xref: /titanic_50/usr/src/common/svc/repcache_protocol.h (revision ff3124eff995e6cd8ebd8c6543648e0670920034)
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").
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13  * When distributing Covered Code, include this CDDL HEADER in each
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21 
22 /*
23  * Copyright 2008 Sun Microsystems, Inc.  All rights reserved.
24  * Use is subject to license terms.
25  */
26 
27 #ifndef	_REPCACHE_PROTOCOL_H
28 #define	_REPCACHE_PROTOCOL_H
29 
30 #pragma ident	"%Z%%M%	%I%	%E% SMI"
31 
32 /*
33  * The Repository Cache Protocol
34  * -----------------------------
35  *
36  * 1. Introduction
37  * ---------------
38  * This header file defines the private protocols between libscf(3lib) and
39  * svc.configd(1m).  There are two separate protocols:
40  *
41  * 1.	The 'global' protocol, accessible via an fattach(3C)ed door located
42  *	at REPOSITORY_DOOR_NAME.
43  *
44  * 2.	The 'client' protocol, accessible through a door created using the
45  *	global protocol, which allows access to the repository.
46  *
47  * 1.1 Design restrictions
48  * -----------------------
49  * A basic constraint of the door IPC mechanism is that there is no reliable
50  * delivery.  In particular:
51  *
52  * 1.	If libscf(3lib) recieves an EINTR from door_call(), it doesn't know
53  *      whether or not the server recieved (and is processing) its request.
54  *
55  * 2.	When svc.configd(1M) calls door_return(), the client may have already
56  *	received an EINTR, aborting its door_call().  In this case, the
57  *	returned values are dropped on the floor.
58  *
59  * The practical upshot of all of this is simple:
60  *
61  *	Every individual protocol action must be idempotent.
62  *
63  * That is, a client must be able to retry any single request multiple times,
64  * and get the correct results.
65  *
66  * 1.2. Protocol shorthand
67  * -----------------------
68  * We represent by "REQUEST(arg1, arg2) -> result, res1, [desc]" a request code
69  * of REP_PROTOCOL_REQUEST (or REPOSITORY_DOOR_REQUEST), which takes two
70  * additional arguments, arg1 and arg2, and returns a result code, res1, and
71  * a file descriptor desc.
72  *
73  * If an error occurs, the server will usually only send the result code. (a
74  * short return)
75  *
76  * Inside the protocol destription, <foo> indicates the type foo indicates.
77  *
78  * 2. The Global protocol
79  * ----------------------
80  * Everything starting with "REPOSITORY_DOOR" or "repository_door" belongs
81  * to the global protocol.
82  *
83  * 2.1. Global requests
84  * --------------------
85  *
86  * REQUEST_CONNECT(rdr_flags, ...) -> result, [new_door]
87  *	Request a new Client door.  rdr_flags determines attributes of the
88  *	connection:
89  *
90  *	    FLAG_DEBUG
91  *		Sets connection debugging flags to those in rdr_debug.
92  *
93  *	The new door is returned with DOOR_RELEASE set, so if the client does
94  *	not recieve the response, the new door will recieve an unref
95  *	notification.  This makes this request idempotent.
96  *
97  * 2.2. Global reponse codes
98  * -------------------------
99  * GLXXX: This needs to be thought through.
100  *
101  * SUCCESS
102  * FAIL_BAD_REQUEST
103  * FAIL_VERSION_MISMATCH
104  * FAIL_BAD_FLAG
105  * FAIL_BAD_USER
106  * FAIL_NO_RESOURCES
107  *
108  * 3. The Client protocol
109  * ----------------------
110  * Everything starting with "REP_PROTOCOL" or "rep_protocol" belongs to the
111  * client protocol.
112  *
113  * 3.1. Techniques used
114  * --------------------
115  * 3.1.1. Client-controlled identifiers
116  *
117  * An idiom the protocol uses to lower the number of round trips is
118  * client-controlled identifiers.  The basic idea is this:  whenever a
119  * client wants to set up and use a piece of server state, he picks an
120  * integer *which he knows is not in use* to identify it.  The server then
121  * maintains per-client, per-resource id->resource maps.  This has a number
122  * of advantages:
123  *
124  * 1.	Since the client allocates the identifiers, we don't need to do
125  *	a round-trip just to allocate a number.
126  *
127  * 2.	Since it is the client's job to make sure identifiers don't collide,
128  *	idempotency for setup (destroy) are simple:  If the identifier
129  *	already exists (does not exist), we just return success.
130  *
131  * 3.	Since the identifiers are per-client, the design automatically
132  *	precludes clients being able to manipulate other client's state.
133  *
134  * 3.1.2 Sequence numbers
135  *
136  * A standard way of gaining idempotency is introducing sequence numbers.
137  * These are simply integers which get incremented at points in the protocol,
138  * and make sure the client and server are in sync.
