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|
/*-------------------------------------------------------------------------
*
* tidbitmap.c
* PostgreSQL tuple-id (TID) bitmap package
*
* This module provides bitmap data structures that are spiritually
* similar to Bitmapsets, but are specially adapted to store sets of
* tuple identifiers (TIDs), or ItemPointers. In particular, the division
* of an ItemPointer into BlockNumber and OffsetNumber is catered for.
* Also, since we wish to be able to store very large tuple sets in
* memory with this data structure, we support "lossy" storage, in which
* we no longer remember individual tuple offsets on a page but only the
* fact that a particular page needs to be visited.
*
* The "lossy" storage uses one bit per disk page, so at the standard 8K
* BLCKSZ, we can represent all pages in 64Gb of disk space in about 1Mb
* of memory. People pushing around tables of that size should have a
* couple of Mb to spare, so we don't worry about providing a second level
* of lossiness. In theory we could fall back to page ranges at some
* point, but for now that seems useless complexity.
*
* We also support the notion of candidate matches, or rechecking. This
* means we know that a search need visit only some tuples on a page,
* but we are not certain that all of those tuples are real matches.
* So the eventual heap scan must recheck the quals for these tuples only,
* rather than rechecking the quals for all tuples on the page as in the
* lossy-bitmap case. Rechecking can be specified when TIDs are inserted
* into a bitmap, and it can also happen internally when we AND a lossy
* and a non-lossy page.
*
*
* Copyright (c) 2003-2020, PostgreSQL Global Development Group
*
* IDENTIFICATION
* src/backend/nodes/tidbitmap.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include <limits.h>
#include "access/htup_details.h"
#include "common/hashfn.h"
#include "nodes/bitmapset.h"
#include "nodes/tidbitmap.h"
#include "storage/lwlock.h"
#include "utils/dsa.h"
/*
* The maximum number of tuples per page is not large (typically 256 with
* 8K pages, or 1024 with 32K pages). So there's not much point in making
* the per-page bitmaps variable size. We just legislate that the size
* is this:
*/
#define MAX_TUPLES_PER_PAGE MaxHeapTuplesPerPage
/*
* When we have to switch over to lossy storage, we use a data structure
* with one bit per page, where all pages having the same number DIV
* PAGES_PER_CHUNK are aggregated into one chunk. When a chunk is present
* and has the bit set for a given page, there must not be a per-page entry
* for that page in the page table.
*
* We actually store both exact pages and lossy chunks in the same hash
* table, using identical data structures. (This is because the memory
* management for hashtables doesn't easily/efficiently allow space to be
* transferred easily from one hashtable to another.) Therefore it's best
* if PAGES_PER_CHUNK is the same as MAX_TUPLES_PER_PAGE, or at least not
* too different. But we also want PAGES_PER_CHUNK to be a power of 2 to
* avoid expensive integer remainder operations. So, define it like this:
*/
#define PAGES_PER_CHUNK (BLCKSZ / 32)
/* We use BITS_PER_BITMAPWORD and typedef bitmapword from nodes/bitmapset.h */
#define WORDNUM(x) ((x) / BITS_PER_BITMAPWORD)
#define BITNUM(x) ((x) % BITS_PER_BITMAPWORD)
/* number of active words for an exact page: */
#define WORDS_PER_PAGE ((MAX_TUPLES_PER_PAGE - 1) / BITS_PER_BITMAPWORD + 1)
/* number of active words for a lossy chunk: */
#define WORDS_PER_CHUNK ((PAGES_PER_CHUNK - 1) / BITS_PER_BITMAPWORD + 1)
/*
* The hashtable entries are represented by this data structure. For
* an exact page, blockno is the page number and bit k of the bitmap
* represents tuple offset k+1. For a lossy chunk, blockno is the first
* page in the chunk (this must be a multiple of PAGES_PER_CHUNK) and
* bit k represents page blockno+k. Note that it is not possible to
* have exact storage for the first page of a chunk if we are using
* lossy storage for any page in the chunk's range, since the same
* hashtable entry has to serve both purposes.
*
* recheck is used only on exact pages --- it indicates that although
* only the stated tuples need be checked, the full index qual condition
* must be checked for each (ie, these are candidate matches).
*/
typedef struct PagetableEntry
{
BlockNumber blockno; /* page number (hashtable key) */
char status; /* hash entry status */
bool ischunk; /* T = lossy storage, F = exact */
bool recheck; /* should the tuples be rechecked? */
bitmapword words[Max(WORDS_PER_PAGE, WORDS_PER_CHUNK)];
} PagetableEntry;
/*
* Holds array of pagetable entries.
*/
typedef struct PTEntryArray
{
pg_atomic_uint32 refcount; /* no. of iterator attached */
PagetableEntry ptentry[FLEXIBLE_ARRAY_MEMBER];
} PTEntryArray;
/*
* We want to avoid the overhead of creating the hashtable, which is
* comparatively large, when not necessary. Particularly when we are using a
* bitmap scan on the inside of a nestloop join: a bitmap may well live only
* long enough to accumulate one entry in such cases. We therefore avoid
* creating an actual hashtable until we need two pagetable entries. When
* just one pagetable entry is needed, we store it in a fixed field of
* TIDBitMap. (NOTE: we don't get rid of the hashtable if the bitmap later
* shrinks down to zero or one page again. So, status can be TBM_HASH even
* when nentries is zero or one.)
*/
typedef enum
{
TBM_EMPTY, /* no hashtable, nentries == 0 */
TBM_ONE_PAGE, /* entry1 contains the single entry */
TBM_HASH /* pagetable is valid, entry1 is not */
} TBMStatus;
/*
* Current iterating state of the TBM.
