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6673 lines
210 KiB
C
6673 lines
210 KiB
C
/*
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** 2004 April 6
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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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** $Id$
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**
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** This file implements a external (disk-based) database using BTrees.
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** For a detailed discussion of BTrees, refer to
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**
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** Donald E. Knuth, THE ART OF COMPUTER PROGRAMMING, Volume 3:
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** "Sorting And Searching", pages 473-480. Addison-Wesley
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** Publishing Company, Reading, Massachusetts.
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**
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** The basic idea is that each page of the file contains N database
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** entries and N+1 pointers to subpages.
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**
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** ----------------------------------------------------------------
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** | Ptr(0) | Key(0) | Ptr(1) | Key(1) | ... | Key(N) | Ptr(N+1) |
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** ----------------------------------------------------------------
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**
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** All of the keys on the page that Ptr(0) points to have values less
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** than Key(0). All of the keys on page Ptr(1) and its subpages have
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** values greater than Key(0) and less than Key(1). All of the keys
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** on Ptr(N+1) and its subpages have values greater than Key(N). And
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** so forth.
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**
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** Finding a particular key requires reading O(log(M)) pages from the
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** disk where M is the number of entries in the tree.
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**
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** In this implementation, a single file can hold one or more separate
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** BTrees. Each BTree is identified by the index of its root page. The
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** key and data for any entry are combined to form the "payload". A
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** fixed amount of payload can be carried directly on the database
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** page. If the payload is larger than the preset amount then surplus
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** bytes are stored on overflow pages. The payload for an entry
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** and the preceding pointer are combined to form a "Cell". Each
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** page has a small header which contains the Ptr(N+1) pointer and other
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** information such as the size of key and data.
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**
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** FORMAT DETAILS
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**
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** The file is divided into pages. The first page is called page 1,
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** the second is page 2, and so forth. A page number of zero indicates
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** "no such page". The page size can be anything between 512 and 65536.
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** Each page can be either a btree page, a freelist page or an overflow
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** page.
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**
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** The first page is always a btree page. The first 100 bytes of the first
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** page contain a special header (the "file header") that describes the file.
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** The format of the file header is as follows:
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**
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** OFFSET SIZE DESCRIPTION
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** 0 16 Header string: "SQLite format 3\000"
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** 16 2 Page size in bytes.
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** 18 1 File format write version
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** 19 1 File format read version
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** 20 1 Bytes of unused space at the end of each page
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** 21 1 Max embedded payload fraction
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** 22 1 Min embedded payload fraction
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** 23 1 Min leaf payload fraction
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** 24 4 File change counter
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** 28 4 Reserved for future use
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** 32 4 First freelist page
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** 36 4 Number of freelist pages in the file
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** 40 60 15 4-byte meta values passed to higher layers
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**
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** All of the integer values are big-endian (most significant byte first).
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**
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** The file change counter is incremented when the database is changed more
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** than once within the same second. This counter, together with the
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** modification time of the file, allows other processes to know
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** when the file has changed and thus when they need to flush their
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** cache.
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**
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** The max embedded payload fraction is the amount of the total usable
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** space in a page that can be consumed by a single cell for standard
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** B-tree (non-LEAFDATA) tables. A value of 255 means 100%. The default
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** is to limit the maximum cell size so that at least 4 cells will fit
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** on one page. Thus the default max embedded payload fraction is 64.
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**
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** If the payload for a cell is larger than the max payload, then extra
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** payload is spilled to overflow pages. Once an overflow page is allocated,
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** as many bytes as possible are moved into the overflow pages without letting
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** the cell size drop below the min embedded payload fraction.
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**
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** The min leaf payload fraction is like the min embedded payload fraction
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** except that it applies to leaf nodes in a LEAFDATA tree. The maximum
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** payload fraction for a LEAFDATA tree is always 100% (or 255) and it
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** not specified in the header.
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**
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** Each btree pages is divided into three sections: The header, the
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** cell pointer array, and the cell area area. Page 1 also has a 100-byte
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** file header that occurs before the page header.
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**
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** |----------------|
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** | file header | 100 bytes. Page 1 only.
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** |----------------|
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** | page header | 8 bytes for leaves. 12 bytes for interior nodes
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** |----------------|
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** | cell pointer | | 2 bytes per cell. Sorted order.
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** | array | | Grows downward
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** | | v
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** |----------------|
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** | unallocated |
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** | space |
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** |----------------| ^ Grows upwards
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** | cell content | | Arbitrary order interspersed with freeblocks.
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** | area | | and free space fragments.
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** |----------------|
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**
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** The page headers looks like this:
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**
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** OFFSET SIZE DESCRIPTION
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** 0 1 Flags. 1: intkey, 2: zerodata, 4: leafdata, 8: leaf
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** 1 2 byte offset to the first freeblock
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** 3 2 number of cells on this page
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** 5 2 first byte of the cell content area
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** 7 1 number of fragmented free bytes
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** 8 4 Right child (the Ptr(N+1) value). Omitted on leaves.
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**
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** The flags define the format of this btree page. The leaf flag means that
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** this page has no children. The zerodata flag means that this page carries
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** only keys and no data. The intkey flag means that the key is a integer
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** which is stored in the key size entry of the cell header rather than in
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** the payload area.
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**
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** The cell pointer array begins on the first byte after the page header.
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** The cell pointer array contains zero or more 2-byte numbers which are
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** offsets from the beginning of the page to the cell content in the cell
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** content area. The cell pointers occur in sorted order. The system strives
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** to keep free space after the last cell pointer so that new cells can
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** be easily added without having to defragment the page.
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**
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** Cell content is stored at the very end of the page and grows toward the
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** beginning of the page.
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**
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** Unused space within the cell content area is collected into a linked list of
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** freeblocks. Each freeblock is at least 4 bytes in size. The byte offset
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** to the first freeblock is given in the header. Freeblocks occur in
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** increasing order. Because a freeblock must be at least 4 bytes in size,
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** any group of 3 or fewer unused bytes in the cell content area cannot
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** exist on the freeblock chain. A group of 3 or fewer free bytes is called
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** a fragment. The total number of bytes in all fragments is recorded.
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** in the page header at offset 7.
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**
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** SIZE DESCRIPTION
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** 2 Byte offset of the next freeblock
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** 2 Bytes in this freeblock
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**
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** Cells are of variable length. Cells are stored in the cell content area at
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** the end of the page. Pointers to the cells are in the cell pointer array
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** that immediately follows the page header. Cells is not necessarily
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** contiguous or in order, but cell pointers are contiguous and in order.
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**
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** Cell content makes use of variable length integers. A variable
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** length integer is 1 to 9 bytes where the lower 7 bits of each
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** byte are used. The integer consists of all bytes that have bit 8 set and
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** the first byte with bit 8 clear. The most significant byte of the integer
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** appears first. A variable-length integer may not be more than 9 bytes long.
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** As a special case, all 8 bytes of the 9th byte are used as data. This
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** allows a 64-bit integer to be encoded in 9 bytes.
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**
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** 0x00 becomes 0x00000000
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** 0x7f becomes 0x0000007f
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** 0x81 0x00 becomes 0x00000080
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** 0x82 0x00 becomes 0x00000100
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** 0x80 0x7f becomes 0x0000007f
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** 0x8a 0x91 0xd1 0xac 0x78 becomes 0x12345678
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** 0x81 0x81 0x81 0x81 0x01 becomes 0x10204081
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**
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** Variable length integers are used for rowids and to hold the number of
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** bytes of key and data in a btree cell.
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**
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** The content of a cell looks like this:
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**
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** SIZE DESCRIPTION
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** 4 Page number of the left child. Omitted if leaf flag is set.
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** var Number of bytes of data. Omitted if the zerodata flag is set.
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** var Number of bytes of key. Or the key itself if intkey flag is set.
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** * Payload
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** 4 First page of the overflow chain. Omitted if no overflow
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**
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** Overflow pages form a linked list. Each page except the last is completely
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** filled with data (pagesize - 4 bytes). The last page can have as little
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** as 1 byte of data.
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**
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** SIZE DESCRIPTION
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** 4 Page number of next overflow page
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** * Data
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**
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** Freelist pages come in two subtypes: trunk pages and leaf pages. The
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** file header points to first in a linked list of trunk page. Each trunk
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** page points to multiple leaf pages. The content of a leaf page is
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** unspecified. A trunk page looks like this:
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**
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** SIZE DESCRIPTION
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** 4 Page number of next trunk page
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** 4 Number of leaf pointers on this page
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** * zero or more pages numbers of leaves
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*/
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#include "sqliteInt.h"
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#include "pager.h"
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#include "btree.h"
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#include "os.h"
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#include <assert.h>
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/* Round up a number to the next larger multiple of 8. This is used
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** to force 8-byte alignment on 64-bit architectures.
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*/
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#define ROUND8(x) ((x+7)&~7)
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/* The following value is the maximum cell size assuming a maximum page
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** size give above.
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*/
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#define MX_CELL_SIZE(pBt) (pBt->pageSize-8)
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/* The maximum number of cells on a single page of the database. This
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** assumes a minimum cell size of 3 bytes. Such small cells will be
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** exceedingly rare, but they are possible.
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*/
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#define MX_CELL(pBt) ((pBt->pageSize-8)/3)
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/* Forward declarations */
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typedef struct MemPage MemPage;
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typedef struct BtLock BtLock;
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/*
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** This is a magic string that appears at the beginning of every
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** SQLite database in order to identify the file as a real database.
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**
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** You can change this value at compile-time by specifying a
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** -DSQLITE_FILE_HEADER="..." on the compiler command-line. The
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** header must be exactly 16 bytes including the zero-terminator so
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** the string itself should be 15 characters long. If you change
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** the header, then your custom library will not be able to read
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** databases generated by the standard tools and the standard tools
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** will not be able to read databases created by your custom library.
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*/
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#ifndef SQLITE_FILE_HEADER /* 123456789 123456 */
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# define SQLITE_FILE_HEADER "SQLite format 3"
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#endif
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static const char zMagicHeader[] = SQLITE_FILE_HEADER;
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/*
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** Page type flags. An ORed combination of these flags appear as the
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** first byte of every BTree page.
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*/
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#define PTF_INTKEY 0x01
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#define PTF_ZERODATA 0x02
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#define PTF_LEAFDATA 0x04
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#define PTF_LEAF 0x08
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/*
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** As each page of the file is loaded into memory, an instance of the following
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** structure is appended and initialized to zero. This structure stores
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** information about the page that is decoded from the raw file page.
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**
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** The pParent field points back to the parent page. This allows us to
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** walk up the BTree from any leaf to the root. Care must be taken to
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** unref() the parent page pointer when this page is no longer referenced.
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** The pageDestructor() routine handles that chore.
