mirror of
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1be5051923
FossilOrigin-Name: cf6da4a52f7f9047e653ef2972e4c0910b29d7182d789a9e30225dc1849e8779
2466 lines
72 KiB
C
2466 lines
72 KiB
C
/*
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** 2011-08-18
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**
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** The author disclaims copyright to this source code. In place of
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** a legal notice, here is a blessing:
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**
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** May you do good and not evil.
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** May you find forgiveness for yourself and forgive others.
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** May you share freely, never taking more than you give.
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**
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*************************************************************************
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**
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** This file contains the implementation of an in-memory tree structure.
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**
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** Technically the tree is a B-tree of order 4 (in the Knuth sense - each
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** node may have up to 4 children). Keys are stored within B-tree nodes by
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** reference. This may be slightly slower than a conventional red-black
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** tree, but it is simpler. It is also an easier structure to modify to
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** create a version that supports nested transaction rollback.
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**
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** This tree does not currently support a delete operation. One is not
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** required. When LSM deletes a key from a database, it inserts a DELETE
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** marker into the data structure. As a result, although the value associated
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** with a key stored in the in-memory tree structure may be modified, no
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** keys are ever removed.
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*/
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/*
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** MVCC NOTES
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**
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** The in-memory tree structure supports SQLite-style MVCC. This means
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** that while one client is writing to the tree structure, other clients
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** may still be querying an older snapshot of the tree.
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**
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** One way to implement this is to use an append-only b-tree. In this
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** case instead of modifying nodes in-place, a copy of the node is made
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** and the required modifications made to the copy. The parent of the
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** node is then modified (to update the pointer so that it points to
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** the new copy), which causes a copy of the parent to be made, and so on.
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** This means that each time the tree is written to a new root node is
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** created. A snapshot is identified by the root node that it uses.
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**
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** The problem with the above is that each time the tree is written to,
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** a copy of the node structure modified and all of its ancestor nodes
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** is made. This may prove excessive with large tree structures.
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**
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** To reduce this overhead, the data structure used for a tree node is
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** designed so that it may be edited in place exactly once without
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** affecting existing users. In other words, the node structure is capable
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** of storing two separate versions of the node at the same time.
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** When a node is to be edited, if the node structure already contains
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** two versions, a copy is made as in the append-only approach. Or, if
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** it only contains a single version, it is edited in place.
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**
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** This reduces the overhead so that, roughly, one new node structure
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** must be allocated for each write (on top of those allocations that
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** would have been required by a non-MVCC tree). Logic: Assume that at
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** any time, 50% of nodes in the tree already contain 2 versions. When
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** a new entry is written to a node, there is a 50% chance that a copy
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** of the node will be required. And a 25% chance that a copy of its
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** parent is required. And so on.
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**
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** ROLLBACK
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**
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** The in-memory tree also supports transaction and sub-transaction
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** rollback. In order to rollback to point in time X, the following is
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** necessary:
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**
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** 1. All memory allocated since X must be freed, and
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** 2. All "v2" data adding to nodes that existed at X should be zeroed.
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** 3. The root node must be restored to its X value.
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**
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** The Mempool object used to allocate memory for the tree supports
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** operation (1) - see the lsmPoolMark() and lsmPoolRevert() functions.
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**
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** To support (2), all nodes that have v2 data are part of a singly linked
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** list, sorted by the age of the v2 data (nodes that have had data added
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** most recently are at the end of the list). So to zero all v2 data added
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** since X, the linked list is traversed from the first node added following
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** X onwards.
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**
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*/
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#ifndef _LSM_INT_H
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# include "lsmInt.h"
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#endif
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#include <string.h>
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#define MAX_DEPTH 32
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typedef struct TreeKey TreeKey;
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typedef struct TreeNode TreeNode;
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typedef struct TreeLeaf TreeLeaf;
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typedef struct NodeVersion NodeVersion;
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struct TreeOld {
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u32 iShmid; /* Last shared-memory chunk in use by old */
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u32 iRoot; /* Offset of root node in shm file */
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u32 nHeight; /* Height of tree structure */
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};
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#if 0
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/*
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** assert() that a TreeKey.flags value is sane. Usage:
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**
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** assert( lsmAssertFlagsOk(pTreeKey->flags) );
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*/
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static int lsmAssertFlagsOk(u8 keyflags){
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/* At least one flag must be set. Otherwise, what is this key doing? */
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assert( keyflags!=0 );
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/* The POINT_DELETE and INSERT flags cannot both be set. */
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assert( (keyflags & LSM_POINT_DELETE)==0 || (keyflags & LSM_INSERT)==0 );
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/* If both the START_DELETE and END_DELETE flags are set, then the INSERT
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** flag must also be set. In other words - the three DELETE flags cannot
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** all be set */
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assert( (keyflags & LSM_END_DELETE)==0
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|| (keyflags & LSM_START_DELETE)==0
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|| (keyflags & LSM_POINT_DELETE)==0
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);
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return 1;
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}
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#endif
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static int assert_delete_ranges_match(lsm_db *);
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static int treeCountEntries(lsm_db *db);
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/*
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** Container for a key-value pair. Within the *-shm file, each key/value
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** pair is stored in a single allocation (which may not actually be
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** contiguous in memory). Layout is the TreeKey structure, followed by
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** the nKey bytes of key blob, followed by the nValue bytes of value blob
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** (if nValue is non-negative).
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*/
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struct TreeKey {
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int nKey; /* Size of pKey in bytes */
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int nValue; /* Size of pValue. Or negative. */
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u8 flags; /* Various LSM_XXX flags */
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};
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#define TKV_KEY(p) ((void *)&(p)[1])
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#define TKV_VAL(p) ((void *)(((u8 *)&(p)[1]) + (p)->nKey))
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/*
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** A single tree node. A node structure may contain up to 3 key/value
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** pairs. Internal (non-leaf) nodes have up to 4 children.
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**
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** TODO: Update the format of this to be more compact. Get it working
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** first though...
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*/
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struct TreeNode {
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u32 aiKeyPtr[3]; /* Array of pointers to TreeKey objects */
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/* The following fields are present for interior nodes only, not leaves. */
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u32 aiChildPtr[4]; /* Array of pointers to child nodes */
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/* The extra child pointer slot. */
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u32 iV2; /* Transaction number of v2 */
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u8 iV2Child; /* apChild[] entry replaced by pV2Ptr */
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u32 iV2Ptr; /* Substitute pointer */
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};
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struct TreeLeaf {
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u32 aiKeyPtr[3]; /* Array of pointers to TreeKey objects */
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};
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typedef struct TreeBlob TreeBlob;
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struct TreeBlob {
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int n;
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u8 *a;
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};
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/*
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** Cursor for searching a tree structure.
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**
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** If a cursor does not point to any element (a.k.a. EOF), then the
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** TreeCursor.iNode variable is set to a negative value. Otherwise, the
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** cursor currently points to key aiCell[iNode] on node apTreeNode[iNode].
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**
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** Entries in the apTreeNode[] and aiCell[] arrays contain the node and
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** index of the TreeNode.apChild[] pointer followed to descend to the
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** current element. Hence apTreeNode[0] always contains the root node of
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** the tree.
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*/
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struct TreeCursor {
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lsm_db *pDb; /* Database handle for this cursor */
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TreeRoot *pRoot; /* Root node and height of tree to access */
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int iNode; /* Cursor points at apTreeNode[iNode] */
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TreeNode *apTreeNode[MAX_DEPTH];/* Current position in tree */
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u8 aiCell[MAX_DEPTH]; /* Current position in tree */
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TreeKey *pSave; /* Saved key */
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TreeBlob blob; /* Dynamic storage for a key */
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};
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/*
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** A value guaranteed to be larger than the largest possible transaction
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** id (TreeHeader.iTransId).
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*/
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#define WORKING_VERSION (1<<30)
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static int tblobGrow(lsm_db *pDb, TreeBlob *p, int n, int *pRc){
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if( n>p->n ){
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lsmFree(pDb->pEnv, p->a);
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p->a = lsmMallocRc(pDb->pEnv, n, pRc);
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p->n = n;
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}
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return (p->a==0);
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}
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static void tblobFree(lsm_db *pDb, TreeBlob *p){
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lsmFree(pDb->pEnv, p->a);
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}
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/***********************************************************************
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** Start of IntArray methods. */
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/*
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** Append value iVal to the contents of IntArray *p. Return LSM_OK if
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** successful, or LSM_NOMEM if an OOM condition is encountered.
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*/
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static int intArrayAppend(lsm_env *pEnv, IntArray *p, u32 iVal){
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assert( p->nArray<=p->nAlloc );
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if( p->nArray>=p->nAlloc ){
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u32 *aNew;
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int nNew = p->nArray ? p->nArray*2 : 128;
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aNew = lsmRealloc(pEnv, p->aArray, nNew*sizeof(u32));
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if( !aNew ) return LSM_NOMEM_BKPT;
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p->aArray = aNew;
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p->nAlloc = nNew;
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}
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p->aArray[p->nArray++] = iVal;
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return LSM_OK;
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}
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/*
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** Zero the IntArray object.
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*/
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static void intArrayFree(lsm_env *pEnv, IntArray *p){
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p->nArray = 0;
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}
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/*
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** Return the number of entries currently in the int-array object.
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*/
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static int intArraySize(IntArray *p){
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return p->nArray;
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}
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/*
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** Return a copy of the iIdx'th entry in the int-array.
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*/
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static u32 intArrayEntry(IntArray *p, int iIdx){
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return p->aArray[iIdx];
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}
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/*
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** Truncate the int-array so that all but the first nVal values are
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** discarded.
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*/
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static void intArrayTruncate(IntArray *p, int nVal){
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p->nArray = nVal;
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}
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/* End of IntArray methods.
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***********************************************************************/
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static int treeKeycmp(void *p1, int n1, void *p2, int n2){
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int res;
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res = memcmp(p1, p2, LSM_MIN(n1, n2));
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if( res==0 ) res = (n1-n2);
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return res;
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}
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/*
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** The pointer passed as the first argument points to an interior node,
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** not a leaf. This function returns the offset of the iCell'th child
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** sub-tree of the node.
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*/
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static u32 getChildPtr(TreeNode *p, int iVersion, int iCell){
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assert( iVersion>=0 );
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assert( iCell>=0 && iCell<=array_size(p->aiChildPtr) );
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if( p->iV2 && p->iV2<=(u32)iVersion && iCell==p->iV2Child ) return p->iV2Ptr;
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return p->aiChildPtr[iCell];
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}
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/*
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** Given an offset within the *-shm file, return the associated chunk number.
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*/
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static int treeOffsetToChunk(u32 iOff){
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assert( LSM_SHM_CHUNK_SIZE==(1<<15) );
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return (int)(iOff>>15);
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}
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#define treeShmptrUnsafe(pDb, iPtr) \
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(&((u8*)((pDb)->apShm[(iPtr)>>15]))[(iPtr) & (LSM_SHM_CHUNK_SIZE-1)])
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/*
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** Return a pointer to the mapped memory location associated with *-shm
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** file offset iPtr.
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*/
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static void *treeShmptr(lsm_db *pDb, u32 iPtr){
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assert( (iPtr>>15)<(u32)pDb->nShm );
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assert( pDb->apShm[iPtr>>15] );
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return iPtr ? treeShmptrUnsafe(pDb, iPtr) : 0;
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}
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static ShmChunk * treeShmChunk(lsm_db *pDb, int iChunk){
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return (ShmChunk *)(pDb->apShm[iChunk]);
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}
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static ShmChunk * treeShmChunkRc(lsm_db *pDb, int iChunk, int *pRc){
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assert( *pRc==LSM_OK );
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if( iChunk<pDb->nShm || LSM_OK==(*pRc = lsmShmCacheChunks(pDb, iChunk+1)) ){
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return (ShmChunk *)(pDb->apShm[iChunk]);
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}
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return 0;
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}
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#ifndef NDEBUG
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static void assertIsWorkingChild(
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lsm_db *db,
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TreeNode *pNode,
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TreeNode *pParent,
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int iCell
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){
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TreeNode *p;
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u32 iPtr = getChildPtr(pParent, WORKING_VERSION, iCell);
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p = treeShmptr(db, iPtr);
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assert( p==pNode );
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}
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#else
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# define assertIsWorkingChild(w,x,y,z)
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#endif
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/* Values for the third argument to treeShmkey(). */
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#define TKV_LOADKEY 1
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#define TKV_LOADVAL 2
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static TreeKey *treeShmkey(
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lsm_db *pDb, /* Database handle */
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u32 iPtr, /* Shmptr to TreeKey struct */
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int eLoad, /* Either zero or a TREEKEY_LOADXXX value */
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TreeBlob *pBlob, /* Used if dynamic memory is required */
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int *pRc /* IN/OUT: Error code */
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){
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TreeKey *pRet;
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assert( eLoad==TKV_LOADKEY || eLoad==TKV_LOADVAL );
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pRet = (TreeKey *)treeShmptr(pDb, iPtr);
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if( pRet ){
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int nReq; /* Bytes of space required at pRet */
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int nAvail; /* Bytes of space available at pRet */
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nReq = sizeof(TreeKey) + pRet->nKey;
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if( eLoad==TKV_LOADVAL && pRet->nValue>0 ){
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nReq += pRet->nValue;
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}
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assert( LSM_SHM_CHUNK_SIZE==(1<<15) );
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nAvail = LSM_SHM_CHUNK_SIZE - (iPtr & (LSM_SHM_CHUNK_SIZE-1));
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if( nAvail<nReq ){
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if( tblobGrow(pDb, pBlob, nReq, pRc)==0 ){
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int nLoad = 0;
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while( *pRc==LSM_OK ){
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ShmChunk *pChunk;
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void *p = treeShmptr(pDb, iPtr);
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int n = LSM_MIN(nAvail, nReq-nLoad);
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memcpy(&pBlob->a[nLoad], p, n);
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nLoad += n;
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if( nLoad==nReq ) break;
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pChunk = treeShmChunk(pDb, treeOffsetToChunk(iPtr));
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assert( pChunk );
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iPtr = (pChunk->iNext * LSM_SHM_CHUNK_SIZE) + LSM_SHM_CHUNK_HDR;
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nAvail = LSM_SHM_CHUNK_SIZE - LSM_SHM_CHUNK_HDR;
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}
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}
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pRet = (TreeKey *)(pBlob->a);
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}
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}
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return pRet;
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}
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#if defined(LSM_DEBUG) && defined(LSM_EXPENSIVE_ASSERT)
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void assert_leaf_looks_ok(TreeNode *pNode){
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assert( pNode->apKey[1] );
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}
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void assert_node_looks_ok(TreeNode *pNode, int nHeight){
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if( pNode ){
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assert( pNode->apKey[1] );
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if( nHeight>1 ){
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int i;
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assert( getChildPtr(pNode, WORKING_VERSION, 1) );
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assert( getChildPtr(pNode, WORKING_VERSION, 2) );
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for(i=0; i<4; i++){
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assert_node_looks_ok(getChildPtr(pNode, WORKING_VERSION, i), nHeight-1);
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}
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}
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}
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}
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/*
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** Run various assert() statements to check that the working-version of the
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** tree is correct in the following respects:
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**
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** * todo...
