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Add functions to binaryheap for efficient key removal and update. 

Previously, binaryheap didn't support updating a key and removing a
node in an efficient way. For example, in order to remove a node from
the binaryheap, the caller had to pass the node's position within the
array that the binaryheap internally has. Removing a node from the
binaryheap is done in O(log n) but searching for the key's position is
done in O(n).

This commit adds a hash table to binaryheap in order to track the
position of each nodes in the binaryheap. That way, by using newly
added functions such as binaryheap_update_up() etc., both updating a
key and removing a node can be done in O(1) on an average and O(log n)
in worst case. This is known as the indexed binary heap. The caller
can specify to use the indexed binaryheap by passing indexed = true.

The current code does not use the new indexing logic, but it will be
used by an upcoming patch.

Reviewed-by: Vignesh C, Peter Smith, Hayato Kuroda, Ajin Cherian,
Tomas Vondra, Shubham Khanna
Discussion: https://postgr.es/m/CAD21AoDffo37RC-eUuyHJKVEr017V2YYDLyn1xF_00ofptWbkg%40mail.gmail.com
This commit is contained in:
Masahiko Sawada 2024-04-03 10:44:21 +09:00
parent bcb14f4abc
commit b840508644
10 changed files with 232 additions and 14 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

1
src/backend/executor/nodeGatherMerge.c
View File

@ -422,6 +422,7 @@ gather_merge_setup(GatherMergeState *gm_state)
/* Allocate the resources for the merge */
gm_state->gm_heap = binaryheap_allocate(nreaders + 1,
heap_compare_slots,
false,
gm_state);
}

2
src/backend/executor/nodeMergeAppend.c
View File

@ -125,7 +125,7 @@ ExecInitMergeAppend(MergeAppend *node, EState *estate, int eflags)
mergestate->ms_nplans = nplans;
mergestate->ms_slots = (TupleTableSlot **) palloc0(sizeof(TupleTableSlot *) * nplans);
mergestate->ms_heap = binaryheap_allocate(nplans, heap_compare_slots,
mergestate->ms_heap = binaryheap_allocate(nplans, heap_compare_slots, false,
mergestate);
/*

3
src/backend/postmaster/pgarch.c
View File

@ -254,7 +254,8 @@ PgArchiverMain(char *startup_data, size_t startup_data_len)
/* Initialize our max-heap for prioritizing files to archive. */
arch_files->arch_heap = binaryheap_allocate(NUM_FILES_PER_DIRECTORY_SCAN,
ready_file_comparator, NULL);
ready_file_comparator, false,
NULL);
/* Load the archive_library. */
LoadArchiveLibrary();

1
src/backend/replication/logical/reorderbuffer.c
View File

@ -1294,6 +1294,7 @@ ReorderBufferIterTXNInit(ReorderBuffer *rb, ReorderBufferTXN *txn,
/* allocate heap */
state->heap = binaryheap_allocate(state->nr_txns,
ReorderBufferIterCompare,
false,
state);
/* Now that the state fields are initialized, it is safe to return it. */

1
src/backend/storage/buffer/bufmgr.c
View File

@ -3014,6 +3014,7 @@ BufferSync(int flags)
*/
ts_heap = binaryheap_allocate(num_spaces,
ts_ckpt_progress_comparator,
false,
NULL);
for (i = 0; i < num_spaces; i++)

1
src/bin/pg_dump/pg_backup_archiver.c
View File

@ -4200,6 +4200,7 @@ restore_toc_entries_parallel(ArchiveHandle *AH, ParallelState *pstate,
/* Set up ready_heap with enough room for all known TocEntrys */
ready_heap = binaryheap_allocate(AH->tocCount,
TocEntrySizeCompareBinaryheap,
false,
NULL);
/*

2
src/bin/pg_dump/pg_dump_sort.c
View File

@ -405,7 +405,7 @@ TopoSort(DumpableObject **objs,
return true;
/* Create workspace for the above-described heap */
pendingHeap = binaryheap_allocate(numObjs, int_cmp, NULL);
pendingHeap = binaryheap_allocate(numObjs, int_cmp, false, NULL);
/*
* Scan the constraints, and for each item in the input, generate a count