139  *
140  * In this protocol, we use sequence numbers for requests (like ITER_READ)
141  * which are repeated, returning different data each time.  Since requests
142  * can also be repeated due to unreliable dispatch, the client increments
143  * the sequence number after every successful request.  This allows the server
144  * to differentiate the two cases. (note that this means that failing
145  * requests have no side effects and are repeatable)
146  *
147  * 3.2. Client abstractions
148  * ------------------------
149  * 3.2.1 Entities
150  *
151  * An "entity" is a typed register which the client can manipulate.
152  * Entities are named in the protocol by client-controlled identifiers.
153  * They have a fixed type for their entire lifetime, and may be in one
154  * of two states:
155  *
156  * valid
157  *	The entity has a valid value, and may be read from.  This state
158  *	is reached by a successful write to the entity by some protocol
159  *	step.
160  *
161  * invalid
162  *	The entity does not contain a valid value.  There are a number
163  *	of ways to reach this state:
164  *
165  *	1.  The entity was just created.
166  *	2.  The underlying object that this entity refers to was destroyed.
167  *	3.  A protocol request which would have modified this entity
168  *	    failed.
169  *
170  * An entity is an element in the tree of repository data.  Every entity
171  * (except for the most distant SCOPE) has exactly one parent.  Entities
172  * can have multiple children of different types, restricted by its base
173  * type.
174  *
175  * The ENTITY_GET call is used to get the root of the tree (the most local
176  * scope)
177  *
178  * 3.2.2. The entity tree
179  * ----------------------
180  * The structure of a scope is as follows:
181  *
182  *	 _______
183  *	| SCOPE |
184  *	|_______|
185  *	    \ .
186  *	     \ .
187  *	      \_________
188  *	      | SERVICE |
189  *	      |_________|
190  *		/.    \ .
191  *	       /.      \ .
192  *	  ____/		\__________
193  *	 | PG |		| INSTANCE |
194  *	 |____|		|__________|
195  *			  /.	 \ .
196  *			 /.	  \ .
197  *		    ____/	   \__________
198  *		   | PG |	   | SNAPSHOT |
199  *		   |____|	   |__________|
200  *					\ .
201  *					 \ .
202  *					  \___________
203  *					  | SNAPLEVEL |
204  *					  |___________|
205  *					     /.
206  *					    /.
207  *				       ____/
208  *				      | PG |
209  *				      |____|
210  *
211  * Where the dots indicate an arbitrary number (including 0) of children.
212  *
213  * For a given scope, the next scope (in the sense of distance) is its
214  * TYPE_SCOPE parent.  The furthest out scope has no parent.
215  *
216  * 3.2.2 Iterators
217  *
218  * GLXXX
219  *
220  * 3.3. Client requests
221  * --------------------
222  *
223  * CLOSE() -> result
224  *	Closes the connection, revoking the door.  After this call completes,
225  *	no further calls will succeed.
226  *
227  * ENTITY_SETUP(entity_id, type) -> result
228  *	Sets up an entity, identified by entity_id, to identify a single
229  *	<type>.  <type> may not be TYPE_NONE.
230  *
231  * ENTITY_NAME(entity_id, name_type) -> result, name
232  *	Returns the name of entity_id.  name_type determines which type of
233  *	name to get.
234  *
235  * ENTITY_PARENT_TYPE(entity_id) -> result, parent_type
236  *	Retrieves the type of entity_id's parent
237  *
238  * ENTITY_GET_CHILD(entity_id, child_id, name) -> result
239  *	Puts entity_id's child (of child_id's type) named 'name' into child_id.
240  *
241  * ENTITY_GET_PARENT(entity_id, out_id) -> result
242  *	Puts entity_id's parent into out_id.
243  *
244  * ENTITY_GET(entity_id, number) -> result
245  *	Makes entity_id point to a particular object.  If any error
246  *	occurs, dest_id will be invalid.
247  *
248  * ENTITY_UPDATE(entity_id, changeid) -> result
249  *	Updates the entity to pick up any new changes.
250  *
251  * ENTITY_CREATE_CHILD(entity_id, type, name, child_id, changeid) -> result
252  *	Attaches the object of type /type/ in child_id as the child of
253  *	entity_id named 'name'.
254  *
255  * ENTITY_CREATE_PG(entity_id, name, type, flags, child_id, changeid) -> result
256  *	Creates a property group child of entity_id named 'name', type 'type'
257  *	and flags 'flags', and puts the resulting object in child_id.
258  *
259  * ENTITY_DELETE(entity_id, changeid) -> result
260  *	Deletes the entity represented by entity_id.
261  *
262  * ENTITY_RESET(entity_id) -> result
263  *	Resets the entity.
264  *
265  * ENTITY_TEARDOWN(entity_id) -> result
266  *	Destroys the entity entity_id.
267  *
268  * ITER_SETUP(iter_id) -> result
269  *	Sets up an iterator id.