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*/
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void assert_tree_looks_ok(int rc, Tree *pTree){
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}
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#else
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# define assert_tree_looks_ok(x,y)
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#endif
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void lsmFlagsToString(int flags, char *zFlags){
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zFlags[0] = (flags & LSM_END_DELETE) ? ']' : '.';
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/* Only one of LSM_POINT_DELETE, LSM_INSERT and LSM_SEPARATOR should ever
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** be set. If this is not true, write a '?' to the output. */
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switch( flags & (LSM_POINT_DELETE|LSM_INSERT|LSM_SEPARATOR) ){
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case 0: zFlags[1] = '.'; break;
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case LSM_POINT_DELETE: zFlags[1] = '-'; break;
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case LSM_INSERT: zFlags[1] = '+'; break;
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case LSM_SEPARATOR: zFlags[1] = '^'; break;
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default: zFlags[1] = '?'; break;
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}
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zFlags[2] = (flags & LSM_SYSTEMKEY) ? '*' : '.';
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zFlags[3] = (flags & LSM_START_DELETE) ? '[' : '.';
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zFlags[4] = '\0';
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}
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#ifdef LSM_DEBUG
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/*
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** Pointer pBlob points to a buffer containing a blob of binary data
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|
** nBlob bytes long. Append the contents of this blob to *pStr, with
|
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** each octet represented by a 2-digit hexadecimal number. For example,
|
|
** if the input blob is three bytes in size and contains {0x01, 0x44, 0xFF},
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** then "0144ff" is appended to *pStr.
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*/
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static void lsmAppendStrBlob(LsmString *pStr, void *pBlob, int nBlob){
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int i;
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lsmStringExtend(pStr, nBlob*2);
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if( pStr->nAlloc==0 ) return;
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for(i=0; i<nBlob; i++){
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u8 c = ((u8*)pBlob)[i];
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if( c>='a' && c<='z' ){
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pStr->z[pStr->n++] = c;
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}else if( c!=0 || nBlob==1 || i!=(nBlob-1) ){
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pStr->z[pStr->n++] = "0123456789abcdef"[(c>>4)&0xf];
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pStr->z[pStr->n++] = "0123456789abcdef"[c&0xf];
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}
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}
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pStr->z[pStr->n] = 0;
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}
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|
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#if 0 /* NOT USED */
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/*
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** Append nIndent space (0x20) characters to string *pStr.
|
|
*/
|
|
static void lsmAppendIndent(LsmString *pStr, int nIndent){
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int i;
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lsmStringExtend(pStr, nIndent);
|
|
for(i=0; i<nIndent; i++) lsmStringAppend(pStr, " ", 1);
|
|
}
|
|
#endif
|
|
|
|
static void strAppendFlags(LsmString *pStr, u8 flags){
|
|
char zFlags[8];
|
|
|
|
lsmFlagsToString(flags, zFlags);
|
|
zFlags[4] = ':';
|
|
|
|
lsmStringAppend(pStr, zFlags, 5);
|
|
}
|
|
|
|
void dump_node_contents(
|
|
lsm_db *pDb,
|
|
u32 iNode, /* Print out the contents of this node */
|
|
char *zPath, /* Path from root to this node */
|
|
int nPath, /* Number of bytes in zPath */
|
|
int nHeight /* Height: (0==leaf) (1==parent-of-leaf) */
|
|
){
|
|
const char *zSpace = " ";
|
|
int i;
|
|
int rc = LSM_OK;
|
|
LsmString s;
|
|
TreeNode *pNode;
|
|
TreeBlob b = {0, 0};
|
|
|
|
pNode = (TreeNode *)treeShmptr(pDb, iNode);
|
|
|
|
if( nHeight==0 ){
|
|
/* Append the nIndent bytes of space to string s. */
|
|
lsmStringInit(&s, pDb->pEnv);
|
|
|
|
/* Append each key to string s. */
|
|
for(i=0; i<3; i++){
|
|
u32 iPtr = pNode->aiKeyPtr[i];
|
|
if( iPtr ){
|
|
TreeKey *pKey = treeShmkey(pDb, pNode->aiKeyPtr[i],TKV_LOADKEY, &b,&rc);
|
|
strAppendFlags(&s, pKey->flags);
|
|
lsmAppendStrBlob(&s, TKV_KEY(pKey), pKey->nKey);
|
|
lsmStringAppend(&s, " ", -1);
|
|
}
|
|
}
|
|
|
|
printf("% 6d %.*sleaf%.*s: %s\n",
|
|
iNode, nPath, zPath, 20-nPath-4, zSpace, s.z
|
|
);
|
|
lsmStringClear(&s);
|
|
}else{
|
|
for(i=0; i<4 && nHeight>0; i++){
|
|
u32 iPtr = getChildPtr(pNode, pDb->treehdr.root.iTransId, i);
|
|
zPath[nPath] = (char)(i+'0');
|
|
zPath[nPath+1] = '/';
|
|
|
|
if( iPtr ){
|
|
dump_node_contents(pDb, iPtr, zPath, nPath+2, nHeight-1);
|
|
}
|
|
if( i!=3 && pNode->aiKeyPtr[i] ){
|
|
TreeKey *pKey = treeShmkey(pDb, pNode->aiKeyPtr[i], TKV_LOADKEY,&b,&rc);
|
|
lsmStringInit(&s, pDb->pEnv);
|
|
strAppendFlags(&s, pKey->flags);
|
|
lsmAppendStrBlob(&s, TKV_KEY(pKey), pKey->nKey);
|
|
printf("% 6d %.*s%.*s: %s\n",
|
|
iNode, nPath+1, zPath, 20-nPath-1, zSpace, s.z);
|
|
lsmStringClear(&s);
|
|
}
|
|
}
|
|
}
|
|
|
|
tblobFree(pDb, &b);
|
|
}
|
|
|
|
void dump_tree_contents(lsm_db *pDb, const char *zCaption){
|
|
char zPath[64];
|
|
TreeRoot *p = &pDb->treehdr.root;
|
|
printf("\n%s\n", zCaption);
|
|
zPath[0] = '/';
|
|
if( p->iRoot ){
|
|
dump_node_contents(pDb, p->iRoot, zPath, 1, p->nHeight-1);
|
|
}
|
|
fflush(stdout);
|
|
}
|
|
|
|
#endif
|
|
|
|
/*
|
|
** Initialize a cursor object, the space for which has already been
|
|
** allocated.
|
|
*/
|
|
static void treeCursorInit(lsm_db *pDb, int bOld, TreeCursor *pCsr){
|
|
memset(pCsr, 0, sizeof(TreeCursor));
|
|
pCsr->pDb = pDb;
|
|
if( bOld ){
|
|
pCsr->pRoot = &pDb->treehdr.oldroot;
|
|
}else{
|
|
pCsr->pRoot = &pDb->treehdr.root;
|
|
}
|
|
pCsr->iNode = -1;
|
|
}
|
|
|
|
/*
|
|
** Return a pointer to the mapping of the TreeKey object that the cursor
|
|
** is pointing to.
|
|
*/
|
|
static TreeKey *csrGetKey(TreeCursor *pCsr, TreeBlob *pBlob, int *pRc){
|
|
TreeKey *pRet;
|
|
lsm_db *pDb = pCsr->pDb;
|
|
u32 iPtr = pCsr->apTreeNode[pCsr->iNode]->aiKeyPtr[pCsr->aiCell[pCsr->iNode]];
|
|
|
|
assert( iPtr );
|
|
pRet = (TreeKey*)treeShmptrUnsafe(pDb, iPtr);
|
|
if( !(pRet->flags & LSM_CONTIGUOUS) ){
|
|
pRet = treeShmkey(pDb, iPtr, TKV_LOADVAL, pBlob, pRc);
|
|
}
|
|
|
|
return pRet;
|
|
}
|
|
|
|
/*
|
|
** Save the current position of tree cursor pCsr.
|
|
*/
|
|
int lsmTreeCursorSave(TreeCursor *pCsr){
|
|
int rc = LSM_OK;
|
|
if( pCsr && pCsr->pSave==0 ){
|
|
int iNode = pCsr->iNode;
|
|
if( iNode>=0 ){
|
|
pCsr->pSave = csrGetKey(pCsr, &pCsr->blob, &rc);
|
|
}
|
|
pCsr->iNode = -1;
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Restore the position of a saved tree cursor.
|
|
*/
|
|
static int treeCursorRestore(TreeCursor *pCsr, int *pRes){
|
|
int rc = LSM_OK;
|
|
if( pCsr->pSave ){
|
|
TreeKey *pKey = pCsr->pSave;
|
|
pCsr->pSave = 0;
|
|
if( pRes ){
|
|
rc = lsmTreeCursorSeek(pCsr, TKV_KEY(pKey), pKey->nKey, pRes);
|
|
}
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Allocate nByte bytes of space within the *-shm file. If successful,
|
|
** return LSM_OK and set *piPtr to the offset within the file at which
|
|
** the allocated space is located.
|
|
*/
|
|
static u32 treeShmalloc(lsm_db *pDb, int bAlign, int nByte, int *pRc){
|
|
u32 iRet = 0;
|
|
if( *pRc==LSM_OK ){
|
|
const static int CHUNK_SIZE = LSM_SHM_CHUNK_SIZE;
|
|
const static int CHUNK_HDR = LSM_SHM_CHUNK_HDR;
|
|
u32 iWrite; /* Current write offset */
|
|
u32 iEof; /* End of current chunk */
|
|
int iChunk; /* Current chunk */
|
|
|
|
assert( nByte <= (CHUNK_SIZE-CHUNK_HDR) );
|
|
|
|
/* Check if there is enough space on the current chunk to fit the
|
|
** new allocation. If not, link in a new chunk and put the new
|
|
** allocation at the start of it. */
|
|
iWrite = pDb->treehdr.iWrite;
|
|
if( bAlign ){
|
|
iWrite = (iWrite + 3) & ~0x0003;
|
|
assert( (iWrite % 4)==0 );
|
|
}
|
|
|
|
assert( iWrite );
|
|
iChunk = treeOffsetToChunk(iWrite-1);
|
|
iEof = (iChunk+1) * CHUNK_SIZE;
|
|
assert( iEof>=iWrite && (iEof-iWrite)<(u32)CHUNK_SIZE );
|
|
if( (iWrite+nByte)>iEof ){
|
|
ShmChunk *pHdr; /* Header of chunk just finished (iChunk) */
|
|
ShmChunk *pFirst; /* Header of chunk treehdr.iFirst */
|
|
ShmChunk *pNext; /* Header of new chunk */
|
|
int iNext = 0; /* Next chunk */
|
|
int rc = LSM_OK;
|
|
|
|
pFirst = treeShmChunk(pDb, pDb->treehdr.iFirst);
|
|
|
|
assert( shm_sequence_ge(pDb->treehdr.iUsedShmid, pFirst->iShmid) );
|
|
assert( (pDb->treehdr.iNextShmid+1-pDb->treehdr.nChunk)==pFirst->iShmid );
|
|
|
|
/* Check if the chunk at the start of the linked list is still in
|
|
** use. If not, reuse it. If so, allocate a new chunk by appending
|
|
** to the *-shm file. */
|
|
if( pDb->treehdr.iUsedShmid!=pFirst->iShmid ){
|
|
int bInUse;
|
|
rc = lsmTreeInUse(pDb, pFirst->iShmid, &bInUse);
|
|
if( rc!=LSM_OK ){
|
|
*pRc = rc;
|
|
return 0;
|
|
}
|
|
if( bInUse==0 ){
|
|
iNext = pDb->treehdr.iFirst;
|
|
pDb->treehdr.iFirst = pFirst->iNext;
|
|
assert( pDb->treehdr.iFirst );
|
|
}
|
|
}
|
|
if( iNext==0 ) iNext = pDb->treehdr.nChunk++;
|
|
|
|
/* Set the header values for the new chunk */
|
|
pNext = treeShmChunkRc(pDb, iNext, &rc);
|
|
if( pNext ){
|
|
pNext->iNext = 0;
|
|
pNext->iShmid = (pDb->treehdr.iNextShmid++);
|
|
}else{
|
|
*pRc = rc;
|
|
return 0;
|
|
}
|
|
|
|
/* Set the header values for the chunk just finished */
|
|
pHdr = (ShmChunk *)treeShmptr(pDb, iChunk*CHUNK_SIZE);
|
|
pHdr->iNext = iNext;
|
|
|
|
/* Advance to the next chunk */
|
|
iWrite = iNext * CHUNK_SIZE + CHUNK_HDR;
|
|
}
|
|
|
|
/* Allocate space at iWrite. */
|
|
iRet = iWrite;
|
|
pDb->treehdr.iWrite = iWrite + nByte;
|
|
pDb->treehdr.root.nByte += nByte;
|
|
}
|
|
return iRet;
