rewriteheap.h File Reference

#include "access/htup.h"
#include "storage/itemptr.h"
#include "storage/relfilelocator.h"
#include "utils/relcache.h"

Include dependency graph for rewriteheap.h:

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Go to the source code of this file.

Data Structures
struct	LogicalRewriteMappingData

Macros
#define	LOGICAL_REWRITE_FORMAT   "map-%x-%x-%X_%X-%x-%x"

Typedefs
typedef struct RewriteStateData *	RewriteState
typedef struct LogicalRewriteMappingData	LogicalRewriteMappingData

Functions
RewriteState	begin_heap_rewrite (Relation old_heap, Relation new_heap, TransactionId oldest_xmin, TransactionId freeze_xid, MultiXactId cutoff_multi)
void	end_heap_rewrite (RewriteState state)
void	rewrite_heap_tuple (RewriteState state, HeapTuple old_tuple, HeapTuple new_tuple)
bool	rewrite_heap_dead_tuple (RewriteState state, HeapTuple old_tuple)
void	CheckPointLogicalRewriteHeap (void)

Macro Definition Documentation

LOGICAL_REWRITE_FORMAT

#define LOGICAL_REWRITE_FORMAT   "map-%x-%x-%X_%X-%x-%x"

Definition at line 54 of file rewriteheap.h.

Typedef Documentation

LogicalRewriteMappingData

typedef struct LogicalRewriteMappingData LogicalRewriteMappingData

RewriteState

typedef struct RewriteStateData* RewriteState

Definition at line 22 of file rewriteheap.h.

Function Documentation

begin_heap_rewrite()

RewriteState begin_heap_rewrite	(	Relation	old_heap,
		Relation	new_heap,
		TransactionId	oldest_xmin,
		TransactionId	freeze_xid,
		MultiXactId	cutoff_multi
	)

Definition at line 234 of file rewriteheap.c.

{
    RewriteState state;
    MemoryContext rw_cxt;
    MemoryContext old_cxt;
    HASHCTL     hash_ctl;
 
    /*
     * To ease cleanup, make a separate context that will contain the
     * RewriteState struct itself plus all subsidiary data.
     */
    rw_cxt = AllocSetContextCreate(CurrentMemoryContext,
                                   "Table rewrite",
                                   ALLOCSET_DEFAULT_SIZES);
    old_cxt = MemoryContextSwitchTo(rw_cxt);
 
    /* Create and fill in the state struct */
    state = palloc0_object(RewriteStateData);
 
    state->rs_old_rel = old_heap;
    state->rs_new_rel = new_heap;
    state->rs_buffer = NULL;
    /* new_heap needn't be empty, just locked */
    state->rs_blockno = RelationGetNumberOfBlocks(new_heap);
    state->rs_oldest_xmin = oldest_xmin;
    state->rs_freeze_xid = freeze_xid;
    state->rs_cutoff_multi = cutoff_multi;
    state->rs_cxt = rw_cxt;
    state->rs_bulkstate = smgr_bulk_start_rel(new_heap, MAIN_FORKNUM);
 
    /* Initialize hash tables used to track update chains */
    hash_ctl.keysize = sizeof(TidHashKey);
    hash_ctl.entrysize = sizeof(UnresolvedTupData);
    hash_ctl.hcxt = state->rs_cxt;
 
    state->rs_unresolved_tups =
        hash_create("Rewrite / Unresolved ctids",
                    128,        /* arbitrary initial size */
                    &hash_ctl,
                    HASH_ELEM | HASH_BLOBS | HASH_CONTEXT);
 
    hash_ctl.entrysize = sizeof(OldToNewMappingData);
 
    state->rs_old_new_tid_map =
        hash_create("Rewrite / Old to new tid map",
                    128,        /* arbitrary initial size */
                    &hash_ctl,
                    HASH_ELEM | HASH_BLOBS | HASH_CONTEXT);
 
    MemoryContextSwitchTo(old_cxt);
 
    logical_begin_heap_rewrite(state);
 
    return state;
}

References ALLOCSET_DEFAULT_SIZES, AllocSetContextCreate, CurrentMemoryContext, HASHCTL::entrysize, HASH_BLOBS, HASH_CONTEXT, hash_create(), HASH_ELEM, HASHCTL::hcxt, HASHCTL::keysize, logical_begin_heap_rewrite(), MAIN_FORKNUM, MemoryContextSwitchTo(), palloc0_object, RelationGetNumberOfBlocks, and smgr_bulk_start_rel().