198
src/common/binaryheap.c
View File

@ -22,8 +22,30 @@
#ifdef FRONTEND
#include "common/logging.h"
#endif
#include "common/hashfn.h"
#include "lib/binaryheap.h"
/*
* Define parameters for hash table code generation. The interface is *also*
* declared in binaryheap.h (to generate the types, which are externally
* visible).
*/
#define SH_PREFIX bh_nodeidx
#define SH_ELEMENT_TYPE bh_nodeidx_entry
#define SH_KEY_TYPE bh_node_type
#define SH_KEY key
#define SH_HASH_KEY(tb, key) \
hash_bytes((const unsigned char *) &key, sizeof(bh_node_type))
#define SH_EQUAL(tb, a, b) (memcmp(&a, &b, sizeof(bh_node_type)) == 0)
#define SH_SCOPE extern
#ifdef FRONTEND
#define SH_RAW_ALLOCATOR pg_malloc0
#endif
#define SH_STORE_HASH
#define SH_GET_HASH(tb, a) a->hash
#define SH_DEFINE
#include "lib/simplehash.h"
static void sift_down(binaryheap *heap, int node_off);
static void sift_up(binaryheap *heap, int node_off);
@ -34,9 +56,14 @@ static void sift_up(binaryheap *heap, int node_off);
* of nodes, and with the heap property defined by the given comparator
* function, which will be invoked with the additional argument specified by
* 'arg'.
*
* If 'indexed' is true, we create a hash table to track each node's
* index in the heap, enabling to perform some operations such as
* binaryheap_remove_node_ptr() etc.
*/
binaryheap *
binaryheap_allocate(int num_nodes, binaryheap_comparator compare, void *arg)
binaryheap_allocate(int num_nodes, binaryheap_comparator compare,
bool indexed, void *arg)
{
binaryheap *heap;
@ -48,6 +75,17 @@ binaryheap_allocate(int num_nodes, binaryheap_comparator compare, void *arg)
heap->bh_size = 0;
heap->bh_has_heap_property = true;
heap->bh_nodes = (bh_node_type *) palloc(sizeof(bh_node_type) * num_nodes);
heap->bh_nodeidx = NULL;
if (indexed)
{
#ifdef FRONTEND
heap->bh_nodeidx = bh_nodeidx_create(num_nodes, NULL);
#else
heap->bh_nodeidx = bh_nodeidx_create(CurrentMemoryContext, num_nodes,
NULL);
#endif
}
return heap;
}
@ -63,6 +101,9 @@ binaryheap_reset(binaryheap *heap)
{
heap->bh_size = 0;
heap->bh_has_heap_property = true;
if (binaryheap_indexed(heap))
bh_nodeidx_reset(heap->bh_nodeidx);
}
/*
@ -73,6 +114,9 @@ binaryheap_reset(binaryheap *heap)
void
binaryheap_free(binaryheap *heap)
{
if (binaryheap_indexed(heap))
bh_nodeidx_destroy(heap->bh_nodeidx);
pfree(heap->bh_nodes);
pfree(heap);
}
@ -115,6 +159,67 @@ enlarge_node_array(binaryheap *heap)
sizeof(bh_node_type) * heap->bh_space);
}
/*
* Set the given node at the 'index' and track it if required.
*
* Return true if the node's index is already tracked.
*/
static bool
set_node(binaryheap *heap, bh_node_type node, int index)
{
bool found = false;
/* Set the node to the nodes array */
heap->bh_nodes[index] = node;
if (binaryheap_indexed(heap))
{
bh_nodeidx_entry *ent;
/* Keep track of the node index */
ent = bh_nodeidx_insert(heap->bh_nodeidx, node, &found);
ent->index = index;
}
return found;
}
/*
* Remove the node's index from the hash table if the heap is indexed.
*/
static inline void
delete_nodeidx(binaryheap *heap, bh_node_type node)
{
if (binaryheap_indexed(heap))
bh_nodeidx_delete(heap->bh_nodeidx, node);
}
/*
* Replace the existing node at 'idx' with the given 'new_node'. Also
* update their positions accordingly. Note that we assume the new_node's
* position is already tracked if enabled, i.e. the new_node is already
* present in the heap.
*/
static void
replace_node(binaryheap *heap, int index, bh_node_type new_node)
{
bool found PG_USED_FOR_ASSERTS_ONLY;
/* Quick return if not necessary to move */
if (heap->bh_nodes[index] == new_node)
return;
/* Remove the overwritten node's index */
delete_nodeidx(heap, heap->bh_nodes[index]);
/*
* Replace it with the given new node. This node's position must also be
* tracked as we assume to replace the node with the existing node.
*/
found = set_node(heap, new_node, index);
Assert(!binaryheap_indexed(heap) || found);
}
/*
* binaryheap_add_unordered
*
@ -131,7 +236,7 @@ binaryheap_add_unordered(binaryheap *heap, bh_node_type d)
