terminology).
154 *
155 * The contract holder is expected to ACK or NACK a negotiation event
156 * within a certain period of time. If the ACK/NACK is not received
157 * within the timeout period, the device contract framework will behave
158 * as if the contract does not exist and will proceed with the event.
159 *
160 * Unlike a process contract a device contract does not need to exist
161 * once it is abandoned, since it does not define a fault boundary. It
162 * merely represents an agreement between a process and the kernel
163 * regarding the state of the device. Once the process has abandoned
164 * the contract (either implicitly via a process exit or explicitly)
165 * the kernel has no reason to retain the contract. As a result
166 * device contracts are neither inheritable nor need to exist in an
167 * orphan state.
168 *
169 * A device unlike a process may exist in multiple contracts and has
170 * a "life" outside a device contract. A device unlike a process
171 * may exist without an associated contract. Unlike a process contract
172 * a device contract may be formed after a binding relationship is
173 * formed between a process and a device.
174 *
175 * IMPLEMENTATION NOTES
176 * ====================
177 * DATA STRUCTURES
178 * ----------------
179 * The heart of the device contracts implementation is the device contract
180 * private cont_device_t (or ctd for short) data structure. It encapsulates
181 * the generic contract_t data structure and has a number of private
182 * fields.
183 * These include:
184 * cond_minor: The minor device that is the subject of the contract
185 * cond_aset: The bitset of states which are guaranteed by the
186 * contract
187 * cond_noneg: If set, indicates that the result of negotiation has
188 * been predefined to be a NACK
189 * In addition, there are other device identifiers such the devinfo node,
190 * dev_t and spec_type of the minor node. There are also a few fields that
191 * are used during negotiation to maintain state. See
192 * include/sys/contract/device_impl.h
193 * for details.
194 * The ctd structure represents the device private part of a contract of
195 * type "device"
196 *
197 * Another data structure used by device contracts is ctmpl_device. It is
198 * the device contracts private part of the contract template structure. It
199 * encapsulates the generic template structure "ct_template_t" and includes
200 * the following device contract specific fields
201 * ctd_aset: The bitset of states that should be guaranteed by a
202 * contract
203 * ctd_noneg: If set, indicates that contract should NACK a
204 * negotiation
205 * ctd_minor: The devfs_path (without the /devices prefix) of the
206 * minor node that is the subject of the contract.
207 *
208 * ALGORITHMS
209 * ---------
210 * There are three sets of routines in this file
211 * Template related routines
212 * -------------------------
213 * These routines provide support for template related operations initated
214 * via the generic template operations. These include routines that dup
215 * a template, free it, and set various terms in the template
216 * (such as the minor node path, the acceptable state set (or A-set)
217 * and the non-negotiable term) as well as a routine to query the
218 * device specific portion of the template for the abovementioned terms.
219 * There is also a routine to create (ctmpl_device_create) that is used to
220 * create a contract from a template. This routine calls (after initial
221 * setup) the common function used to create a device contract
222 * (contract_device_create).
223 *
224 * core device contract implementation
225 * ----------------------------------
226 * These routines support the generic contract framework to provide
227 * functionality that allows contracts to be created, managed and
228 * destroyed. The contract_device_create() routine is a routine used
229 * to create a contract from a template (either via an explicit create
230 * operation on a template or implicitly via an open with an
231 * activated template.). The contract_device_free() routine assists
232 * in freeing the device contract specific parts. There are routines
233 * used to abandon (contract_device_abandon) a device contract as well
234 * as a routine to destroy (which despite its name does not destroy,
235 * it only moves a contract to a dead state) a contract.
236 * There is also a routine to return status information about a
237 * contract - the level of detail depends on what is requested by the
238 * user. A value of CTD_FIXED only returns fixed length fields such
239 * as the A-set, state of device and value of the "noneg" term. If
240 * CTD_ALL is specified, the minor node path is returned as well.
241 *
242 * In addition there are interfaces (contract_device_ack/nack) which
243 * are used to support negotiation between userland processes and
244 * device contracts. These interfaces record the acknowledgement
245 * or lack thereof for negotiation events and help determine if the
246 * negotiated event should occur.