*/
typedef enum
{
TBM_NOT_ITERATING, /* not yet converted to page and chunk array */
TBM_ITERATING_PRIVATE, /* converted to local page and chunk array */
TBM_ITERATING_SHARED /* converted to shared page and chunk array */
} TBMIteratingState;
/*
* Here is the representation for a whole TIDBitMap:
*/
struct TIDBitmap
{
NodeTag type; /* to make it a valid Node */
MemoryContext mcxt; /* memory context containing me */
TBMStatus status; /* see codes above */
struct pagetable_hash *pagetable; /* hash table of PagetableEntry's */
int nentries; /* number of entries in pagetable */
int maxentries; /* limit on same to meet maxbytes */
int npages; /* number of exact entries in pagetable */
int nchunks; /* number of lossy entries in pagetable */
TBMIteratingState iterating; /* tbm_begin_iterate called? */
uint32 lossify_start; /* offset to start lossifying hashtable at */
PagetableEntry entry1; /* used when status == TBM_ONE_PAGE */
/* these are valid when iterating is true: */
PagetableEntry **spages; /* sorted exact-page list, or NULL */
PagetableEntry **schunks; /* sorted lossy-chunk list, or NULL */
dsa_pointer dsapagetable; /* dsa_pointer to the element array */
dsa_pointer dsapagetableold; /* dsa_pointer to the old element array */
dsa_pointer ptpages; /* dsa_pointer to the page array */
dsa_pointer ptchunks; /* dsa_pointer to the chunk array */
dsa_area *dsa; /* reference to per-query dsa area */
};
/*
* When iterating over a bitmap in sorted order, a TBMIterator is used to
* track our progress. There can be several iterators scanning the same
* bitmap concurrently. Note that the bitmap becomes read-only as soon as
* any iterator is created.
*/
struct TBMIterator
{
TIDBitmap *tbm; /* TIDBitmap we're iterating over */
int spageptr; /* next spages index */
int schunkptr; /* next schunks index */
int schunkbit; /* next bit to check in current schunk */
TBMIterateResult output; /* MUST BE LAST (because variable-size) */
};
/*
* Holds the shared members of the iterator so that multiple processes
* can jointly iterate.
*/
typedef struct TBMSharedIteratorState
{
int nentries; /* number of entries in pagetable */
int maxentries; /* limit on same to meet maxbytes */
int npages; /* number of exact entries in pagetable */
int nchunks; /* number of lossy entries in pagetable */
dsa_pointer pagetable; /* dsa pointers to head of pagetable data */
dsa_pointer spages; /* dsa pointer to page array */
dsa_pointer schunks; /* dsa pointer to chunk array */
LWLock lock; /* lock to protect below members */
int spageptr; /* next spages index */
int schunkptr; /* next schunks index */
int schunkbit; /* next bit to check in current schunk */
} TBMSharedIteratorState;
/*
* pagetable iteration array.
*/
typedef struct PTIterationArray
{
pg_atomic_uint32 refcount; /* no. of iterator attached */
int index[FLEXIBLE_ARRAY_MEMBER]; /* index array */
} PTIterationArray;
/*
* same as TBMIterator, but it is used for joint iteration, therefore this
* also holds a reference to the shared state.
*/
struct TBMSharedIterator
{
TBMSharedIteratorState *state; /* shared state */
PTEntryArray *ptbase; /* pagetable element array */
PTIterationArray *ptpages; /* sorted exact page index list */
PTIterationArray *ptchunks; /* sorted lossy page index list */
TBMIterateResult output; /* MUST BE LAST (because variable-size) */
};
/* Local function prototypes */
static void tbm_union_page(TIDBitmap *a, const PagetableEntry *bpage);
static bool tbm_intersect_page(TIDBitmap *a, PagetableEntry *apage,
const TIDBitmap *b);
static const PagetableEntry *tbm_find_pageentry(const TIDBitmap *tbm,
BlockNumber pageno);
static PagetableEntry *tbm_get_pageentry(TIDBitmap *tbm, BlockNumber pageno);
static bool tbm_page_is_lossy(const TIDBitmap *tbm, BlockNumber pageno);
static void tbm_mark_page_lossy(TIDBitmap *tbm, BlockNumber pageno);
static void tbm_lossify(TIDBitmap *tbm);
static int tbm_comparator(const void *left, const void *right);
static int tbm_shared_comparator(const void *left, const void *right,
void *arg);
/* define hashtable mapping block numbers to PagetableEntry's */
#define SH_USE_NONDEFAULT_ALLOCATOR
#define SH_PREFIX pagetable
#define SH_ELEMENT_TYPE PagetableEntry
#define SH_KEY_TYPE BlockNumber
#define SH_KEY blockno
#define SH_HASH_KEY(tb, key) murmurhash32(key)
#define SH_EQUAL(tb, a, b) a == b
#define SH_SCOPE static inline
#define SH_DEFINE
#define SH_DECLARE
#include "lib/simplehash.h"
/*
* tbm_create - create an initially-empty bitmap
*
* The bitmap will live in the memory context that is CurrentMemoryContext
* at the time of this call. It will be limited to (approximately) maxbytes
* total memory consumption. If the DSA passed to this function is not NULL
* then the memory for storing elements of the underlying page table will
* be allocated from the DSA.
*/
TIDBitmap *
tbm_create(long maxbytes, dsa_area *dsa)
{
TIDBitmap *tbm;
/* Create the TIDBitmap struct and zero all its fields */
tbm = makeNode(TIDBitmap);
tbm->mcxt = CurrentMemoryContext;
tbm->status = TBM_EMPTY;
tbm->maxentries = (int) tbm_calculate_entries(maxbytes);
tbm->lossify_start = 0;
tbm->dsa = dsa;
tbm->dsapagetable = InvalidDsaPointer;
tbm->dsapagetableold = InvalidDsaPointer;
tbm->ptpages = InvalidDsaPointer;
tbm->ptchunks = InvalidDsaPointer;
return tbm;
}
/*
* Actually create the hashtable. Since this is a moderately expensive
* proposition, we don't do it until we have to.