270  *
271  * ITER_START(iter_id, entity_id, itertype, flags, pattern) -> result
272  *	Sets up an iterator, identified by iter_id, which will iterate the
273  *	<itertype> children of entity_id whose names match 'pattern',
274  *	with the matching controlled by flags.  Initializing an iterator
275  *	counts as the first sequence number (1).
276  *
277  * ITER_READ(iter_id, sequence, entity_id) -> result
278  *	Retrieves the next element of iterator iter_id.  Sequence starts at 2,
279  *	and is incremented by the client after each successful iteration.
280  *	The result is written to entity_id, which must be of the same type
281  *	as the iterator result.  The iterator must not be iterating values.
282  *
283  * ITER_READ_VALUE(iter_id, sequence) -> result, type, value
284  *	Retrieves the next value for iterator iter_id.  Sequence starts at 2,
285  *	and is incremented by the client after each successful iteration.
286  *	The iterator must be iterating a property's values.
287  *
288  * ITER_RESET(iter_id) -> result
289  *	Throws away any accumulated state.
290  *
291  * ITER_TEARDOWN(iter_id) -> result
292  *	Destroys the iterator iter_id.
293  *
294  * NEXT_SNAPLEVEL(entity_src, entity_dst) -> result
295  *	If entity_src is a snapshot, set entity_dst to the first snaplevel
296  *	in it.  If entity_src is a snaplevel, set entity_dst to the next
297  *	snaplevel, or fail if there isn't one.
298  *
299  * SNAPSHOT_TAKE(entity_id, name, dest_id, flags) -> result
300  *	Takes a snapshot of entity_id, creating snaplevels for the instance and
301  *	its parent service.  If flags is REP_SNAPSHOT_NEW, a new snapshot named
302  *	'name' is created as a child of entity_id, dest_id is pointed to it,
303  *	and the new snaplevels are attached to it.  If flags is
304  *	REP_SNAPSHOT_ATTACH, name must be empty, and the new snaplevels are
305  *	attached to the snapshot dest_id points to.
306  *
307  * SNAPSHOT_TAKE_NAMED(entity_id, instname, svcname, name, dest_id) -> result
308  *	Like SNAPSHOT_TAKE, but always acts as if REP_SNAPSHOT_NEW is
309  *	specified, and instname and svcname override the actual service and
310  *	instance names, respectively, written into the snaplevels.
311  *
312  *	Note that this is only useful for writing snapshots which will later
313  *	be transferred to another instance (svc:/svcname:instname/)
314  *
315  * SNAPSHOT_ATTACH(source_id, dest_id) -> result
316  *	The snaplevels attached to the snapshot referenced by source_id are
317  *	attached to the snapshot dest_id is pointed at.
318  *
319  * PROPERTY_GET_TYPE(entity_id) -> result, value type
320  *	Finds the value type of entity_id, which must be a property.
321  *
322  * PROPERTY_GET_VALUE(entity_id) -> result, type, value
323  *	If the property contains a single value, returns it and its type.
324  *
325  * PROPERTYGRP_SETUP_WAIT(entity_id) -> result, [pipe fd]
326  *	Sets up a notification for changes to the object entity_id currently
327  *	references.  On success, returns one side of a pipe -- when there
328  *	has been a change (or the daemon dies), the other end of the pipe will
329  *	be closed.
330  *
331  *	Only one of these can be set up per client -- attempts to set up more
332  *	than one will cause the previous one to get closed.
333  *
334  * PROPERTYGRP_TX_START(entity_id_tx, entity_id) -> result
335  *	Makes entity_id_tx point to the same property group as entity_id,
336  *	then attempts to set up entity_id_tx as a transaction on that group.
337  *	entity_id and entity_id_tx must be distinct.  On failure, entity_id_tx
338  *	is reset.
339  *
340  * PROPERTYGRP_TX_COMMIT(entity_id, data) -> result
341  *	Gives the actual steps to follow, and attempts to commit them.
342  *
343  * CLIENT_ADD_NOTIFY(type, pattern) -> result
344  *	Adds a new property group name or type pattern to the notify list
345  *	(see CLIENT_WAIT).  If successful, takes effect immediately.
346  *
347  * CLIENT_WAIT(entity_id) -> result, fmri
348  *	Waits for a change to a propertygroup that matches the patterns
349  *	set up using CLIENT_ADD_NOTIFY, and puts the resultant propertygroup
350  *	in entity_id.  Note that if an error occurs, you can loose
351  *	notifications.  Either entity_id is set to a changed propertygroup,
352  *	or fmri is a non-zero-length string identifying a deleted thing.
353  *
354  * BACKUP(name) -> result
355  *	Backs up the persistant repository with a particular name.
356  *
357  * SET_ANNOTATION(operation, file)
358  *	Set up a security audit annotation event.  operation is the name of
359  *	the operation that is being annotated, and file is the file being
360  *	processed.  This will be used to mark operations which comprise
361  *	multiple primitive operations such as svccfg import.