|
|
}
|
|
|
|
/*
|
|
** Allocate and zero nByte bytes of space within the *-shm file.
|
|
*/
|
|
static void *treeShmallocZero(lsm_db *pDb, int nByte, u32 *piPtr, int *pRc){
|
|
u32 iPtr;
|
|
void *p;
|
|
iPtr = treeShmalloc(pDb, 1, nByte, pRc);
|
|
p = treeShmptr(pDb, iPtr);
|
|
if( p ){
|
|
assert( *pRc==LSM_OK );
|
|
memset(p, 0, nByte);
|
|
*piPtr = iPtr;
|
|
}
|
|
return p;
|
|
}
|
|
|
|
static TreeNode *newTreeNode(lsm_db *pDb, u32 *piPtr, int *pRc){
|
|
return treeShmallocZero(pDb, sizeof(TreeNode), piPtr, pRc);
|
|
}
|
|
|
|
static TreeLeaf *newTreeLeaf(lsm_db *pDb, u32 *piPtr, int *pRc){
|
|
return treeShmallocZero(pDb, sizeof(TreeLeaf), piPtr, pRc);
|
|
}
|
|
|
|
static TreeKey *newTreeKey(
|
|
lsm_db *pDb,
|
|
u32 *piPtr,
|
|
void *pKey, int nKey, /* Key data */
|
|
void *pVal, int nVal, /* Value data (or nVal<0 for delete) */
|
|
int *pRc
|
|
){
|
|
TreeKey *p;
|
|
u32 iPtr;
|
|
u32 iEnd;
|
|
int nRem;
|
|
u8 *a;
|
|
int n;
|
|
|
|
/* Allocate space for the TreeKey structure itself */
|
|
*piPtr = iPtr = treeShmalloc(pDb, 1, sizeof(TreeKey), pRc);
|
|
p = treeShmptr(pDb, iPtr);
|
|
if( *pRc ) return 0;
|
|
p->nKey = nKey;
|
|
p->nValue = nVal;
|
|
|
|
/* Allocate and populate the space required for the key and value. */
|
|
n = nRem = nKey;
|
|
a = (u8 *)pKey;
|
|
while( a ){
|
|
while( nRem>0 ){
|
|
u8 *aAlloc;
|
|
int nAlloc;
|
|
u32 iWrite;
|
|
|
|
iWrite = (pDb->treehdr.iWrite & (LSM_SHM_CHUNK_SIZE-1));
|
|
iWrite = LSM_MAX(iWrite, LSM_SHM_CHUNK_HDR);
|
|
nAlloc = LSM_MIN((LSM_SHM_CHUNK_SIZE-iWrite), (u32)nRem);
|
|
|
|
aAlloc = treeShmptr(pDb, treeShmalloc(pDb, 0, nAlloc, pRc));
|
|
if( aAlloc==0 ) break;
|
|
memcpy(aAlloc, &a[n-nRem], nAlloc);
|
|
nRem -= nAlloc;
|
|
}
|
|
a = pVal;
|
|
n = nRem = nVal;
|
|
pVal = 0;
|
|
}
|
|
|
|
iEnd = iPtr + sizeof(TreeKey) + nKey + LSM_MAX(0, nVal);
|
|
if( (iPtr & ~(LSM_SHM_CHUNK_SIZE-1))!=(iEnd & ~(LSM_SHM_CHUNK_SIZE-1)) ){
|
|
p->flags = 0;
|
|
}else{
|
|
p->flags = LSM_CONTIGUOUS;
|
|
}
|
|
|
|
if( *pRc ) return 0;
|
|
#if 0
|
|
printf("store: %d %s\n", (int)iPtr, (char *)pKey);
|
|
#endif
|
|
return p;
|
|
}
|
|
|
|
static TreeNode *copyTreeNode(
|
|
lsm_db *pDb,
|
|
TreeNode *pOld,
|
|
u32 *piNew,
|
|
int *pRc
|
|
){
|
|
TreeNode *pNew;
|
|
|
|
pNew = newTreeNode(pDb, piNew, pRc);
|
|
if( pNew ){
|
|
memcpy(pNew->aiKeyPtr, pOld->aiKeyPtr, sizeof(pNew->aiKeyPtr));
|
|
memcpy(pNew->aiChildPtr, pOld->aiChildPtr, sizeof(pNew->aiChildPtr));
|
|
if( pOld->iV2 ) pNew->aiChildPtr[pOld->iV2Child] = pOld->iV2Ptr;
|
|
}
|
|
return pNew;
|
|
}
|
|
|
|
static TreeNode *copyTreeLeaf(
|
|
lsm_db *pDb,
|
|
TreeLeaf *pOld,
|
|
u32 *piNew,
|
|
int *pRc
|
|
){
|
|
TreeLeaf *pNew;
|
|
pNew = newTreeLeaf(pDb, piNew, pRc);
|
|
if( pNew ){
|
|
memcpy(pNew, pOld, sizeof(TreeLeaf));
|
|
}
|
|
return (TreeNode *)pNew;
|
|
}
|
|
|
|
/*
|
|
** The tree cursor passed as the second argument currently points to an
|
|
** internal node (not a leaf). Specifically, to a sub-tree pointer. This
|
|
** function replaces the sub-tree that the cursor currently points to
|
|
** with sub-tree pNew.
|
|
**
|
|
** The sub-tree may be replaced either by writing the "v2 data" on the
|
|
** internal node, or by allocating a new TreeNode structure and then
|
|
** calling this function on the parent of the internal node.
|
|
*/
|
|
static int treeUpdatePtr(lsm_db *pDb, TreeCursor *pCsr, u32 iNew){
|
|
int rc = LSM_OK;
|
|
if( pCsr->iNode<0 ){
|
|
/* iNew is the new root node */
|
|
pDb->treehdr.root.iRoot = iNew;
|
|
}else{
|
|
/* If this node already has version 2 content, allocate a copy and
|
|
** update the copy with the new pointer value. Otherwise, store the
|
|
** new pointer as v2 data within the current node structure. */
|
|
|
|
TreeNode *p; /* The node to be modified */
|
|
int iChildPtr; /* apChild[] entry to modify */
|
|
|
|
p = pCsr->apTreeNode[pCsr->iNode];
|
|
iChildPtr = pCsr->aiCell[pCsr->iNode];
|
|
|
|
if( p->iV2 ){
|
|
/* The "allocate new TreeNode" option */
|
|
u32 iCopy;
|
|
TreeNode *pCopy;
|
|
pCopy = copyTreeNode(pDb, p, &iCopy, &rc);
|
|
if( pCopy ){
|
|
assert( rc==LSM_OK );
|
|
pCopy->aiChildPtr[iChildPtr] = iNew;
|
|
pCsr->iNode--;
|
|
rc = treeUpdatePtr(pDb, pCsr, iCopy);
|
|
}
|
|
}else{
|
|
/* The "v2 data" option */
|
|
u32 iPtr;
|
|
assert( pDb->treehdr.root.iTransId>0 );
|
|
|
|
if( pCsr->iNode ){
|
|
iPtr = getChildPtr(
|
|
pCsr->apTreeNode[pCsr->iNode-1],
|
|
pDb->treehdr.root.iTransId, pCsr->aiCell[pCsr->iNode-1]
|
|
);
|
|
}else{
|
|
iPtr = pDb->treehdr.root.iRoot;
|
|
}
|
|
rc = intArrayAppend(pDb->pEnv, &pDb->rollback, iPtr);
|
|
|
|
if( rc==LSM_OK ){
|
|
p->iV2 = pDb->treehdr.root.iTransId;
|
|
p->iV2Child = (u8)iChildPtr;
|
|
p->iV2Ptr = iNew;
|
|
}
|
|
}
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Cursor pCsr points at a node that is part of pTree. This function
|
|
** inserts a new key and optionally child node pointer into that node.
|
|
**
|
|
** The position into which the new key and pointer are inserted is
|
|
** determined by the iSlot parameter. The new key will be inserted to
|
|
** the left of the key currently stored in apKey[iSlot]. Or, if iSlot is
|
|
** greater than the index of the rightmost key in the node.
|
|
**
|
|
** Pointer pLeftPtr points to a child tree that contains keys that are
|
|
** smaller than pTreeKey.
|
|
*/
|
|
static int treeInsert(
|
|
lsm_db *pDb, /* Database handle */
|
|
TreeCursor *pCsr, /* Cursor indicating path to insert at */
|
|
u32 iLeftPtr, /* Left child pointer */
|
|
u32 iTreeKey, /* Location of key to insert */
|
|
u32 iRightPtr, /* Right child pointer */
|
|
int iSlot /* Position to insert key into */
|
|
){
|
|
int rc = LSM_OK;
|
|
TreeNode *pNode = pCsr->apTreeNode[pCsr->iNode];
|
|
|
|
/* Check if the node is currently full. If so, split pNode in two and
|
|
** call this function recursively to add a key to the parent. Otherwise,
|
|
** insert the new key directly into pNode. */
|
|
assert( pNode->aiKeyPtr[1] );
|
|
if( pNode->aiKeyPtr[0] && pNode->aiKeyPtr[2] ){
|
|
u32 iLeft; TreeNode *pLeft; /* New left-hand sibling node */
|
|
u32 iRight; TreeNode *pRight; /* New right-hand sibling node */
|
|
|
|
pLeft = newTreeNode(pDb, &iLeft, &rc);
|
|
pRight = newTreeNode(pDb, &iRight, &rc);
|
|
if( rc ) return rc;
|
|
|
|
pLeft->aiChildPtr[1] = getChildPtr(pNode, WORKING_VERSION, 0);
|
|
pLeft->aiKeyPtr[1] = pNode->aiKeyPtr[0];
|
|
pLeft->aiChildPtr[2] = getChildPtr(pNode, WORKING_VERSION, 1);
|
|
|
|
pRight->aiChildPtr[1] = getChildPtr(pNode, WORKING_VERSION, 2);
|
|
pRight->aiKeyPtr[1] = pNode->aiKeyPtr[2];
|
|
pRight->aiChildPtr[2] = getChildPtr(pNode, WORKING_VERSION, 3);
|
|
|
|
if( pCsr->iNode==0 ){
|
|
/* pNode is the root of the tree. Grow the tree by one level. */
|
|
u32 iRoot; TreeNode *pRoot; /* New root node */
|
|
|
|
pRoot = newTreeNode(pDb, &iRoot, &rc);
|
|
pRoot->aiKeyPtr[1] = pNode->aiKeyPtr[1];
|
|
pRoot->aiChildPtr[1] = iLeft;
|
|
pRoot->aiChildPtr[2] = iRight;
|
|
|
|
pDb->treehdr.root.iRoot = iRoot;
|
|
pDb->treehdr.root.nHeight++;
|
|
}else{
|
|
|
|
pCsr->iNode--;
|
|
rc = treeInsert(pDb, pCsr,
|
|
iLeft, pNode->aiKeyPtr[1], iRight, pCsr->aiCell[pCsr->iNode]
|
|
);
|
|
}
|
|
|
|
assert( pLeft->iV2==0 );
|
|
assert( pRight->iV2==0 );
|
|
switch( iSlot ){
|
|
case 0:
|
|
pLeft->aiKeyPtr[0] = iTreeKey;
|
|
pLeft->aiChildPtr[0] = iLeftPtr;
|
|
if( iRightPtr ) pLeft->aiChildPtr[1] = iRightPtr;
|
|
break;
|
|
case 1:
|
|
pLeft->aiChildPtr[3] = (iRightPtr ? iRightPtr : pLeft->aiChildPtr[2]);
|
|
pLeft->aiKeyPtr[2] = iTreeKey;
|
|
pLeft->aiChildPtr[2] = iLeftPtr;
|
|
break;
|
|
case 2:
|
|
pRight->aiKeyPtr[0] = iTreeKey;
|
|
pRight->aiChildPtr[0] = iLeftPtr;
|
|
if( iRightPtr ) pRight->aiChildPtr[1] = iRightPtr;
|
|
break;
|
|
case 3:
|
|
pRight->aiChildPtr[3] = (iRightPtr ? iRightPtr : pRight->aiChildPtr[2]);
|
|
pRight->aiKeyPtr[2] = iTreeKey;
|
|
pRight->aiChildPtr[2] = iLeftPtr;
|
|
break;
|
|
}
|
|
|
|
}else{
|
|
TreeNode *pNew;
|
|
u32 *piKey;
|
|
u32 *piChild;
|
|
u32 iStore = 0;
|
|
u32 iNew = 0;
|
|
int i;
|
|
|
|
/* Allocate a new version of node pNode. */
|
|
pNew = newTreeNode(pDb, &iNew, &rc);
|
|
if( rc ) return rc;
|
|
|
|
piKey = pNew->aiKeyPtr;
|
|
piChild = pNew->aiChildPtr;
|
|
|
|
for(i=0; i<iSlot; i++){
|
|
if( pNode->aiKeyPtr[i] ){
|
|
*(piKey++) = pNode->aiKeyPtr[i];
|
|
*(piChild++) = getChildPtr(pNode, WORKING_VERSION, i);
|
|
}
|
|
}
|
|
|
|
*piKey++ = iTreeKey;
|
|
*piChild++ = iLeftPtr;
|
|
|
|
iStore = iRightPtr;
|
|
for(i=iSlot; i<3; i++){
|
|
if( pNode->aiKeyPtr[i] ){
|
|
*(piKey++) = pNode->aiKeyPtr[i];
|
|
*(piChild++) = iStore ? iStore : getChildPtr(pNode, WORKING_VERSION, i);
|
|
iStore = 0;
|
|
}
|
|
}
|
|
|
|
if( iStore ){
|
|
*piChild = iStore;
|
|
}else{
|
|
*piChild = getChildPtr(pNode, WORKING_VERSION,
|
|
(pNode->aiKeyPtr[2] ? 3 : 2)
|
|
);
|
|
}
|
|
pCsr->iNode--;
|
|
rc = treeUpdatePtr(pDb, pCsr, iNew);
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
static int treeInsertLeaf(
|
|
lsm_db *pDb, /* Database handle */
|
|
TreeCursor *pCsr, /* Cursor structure */
|
|
u32 iTreeKey, /* Key pointer to insert */
|
|
int iSlot /* Insert key to the left of this */
|
|
){
|
|
int rc = LSM_OK; /* Return code */
|
|
TreeNode *pLeaf = pCsr->apTreeNode[pCsr->iNode];
|
|
TreeLeaf *pNew;
|
|
u32 iNew;
|
|
|
|
assert( iSlot>=0 && iSlot<=4 );
|
|
assert( pCsr->iNode>0 );
|
|
assert( pLeaf->aiKeyPtr[1] );
|
|
|
|
pCsr->iNode--;
|
|
|
|
pNew = newTreeLeaf(pDb, &iNew, &rc);
|
|
if( pNew ){
|
|
if( pLeaf->aiKeyPtr[0] && pLeaf->aiKeyPtr[2] ){
|
|
/* The leaf is full. Split it in two. */
|
|
TreeLeaf *pRight;
|
|
u32 iRight;
|
|
pRight = newTreeLeaf(pDb, &iRight, &rc);
|
|
if( pRight ){
|
|
assert( rc==LSM_OK );
|
|
pNew->aiKeyPtr[1] = pLeaf->aiKeyPtr[0];
|
|
pRight->aiKeyPtr[1] = pLeaf->aiKeyPtr[2];
|
|
switch( iSlot ){
|
|
case 0: pNew->aiKeyPtr[0] = iTreeKey; break;
|
|
case 1: pNew->aiKeyPtr[2] = iTreeKey; break;
|
|
case 2: pRight->aiKeyPtr[0] = iTreeKey; break;
|
|
case 3: pRight->aiKeyPtr[2] = iTreeKey; break;
|
|
}
|
|
|
|
rc = treeInsert(pDb, pCsr, iNew, pLeaf->aiKeyPtr[1], iRight,
|
|
pCsr->aiCell[pCsr->iNode]
|
|
);
|
|
}
|
|
}else{
|
|
int iOut = 0;
|
|
int i;
|
|
for(i=0; i<4; i++){
|
|
if( i==iSlot ) pNew->aiKeyPtr[iOut++] = iTreeKey;
|
|
if( i<3 && pLeaf->aiKeyPtr[i] ){
|
|
pNew->aiKeyPtr[iOut++] = pLeaf->aiKeyPtr[i];
|
|
}
|
|
}
|
|
rc = treeUpdatePtr(pDb, pCsr, iNew);