*/
static void
tbm_create_pagetable(TIDBitmap *tbm)
{
Assert(tbm->status != TBM_HASH);
Assert(tbm->pagetable == NULL);
tbm->pagetable = pagetable_create(tbm->mcxt, 128, tbm);
/* If entry1 is valid, push it into the hashtable */
if (tbm->status == TBM_ONE_PAGE)
{
PagetableEntry *page;
bool found;
char oldstatus;
page = pagetable_insert(tbm->pagetable,
tbm->entry1.blockno,
&found);
Assert(!found);
oldstatus = page->status;
memcpy(page, &tbm->entry1, sizeof(PagetableEntry));
page->status = oldstatus;
}
tbm->status = TBM_HASH;
}
/*
* tbm_free - free a TIDBitmap
*/
void
tbm_free(TIDBitmap *tbm)
{
if (tbm->pagetable)
pagetable_destroy(tbm->pagetable);
if (tbm->spages)
pfree(tbm->spages);
if (tbm->schunks)
pfree(tbm->schunks);
pfree(tbm);
}
/*
* tbm_free_shared_area - free shared state
*
* Free shared iterator state, Also free shared pagetable and iterator arrays
* memory if they are not referred by any of the shared iterator i.e recount
* is becomes 0.
*/
void
tbm_free_shared_area(dsa_area *dsa, dsa_pointer dp)
{
TBMSharedIteratorState *istate = dsa_get_address(dsa, dp);
PTEntryArray *ptbase;
PTIterationArray *ptpages;
PTIterationArray *ptchunks;
if (DsaPointerIsValid(istate->pagetable))
{
ptbase = dsa_get_address(dsa, istate->pagetable);
if (pg_atomic_sub_fetch_u32(&ptbase->refcount, 1) == 0)
dsa_free(dsa, istate->pagetable);
}
if (DsaPointerIsValid(istate->spages))
{
ptpages = dsa_get_address(dsa, istate->spages);
if (pg_atomic_sub_fetch_u32(&ptpages->refcount, 1) == 0)
dsa_free(dsa, istate->spages);
}
if (DsaPointerIsValid(istate->schunks))
{
ptchunks = dsa_get_address(dsa, istate->schunks);
if (pg_atomic_sub_fetch_u32(&ptchunks->refcount, 1) == 0)
dsa_free(dsa, istate->schunks);
}
dsa_free(dsa, dp);
}
/*
* tbm_add_tuples - add some tuple IDs to a TIDBitmap
*
* If recheck is true, then the recheck flag will be set in the
* TBMIterateResult when any of these tuples are reported out.
*/
void
tbm_add_tuples(TIDBitmap *tbm, const ItemPointer tids, int ntids,
bool recheck)
{
BlockNumber currblk = InvalidBlockNumber;
PagetableEntry *page = NULL; /* only valid when currblk is valid */
int i;
Assert(tbm->iterating == TBM_NOT_ITERATING);
for (i = 0; i < ntids; i++)
{
BlockNumber blk = ItemPointerGetBlockNumber(tids + i);
OffsetNumber off = ItemPointerGetOffsetNumber(tids + i);
int wordnum,
bitnum;
/* safety check to ensure we don't overrun bit array bounds */
if (off < 1 || off > MAX_TUPLES_PER_PAGE)
elog(ERROR, "tuple offset out of range: %u", off);
/*
* Look up target page unless we already did. This saves cycles when
* the input includes consecutive tuples on the same page, which is
* common enough to justify an extra test here.
*/
if (blk != currblk)
{
if (tbm_page_is_lossy(tbm, blk))
page = NULL; /* remember page is lossy */
else
page = tbm_get_pageentry(tbm, blk);
currblk = blk;
}
if (page == NULL)
continue; /* whole page is already marked */
if (page->ischunk)
{
/* The page is a lossy chunk header, set bit for itself */
wordnum = bitnum = 0;
}
else
{
/* Page is exact, so set bit for individual tuple */
wordnum = WORDNUM(off - 1);
bitnum = BITNUM(off - 1);
}
page->words[wordnum] |= ((bitmapword) 1 << bitnum);
page->recheck |= recheck;
if (tbm->nentries > tbm->maxentries)
{
tbm_lossify(tbm);
/* Page could have been converted to lossy, so force new lookup */
currblk = InvalidBlockNumber;
}
}
}
/*
* tbm_add_page - add a whole page to a TIDBitmap
*
* This causes the whole page to be reported (with the recheck flag)
* when the TIDBitmap is scanned.
*/
void
tbm_add_page(TIDBitmap *tbm, BlockNumber pageno)
{
/* Enter the page in the bitmap, or mark it lossy if already present */
tbm_mark_page_lossy(tbm, pageno);
/* If we went over the memory limit, lossify some more pages */
if (tbm->nentries > tbm->maxentries)
tbm_lossify(tbm);
}
/*
* tbm_union - set union
*
* a is modified in-place, b is not changed
*/
void
tbm_union(TIDBitmap *a, const TIDBitmap *b)
{
Assert(!a->iterating);
/* Nothing to do if b is empty */
if (b->nentries == 0)
return;
/* Scan through chunks and pages in b, merge into a */
if (b->status == TBM_ONE_PAGE)
tbm_union_page(a, &b->entry1);
else
{
pagetable_iterator i;
PagetableEntry *bpage;
Assert(b->status == TBM_HASH);
pagetable_start_iterate(b->pagetable, &i);
while ((bpage = pagetable_iterate(b->pagetable, &i)) != NULL)
tbm_union_page(a, bpage);
}
}
/* Process one page of b during a union op */
static void
tbm_union_page(TIDBitmap *a, const PagetableEntry *bpage)
{
PagetableEntry *apage;
int wordnum;
if (bpage->ischunk)
{
/* Scan b's chunk, mark each indicated page lossy in a */
for (wordnum = 0; wordnum < WORDS_PER_CHUNK; wordnum++)
{
bitmapword w = bpage->words[wordnum];
if (w != 0)
{
BlockNumber pg;
pg = bpage->blockno + (wordnum * BITS_PER_BITMAPWORD);
while (w != 0)
{
if (w & 1)
tbm_mark_page_lossy(a, pg);
pg++;
w >>= 1;
}
}
}
}
else if (tbm_page_is_lossy(a, bpage->blockno))
{
/* page is already lossy in a, nothing to do */
return;
}
else
{
apage = tbm_get_pageentry(a, bpage->blockno);
if (apage->ischunk)
{
/* The page is a lossy chunk header, set bit for itself */
apage->words[0] |= ((bitmapword) 1 << 0);
}
else
{
/* Both pages are exact, merge at the bit level */
for (wordnum = 0; wordnum < WORDS_PER_PAGE; wordnum++)