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*/
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struct MemPage {
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u8 isInit; /* True if previously initialized. MUST BE FIRST! */
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u8 idxShift; /* True if Cell indices have changed */
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u8 nOverflow; /* Number of overflow cell bodies in aCell[] */
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u8 intKey; /* True if intkey flag is set */
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u8 leaf; /* True if leaf flag is set */
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u8 zeroData; /* True if table stores keys only */
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u8 leafData; /* True if tables stores data on leaves only */
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u8 hasData; /* True if this page stores data */
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u8 hdrOffset; /* 100 for page 1. 0 otherwise */
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u8 childPtrSize; /* 0 if leaf==1. 4 if leaf==0 */
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u16 maxLocal; /* Copy of Btree.maxLocal or Btree.maxLeaf */
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u16 minLocal; /* Copy of Btree.minLocal or Btree.minLeaf */
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u16 cellOffset; /* Index in aData of first cell pointer */
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u16 idxParent; /* Index in parent of this node */
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u16 nFree; /* Number of free bytes on the page */
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u16 nCell; /* Number of cells on this page, local and ovfl */
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struct _OvflCell { /* Cells that will not fit on aData[] */
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u8 *pCell; /* Pointers to the body of the overflow cell */
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u16 idx; /* Insert this cell before idx-th non-overflow cell */
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} aOvfl[5];
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BtShared *pBt; /* Pointer back to BTree structure */
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u8 *aData; /* Pointer back to the start of the page */
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Pgno pgno; /* Page number for this page */
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MemPage *pParent; /* The parent of this page. NULL for root */
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};
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/*
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** The in-memory image of a disk page has the auxiliary information appended
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** to the end. EXTRA_SIZE is the number of bytes of space needed to hold
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** that extra information.
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*/
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#define EXTRA_SIZE sizeof(MemPage)
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/* Btree handle */
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struct Btree {
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sqlite3 *pSqlite;
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BtShared *pBt;
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u8 inTrans; /* TRANS_NONE, TRANS_READ or TRANS_WRITE */
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};
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/*
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** Btree.inTrans may take one of the following values.
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**
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** If the shared-data extension is enabled, there may be multiple users
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** of the Btree structure. At most one of these may open a write transaction,
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** but any number may have active read transactions. Variable Btree.pDb
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** points to the handle that owns any current write-transaction.
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*/
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#define TRANS_NONE 0
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#define TRANS_READ 1
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#define TRANS_WRITE 2
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/*
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** Everything we need to know about an open database
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*/
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struct BtShared {
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Pager *pPager; /* The page cache */
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BtCursor *pCursor; /* A list of all open cursors */
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MemPage *pPage1; /* First page of the database */
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u8 inStmt; /* True if we are in a statement subtransaction */
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u8 readOnly; /* True if the underlying file is readonly */
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u8 maxEmbedFrac; /* Maximum payload as % of total page size */
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u8 minEmbedFrac; /* Minimum payload as % of total page size */
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u8 minLeafFrac; /* Minimum leaf payload as % of total page size */
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u8 pageSizeFixed; /* True if the page size can no longer be changed */
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#ifndef SQLITE_OMIT_AUTOVACUUM
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u8 autoVacuum; /* True if database supports auto-vacuum */
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#endif
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u16 pageSize; /* Total number of bytes on a page */
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u16 usableSize; /* Number of usable bytes on each page */
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int maxLocal; /* Maximum local payload in non-LEAFDATA tables */
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int minLocal; /* Minimum local payload in non-LEAFDATA tables */
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int maxLeaf; /* Maximum local payload in a LEAFDATA table */
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int minLeaf; /* Minimum local payload in a LEAFDATA table */
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BusyHandler *pBusyHandler; /* Callback for when there is lock contention */
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u8 inTransaction; /* Transaction state */
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int nRef; /* Number of references to this structure */
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int nTransaction; /* Number of open transactions (read + write) */
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void *pSchema; /* Pointer to space allocated by sqlite3BtreeSchema() */
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void (*xFreeSchema)(void*); /* Destructor for BtShared.pSchema */
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#ifndef SQLITE_OMIT_SHARED_CACHE
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BtLock *pLock; /* List of locks held on this shared-btree struct */
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BtShared *pNext; /* Next in ThreadData.pBtree linked list */
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#endif
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};
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/*
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** An instance of the following structure is used to hold information
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** about a cell. The parseCellPtr() function fills in this structure
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** based on information extract from the raw disk page.
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*/
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typedef struct CellInfo CellInfo;
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struct CellInfo {
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u8 *pCell; /* Pointer to the start of cell content */
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i64 nKey; /* The key for INTKEY tables, or number of bytes in key */
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u32 nData; /* Number of bytes of data */
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u16 nHeader; /* Size of the cell content header in bytes */
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u16 nLocal; /* Amount of payload held locally */
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u16 iOverflow; /* Offset to overflow page number. Zero if no overflow */
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u16 nSize; /* Size of the cell content on the main b-tree page */
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};
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/*
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** A cursor is a pointer to a particular entry in the BTree.
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** The entry is identified by its MemPage and the index in
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** MemPage.aCell[] of the entry.
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*/
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struct BtCursor {
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Btree *pBtree; /* The Btree to which this cursor belongs */
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BtCursor *pNext, *pPrev; /* Forms a linked list of all cursors */
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int (*xCompare)(void*,int,const void*,int,const void*); /* Key comp func */
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void *pArg; /* First arg to xCompare() */
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Pgno pgnoRoot; /* The root page of this tree */
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MemPage *pPage; /* Page that contains the entry */
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int idx; /* Index of the entry in pPage->aCell[] */
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CellInfo info; /* A parse of the cell we are pointing at */
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u8 wrFlag; /* True if writable */
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u8 eState; /* One of the CURSOR_XXX constants (see below) */
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#ifndef SQLITE_OMIT_SHARED_CACHE
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void *pKey; /* Saved key that was cursor's last known position */
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i64 nKey; /* Size of pKey, or last integer key */
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int skip; /* (skip<0) -> Prev() is a no-op. (skip>0) -> Next() is */
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#endif
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};
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/*
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** Potential values for BtCursor.eState. The first two values (VALID and
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** INVALID) may occur in any build. The third (REQUIRESEEK) may only occur
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** if sqlite was compiled without the OMIT_SHARED_CACHE symbol defined.
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**
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** CURSOR_VALID:
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** Cursor points to a valid entry. getPayload() etc. may be called.
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**
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** CURSOR_INVALID:
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** Cursor does not point to a valid entry. This can happen (for example)
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** because the table is empty or because BtreeCursorFirst() has not been
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** called.
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**
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** CURSOR_REQUIRESEEK:
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** The table that this cursor was opened on still exists, but has been
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** modified since the cursor was last used. The cursor position is saved
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** in variables BtCursor.pKey and BtCursor.nKey. When a cursor is in
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** this state, restoreOrClearCursorPosition() can be called to attempt to
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** seek the cursor to the saved position.
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*/
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#define CURSOR_INVALID 0
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#define CURSOR_VALID 1
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#define CURSOR_REQUIRESEEK 2
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/*
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** The TRACE macro will print high-level status information about the
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** btree operation when the global variable sqlite3_btree_trace is
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** enabled.
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*/
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#if SQLITE_TEST
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# define TRACE(X) if( sqlite3_btree_trace )\
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{ sqlite3DebugPrintf X; fflush(stdout); }
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#else
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# define TRACE(X)
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#endif
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int sqlite3_btree_trace=0; /* True to enable tracing */
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/*
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** Forward declaration
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*/
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static int checkReadLocks(BtShared*,Pgno,BtCursor*);
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/*
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** Read or write a two- and four-byte big-endian integer values.
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*/
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static u32 get2byte(unsigned char *p){
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return (p[0]<<8) | p[1];
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}
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static u32 get4byte(unsigned char *p){
|
|
return (p[0]<<24) | (p[1]<<16) | (p[2]<<8) | p[3];
|
|
}
|
|
static void put2byte(unsigned char *p, u32 v){
|
|
p[0] = v>>8;
|
|
p[1] = v;
|
|
}
|
|
static void put4byte(unsigned char *p, u32 v){
|
|
p[0] = v>>24;
|
|
p[1] = v>>16;
|
|
p[2] = v>>8;
|
|
p[3] = v;
|
|
}
|
|
|
|
/*
|
|
** Routines to read and write variable-length integers. These used to
|
|
** be defined locally, but now we use the varint routines in the util.c
|
|
** file.
|
|
*/
|
|
#define getVarint sqlite3GetVarint
|
|
/* #define getVarint32 sqlite3GetVarint32 */
|
|
#define getVarint32(A,B) ((*B=*(A))<=0x7f?1:sqlite3GetVarint32(A,B))
|
|
#define putVarint sqlite3PutVarint
|
|
|
|
/* The database page the PENDING_BYTE occupies. This page is never used.
|
|
** TODO: This macro is very similary to PAGER_MJ_PGNO() in pager.c. They
|
|
** should possibly be consolidated (presumably in pager.h).
|
|
**
|
|
** If disk I/O is omitted (meaning that the database is stored purely
|
|
** in memory) then there is no pending byte.
|
|
*/
|
|
#ifdef SQLITE_OMIT_DISKIO
|
|
# define PENDING_BYTE_PAGE(pBt) 0x7fffffff
|
|
#else
|
|
# define PENDING_BYTE_PAGE(pBt) ((PENDING_BYTE/(pBt)->pageSize)+1)
|
|
#endif
|
|
|
|
/*
|
|
** A linked list of the following structures is stored at BtShared.pLock.
|
|
** Locks are added (or upgraded from READ_LOCK to WRITE_LOCK) when a cursor
|
|
** is opened on the table with root page BtShared.iTable. Locks are removed
|
|
** from this list when a transaction is committed or rolled back, or when
|
|
** a btree handle is closed.
|
|
*/
|
|
struct BtLock {
|
|
Btree *pBtree; /* Btree handle holding this lock */
|
|
Pgno iTable; /* Root page of table */
|
|
u8 eLock; /* READ_LOCK or WRITE_LOCK */
|
|
BtLock *pNext; /* Next in BtShared.pLock list */
|
|
};
|
|
|
|
/* Candidate values for BtLock.eLock */
|
|
#define READ_LOCK 1
|
|
#define WRITE_LOCK 2
|
|
|
|
#ifdef SQLITE_OMIT_SHARED_CACHE
|
|
/*
|
|
** The functions queryTableLock(), lockTable() and unlockAllTables()
|
|
** manipulate entries in the BtShared.pLock linked list used to store
|
|
** shared-cache table level locks. If the library is compiled with the
|
|
** shared-cache feature disabled, then there is only ever one user
|
|
** of each BtShared structure and so this locking is not necessary.
|
|
** So define the lock related functions as no-ops.
|
|
*/
|
|
#define queryTableLock(a,b,c) SQLITE_OK
|
|
#define lockTable(a,b,c) SQLITE_OK
|
|
#define unlockAllTables(a)
|
|
#define restoreOrClearCursorPosition(a,b) SQLITE_OK
|
|
#define saveAllCursors(a,b,c) SQLITE_OK
|
|
|
|
#else
|
|
|
|
static void releasePage(MemPage *pPage);