Referenced by heapam_relation_copy_for_cluster().

CheckPointLogicalRewriteHeap()

void CheckPointLogicalRewriteHeap

(

void

)

Definition at line 1157 of file rewriteheap.c.

{
    XLogRecPtr  cutoff;
    XLogRecPtr  redo;
    DIR        *mappings_dir;
    struct dirent *mapping_de;
    char        path[MAXPGPATH + sizeof(PG_LOGICAL_MAPPINGS_DIR)];
 
    /*
     * We start of with a minimum of the last redo pointer. No new decoding
     * slot will start before that, so that's a safe upper bound for removal.
     */
    redo = GetRedoRecPtr();
 
    /* now check for the restart ptrs from existing slots */
    cutoff = ReplicationSlotsComputeLogicalRestartLSN();
 
    /* don't start earlier than the restart lsn */
    if (XLogRecPtrIsValid(cutoff) && redo < cutoff)
        cutoff = redo;
 
    mappings_dir = AllocateDir(PG_LOGICAL_MAPPINGS_DIR);
    while ((mapping_de = ReadDir(mappings_dir, PG_LOGICAL_MAPPINGS_DIR)) != NULL)
    {
        Oid         dboid;
        Oid         relid;
        XLogRecPtr  lsn;
        TransactionId rewrite_xid;
        TransactionId create_xid;
        uint32      hi,
                    lo;
        PGFileType  de_type;
 
        if (strcmp(mapping_de->d_name, ".") == 0 ||
            strcmp(mapping_de->d_name, "..") == 0)
            continue;
 
        snprintf(path, sizeof(path), "%s/%s", PG_LOGICAL_MAPPINGS_DIR, mapping_de->d_name);
        de_type = get_dirent_type(path, mapping_de, false, DEBUG1);
 
        if (de_type != PGFILETYPE_ERROR && de_type != PGFILETYPE_REG)
            continue;
 
        /* Skip over files that cannot be ours. */
        if (strncmp(mapping_de->d_name, "map-", 4) != 0)
            continue;
 
        if (sscanf(mapping_de->d_name, LOGICAL_REWRITE_FORMAT,
                   &dboid, &relid, &hi, &lo, &rewrite_xid, &create_xid) != 6)
            elog(ERROR, "could not parse filename \"%s\"", mapping_de->d_name);
 
        lsn = ((uint64) hi) << 32 | lo;
 
        if (lsn < cutoff || !XLogRecPtrIsValid(cutoff))
        {
            elog(DEBUG1, "removing logical rewrite file \"%s\"", path);
            if (unlink(path) < 0)
                ereport(ERROR,
                        (errcode_for_file_access(),
                         errmsg("could not remove file \"%s\": %m", path)));
        }
        else
        {
            /* on some operating systems fsyncing a file requires O_RDWR */
            int         fd = OpenTransientFile(path, O_RDWR | PG_BINARY);
 
            /*
             * The file cannot vanish due to concurrency since this function
             * is the only one removing logical mappings and only one
             * checkpoint can be in progress at a time.
             */
            if (fd < 0)
                ereport(ERROR,
                        (errcode_for_file_access(),
                         errmsg("could not open file \"%s\": %m", path)));
 
            /*
             * We could try to avoid fsyncing files that either haven't
             * changed or have only been created since the checkpoint's start,
             * but it's currently not deemed worth the effort.
             */
            pgstat_report_wait_start(WAIT_EVENT_LOGICAL_REWRITE_CHECKPOINT_SYNC);
            if (pg_fsync(fd) != 0)
                ereport(data_sync_elevel(ERROR),
                        (errcode_for_file_access(),
                         errmsg("could not fsync file \"%s\": %m", path)));
            pgstat_report_wait_end();
 
            if (CloseTransientFile(fd) != 0)
                ereport(ERROR,
                        (errcode_for_file_access(),
                         errmsg("could not close file \"%s\": %m", path)));
        }
    }
    FreeDir(mappings_dir);
 