247 *
248 * "backend routines"
249 * -----------------
250 * The backend routines form the interface between the I/O framework
251 * and the device contract subsystem. These routines, allow the I/O
252 * framework to call into the device contract subsystem to notify it of
253 * impending changes to a device state as well as to inform of the
254 * final disposition of such attempted state changes. Routines in this
255 * class include contract_device_offline() that indicates an attempt to
256 * offline a device, contract_device_degrade() that indicates that
257 * a device is moving to the degraded state and contract_device_negend()
258 * that is used by the I/O framework to inform the contracts subsystem of
259 * the final disposition of an attempted operation.
260 *
261 * SUMMARY
262 * -------
263 * A contract starts its life as a template. A process allocates a device
264 * contract template and sets various terms:
265 * The A-set
266 * The device minor node
267 * Critical and informative events
268 * The noneg i.e. no negotition term
269 * Setting of these terms in the template is done via the
270 * ctmpl_device_set() entry point in this file. A process can query a
271 * template to determine the terms already set in the template - this is
272 * facilitated by the ctmpl_device_get() routine.
273 *
274 * Once all the appropriate terms are set, the contract is instantiated via
275 * one of two methods
276 * - via an explicit create operation - this is facilitated by the
277 * ctmpl_device_create() entry point
278 * - synchronously with the open(2) system call - this is achieved via the
279 * contract_device_open() routine.
280 * The core work for both these above functions is done by
281 * contract_device_create()
282 *
283 * A contract once created can be queried for its status. Support for
284 * status info is provided by both the common contracts framework and by
285 * the "device" contract type. If the level of detail requested is
286 * CTD_COMMON, only the common contract framework data is used. Higher
287 * levels of detail result in calls to contract_device_status() to supply
288 * device contract type specific status information.
289 *
290 * A contract once created may be abandoned either explicitly or implictly.
291 * In either case, the contract_device_abandon() function is invoked. This
292 * function merely calls contract_destroy() which moves the contract to
293 * the DEAD state. The device contract portion of destroy processing is
294 * provided by contract_device_destroy() which merely disassociates the
295 * contract from its device devinfo node. A contract in the DEAD state is
296 * not freed. It hanbgs around until all references to the contract are
297 * gone. When that happens, the contract is finally deallocated. The
298 * device contract specific portion of the free is done by
299 * contract_device_free() which finally frees the device contract specific
300 * data structure (cont_device_t).
301 *
302 * When a device undergoes a state change, the I/O framework calls the
303 * corresponding device contract entry point. For example, when a device
304 * is about to go OFFLINE, the routine contract_device_offline() is
305 * invoked. Similarly if a device moves to DEGRADED state, the routine
306 * contract_device_degrade() function is called. These functions call the
307 * core routine contract_device_publish(). This function determines via
308 * the function is_sync_neg() whether an event is a synchronous (i.e.
309 * negotiable) event or not. In the former case contract_device_publish()
310 * publishes a CTE_NEG event and then waits in wait_for_acks() for ACKs
311 * and/or NACKs from contract holders. In the latter case, it simply
312 * publishes the event and does not wait. In the negotiation case, ACKs or
313 * NACKs from userland consumers results in contract_device_ack_nack()
314 * being called where the result of the negotiation is recorded in the
315 * contract data structure. Once all outstanding contract owners have
316 * responded, the device contract code in wait_for_acks() determines the
317 * final result of the negotiation. A single NACK overrides all other ACKs
318 * If there is no NACK, then a single ACK will result in an overall ACK
319 * result. If there are no ACKs or NACKs, then the result CT_NONE is
320 * returned back to the I/O framework. Once the event is permitted or
321 * blocked, the I/O framework proceeds or aborts the state change. The
322 * I/O framework then calls contract_device_negend() with a result code
323 * indicating final disposition of the event. This call releases the
324 * barrier and other state associated with the previous negotiation,
325 * which permits the next event (if any) to come into the device contract
326 * framework.
