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1 /*-
2 * Copyright (c) 1991, 1993, 1994
3 * The Regents of the University of California. All rights reserved.
4 *
5 * This code is derived from software contributed to Berkeley by
6 * Mike Olson.
7 *
8 * Redistribution and use in source and binary forms, with or without
9 * modification, are permitted provided that the following conditions
10 * are met:
11 * 1. Redistributions of source code must retain the above copyright
12 * notice, this list of conditions and the following disclaimer.
13 * 2. Redistributions in binary form must reproduce the above copyright
14 * notice, this list of conditions and the following disclaimer in the
15 * documentation and/or other materials provided with the distribution.
16 * 3. All advertising materials mentioning features or use of this software
17 * must display the following acknowledgement:
18 * This product includes software developed by the University of
19 * California, Berkeley and its contributors.
20 * 4. Neither the name of the University nor the names of its contributors
21 * may be used to endorse or promote products derived from this software
22 * without specific prior written permission.
23 *
24 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
25 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
26 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
27 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
28 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
29 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
30 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
31 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
32 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
33 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
34 * SUCH DAMAGE.
35 *
36 * @(#)btree.h 8.11 (Berkeley) 8/17/94
37 */
39 /* Macros to set/clear/test flags. */
40 #define F_SET(p, f) (p)->flags |= (f)
41 #define F_CLR(p, f) (p)->flags &= ~(f)
42 #define F_ISSET(p, f) ((p)->flags & (f))
44 #include <mpool.h>
50 /*
51 * Page 0 of a btree file contains a copy of the meta-data. This page is also
52 * used as an out-of-band page, i.e. page pointers that point to nowhere point
53 * to page 0. Page 1 is the root of the btree.
54 */
59 /*
60 * There are five page layouts in the btree: btree internal pages (BINTERNAL),
61 * btree leaf pages (BLEAF), recno internal pages (RINTERNAL), recno leaf pages
62 * (RLEAF) and overflow pages. All five page types have a page header (PAGE).
63 * This implementation requires that values within structures NOT be padded.
64 * (ANSI C permits random padding.) If your compiler pads randomly you'll have
65 * to do some work to get this package to run.
66 */
79 u_int32_t flags;
86 /* First and next index. */
87 #define BTDATAOFF \
88 (sizeof(pgno_t) + sizeof(pgno_t) + sizeof(pgno_t) + \
89 sizeof(u_int32_t) + sizeof(indx_t) + sizeof(indx_t))
90 #define NEXTINDEX(p) (((p)->lower - BTDATAOFF) / sizeof(indx_t))
92 /*
93 * For pages other than overflow pages, there is an array of offsets into the
94 * rest of the page immediately following the page header. Each offset is to
95 * an item which is unique to the type of page. The h_lower offset is just
96 * past the last filled-in index. The h_upper offset is the first item on the
97 * page. Offsets are from the beginning of the page.
98 *
99 * If an item is too big to store on a single page, a flag is set and the item
100 * is a { page, size } pair such that the page is the first page of an overflow
101 * chain with size bytes of item. Overflow pages are simply bytes without any
102 * external structure.
103 *
104 * The page number and size fields in the items are pgno_t-aligned so they can
105 * be manipulated without copying. (This presumes that 32 bit items can be
106 * manipulated on this system.)
107 */
108 #define LALIGN(n) (((n) + sizeof(pgno_t) - 1) & ~(sizeof(pgno_t) - 1))
109 #define NOVFLSIZE (sizeof(pgno_t) + sizeof(u_int32_t))
111 /*
112 * For the btree internal pages, the item is a key. BINTERNALs are {key, pgno}
113 * pairs, such that the key compares less than or equal to all of the records
114 * on that page. For a tree without duplicate keys, an internal page with two
115 * consecutive keys, a and b, will have all records greater than or equal to a
116 * and less than b stored on the page associated with a. Duplicate keys are
117 * somewhat special and can cause duplicate internal and leaf page records and
118 * some minor modifications of the above rule.
119 */
125 u_char flags;
129 /* Get the page's BINTERNAL structure at index indx. */
130 #define GETBINTERNAL(pg, indx) \
131 ((BINTERNAL *)((char *)(pg) + (pg)->linp[indx]))
133 /* Get the number of bytes in the entry. */
134 #define NBINTERNAL(len) \
135 LALIGN(sizeof(u_int32_t) + sizeof(pgno_t) + sizeof(u_char) + (len))
137 /* Copy a BINTERNAL entry to the page. */
138 #define WR_BINTERNAL(p, size, pgno, flags) { \
139 *(u_int32_t *)p = size; \
140 p += sizeof(u_int32_t); \
141 *(pgno_t *)p = pgno; \
142 p += sizeof(pgno_t); \
143 *(u_char *)p = flags; \
144 p += sizeof(u_char); \
145 }
147 /*
148 * For the recno internal pages, the item is a page number with the number of
149 * keys found on that page and below.