    /* persist directory entries to disk */
    fsync_fname(PG_LOGICAL_MAPPINGS_DIR, true);
}

References AllocateDir(), CloseTransientFile(), dirent::d_name, data_sync_elevel(), DEBUG1, elog, ereport, errcode_for_file_access(), errmsg(), ERROR, fd(), FreeDir(), fsync_fname(), get_dirent_type(), GetRedoRecPtr(), LOGICAL_REWRITE_FORMAT, MAXPGPATH, OpenTransientFile(), PG_BINARY, pg_fsync(), PG_LOGICAL_MAPPINGS_DIR, PGFILETYPE_ERROR, PGFILETYPE_REG, pgstat_report_wait_end(), pgstat_report_wait_start(), ReadDir(), ReplicationSlotsComputeLogicalRestartLSN(), snprintf, and XLogRecPtrIsValid.

Referenced by CheckPointGuts().

end_heap_rewrite()

void end_heap_rewrite

(

RewriteState

state

)

Definition at line 297 of file rewriteheap.c.

{
    HASH_SEQ_STATUS seq_status;
    UnresolvedTup unresolved;
 
    /*
     * Write any remaining tuples in the UnresolvedTups table. If we have any
     * left, they should in fact be dead, but let's err on the safe side.
     */
    hash_seq_init(&seq_status, state->rs_unresolved_tups);
 
    while ((unresolved = hash_seq_search(&seq_status)) != NULL)
    {
        ItemPointerSetInvalid(&unresolved->tuple->t_data->t_ctid);
        raw_heap_insert(state, unresolved->tuple);
    }
 
    /* Write the last page, if any */
    if (state->rs_buffer)
    {
        smgr_bulk_write(state->rs_bulkstate, state->rs_blockno, state->rs_buffer, true);
        state->rs_buffer = NULL;
    }
 
    smgr_bulk_finish(state->rs_bulkstate);
 
    logical_end_heap_rewrite(state);
 
    /* Deleting the context frees everything */
    MemoryContextDelete(state->rs_cxt);
}

References hash_seq_init(), hash_seq_search(), ItemPointerSetInvalid(), logical_end_heap_rewrite(), MemoryContextDelete(), raw_heap_insert(), smgr_bulk_finish(), smgr_bulk_write(), HeapTupleHeaderData::t_ctid, HeapTupleData::t_data, and UnresolvedTupData::tuple.

Referenced by heapam_relation_copy_for_cluster().

rewrite_heap_dead_tuple()

bool rewrite_heap_dead_tuple	(	RewriteState	state,
		HeapTuple	old_tuple
	)

Definition at line 546 of file rewriteheap.c.

{
    /*
     * If we have already seen an earlier tuple in the update chain that
     * points to this tuple, let's forget about that earlier tuple. It's in
     * fact dead as well, our simple xmax < OldestXmin test in
     * HeapTupleSatisfiesVacuum just wasn't enough to detect it. It happens
     * when xmin of a tuple is greater than xmax, which sounds
     * counter-intuitive but is perfectly valid.
     *
     * We don't bother to try to detect the situation the other way round,
     * when we encounter the dead tuple first and then the recently dead one
     * that points to it. If that happens, we'll have some unmatched entries
     * in the UnresolvedTups hash table at the end. That can happen anyway,
     * because a vacuum might have removed the dead tuple in the chain before
     * us.
     */
    UnresolvedTup unresolved;
    TidHashKey  hashkey;
    bool        found;
 
    memset(&hashkey, 0, sizeof(hashkey));
    hashkey.xmin = HeapTupleHeaderGetXmin(old_tuple->t_data);
    hashkey.tid = old_tuple->t_self;
 
    unresolved = hash_search(state->rs_unresolved_tups, &hashkey,
                             HASH_FIND, NULL);
 
    if (unresolved != NULL)
    {
        /* Need to free the contained tuple as well as the hashtable entry */
        heap_freetuple(unresolved->tuple);
        hash_search(state->rs_unresolved_tups, &hashkey,
                    HASH_REMOVE, &found);
        Assert(found);
        return true;
    }
 
    return false;
}

References Assert(), HASH_FIND, HASH_REMOVE, hash_search(), heap_freetuple(), HeapTupleHeaderGetXmin(), HeapTupleData::t_data, HeapTupleData::t_self, TidHashKey::tid, UnresolvedTupData::tuple, and TidHashKey::xmin.