|
|
|
|
/*
|
|
** Save the current cursor position in the variables BtCursor.nKey
|
|
** and BtCursor.pKey. The cursor's state is set to CURSOR_REQUIRESEEK.
|
|
*/
|
|
static int saveCursorPosition(BtCursor *pCur){
|
|
int rc;
|
|
|
|
assert( CURSOR_VALID==pCur->eState );
|
|
assert( 0==pCur->pKey );
|
|
|
|
rc = sqlite3BtreeKeySize(pCur, &pCur->nKey);
|
|
|
|
/* If this is an intKey table, then the above call to BtreeKeySize()
|
|
** stores the integer key in pCur->nKey. In this case this value is
|
|
** all that is required. Otherwise, if pCur is not open on an intKey
|
|
** table, then malloc space for and store the pCur->nKey bytes of key
|
|
** data.
|
|
*/
|
|
if( rc==SQLITE_OK && 0==pCur->pPage->intKey){
|
|
void *pKey = sqliteMalloc((int)pCur->nKey);
|
|
if( pKey ){
|
|
rc = sqlite3BtreeKey(pCur, 0, (u32)pCur->nKey, pKey);
|
|
if( rc==SQLITE_OK ){
|
|
pCur->pKey = pKey;
|
|
}else{
|
|
sqliteFree(pKey);
|
|
}
|
|
}else{
|
|
rc = SQLITE_NOMEM;
|
|
}
|
|
}
|
|
assert( !pCur->pPage->intKey || !pCur->pKey );
|
|
|
|
if( rc==SQLITE_OK ){
|
|
releasePage(pCur->pPage);
|
|
pCur->pPage = 0;
|
|
pCur->eState = CURSOR_REQUIRESEEK;
|
|
}
|
|
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Save the positions of all cursors except pExcept open on the table
|
|
** with root-page iRoot. Usually, this is called just before cursor
|
|
** pExcept is used to modify the table (BtreeDelete() or BtreeInsert()).
|
|
*/
|
|
static int saveAllCursors(BtShared *pBt, Pgno iRoot, BtCursor *pExcept){
|
|
BtCursor *p;
|
|
if( sqlite3ThreadDataReadOnly()->useSharedData ){
|
|
for(p=pBt->pCursor; p; p=p->pNext){
|
|
if( p!=pExcept && (0==iRoot || p->pgnoRoot==iRoot) &&
|
|
p->eState==CURSOR_VALID ){
|
|
int rc = saveCursorPosition(p);
|
|
if( SQLITE_OK!=rc ){
|
|
return rc;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Restore the cursor to the position it was in (or as close to as possible)
|
|
** when saveCursorPosition() was called. Note that this call deletes the
|
|
** saved position info stored by saveCursorPosition(), so there can be
|
|
** at most one effective restoreOrClearCursorPosition() call after each
|
|
** saveCursorPosition().
|
|
**
|
|
** If the second argument argument - doSeek - is false, then instead of
|
|
** returning the cursor to it's saved position, any saved position is deleted
|
|
** and the cursor state set to CURSOR_INVALID.
|
|
*/
|
|
static int restoreOrClearCursorPositionX(BtCursor *pCur, int doSeek){
|
|
int rc = SQLITE_OK;
|
|
assert( sqlite3ThreadDataReadOnly()->useSharedData );
|
|
assert( pCur->eState==CURSOR_REQUIRESEEK );
|
|
pCur->eState = CURSOR_INVALID;
|
|
if( doSeek ){
|
|
rc = sqlite3BtreeMoveto(pCur, pCur->pKey, pCur->nKey, &pCur->skip);
|
|
}
|
|
if( rc==SQLITE_OK ){
|
|
sqliteFree(pCur->pKey);
|
|
pCur->pKey = 0;
|
|
assert( CURSOR_VALID==pCur->eState || CURSOR_INVALID==pCur->eState );
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
#define restoreOrClearCursorPosition(p,x) \
|
|
(p->eState==CURSOR_REQUIRESEEK?restoreOrClearCursorPositionX(p,x):SQLITE_OK)
|
|
|
|
/*
|
|
** Query to see if btree handle p may obtain a lock of type eLock
|
|
** (READ_LOCK or WRITE_LOCK) on the table with root-page iTab. Return
|
|
** SQLITE_OK if the lock may be obtained (by calling lockTable()), or
|
|
** SQLITE_LOCKED if not.
|
|
*/
|
|
static int queryTableLock(Btree *p, Pgno iTab, u8 eLock){
|
|
BtShared *pBt = p->pBt;
|
|
BtLock *pIter;
|
|
|
|
/* This is a no-op if the shared-cache is not enabled */
|
|
if( 0==sqlite3ThreadDataReadOnly()->useSharedData ){
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/* This (along with lockTable()) is where the ReadUncommitted flag is
|
|
** dealt with. If the caller is querying for a read-lock and the flag is
|
|
** set, it is unconditionally granted - even if there are write-locks
|
|
** on the table. If a write-lock is requested, the ReadUncommitted flag
|
|
** is not considered.
|
|
**
|
|
** In function lockTable(), if a read-lock is demanded and the
|
|
** ReadUncommitted flag is set, no entry is added to the locks list
|
|
** (BtShared.pLock).
|
|
**
|
|
** To summarize: If the ReadUncommitted flag is set, then read cursors do
|
|
** not create or respect table locks. The locking procedure for a
|
|
** write-cursor does not change.
|
|
*/
|
|
if(
|
|
!p->pSqlite ||
|
|
0==(p->pSqlite->flags&SQLITE_ReadUncommitted) ||
|
|
eLock==WRITE_LOCK ||
|
|
iTab==MASTER_ROOT
|
|
){
|
|
for(pIter=pBt->pLock; pIter; pIter=pIter->pNext){
|
|
if( pIter->pBtree!=p && pIter->iTable==iTab &&
|
|
(pIter->eLock!=eLock || eLock!=READ_LOCK) ){
|
|
return SQLITE_LOCKED;
|
|
}
|
|
}
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Add a lock on the table with root-page iTable to the shared-btree used
|
|
** by Btree handle p. Parameter eLock must be either READ_LOCK or
|
|
** WRITE_LOCK.
|
|
**
|
|
** SQLITE_OK is returned if the lock is added successfully. SQLITE_BUSY and
|
|
** SQLITE_NOMEM may also be returned.
|
|
*/
|
|
static int lockTable(Btree *p, Pgno iTable, u8 eLock){
|
|
BtShared *pBt = p->pBt;
|
|
BtLock *pLock = 0;
|
|
BtLock *pIter;
|
|
|
|
/* This is a no-op if the shared-cache is not enabled */
|
|
if( 0==sqlite3ThreadDataReadOnly()->useSharedData ){
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
assert( SQLITE_OK==queryTableLock(p, iTable, eLock) );
|
|
|
|
/* If the read-uncommitted flag is set and a read-lock is requested,
|
|
** return early without adding an entry to the BtShared.pLock list. See
|
|
** comment in function queryTableLock() for more info on handling
|
|
** the ReadUncommitted flag.
|
|
*/
|
|
if(
|
|
(p->pSqlite) &&
|
|
(p->pSqlite->flags&SQLITE_ReadUncommitted) &&
|
|
(eLock==READ_LOCK) &&
|
|
iTable!=MASTER_ROOT
|
|
){
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/* First search the list for an existing lock on this table. */
|
|
for(pIter=pBt->pLock; pIter; pIter=pIter->pNext){
|
|
if( pIter->iTable==iTable && pIter->pBtree==p ){
|
|
pLock = pIter;
|
|
break;
|
|
}
|
|
}
|
|
|
|
/* If the above search did not find a BtLock struct associating Btree p
|
|
** with table iTable, allocate one and link it into the list.
|
|
*/
|
|
if( !pLock ){
|
|
pLock = (BtLock *)sqliteMalloc(sizeof(BtLock));
|
|
if( !pLock ){
|
|
return SQLITE_NOMEM;
|
|
}
|
|
pLock->iTable = iTable;
|
|
pLock->pBtree = p;
|
|
pLock->pNext = pBt->pLock;
|
|
pBt->pLock = pLock;
|
|
}
|
|
|
|
/* Set the BtLock.eLock variable to the maximum of the current lock
|
|
** and the requested lock. This means if a write-lock was already held
|
|
** and a read-lock requested, we don't incorrectly downgrade the lock.
|
|
*/
|
|
assert( WRITE_LOCK>READ_LOCK );
|
|
if( eLock>pLock->eLock ){
|
|
pLock->eLock = eLock;
|
|
}
|
|
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Release all the table locks (locks obtained via calls to the lockTable()
|
|
** procedure) held by Btree handle p.
|
|
*/
|
|
static void unlockAllTables(Btree *p){
|
|
BtLock **ppIter = &p->pBt->pLock;
|
|
|
|
/* If the shared-cache extension is not enabled, there should be no
|
|
** locks in the BtShared.pLock list, making this procedure a no-op. Assert
|
|
** that this is the case.
|
|
*/
|
|
assert( sqlite3ThreadDataReadOnly()->useSharedData || 0==*ppIter );
|
|
|
|
while( *ppIter ){
|
|
BtLock *pLock = *ppIter;
|
|
if( pLock->pBtree==p ){
|
|
*ppIter = pLock->pNext;
|
|
sqliteFree(pLock);
|
|
}else{
|
|
ppIter = &pLock->pNext;
|
|
}
|
|
}
|
|
}
|
|
#endif /* SQLITE_OMIT_SHARED_CACHE */
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/*
|
|
** These macros define the location of the pointer-map entry for a
|
|
** database page. The first argument to each is the number of usable
|
|
** bytes on each page of the database (often 1024). The second is the
|
|
** page number to look up in the pointer map.
|
|
**
|
|
** PTRMAP_PAGENO returns the database page number of the pointer-map
|
|
** page that stores the required pointer. PTRMAP_PTROFFSET returns
|
|
** the offset of the requested map entry.
|
|
**
|
|
** If the pgno argument passed to PTRMAP_PAGENO is a pointer-map page,
|
|
** then pgno is returned. So (pgno==PTRMAP_PAGENO(pgsz, pgno)) can be
|
|
** used to test if pgno is a pointer-map page. PTRMAP_ISPAGE implements
|
|
** this test.
|
|
*/
|
|
#define PTRMAP_PAGENO(pBt, pgno) ptrmapPageno(pBt, pgno)
|
|
#define PTRMAP_PTROFFSET(pBt, pgno) (5*(pgno-ptrmapPageno(pBt, pgno)-1))
|
|
#define PTRMAP_ISPAGE(pBt, pgno) (PTRMAP_PAGENO((pBt),(pgno))==(pgno))
|
|
|
|
static Pgno ptrmapPageno(BtShared *pBt, Pgno pgno){
|
|
int nPagesPerMapPage = (pBt->usableSize/5)+1;
|
|
int iPtrMap = (pgno-2)/nPagesPerMapPage;
|
|
int ret = (iPtrMap*nPagesPerMapPage) + 2;
|
|
if( ret==PENDING_BYTE_PAGE(pBt) ){
|
|
ret++;
|
|
}
|
|
return ret;
