aboutsummaryrefslogtreecommitdiffstats
path: root/yql/essentials/parser/pg_wrapper/postgresql/src/include/access/nbtxlog.h
blob: 7dd9fd020658a28b1cddf788eda1c743ec1b5a3b (plain) (blame)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
/*-------------------------------------------------------------------------
 *
 * nbtxlog.h
 *	  header file for postgres btree xlog routines
 *
 * Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 * src/include/access/nbtxlog.h
 *
 *-------------------------------------------------------------------------
 */
#ifndef NBTXLOG_H
#define NBTXLOG_H

#include "access/transam.h"
#include "access/xlogreader.h"
#include "lib/stringinfo.h"
#include "storage/off.h"

/*
 * XLOG records for btree operations
 *
 * XLOG allows to store some information in high 4 bits of log
 * record xl_info field
 */
#define XLOG_BTREE_INSERT_LEAF	0x00	/* add index tuple without split */
#define XLOG_BTREE_INSERT_UPPER 0x10	/* same, on a non-leaf page */
#define XLOG_BTREE_INSERT_META	0x20	/* same, plus update metapage */
#define XLOG_BTREE_SPLIT_L		0x30	/* add index tuple with split */
#define XLOG_BTREE_SPLIT_R		0x40	/* as above, new item on right */
#define XLOG_BTREE_INSERT_POST	0x50	/* add index tuple with posting split */
#define XLOG_BTREE_DEDUP		0x60	/* deduplicate tuples for a page */
#define XLOG_BTREE_DELETE		0x70	/* delete leaf index tuples for a page */
#define XLOG_BTREE_UNLINK_PAGE	0x80	/* delete a half-dead page */
#define XLOG_BTREE_UNLINK_PAGE_META 0x90	/* same, and update metapage */
#define XLOG_BTREE_NEWROOT		0xA0	/* new root page */
#define XLOG_BTREE_MARK_PAGE_HALFDEAD 0xB0	/* mark a leaf as half-dead */
#define XLOG_BTREE_VACUUM		0xC0	/* delete entries on a page during
										 * vacuum */
#define XLOG_BTREE_REUSE_PAGE	0xD0	/* old page is about to be reused from
										 * FSM */
#define XLOG_BTREE_META_CLEANUP	0xE0	/* update cleanup-related data in the
										 * metapage */

/*
 * All that we need to regenerate the meta-data page
 */
typedef struct xl_btree_metadata
{
	uint32		version;
	BlockNumber root;
	uint32		level;
	BlockNumber fastroot;
	uint32		fastlevel;
	uint32		last_cleanup_num_delpages;
	bool		allequalimage;
} xl_btree_metadata;

/*
 * This is what we need to know about simple (without split) insert.
 *
 * This data record is used for INSERT_LEAF, INSERT_UPPER, INSERT_META, and
 * INSERT_POST.  Note that INSERT_META and INSERT_UPPER implies it's not a
 * leaf page, while INSERT_POST and INSERT_LEAF imply that it must be a leaf
 * page.
 *
 * Backup Blk 0: original page
 * Backup Blk 1: child's left sibling, if INSERT_UPPER or INSERT_META
 * Backup Blk 2: xl_btree_metadata, if INSERT_META
 *
 * Note: The new tuple is actually the "original" new item in the posting
 * list split insert case (i.e. the INSERT_POST case).  A split offset for
 * the posting list is logged before the original new item.  Recovery needs
 * both, since it must do an in-place update of the existing posting list
 * that was split as an extra step.  Also, recovery generates a "final"
 * newitem.  See _bt_swap_posting() for details on posting list splits.
 */
typedef struct xl_btree_insert
{
	OffsetNumber offnum;

	/* POSTING SPLIT OFFSET FOLLOWS (INSERT_POST case) */
	/* NEW TUPLE ALWAYS FOLLOWS AT THE END */
} xl_btree_insert;

#define SizeOfBtreeInsert	(offsetof(xl_btree_insert, offnum) + sizeof(OffsetNumber))