|
|
}
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
void lsmTreeMakeOld(lsm_db *pDb){
|
|
|
|
/* A write transaction must be open. Otherwise the code below that
|
|
** assumes (pDb->pClient->iLogOff) is current may malfunction.
|
|
**
|
|
** Update: currently this assert fails due to lsm_flush(), which does
|
|
** not set nTransOpen.
|
|
*/
|
|
assert( /* pDb->nTransOpen>0 && */ pDb->iReader>=0 );
|
|
|
|
if( pDb->treehdr.iOldShmid==0 ){
|
|
pDb->treehdr.iOldLog = (pDb->treehdr.log.aRegion[2].iEnd << 1);
|
|
pDb->treehdr.iOldLog |= (~(pDb->pClient->iLogOff) & (i64)0x0001);
|
|
|
|
pDb->treehdr.oldcksum0 = pDb->treehdr.log.cksum0;
|
|
pDb->treehdr.oldcksum1 = pDb->treehdr.log.cksum1;
|
|
pDb->treehdr.iOldShmid = pDb->treehdr.iNextShmid-1;
|
|
memcpy(&pDb->treehdr.oldroot, &pDb->treehdr.root, sizeof(TreeRoot));
|
|
|
|
pDb->treehdr.root.iTransId = 1;
|
|
pDb->treehdr.root.iRoot = 0;
|
|
pDb->treehdr.root.nHeight = 0;
|
|
pDb->treehdr.root.nByte = 0;
|
|
}
|
|
}
|
|
|
|
void lsmTreeDiscardOld(lsm_db *pDb){
|
|
assert( lsmShmAssertLock(pDb, LSM_LOCK_WRITER, LSM_LOCK_EXCL)
|
|
|| lsmShmAssertLock(pDb, LSM_LOCK_DMS2, LSM_LOCK_EXCL)
|
|
);
|
|
pDb->treehdr.iUsedShmid = pDb->treehdr.iOldShmid;
|
|
pDb->treehdr.iOldShmid = 0;
|
|
}
|
|
|
|
int lsmTreeHasOld(lsm_db *pDb){
|
|
return pDb->treehdr.iOldShmid!=0;
|
|
}
|
|
|
|
/*
|
|
** This function is called during recovery to initialize the
|
|
** tree header. Only the database connections private copy of the tree-header
|
|
** is initialized here - it will be copied into shared memory if log file
|
|
** recovery is successful.
|
|
*/
|
|
int lsmTreeInit(lsm_db *pDb){
|
|
ShmChunk *pOne;
|
|
int rc = LSM_OK;
|
|
|
|
memset(&pDb->treehdr, 0, sizeof(TreeHeader));
|
|
pDb->treehdr.root.iTransId = 1;
|
|
pDb->treehdr.iFirst = 1;
|
|
pDb->treehdr.nChunk = 2;
|
|
pDb->treehdr.iWrite = LSM_SHM_CHUNK_SIZE + LSM_SHM_CHUNK_HDR;
|
|
pDb->treehdr.iNextShmid = 2;
|
|
pDb->treehdr.iUsedShmid = 1;
|
|
|
|
pOne = treeShmChunkRc(pDb, 1, &rc);
|
|
if( pOne ){
|
|
pOne->iNext = 0;
|
|
pOne->iShmid = 1;
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
static void treeHeaderChecksum(
|
|
TreeHeader *pHdr,
|
|
u32 *aCksum
|
|
){
|
|
u32 cksum1 = 0x12345678;
|
|
u32 cksum2 = 0x9ABCDEF0;
|
|
u32 *a = (u32 *)pHdr;
|
|
int i;
|
|
|
|
assert( (offsetof(TreeHeader, aCksum) + sizeof(u32)*2)==sizeof(TreeHeader) );
|
|
assert( (sizeof(TreeHeader) % (sizeof(u32)*2))==0 );
|
|
|
|
for(i=0; i<(offsetof(TreeHeader, aCksum) / sizeof(u32)); i+=2){
|
|
cksum1 += a[i];
|
|
cksum2 += (cksum1 + a[i+1]);
|
|
}
|
|
aCksum[0] = cksum1;
|
|
aCksum[1] = cksum2;
|
|
}
|
|
|
|
/*
|
|
** Return true if the checksum stored in TreeHeader object *pHdr is
|
|
** consistent with the contents of its other fields.
|
|
*/
|
|
static int treeHeaderChecksumOk(TreeHeader *pHdr){
|
|
u32 aCksum[2];
|
|
treeHeaderChecksum(pHdr, aCksum);
|
|
return (0==memcmp(aCksum, pHdr->aCksum, sizeof(aCksum)));
|
|
}
|
|
|
|
/*
|
|
** This type is used by functions lsmTreeRepair() and treeSortByShmid() to
|
|
** make relinking the linked list of shared-memory chunks easier.
|
|
*/
|
|
typedef struct ShmChunkLoc ShmChunkLoc;
|
|
struct ShmChunkLoc {
|
|
ShmChunk *pShm;
|
|
u32 iLoc;
|
|
};
|
|
|
|
/*
|
|
** This function checks that the linked list of shared memory chunks
|
|
** that starts at chunk db->treehdr.iFirst:
|
|
**
|
|
** 1) Includes all chunks in the shared-memory region, and
|
|
** 2) Links them together in order of ascending shm-id.
|
|
**
|
|
** If no error occurs and the conditions above are met, LSM_OK is returned.
|
|
**
|
|
** If either of the conditions are untrue, LSM_CORRUPT is returned. Or, if
|
|
** an error is encountered before the checks are completed, another LSM error
|
|
** code (i.e. LSM_IOERR or LSM_NOMEM) may be returned.
|
|
*/
|
|
static int treeCheckLinkedList(lsm_db *db){
|
|
int rc = LSM_OK;
|
|
int nVisit = 0;
|
|
ShmChunk *p;
|
|
|
|
p = treeShmChunkRc(db, db->treehdr.iFirst, &rc);
|
|
while( rc==LSM_OK && p ){
|
|
if( p->iNext ){
|
|
if( p->iNext>=db->treehdr.nChunk ){
|
|
rc = LSM_CORRUPT_BKPT;
|
|
}else{
|
|
ShmChunk *pNext = treeShmChunkRc(db, p->iNext, &rc);
|
|
if( rc==LSM_OK ){
|
|
if( pNext->iShmid!=p->iShmid+1 ){
|
|
rc = LSM_CORRUPT_BKPT;
|
|
}
|
|
p = pNext;
|
|
}
|
|
}
|
|
}else{
|
|
p = 0;
|
|
}
|
|
nVisit++;
|
|
}
|
|
|
|
if( rc==LSM_OK && (u32)nVisit!=db->treehdr.nChunk-1 ){
|
|
rc = LSM_CORRUPT_BKPT;
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Iterate through the current in-memory tree. If there are any v2-pointers
|
|
** with transaction ids larger than db->treehdr.iTransId, zero them.
|
|
*/
|
|
static int treeRepairPtrs(lsm_db *db){
|
|
int rc = LSM_OK;
|
|
|
|
if( db->treehdr.root.nHeight>1 ){
|
|
TreeCursor csr; /* Cursor used to iterate through tree */
|
|
u32 iTransId = db->treehdr.root.iTransId;
|
|
|
|
/* Initialize the cursor structure. Also decrement the nHeight variable
|
|
** in the tree-header. This will prevent the cursor from visiting any
|
|
** leaf nodes. */
|
|
db->treehdr.root.nHeight--;
|
|
treeCursorInit(db, 0, &csr);
|
|
|
|
rc = lsmTreeCursorEnd(&csr, 0);
|
|
while( rc==LSM_OK && lsmTreeCursorValid(&csr) ){
|
|
TreeNode *pNode = csr.apTreeNode[csr.iNode];
|
|
if( pNode->iV2>iTransId ){
|
|
pNode->iV2Child = 0;
|
|
pNode->iV2Ptr = 0;
|
|
pNode->iV2 = 0;
|
|
}
|
|
rc = lsmTreeCursorNext(&csr);
|
|
}
|
|
tblobFree(csr.pDb, &csr.blob);
|
|
|
|
db->treehdr.root.nHeight++;
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
static int treeRepairList(lsm_db *db){
|
|
int rc = LSM_OK;
|
|
int i;
|
|
ShmChunk *p;
|
|
ShmChunk *pMin = 0;
|
|
u32 iMin = 0;
|
|
|
|
/* Iterate through all shm chunks. Find the smallest shm-id present in
|
|
** the shared-memory region. */
|
|
for(i=1; rc==LSM_OK && (u32)i<db->treehdr.nChunk; i++){
|
|
p = treeShmChunkRc(db, i, &rc);
|
|
if( p && (pMin==0 || shm_sequence_ge(pMin->iShmid, p->iShmid)) ){
|
|
pMin = p;
|
|
iMin = i;