|
|
}
|
|
|
|
/*
|
|
** The pointer map is a lookup table that identifies the parent page for
|
|
** each child page in the database file. The parent page is the page that
|
|
** contains a pointer to the child. Every page in the database contains
|
|
** 0 or 1 parent pages. (In this context 'database page' refers
|
|
** to any page that is not part of the pointer map itself.) Each pointer map
|
|
** entry consists of a single byte 'type' and a 4 byte parent page number.
|
|
** The PTRMAP_XXX identifiers below are the valid types.
|
|
**
|
|
** The purpose of the pointer map is to facility moving pages from one
|
|
** position in the file to another as part of autovacuum. When a page
|
|
** is moved, the pointer in its parent must be updated to point to the
|
|
** new location. The pointer map is used to locate the parent page quickly.
|
|
**
|
|
** PTRMAP_ROOTPAGE: The database page is a root-page. The page-number is not
|
|
** used in this case.
|
|
**
|
|
** PTRMAP_FREEPAGE: The database page is an unused (free) page. The page-number
|
|
** is not used in this case.
|
|
**
|
|
** PTRMAP_OVERFLOW1: The database page is the first page in a list of
|
|
** overflow pages. The page number identifies the page that
|
|
** contains the cell with a pointer to this overflow page.
|
|
**
|
|
** PTRMAP_OVERFLOW2: The database page is the second or later page in a list of
|
|
** overflow pages. The page-number identifies the previous
|
|
** page in the overflow page list.
|
|
**
|
|
** PTRMAP_BTREE: The database page is a non-root btree page. The page number
|
|
** identifies the parent page in the btree.
|
|
*/
|
|
#define PTRMAP_ROOTPAGE 1
|
|
#define PTRMAP_FREEPAGE 2
|
|
#define PTRMAP_OVERFLOW1 3
|
|
#define PTRMAP_OVERFLOW2 4
|
|
#define PTRMAP_BTREE 5
|
|
|
|
/*
|
|
** Write an entry into the pointer map.
|
|
**
|
|
** This routine updates the pointer map entry for page number 'key'
|
|
** so that it maps to type 'eType' and parent page number 'pgno'.
|
|
** An error code is returned if something goes wrong, otherwise SQLITE_OK.
|
|
*/
|
|
static int ptrmapPut(BtShared *pBt, Pgno key, u8 eType, Pgno parent){
|
|
u8 *pPtrmap; /* The pointer map page */
|
|
Pgno iPtrmap; /* The pointer map page number */
|
|
int offset; /* Offset in pointer map page */
|
|
int rc;
|
|
|
|
/* The master-journal page number must never be used as a pointer map page */
|
|
assert( 0==PTRMAP_ISPAGE(pBt, PENDING_BYTE_PAGE(pBt)) );
|
|
|
|
assert( pBt->autoVacuum );
|
|
if( key==0 ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
iPtrmap = PTRMAP_PAGENO(pBt, key);
|
|
rc = sqlite3pager_get(pBt->pPager, iPtrmap, (void **)&pPtrmap);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
offset = PTRMAP_PTROFFSET(pBt, key);
|
|
|
|
if( eType!=pPtrmap[offset] || get4byte(&pPtrmap[offset+1])!=parent ){
|
|
TRACE(("PTRMAP_UPDATE: %d->(%d,%d)\n", key, eType, parent));
|
|
rc = sqlite3pager_write(pPtrmap);
|
|
if( rc==SQLITE_OK ){
|
|
pPtrmap[offset] = eType;
|
|
put4byte(&pPtrmap[offset+1], parent);
|
|
}
|
|
}
|
|
|
|
sqlite3pager_unref(pPtrmap);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Read an entry from the pointer map.
|
|
**
|
|
** This routine retrieves the pointer map entry for page 'key', writing
|
|
** the type and parent page number to *pEType and *pPgno respectively.
|
|
** An error code is returned if something goes wrong, otherwise SQLITE_OK.
|
|
*/
|
|
static int ptrmapGet(BtShared *pBt, Pgno key, u8 *pEType, Pgno *pPgno){
|
|
int iPtrmap; /* Pointer map page index */
|
|
u8 *pPtrmap; /* Pointer map page data */
|
|
int offset; /* Offset of entry in pointer map */
|
|
int rc;
|
|
|
|
iPtrmap = PTRMAP_PAGENO(pBt, key);
|
|
rc = sqlite3pager_get(pBt->pPager, iPtrmap, (void **)&pPtrmap);
|
|
if( rc!=0 ){
|
|
return rc;
|
|
}
|
|
|
|
offset = PTRMAP_PTROFFSET(pBt, key);
|
|
assert( pEType!=0 );
|
|
*pEType = pPtrmap[offset];
|
|
if( pPgno ) *pPgno = get4byte(&pPtrmap[offset+1]);
|
|
|
|
sqlite3pager_unref(pPtrmap);
|
|
if( *pEType<1 || *pEType>5 ) return SQLITE_CORRUPT_BKPT;
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
#endif /* SQLITE_OMIT_AUTOVACUUM */
|
|
|
|
/*
|
|
** Given a btree page and a cell index (0 means the first cell on
|
|
** the page, 1 means the second cell, and so forth) return a pointer
|
|
** to the cell content.
|
|
**
|
|
** This routine works only for pages that do not contain overflow cells.
|
|
*/
|
|
static u8 *findCell(MemPage *pPage, int iCell){
|
|
u8 *data = pPage->aData;
|
|
assert( iCell>=0 );
|
|
assert( iCell<get2byte(&data[pPage->hdrOffset+3]) );
|
|
return data + get2byte(&data[pPage->cellOffset+2*iCell]);
|
|
}
|
|
|
|
/*
|
|
** This a more complex version of findCell() that works for
|
|
** pages that do contain overflow cells. See insert
|
|
*/
|
|
static u8 *findOverflowCell(MemPage *pPage, int iCell){
|
|
int i;
|
|
for(i=pPage->nOverflow-1; i>=0; i--){
|
|
int k;
|
|
struct _OvflCell *pOvfl;
|
|
pOvfl = &pPage->aOvfl[i];
|
|
k = pOvfl->idx;
|
|
if( k<=iCell ){
|
|
if( k==iCell ){
|
|
return pOvfl->pCell;
|
|
}
|
|
iCell--;
|
|
}
|
|
}
|
|
return findCell(pPage, iCell);
|
|
}
|
|
|
|
/*
|
|
** Parse a cell content block and fill in the CellInfo structure. There
|
|
** are two versions of this function. parseCell() takes a cell index
|
|
** as the second argument and parseCellPtr() takes a pointer to the
|
|
** body of the cell as its second argument.
|
|
*/
|
|
static void parseCellPtr(
|
|
MemPage *pPage, /* Page containing the cell */
|
|
u8 *pCell, /* Pointer to the cell text. */
|
|
CellInfo *pInfo /* Fill in this structure */
|
|
){
|
|
int n; /* Number bytes in cell content header */
|
|
u32 nPayload; /* Number of bytes of cell payload */
|
|
|
|
pInfo->pCell = pCell;
|
|
assert( pPage->leaf==0 || pPage->leaf==1 );
|
|
n = pPage->childPtrSize;
|
|
assert( n==4-4*pPage->leaf );
|
|
if( pPage->hasData ){
|
|
n += getVarint32(&pCell[n], &nPayload);
|
|
}else{
|
|
nPayload = 0;
|
|
}
|
|
pInfo->nData = nPayload;
|
|
if( pPage->intKey ){
|
|
n += getVarint(&pCell[n], (u64 *)&pInfo->nKey);
|
|
}else{
|
|
u32 x;
|
|
n += getVarint32(&pCell[n], &x);
|
|
pInfo->nKey = x;
|
|
nPayload += x;
|
|
}
|
|
pInfo->nHeader = n;
|
|
if( nPayload<=pPage->maxLocal ){
|
|
/* This is the (easy) common case where the entire payload fits
|
|
** on the local page. No overflow is required.
|
|
*/
|
|
int nSize; /* Total size of cell content in bytes */
|
|
pInfo->nLocal = nPayload;
|
|
pInfo->iOverflow = 0;
|
|
nSize = nPayload + n;
|
|
if( nSize<4 ){
|
|
nSize = 4; /* Minimum cell size is 4 */
|
|
}
|
|
pInfo->nSize = nSize;
|
|
}else{
|
|
/* If the payload will not fit completely on the local page, we have
|
|
** to decide how much to store locally and how much to spill onto
|
|
** overflow pages. The strategy is to minimize the amount of unused
|
|
** space on overflow pages while keeping the amount of local storage
|
|
** in between minLocal and maxLocal.
|
|
**
|
|
** Warning: changing the way overflow payload is distributed in any
|
|
** way will result in an incompatible file format.
|
|
*/
|
|
int minLocal; /* Minimum amount of payload held locally */
|
|
int maxLocal; /* Maximum amount of payload held locally */
|
|
int surplus; /* Overflow payload available for local storage */
|
|
|
|
minLocal = pPage->minLocal;
|
|
maxLocal = pPage->maxLocal;
|
|
surplus = minLocal + (nPayload - minLocal)%(pPage->pBt->usableSize - 4);
|
|
if( surplus <= maxLocal ){
|
|
pInfo->nLocal = surplus;
|
|
}else{
|
|
pInfo->nLocal = minLocal;
|
|
}
|
|
pInfo->iOverflow = pInfo->nLocal + n;
|
|
pInfo->nSize = pInfo->iOverflow + 4;
|
|
}
|
|
}
|
|
static void parseCell(
|
|
MemPage *pPage, /* Page containing the cell */
|
|
int iCell, /* The cell index. First cell is 0 */
|
|
CellInfo *pInfo /* Fill in this structure */
|
|
){
|
|
parseCellPtr(pPage, findCell(pPage, iCell), pInfo);
|
|
}
|
|
|
|
/*
|
|
** Compute the total number of bytes that a Cell needs in the cell
|
|
** data area of the btree-page. The return number includes the cell
|
|
** data header and the local payload, but not any overflow page or
|
|
** the space used by the cell pointer.
|
|
*/
|
|
#ifndef NDEBUG
|
|
static int cellSize(MemPage *pPage, int iCell){
|
|
CellInfo info;
|
|
parseCell(pPage, iCell, &info);
|
|
return info.nSize;
|
|
}
|
|
#endif
|
|
static int cellSizePtr(MemPage *pPage, u8 *pCell){
|
|
CellInfo info;
|
|
parseCellPtr(pPage, pCell, &info);
|
|
return info.nSize;
|
|
}
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/*
|
|
** If the cell pCell, part of page pPage contains a pointer
|
|
** to an overflow page, insert an entry into the pointer-map
|
|
** for the overflow page.
|
|
*/
|
|
static int ptrmapPutOvflPtr(MemPage *pPage, u8 *pCell){
|
|
if( pCell ){
|
|
CellInfo info;
|
|
parseCellPtr(pPage, pCell, &info);
|
|
if( (info.nData+(pPage->intKey?0:info.nKey))>info.nLocal ){
|
|
Pgno ovfl = get4byte(&pCell[info.iOverflow]);
|
|
return ptrmapPut(pPage->pBt, ovfl, PTRMAP_OVERFLOW1, pPage->pgno);
|
|
}
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
/*
|
|
** If the cell with index iCell on page pPage contains a pointer
|
|
** to an overflow page, insert an entry into the pointer-map
|
|
** for the overflow page.
|
|
*/
|
|
static int ptrmapPutOvfl(MemPage *pPage, int iCell){
|
|
u8 *pCell;
|
|
pCell = findOverflowCell(pPage, iCell);
|
|
return ptrmapPutOvflPtr(pPage, pCell);