/*
 * On insert with split, we save all the items going into the right sibling
 * so that we can restore it completely from the log record.  This way takes
 * less xlog space than the normal approach, because if we did it standardly,
 * XLogInsert would almost always think the right page is new and store its
 * whole page image.  The left page, however, is handled in the normal
 * incremental-update fashion.
 *
 * Note: XLOG_BTREE_SPLIT_L and XLOG_BTREE_SPLIT_R share this data record.
 * There are two variants to indicate whether the inserted tuple went into the
 * left or right split page (and thus, whether the new item is stored or not).
 * We always log the left page high key because suffix truncation can generate
 * a new leaf high key using user-defined code.  This is also necessary on
 * internal pages, since the firstright item that the left page's high key was
 * based on will have been truncated to zero attributes in the right page (the
 * separator key is unavailable from the right page).
 *
 * Backup Blk 0: original page / new left page
 *
 * The left page's data portion contains the new item, if it's the _L variant.
 * _R variant split records generally do not have a newitem (_R variant leaf
 * page split records that must deal with a posting list split will include an
 * explicit newitem, though it is never used on the right page -- it is
 * actually an orignewitem needed to update existing posting list).  The new
 * high key of the left/original page appears last of all (and must always be
 * present).
 *
 * Page split records that need the REDO routine to deal with a posting list
 * split directly will have an explicit newitem, which is actually an
 * orignewitem (the newitem as it was before the posting list split, not
 * after).  A posting list split always has a newitem that comes immediately
 * after the posting list being split (which would have overlapped with
 * orignewitem prior to split).  Usually REDO must deal with posting list
 * splits with an _L variant page split record, and usually both the new
 * posting list and the final newitem go on the left page (the existing
 * posting list will be inserted instead of the old, and the final newitem
 * will be inserted next to that).  However, _R variant split records will
 * include an orignewitem when the split point for the page happens to have a
 * lastleft tuple that is also the posting list being split (leaving newitem
 * as the page split's firstright tuple).  The existence of this corner case
 * does not change the basic fact about newitem/orignewitem for the REDO
 * routine: it is always state used for the left page alone.  (This is why the
 * record's postingoff field isn't a reliable indicator of whether or not a
 * posting list split occurred during the page split; a non-zero value merely
 * indicates that the REDO routine must reconstruct a new posting list tuple
 * that is needed for the left page.)
 *
 * This posting list split handling is equivalent to the xl_btree_insert REDO
 * routine's INSERT_POST handling.  While the details are more complicated
 * here, the concept and goals are exactly the same.  See _bt_swap_posting()
 * for details on posting list splits.
 *
 * Backup Blk 1: new right page
 *
 * The right page's data portion contains the right page's tuples in the form
 * used by _bt_restore_page.  This includes the new item, if it's the _R
 * variant.  The right page's tuples also include the right page's high key
 * with either variant (moved from the left/original page during the split),
 * unless the split happened to be of the rightmost page on its level, where
 * there is no high key for new right page.
 *
 * Backup Blk 2: next block (orig page's rightlink), if any
 * Backup Blk 3: child's left sibling, if non-leaf split
 */
typedef struct xl_btree_split
{
	uint32		level;			/* tree level of page being split */
	OffsetNumber firstrightoff; /* first origpage item on rightpage */
	OffsetNumber newitemoff;	/* new item's offset */
	uint16		postingoff;		/* offset inside orig posting tuple */
} xl_btree_split;

#define SizeOfBtreeSplit	(offsetof(xl_btree_split, postingoff) + sizeof(uint16))

/*
 * When page is deduplicated, consecutive groups of tuples with equal keys are
 * merged together into posting list tuples.
 *
 * The WAL record represents a deduplication pass for a leaf page.  An array
 * of BTDedupInterval structs follows.
 */
typedef struct xl_btree_dedup
{
	uint16		nintervals;