Referenced by heapam_relation_copy_for_cluster().

rewrite_heap_tuple()

void rewrite_heap_tuple	(	RewriteState	state,
		HeapTuple	old_tuple,
		HeapTuple	new_tuple
	)

Definition at line 341 of file rewriteheap.c.

{
    MemoryContext old_cxt;
    ItemPointerData old_tid;
    TidHashKey  hashkey;
    bool        found;
    bool        free_new;
 
    old_cxt = MemoryContextSwitchTo(state->rs_cxt);
 
    /*
     * Copy the original tuple's visibility information into new_tuple.
     *
     * XXX we might later need to copy some t_infomask2 bits, too? Right now,
     * we intentionally clear the HOT status bits.
     */
    memcpy(&new_tuple->t_data->t_choice.t_heap,
           &old_tuple->t_data->t_choice.t_heap,
           sizeof(HeapTupleFields));
 
    new_tuple->t_data->t_infomask &= ~HEAP_XACT_MASK;
    new_tuple->t_data->t_infomask2 &= ~HEAP2_XACT_MASK;
    new_tuple->t_data->t_infomask |=
        old_tuple->t_data->t_infomask & HEAP_XACT_MASK;
 
    /*
     * While we have our hands on the tuple, we may as well freeze any
     * eligible xmin or xmax, so that future VACUUM effort can be saved.
     */
    heap_freeze_tuple(new_tuple->t_data,
                      state->rs_old_rel->rd_rel->relfrozenxid,
                      state->rs_old_rel->rd_rel->relminmxid,
                      state->rs_freeze_xid,
                      state->rs_cutoff_multi);
 
    /*
     * Invalid ctid means that ctid should point to the tuple itself. We'll
     * override it later if the tuple is part of an update chain.
     */
    ItemPointerSetInvalid(&new_tuple->t_data->t_ctid);
 
    /*
     * If the tuple has been updated, check the old-to-new mapping hash table.
     *
     * Note that this check relies on the HeapTupleSatisfiesVacuum() in
     * heapam_relation_copy_for_cluster() to have set hint bits.
     */
    if (!((old_tuple->t_data->t_infomask & HEAP_XMAX_INVALID) ||
          HeapTupleHeaderIsOnlyLocked(old_tuple->t_data)) &&
        !HeapTupleHeaderIndicatesMovedPartitions(old_tuple->t_data) &&
        !(ItemPointerEquals(&(old_tuple->t_self),
                            &(old_tuple->t_data->t_ctid))))
    {
        OldToNewMapping mapping;
 
        memset(&hashkey, 0, sizeof(hashkey));
        hashkey.xmin = HeapTupleHeaderGetUpdateXid(old_tuple->t_data);
        hashkey.tid = old_tuple->t_data->t_ctid;
 
        mapping = (OldToNewMapping)
            hash_search(state->rs_old_new_tid_map, &hashkey,
                        HASH_FIND, NULL);
 
        if (mapping != NULL)
        {
            /*
             * We've already copied the tuple that t_ctid points to, so we can
             * set the ctid of this tuple to point to the new location, and
             * insert it right away.
             */
            new_tuple->t_data->t_ctid = mapping->new_tid;
 
            /* We don't need the mapping entry anymore */
            hash_search(state->rs_old_new_tid_map, &hashkey,
                        HASH_REMOVE, &found);
            Assert(found);
        }
        else
        {
            /*
             * We haven't seen the tuple t_ctid points to yet. Stash this
             * tuple into unresolved_tups to be written later.
             */
            UnresolvedTup unresolved;
 
            unresolved = hash_search(state->rs_unresolved_tups, &hashkey,
                                     HASH_ENTER, &found);
            Assert(!found);
 
            unresolved->old_tid = old_tuple->t_self;
            unresolved->tuple = heap_copytuple(new_tuple);
 
            /*
             * We can't do anything more now, since we don't know where the
             * tuple will be written.
             */
            MemoryContextSwitchTo(old_cxt);
            return;
        }
    }
 