362  *
363  * SWITCH(flag) -> result
364  *	The flag is used to indicate the direction of the switch operation.
365  *	When the flag is set to 'fast', move the main repository from the
366  *	default location (/etc/svc) to the tmpfs locationa (/etc/svc/volatile).
367  *	When it is set to 'perm', the switch is reversed.
368  */
369 
370 #include <door.h>
371 #include <stddef.h>
372 #include <sys/sysmacros.h>
373 
374 #ifdef	__cplusplus
375 extern "C" {
376 #endif
377 
378 /*
379  * svc.configd initial protocol details
380  */
381 #define	REPOSITORY_DOOR_BASEVER	(('R' << 24) | ('e' << 16) | ('p' << 8))
382 #define	REPOSITORY_DOOR_NAME	"/etc/svc/volatile/repository_door"
383 #define	REPOSITORY_DOOR_COOKIE	((void *)REPOSITORY_DOOR_BASEVER)
384 
385 #define	REPOSITORY_BOOT_BACKUP	((const char *)"boot")
386 
387 /*
388  * This value should be incremented any time the protocol changes.  When in
389  * doubt, bump it.
390  */
391 #define	REPOSITORY_DOOR_VERSION			(21 + REPOSITORY_DOOR_BASEVER)
392 
393 /*
394  * flags for rdr_flags
395  */
396 #define	REPOSITORY_DOOR_FLAG_DEBUG		0x00000001	/* rdr_debug */
397 
398 #define	REPOSITORY_DOOR_FLAG_ALL		0x00000001	/* all flags */
399 
400 /*
401  * Request IDs
402  */
403 enum repository_door_requestid {
404 	REPOSITORY_DOOR_REQUEST_CONNECT = (('M' << 8) | 1)
405 };
406 
407 enum repository_door_statusid {
408 	REPOSITORY_DOOR_SUCCESS			= 0,
409 	REPOSITORY_DOOR_FAIL_BAD_REQUEST	= 1,
410 	REPOSITORY_DOOR_FAIL_VERSION_MISMATCH	= 2,
411 	REPOSITORY_DOOR_FAIL_BAD_FLAG		= 3,
412 	REPOSITORY_DOOR_FAIL_NO_RESOURCES	= 4,
413 	REPOSITORY_DOOR_FAIL_PERMISSION_DENIED	= 5
414 };
415 
416 /*
417  * You may only add elements to the end of this structure.
418  */
419 typedef struct repository_door_request {
420 	uint32_t rdr_version;			/* must be first element */
421 	enum repository_door_requestid rdr_request;
422 	uint32_t rdr_flags;
423 	uint32_t rdr_debug;
424 } repository_door_request_t;
425 
426 typedef struct repository_door_response {
427 	enum repository_door_statusid rdr_status;
428 } repository_door_response_t;
429 
430 /*
431  * Client interface.  Used on doors returned by REQUEST_CONNECT
432  */
433 
434 #define	REP_PROTOCOL_NAME_LEN		120	/* maximum name length */
435 #define	REP_PROTOCOL_VALUE_LEN		4096	/* maximum value length */
436 
437 #define	REP_PROTOCOL_FMRI_LEN		(6 * REP_PROTOCOL_NAME_LEN)
438 
439 #define	REP_PROTOCOL_BASE		('C' << 8)
440 
441 /*
442  * Request codes
443  */
444 enum rep_protocol_requestid {
445 	REP_PROTOCOL_CLOSE		= REP_PROTOCOL_BASE,
446 
447 	REP_PROTOCOL_ENTITY_SETUP,
448 	REP_PROTOCOL_ENTITY_NAME,
449 	REP_PROTOCOL_ENTITY_PARENT_TYPE,
450 	REP_PROTOCOL_ENTITY_GET_CHILD,
451 	REP_PROTOCOL_ENTITY_GET_PARENT,
452 	REP_PROTOCOL_ENTITY_GET,
453 	REP_PROTOCOL_ENTITY_UPDATE,
454 	REP_PROTOCOL_ENTITY_CREATE_CHILD,
455 	REP_PROTOCOL_ENTITY_CREATE_PG,
456 	REP_PROTOCOL_ENTITY_DELETE,
457 	REP_PROTOCOL_ENTITY_RESET,
458 	REP_PROTOCOL_ENTITY_TEARDOWN,
459 
460 	REP_PROTOCOL_ITER_SETUP,
461 	REP_PROTOCOL_ITER_START,
462 	REP_PROTOCOL_ITER_READ,
463 	REP_PROTOCOL_ITER_READ_VALUE,
464 	REP_PROTOCOL_ITER_RESET,
465 	REP_PROTOCOL_ITER_TEARDOWN,
466 
467 	REP_PROTOCOL_NEXT_SNAPLEVEL,
468 
469 	REP_PROTOCOL_SNAPSHOT_TAKE,
470 	REP_PROTOCOL_SNAPSHOT_TAKE_NAMED,
471 	REP_PROTOCOL_SNAPSHOT_ATTACH,
472 
473 	REP_PROTOCOL_PROPERTY_GET_TYPE,
474 	REP_PROTOCOL_PROPERTY_GET_VALUE,
475 
476 	REP_PROTOCOL_PROPERTYGRP_SETUP_WAIT,
477 	REP_PROTOCOL_PROPERTYGRP_TX_START,
478 	REP_PROTOCOL_PROPERTYGRP_TX_COMMIT,
479 
480 	REP_PROTOCOL_CLIENT_ADD_NOTIFY,
481 	REP_PROTOCOL_CLIENT_WAIT,
482 
483 	REP_PROTOCOL_BACKUP,
484 
485 	REP_PROTOCOL_SET_AUDIT_ANNOTATION,
486 
487 	REP_PROTOCOL_SWITCH,
488 
489 	REP_PROTOCOL_MAX_REQUEST
490 };
491 
492 /*
493  * Response codes.  These are returned to the client, and the errors are
494  * translated into scf_error_t's by libscf (see proto_error()).