	/* DEDUPLICATION INTERVALS FOLLOW */
} xl_btree_dedup;

#define SizeOfBtreeDedup 	(offsetof(xl_btree_dedup, nintervals) + sizeof(uint16))

/*
 * This is what we need to know about page reuse within btree.  This record
 * only exists to generate a conflict point for Hot Standby.
 *
 * Note that we must include a RelFileLocator in the record because we don't
 * actually register the buffer with the record.
 */
typedef struct xl_btree_reuse_page
{
	RelFileLocator locator;
	BlockNumber block;
	FullTransactionId snapshotConflictHorizon;
	bool		isCatalogRel;	/* to handle recovery conflict during logical
								 * decoding on standby */
} xl_btree_reuse_page;

#define SizeOfBtreeReusePage	(offsetof(xl_btree_reuse_page, isCatalogRel) + sizeof(bool))

/*
 * xl_btree_vacuum and xl_btree_delete records describe deletion of index
 * tuples on a leaf page.  The former variant is used by VACUUM, while the
 * latter variant is used by the ad-hoc deletions that sometimes take place
 * when btinsert() is called.
 *
 * The records are very similar.  The only difference is that xl_btree_delete
 * have snapshotConflictHorizon/isCatalogRel fields for recovery conflicts.
 * (VACUUM operations can just rely on earlier conflicts generated during
 * pruning of the table whose TIDs the to-be-deleted index tuples point to.
 * There are also small differences between each REDO routine that we don't go
 * into here.)
 *
 * xl_btree_vacuum and xl_btree_delete both represent deletion of any number
 * of index tuples on a single leaf page using page offset numbers.  Both also
 * support "updates" of index tuples, which is how deletes of a subset of TIDs
 * contained in an existing posting list tuple are implemented.
 *
 * Updated posting list tuples are represented using xl_btree_update metadata.
 * The REDO routines each use the xl_btree_update entries (plus each
 * corresponding original index tuple from the target leaf page) to generate
 * the final updated tuple.
 *
 * Updates are only used when there will be some remaining TIDs left by the
 * REDO routine.  Otherwise the posting list tuple just gets deleted outright.
 */
typedef struct xl_btree_vacuum
{
	uint16		ndeleted;
	uint16		nupdated;

	/*----
	 * In payload of blk 0 :
	 * - DELETED TARGET OFFSET NUMBERS
	 * - UPDATED TARGET OFFSET NUMBERS
	 * - UPDATED TUPLES METADATA (xl_btree_update) ITEMS
	 *----
	 */
} xl_btree_vacuum;

#define SizeOfBtreeVacuum	(offsetof(xl_btree_vacuum, nupdated) + sizeof(uint16))

typedef struct xl_btree_delete
{
	TransactionId snapshotConflictHorizon;
	uint16		ndeleted;
	uint16		nupdated;
	bool		isCatalogRel;	/* to handle recovery conflict during logical
								 * decoding on standby */

	/*----
	 * In payload of blk 0 :
	 * - DELETED TARGET OFFSET NUMBERS
	 * - UPDATED TARGET OFFSET NUMBERS
	 * - UPDATED TUPLES METADATA (xl_btree_update) ITEMS
	 *----
	 */
} xl_btree_delete;

#define SizeOfBtreeDelete	(offsetof(xl_btree_delete, isCatalogRel) + sizeof(bool))

/*
 * The offsets that appear in xl_btree_update metadata are offsets into the
 * original posting list from tuple, not page offset numbers.  These are
 * 0-based.  The page offset number for the original posting list tuple comes
 * from the main xl_btree_vacuum/xl_btree_delete record.
 */
typedef struct xl_btree_update
{
	uint16		ndeletedtids;

	/* POSTING LIST uint16 OFFSETS TO A DELETED TID FOLLOW */
} xl_btree_update;

#define SizeOfBtreeUpdate	(offsetof(xl_btree_update, ndeletedtids) + sizeof(uint16))