apage->words[wordnum] |= bpage->words[wordnum];
apage->recheck |= bpage->recheck;
}
}
if (a->nentries > a->maxentries)
tbm_lossify(a);
}
/*
* tbm_intersect - set intersection
*
* a is modified in-place, b is not changed
*/
void
tbm_intersect(TIDBitmap *a, const TIDBitmap *b)
{
Assert(!a->iterating);
/* Nothing to do if a is empty */
if (a->nentries == 0)
return;
/* Scan through chunks and pages in a, try to match to b */
if (a->status == TBM_ONE_PAGE)
{
if (tbm_intersect_page(a, &a->entry1, b))
{
/* Page is now empty, remove it from a */
Assert(!a->entry1.ischunk);
a->npages--;
a->nentries--;
Assert(a->nentries == 0);
a->status = TBM_EMPTY;
}
}
else
{
pagetable_iterator i;
PagetableEntry *apage;
Assert(a->status == TBM_HASH);
pagetable_start_iterate(a->pagetable, &i);
while ((apage = pagetable_iterate(a->pagetable, &i)) != NULL)
{
if (tbm_intersect_page(a, apage, b))
{
/* Page or chunk is now empty, remove it from a */
if (apage->ischunk)
a->nchunks--;
else
a->npages--;
a->nentries--;
if (!pagetable_delete(a->pagetable, apage->blockno))
elog(ERROR, "hash table corrupted");
}
}
}
}
/*
* Process one page of a during an intersection op
*
* Returns true if apage is now empty and should be deleted from a
*/
static bool
tbm_intersect_page(TIDBitmap *a, PagetableEntry *apage, const TIDBitmap *b)
{
const PagetableEntry *bpage;
int wordnum;
if (apage->ischunk)
{
/* Scan each bit in chunk, try to clear */
bool candelete = true;
for (wordnum = 0; wordnum < WORDS_PER_CHUNK; wordnum++)
{
bitmapword w = apage->words[wordnum];
if (w != 0)
{
bitmapword neww = w;
BlockNumber pg;
int bitnum;
pg = apage->blockno + (wordnum * BITS_PER_BITMAPWORD);
bitnum = 0;
while (w != 0)
{
if (w & 1)
{
if (!tbm_page_is_lossy(b, pg) &&
tbm_find_pageentry(b, pg) == NULL)
{
/* Page is not in b at all, lose lossy bit */
neww &= ~((bitmapword) 1 << bitnum);
}
}
pg++;
bitnum++;
w >>= 1;
}
apage->words[wordnum] = neww;
if (neww != 0)
candelete = false;
}
}
return candelete;
}
else if (tbm_page_is_lossy(b, apage->blockno))
{
/*
* Some of the tuples in 'a' might not satisfy the quals for 'b', but
* because the page 'b' is lossy, we don't know which ones. Therefore
* we mark 'a' as requiring rechecks, to indicate that at most those
* tuples set in 'a' are matches.
*/
apage->recheck = true;
return false;
}
else
{
bool candelete = true;
bpage = tbm_find_pageentry(b, apage->blockno);
if (bpage != NULL)
{
/* Both pages are exact, merge at the bit level */
Assert(!bpage->ischunk);
for (wordnum = 0; wordnum < WORDS_PER_PAGE; wordnum++)
{
apage->words[wordnum] &= bpage->words[wordnum];
if (apage->words[wordnum] != 0)
candelete = false;
}
apage->recheck |= bpage->recheck;
}
/* If there is no matching b page, we can just delete the a page */
return candelete;
}
}
/*
* tbm_is_empty - is a TIDBitmap completely empty?
*/
bool
tbm_is_empty(const TIDBitmap *tbm)
{
return (tbm->nentries == 0);
}
/*
* tbm_begin_iterate - prepare to iterate through a TIDBitmap
*
* The TBMIterator struct is created in the caller's memory context.
* For a clean shutdown of the iteration, call tbm_end_iterate; but it's
* okay to just allow the memory context to be released, too. It is caller's
* responsibility not to touch the TBMIterator anymore once the TIDBitmap
* is freed.
*
* NB: after this is called, it is no longer allowed to modify the contents
* of the bitmap. However, you can call this multiple times to scan the
* contents repeatedly, including parallel scans.
*/
TBMIterator *
tbm_begin_iterate(TIDBitmap *tbm)
{
TBMIterator *iterator;
Assert(tbm->iterating != TBM_ITERATING_SHARED);
/*
* Create the TBMIterator struct, with enough trailing space to serve the
* needs of the TBMIterateResult sub-struct.
*/
iterator = (TBMIterator *) palloc(sizeof(TBMIterator) +
MAX_TUPLES_PER_PAGE * sizeof(OffsetNumber));
iterator->tbm = tbm;
/*
* Initialize iteration pointers.
*/
iterator->spageptr = 0;
iterator->schunkptr = 0;
iterator->schunkbit = 0;
/*
* If we have a hashtable, create and fill the sorted page lists, unless
* we already did that for a previous iterator. Note that the lists are
* attached to the bitmap not the iterator, so they can be used by more
* than one iterator.
*/
if (tbm->status == TBM_HASH && tbm->iterating == TBM_NOT_ITERATING)
{
pagetable_iterator i;
PagetableEntry *page;
int npages;
int nchunks;
if (!tbm->spages && tbm->npages > 0)
tbm->spages = (PagetableEntry **)
MemoryContextAlloc(tbm->mcxt,
tbm->npages * sizeof(PagetableEntry *));
if (!tbm->schunks && tbm->nchunks > 0)
tbm->schunks = (PagetableEntry **)
MemoryContextAlloc(tbm->mcxt,
tbm->nchunks * sizeof(PagetableEntry *));
npages = nchunks = 0;
pagetable_start_iterate(tbm->pagetable, &i);
while ((page = pagetable_iterate(tbm->pagetable, &i)) != NULL)
{
if (page->ischunk)
tbm->schunks[nchunks++] = page;
else
tbm->spages[npages++] = page;
}
Assert(npages == tbm->npages);
Assert(nchunks == tbm->nchunks);
if (npages > 1)
qsort(tbm->spages, npages, sizeof(PagetableEntry *),
tbm_comparator);
if (nchunks > 1)
qsort(tbm->schunks, nchunks, sizeof(PagetableEntry *),
tbm_comparator);
}
tbm->iterating = TBM_ITERATING_PRIVATE;
return iterator;
}
/*
* tbm_prepare_shared_iterate - prepare shared iteration state for a TIDBitmap.