495  */
496 typedef int32_t rep_protocol_responseid_t;
497 enum rep_protocol_responseid {
498 	REP_PROTOCOL_SUCCESS =			0,
499 	/* iterators: No more values. */
500 	REP_PROTOCOL_DONE =			1,
501 
502 	/* Request from client was malformed. */
503 	REP_PROTOCOL_FAIL_BAD_REQUEST =		-1,
504 	/* Prerequisite call has not been made. */
505 	REP_PROTOCOL_FAIL_MISORDERED =		-2,
506 	/* Register for ID has not been created. */
507 	REP_PROTOCOL_FAIL_UNKNOWN_ID =		-3,
508 	/* Out of memory or other resource. */
509 	REP_PROTOCOL_FAIL_NO_RESOURCES =	-4,
510 	/* Type argument is invalid. */
511 	REP_PROTOCOL_FAIL_INVALID_TYPE =	-5,
512 	/* Requested object does not exist. */
513 	REP_PROTOCOL_FAIL_NOT_FOUND =		-6,
514 	/* Register for given ID does not point to an object. */
515 	REP_PROTOCOL_FAIL_NOT_SET =		-7,
516 
517 	/* Requested name is longer than supplied buffer. */
518 	REP_PROTOCOL_FAIL_TRUNCATED =		-8,
519 	/* Operation requires different type. */
520 	REP_PROTOCOL_FAIL_TYPE_MISMATCH =	-9,
521 
522 	/* Changeable object has been changed since last update. */
523 	REP_PROTOCOL_FAIL_NOT_LATEST =		-10,
524 	/* Creation failed because object with given name exists. */
525 	REP_PROTOCOL_FAIL_EXISTS =		-11,
526 	/* Transaction is invalid. */
527 	REP_PROTOCOL_FAIL_BAD_TX =		-12,
528 	/* Operation is not applicable to indicated object. */
529 	REP_PROTOCOL_FAIL_NOT_APPLICABLE =	-13,
530 	/* Two IDs for operation were unexpectedly equal. */
531 	REP_PROTOCOL_FAIL_DUPLICATE_ID =	-14,
532 
533 	/* Permission denied. */
534 	REP_PROTOCOL_FAIL_PERMISSION_DENIED =	-15,
535 	/* Backend does not exist or otherwise refused access. */
536 	REP_PROTOCOL_FAIL_BACKEND_ACCESS =	-16,
537 	/* Backend is read-only. */
538 	REP_PROTOCOL_FAIL_BACKEND_READONLY =	-17,
539 
540 	/* Object has been deleted. */
541 	REP_PROTOCOL_FAIL_DELETED =		-18,
542 
543 	REP_PROTOCOL_FAIL_UNKNOWN =		-0xfd
544 };
545 
546 /*
547  * Types
548  */
549 typedef enum rep_protocol_entity {
550 	REP_PROTOCOL_ENTITY_NONE,
551 	REP_PROTOCOL_ENTITY_SCOPE,
552 	REP_PROTOCOL_ENTITY_SERVICE,
553 	REP_PROTOCOL_ENTITY_INSTANCE,
554 	REP_PROTOCOL_ENTITY_SNAPSHOT,
555 	REP_PROTOCOL_ENTITY_SNAPLEVEL,
556 	REP_PROTOCOL_ENTITY_PROPERTYGRP,
557 	REP_PROTOCOL_ENTITY_CPROPERTYGRP,	/* "composed" property group */
558 	REP_PROTOCOL_ENTITY_PROPERTY,
559 	REP_PROTOCOL_ENTITY_VALUE,
560 
561 	REP_PROTOCOL_ENTITY_MAX
562 } rep_protocol_entity_t;
563 
564 typedef enum rep_protocol_value_type {
565 	REP_PROTOCOL_TYPE_INVALID	= '\0',
566 	REP_PROTOCOL_TYPE_BOOLEAN	= 'b',
567 	REP_PROTOCOL_TYPE_COUNT		= 'c',
568 	REP_PROTOCOL_TYPE_INTEGER	= 'i',
569 	REP_PROTOCOL_TYPE_TIME		= 't',
570 	REP_PROTOCOL_TYPE_STRING	= 's',
571 	REP_PROTOCOL_TYPE_OPAQUE	= 'o',
572 
573 	REP_PROTOCOL_SUBTYPE_USTRING	= REP_PROTOCOL_TYPE_STRING|('u' << 8),
574 	REP_PROTOCOL_SUBTYPE_URI	= REP_PROTOCOL_TYPE_STRING|('U' << 8),
575 	REP_PROTOCOL_SUBTYPE_FMRI	= REP_PROTOCOL_TYPE_STRING|('f' << 8),
576 
577 	REP_PROTOCOL_SUBTYPE_HOST	= REP_PROTOCOL_TYPE_STRING|('h' << 8),
578 	REP_PROTOCOL_SUBTYPE_HOSTNAME	= REP_PROTOCOL_TYPE_STRING|('N' << 8),