327 *
328 * Finally, a device that has outstanding contracts may be removed from
329 * the system which results in its devinfo node being freed. The devinfo
330 * free routine in the I/O framework, calls into the device contract
331 * function - contract_device_remove_dip(). This routine, disassociates
332 * the dip from all contracts associated with the contract being freed,
333 * allowing the devinfo node to be freed.
334 *
335 * LOCKING
336 * ---------
337 * There are four sets of data that need to be protected by locks
338 *
339 * i) device contract specific portion of the contract template - This data
340 * is protected by the template lock ctmpl_lock.
341 *
342 * ii) device contract specific portion of the contract - This data is
343 * protected by the contract lock ct_lock
344 *
345 * iii) The linked list of contracts hanging off a devinfo node - This
346 * list is protected by the per-devinfo node lock devi_ct_lock
347 *
348 * iv) Finally there is a barrier, controlled by devi_ct_lock, devi_ct_cv
349 * and devi_ct_count that controls state changes to a dip
350 *
351 * The template lock is independent in that none of the other locks in this
352 * file may be taken while holding the template lock (and vice versa).
353 *
354 * The remaining three locks have the following lock order
355 *
356 * devi_ct_lock -> ct_count barrier -> ct_lock
357 *
358 */
363 /* barrier routines */
375 /*
376 * Macro predicates for determining when events should be sent and how.
377 */
378 #define EVSENDP(ctd, flag) \
379 ((ctd->cond_contract.ct_ev_info | ctd->cond_contract.ct_ev_crit) & flag)
381 #define EVINFOP(ctd, flag) \
382 ((ctd->cond_contract.ct_ev_crit & flag) == 0)
384 /*
385 * State transition table showing which transitions are synchronous and which
386 * are not.
387 */
389 uint_t st_old;
390 uint_t st_new;
391 uint_t st_neg;
398 };
400 /*
401 * Device contract template implementation
402 */
404 /*
405 * ctmpl_device_dup
406 *
407 * The device contract template dup entry point.
408 * This simply copies all the fields (generic as well as device contract
409 * specific) fields of the original.
410 */
413 {
422 /*
423 * copy generic fields.
424 * ctmpl_copy returns with old template lock held
425 */
439 }
448 }
453 }
457 }
459 /*
460 * ctmpl_device_free
461 *
462 * The device contract template free entry point. Just
463 * frees the template.
464 */
465 static void
467 {
474 }
476 /*
477 * SAFE_EV is the set of events which a non-privileged process is
478 * allowed to make critical. An unprivileged device contract owner has
479 * no control over when a device changes state, so all device events
480 * can be in the critical set.
481 *
482 * EXCESS tells us if "value", a critical event set, requires
483 * additional privilege. For device contracts EXCESS currently
484 * evaluates to 0.
485 */
486 #define SAFE_EV (CT_DEV_ALLEVENT)
487 #define EXCESS(value) ((value) & ~SAFE_EV)
490 /*
491 * ctmpl_device_set
492 *
493 * The device contract template set entry point. Sets various terms in the
494 * template. The non-negotiable term can only be set if the process has
495 * the {PRIV_SYS_DEVICES} privilege asserted in its effective set.
496 */
497 static int
500 {
518 }
536 /*
537 * only privileged processes can designate a contract
538 * non-negotiatble.
539 */
543 }
555 }
561 }
566 }
571 }
575 /*
576 * Currently for device contracts, any event
577 * may be added to the critical set. We retain the
578 * following code however for future enhancements.
579 */
587 }
590 }
592 /*
593 * ctmpl_device_get
594 *
595 * The device contract template get entry point. Simply fetches and
596 * returns the value of the requested term.
597 */
598 static int
600 {
612 }
628 }
632 }
635 }
637 /*
638 * Device contract type specific portion of creating a contract using
639 * a specified template
640 */
641 /*ARGSUSED*/
642 int
644 {
647 dev_t dev;
661 /* incomplete template */
668 }
680 }
692 }
699 }
701 /*
702 * Device contract specific template entry points
703 */
710 CT_DEV_ALLEVENT /* all device events bitmask */
711 };
714 /*
715 * Device contract implementation
716 */
718 /*
719 * contract_device_default
720 *
721 * The device contract default template entry point. Creates a
722 * device contract template with a default A-set and no "noneg" ,
723 * with informative degrade events and critical offline events.