*
* The necessary shared state will be allocated from the DSA passed to
* tbm_create, so that multiple processes can attach to it and iterate jointly.
*
* This will convert the pagetable hash into page and chunk array of the index
* into pagetable array.
*/
dsa_pointer
tbm_prepare_shared_iterate(TIDBitmap *tbm)
{
dsa_pointer dp;
TBMSharedIteratorState *istate;
PTEntryArray *ptbase = NULL;
PTIterationArray *ptpages = NULL;
PTIterationArray *ptchunks = NULL;
Assert(tbm->dsa != NULL);
Assert(tbm->iterating != TBM_ITERATING_PRIVATE);
/*
* Allocate TBMSharedIteratorState from DSA to hold the shared members and
* lock, this will also be used by multiple worker for shared iterate.
*/
dp = dsa_allocate0(tbm->dsa, sizeof(TBMSharedIteratorState));
istate = dsa_get_address(tbm->dsa, dp);
/*
* If we're not already iterating, create and fill the sorted page lists.
* (If we are, the sorted page lists are already stored in the TIDBitmap,
* and we can just reuse them.)
*/
if (tbm->iterating == TBM_NOT_ITERATING)
{
pagetable_iterator i;
PagetableEntry *page;
int idx;
int npages;
int nchunks;
/*
* Allocate the page and chunk array memory from the DSA to share
* across multiple processes.
*/
if (tbm->npages)
{
tbm->ptpages = dsa_allocate(tbm->dsa, sizeof(PTIterationArray) +
tbm->npages * sizeof(int));
ptpages = dsa_get_address(tbm->dsa, tbm->ptpages);
pg_atomic_init_u32(&ptpages->refcount, 0);
}
if (tbm->nchunks)
{
tbm->ptchunks = dsa_allocate(tbm->dsa, sizeof(PTIterationArray) +
tbm->nchunks * sizeof(int));
ptchunks = dsa_get_address(tbm->dsa, tbm->ptchunks);
pg_atomic_init_u32(&ptchunks->refcount, 0);
}
/*
* If TBM status is TBM_HASH then iterate over the pagetable and
* convert it to page and chunk arrays. But if it's in the
* TBM_ONE_PAGE mode then directly allocate the space for one entry
* from the DSA.
*/
npages = nchunks = 0;
if (tbm->status == TBM_HASH)
{
ptbase = dsa_get_address(tbm->dsa, tbm->dsapagetable);
pagetable_start_iterate(tbm->pagetable, &i);
while ((page = pagetable_iterate(tbm->pagetable, &i)) != NULL)
{
idx = page - ptbase->ptentry;
if (page->ischunk)
ptchunks->index[nchunks++] = idx;
else
ptpages->index[npages++] = idx;
}
Assert(npages == tbm->npages);
Assert(nchunks == tbm->nchunks);
}
else if (tbm->status == TBM_ONE_PAGE)
{
/*
* In one page mode allocate the space for one pagetable entry,
* initialize it, and directly store its index (i.e. 0) in the
* page array.
*/
tbm->dsapagetable = dsa_allocate(tbm->dsa, sizeof(PTEntryArray) +
sizeof(PagetableEntry));
ptbase = dsa_get_address(tbm->dsa, tbm->dsapagetable);
memcpy(ptbase->ptentry, &tbm->entry1, sizeof(PagetableEntry));
ptpages->index[0] = 0;
}
if (ptbase != NULL)
pg_atomic_init_u32(&ptbase->refcount, 0);
if (npages > 1)
qsort_arg((void *) (ptpages->index), npages, sizeof(int),
tbm_shared_comparator, (void *) ptbase->ptentry);
if (nchunks > 1)
qsort_arg((void *) (ptchunks->index), nchunks, sizeof(int),
tbm_shared_comparator, (void *) ptbase->ptentry);
}
/*
* Store the TBM members in the shared state so that we can share them
* across multiple processes.
*/
istate->nentries = tbm->nentries;
istate->maxentries = tbm->maxentries;
istate->npages = tbm->npages;
istate->nchunks = tbm->nchunks;
istate->pagetable = tbm->dsapagetable;
istate->spages = tbm->ptpages;
istate->schunks = tbm->ptchunks;
ptbase = dsa_get_address(tbm->dsa, tbm->dsapagetable);
ptpages = dsa_get_address(tbm->dsa, tbm->ptpages);
ptchunks = dsa_get_address(tbm->dsa, tbm->ptchunks);
/*
* For every shared iterator, referring to pagetable and iterator array,
* increase the refcount by 1 so that while freeing the shared iterator we
* don't free pagetable and iterator array until its refcount becomes 0.
*/
if (ptbase != NULL)
pg_atomic_add_fetch_u32(&ptbase->refcount, 1);
if (ptpages != NULL)
pg_atomic_add_fetch_u32(&ptpages->refcount, 1);
if (ptchunks != NULL)
pg_atomic_add_fetch_u32(&ptchunks->refcount, 1);
/* Initialize the iterator lock */
LWLockInitialize(&istate->lock, LWTRANCHE_SHARED_TIDBITMAP);
/* Initialize the shared iterator state */
istate->schunkbit = 0;
istate->schunkptr = 0;
istate->spageptr = 0;
tbm->iterating = TBM_ITERATING_SHARED;
return dp;
}
/*
* tbm_extract_page_tuple - extract the tuple offsets from a page
*
* The extracted offsets are stored into TBMIterateResult.