579 	REP_PROTOCOL_SUBTYPE_NETADDR_V4	= REP_PROTOCOL_TYPE_STRING|('4' << 8),
580 	REP_PROTOCOL_SUBTYPE_NETADDR_V6	= REP_PROTOCOL_TYPE_STRING|('6' << 8)
581 } rep_protocol_value_type_t;
582 
583 
584 #define	REP_PROTOCOL_BASE_TYPE(t)	((t) & 0x00ff)
585 #define	REP_PROTOCOL_SUBTYPE(t)		(((t) & 0xff00) >> 8)
586 
587 /*
588  * Request structures
589  */
590 typedef struct rep_protocol_request {
591 	enum rep_protocol_requestid rpr_request;
592 } rep_protocol_request_t;
593 
594 struct rep_protocol_iter_request {
595 	enum rep_protocol_requestid rpr_request;
596 	uint32_t rpr_iterid;
597 };
598 
599 struct rep_protocol_iter_start {
600 	enum rep_protocol_requestid rpr_request;	/* ITER_START */
601 	uint32_t rpr_iterid;
602 
603 	uint32_t rpr_entity;
604 	uint32_t rpr_itertype;
605 	uint32_t rpr_flags;
606 	char	rpr_pattern[REP_PROTOCOL_NAME_LEN];
607 };
608 #define	RP_ITER_START_ALL	0x00000001	/* ignore pattern, match all */
609 #define	RP_ITER_START_EXACT	0x00000002	/* exact match with pattern */
610 #define	RP_ITER_START_PGTYPE	0x00000003	/* exact match pg type */
611 #define	RP_ITER_START_FILT_MASK	0x00000003
612 #define	RP_ITER_START_COMPOSED	0x00000004	/* composed */
613 
614 struct rep_protocol_iter_read {
615 	enum rep_protocol_requestid rpr_request;	/* ITER_READ */
616 	uint32_t rpr_iterid;
617 	uint32_t rpr_sequence;		/* client increments upon success */
618 	uint32_t rpr_entityid;		/* entity to write result to */
619 };
620 
621 struct rep_protocol_iter_read_value {
622 	enum rep_protocol_requestid rpr_request;	/* ITER_READ_VALUE */
623 	uint32_t rpr_iterid;
624 	uint32_t rpr_sequence;		/* client increments upon success */
625 };
626 
627 struct rep_protocol_entity_setup {
628 	enum rep_protocol_requestid rpr_request;	/* ENTITY_SETUP */
629 	uint32_t rpr_entityid;
630 	uint32_t rpr_entitytype;
631 };
632 
633 struct rep_protocol_entity_name {
634 	enum rep_protocol_requestid rpr_request;	/* ENTITY_NAME */
635 	uint32_t rpr_entityid;
636 	uint32_t rpr_answertype;
637 };
638 #define	RP_ENTITY_NAME_NAME			0
639 #define	RP_ENTITY_NAME_PGTYPE			1
640 #define	RP_ENTITY_NAME_PGFLAGS			2
641 #define	RP_ENTITY_NAME_SNAPLEVEL_SCOPE		3
642 #define	RP_ENTITY_NAME_SNAPLEVEL_SERVICE	4
643 #define	RP_ENTITY_NAME_SNAPLEVEL_INSTANCE	5
644 #define	RP_ENTITY_NAME_PGREADPROT		6
645 
646 struct rep_protocol_entity_update {
647 	enum rep_protocol_requestid rpr_request;	/* ENTITY_UPDATE */
648 	uint32_t rpr_entityid;
649 	uint32_t rpr_changeid;
650 };
651 
652 struct rep_protocol_entity_parent_type {
653 	enum rep_protocol_requestid rpr_request;	/* ENTITY_PARENT_TYPE */
654 	uint32_t rpr_entityid;
655 };
656 
657 struct rep_protocol_entity_parent {
658 	enum rep_protocol_requestid rpr_request;	/* ENTITY_GET_PARENT */
659 	uint32_t rpr_entityid;
660 	uint32_t rpr_outid;
661 };
662 
663 struct rep_protocol_entity_get {
664 	enum rep_protocol_requestid rpr_request;	/* ENTITY_SET */
665 	uint32_t rpr_entityid;
666 	uint32_t rpr_object;
667 };
668 #define	RP_ENTITY_GET_INVALIDATE	1
669 #define	RP_ENTITY_GET_MOST_LOCAL_SCOPE	2
670 
671 struct rep_protocol_entity_create_child {