enlarge_node_array(heap);
heap->bh_has_heap_property = false;
heap->bh_nodes[heap->bh_size] = d;
set_node(heap, d, heap->bh_size);
heap->bh_size++;
}
@ -164,7 +269,7 @@ binaryheap_add(binaryheap *heap, bh_node_type d)
if (heap->bh_size >= heap->bh_space)
enlarge_node_array(heap);
heap->bh_nodes[heap->bh_size] = d;
set_node(heap, d, heap->bh_size);
heap->bh_size++;
sift_up(heap, heap->bh_size - 1);
}
@ -205,6 +310,8 @@ binaryheap_remove_first(binaryheap *heap)
if (heap->bh_size == 1)
{
heap->bh_size--;
delete_nodeidx(heap, result);
return result;
}
@ -212,7 +319,7 @@ binaryheap_remove_first(binaryheap *heap)
* Remove the last node, placing it in the vacated root entry, and sift
* the new root node down to its correct position.
*/
heap->bh_nodes[0] = heap->bh_nodes[--heap->bh_size];
replace_node(heap, 0, heap->bh_nodes[--heap->bh_size]);
sift_down(heap, 0);
return result;
@ -238,7 +345,7 @@ binaryheap_remove_node(binaryheap *heap, int n)
heap->bh_arg);
/* remove the last node, placing it in the vacated entry */
heap->bh_nodes[n] = heap->bh_nodes[heap->bh_size];
replace_node(heap, n, heap->bh_nodes[heap->bh_size]);
/* sift as needed to preserve the heap property */
if (cmp > 0)
@ -247,6 +354,77 @@ binaryheap_remove_node(binaryheap *heap, int n)
sift_down(heap, n);
}
/*
* binaryheap_remove_node_ptr
*
* Similar to binaryheap_remove_node() but removes the given node. The caller
* must ensure that the given node is in the heap. O(log n) worst case.
*
* This function can be used only if the heap is indexed.
*/
void
binaryheap_remove_node_ptr(binaryheap *heap, bh_node_type d)
{
bh_nodeidx_entry *ent;
Assert(!binaryheap_empty(heap) && heap->bh_has_heap_property);
Assert(binaryheap_indexed(heap));
ent = bh_nodeidx_lookup(heap->bh_nodeidx, d);
Assert(ent);
binaryheap_remove_node(heap, ent->index);
}
/*
* Workhorse for binaryheap_update_up and binaryheap_update_down.
*/
static void
resift_node(binaryheap *heap, bh_node_type node, bool sift_dir_up)
{
bh_nodeidx_entry *ent;
Assert(!binaryheap_empty(heap) && heap->bh_has_heap_property);
Assert(binaryheap_indexed(heap));
ent = bh_nodeidx_lookup(heap->bh_nodeidx, node);
Assert(ent);
Assert(ent->index >= 0 && ent->index < heap->bh_size);
if (sift_dir_up)
sift_up(heap, ent->index);
else
sift_down(heap, ent->index);
}
/*
* binaryheap_update_up
*
* Sift the given node up after the node's key is updated. The caller must
* ensure that the given node is in the heap. O(log n) worst case.
*
* This function can be used only if the heap is indexed.
*/
void
binaryheap_update_up(binaryheap *heap, bh_node_type d)
{
resift_node(heap, d, true);
}
/*
* binaryheap_update_down
*
* Sift the given node down after the node's key is updated. The caller must
* ensure that the given node is in the heap. O(log n) worst case.
*
* This function can be used only if the heap is indexed.
*/
void
binaryheap_update_down(binaryheap *heap, bh_node_type d)
{
resift_node(heap, d, false);
}
/*
* binaryheap_replace_first
*
@ -259,7 +437,7 @@ binaryheap_replace_first(binaryheap *heap, bh_node_type d)
{
Assert(!binaryheap_empty(heap) && heap->bh_has_heap_property);
heap->bh_nodes[0] = d;
replace_node(heap, 0, d);
if (heap->bh_size > 1)
sift_down(heap, 0);
@ -301,11 +479,11 @@ sift_up(binaryheap *heap, int node_off)
* Otherwise, swap the parent value with the hole, and go on to check
* the node's new parent.
*/
heap->bh_nodes[node_off] = parent_val;
set_node(heap, parent_val, node_off);
node_off = parent_off;
}
/* Re-fill the hole */
heap->bh_nodes[node_off] = node_val;
set_node(heap, node_val, node_off);
}
/*
@ -360,9 +538,9 @@ sift_down(binaryheap *heap, int node_off)
* Otherwise, swap the hole with the child that violates the heap
* property; then go on to check its children.
*/
heap->bh_nodes[node_off] = heap->bh_nodes[swap_off];
set_node(heap, heap->bh_nodes[swap_off], node_off);
node_off = swap_off;
}
/* Re-fill the hole */
heap->bh_nodes[node_off] = node_val;
set_node(heap, node_val, node_off);
}