724 * There is no default minor path.
725 */
728 {
740 }
742 /*
743 * contract_device_free
744 *
745 * Destroys the device contract specific portion of a contract and
746 * frees the contract.
747 */
748 static void
750 {
774 }
776 /*
777 * contract_device_abandon
778 *
779 * The device contract abandon entry point.
780 */
781 static void
783 {
786 /*
787 * device contracts cannot be inherited or orphaned.
788 * Move the contract to the DEAD_STATE. It will be freed
789 * once all references to it are gone.
790 */
792 }
794 /*
795 * contract_device_destroy
796 *
797 * The device contract destroy entry point.
798 * Called from contract_destroy() to do any type specific destroy. Note
799 * that destroy is a misnomer - this does not free the contract, it only
800 * moves it to the dead state. A contract is actually freed via
801 * contract_rele() -> contract_dtor(), contop_free()
802 */
803 static void
805 {
815 /*
816 * The dip has been removed, this is a dangling contract
817 * Check that dip linkages are NULL
818 */
824 }
826 /*
827 * The intended lock order is : devi_ct_lock -> ct_count
828 * barrier -> ct_lock.
829 * However we can't do this here as dropping the ct_lock allows
830 * a race condition with i_ddi_free_node()/
831 * contract_device_remove_dip() which may free off dip before
832 * we can take devi_ct_lock. So use mutex_tryenter to avoid
833 * dropping ct_lock until we have acquired devi_ct_lock.
834 */
840 }
843 /*
844 * Waiting for the barrier to be released is strictly speaking not
845 * necessary. But it simplifies the implementation of
846 * contract_device_publish() by establishing the invariant that
847 * device contracts cannot go away during negotiation.
848 */
859 }
861 /*
862 * contract_device_status
863 *
864 * The device contract status entry point. Called when level of "detail"
865 * is either CTD_FIXED or CTD_ALL
866 *
867 */
868 static void
871 {
879 /*
880 * There's no need to hold the contract lock while accessing static
881 * data like aset or noneg. But since we need the lock to access other
882 * data like state, we hold it anyway.
883 */
891 }
897 }
899 /*
900 * Converts a result integer into the corresponding string. Used for printing
901 * messages
902 */
905 {
915 }
916 }
918 /*
919 * Converts a device state integer constant into the corresponding string.
920 * Used to print messages.
921 */
924 {
934 }
935 }
937 /*
938 * Routine that determines if a particular CT_DEV_EV_? event corresponds to a
939 * synchronous state change or not.
940 */
941 static int
943 {
953 }
959 }
960 }
966 }
968 /*
969 * Used to cleanup cached dv_nodes so that when a device is released by
970 * a contract holder, its devinfo node can be successfully detached.
971 */
972 static int
974 {
980 /* pdip can be NULL if we have contracts against the root dip */
992 }
1001 }
1004 }
1006 /*
1007 * Endpoint of a ct_ctl_ack() or ct_ctl_nack() call from userland.
1008 * Results in the ACK or NACK being recorded on the dip for one particular
1009 * contract. The device contracts framework evaluates the ACK/NACKs for all
1010 * contracts against a device to determine if a particular device state change
1011 * should be allowed.
1012 */
1013 static int
1015 uint_t cmd)
1016 {
1019 ctid_t ctid;
1034 /*
1035 * Negotiation only if new state is not in A-set
1036 */
1039 /*
1040 * Negotiation only if transition is synchronous
1041 */
1044 /*
1045 * We shouldn't be negotiating if the "noneg" flag is set
1046 */
1054 /*
1055 * dv_clean only if !NACK and offline state change
1056 */
1062 ctid));
1064 }
1065 }
1079 ctid));
1084 }
1089 }
1091 /*
1092 * Must follow lock order: devi_ct_lock -> ct_count barrier - >ct_lock
1093 */
1114 }
1131 }
1133 /*
1134 * Invoked when a userland contract holder approves (i.e. ACKs) a state change
1135 */
1136 static int
1138 {
1140 }
1142 /*
1143 * Invoked when a userland contract holder blocks (i.e. NACKs) a state change
1144 */
1145 static int
1147 {
1149 }
1151 /*
1152 * Creates a new contract synchronously with the breaking of an existing
1153 * contract. Currently not supported.