    /*
     * Now we will write the tuple, and then check to see if it is the B tuple
     * in any new or known pair.  When we resolve a known pair, we will be
     * able to write that pair's A tuple, and then we have to check if it
     * resolves some other pair.  Hence, we need a loop here.
     */
    old_tid = old_tuple->t_self;
    free_new = false;
 
    for (;;)
    {
        ItemPointerData new_tid;
 
        /* Insert the tuple and find out where it's put in new_heap */
        raw_heap_insert(state, new_tuple);
        new_tid = new_tuple->t_self;
 
        logical_rewrite_heap_tuple(state, old_tid, new_tuple);
 
        /*
         * If the tuple is the updated version of a row, and the prior version
         * wouldn't be DEAD yet, then we need to either resolve the prior
         * version (if it's waiting in rs_unresolved_tups), or make an entry
         * in rs_old_new_tid_map (so we can resolve it when we do see it). The
         * previous tuple's xmax would equal this one's xmin, so it's
         * RECENTLY_DEAD if and only if the xmin is not before OldestXmin.
         */
        if ((new_tuple->t_data->t_infomask & HEAP_UPDATED) &&
            !TransactionIdPrecedes(HeapTupleHeaderGetXmin(new_tuple->t_data),
                                   state->rs_oldest_xmin))
        {
            /*
             * Okay, this is B in an update pair.  See if we've seen A.
             */
            UnresolvedTup unresolved;
 
            memset(&hashkey, 0, sizeof(hashkey));
            hashkey.xmin = HeapTupleHeaderGetXmin(new_tuple->t_data);
            hashkey.tid = old_tid;
 
            unresolved = hash_search(state->rs_unresolved_tups, &hashkey,
                                     HASH_FIND, NULL);
 
            if (unresolved != NULL)
            {
                /*
                 * We have seen and memorized the previous tuple already. Now
                 * that we know where we inserted the tuple its t_ctid points
                 * to, fix its t_ctid and insert it to the new heap.
                 */
                if (free_new)
                    heap_freetuple(new_tuple);
                new_tuple = unresolved->tuple;
                free_new = true;
                old_tid = unresolved->old_tid;
                new_tuple->t_data->t_ctid = new_tid;
 
                /*
                 * We don't need the hash entry anymore, but don't free its
                 * tuple just yet.
                 */
                hash_search(state->rs_unresolved_tups, &hashkey,
                            HASH_REMOVE, &found);
                Assert(found);
 
                /* loop back to insert the previous tuple in the chain */
                continue;
            }
            else
            {
                /*
                 * Remember the new tid of this tuple. We'll use it to set the
                 * ctid when we find the previous tuple in the chain.
                 */
                OldToNewMapping mapping;
 
                mapping = hash_search(state->rs_old_new_tid_map, &hashkey,
                                      HASH_ENTER, &found);
                Assert(!found);
 
                mapping->new_tid = new_tid;
            }
        }
 
        /* Done with this (chain of) tuples, for now */
        if (free_new)
            heap_freetuple(new_tuple);
        break;
    }
 
    MemoryContextSwitchTo(old_cxt);
}

References Assert(), HASH_ENTER, HASH_FIND, HASH_REMOVE, hash_search(), heap_copytuple(), heap_freetuple(), heap_freeze_tuple(), HEAP_UPDATED, HEAP_XACT_MASK, HEAP_XMAX_INVALID, HeapTupleHeaderGetUpdateXid(), HeapTupleHeaderGetXmin(), HeapTupleHeaderIndicatesMovedPartitions(), HeapTupleHeaderIsOnlyLocked(), ItemPointerEquals(), ItemPointerSetInvalid(), logical_rewrite_heap_tuple(), MemoryContextSwitchTo(), OldToNewMappingData::new_tid, UnresolvedTupData::old_tid, raw_heap_insert(), HeapTupleHeaderData::t_choice, HeapTupleHeaderData::t_ctid, HeapTupleData::t_data, HeapTupleHeaderData::t_heap, HeapTupleHeaderData::t_infomask, HeapTupleHeaderData::t_infomask2, HeapTupleData::t_self, TidHashKey::tid, TransactionIdPrecedes(), UnresolvedTupData::tuple, and TidHashKey::xmin.

Referenced by reform_and_rewrite_tuple().