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1 /* handle.c
3 Functions for maintaining handles on objects. */
5 /*
6 * Copyright (c) 2004 by Internet Systems Consortium, Inc. ("ISC")
7 * Copyright (c) 1999-2003 by Internet Software Consortium
8 *
9 * Permission to use, copy, modify, and distribute this software for any
10 * purpose with or without fee is hereby granted, provided that the above
11 * copyright notice and this permission notice appear in all copies.
12 *
13 * THE SOFTWARE IS PROVIDED "AS IS" AND ISC DISCLAIMS ALL WARRANTIES
14 * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
15 * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL ISC BE LIABLE FOR
16 * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
17 * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
18 * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT
19 * OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
20 *
21 * Internet Systems Consortium, Inc.
22 * 950 Charter Street
23 * Redwood City, CA 94063
24 * <info@isc.org>
25 * http://www.isc.org/
26 *
27 * This software has been written for Internet Systems Consortium
28 * by Ted Lemon in cooperation with Vixie Enterprises and Nominum, Inc.
29 * To learn more about Internet Systems Consortium, see
30 * ``http://www.isc.org/''. To learn more about Vixie Enterprises,
31 * see ``http://www.vix.com''. To learn more about Nominum, Inc., see
32 * ``http://www.nominum.com''.
33 */
35 #include <omapip/omapip_p.h>
37 /* The handle table is a hierarchical tree designed for quick mapping
38 of handle identifiers to objects. Objects contain their own handle
39 identifiers if they have them, so the reverse mapping is also
40 quick. The hierarchy is made up of table objects, each of which
41 has 120 entries, a flag indicating whether the table is a leaf
42 table or an indirect table, the handle of the first object covered
43 by the table and the first object after that that's *not* covered
44 by the table, a count of how many objects of either type are
45 currently stored in the table, and an array of 120 entries pointing
46 either to objects or tables.
48 When we go to add an object to the table, we look to see if the
49 next object handle to be assigned is covered by the outermost
50 table. If it is, we find the place within that table where the
51 next handle should go, and if necessary create additional nodes in
52 the tree to contain the new handle. The pointer to the object is
53 then stored in the correct position.
55 Theoretically, we could have some code here to free up handle
56 tables as they go out of use, but by and large handle tables won't
57 go out of use, so this is being skipped for now. It shouldn't be
58 too hard to implement in the future if there's a different
59 application. */
65 omapi_handle_t,
66 omapi_handle_table_t *);
68 omapi_handle_table_t *,
69 omapi_object_t *);
73 {
75 isc_result_t status;
80 }
90 }
92 /* If this handle doesn't fit in the outer table, we need to
93 make a new outer table. This is a while loop in case for
94 some reason we decide to do disjoint handle allocation,
95 where the next level of indirection still isn't big enough
96 to enclose the next handle ID. */
107 OMAPI_HANDLE_TABLE_SIZE);
111 }
113 /* Try to cram this handle into the existing table. */
116 /* If it worked, return the next handle and increment it. */
119 omapi_next_handle++;
121 }
134 omapi_next_handle++;
137 }
142 {
145 isc_result_t status;
150 /* If this is a leaf table, just stash the object in the
151 appropriate place. */
153 status = (omapi_object_reference
160 }
162 /* Scale is the number of handles represented by each child of this
163 table. For a leaf table, scale would be 1. For a first level
164 of indirection, 120. For a second, 120 * 120. Et cetera. */
167 /* So the next most direct table from this one that contains the
168 handle must be the subtable of this table whose index into this
169 table's array of children is the handle divided by the scale. */
173 /* If there is no more direct table than this one in the slot
174 we came up with, make one. */
185 }
189 status = (omapi_handle_table_enclose
194 return omapi_object_handle_in_table
196 }
198 }
201 {
206 /* The scale of the table we're enclosing is going to be the
207 difference between its "first" and "limit" members. So the
208 scale of the table enclosing it is going to be that multiplied
209 by the table size. */
212 /* The range that the enclosing table covers is going to be
213 the result of subtracting the remainder of dividing the
214 enclosed table's first entry number by the enclosing
215 table's scale. If handle IDs are being allocated
216 sequentially, the enclosing table's "first" value will be
217 the same as the enclosed table's "first" value. */
220 /* The index into the enclosing table at which the enclosed table
221 will be stored is going to be the difference between the "first"
222 value of the enclosing table and the enclosed table - zero, if
223 we are allocating sequentially. */
237 }
240 {
242 }
245 omapi_handle_t h,
248 {
255 /* If this is a leaf table, just grab the object. */
257 /* Not there? */
260 return omapi_object_reference
262 MDL);
263 }
265 /* Scale is the number of handles represented by each child of this
266 table. For a leaf table, scale would be 1. For a first level
267 of indirection, 120. For a second, 120 * 120. Et cetera. */
270 /* So the next most direct table from this one that contains the
271 handle must be the subtable of this table whose index into this
272 table's array of children is the handle divided by the scale. */
277 }
279 /* For looking up objects based on handles that have been sent on the wire. */
282 {
283 isc_result_t status;
284 omapi_handle_t h;
295 }