1154 */
1155 /*ARGSUSED*/
1156 static int
1158 {
1160 }
1162 /*
1163 * Core device contract implementation entry points
1164 */
1173 contract_device_newct /* contop_newct */
1174 };
1176 /*
1177 * contract_device_init
1178 *
1179 * Initializes the device contract type.
1180 */
1181 void
1183 {
1186 }
1188 /*
1189 * contract_device_create
1190 *
1191 * create a device contract given template "tmpl" and the "owner" process.
1192 * May fail and return NULL if project.max-contracts would have been exceeded.
1193 *
1194 * Common device contract creation routine called for both open-time and
1195 * non-open time device contract creation
1196 */
1200 {
1227 }
1229 /*
1230 * Lock out any parallel contract negotiations
1231 */
1243 /*
1244 * Only we hold a refernce to this contract. Safe to access
1245 * the fields without a ct_lock
1246 */
1248 /*
1249 * It is safe to set the dip pointer in the contract
1250 * as the contract will always be destroyed before the dip
1251 * is released
1252 */
1257 /*
1258 * Since we are able to lookup the device, it is either
1259 * online or degraded
1260 */
1268 /*
1269 * contract_ctor() initailizes the common portion of a contract
1270 * contract_dtor() destroys the common portion of a contract
1271 */
1275 /*
1276 * contract_device_free() destroys the type specific
1277 * portion of a contract and frees the contract.
1278 * The "minor" path and "cred" is a part of the type specific
1279 * portion of the contract and will be freed by
1280 * contract_device_free()
1281 */
1284 /* release barrier */
1292 }
1302 /*
1303 * Insert device contract into list hanging off the dip
1304 * Bump up the ref-count on the contract to reflect this
1305 */
1310 /* release barrier */
1317 }
1319 /*
1320 * Called when a device is successfully opened to create an open-time contract
1321 * i.e. synchronously with a device open.
1322 */
1323 int
1325 {
1336 /*
1337 * Check if we are in user-context i.e. if we have an lwp
1338 */
1343 }
1348 }
1351 /*
1352 * If the user set a minor path in the template before an open,
1353 * ignore it. We use the minor path of the actual minor opened.
1354 */
1360 /*
1361 * This is a copy of the actual activated template.
1362 * Safe to make changes such as freeing the minor
1363 * path in the template.
1364 */
1367 }
1379 }
1397 "create device contract for process (%d) holding "
1401 }
1407 }
1409 }
1411 /*
1412 * Called during contract negotiation by the device contract framework to wait
1413 * for ACKs or NACKs from contract holders. If all responses are not received
1414 * before a specified timeout, this routine times out.
1415 */
1416 static uint_t
1418 {
1435 /*
1436 * some contract owner(s) didn't respond in time
1437 */
1440 }
1453 }
1457 }
1459 /* skip if non-negotiable contract */
1463 }
1475 }
1477 }
1489 }
1493 }
1495 /*
1496 * Determines the current state of a device (i.e a devinfo node
1497 */
1498 static int
1500 {
1505 else
1507 }
1509 /*
1510 * Sets the current state of a device in a device contract
1511 */
1512 static void
1514 {
1518 /* verify that barrier is held */
1527 }
1528 }
1530 /*
1531 * Core routine called by event-specific routines when an event occurs.
1532 * Determines if an event should be be published, and if it is to be
1533 * published, whether a negotiation should take place. Also implements
1534 * NEGEND events which publish the final disposition of an event after
1535 * negotiations are complete.