|
|
}
|
|
#endif
|
|
|
|
|
|
/*
|
|
** Do sanity checking on a page. Throw an exception if anything is
|
|
** not right.
|
|
**
|
|
** This routine is used for internal error checking only. It is omitted
|
|
** from most builds.
|
|
*/
|
|
#if defined(BTREE_DEBUG) && !defined(NDEBUG) && 0
|
|
static void _pageIntegrity(MemPage *pPage){
|
|
int usableSize;
|
|
u8 *data;
|
|
int i, j, idx, c, pc, hdr, nFree;
|
|
int cellOffset;
|
|
int nCell, cellLimit;
|
|
u8 *used;
|
|
|
|
used = sqliteMallocRaw( pPage->pBt->pageSize );
|
|
if( used==0 ) return;
|
|
usableSize = pPage->pBt->usableSize;
|
|
assert( pPage->aData==&((unsigned char*)pPage)[-pPage->pBt->pageSize] );
|
|
hdr = pPage->hdrOffset;
|
|
assert( hdr==(pPage->pgno==1 ? 100 : 0) );
|
|
assert( pPage->pgno==sqlite3pager_pagenumber(pPage->aData) );
|
|
c = pPage->aData[hdr];
|
|
if( pPage->isInit ){
|
|
assert( pPage->leaf == ((c & PTF_LEAF)!=0) );
|
|
assert( pPage->zeroData == ((c & PTF_ZERODATA)!=0) );
|
|
assert( pPage->leafData == ((c & PTF_LEAFDATA)!=0) );
|
|
assert( pPage->intKey == ((c & (PTF_INTKEY|PTF_LEAFDATA))!=0) );
|
|
assert( pPage->hasData ==
|
|
!(pPage->zeroData || (!pPage->leaf && pPage->leafData)) );
|
|
assert( pPage->cellOffset==pPage->hdrOffset+12-4*pPage->leaf );
|
|
assert( pPage->nCell = get2byte(&pPage->aData[hdr+3]) );
|
|
}
|
|
data = pPage->aData;
|
|
memset(used, 0, usableSize);
|
|
for(i=0; i<hdr+10-pPage->leaf*4; i++) used[i] = 1;
|
|
nFree = 0;
|
|
pc = get2byte(&data[hdr+1]);
|
|
while( pc ){
|
|
int size;
|
|
assert( pc>0 && pc<usableSize-4 );
|
|
size = get2byte(&data[pc+2]);
|
|
assert( pc+size<=usableSize );
|
|
nFree += size;
|
|
for(i=pc; i<pc+size; i++){
|
|
assert( used[i]==0 );
|
|
used[i] = 1;
|
|
}
|
|
pc = get2byte(&data[pc]);
|
|
}
|
|
idx = 0;
|
|
nCell = get2byte(&data[hdr+3]);
|
|
cellLimit = get2byte(&data[hdr+5]);
|
|
assert( pPage->isInit==0
|
|
|| pPage->nFree==nFree+data[hdr+7]+cellLimit-(cellOffset+2*nCell) );
|
|
cellOffset = pPage->cellOffset;
|
|
for(i=0; i<nCell; i++){
|
|
int size;
|
|
pc = get2byte(&data[cellOffset+2*i]);
|
|
assert( pc>0 && pc<usableSize-4 );
|
|
size = cellSize(pPage, &data[pc]);
|
|
assert( pc+size<=usableSize );
|
|
for(j=pc; j<pc+size; j++){
|
|
assert( used[j]==0 );
|
|
used[j] = 1;
|
|
}
|
|
}
|
|
for(i=cellOffset+2*nCell; i<cellimit; i++){
|
|
assert( used[i]==0 );
|
|
used[i] = 1;
|
|
}
|
|
nFree = 0;
|
|
for(i=0; i<usableSize; i++){
|
|
assert( used[i]<=1 );
|
|
if( used[i]==0 ) nFree++;
|
|
}
|
|
assert( nFree==data[hdr+7] );
|
|
sqliteFree(used);
|
|
}
|
|
#define pageIntegrity(X) _pageIntegrity(X)
|
|
#else
|
|
# define pageIntegrity(X)
|
|
#endif
|
|
|
|
/* A bunch of assert() statements to check the transaction state variables
|
|
** of handle p (type Btree*) are internally consistent.
|
|
*/
|
|
#define btreeIntegrity(p) \
|
|
assert( p->inTrans!=TRANS_NONE || p->pBt->nTransaction<p->pBt->nRef ); \
|
|
assert( p->pBt->nTransaction<=p->pBt->nRef ); \
|
|
assert( p->pBt->inTransaction!=TRANS_NONE || p->pBt->nTransaction==0 ); \
|
|
assert( p->pBt->inTransaction>=p->inTrans );
|
|
|
|
/*
|
|
** Defragment the page given. All Cells are moved to the
|
|
** end of the page and all free space is collected into one
|
|
** big FreeBlk that occurs in between the header and cell
|
|
** pointer array and the cell content area.
|
|
*/
|
|
static int defragmentPage(MemPage *pPage){
|
|
int i; /* Loop counter */
|
|
int pc; /* Address of a i-th cell */
|
|
int addr; /* Offset of first byte after cell pointer array */
|
|
int hdr; /* Offset to the page header */
|
|
int size; /* Size of a cell */
|
|
int usableSize; /* Number of usable bytes on a page */
|
|
int cellOffset; /* Offset to the cell pointer array */
|
|
int brk; /* Offset to the cell content area */
|
|
int nCell; /* Number of cells on the page */
|
|
unsigned char *data; /* The page data */
|
|
unsigned char *temp; /* Temp area for cell content */
|
|
|
|
assert( sqlite3pager_iswriteable(pPage->aData) );
|
|
assert( pPage->pBt!=0 );
|
|
assert( pPage->pBt->usableSize <= SQLITE_MAX_PAGE_SIZE );
|
|
assert( pPage->nOverflow==0 );
|
|
temp = sqliteMalloc( pPage->pBt->pageSize );
|
|
if( temp==0 ) return SQLITE_NOMEM;
|
|
data = pPage->aData;
|
|
hdr = pPage->hdrOffset;
|
|
cellOffset = pPage->cellOffset;
|
|
nCell = pPage->nCell;
|
|
assert( nCell==get2byte(&data[hdr+3]) );
|
|
usableSize = pPage->pBt->usableSize;
|
|
brk = get2byte(&data[hdr+5]);
|
|
memcpy(&temp[brk], &data[brk], usableSize - brk);
|
|
brk = usableSize;
|
|
for(i=0; i<nCell; i++){
|
|
u8 *pAddr; /* The i-th cell pointer */
|
|
pAddr = &data[cellOffset + i*2];
|
|
pc = get2byte(pAddr);
|
|
assert( pc<pPage->pBt->usableSize );
|
|
size = cellSizePtr(pPage, &temp[pc]);
|
|
brk -= size;
|
|
memcpy(&data[brk], &temp[pc], size);
|
|
put2byte(pAddr, brk);
|
|
}
|
|
assert( brk>=cellOffset+2*nCell );
|
|
put2byte(&data[hdr+5], brk);
|
|
data[hdr+1] = 0;
|
|
data[hdr+2] = 0;
|
|
data[hdr+7] = 0;
|
|
addr = cellOffset+2*nCell;
|
|
memset(&data[addr], 0, brk-addr);
|
|
sqliteFree(temp);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Allocate nByte bytes of space on a page.
|
|
**
|
|
** Return the index into pPage->aData[] of the first byte of
|
|
** the new allocation. Or return 0 if there is not enough free
|
|
** space on the page to satisfy the allocation request.
|
|
**
|
|
** If the page contains nBytes of free space but does not contain
|
|
** nBytes of contiguous free space, then this routine automatically
|
|
** calls defragementPage() to consolidate all free space before
|
|
** allocating the new chunk.
|
|
*/
|
|
static int allocateSpace(MemPage *pPage, int nByte){
|
|
int addr, pc, hdr;
|
|
int size;
|
|
int nFrag;
|
|
int top;
|
|
int nCell;
|
|
int cellOffset;
|
|
unsigned char *data;
|
|
|
|
data = pPage->aData;
|
|
assert( sqlite3pager_iswriteable(data) );
|
|
assert( pPage->pBt );
|
|
if( nByte<4 ) nByte = 4;
|
|
if( pPage->nFree<nByte || pPage->nOverflow>0 ) return 0;
|
|
pPage->nFree -= nByte;
|
|
hdr = pPage->hdrOffset;
|
|
|
|
nFrag = data[hdr+7];
|
|
if( nFrag<60 ){
|
|
/* Search the freelist looking for a slot big enough to satisfy the
|
|
** space request. */
|
|
addr = hdr+1;
|
|
while( (pc = get2byte(&data[addr]))>0 ){
|
|
size = get2byte(&data[pc+2]);
|
|
if( size>=nByte ){
|
|
if( size<nByte+4 ){
|
|
memcpy(&data[addr], &data[pc], 2);
|
|
data[hdr+7] = nFrag + size - nByte;
|
|
return pc;
|
|
}else{
|
|
put2byte(&data[pc+2], size-nByte);
|
|
return pc + size - nByte;
|
|
}
|
|
}
|
|
addr = pc;
|
|
}
|
|
}
|
|
|
|
/* Allocate memory from the gap in between the cell pointer array
|
|
** and the cell content area.
|
|
*/
|
|
top = get2byte(&data[hdr+5]);
|
|
nCell = get2byte(&data[hdr+3]);
|
|
cellOffset = pPage->cellOffset;
|
|
if( nFrag>=60 || cellOffset + 2*nCell > top - nByte ){
|
|
if( defragmentPage(pPage) ) return 0;
|
|
top = get2byte(&data[hdr+5]);
|
|
}
|
|
top -= nByte;
|
|
assert( cellOffset + 2*nCell <= top );
|
|
put2byte(&data[hdr+5], top);
|
|
return top;