|
|
}
|
|
}
|
|
|
|
/* Fix the shm-id values on any chunks with a shm-id greater than or
|
|
** equal to treehdr.iNextShmid. Then do a merge-sort of all chunks to
|
|
** fix the ShmChunk.iNext pointers.
|
|
*/
|
|
if( rc==LSM_OK ){
|
|
int nSort;
|
|
int nByte;
|
|
u32 iPrevShmid;
|
|
ShmChunkLoc *aSort;
|
|
|
|
/* Allocate space for a merge sort. */
|
|
nSort = 1;
|
|
while( (u32)nSort < (db->treehdr.nChunk-1) ) nSort = nSort * 2;
|
|
nByte = sizeof(ShmChunkLoc) * nSort * 2;
|
|
aSort = lsmMallocZeroRc(db->pEnv, nByte, &rc);
|
|
iPrevShmid = pMin->iShmid;
|
|
|
|
/* Fix all shm-ids, if required. */
|
|
if( rc==LSM_OK ){
|
|
iPrevShmid = pMin->iShmid-1;
|
|
for(i=1; (u32)i<db->treehdr.nChunk; i++){
|
|
p = treeShmChunk(db, i);
|
|
aSort[i-1].pShm = p;
|
|
aSort[i-1].iLoc = i;
|
|
if( (u32)i!=db->treehdr.iFirst ){
|
|
if( shm_sequence_ge(p->iShmid, db->treehdr.iNextShmid) ){
|
|
p->iShmid = iPrevShmid--;
|
|
}
|
|
}
|
|
}
|
|
if( iMin!=db->treehdr.iFirst ){
|
|
p = treeShmChunk(db, db->treehdr.iFirst);
|
|
p->iShmid = iPrevShmid;
|
|
}
|
|
}
|
|
|
|
if( rc==LSM_OK ){
|
|
ShmChunkLoc *aSpace = &aSort[nSort];
|
|
for(i=0; i<nSort; i++){
|
|
if( aSort[i].pShm ){
|
|
assert( shm_sequence_ge(aSort[i].pShm->iShmid, iPrevShmid) );
|
|
assert( aSpace[aSort[i].pShm->iShmid - iPrevShmid].pShm==0 );
|
|
aSpace[aSort[i].pShm->iShmid - iPrevShmid] = aSort[i];
|
|
}
|
|
}
|
|
|
|
if( aSpace[nSort-1].pShm ) aSpace[nSort-1].pShm->iNext = 0;
|
|
for(i=0; i<nSort-1; i++){
|
|
if( aSpace[i].pShm ){
|
|
aSpace[i].pShm->iNext = aSpace[i+1].iLoc;
|
|
}
|
|
}
|
|
|
|
rc = treeCheckLinkedList(db);
|
|
lsmFree(db->pEnv, aSort);
|
|
}
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** This function is called as part of opening a write-transaction if the
|
|
** writer-flag is already set - indicating that the previous writer
|
|
** failed before ending its transaction.
|
|
*/
|
|
int lsmTreeRepair(lsm_db *db){
|
|
int rc = LSM_OK;
|
|
TreeHeader hdr;
|
|
ShmHeader *pHdr = db->pShmhdr;
|
|
|
|
/* Ensure that the two tree-headers are consistent. Copy one over the other
|
|
** if necessary. Prefer the data from a tree-header for which the checksum
|
|
** computes. Or, if they both compute, prefer tree-header-1. */
|
|
if( memcmp(&pHdr->hdr1, &pHdr->hdr2, sizeof(TreeHeader)) ){
|
|
if( treeHeaderChecksumOk(&pHdr->hdr1) ){
|
|
memcpy(&pHdr->hdr2, &pHdr->hdr1, sizeof(TreeHeader));
|
|
}else{
|
|
memcpy(&pHdr->hdr1, &pHdr->hdr2, sizeof(TreeHeader));
|
|
}
|
|
}
|
|
|
|
/* Save the connections current copy of the tree-header. It will be
|
|
** restored before returning. */
|
|
memcpy(&hdr, &db->treehdr, sizeof(TreeHeader));
|
|
|
|
/* Walk the tree. Zero any v2 pointers with a transaction-id greater than
|
|
** the transaction-id currently in the tree-headers. */
|
|
rc = treeRepairPtrs(db);
|
|
|
|
/* Repair the linked list of shared-memory chunks. */
|
|
if( rc==LSM_OK ){
|
|
rc = treeRepairList(db);
|
|
}
|
|
|
|
memcpy(&db->treehdr, &hdr, sizeof(TreeHeader));
|
|
return rc;
|
|
}
|
|
|
|
static void treeOverwriteKey(lsm_db *db, TreeCursor *pCsr, u32 iKey, int *pRc){
|
|
if( *pRc==LSM_OK ){
|
|
TreeRoot *p = &db->treehdr.root;
|
|
TreeNode *pNew;
|
|
u32 iNew;
|
|
TreeNode *pNode = pCsr->apTreeNode[pCsr->iNode];
|
|
int iCell = pCsr->aiCell[pCsr->iNode];
|
|
|
|
/* Create a copy of this node */
|
|
if( (pCsr->iNode>0 && (u32)pCsr->iNode==(p->nHeight-1)) ){
|
|
pNew = copyTreeLeaf(db, (TreeLeaf *)pNode, &iNew, pRc);
|
|
}else{
|
|
pNew = copyTreeNode(db, pNode, &iNew, pRc);
|
|
}
|
|
|
|
if( pNew ){
|
|
/* Modify the value in the new version */
|
|
pNew->aiKeyPtr[iCell] = iKey;
|
|
|
|
/* Change the pointer in the parent (if any) to point at the new
|
|
** TreeNode */
|
|
pCsr->iNode--;
|
|
treeUpdatePtr(db, pCsr, iNew);
|
|
}
|
|
}
|
|
}
|
|
|
|
static int treeNextIsEndDelete(lsm_db *db, TreeCursor *pCsr){
|
|
int iNode = pCsr->iNode;
|
|
int iCell = pCsr->aiCell[iNode]+1;
|
|
|
|
/* Cursor currently points to a leaf node. */
|
|
assert( (u32)pCsr->iNode==(db->treehdr.root.nHeight-1) );
|
|
|
|
while( iNode>=0 ){
|
|
TreeNode *pNode = pCsr->apTreeNode[iNode];
|
|
if( iCell<3 && pNode->aiKeyPtr[iCell] ){
|
|
int rc = LSM_OK;
|
|
TreeKey *pKey = treeShmptr(db, pNode->aiKeyPtr[iCell]);
|
|
assert( rc==LSM_OK );
|
|
return ((pKey->flags & LSM_END_DELETE) ? 1 : 0);
|
|
}
|
|
iNode--;
|
|
iCell = pCsr->aiCell[iNode];
|
|
}
|
|
|
|
return 0;
|
|
}
|
|
|
|
static int treePrevIsStartDelete(lsm_db *db, TreeCursor *pCsr){
|
|
int iNode = pCsr->iNode;
|
|
|
|
/* Cursor currently points to a leaf node. */
|
|
assert( (u32)pCsr->iNode==(db->treehdr.root.nHeight-1) );
|
|
|
|
while( iNode>=0 ){
|
|
TreeNode *pNode = pCsr->apTreeNode[iNode];
|
|
int iCell = pCsr->aiCell[iNode]-1;
|
|
if( iCell>=0 && pNode->aiKeyPtr[iCell] ){
|
|
int rc = LSM_OK;
|
|
TreeKey *pKey = treeShmptr(db, pNode->aiKeyPtr[iCell]);
|
|
assert( rc==LSM_OK );
|
|
return ((pKey->flags & LSM_START_DELETE) ? 1 : 0);
|
|
}
|
|
iNode--;
|
|
}
|
|
|
|
return 0;
|
|
}
|
|
|
|
|
|
static int treeInsertEntry(
|
|
lsm_db *pDb, /* Database handle */
|
|
int flags, /* Flags associated with entry */
|
|
void *pKey, /* Pointer to key data */
|
|
int nKey, /* Size of key data in bytes */
|
|
void *pVal, /* Pointer to value data (or NULL) */
|
|
int nVal /* Bytes in value data (or -ve for delete) */
|
|
){
|
|
int rc = LSM_OK; /* Return Code */
|
|
TreeKey *pTreeKey; /* New key-value being inserted */
|
|
u32 iTreeKey;
|
|
TreeRoot *p = &pDb->treehdr.root;
|
|
TreeCursor csr; /* Cursor to seek to pKey/nKey */
|
|
int res = 0; /* Result of seek operation on csr */
|
|
|
|
assert( nVal>=0 || pVal==0 );
|
|
assert_tree_looks_ok(LSM_OK, pTree);
|
|
assert( flags==LSM_INSERT || flags==LSM_POINT_DELETE
|
|
|| flags==LSM_START_DELETE || flags==LSM_END_DELETE
|
|
);
|
|
assert( (flags & LSM_CONTIGUOUS)==0 );
|
|
#if 0
|
|
dump_tree_contents(pDb, "before");
|
|
#endif
|
|
|
|
if( p->iRoot ){
|
|
TreeKey *pRes; /* Key at end of seek operation */
|
|
treeCursorInit(pDb, 0, &csr);
|
|
|
|
/* Seek to the leaf (or internal node) that the new key belongs on */
|
|
rc = lsmTreeCursorSeek(&csr, pKey, nKey, &res);
|
|
pRes = csrGetKey(&csr, &csr.blob, &rc);
|
|
if( rc!=LSM_OK ) return rc;
|
|
assert( pRes );
|
|
|
|
if( flags==LSM_START_DELETE ){
|
|
/* When inserting a start-delete-range entry, if the key that
|
|
** occurs immediately before the new entry is already a START_DELETE,
|
|
** then the new entry is not required. */
|
|
if( (res<=0 && (pRes->flags & LSM_START_DELETE))
|
|
|| (res>0 && treePrevIsStartDelete(pDb, &csr))
|
|
){
|
|
goto insert_entry_out;
|
|
}
|
|
}else if( flags==LSM_END_DELETE ){
|
|
/* When inserting an start-delete-range entry, if the key that
|
|
** occurs immediately after the new entry is already an END_DELETE,
|
|
** then the new entry is not required. */
|
|
if( (res<0 && treeNextIsEndDelete(pDb, &csr))
|
|
|| (res>=0 && (pRes->flags & LSM_END_DELETE))
|
|
){
|
|
goto insert_entry_out;
|
|
}
|
|
}
|
|
|
|
if( res==0 && (flags & (LSM_END_DELETE|LSM_START_DELETE)) ){
|
|
if( pRes->flags & LSM_INSERT ){
|
|
nVal = pRes->nValue;
|
|
pVal = TKV_VAL(pRes);
|
|
}
|
|
flags = flags | pRes->flags;
|
|
}
|
|
|
|
if( flags & (LSM_INSERT|LSM_POINT_DELETE) ){
|
|
if( (res<0 && (pRes->flags & LSM_START_DELETE))
|
|
|| (res>0 && (pRes->flags & LSM_END_DELETE))
|
|
){
|
|
flags = flags | (LSM_END_DELETE|LSM_START_DELETE);
|
|
}else if( res==0 ){
|
|
flags = flags | (pRes->flags & (LSM_END_DELETE|LSM_START_DELETE));
|
|
}
|
|
}
|
|
}else{
|
|
memset(&csr, 0, sizeof(TreeCursor));
|
|
}
|
|
|
|
/* Allocate and populate a new key-value pair structure */
|
|
pTreeKey = newTreeKey(pDb, &iTreeKey, pKey, nKey, pVal, nVal, &rc);
|
|
if( rc!=LSM_OK ) return rc;
|
|
assert( pTreeKey->flags==0 || pTreeKey->flags==LSM_CONTIGUOUS );
|
|
pTreeKey->flags |= flags;
|
|
|
|
if( p->iRoot==0 ){
|
|
/* The tree is completely empty. Add a new root node and install
|
|
** (pKey/nKey) as the middle entry. Even though it is a leaf at the
|
|
** moment, use newTreeNode() to allocate the node (i.e. allocate enough
|
|
** space for the fields used by interior nodes). This is because the
|
|
** treeInsert() routine may convert this node to an interior node. */
|
|
TreeNode *pRoot = newTreeNode(pDb, &p->iRoot, &rc);
|
|
if( rc==LSM_OK ){
|
|
assert( p->nHeight==0 );
|
|
pRoot->aiKeyPtr[1] = iTreeKey;
|
|
p->nHeight = 1;
|
|
}
|
|
}else{
|
|
if( res==0 ){
|
|
/* The search found a match within the tree. */
|
|
treeOverwriteKey(pDb, &csr, iTreeKey, &rc);
|
|
}else{
|
|
/* The cursor now points to the leaf node into which the new entry should
|
|
** be inserted. There may or may not be a free slot within the leaf for
|
|
** the new key-value pair.
|
|
**
|
|
** iSlot is set to the index of the key within pLeaf that the new key
|
|
** should be inserted to the left of (or to a value 1 greater than the
|
|
** index of the rightmost key if the new key is larger than all keys
|
|
** currently stored in the node).
|
|
*/
|
|
int iSlot = csr.aiCell[csr.iNode] + (res<0);
|
|
if( csr.iNode==0 ){
|
|
rc = treeInsert(pDb, &csr, 0, iTreeKey, 0, iSlot);
|
|
}else{
|
|
rc = treeInsertLeaf(pDb, &csr, iTreeKey, iSlot);
|
|
}
|
|
}
|
|
}
|
|
|
|
#if 0
|
|
dump_tree_contents(pDb, "after");
|
|
#endif
|
|
insert_entry_out:
|
|
tblobFree(pDb, &csr.blob);
|
|
assert_tree_looks_ok(rc, pTree);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Insert a new entry into the in-memory tree.