1536 *
1537 * When an event occurs on a minor node, this routine walks the list of
1538 * contracts hanging off a devinfo node and for each contract on the affected
1539 * dip, evaluates the following cases
1540 *
1541 * a. an event that is synchronous, breaks the contract and NONEG not set
1542 * - bumps up the outstanding negotiation counts on the dip
1543 * - marks the dip as undergoing negotiation (devi_ct_neg)
1544 * - event of type CTE_NEG is published
1545 * b. an event that is synchronous, breaks the contract and NONEG is set
1546 * - sets the final result to CT_NACK, event is blocked
1547 * - does not publish an event
1548 * c. event is asynchronous and breaks the contract
1549 * - publishes a critical event irrespect of whether the NONEG
1550 * flag is set, since the contract will be broken and contract
1551 * owner needs to be informed.
1552 * d. No contract breakage but the owner has subscribed to the event
1553 * - publishes the event irrespective of the NONEG event as the
1554 * owner has explicitly subscribed to the event.
1555 * e. NEGEND event
1556 * - publishes a critical event. Should only be doing this if
1557 * if NONEG is not set.
1558 * f. all other events
1559 * - Since a contract is not broken and this event has not been
1560 * subscribed to, this event does not need to be published for
1561 * for this contract.
1562 *
1563 * Once an event is published, what happens next depends on the type of
1564 * event:
1565 *
1566 * a. NEGEND event
1567 * - cleanup all state associated with the preceding negotiation
1568 * and return CT_ACK to the caller of contract_device_publish()
1569 * b. NACKed event
1570 * - One or more contracts had the NONEG term, so the event was
1571 * blocked. Return CT_NACK to the caller.
1572 * c. Negotiated event
1573 * - Call wait_for_acks() to wait for responses from contract
1574 * holders. The end result is either CT_ACK (event is permitted),
1575 * CT_NACK (event is blocked) or CT_NONE (no contract owner)
1576 * responded. This result is returned back to the caller.
1577 * d. All other events
1578 * - If the event was asynchronous (i.e. not negotiated) or
1579 * a contract was not broken return CT_ACK to the caller.
1580 */
1581 static uint_t
1584 {
1604 /* Is this a synchronous state change ? */
1607 /* NOP if unsupported transition */
1612 }
1619 }
1626 /*
1627 * Negotiation end - set the state of the device in the contract
1628 */
1632 }
1634 /*
1635 * If this device didn't go through negotiation, don't publish
1636 * a NEGEND event - simply release the barrier to allow other
1637 * device events in.
1638 */
1647 /*
1648 * There are negotiated contract breakages that
1649 * need a NEGEND event
1650 */
1655 /*
1656 * This is a new event, not a NEGEND event. Wait for previous
1657 * contract events to complete.
1658 */
1660 }
1667 ctid_t ctid;
1680 }
1684 }
1686 /* We have a matching contract */
1690 ctid));
1692 /*
1693 * There are 4 possible cases
1694 * 1. A contract is broken (dev not in acceptable state) and
1695 * the state change is synchronous - start negotiation
1696 * by sending a CTE_NEG critical event.
1697 * 2. A contract is broken and the state change is
1698 * asynchronous - just send a critical event and
1699 * break the contract.
1700 * 3. Contract is not broken, but consumer has subscribed
1701 * to the event as a critical or informative event
1702 * - just send the appropriate event
1703 * 4. contract waiting for negend event - just send the critical
1704 * NEGEND event.
1705 */
1710 ctid));
1711 }
1713 /*
1714 * Don't send event if
1715 * - contract is not broken AND
1716 * - contract holder has not subscribed to this event AND
1717 * - contract not waiting for a NEGEND event
1718 */
1726 }
1728 /*
1729 * Note: need to kmem_zalloc() the event so mutexes are
1730 * initialized automatically
1731 */
1745 /* Nothing to publish. Event has been blocked */
1748 ctid));
1753 }
1761 ctid));
1770 ctid));
1802 }
1822 }
1823 }
1831 }
1833 /*
1834 * by holding the dip's devi_ct_lock we ensure that
1835 * all ACK/NACKs are held up until we have finished
1836 * publishing to all contracts.