|
|
}
|
|
|
|
/*
|
|
** Return a section of the pPage->aData to the freelist.
|
|
** The first byte of the new free block is pPage->aDisk[start]
|
|
** and the size of the block is "size" bytes.
|
|
**
|
|
** Most of the effort here is involved in coalesing adjacent
|
|
** free blocks into a single big free block.
|
|
*/
|
|
static void freeSpace(MemPage *pPage, int start, int size){
|
|
int addr, pbegin, hdr;
|
|
unsigned char *data = pPage->aData;
|
|
|
|
assert( pPage->pBt!=0 );
|
|
assert( sqlite3pager_iswriteable(data) );
|
|
assert( start>=pPage->hdrOffset+6+(pPage->leaf?0:4) );
|
|
assert( (start + size)<=pPage->pBt->usableSize );
|
|
if( size<4 ) size = 4;
|
|
|
|
#ifdef SQLITE_SECURE_DELETE
|
|
/* Overwrite deleted information with zeros when the SECURE_DELETE
|
|
** option is enabled at compile-time */
|
|
memset(&data[start], 0, size);
|
|
#endif
|
|
|
|
/* Add the space back into the linked list of freeblocks */
|
|
hdr = pPage->hdrOffset;
|
|
addr = hdr + 1;
|
|
while( (pbegin = get2byte(&data[addr]))<start && pbegin>0 ){
|
|
assert( pbegin<=pPage->pBt->usableSize-4 );
|
|
assert( pbegin>addr );
|
|
addr = pbegin;
|
|
}
|
|
assert( pbegin<=pPage->pBt->usableSize-4 );
|
|
assert( pbegin>addr || pbegin==0 );
|
|
put2byte(&data[addr], start);
|
|
put2byte(&data[start], pbegin);
|
|
put2byte(&data[start+2], size);
|
|
pPage->nFree += size;
|
|
|
|
/* Coalesce adjacent free blocks */
|
|
addr = pPage->hdrOffset + 1;
|
|
while( (pbegin = get2byte(&data[addr]))>0 ){
|
|
int pnext, psize;
|
|
assert( pbegin>addr );
|
|
assert( pbegin<=pPage->pBt->usableSize-4 );
|
|
pnext = get2byte(&data[pbegin]);
|
|
psize = get2byte(&data[pbegin+2]);
|
|
if( pbegin + psize + 3 >= pnext && pnext>0 ){
|
|
int frag = pnext - (pbegin+psize);
|
|
assert( frag<=data[pPage->hdrOffset+7] );
|
|
data[pPage->hdrOffset+7] -= frag;
|
|
put2byte(&data[pbegin], get2byte(&data[pnext]));
|
|
put2byte(&data[pbegin+2], pnext+get2byte(&data[pnext+2])-pbegin);
|
|
}else{
|
|
addr = pbegin;
|
|
}
|
|
}
|
|
|
|
/* If the cell content area begins with a freeblock, remove it. */
|
|
if( data[hdr+1]==data[hdr+5] && data[hdr+2]==data[hdr+6] ){
|
|
int top;
|
|
pbegin = get2byte(&data[hdr+1]);
|
|
memcpy(&data[hdr+1], &data[pbegin], 2);
|
|
top = get2byte(&data[hdr+5]);
|
|
put2byte(&data[hdr+5], top + get2byte(&data[pbegin+2]));
|
|
}
|
|
}
|
|
|
|
/*
|
|
** Decode the flags byte (the first byte of the header) for a page
|
|
** and initialize fields of the MemPage structure accordingly.
|
|
*/
|
|
static void decodeFlags(MemPage *pPage, int flagByte){
|
|
BtShared *pBt; /* A copy of pPage->pBt */
|
|
|
|
assert( pPage->hdrOffset==(pPage->pgno==1 ? 100 : 0) );
|
|
pPage->intKey = (flagByte & (PTF_INTKEY|PTF_LEAFDATA))!=0;
|
|
pPage->zeroData = (flagByte & PTF_ZERODATA)!=0;
|
|
pPage->leaf = (flagByte & PTF_LEAF)!=0;
|
|
pPage->childPtrSize = 4*(pPage->leaf==0);
|
|
pBt = pPage->pBt;
|
|
if( flagByte & PTF_LEAFDATA ){
|
|
pPage->leafData = 1;
|
|
pPage->maxLocal = pBt->maxLeaf;
|
|
pPage->minLocal = pBt->minLeaf;
|
|
}else{
|
|
pPage->leafData = 0;
|
|
pPage->maxLocal = pBt->maxLocal;
|
|
pPage->minLocal = pBt->minLocal;
|
|
}
|
|
pPage->hasData = !(pPage->zeroData || (!pPage->leaf && pPage->leafData));
|
|
}
|
|
|
|
/*
|
|
** Initialize the auxiliary information for a disk block.
|
|
**
|
|
** The pParent parameter must be a pointer to the MemPage which
|
|
** is the parent of the page being initialized. The root of a
|
|
** BTree has no parent and so for that page, pParent==NULL.
|
|
**
|
|
** Return SQLITE_OK on success. If we see that the page does
|
|
** not contain a well-formed database page, then return
|
|
** SQLITE_CORRUPT. Note that a return of SQLITE_OK does not
|
|
** guarantee that the page is well-formed. It only shows that
|
|
** we failed to detect any corruption.
|
|
*/
|
|
static int initPage(
|
|
MemPage *pPage, /* The page to be initialized */
|
|
MemPage *pParent /* The parent. Might be NULL */
|
|
){
|
|
int pc; /* Address of a freeblock within pPage->aData[] */
|
|
int hdr; /* Offset to beginning of page header */
|
|
u8 *data; /* Equal to pPage->aData */
|
|
BtShared *pBt; /* The main btree structure */
|
|
int usableSize; /* Amount of usable space on each page */
|
|
int cellOffset; /* Offset from start of page to first cell pointer */
|
|
int nFree; /* Number of unused bytes on the page */
|
|
int top; /* First byte of the cell content area */
|
|
|
|
pBt = pPage->pBt;
|
|
assert( pBt!=0 );
|
|
assert( pParent==0 || pParent->pBt==pBt );
|
|
assert( pPage->pgno==sqlite3pager_pagenumber(pPage->aData) );
|
|
assert( pPage->aData == &((unsigned char*)pPage)[-pBt->pageSize] );
|
|
if( pPage->pParent!=pParent && (pPage->pParent!=0 || pPage->isInit) ){
|
|
/* The parent page should never change unless the file is corrupt */
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
if( pPage->isInit ) return SQLITE_OK;
|
|
if( pPage->pParent==0 && pParent!=0 ){
|
|
pPage->pParent = pParent;
|
|
sqlite3pager_ref(pParent->aData);
|
|
}
|
|
hdr = pPage->hdrOffset;
|
|
data = pPage->aData;
|
|
decodeFlags(pPage, data[hdr]);
|
|
pPage->nOverflow = 0;
|
|
pPage->idxShift = 0;
|
|
usableSize = pBt->usableSize;
|
|
pPage->cellOffset = cellOffset = hdr + 12 - 4*pPage->leaf;
|
|
top = get2byte(&data[hdr+5]);
|
|
pPage->nCell = get2byte(&data[hdr+3]);
|
|
if( pPage->nCell>MX_CELL(pBt) ){
|
|
/* To many cells for a single page. The page must be corrupt */
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
if( pPage->nCell==0 && pParent!=0 && pParent->pgno!=1 ){
|
|
/* All pages must have at least one cell, except for root pages */
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
|
|
/* Compute the total free space on the page */
|
|
pc = get2byte(&data[hdr+1]);
|
|
nFree = data[hdr+7] + top - (cellOffset + 2*pPage->nCell);
|
|
while( pc>0 ){
|
|
int next, size;
|
|
if( pc>usableSize-4 ){
|
|
/* Free block is off the page */
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
next = get2byte(&data[pc]);
|
|
size = get2byte(&data[pc+2]);
|
|
if( next>0 && next<=pc+size+3 ){
|
|
/* Free blocks must be in accending order */
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
nFree += size;
|
|
pc = next;
|
|
}
|
|
pPage->nFree = nFree;
|
|
if( nFree>=usableSize ){
|
|
/* Free space cannot exceed total page size */
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
|
|
pPage->isInit = 1;
|
|
pageIntegrity(pPage);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Set up a raw page so that it looks like a database page holding
|
|
** no entries.
|
|
*/
|
|
static void zeroPage(MemPage *pPage, int flags){
|
|
unsigned char *data = pPage->aData;
|
|
BtShared *pBt = pPage->pBt;
|
|
int hdr = pPage->hdrOffset;
|
|
int first;
|
|
|
|
assert( sqlite3pager_pagenumber(data)==pPage->pgno );
|
|
assert( &data[pBt->pageSize] == (unsigned char*)pPage );
|
|
assert( sqlite3pager_iswriteable(data) );
|
|
memset(&data[hdr], 0, pBt->usableSize - hdr);
|
|
data[hdr] = flags;
|
|
first = hdr + 8 + 4*((flags&PTF_LEAF)==0);
|
|
memset(&data[hdr+1], 0, 4);
|
|
data[hdr+7] = 0;
|
|
put2byte(&data[hdr+5], pBt->usableSize);
|
|
pPage->nFree = pBt->usableSize - first;
|
|
decodeFlags(pPage, flags);
|
|
pPage->hdrOffset = hdr;
|
|
pPage->cellOffset = first;
|
|
pPage->nOverflow = 0;
|
|
pPage->idxShift = 0;
|
|
pPage->nCell = 0;
|
|
pPage->isInit = 1;
|
|
pageIntegrity(pPage);
|
|
}
|
|
|
|
/*
|
|
** Get a page from the pager. Initialize the MemPage.pBt and
|
|
** MemPage.aData elements if needed.
|
|
*/
|
|
static int getPage(BtShared *pBt, Pgno pgno, MemPage **ppPage){
|
|
int rc;
|
|
unsigned char *aData;
|
|
MemPage *pPage;
|
|
rc = sqlite3pager_get(pBt->pPager, pgno, (void**)&aData);
|
|
if( rc ) return rc;
|
|
pPage = (MemPage*)&aData[pBt->pageSize];
|
|
pPage->aData = aData;
|
|
pPage->pBt = pBt;
|
|
pPage->pgno = pgno;
|
|
pPage->hdrOffset = pPage->pgno==1 ? 100 : 0;
|
|
*ppPage = pPage;
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Get a page from the pager and initialize it. This routine
|
|
** is just a convenience wrapper around separate calls to
|
|
** getPage() and initPage().
|
|
*/
|
|
static int getAndInitPage(
|
|
BtShared *pBt, /* The database file */
|
|
Pgno pgno, /* Number of the page to get */
|
|
MemPage **ppPage, /* Write the page pointer here */
|
|
MemPage *pParent /* Parent of the page */
|
|
){
|
|
int rc;
|
|
if( pgno==0 ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
rc = getPage(pBt, pgno, ppPage);
|
|
if( rc==SQLITE_OK && (*ppPage)->isInit==0 ){
|
|
rc = initPage(*ppPage, pParent);
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Release a MemPage. This should be called once for each prior
|
|
** call to getPage.
|
|
*/
|
|
static void releasePage(MemPage *pPage){
|
|
if( pPage ){
|
|
assert( pPage->aData );
|
|
assert( pPage->pBt );
|
|
assert( &pPage->aData[pPage->pBt->pageSize]==(unsigned char*)pPage );
|
|
sqlite3pager_unref(pPage->aData);
|
|
}
|
|
}
|
|
|
|
/*
|
|
** This routine is called when the reference count for a page
|
|
** reaches zero. We need to unref the pParent pointer when that
|
|
** happens.
|
|
*/
|
|
static void pageDestructor(void *pData, int pageSize){
|
|
MemPage *pPage;
|
|
assert( (pageSize & 7)==0 );
|
|
pPage = (MemPage*)&((char*)pData)[pageSize];
|
|
if( pPage->pParent ){
|
|
MemPage *pParent = pPage->pParent;
|
|
pPage->pParent = 0;
|
|
releasePage(pParent);
|
|
}
|
|
pPage->isInit = 0;