*/
static inline int
tbm_extract_page_tuple(PagetableEntry *page, TBMIterateResult *output)
{
int wordnum;
int ntuples = 0;
for (wordnum = 0; wordnum < WORDS_PER_PAGE; wordnum++)
{
bitmapword w = page->words[wordnum];
if (w != 0)
{
int off = wordnum * BITS_PER_BITMAPWORD + 1;
while (w != 0)
{
if (w & 1)
output->offsets[ntuples++] = (OffsetNumber) off;
off++;
w >>= 1;
}
}
}
return ntuples;
}
/*
* tbm_advance_schunkbit - Advance the schunkbit
*/
static inline void
tbm_advance_schunkbit(PagetableEntry *chunk, int *schunkbitp)
{
int schunkbit = *schunkbitp;
while (schunkbit < PAGES_PER_CHUNK)
{
int wordnum = WORDNUM(schunkbit);
int bitnum = BITNUM(schunkbit);
if ((chunk->words[wordnum] & ((bitmapword) 1 << bitnum)) != 0)
break;
schunkbit++;
}
*schunkbitp = schunkbit;
}
/*
* tbm_iterate - scan through next page of a TIDBitmap
*
* Returns a TBMIterateResult representing one page, or NULL if there are
* no more pages to scan. Pages are guaranteed to be delivered in numerical
* order. If result->ntuples < 0, then the bitmap is "lossy" and failed to
* remember the exact tuples to look at on this page --- the caller must
* examine all tuples on the page and check if they meet the intended
* condition. If result->recheck is true, only the indicated tuples need
* be examined, but the condition must be rechecked anyway. (For ease of
* testing, recheck is always set true when ntuples < 0.)
*/
TBMIterateResult *
tbm_iterate(TBMIterator *iterator)
{
TIDBitmap *tbm = iterator->tbm;
TBMIterateResult *output = &(iterator->output);
Assert(tbm->iterating == TBM_ITERATING_PRIVATE);
/*
* If lossy chunk pages remain, make sure we've advanced schunkptr/
* schunkbit to the next set bit.
*/
while (iterator->schunkptr < tbm->nchunks)
{
PagetableEntry *chunk = tbm->schunks[iterator->schunkptr];
int schunkbit = iterator->schunkbit;
tbm_advance_schunkbit(chunk, &schunkbit);
if (schunkbit < PAGES_PER_CHUNK)
{
iterator->schunkbit = schunkbit;
break;
}
/* advance to next chunk */
iterator->schunkptr++;
iterator->schunkbit = 0;
}
/*
* If both chunk and per-page data remain, must output the numerically
* earlier page.
*/
if (iterator->schunkptr < tbm->nchunks)
{
PagetableEntry *chunk = tbm->schunks[iterator->schunkptr];
BlockNumber chunk_blockno;
chunk_blockno = chunk->blockno + iterator->schunkbit;
if (iterator->spageptr >= tbm->npages ||
chunk_blockno < tbm->spages[iterator->spageptr]->blockno)
{
/* Return a lossy page indicator from the chunk */
output->blockno = chunk_blockno;
output->ntuples = -1;
output->recheck = true;
iterator->schunkbit++;
return output;
}
}
if (iterator->spageptr < tbm->npages)
{
PagetableEntry *page;
int ntuples;
/* In TBM_ONE_PAGE state, we don't allocate an spages[] array */
if (tbm->status == TBM_ONE_PAGE)
page = &tbm->entry1;
else
page = tbm->spages[iterator->spageptr];
/* scan bitmap to extract individual offset numbers */
ntuples = tbm_extract_page_tuple(page, output);
output->blockno = page->blockno;
output->ntuples = ntuples;
output->recheck = page->recheck;
iterator->spageptr++;
return output;
}
/* Nothing more in the bitmap */
return NULL;
}
/*
* tbm_shared_iterate - scan through next page of a TIDBitmap
*
* As above, but this will iterate using an iterator which is shared
* across multiple processes. We need to acquire the iterator LWLock,
* before accessing the shared members.
*/
TBMIterateResult *
tbm_shared_iterate(TBMSharedIterator *iterator)
{
TBMIterateResult *output = &iterator->output;
TBMSharedIteratorState *istate = iterator->state;
PagetableEntry *ptbase = NULL;
int *idxpages = NULL;
int *idxchunks = NULL;
if (iterator->ptbase != NULL)
ptbase = iterator->ptbase->ptentry;
if (iterator->ptpages != NULL)
idxpages = iterator->ptpages->index;
if (iterator->ptchunks != NULL)
idxchunks = iterator->ptchunks->index;
/* Acquire the LWLock before accessing the shared members */
LWLockAcquire(&istate->lock, LW_EXCLUSIVE);
/*
* If lossy chunk pages remain, make sure we've advanced schunkptr/
* schunkbit to the next set bit.
*/
while (istate->schunkptr < istate->nchunks)
{
PagetableEntry *chunk = &ptbase[idxchunks[istate->schunkptr]];
int schunkbit = istate->schunkbit;
tbm_advance_schunkbit(chunk, &schunkbit);
if (schunkbit < PAGES_PER_CHUNK)
{
istate->schunkbit = schunkbit;
break;
}
/* advance to next chunk */
istate->schunkptr++;
istate->schunkbit = 0;
}
/*
* If both chunk and per-page data remain, must output the numerically
* earlier page.
*/
if (istate->schunkptr < istate->nchunks)
{
PagetableEntry *chunk = &ptbase[idxchunks[istate->schunkptr]];
BlockNumber chunk_blockno;
chunk_blockno = chunk->blockno + istate->schunkbit;
if (istate->spageptr >= istate->npages ||
chunk_blockno < ptbase[idxpages[istate->spageptr]].blockno)
{
/* Return a lossy page indicator from the chunk */
output->blockno = chunk_blockno;
output->ntuples = -1;
output->recheck = true;
istate->schunkbit++;
LWLockRelease(&istate->lock);
return output;
}
}
if (istate->spageptr < istate->npages)
{
PagetableEntry *page = &ptbase[idxpages[istate->spageptr]];
int ntuples;
/* scan bitmap to extract individual offset numbers */
ntuples = tbm_extract_page_tuple(page, output);
output->blockno = page->blockno;
output->ntuples = ntuples;
output->recheck = page->recheck;
istate->spageptr++;
LWLockRelease(&istate->lock);
return output;
}
LWLockRelease(&istate->lock);
/* Nothing more in the bitmap */
return NULL;
}
/*
* tbm_end_iterate - finish an iteration over a TIDBitmap
*
* Currently this is just a pfree, but it might do more someday. (For
* instance, it could be useful to count open iterators and allow the
* bitmap to return to read/write status when there are no more iterators.)