|
|
**
|
|
** If the value of the 5th parameter, nVal, is negative, then a delete-marker
|
|
** is inserted into the tree. In this case the value pointer, pVal, must be
|
|
** NULL.
|
|
*/
|
|
int lsmTreeInsert(
|
|
lsm_db *pDb, /* Database handle */
|
|
void *pKey, /* Pointer to key data */
|
|
int nKey, /* Size of key data in bytes */
|
|
void *pVal, /* Pointer to value data (or NULL) */
|
|
int nVal /* Bytes in value data (or -ve for delete) */
|
|
){
|
|
int flags;
|
|
if( nVal<0 ){
|
|
flags = LSM_POINT_DELETE;
|
|
}else{
|
|
flags = LSM_INSERT;
|
|
}
|
|
|
|
return treeInsertEntry(pDb, flags, pKey, nKey, pVal, nVal);
|
|
}
|
|
|
|
static int treeDeleteEntry(lsm_db *db, TreeCursor *pCsr, u32 iNewptr){
|
|
TreeRoot *p = &db->treehdr.root;
|
|
TreeNode *pNode = pCsr->apTreeNode[pCsr->iNode];
|
|
int iSlot = pCsr->aiCell[pCsr->iNode];
|
|
int bLeaf;
|
|
int rc = LSM_OK;
|
|
|
|
assert( pNode->aiKeyPtr[1] );
|
|
assert( pNode->aiKeyPtr[iSlot] );
|
|
assert( iSlot==0 || iSlot==1 || iSlot==2 );
|
|
assert( ((u32)pCsr->iNode==(db->treehdr.root.nHeight-1))==(iNewptr==0) );
|
|
|
|
bLeaf = ((u32)pCsr->iNode==(p->nHeight-1) && p->nHeight>1);
|
|
|
|
if( pNode->aiKeyPtr[0] || pNode->aiKeyPtr[2] ){
|
|
/* There are currently at least 2 keys on this node. So just create
|
|
** a new copy of the node with one of the keys removed. If the node
|
|
** happens to be the root node of the tree, allocate an entire
|
|
** TreeNode structure instead of just a TreeLeaf. */
|
|
TreeNode *pNew;
|
|
u32 iNew;
|
|
|
|
if( bLeaf ){
|
|
pNew = (TreeNode *)newTreeLeaf(db, &iNew, &rc);
|
|
}else{
|
|
pNew = newTreeNode(db, &iNew, &rc);
|
|
}
|
|
if( pNew ){
|
|
int i;
|
|
int iOut = 1;
|
|
for(i=0; i<4; i++){
|
|
if( i==iSlot ){
|
|
i++;
|
|
if( bLeaf==0 ) pNew->aiChildPtr[iOut] = iNewptr;
|
|
if( i<3 ) pNew->aiKeyPtr[iOut] = pNode->aiKeyPtr[i];
|
|
iOut++;
|
|
}else if( bLeaf || p->nHeight==1 ){
|
|
if( i<3 && pNode->aiKeyPtr[i] ){
|
|
pNew->aiKeyPtr[iOut++] = pNode->aiKeyPtr[i];
|
|
}
|
|
}else{
|
|
if( getChildPtr(pNode, WORKING_VERSION, i) ){
|
|
pNew->aiChildPtr[iOut] = getChildPtr(pNode, WORKING_VERSION, i);
|
|
if( i<3 ) pNew->aiKeyPtr[iOut] = pNode->aiKeyPtr[i];
|
|
iOut++;
|
|
}
|
|
}
|
|
}
|
|
assert( iOut<=4 );
|
|
assert( bLeaf || pNew->aiChildPtr[0]==0 );
|
|
pCsr->iNode--;
|
|
rc = treeUpdatePtr(db, pCsr, iNew);
|
|
}
|
|
|
|
}else if( pCsr->iNode==0 ){
|
|
/* Removing the only key in the root node. iNewptr is the new root. */
|
|
assert( iSlot==1 );
|
|
db->treehdr.root.iRoot = iNewptr;
|
|
db->treehdr.root.nHeight--;
|
|
|
|
}else{
|
|
/* There is only one key on this node and the node is not the root
|
|
** node. Find a peer for this node. Then redistribute the contents of
|
|
** the peer and the parent cell between the parent and either one or
|
|
** two new nodes. */
|
|
TreeNode *pParent; /* Parent tree node */
|
|
int iPSlot;
|
|
u32 iPeer; /* Pointer to peer leaf node */
|
|
int iDir;
|
|
TreeNode *pPeer; /* The peer leaf node */
|
|
TreeNode *pNew1; u32 iNew1; /* First new leaf node */
|
|
|
|
assert( iSlot==1 );
|
|
|
|
pParent = pCsr->apTreeNode[pCsr->iNode-1];
|
|
iPSlot = pCsr->aiCell[pCsr->iNode-1];
|
|
|
|
if( iPSlot>0 && getChildPtr(pParent, WORKING_VERSION, iPSlot-1) ){
|
|
iDir = -1;
|
|
}else{
|
|
iDir = +1;
|
|
}
|
|
iPeer = getChildPtr(pParent, WORKING_VERSION, iPSlot+iDir);
|
|
pPeer = (TreeNode *)treeShmptr(db, iPeer);
|
|
assertIsWorkingChild(db, pNode, pParent, iPSlot);
|
|
|
|
/* Allocate the first new leaf node. This is always required. */
|
|
if( bLeaf ){
|
|
pNew1 = (TreeNode *)newTreeLeaf(db, &iNew1, &rc);
|
|
}else{
|
|
pNew1 = (TreeNode *)newTreeNode(db, &iNew1, &rc);
|
|
}
|
|
|
|
if( pPeer->aiKeyPtr[0] && pPeer->aiKeyPtr[2] ){
|
|
/* Peer node is completely full. This means that two new leaf nodes
|
|
** and a new parent node are required. */
|
|
|
|
TreeNode *pNew2; u32 iNew2; /* Second new leaf node */
|
|
TreeNode *pNewP; u32 iNewP; /* New parent node */
|
|
|
|
if( bLeaf ){
|
|
pNew2 = (TreeNode *)newTreeLeaf(db, &iNew2, &rc);
|
|
}else{
|
|
pNew2 = (TreeNode *)newTreeNode(db, &iNew2, &rc);
|
|
}
|
|
pNewP = copyTreeNode(db, pParent, &iNewP, &rc);
|
|
|
|
if( iDir==-1 ){
|
|
pNew1->aiKeyPtr[1] = pPeer->aiKeyPtr[0];
|
|
if( bLeaf==0 ){
|
|
pNew1->aiChildPtr[1] = getChildPtr(pPeer, WORKING_VERSION, 0);
|
|
pNew1->aiChildPtr[2] = getChildPtr(pPeer, WORKING_VERSION, 1);
|
|
}
|
|
|
|
pNewP->aiChildPtr[iPSlot-1] = iNew1;
|
|
pNewP->aiKeyPtr[iPSlot-1] = pPeer->aiKeyPtr[1];
|
|
pNewP->aiChildPtr[iPSlot] = iNew2;
|
|
|
|
pNew2->aiKeyPtr[0] = pPeer->aiKeyPtr[2];
|
|
pNew2->aiKeyPtr[1] = pParent->aiKeyPtr[iPSlot-1];
|
|
if( bLeaf==0 ){
|
|
pNew2->aiChildPtr[0] = getChildPtr(pPeer, WORKING_VERSION, 2);
|
|
pNew2->aiChildPtr[1] = getChildPtr(pPeer, WORKING_VERSION, 3);
|
|
pNew2->aiChildPtr[2] = iNewptr;
|
|
}
|
|
}else{
|
|
pNew1->aiKeyPtr[1] = pParent->aiKeyPtr[iPSlot];
|
|
if( bLeaf==0 ){
|
|
pNew1->aiChildPtr[1] = iNewptr;
|
|
pNew1->aiChildPtr[2] = getChildPtr(pPeer, WORKING_VERSION, 0);
|
|
}
|
|
|
|
pNewP->aiChildPtr[iPSlot] = iNew1;
|
|
pNewP->aiKeyPtr[iPSlot] = pPeer->aiKeyPtr[0];
|
|
pNewP->aiChildPtr[iPSlot+1] = iNew2;
|
|
|
|
pNew2->aiKeyPtr[0] = pPeer->aiKeyPtr[1];
|
|
pNew2->aiKeyPtr[1] = pPeer->aiKeyPtr[2];
|
|
if( bLeaf==0 ){
|
|
pNew2->aiChildPtr[0] = getChildPtr(pPeer, WORKING_VERSION, 1);
|
|
pNew2->aiChildPtr[1] = getChildPtr(pPeer, WORKING_VERSION, 2);
|
|
pNew2->aiChildPtr[2] = getChildPtr(pPeer, WORKING_VERSION, 3);
|
|
}
|
|
}
|
|
assert( pCsr->iNode>=1 );
|
|
pCsr->iNode -= 2;
|
|
if( rc==LSM_OK ){
|
|
assert( pNew1->aiKeyPtr[1] && pNew2->aiKeyPtr[1] );
|
|
rc = treeUpdatePtr(db, pCsr, iNewP);
|
|
}
|
|
}else{
|
|
int iKOut = 0;
|
|
int iPOut = 0;
|
|
int i;
|
|
|
|
pCsr->iNode--;
|
|
|
|
if( iDir==1 ){
|
|
pNew1->aiKeyPtr[iKOut++] = pParent->aiKeyPtr[iPSlot];
|
|
if( bLeaf==0 ) pNew1->aiChildPtr[iPOut++] = iNewptr;
|
|
}
|
|
for(i=0; i<3; i++){
|
|
if( pPeer->aiKeyPtr[i] ){
|
|
pNew1->aiKeyPtr[iKOut++] = pPeer->aiKeyPtr[i];
|
|
}
|
|
}
|
|
if( bLeaf==0 ){
|
|
for(i=0; i<4; i++){
|
|
if( getChildPtr(pPeer, WORKING_VERSION, i) ){
|
|
pNew1->aiChildPtr[iPOut++] = getChildPtr(pPeer, WORKING_VERSION, i);
|
|
}
|
|
}
|
|
}
|
|
if( iDir==-1 ){
|
|
iPSlot--;
|
|
pNew1->aiKeyPtr[iKOut++] = pParent->aiKeyPtr[iPSlot];
|
|
if( bLeaf==0 ) pNew1->aiChildPtr[iPOut++] = iNewptr;
|
|
pCsr->aiCell[pCsr->iNode] = (u8)iPSlot;
|
|
}
|
|
|
|
rc = treeDeleteEntry(db, pCsr, iNew1);
|
|
}
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Delete a range of keys from the tree structure (i.e. the lsm_delete_range()
|
|
** function, not lsm_delete()).
|
|
**
|
|
** This is a two step process:
|
|
**
|
|
** 1) Remove all entries currently stored in the tree that have keys
|
|
** that fall into the deleted range.
|
|
**
|
|
** TODO: There are surely good ways to optimize this step - removing
|
|
** a range of keys from a b-tree. But for now, this function removes
|
|
** them one at a time using the usual approach.
|
|
**
|
|
** 2) Unless the largest key smaller than or equal to (pKey1/nKey1) is
|
|
** already marked as START_DELETE, insert a START_DELETE key.
|
|
** Similarly, unless the smallest key greater than or equal to
|
|
** (pKey2/nKey2) is already START_END, insert a START_END key.
|
|
*/
|
|
int lsmTreeDelete(
|
|
lsm_db *db,
|
|
void *pKey1, int nKey1, /* Start of range */
|
|
void *pKey2, int nKey2 /* End of range */
|
|
){
|
|
int rc = LSM_OK;
|
|
int bDone = 0;
|
|
TreeRoot *p = &db->treehdr.root;
|
|
TreeBlob blob = {0, 0};
|
|
|
|
/* The range must be sensible - that (key1 < key2). */
|
|
assert( treeKeycmp(pKey1, nKey1, pKey2, nKey2)<0 );
|
|
assert( assert_delete_ranges_match(db) );
|
|
|
|
#if 0
|
|
static int nCall = 0;
|
|
printf("\n");
|
|
nCall++;
|
|
printf("%d delete %s .. %s\n", nCall, (char *)pKey1, (char *)pKey2);
|
|
dump_tree_contents(db, "before delete");
|
|
#endif
|
|
|
|
/* Step 1. This loop runs until the tree contains no keys within the
|
|
** range being deleted. Or until an error occurs. */
|
|
while( bDone==0 && rc==LSM_OK ){
|
|
int res;
|
|
TreeCursor csr; /* Cursor to seek to first key in range */
|
|
void *pDel; int nDel; /* Key to (possibly) delete this iteration */
|
|
#ifndef NDEBUG
|
|
int nEntry = treeCountEntries(db);
|
|
#endif
|
|
|
|
/* Seek the cursor to the first entry in the tree greater than pKey1. */
|
|
treeCursorInit(db, 0, &csr);
|
|
lsmTreeCursorSeek(&csr, pKey1, nKey1, &res);
|
|
if( res<=0 && lsmTreeCursorValid(&csr) ) lsmTreeCursorNext(&csr);
|
|
|
|
/* If there is no such entry, or if it is greater than pKey2, then the
|
|
** tree now contains no keys in the range being deleted. In this case
|
|
** break out of the loop. */
|
|
bDone = 1;
|
|
if( lsmTreeCursorValid(&csr) ){
|
|
lsmTreeCursorKey(&csr, 0, &pDel, &nDel);
|
|
if( treeKeycmp(pDel, nDel, pKey2, nKey2)<0 ) bDone = 0;
|
|
}
|
|
|
|
if( bDone==0 ){
|
|
if( (u32)csr.iNode==(p->nHeight-1) ){
|
|
/* The element to delete already lies on a leaf node */
|
|
rc = treeDeleteEntry(db, &csr, 0);