|
|
}
|
|
|
|
/*
|
|
** During a rollback, when the pager reloads information into the cache
|
|
** so that the cache is restored to its original state at the start of
|
|
** the transaction, for each page restored this routine is called.
|
|
**
|
|
** This routine needs to reset the extra data section at the end of the
|
|
** page to agree with the restored data.
|
|
*/
|
|
static void pageReinit(void *pData, int pageSize){
|
|
MemPage *pPage;
|
|
assert( (pageSize & 7)==0 );
|
|
pPage = (MemPage*)&((char*)pData)[pageSize];
|
|
if( pPage->isInit ){
|
|
pPage->isInit = 0;
|
|
initPage(pPage, pPage->pParent);
|
|
}
|
|
}
|
|
|
|
/*
|
|
** Open a database file.
|
|
**
|
|
** zFilename is the name of the database file. If zFilename is NULL
|
|
** a new database with a random name is created. This randomly named
|
|
** database file will be deleted when sqlite3BtreeClose() is called.
|
|
*/
|
|
int sqlite3BtreeOpen(
|
|
const char *zFilename, /* Name of the file containing the BTree database */
|
|
sqlite3 *pSqlite, /* Associated database handle */
|
|
Btree **ppBtree, /* Pointer to new Btree object written here */
|
|
int flags /* Options */
|
|
){
|
|
BtShared *pBt; /* Shared part of btree structure */
|
|
Btree *p; /* Handle to return */
|
|
int rc;
|
|
int nReserve;
|
|
unsigned char zDbHeader[100];
|
|
#if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
|
|
const ThreadData *pTsdro;
|
|
#endif
|
|
|
|
/* Set the variable isMemdb to true for an in-memory database, or
|
|
** false for a file-based database. This symbol is only required if
|
|
** either of the shared-data or autovacuum features are compiled
|
|
** into the library.
|
|
*/
|
|
#if !defined(SQLITE_OMIT_SHARED_CACHE) || !defined(SQLITE_OMIT_AUTOVACUUM)
|
|
#ifdef SQLITE_OMIT_MEMORYDB
|
|
const int isMemdb = !zFilename;
|
|
#else
|
|
const int isMemdb = !zFilename || (strcmp(zFilename, ":memory:")?0:1);
|
|
#endif
|
|
#endif
|
|
|
|
p = sqliteMalloc(sizeof(Btree));
|
|
if( !p ){
|
|
return SQLITE_NOMEM;
|
|
}
|
|
p->inTrans = TRANS_NONE;
|
|
p->pSqlite = pSqlite;
|
|
|
|
/* Try to find an existing Btree structure opened on zFilename. */
|
|
#if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
|
|
pTsdro = sqlite3ThreadDataReadOnly();
|
|
if( pTsdro->useSharedData && zFilename && !isMemdb ){
|
|
char *zFullPathname = sqlite3OsFullPathname(zFilename);
|
|
if( !zFullPathname ){
|
|
sqliteFree(p);
|
|
return SQLITE_NOMEM;
|
|
}
|
|
for(pBt=pTsdro->pBtree; pBt; pBt=pBt->pNext){
|
|
assert( pBt->nRef>0 );
|
|
if( 0==strcmp(zFullPathname, sqlite3pager_filename(pBt->pPager)) ){
|
|
p->pBt = pBt;
|
|
*ppBtree = p;
|
|
pBt->nRef++;
|
|
sqliteFree(zFullPathname);
|
|
return SQLITE_OK;
|
|
}
|
|
}
|
|
sqliteFree(zFullPathname);
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** The following asserts make sure that structures used by the btree are
|
|
** the right size. This is to guard against size changes that result
|
|
** when compiling on a different architecture.
|
|
*/
|
|
assert( sizeof(i64)==8 || sizeof(i64)==4 );
|
|
assert( sizeof(u64)==8 || sizeof(u64)==4 );
|
|
assert( sizeof(u32)==4 );
|
|
assert( sizeof(u16)==2 );
|
|
assert( sizeof(Pgno)==4 );
|
|
|
|
pBt = sqliteMalloc( sizeof(*pBt) );
|
|
if( pBt==0 ){
|
|
*ppBtree = 0;
|
|
sqliteFree(p);
|
|
return SQLITE_NOMEM;
|
|
}
|
|
rc = sqlite3pager_open(&pBt->pPager, zFilename, EXTRA_SIZE, flags);
|
|
if( rc!=SQLITE_OK ){
|
|
if( pBt->pPager ) sqlite3pager_close(pBt->pPager);
|
|
sqliteFree(pBt);
|
|
sqliteFree(p);
|
|
*ppBtree = 0;
|
|
return rc;
|
|
}
|
|
p->pBt = pBt;
|
|
|
|
sqlite3pager_set_destructor(pBt->pPager, pageDestructor);
|
|
sqlite3pager_set_reiniter(pBt->pPager, pageReinit);
|
|
pBt->pCursor = 0;
|
|
pBt->pPage1 = 0;
|
|
pBt->readOnly = sqlite3pager_isreadonly(pBt->pPager);
|
|
sqlite3pager_read_fileheader(pBt->pPager, sizeof(zDbHeader), zDbHeader);
|
|
pBt->pageSize = get2byte(&zDbHeader[16]);
|
|
if( pBt->pageSize<512 || pBt->pageSize>SQLITE_MAX_PAGE_SIZE
|
|
|| ((pBt->pageSize-1)&pBt->pageSize)!=0 ){
|
|
pBt->pageSize = SQLITE_DEFAULT_PAGE_SIZE;
|
|
pBt->maxEmbedFrac = 64; /* 25% */
|
|
pBt->minEmbedFrac = 32; /* 12.5% */
|
|
pBt->minLeafFrac = 32; /* 12.5% */
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/* If the magic name ":memory:" will create an in-memory database, then
|
|
** do not set the auto-vacuum flag, even if SQLITE_DEFAULT_AUTOVACUUM
|
|
** is true. On the other hand, if SQLITE_OMIT_MEMORYDB has been defined,
|
|
** then ":memory:" is just a regular file-name. Respect the auto-vacuum
|
|
** default in this case.
|
|
*/
|
|
if( zFilename && !isMemdb ){
|
|
pBt->autoVacuum = SQLITE_DEFAULT_AUTOVACUUM;
|
|
}
|
|
#endif
|
|
nReserve = 0;
|
|
}else{
|
|
nReserve = zDbHeader[20];
|
|
pBt->maxEmbedFrac = zDbHeader[21];
|
|
pBt->minEmbedFrac = zDbHeader[22];
|
|
pBt->minLeafFrac = zDbHeader[23];
|
|
pBt->pageSizeFixed = 1;
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
pBt->autoVacuum = (get4byte(&zDbHeader[36 + 4*4])?1:0);
|
|
#endif
|
|
}
|
|
pBt->usableSize = pBt->pageSize - nReserve;
|
|
assert( (pBt->pageSize & 7)==0 ); /* 8-byte alignment of pageSize */
|
|
sqlite3pager_set_pagesize(pBt->pPager, pBt->pageSize);
|
|
|
|
#if !defined(SQLITE_OMIT_SHARED_CACHE) && !defined(SQLITE_OMIT_DISKIO)
|
|
/* Add the new btree to the linked list starting at ThreadData.pBtree.
|
|
** There is no chance that a malloc() may fail inside of the
|
|
** sqlite3ThreadData() call, as the ThreadData structure must have already
|
|
** been allocated for pTsdro->useSharedData to be non-zero.
|
|
*/
|
|
if( pTsdro->useSharedData && zFilename && !isMemdb ){
|
|
pBt->pNext = pTsdro->pBtree;
|
|
sqlite3ThreadData()->pBtree = pBt;
|
|
}
|
|
#endif
|
|
pBt->nRef = 1;
|
|
*ppBtree = p;
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Close an open database and invalidate all cursors.
|
|
*/
|
|
int sqlite3BtreeClose(Btree *p){
|
|
BtShared *pBt = p->pBt;
|
|
BtCursor *pCur;
|
|
|
|
#ifndef SQLITE_OMIT_SHARED_CACHE
|
|
ThreadData *pTsd;
|
|
#endif
|
|
|
|
/* Close all cursors opened via this handle. */
|
|
pCur = pBt->pCursor;
|
|
while( pCur ){
|
|
BtCursor *pTmp = pCur;
|
|
pCur = pCur->pNext;
|
|
if( pTmp->pBtree==p ){
|
|
sqlite3BtreeCloseCursor(pTmp);
|
|
}
|
|
}
|
|
|
|
/* Rollback any active transaction and free the handle structure.
|
|
** The call to sqlite3BtreeRollback() drops any table-locks held by
|
|
** this handle.
|
|
*/
|
|
sqlite3BtreeRollback(p);
|
|
sqliteFree(p);
|
|
|
|
#ifndef SQLITE_OMIT_SHARED_CACHE
|
|
/* If there are still other outstanding references to the shared-btree
|
|
** structure, return now. The remainder of this procedure cleans
|
|
** up the shared-btree.
|
|
*/
|
|
assert( pBt->nRef>0 );
|
|
pBt->nRef--;
|
|
if( pBt->nRef ){
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/* Remove the shared-btree from the thread wide list. Call
|
|
** ThreadDataReadOnly() and then cast away the const property of the
|
|
** pointer to avoid allocating thread data if it is not really required.
|
|
*/
|
|
pTsd = (ThreadData *)sqlite3ThreadDataReadOnly();
|
|
if( pTsd->pBtree==pBt ){
|
|
assert( pTsd==sqlite3ThreadData() );
|
|
pTsd->pBtree = pBt->pNext;
|
|
}else{
|
|
BtShared *pPrev;
|
|
for(pPrev=pTsd->pBtree; pPrev && pPrev->pNext!=pBt; pPrev=pPrev->pNext){}
|
|
if( pPrev ){
|
|
assert( pTsd==sqlite3ThreadData() );
|
|
pPrev->pNext = pBt->pNext;
|
|
}
|
|
}
|
|
#endif
|
|
|
|
/* Close the pager and free the shared-btree structure */
|
|
assert( !pBt->pCursor );
|
|
sqlite3pager_close(pBt->pPager);
|
|
if( pBt->xFreeSchema && pBt->pSchema ){
|
|
pBt->xFreeSchema(pBt->pSchema);
|
|
}
|
|
sqliteFree(pBt->pSchema);
|
|
sqliteFree(pBt);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Change the busy handler callback function.
|
|
*/
|
|
int sqlite3BtreeSetBusyHandler(Btree *p, BusyHandler *pHandler){
|
|
BtShared *pBt = p->pBt;
|
|
pBt->pBusyHandler = pHandler;
|
|
sqlite3pager_set_busyhandler(pBt->pPager, pHandler);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Change the limit on the number of pages allowed in the cache.