672 	enum rep_protocol_requestid rpr_request; /* ENTITY_CREATE_CHILD */
673 	uint32_t rpr_entityid;
674 	uint32_t rpr_childtype;
675 	uint32_t rpr_childid;
676 	uint32_t rpr_changeid;
677 	char	rpr_name[REP_PROTOCOL_NAME_LEN];
678 };
679 
680 struct rep_protocol_entity_create_pg {
681 	enum rep_protocol_requestid rpr_request; /* ENTITY_CREATE_PG */
682 	uint32_t rpr_entityid;
683 	uint32_t rpr_childtype;
684 	uint32_t rpr_childid;
685 	uint32_t rpr_changeid;
686 	char	rpr_name[REP_PROTOCOL_NAME_LEN];
687 	char	rpr_type[REP_PROTOCOL_NAME_LEN];
688 	uint32_t rpr_flags;
689 };
690 
691 struct rep_protocol_entity_get_child {
692 	enum rep_protocol_requestid rpr_request;	/* ENTITY_GET_CHILD */
693 	uint32_t rpr_entityid;
694 	uint32_t rpr_childid;
695 	char	rpr_name[REP_PROTOCOL_NAME_LEN];
696 };
697 
698 struct rep_protocol_entity_delete {
699 	enum rep_protocol_requestid rpr_request; /* ENTITY_DELETE_CHILD */
700 	uint32_t rpr_entityid;
701 	uint32_t rpr_changeid;
702 };
703 
704 struct rep_protocol_entity_reset {
705 	enum rep_protocol_requestid rpr_request;	/* ENTITY_NAME */
706 	uint32_t rpr_entityid;
707 };
708 
709 struct rep_protocol_entity_request {
710 	enum rep_protocol_requestid rpr_request;	/* ENTITY_NAME */
711 	uint32_t rpr_entityid;
712 };
713 
714 struct rep_protocol_entity_teardown {
715 	enum rep_protocol_requestid rpr_request;	/* ENTITY_TEARDOWN */
716 	uint32_t rpr_entityid;
717 };
718 
719 struct rep_protocol_entity_pair {
720 	enum rep_protocol_requestid rpr_request;	/* NEXT_SNAPLEVEL */
721 	uint32_t rpr_entity_src;
722 	uint32_t rpr_entity_dst;
723 };
724 
725 struct rep_protocol_transaction_start {
726 	enum rep_protocol_requestid rpr_request;	/* TX_SETUP */
727 	uint32_t rpr_entityid_tx;		/* property group tx entity */
728 	uint32_t rpr_entityid;			/* property group entity */
729 };
730 
731 struct rep_protocol_transaction_commit {
732 	enum rep_protocol_requestid rpr_request; /* TX_COMMIT */
733 	uint32_t rpr_entityid;
734 	uint32_t rpr_size;			/* size of entire structure */
735 	uint8_t rpr_cmd[1];
736 };
737 
738 #define	REP_PROTOCOL_TRANSACTION_COMMIT_SIZE(sz) \
739 	    (offsetof(struct rep_protocol_transaction_commit, rpr_cmd[sz]))
740 
741 #define	REP_PROTOCOL_TRANSACTION_COMMIT_MIN_SIZE \
742 	    REP_PROTOCOL_TRANSACTION_COMMIT_SIZE(0)
743 
744 enum rep_protocol_transaction_action {
745 	REP_PROTOCOL_TX_ENTRY_INVALID,	/* N/A */
746 	REP_PROTOCOL_TX_ENTRY_NEW,	/* new property */
747 	REP_PROTOCOL_TX_ENTRY_CLEAR,	/* clear old property */
748 	REP_PROTOCOL_TX_ENTRY_REPLACE,	/* change type of old property */
749 	REP_PROTOCOL_TX_ENTRY_DELETE	/* delete property (no values) */
750 };
751 
752 struct rep_protocol_transaction_cmd {
753 	enum	rep_protocol_transaction_action rptc_action;
754 	uint32_t rptc_type;
755 	uint32_t rptc_size;		/* size of entire structure */
756 	uint32_t rptc_name_len;
757 	uint8_t	rptc_data[1];
758 };
759 
760 #define	REP_PROTOCOL_TRANSACTION_CMD_SIZE(sz) \
761 	    (offsetof(struct rep_protocol_transaction_cmd, rptc_data[sz]))
762 
763 #define	REP_PROTOCOL_TRANSACTION_CMD_MIN_SIZE \
764 	    REP_PROTOCOL_TRANSACTION_CMD_SIZE(0)
765 