|
|
}else{
|
|
/* 1. Overwrite the current key with a copy of the next key in the
|
|
** tree (key N).
|
|
**
|
|
** 2. Seek to key N (cursor will stop at the internal node copy of
|
|
** N). Move to the next key (original copy of N). Delete
|
|
** this entry.
|
|
*/
|
|
u32 iKey;
|
|
TreeKey *pKey;
|
|
int iNode = csr.iNode;
|
|
lsmTreeCursorNext(&csr);
|
|
assert( (u32)csr.iNode==(p->nHeight-1) );
|
|
|
|
iKey = csr.apTreeNode[csr.iNode]->aiKeyPtr[csr.aiCell[csr.iNode]];
|
|
lsmTreeCursorPrev(&csr);
|
|
|
|
treeOverwriteKey(db, &csr, iKey, &rc);
|
|
pKey = treeShmkey(db, iKey, TKV_LOADKEY, &blob, &rc);
|
|
if( pKey ){
|
|
rc = lsmTreeCursorSeek(&csr, TKV_KEY(pKey), pKey->nKey, &res);
|
|
}
|
|
if( rc==LSM_OK ){
|
|
assert( res==0 && csr.iNode==iNode );
|
|
rc = lsmTreeCursorNext(&csr);
|
|
if( rc==LSM_OK ){
|
|
rc = treeDeleteEntry(db, &csr, 0);
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
/* Clean up any memory allocated by the cursor. */
|
|
tblobFree(db, &csr.blob);
|
|
#if 0
|
|
dump_tree_contents(db, "ddd delete");
|
|
#endif
|
|
assert( bDone || treeCountEntries(db)==(nEntry-1) );
|
|
}
|
|
|
|
#if 0
|
|
dump_tree_contents(db, "during delete");
|
|
#endif
|
|
|
|
/* Now insert the START_DELETE and END_DELETE keys. */
|
|
if( rc==LSM_OK ){
|
|
rc = treeInsertEntry(db, LSM_START_DELETE, pKey1, nKey1, 0, -1);
|
|
}
|
|
#if 0
|
|
dump_tree_contents(db, "during delete 2");
|
|
#endif
|
|
if( rc==LSM_OK ){
|
|
rc = treeInsertEntry(db, LSM_END_DELETE, pKey2, nKey2, 0, -1);
|
|
}
|
|
|
|
#if 0
|
|
dump_tree_contents(db, "after delete");
|
|
#endif
|
|
|
|
tblobFree(db, &blob);
|
|
assert( assert_delete_ranges_match(db) );
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Return, in bytes, the amount of memory currently used by the tree
|
|
** structure.
|
|
*/
|
|
int lsmTreeSize(lsm_db *pDb){
|
|
return pDb->treehdr.root.nByte;
|
|
}
|
|
|
|
/*
|
|
** Open a cursor on the in-memory tree pTree.
|
|
*/
|
|
int lsmTreeCursorNew(lsm_db *pDb, int bOld, TreeCursor **ppCsr){
|
|
TreeCursor *pCsr;
|
|
*ppCsr = pCsr = lsmMalloc(pDb->pEnv, sizeof(TreeCursor));
|
|
if( pCsr ){
|
|
treeCursorInit(pDb, bOld, pCsr);
|
|
return LSM_OK;
|
|
}
|
|
return LSM_NOMEM_BKPT;
|
|
}
|
|
|
|
/*
|
|
** Close an in-memory tree cursor.
|
|
*/
|
|
void lsmTreeCursorDestroy(TreeCursor *pCsr){
|
|
if( pCsr ){
|
|
tblobFree(pCsr->pDb, &pCsr->blob);
|
|
lsmFree(pCsr->pDb->pEnv, pCsr);
|
|
}
|
|
}
|
|
|
|
void lsmTreeCursorReset(TreeCursor *pCsr){
|
|
if( pCsr ){
|
|
pCsr->iNode = -1;
|
|
pCsr->pSave = 0;
|
|
}
|
|
}
|
|
|
|
#ifndef NDEBUG
|
|
static int treeCsrCompare(TreeCursor *pCsr, void *pKey, int nKey, int *pRc){
|
|
TreeKey *p;
|
|
int cmp = 0;
|
|
assert( pCsr->iNode>=0 );
|
|
p = csrGetKey(pCsr, &pCsr->blob, pRc);
|
|
if( p ){
|
|
cmp = treeKeycmp(TKV_KEY(p), p->nKey, pKey, nKey);
|
|
}
|
|
return cmp;
|
|
}
|
|
#endif
|
|
|
|
|
|
/*
|
|
** Attempt to seek the cursor passed as the first argument to key (pKey/nKey)
|
|
** in the tree structure. If an exact match for the key is found, leave the
|
|
** cursor pointing to it and set *pRes to zero before returning. If an
|
|
** exact match cannot be found, do one of the following:
|
|
**
|
|
** * Leave the cursor pointing to the smallest element in the tree that
|
|
** is larger than the key and set *pRes to +1, or
|
|
**
|
|
** * Leave the cursor pointing to the largest element in the tree that
|
|
** is smaller than the key and set *pRes to -1, or
|
|
**
|
|
** * If the tree is empty, leave the cursor at EOF and set *pRes to -1.
|
|
*/
|
|
int lsmTreeCursorSeek(TreeCursor *pCsr, void *pKey, int nKey, int *pRes){
|
|
int rc = LSM_OK; /* Return code */
|
|
lsm_db *pDb = pCsr->pDb;
|
|
TreeRoot *pRoot = pCsr->pRoot;
|
|
u32 iNodePtr; /* Location of current node in search */
|
|
|
|
/* Discard any saved position data */
|
|
treeCursorRestore(pCsr, 0);
|
|
|
|
iNodePtr = pRoot->iRoot;
|
|
if( iNodePtr==0 ){
|
|
/* Either an error occurred or the tree is completely empty. */
|
|
assert( rc!=LSM_OK || pRoot->iRoot==0 );
|
|
*pRes = -1;
|
|
pCsr->iNode = -1;
|
|
}else{
|
|
TreeBlob b = {0, 0};
|
|
int res = 0; /* Result of comparison function */
|
|
int iNode = -1;
|
|
while( iNodePtr ){
|
|
TreeNode *pNode; /* Node at location iNodePtr */
|
|
int iTest; /* Index of second key to test (0 or 2) */
|
|
u32 iTreeKey;
|
|
TreeKey *pTreeKey; /* Key to compare against */
|
|
|
|
pNode = (TreeNode *)treeShmptrUnsafe(pDb, iNodePtr);
|
|
iNode++;
|
|
pCsr->apTreeNode[iNode] = pNode;
|
|
|
|
/* Compare (pKey/nKey) with the key in the middle slot of B-tree node
|
|
** pNode. The middle slot is never empty. If the comparison is a match,
|
|
** then the search is finished. Break out of the loop. */
|
|
pTreeKey = (TreeKey*)treeShmptrUnsafe(pDb, pNode->aiKeyPtr[1]);
|
|
if( !(pTreeKey->flags & LSM_CONTIGUOUS) ){
|
|
pTreeKey = treeShmkey(pDb, pNode->aiKeyPtr[1], TKV_LOADKEY, &b, &rc);
|
|
if( rc!=LSM_OK ) break;
|
|
}
|
|
res = treeKeycmp((void *)&pTreeKey[1], pTreeKey->nKey, pKey, nKey);
|
|
if( res==0 ){
|
|
pCsr->aiCell[iNode] = 1;
|
|
break;
|
|
}
|
|
|
|
/* Based on the results of the previous comparison, compare (pKey/nKey)
|
|
** to either the left or right key of the B-tree node, if such a key
|
|
** exists. */
|
|
iTest = (res>0 ? 0 : 2);
|
|
iTreeKey = pNode->aiKeyPtr[iTest];
|
|
if( iTreeKey ){
|
|
pTreeKey = (TreeKey*)treeShmptrUnsafe(pDb, iTreeKey);
|
|
if( !(pTreeKey->flags & LSM_CONTIGUOUS) ){
|
|
pTreeKey = treeShmkey(pDb, iTreeKey, TKV_LOADKEY, &b, &rc);
|
|
if( rc ) break;
|
|
}
|
|
res = treeKeycmp((void *)&pTreeKey[1], pTreeKey->nKey, pKey, nKey);
|
|
if( res==0 ){
|
|
pCsr->aiCell[iNode] = (u8)iTest;
|
|
break;
|
|
}
|
|
}else{
|
|
iTest = 1;
|
|
}
|
|
|
|
if( (u32)iNode<(pRoot->nHeight-1) ){
|
|
iNodePtr = getChildPtr(pNode, pRoot->iTransId, iTest + (res<0));
|
|
}else{
|
|
iNodePtr = 0;
|
|
}
|
|
pCsr->aiCell[iNode] = (u8)(iTest + (iNodePtr && (res<0)));
|
|
}
|
|
|
|
*pRes = res;
|
|
pCsr->iNode = iNode;
|
|
tblobFree(pDb, &b);
|
|
}
|
|
|
|
/* assert() that *pRes has been set properly */
|
|
#ifndef NDEBUG
|
|
if( rc==LSM_OK && lsmTreeCursorValid(pCsr) ){
|
|
int cmp = treeCsrCompare(pCsr, pKey, nKey, &rc);
|
|
assert( rc!=LSM_OK || *pRes==cmp || (*pRes ^ cmp)>0 );
|
|
}
|
|
#endif
|
|
|
|
return rc;
|
|
}
|
|
|
|
int lsmTreeCursorNext(TreeCursor *pCsr){
|
|
#ifndef NDEBUG
|
|
TreeKey *pK1;
|
|
TreeBlob key1 = {0, 0};
|
|
#endif
|
|
lsm_db *pDb = pCsr->pDb;
|
|
TreeRoot *pRoot = pCsr->pRoot;
|
|
const int iLeaf = pRoot->nHeight-1;
|
|
int iCell;
|
|
int rc = LSM_OK;
|
|
TreeNode *pNode;
|
|
|
|
/* Restore the cursor position, if required */
|
|
int iRestore = 0;
|
|
treeCursorRestore(pCsr, &iRestore);
|
|
if( iRestore>0 ) return LSM_OK;
|
|
|
|
/* Save a pointer to the current key. This is used in an assert() at the
|
|
** end of this function - to check that the 'next' key really is larger
|
|
** than the current key. */
|
|
#ifndef NDEBUG
|
|
pK1 = csrGetKey(pCsr, &key1, &rc);
|
|
if( rc!=LSM_OK ) return rc;
|
|
#endif
|
|
|
|
assert( lsmTreeCursorValid(pCsr) );
|
|
assert( pCsr->aiCell[pCsr->iNode]<3 );
|
|
|
|
pNode = pCsr->apTreeNode[pCsr->iNode];
|
|
iCell = ++pCsr->aiCell[pCsr->iNode];
|
|
|
|
/* If the current node is not a leaf, and the current cell has sub-tree
|
|
** associated with it, descend to the left-most key on the left-most
|
|
** leaf of the sub-tree. */
|
|
if( pCsr->iNode<iLeaf && getChildPtr(pNode, pRoot->iTransId, iCell) ){
|
|
do {
|
|
u32 iNodePtr;
|
|
pCsr->iNode++;
|
|
iNodePtr = getChildPtr(pNode, pRoot->iTransId, iCell);
|
|
pNode = (TreeNode *)treeShmptr(pDb, iNodePtr);
|
|
pCsr->apTreeNode[pCsr->iNode] = pNode;
|
|
iCell = pCsr->aiCell[pCsr->iNode] = (pNode->aiKeyPtr[0]==0);
|
|
}while( pCsr->iNode < iLeaf );
|
|
}
|
|
|
|
/* Otherwise, the next key is found by following pointer up the tree
|
|
** until there is a key immediately to the right of the pointer followed
|
|
** to reach the sub-tree containing the current key. */
|
|
else if( iCell>=3 || pNode->aiKeyPtr[iCell]==0 ){
|
|
while( (--pCsr->iNode)>=0 ){
|
|
iCell = pCsr->aiCell[pCsr->iNode];
|
|
if( iCell<3 && pCsr->apTreeNode[pCsr->iNode]->aiKeyPtr[iCell] ) break;
|
|
}
|
|
}
|
|
|
|
#ifndef NDEBUG
|
|
if( pCsr->iNode>=0 ){
|
|
TreeKey *pK2 = csrGetKey(pCsr, &pCsr->blob, &rc);
|
|
assert( rc||treeKeycmp(TKV_KEY(pK2),pK2->nKey,TKV_KEY(pK1),pK1->nKey)>=0 );
|
|
}
|
|
tblobFree(pDb, &key1);
|
|
#endif
|
|
|
|
return rc;
|
|
}
|
|
|
|
int lsmTreeCursorPrev(TreeCursor *pCsr){
|
|
#ifndef NDEBUG
|
|
TreeKey *pK1;
|
|
TreeBlob key1 = {0, 0};
|
|
#endif
|
|
lsm_db *pDb = pCsr->pDb;
|
|
TreeRoot *pRoot = pCsr->pRoot;
|
|
const int iLeaf = pRoot->nHeight-1;
|
|
int iCell;
|
|
int rc = LSM_OK;
|
|
TreeNode *pNode;
|
|
|
|
/* Restore the cursor position, if required */
|
|
int iRestore = 0;
|
|
treeCursorRestore(pCsr, &iRestore);
|
|
if( iRestore<0 ) return LSM_OK;
|
|
|
|
/* Save a pointer to the current key. This is used in an assert() at the
|
|
** end of this function - to check that the 'next' key really is smaller
|
|
** than the current key. */
|
|
#ifndef NDEBUG
|
|
pK1 = csrGetKey(pCsr, &key1, &rc);
|
|
if( rc!=LSM_OK ) return rc;
|
|
#endif
|
|
|
|
assert( lsmTreeCursorValid(pCsr) );
|
|
pNode = pCsr->apTreeNode[pCsr->iNode];
|
|
iCell = pCsr->aiCell[pCsr->iNode];
|
|
assert( iCell>=0 && iCell<3 );
|
|
|
|
/* If the current node is not a leaf, and the current cell has sub-tree
|
|
** associated with it, descend to the right-most key on the right-most
|
|
** leaf of the sub-tree. */
|
|
if( pCsr->iNode<iLeaf && getChildPtr(pNode, pRoot->iTransId, iCell) ){
|
|
do {
|
|
u32 iNodePtr;
|
|
pCsr->iNode++;
|
|
iNodePtr = getChildPtr(pNode, pRoot->iTransId, iCell);
|
|
pNode = (TreeNode *)treeShmptr(pDb, iNodePtr);
|
|
if( rc!=LSM_OK ) break;
|
|
pCsr->apTreeNode[pCsr->iNode] = pNode;
|
|
iCell = 1 + (pNode->aiKeyPtr[2]!=0) + (pCsr->iNode < iLeaf);
|
|
pCsr->aiCell[pCsr->iNode] = (u8)iCell;
|
|
}while( pCsr->iNode < iLeaf );
|
|
}
|
|
|
|
/* Otherwise, the next key is found by following pointer up the tree until
|
|
** there is a key immediately to the left of the pointer followed to reach
|
|
** the sub-tree containing the current key. */
|
|
else{
|
|
do {
|
|
iCell = pCsr->aiCell[pCsr->iNode]-1;
|
|
if( iCell>=0 && pCsr->apTreeNode[pCsr->iNode]->aiKeyPtr[iCell] ) break;
|
|
}while( (--pCsr->iNode)>=0 );
|
|
pCsr->aiCell[pCsr->iNode] = (u8)iCell;
|
|
}
|
|
|
|
#ifndef NDEBUG
|
|
if( pCsr->iNode>=0 ){
|
|
TreeKey *pK2 = csrGetKey(pCsr, &pCsr->blob, &rc);
|
|
assert( rc || treeKeycmp(TKV_KEY(pK2),pK2->nKey,TKV_KEY(pK1),pK1->nKey)<0 );
|
|
}
|
|
tblobFree(pDb, &key1);
|
|
#endif
|
|
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Move the cursor to the first (bLast==0) or last (bLast!=0) entry in the