1837 */
1853 }
1855 }
1857 /*
1858 * If "negend" set counter back to initial state (-1) so that
1859 * other events can be published. Also clear the negotiation flag
1860 * on dip.
1861 *
1862 * 0 .. n are used for counting.
1863 * -1 indicates counter is available for use.
1864 */
1866 /*
1867 * devi_ct_count not necessarily 0. We may have
1868 * timed out in which case, count will be non-zero.
1869 */
1880 /*
1881 * for non-negotiated events or subscribed events or no
1882 * matching contracts
1883 */
1889 /*
1890 * only this function when called from contract_device_negend()
1891 * can reset the counter to READY state i.e. -1. This function
1892 * is so called for every event whether a NEGEND event is needed
1893 * or not, but the negend event is only published if the event
1894 * whose end they signal is a negotiated event for the contract.
1895 */
1896 }
1899 /* No matching contracts */
1903 /* a non-negotiable contract exists and this is a neg. event */
1907 /* one or more contracts going through negotations */
1911 /* no negotiated contracts or no broken contracts or NEGEND */
1914 }
1916 /*
1917 * Release the lock only now so that the only point where we
1918 * drop the lock is in wait_for_acks(). This is so that we don't
1919 * miss cv_signal/cv_broadcast from contract holders
1920 */
1924 out:
1932 }
1935 /*
1936 * contract_device_offline
1937 *
1938 * Event publishing routine called by I/O framework when a device is offlined.
1939 */
1940 ct_ack_t
1942 {
1944 uint_t result;
1945 uint_t evtype;
1952 /*
1953 * If a contract offline is NACKED, the framework expects us to call
1954 * NEGEND ourselves, since we know the final result
1955 */
1958 }
1961 }
1963 /*
1964 * contract_device_degrade
1965 *
1966 * Event publishing routine called by I/O framework when a device
1967 * moves to degrade state.
1968 */
1969 /*ARGSUSED*/
1970 void
1972 {
1974 uint_t evtype;
1980 }
1982 /*
1983 * contract_device_undegrade
1984 *
1985 * Event publishing routine called by I/O framework when a device
1986 * moves from degraded state to online state.
1987 */
1988 /*ARGSUSED*/
1989 void
1991 {
1993 uint_t evtype;
1999 }
2001 /*
2002 * For all contracts which have undergone a negotiation (because the device
2003 * moved out of the acceptable state for that contract and the state
2004 * change is synchronous i.e. requires negotiation) this routine publishes
2005 * a CT_EV_NEGEND event with the final disposition of the event.
2006 *
2007 * This event is always a critical event.
2008 */
2009 void
2011 {
2013 uint_t evtype;
2029 }
2031 /*
2032 * Wrapper routine called by other subsystems (such as LDI) to start
2033 * negotiations when a synchronous device state change occurs.
2034 * Returns CT_ACK or CT_NACK.
2035 */
2036 ct_ack_t
2038 uint_t evtype)
2039 {
2054 "not supported: event (%d) for dev_t (%lu) and spec (%d), "
2058 }
2061 }
2063 /*
2064 * A wrapper routine called by other subsystems (such as the LDI) to
2065 * finalize event processing for a state change event. For synchronous
2066 * state changes, this publishes NEGEND events. For asynchronous i.e.
2067 * non-negotiable events this publishes the event.
2068 */
2069 void
2072 {
2096 }
2097 }
2099 /*
2100 * Called by I/O framework when a devinfo node is freed to remove the
2101 * association between a devinfo node and its contracts.
2102 */
2103 void
2105 {
2117 /*
2118 * Unlink the dip associated with this contract
2119 */
2127 }
2130 }
2132 /*
2133 * Barrier related routines
2134 */
2135 static void
2137 {
2144 }
2146 static void
2148 {
2154 }
2156 static int
2158 {
2161 }
2163 static int
2165 {
2169 }
2171 static void
2173 {
2177 }
2179 static void
2181 {
2192 }
2193 }
2195 static void
2197 {
2200 }
2202 static int
2204 {
2214 }
2215 }
2217 }