*/
void
tbm_end_iterate(TBMIterator *iterator)
{
pfree(iterator);
}
/*
* tbm_end_shared_iterate - finish a shared iteration over a TIDBitmap
*
* This doesn't free any of the shared state associated with the iterator,
* just our backend-private state.
*/
void
tbm_end_shared_iterate(TBMSharedIterator *iterator)
{
pfree(iterator);
}
/*
* tbm_find_pageentry - find a PagetableEntry for the pageno
*
* Returns NULL if there is no non-lossy entry for the pageno.
*/
static const PagetableEntry *
tbm_find_pageentry(const TIDBitmap *tbm, BlockNumber pageno)
{
const PagetableEntry *page;
if (tbm->nentries == 0) /* in case pagetable doesn't exist */
return NULL;
if (tbm->status == TBM_ONE_PAGE)
{
page = &tbm->entry1;
if (page->blockno != pageno)
return NULL;
Assert(!page->ischunk);
return page;
}
page = pagetable_lookup(tbm->pagetable, pageno);
if (page == NULL)
return NULL;
if (page->ischunk)
return NULL; /* don't want a lossy chunk header */
return page;
}
/*
* tbm_get_pageentry - find or create a PagetableEntry for the pageno
*
* If new, the entry is marked as an exact (non-chunk) entry.
*
* This may cause the table to exceed the desired memory size. It is
* up to the caller to call tbm_lossify() at the next safe point if so.
*/
static PagetableEntry *
tbm_get_pageentry(TIDBitmap *tbm, BlockNumber pageno)
{
PagetableEntry *page;
bool found;
if (tbm->status == TBM_EMPTY)
{
/* Use the fixed slot */
page = &tbm->entry1;
found = false;
tbm->status = TBM_ONE_PAGE;
}
else
{
if (tbm->status == TBM_ONE_PAGE)
{
page = &tbm->entry1;
if (page->blockno == pageno)
return page;
/* Time to switch from one page to a hashtable */
tbm_create_pagetable(tbm);
}
/* Look up or create an entry */
page = pagetable_insert(tbm->pagetable, pageno, &found);
}
/* Initialize it if not present before */
if (!found)
{
char oldstatus = page->status;
MemSet(page, 0, sizeof(PagetableEntry));
page->status = oldstatus;
page->blockno = pageno;
/* must count it too */
tbm->nentries++;
tbm->npages++;
}
return page;
}
/*
* tbm_page_is_lossy - is the page marked as lossily stored?
*/
static bool
tbm_page_is_lossy(const TIDBitmap *tbm, BlockNumber pageno)
{
PagetableEntry *page;
BlockNumber chunk_pageno;
int bitno;
/* we can skip the lookup if there are no lossy chunks */
if (tbm->nchunks == 0)
return false;
Assert(tbm->status == TBM_HASH);
bitno = pageno % PAGES_PER_CHUNK;
chunk_pageno = pageno - bitno;
page = pagetable_lookup(tbm->pagetable, chunk_pageno);
if (page != NULL && page->ischunk)
{
int wordnum = WORDNUM(bitno);
int bitnum = BITNUM(bitno);
if ((page->words[wordnum] & ((bitmapword) 1 << bitnum)) != 0)
return true;
}
return false;
}
/*
* tbm_mark_page_lossy - mark the page number as lossily stored
*
* This may cause the table to exceed the desired memory size. It is
* up to the caller to call tbm_lossify() at the next safe point if so.
*/
static void
tbm_mark_page_lossy(TIDBitmap *tbm, BlockNumber pageno)
{
PagetableEntry *page;
bool found;
BlockNumber chunk_pageno;
int bitno;
int wordnum;
int bitnum;
/* We force the bitmap into hashtable mode whenever it's lossy */
if (tbm->status != TBM_HASH)
tbm_create_pagetable(tbm);
bitno = pageno % PAGES_PER_CHUNK;
chunk_pageno = pageno - bitno;
/*
* Remove any extant non-lossy entry for the page. If the page is its own
* chunk header, however, we skip this and handle the case below.
*/
if (bitno != 0)
{
if (pagetable_delete(tbm->pagetable, pageno))
{
/* It was present, so adjust counts */
tbm->nentries--;
tbm->npages--; /* assume it must have been non-lossy */
}
}
/* Look up or create entry for chunk-header page */
page = pagetable_insert(tbm->pagetable, chunk_pageno, &found);
/* Initialize it if not present before */
if (!found)
{
char oldstatus = page->status;
MemSet(page, 0, sizeof(PagetableEntry));
page->status = oldstatus;
page->blockno = chunk_pageno;
page->ischunk = true;
/* must count it too */
tbm->nentries++;
tbm->nchunks++;
}
else if (!page->ischunk)
{
char oldstatus = page->status;
/* chunk header page was formerly non-lossy, make it lossy */
MemSet(page, 0, sizeof(PagetableEntry));
page->status = oldstatus;
page->blockno = chunk_pageno;
page->ischunk = true;
/* we assume it had some tuple bit(s) set, so mark it lossy */
page->words[0] = ((bitmapword) 1 << 0);
/* adjust counts */
tbm->nchunks++;
tbm->npages--;
}
/* Now set the original target page's bit */
wordnum = WORDNUM(bitno);
bitnum = BITNUM(bitno);
page->words[wordnum] |= ((bitmapword) 1 << bitnum);
}
/*
* tbm_lossify - lose some information to get back under the memory limit
*/
static void
tbm_lossify(TIDBitmap *tbm)
{
pagetable_iterator i;
PagetableEntry *page;
/*
* XXX Really stupid implementation: this just lossifies pages in
* essentially random order. We should be paying some attention to the
* number of bits set in each page, instead.
*
* Since we are called as soon as nentries exceeds maxentries, we should
* push nentries down to significantly less than maxentries, or else we'll
* just end up doing this again very soon. We shoot for maxentries/2.