766 #define	TX_SIZE(x)	P2ROUNDUP((x), sizeof (uint32_t))
767 
768 struct rep_protocol_transaction_request {
769 	enum rep_protocol_requestid rpr_request; /* SETUP, ABORT or TEARDOWN */
770 	uint32_t rpr_txid;
771 };
772 
773 struct rep_protocol_property_request {
774 	enum rep_protocol_requestid rpr_request;
775 	uint32_t rpr_entityid;
776 };
777 
778 struct rep_protocol_propertygrp_request {
779 	enum rep_protocol_requestid rpr_request;
780 	uint32_t rpr_entityid;
781 };
782 
783 struct rep_protocol_notify_request {
784 	enum rep_protocol_requestid rpr_request;
785 	uint32_t rpr_type;
786 	char	rpr_pattern[REP_PROTOCOL_NAME_LEN];
787 };
788 #define	REP_PROTOCOL_NOTIFY_PGNAME 1
789 #define	REP_PROTOCOL_NOTIFY_PGTYPE 2
790 
791 struct rep_protocol_wait_request {
792 	enum rep_protocol_requestid rpr_request;
793 	uint32_t rpr_entityid;
794 };
795 
796 struct rep_protocol_snapshot_take {
797 	enum rep_protocol_requestid rpr_request;	/* SNAPSHOT_TAKE */
798 	uint32_t rpr_entityid_src;
799 	uint32_t rpr_entityid_dest;
800 	int	rpr_flags;
801 	char	rpr_name[REP_PROTOCOL_NAME_LEN];
802 };
803 #define	REP_SNAPSHOT_NEW	0x00000001
804 #define	REP_SNAPSHOT_ATTACH	0x00000002
805 
806 struct rep_protocol_snapshot_take_named {
807 	enum rep_protocol_requestid rpr_request; /* SNAPSHOT_TAKE_NAMED */
808 	uint32_t rpr_entityid_src;
809 	uint32_t rpr_entityid_dest;
810 	char	rpr_svcname[REP_PROTOCOL_NAME_LEN];
811 	char	rpr_instname[REP_PROTOCOL_NAME_LEN];
812 	char	rpr_name[REP_PROTOCOL_NAME_LEN];
813 };
814 
815 struct rep_protocol_snapshot_attach {
816 	enum rep_protocol_requestid rpr_request;	/* SNAPSHOT_ATTACH */
817 	uint32_t rpr_entityid_src;
818 	uint32_t rpr_entityid_dest;
819 };
820 
821 struct rep_protocol_backup_request {
822 	enum rep_protocol_requestid rpr_request;	/* BACKUP */
823 	uint32_t rpr_changeid;
824 	char rpr_name[REP_PROTOCOL_NAME_LEN];
825 };
826 
827 struct rep_protocol_annotation {
828 	enum rep_protocol_requestid rpr_request;	/* SET_ANNOTATION */
829 	char rpr_operation[REP_PROTOCOL_NAME_LEN];
830 	char rpr_file[MAXPATHLEN];
831 };
832 
833 struct rep_protocol_switch_request {
834 	enum rep_protocol_requestid rpr_request;	/* SWITCH */
835 	uint32_t rpr_changeid;
836 	int rpr_flag;
837 };
838 
839 /*
840  * Response structures
841  */
842 typedef struct rep_protocol_response {
843 	rep_protocol_responseid_t rpr_response;
844 } rep_protocol_response_t;
845 
846 struct rep_protocol_integer_response {
847 	rep_protocol_responseid_t rpr_response;
848 	uint32_t rpr_value;
849 };
850 
851 struct rep_protocol_name_response {	/* response to ENTITY_NAME */
852 	rep_protocol_responseid_t rpr_response;
853 	char rpr_name[REP_PROTOCOL_NAME_LEN];
854 };
855 
856 struct rep_protocol_fmri_response {
857 	rep_protocol_responseid_t rpr_response;
858 	char rpr_fmri[REP_PROTOCOL_FMRI_LEN];
859 };
860 
861 struct rep_protocol_value_response {
862 	rep_protocol_responseid_t rpr_response;
863 	rep_protocol_value_type_t rpr_type;
864 	char			rpr_value[2 * REP_PROTOCOL_VALUE_LEN + 1];
865 };
866 
867 #ifdef	__cplusplus
868 }
869 #endif
870 
871 #endif	/* _REPCACHE_PROTOCOL_H */
872