36
src/include/lib/binaryheap.h
View File

@ -29,6 +29,29 @@ typedef Datum bh_node_type;
*/
typedef int (*binaryheap_comparator) (bh_node_type a, bh_node_type b, void *arg);
/*
* Struct for a hash table element to store the node's index in the bh_nodes
* array.
*/
typedef struct bh_nodeidx_entry
{
bh_node_type key;
int index; /* entry's index within the node array */
char status; /* hash status */
uint32 hash; /* hash values (cached) */
} bh_nodeidx_entry;
/* Define parameters necessary to generate the hash table interface. */
#define SH_PREFIX bh_nodeidx
#define SH_ELEMENT_TYPE bh_nodeidx_entry
#define SH_KEY_TYPE bh_node_type
#define SH_SCOPE extern
#ifdef FRONTEND
#define SH_RAW_ALLOCATOR pg_malloc0
#endif
#define SH_DECLARE
#include "lib/simplehash.h"
/*
* binaryheap
*
@ -47,11 +70,18 @@ typedef struct binaryheap
binaryheap_comparator bh_compare;
void *bh_arg;
bh_node_type *bh_nodes;
/*
* If bh_nodeidx is not NULL, the bh_nodeidx is used to track of each
* node's index in bh_nodes. This enables the caller to perform
* binaryheap_remove_node_ptr(), binaryheap_update_up/down in O(log n).
*/
bh_nodeidx_hash *bh_nodeidx;
} binaryheap;
extern binaryheap *binaryheap_allocate(int num_nodes,
binaryheap_comparator compare,
void *arg);
bool indexed, void *arg);
extern void binaryheap_reset(binaryheap *heap);
extern void binaryheap_free(binaryheap *heap);
extern void binaryheap_add_unordered(binaryheap *heap, bh_node_type d);
@ -60,10 +90,14 @@ extern void binaryheap_add(binaryheap *heap, bh_node_type d);
extern bh_node_type binaryheap_first(binaryheap *heap);
extern bh_node_type binaryheap_remove_first(binaryheap *heap);
extern void binaryheap_remove_node(binaryheap *heap, int n);
extern void binaryheap_remove_node_ptr(binaryheap *heap, bh_node_type d);
extern void binaryheap_replace_first(binaryheap *heap, bh_node_type d);
extern void binaryheap_update_up(binaryheap *heap, bh_node_type d);
extern void binaryheap_update_down(binaryheap *heap, bh_node_type d);
#define binaryheap_empty(h) ((h)->bh_size == 0)
#define binaryheap_size(h) ((h)->bh_size)
#define binaryheap_get_node(h, n) ((h)->bh_nodes[n])
#define binaryheap_indexed(h) ((h)->bh_nodeidx != NULL)
#endif /* BINARYHEAP_H */

1
src/tools/pgindent/typedefs.list
View File

@ -4091,3 +4091,4 @@ TidStoreIter
TidStoreIterResult
BlocktableEntry
ItemArray
bh_nodeidx_entry