*/
Assert(tbm->iterating == TBM_NOT_ITERATING);
Assert(tbm->status == TBM_HASH);
pagetable_start_iterate_at(tbm->pagetable, &i, tbm->lossify_start);
while ((page = pagetable_iterate(tbm->pagetable, &i)) != NULL)
{
if (page->ischunk)
continue; /* already a chunk header */
/*
* If the page would become a chunk header, we won't save anything by
* converting it to lossy, so skip it.
*/
if ((page->blockno % PAGES_PER_CHUNK) == 0)
continue;
/* This does the dirty work ... */
tbm_mark_page_lossy(tbm, page->blockno);
if (tbm->nentries <= tbm->maxentries / 2)
{
/*
* We have made enough room. Remember where to start lossifying
* next round, so we evenly iterate over the hashtable.
*/
tbm->lossify_start = i.cur;
break;
}
/*
* Note: tbm_mark_page_lossy may have inserted a lossy chunk into the
* hashtable and may have deleted the non-lossy chunk. We can
* continue the same hash table scan, since failure to visit one
* element or visiting the newly inserted element, isn't fatal.
*/
}
/*
* With a big bitmap and small work_mem, it's possible that we cannot get
* under maxentries. Again, if that happens, we'd end up uselessly
* calling tbm_lossify over and over. To prevent this from becoming a
* performance sink, force maxentries up to at least double the current
* number of entries. (In essence, we're admitting inability to fit
* within work_mem when we do this.) Note that this test will not fire if
* we broke out of the loop early; and if we didn't, the current number of
* entries is simply not reducible any further.
*/
if (tbm->nentries > tbm->maxentries / 2)
tbm->maxentries = Min(tbm->nentries, (INT_MAX - 1) / 2) * 2;
}
/*
* qsort comparator to handle PagetableEntry pointers.
*/
static int
tbm_comparator(const void *left, const void *right)
{
BlockNumber l = (*((PagetableEntry *const *) left))->blockno;
BlockNumber r = (*((PagetableEntry *const *) right))->blockno;
if (l < r)
return -1;
else if (l > r)
return 1;
return 0;
}
/*
* As above, but this will get index into PagetableEntry array. Therefore,
* it needs to get actual PagetableEntry using the index before comparing the
* blockno.
*/
static int
tbm_shared_comparator(const void *left, const void *right, void *arg)
{
PagetableEntry *base = (PagetableEntry *) arg;
PagetableEntry *lpage = &base[*(int *) left];
PagetableEntry *rpage = &base[*(int *) right];
if (lpage->blockno < rpage->blockno)
return -1;
else if (lpage->blockno > rpage->blockno)
return 1;
return 0;
}
/*
* tbm_attach_shared_iterate
*
* Allocate a backend-private iterator and attach the shared iterator state
* to it so that multiple processed can iterate jointly.
*
* We also converts the DSA pointers to local pointers and store them into
* our private iterator.
*/
TBMSharedIterator *
tbm_attach_shared_iterate(dsa_area *dsa, dsa_pointer dp)
{
TBMSharedIterator *iterator;
TBMSharedIteratorState *istate;
/*
* Create the TBMSharedIterator struct, with enough trailing space to
* serve the needs of the TBMIterateResult sub-struct.
*/
iterator = (TBMSharedIterator *) palloc0(sizeof(TBMSharedIterator) +
MAX_TUPLES_PER_PAGE * sizeof(OffsetNumber));
istate = (TBMSharedIteratorState *) dsa_get_address(dsa, dp);
iterator->state = istate;
iterator->ptbase = dsa_get_address(dsa, istate->pagetable);
if (istate->npages)
iterator->ptpages = dsa_get_address(dsa, istate->spages);
if (istate->nchunks)
iterator->ptchunks = dsa_get_address(dsa, istate->schunks);
return iterator;
}
/*
* pagetable_allocate
*
* Callback function for allocating the memory for hashtable elements.
* Allocate memory for hashtable elements, using DSA if available.
*/
static inline void *
pagetable_allocate(pagetable_hash *pagetable, Size size)
{
TIDBitmap *tbm = (TIDBitmap *) pagetable->private_data;
PTEntryArray *ptbase;
if (tbm->dsa == NULL)
return MemoryContextAllocExtended(pagetable->ctx, size,
MCXT_ALLOC_HUGE | MCXT_ALLOC_ZERO);
/*
* Save the dsapagetable reference in dsapagetableold before allocating
* new memory so that pagetable_free can free the old entry.
*/
tbm->dsapagetableold = tbm->dsapagetable;
tbm->dsapagetable = dsa_allocate_extended(tbm->dsa,
sizeof(PTEntryArray) + size,
DSA_ALLOC_HUGE | DSA_ALLOC_ZERO);
ptbase = dsa_get_address(tbm->dsa, tbm->dsapagetable);
return ptbase->ptentry;
}
/*
* pagetable_free
*
* Callback function for freeing hash table elements.
*/
static inline void
pagetable_free(pagetable_hash *pagetable, void *pointer)
{
TIDBitmap *tbm = (TIDBitmap *) pagetable->private_data;
/* pfree the input pointer if DSA is not available */
if (tbm->dsa == NULL)
pfree(pointer);
else if (DsaPointerIsValid(tbm->dsapagetableold))
{
dsa_free(tbm->dsa, tbm->dsapagetableold);
tbm->dsapagetableold = InvalidDsaPointer;
}
}
/*
* tbm_calculate_entries
*
* Estimate number of hashtable entries we can have within maxbytes.
*/
long
tbm_calculate_entries(double maxbytes)
{
long nbuckets;
/*
* Estimate number of hashtable entries we can have within maxbytes. This
* estimates the hash cost as sizeof(PagetableEntry), which is good enough
* for our purpose. Also count an extra Pointer per entry for the arrays
* created during iteration readout.
*/
nbuckets = maxbytes /
(sizeof(PagetableEntry) + sizeof(Pointer) + sizeof(Pointer));
nbuckets = Min(nbuckets, INT_MAX - 1); /* safety limit */
nbuckets = Max(nbuckets, 16); /* sanity limit */
return nbuckets;
}
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