150 */
156 /* Get the page's RINTERNAL structure at index indx. */
157 #define GETRINTERNAL(pg, indx) \
158 ((RINTERNAL *)((char *)(pg) + (pg)->linp[indx]))
160 /* Get the number of bytes in the entry. */
161 #define NRINTERNAL \
162 LALIGN(sizeof(recno_t) + sizeof(pgno_t))
164 /* Copy a RINTERAL entry to the page. */
165 #define WR_RINTERNAL(p, nrecs, pgno) { \
166 *(recno_t *)p = nrecs; \
167 p += sizeof(recno_t); \
168 *(pgno_t *)p = pgno; \
169 }
171 /* For the btree leaf pages, the item is a key and data pair. */
179 /* Get the page's BLEAF structure at index indx. */
180 #define GETBLEAF(pg, indx) \
181 ((BLEAF *)((char *)(pg) + (pg)->linp[indx]))
183 /* Get the number of bytes in the entry. */
184 #define NBLEAF(p) NBLEAFDBT((p)->ksize, (p)->dsize)
186 /* Get the number of bytes in the user's key/data pair. */
187 #define NBLEAFDBT(ksize, dsize) \
188 LALIGN(sizeof(u_int32_t) + sizeof(u_int32_t) + sizeof(u_char) + \
189 (ksize) + (dsize))
191 /* Copy a BLEAF entry to the page. */
192 #define WR_BLEAF(p, key, data, flags) { \
193 *(u_int32_t *)p = key->size; \
194 p += sizeof(u_int32_t); \
195 *(u_int32_t *)p = data->size; \
196 p += sizeof(u_int32_t); \
197 *(u_char *)p = flags; \
198 p += sizeof(u_char); \
199 memmove(p, key->data, key->size); \
200 p += key->size; \
201 memmove(p, data->data, data->size); \
202 }
204 /* For the recno leaf pages, the item is a data entry. */
211 /* Get the page's RLEAF structure at index indx. */
212 #define GETRLEAF(pg, indx) \
213 ((RLEAF *)((char *)(pg) + (pg)->linp[indx]))
215 /* Get the number of bytes in the entry. */
216 #define NRLEAF(p) NRLEAFDBT((p)->dsize)
218 /* Get the number of bytes from the user's data. */
219 #define NRLEAFDBT(dsize) \
220 LALIGN(sizeof(u_int32_t) + sizeof(u_char) + (dsize))
222 /* Copy a RLEAF entry to the page. */
223 #define WR_RLEAF(p, data, flags) { \
224 *(u_int32_t *)p = data->size; \
225 p += sizeof(u_int32_t); \
226 *(u_char *)p = flags; \
227 p += sizeof(u_char); \
228 memmove(p, data->data, data->size); \
229 }
231 /*
232 * A record in the tree is either a pointer to a page and an index in the page
233 * or a page number and an index. These structures are used as a cursor, stack
234 * entry and search returns as well as to pass records to other routines.
235 *
236 * One comment about searches. Internal page searches must find the largest
237 * record less than key in the tree so that descents work. Leaf page searches
238 * must find the smallest record greater than key so that the returned index
239 * is the record's correct position for insertion.
240 */
251 /*
252 * About cursors. The cursor (and the page that contained the key/data pair
253 * that it referenced) can be deleted, which makes things a bit tricky. If
254 * there are no duplicates of the cursor key in the tree (i.e. B_NODUPS is set
255 * or there simply aren't any duplicates of the key) we copy the key that it
256 * referenced when it's deleted, and reacquire a new cursor key if the cursor
257 * is used again. If there are duplicates keys, we move to the next/previous
258 * key, and set a flag so that we know what happened. NOTE: if duplicate (to
259 * the cursor) keys are added to the tree during this process, it is undefined
260 * if they will be returned or not in a cursor scan.
261 *
262 * The flags determine the possible states of the cursor:
263 *
264 * CURS_INIT The cursor references *something*.
265 * CURS_ACQUIRE The cursor was deleted, and a key has been saved so that
266 * we can reacquire the right position in the tree.
267 * CURS_AFTER, CURS_BEFORE
268 * The cursor was deleted, and now references a key/data pair
269 * that has not yet been returned, either before or after the
270 * deleted key/data pair.
271 * XXX
272 * This structure is broken out so that we can eventually offer multiple
273 * cursors as part of the DB interface.
274 */
284 u_int8_t flags;
287 /*
288 * The metadata of the tree. The nrecs field is used only by the RECNO code.
289 * This is because the btree doesn't really need it and it requires that every
290 * put or delete call modify the metadata.
291 */
299 #define SAVEMETA (B_NODUPS | R_RECNO)
303 /* The in-memory btree/recno data structure. */
314 #define BT_PUSH(t, p, i) { \
315 t->bt_sp->pgno = p; \
316 t->bt_sp->index = i; \
317 ++t->bt_sp; \
318 }
319 #define BT_POP(t) (t->bt_sp == t->bt_stack ? NULL : --t->bt_sp)
320 #define BT_CLR(t) (t->bt_sp = t->bt_stack)
333 /* sorted order */
337 /* B: key comparison function */
339 /* B: prefix comparison function */
341 /* R: recno input function */
356 /*
357 * NB:
358 * B_NODUPS and R_RECNO are stored on disk, and may not be changed.
359 */
380 u_int32_t flags;