|
|
** in-memory tree.
|
|
*/
|
|
int lsmTreeCursorEnd(TreeCursor *pCsr, int bLast){
|
|
lsm_db *pDb = pCsr->pDb;
|
|
TreeRoot *pRoot = pCsr->pRoot;
|
|
int rc = LSM_OK;
|
|
|
|
u32 iNodePtr;
|
|
pCsr->iNode = -1;
|
|
|
|
/* Discard any saved position data */
|
|
treeCursorRestore(pCsr, 0);
|
|
|
|
iNodePtr = pRoot->iRoot;
|
|
while( iNodePtr ){
|
|
int iCell;
|
|
TreeNode *pNode;
|
|
|
|
pNode = (TreeNode *)treeShmptr(pDb, iNodePtr);
|
|
if( rc ) break;
|
|
|
|
if( bLast ){
|
|
iCell = ((pNode->aiKeyPtr[2]==0) ? 2 : 3);
|
|
}else{
|
|
iCell = ((pNode->aiKeyPtr[0]==0) ? 1 : 0);
|
|
}
|
|
pCsr->iNode++;
|
|
pCsr->apTreeNode[pCsr->iNode] = pNode;
|
|
|
|
if( (u32)pCsr->iNode<pRoot->nHeight-1 ){
|
|
iNodePtr = getChildPtr(pNode, pRoot->iTransId, iCell);
|
|
}else{
|
|
iNodePtr = 0;
|
|
}
|
|
pCsr->aiCell[pCsr->iNode] = (u8)(iCell - (iNodePtr==0 && bLast));
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
int lsmTreeCursorFlags(TreeCursor *pCsr){
|
|
int flags = 0;
|
|
if( pCsr && pCsr->iNode>=0 ){
|
|
int rc = LSM_OK;
|
|
TreeKey *pKey = (TreeKey *)treeShmptrUnsafe(pCsr->pDb,
|
|
pCsr->apTreeNode[pCsr->iNode]->aiKeyPtr[pCsr->aiCell[pCsr->iNode]]
|
|
);
|
|
assert( rc==LSM_OK );
|
|
flags = (pKey->flags & ~LSM_CONTIGUOUS);
|
|
}
|
|
return flags;
|
|
}
|
|
|
|
int lsmTreeCursorKey(TreeCursor *pCsr, int *pFlags, void **ppKey, int *pnKey){
|
|
TreeKey *pTreeKey;
|
|
int rc = LSM_OK;
|
|
|
|
assert( lsmTreeCursorValid(pCsr) );
|
|
|
|
pTreeKey = pCsr->pSave;
|
|
if( !pTreeKey ){
|
|
pTreeKey = csrGetKey(pCsr, &pCsr->blob, &rc);
|
|
}
|
|
if( rc==LSM_OK ){
|
|
*pnKey = pTreeKey->nKey;
|
|
if( pFlags ) *pFlags = pTreeKey->flags;
|
|
*ppKey = (void *)&pTreeKey[1];
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
int lsmTreeCursorValue(TreeCursor *pCsr, void **ppVal, int *pnVal){
|
|
int res = 0;
|
|
int rc;
|
|
|
|
rc = treeCursorRestore(pCsr, &res);
|
|
if( res==0 ){
|
|
TreeKey *pTreeKey = csrGetKey(pCsr, &pCsr->blob, &rc);
|
|
if( rc==LSM_OK ){
|
|
if( pTreeKey->flags & LSM_INSERT ){
|
|
*pnVal = pTreeKey->nValue;
|
|
*ppVal = TKV_VAL(pTreeKey);
|
|
}else{
|
|
*ppVal = 0;
|
|
*pnVal = -1;
|
|
}
|
|
}
|
|
}else{
|
|
*ppVal = 0;
|
|
*pnVal = 0;
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Return true if the cursor currently points to a valid entry.
|
|
*/
|
|
int lsmTreeCursorValid(TreeCursor *pCsr){
|
|
return (pCsr && (pCsr->pSave || pCsr->iNode>=0));
|
|
}
|
|
|
|
/*
|
|
** Store a mark in *pMark. Later on, a call to lsmTreeRollback() with a
|
|
** pointer to the same TreeMark structure may be used to roll the tree
|
|
** contents back to their current state.
|
|
*/
|
|
void lsmTreeMark(lsm_db *pDb, TreeMark *pMark){
|
|
pMark->iRoot = pDb->treehdr.root.iRoot;
|
|
pMark->nHeight = pDb->treehdr.root.nHeight;
|
|
pMark->iWrite = pDb->treehdr.iWrite;
|
|
pMark->nChunk = pDb->treehdr.nChunk;
|
|
pMark->iNextShmid = pDb->treehdr.iNextShmid;
|
|
pMark->iRollback = intArraySize(&pDb->rollback);
|
|
}
|
|
|
|
/*
|
|
** Roll back to mark pMark. Structure *pMark should have been previously
|
|
** populated by a call to lsmTreeMark().
|
|
*/
|
|
void lsmTreeRollback(lsm_db *pDb, TreeMark *pMark){
|
|
int iIdx;
|
|
int nIdx;
|
|
u32 iNext;
|
|
ShmChunk *pChunk;
|
|
u32 iChunk;
|
|
u32 iShmid;
|
|
|
|
/* Revert all required v2 pointers. */
|
|
nIdx = intArraySize(&pDb->rollback);
|
|
for(iIdx = pMark->iRollback; iIdx<nIdx; iIdx++){
|
|
TreeNode *pNode;
|
|
pNode = treeShmptr(pDb, intArrayEntry(&pDb->rollback, iIdx));
|
|
assert( pNode );
|
|
pNode->iV2 = 0;
|
|
pNode->iV2Child = 0;
|
|
pNode->iV2Ptr = 0;
|
|
}
|
|
intArrayTruncate(&pDb->rollback, pMark->iRollback);
|
|
|
|
/* Restore the free-chunk list. */
|
|
assert( pMark->iWrite!=0 );
|
|
iChunk = treeOffsetToChunk(pMark->iWrite-1);
|
|
pChunk = treeShmChunk(pDb, iChunk);
|
|
iNext = pChunk->iNext;
|
|
pChunk->iNext = 0;
|
|
|
|
pChunk = treeShmChunk(pDb, pDb->treehdr.iFirst);
|
|
iShmid = pChunk->iShmid-1;
|
|
|
|
while( iNext ){
|
|
u32 iFree = iNext; /* Current chunk being rollback-freed */
|
|
ShmChunk *pFree; /* Pointer to chunk iFree */
|
|
|
|
pFree = treeShmChunk(pDb, iFree);
|
|
iNext = pFree->iNext;
|
|
|
|
if( iFree<pMark->nChunk ){
|
|
pFree->iNext = pDb->treehdr.iFirst;
|
|
pFree->iShmid = iShmid--;
|
|
pDb->treehdr.iFirst = iFree;
|
|
}
|
|
}
|
|
|
|
/* Restore the tree-header fields */
|
|
pDb->treehdr.root.iRoot = pMark->iRoot;
|
|
pDb->treehdr.root.nHeight = pMark->nHeight;
|
|
pDb->treehdr.iWrite = pMark->iWrite;
|
|
pDb->treehdr.nChunk = pMark->nChunk;
|
|
pDb->treehdr.iNextShmid = pMark->iNextShmid;
|
|
}
|
|
|
|
/*
|
|
** Load the in-memory tree header from shared-memory into pDb->treehdr.
|
|
** If the header cannot be loaded, return LSM_PROTOCOL.
|
|
**
|
|
** If the header is successfully loaded and parameter piRead is not NULL,
|
|
** is is set to 1 if the header was loaded from ShmHeader.hdr1, or 2 if
|
|
** the header was loaded from ShmHeader.hdr2.
|
|
*/
|
|
int lsmTreeLoadHeader(lsm_db *pDb, int *piRead){
|
|
int nRem = LSM_ATTEMPTS_BEFORE_PROTOCOL;
|
|
while( (nRem--)>0 ){
|
|
ShmHeader *pShm = pDb->pShmhdr;
|
|
|
|
memcpy(&pDb->treehdr, &pShm->hdr1, sizeof(TreeHeader));
|
|
if( treeHeaderChecksumOk(&pDb->treehdr) ){
|
|
if( piRead ) *piRead = 1;
|
|
return LSM_OK;
|
|
}
|
|
memcpy(&pDb->treehdr, &pShm->hdr2, sizeof(TreeHeader));
|
|
if( treeHeaderChecksumOk(&pDb->treehdr) ){
|
|
if( piRead ) *piRead = 2;
|
|
return LSM_OK;
|
|
}
|
|
|
|
lsmShmBarrier(pDb);
|
|
}
|
|
return LSM_PROTOCOL_BKPT;
|
|
}
|
|
|
|
int lsmTreeLoadHeaderOk(lsm_db *pDb, int iRead){
|
|
TreeHeader *p = (iRead==1) ? &pDb->pShmhdr->hdr1 : &pDb->pShmhdr->hdr2;
|
|
assert( iRead==1 || iRead==2 );
|
|
return (0==memcmp(pDb->treehdr.aCksum, p->aCksum, sizeof(u32)*2));
|
|
}
|
|
|
|
/*
|
|
** This function is called to conclude a transaction. If argument bCommit
|
|
** is true, the transaction is committed. Otherwise it is rolled back.
|
|
*/
|
|
int lsmTreeEndTransaction(lsm_db *pDb, int bCommit){
|
|
ShmHeader *pShm = pDb->pShmhdr;
|
|
|
|
treeHeaderChecksum(&pDb->treehdr, pDb->treehdr.aCksum);
|
|
memcpy(&pShm->hdr2, &pDb->treehdr, sizeof(TreeHeader));
|
|
lsmShmBarrier(pDb);
|
|
memcpy(&pShm->hdr1, &pDb->treehdr, sizeof(TreeHeader));
|
|
pShm->bWriter = 0;
|
|
intArrayFree(pDb->pEnv, &pDb->rollback);
|
|
|
|
return LSM_OK;
|
|
}
|
|
|
|
#ifndef NDEBUG
|
|
static int assert_delete_ranges_match(lsm_db *db){
|
|
int prev = 0;
|
|
TreeBlob blob = {0, 0};
|
|
TreeCursor csr; /* Cursor used to iterate through tree */
|
|
int rc;
|
|
|
|
treeCursorInit(db, 0, &csr);
|
|
for( rc = lsmTreeCursorEnd(&csr, 0);
|
|
rc==LSM_OK && lsmTreeCursorValid(&csr);
|
|
rc = lsmTreeCursorNext(&csr)
|
|
){
|
|
TreeKey *pKey = csrGetKey(&csr, &blob, &rc);
|
|
if( rc!=LSM_OK ) break;
|
|
assert( ((prev&LSM_START_DELETE)==0)==((pKey->flags&LSM_END_DELETE)==0) );
|
|
prev = pKey->flags;
|
|
}
|
|
|
|
tblobFree(csr.pDb, &csr.blob);
|
|
tblobFree(csr.pDb, &blob);
|
|
|
|
return 1;
|
|
}
|
|
|
|
static int treeCountEntries(lsm_db *db){
|
|
TreeCursor csr; /* Cursor used to iterate through tree */
|
|
int rc;
|
|
int nEntry = 0;
|
|
|
|
treeCursorInit(db, 0, &csr);
|
|
for( rc = lsmTreeCursorEnd(&csr, 0);
|
|
rc==LSM_OK && lsmTreeCursorValid(&csr);
|
|
rc = lsmTreeCursorNext(&csr)
|
|
){
|
|
nEntry++;
|
|
}
|
|
|
|
tblobFree(csr.pDb, &csr.blob);
|
|
|
|
return nEntry;
|
|
}
|
|
#endif
|