/*
 * This is what we need to know about marking an empty subtree for deletion.
 * The target identifies the tuple removed from the parent page (note that we
 * remove this tuple's downlink and the *following* tuple's key).  Note that
 * the leaf page is empty, so we don't need to store its content --- it is
 * just reinitialized during recovery using the rest of the fields.
 *
 * Backup Blk 0: leaf block
 * Backup Blk 1: top parent
 */
typedef struct xl_btree_mark_page_halfdead
{
	OffsetNumber poffset;		/* deleted tuple id in parent page */

	/* information needed to recreate the leaf page: */
	BlockNumber leafblk;		/* leaf block ultimately being deleted */
	BlockNumber leftblk;		/* leaf block's left sibling, if any */
	BlockNumber rightblk;		/* leaf block's right sibling */
	BlockNumber topparent;		/* topmost internal page in the subtree */
} xl_btree_mark_page_halfdead;

#define SizeOfBtreeMarkPageHalfDead (offsetof(xl_btree_mark_page_halfdead, topparent) + sizeof(BlockNumber))

/*
 * This is what we need to know about deletion of a btree page.  Note that we
 * only leave behind a small amount of bookkeeping information in deleted
 * pages (deleted pages must be kept around as tombstones for a while).  It is
 * convenient for the REDO routine to regenerate its target page from scratch.
 * This is why WAL record describes certain details that are actually directly
 * available from the target page.
 *
 * Backup Blk 0: target block being deleted
 * Backup Blk 1: target block's left sibling, if any
 * Backup Blk 2: target block's right sibling
 * Backup Blk 3: leaf block (if different from target)
 * Backup Blk 4: metapage (if rightsib becomes new fast root)
 */
typedef struct xl_btree_unlink_page
{
	BlockNumber leftsib;		/* target block's left sibling, if any */
	BlockNumber rightsib;		/* target block's right sibling */
	uint32		level;			/* target block's level */
	FullTransactionId safexid;	/* target block's BTPageSetDeleted() XID */

	/*
	 * Information needed to recreate a half-dead leaf page with correct
	 * topparent link.  The fields are only used when deletion operation's
	 * target page is an internal page.  REDO routine creates half-dead page
	 * from scratch to keep things simple (this is the same convenient
	 * approach used for the target page itself).
	 */
	BlockNumber leafleftsib;
	BlockNumber leafrightsib;
	BlockNumber leaftopparent;	/* next child down in the subtree */

	/* xl_btree_metadata FOLLOWS IF XLOG_BTREE_UNLINK_PAGE_META */
} xl_btree_unlink_page;

#define SizeOfBtreeUnlinkPage	(offsetof(xl_btree_unlink_page, leaftopparent) + sizeof(BlockNumber))

/*
 * New root log record.  There are zero tuples if this is to establish an
 * empty root, or two if it is the result of splitting an old root.
 *
 * Note that although this implies rewriting the metadata page, we don't need
 * an xl_btree_metadata record --- the rootblk and level are sufficient.
 *
 * Backup Blk 0: new root page (2 tuples as payload, if splitting old root)
 * Backup Blk 1: left child (if splitting an old root)
 * Backup Blk 2: metapage
 */
typedef struct xl_btree_newroot
{
	BlockNumber rootblk;		/* location of new root (redundant with blk 0) */
	uint32		level;			/* its tree level */
} xl_btree_newroot;

#define SizeOfBtreeNewroot	(offsetof(xl_btree_newroot, level) + sizeof(uint32))


/*
 * prototypes for functions in nbtxlog.c
 */
extern void btree_redo(XLogReaderState *record);
extern void btree_xlog_startup(void);
extern void btree_xlog_cleanup(void);
extern void btree_mask(char *pagedata, BlockNumber blkno);

/*
 * prototypes for functions in nbtdesc.c
 */
extern void btree_desc(StringInfo buf, XLogReaderState *record);
extern const char *btree_identify(uint8 info);

#endif							/* NBTXLOG_H */