|
|
**
|
|
** The maximum number of cache pages is set to the absolute
|
|
** value of mxPage. If mxPage is negative, the pager will
|
|
** operate asynchronously - it will not stop to do fsync()s
|
|
** to insure data is written to the disk surface before
|
|
** continuing. Transactions still work if synchronous is off,
|
|
** and the database cannot be corrupted if this program
|
|
** crashes. But if the operating system crashes or there is
|
|
** an abrupt power failure when synchronous is off, the database
|
|
** could be left in an inconsistent and unrecoverable state.
|
|
** Synchronous is on by default so database corruption is not
|
|
** normally a worry.
|
|
*/
|
|
int sqlite3BtreeSetCacheSize(Btree *p, int mxPage){
|
|
BtShared *pBt = p->pBt;
|
|
sqlite3pager_set_cachesize(pBt->pPager, mxPage);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Change the way data is synced to disk in order to increase or decrease
|
|
** how well the database resists damage due to OS crashes and power
|
|
** failures. Level 1 is the same as asynchronous (no syncs() occur and
|
|
** there is a high probability of damage) Level 2 is the default. There
|
|
** is a very low but non-zero probability of damage. Level 3 reduces the
|
|
** probability of damage to near zero but with a write performance reduction.
|
|
*/
|
|
#ifndef SQLITE_OMIT_PAGER_PRAGMAS
|
|
int sqlite3BtreeSetSafetyLevel(Btree *p, int level, int fullSync){
|
|
BtShared *pBt = p->pBt;
|
|
sqlite3pager_set_safety_level(pBt->pPager, level, fullSync);
|
|
return SQLITE_OK;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** Return TRUE if the given btree is set to safety level 1. In other
|
|
** words, return TRUE if no sync() occurs on the disk files.
|
|
*/
|
|
int sqlite3BtreeSyncDisabled(Btree *p){
|
|
BtShared *pBt = p->pBt;
|
|
assert( pBt && pBt->pPager );
|
|
return sqlite3pager_nosync(pBt->pPager);
|
|
}
|
|
|
|
#if !defined(SQLITE_OMIT_PAGER_PRAGMAS) || !defined(SQLITE_OMIT_VACUUM)
|
|
/*
|
|
** Change the default pages size and the number of reserved bytes per page.
|
|
**
|
|
** The page size must be a power of 2 between 512 and 65536. If the page
|
|
** size supplied does not meet this constraint then the page size is not
|
|
** changed.
|
|
**
|
|
** Page sizes are constrained to be a power of two so that the region
|
|
** of the database file used for locking (beginning at PENDING_BYTE,
|
|
** the first byte past the 1GB boundary, 0x40000000) needs to occur
|
|
** at the beginning of a page.
|
|
**
|
|
** If parameter nReserve is less than zero, then the number of reserved
|
|
** bytes per page is left unchanged.
|
|
*/
|
|
int sqlite3BtreeSetPageSize(Btree *p, int pageSize, int nReserve){
|
|
BtShared *pBt = p->pBt;
|
|
if( pBt->pageSizeFixed ){
|
|
return SQLITE_READONLY;
|
|
}
|
|
if( nReserve<0 ){
|
|
nReserve = pBt->pageSize - pBt->usableSize;
|
|
}
|
|
if( pageSize>=512 && pageSize<=SQLITE_MAX_PAGE_SIZE &&
|
|
((pageSize-1)&pageSize)==0 ){
|
|
assert( (pageSize & 7)==0 );
|
|
assert( !pBt->pPage1 && !pBt->pCursor );
|
|
pBt->pageSize = sqlite3pager_set_pagesize(pBt->pPager, pageSize);
|
|
}
|
|
pBt->usableSize = pBt->pageSize - nReserve;
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Return the currently defined page size
|
|
*/
|
|
int sqlite3BtreeGetPageSize(Btree *p){
|
|
return p->pBt->pageSize;
|
|
}
|
|
int sqlite3BtreeGetReserve(Btree *p){
|
|
return p->pBt->pageSize - p->pBt->usableSize;
|
|
}
|
|
#endif /* !defined(SQLITE_OMIT_PAGER_PRAGMAS) || !defined(SQLITE_OMIT_VACUUM) */
|
|
|
|
/*
|
|
** Change the 'auto-vacuum' property of the database. If the 'autoVacuum'
|
|
** parameter is non-zero, then auto-vacuum mode is enabled. If zero, it
|
|
** is disabled. The default value for the auto-vacuum property is
|
|
** determined by the SQLITE_DEFAULT_AUTOVACUUM macro.
|
|
*/
|
|
int sqlite3BtreeSetAutoVacuum(Btree *p, int autoVacuum){
|
|
BtShared *pBt = p->pBt;;
|
|
#ifdef SQLITE_OMIT_AUTOVACUUM
|
|
return SQLITE_READONLY;
|
|
#else
|
|
if( pBt->pageSizeFixed ){
|
|
return SQLITE_READONLY;
|
|
}
|
|
pBt->autoVacuum = (autoVacuum?1:0);
|
|
return SQLITE_OK;
|
|
#endif
|
|
}
|
|
|
|
/*
|
|
** Return the value of the 'auto-vacuum' property. If auto-vacuum is
|
|
** enabled 1 is returned. Otherwise 0.
|
|
*/
|
|
int sqlite3BtreeGetAutoVacuum(Btree *p){
|
|
#ifdef SQLITE_OMIT_AUTOVACUUM
|
|
return 0;
|
|
#else
|
|
return p->pBt->autoVacuum;
|
|
#endif
|
|
}
|
|
|
|
|
|
/*
|
|
** Get a reference to pPage1 of the database file. This will
|
|
** also acquire a readlock on that file.
|
|
**
|
|
** SQLITE_OK is returned on success. If the file is not a
|
|
** well-formed database file, then SQLITE_CORRUPT is returned.
|
|
** SQLITE_BUSY is returned if the database is locked. SQLITE_NOMEM
|
|
** is returned if we run out of memory. SQLITE_PROTOCOL is returned
|
|
** if there is a locking protocol violation.
|
|
*/
|
|
static int lockBtree(BtShared *pBt){
|
|
int rc, pageSize;
|
|
MemPage *pPage1;
|
|
if( pBt->pPage1 ) return SQLITE_OK;
|
|
rc = getPage(pBt, 1, &pPage1);
|
|
if( rc!=SQLITE_OK ) return rc;
|
|
|
|
|
|
/* Do some checking to help insure the file we opened really is
|
|
** a valid database file.
|
|
*/
|
|
rc = SQLITE_NOTADB;
|
|
if( sqlite3pager_pagecount(pBt->pPager)>0 ){
|
|
u8 *page1 = pPage1->aData;
|
|
if( memcmp(page1, zMagicHeader, 16)!=0 ){
|
|
goto page1_init_failed;
|
|
}
|
|
if( page1[18]>1 || page1[19]>1 ){
|
|
goto page1_init_failed;
|
|
}
|
|
pageSize = get2byte(&page1[16]);
|
|
if( ((pageSize-1)&pageSize)!=0 ){
|
|
goto page1_init_failed;
|
|
}
|
|
assert( (pageSize & 7)==0 );
|
|
pBt->pageSize = pageSize;
|
|
pBt->usableSize = pageSize - page1[20];
|
|
if( pBt->usableSize<500 ){
|
|
goto page1_init_failed;
|
|
}
|
|
pBt->maxEmbedFrac = page1[21];
|
|
pBt->minEmbedFrac = page1[22];
|
|
pBt->minLeafFrac = page1[23];
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
pBt->autoVacuum = (get4byte(&page1[36 + 4*4])?1:0);
|
|
#endif
|
|
}
|
|
|
|
/* maxLocal is the maximum amount of payload to store locally for
|
|
** a cell. Make sure it is small enough so that at least minFanout
|
|
** cells can will fit on one page. We assume a 10-byte page header.
|
|
** Besides the payload, the cell must store:
|
|
** 2-byte pointer to the cell
|
|
** 4-byte child pointer
|
|
** 9-byte nKey value
|
|
** 4-byte nData value
|
|
** 4-byte overflow page pointer
|
|
** So a cell consists of a 2-byte poiner, a header which is as much as
|
|
** 17 bytes long, 0 to N bytes of payload, and an optional 4 byte overflow
|
|
** page pointer.
|
|
*/
|
|
pBt->maxLocal = (pBt->usableSize-12)*pBt->maxEmbedFrac/255 - 23;
|
|
pBt->minLocal = (pBt->usableSize-12)*pBt->minEmbedFrac/255 - 23;
|
|
pBt->maxLeaf = pBt->usableSize - 35;
|
|
pBt->minLeaf = (pBt->usableSize-12)*pBt->minLeafFrac/255 - 23;
|
|
if( pBt->minLocal>pBt->maxLocal || pBt->maxLocal<0 ){
|
|
goto page1_init_failed;
|
|
}
|
|
assert( pBt->maxLeaf + 23 <= MX_CELL_SIZE(pBt) );
|
|
pBt->pPage1 = pPage1;
|
|
return SQLITE_OK;
|
|
|
|
page1_init_failed:
|
|
releasePage(pPage1);
|
|
pBt->pPage1 = 0;
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** This routine works like lockBtree() except that it also invokes the
|
|
** busy callback if there is lock contention.
|
|
*/
|
|
static int lockBtreeWithRetry(Btree *pRef){
|
|
int rc = SQLITE_OK;
|
|
if( pRef->inTrans==TRANS_NONE ){
|
|
u8 inTransaction = pRef->pBt->inTransaction;
|
|
btreeIntegrity(pRef);
|
|
rc = sqlite3BtreeBeginTrans(pRef, 0);
|
|
pRef->pBt->inTransaction = inTransaction;
|
|
pRef->inTrans = TRANS_NONE;
|
|
if( rc==SQLITE_OK ){
|
|
pRef->pBt->nTransaction--;
|
|
}
|
|
btreeIntegrity(pRef);
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
|
|
/*
|
|
** If there are no outstanding cursors and we are not in the middle
|
|
** of a transaction but there is a read lock on the database, then
|
|
** this routine unrefs the first page of the database file which
|
|
** has the effect of releasing the read lock.
|
|
**
|
|
** If there are any outstanding cursors, this routine is a no-op.
|
|
**
|
|
** If there is a transaction in progress, this routine is a no-op.
|
|
*/
|
|
static void unlockBtreeIfUnused(BtShared *pBt){
|
|
if( pBt->inTransaction==TRANS_NONE && pBt->pCursor==0 && pBt->pPage1!=0 ){
|
|
if( pBt->pPage1->aData==0 ){
|
|
MemPage *pPage = pBt->pPage1;
|
|
pPage->aData = &((u8*)pPage)[-pBt->pageSize];
|
|
pPage->pBt = pBt;
|
|
pPage->pgno = 1;
|
|
}
|
|
releasePage(pBt->pPage1);
|
|
pBt->pPage1 = 0;
|
|
pBt->inStmt = 0;
|
|
}
|
|
}
|
|
|
|
/*
|
|
** Create a new database by initializing the first page of the
|
|
** file.
|
|
*/
|
|
static int newDatabase(BtShared *pBt){
|
|
MemPage *pP1;
|
|
unsigned char *data;
|
|
int rc;
|
|
if( sqlite3pager_pagecount(pBt->pPager)>0 ) return SQLITE_OK;
|
|
pP1 = pBt->pPage1;
|
|
assert( pP1!=0 );
|
|
data = pP1->aData;
|
|
rc = sqlite3pager_write(data);
|
|
if( rc ) return rc;
|
|
memcpy(data, zMagicHeader, sizeof(zMagicHeader));
|
|
assert( sizeof(zMagicHeader)==16 );
|
|
put2byte(&data[16], pBt->pageSize);
|
|
data[18] = 1;
|
|
data[19] = 1;
|
|
data[20] = pBt->pageSize - pBt->usableSize;
|
|
data[21] = pBt->maxEmbedFrac;
|
|
data[22] = pBt->minEmbedFrac;
|
|
data[23] = pBt->minLeafFrac;
|
|
memset(&data[24], 0, 100-24);
|
|
zeroPage(pP1, PTF_INTKEY|PTF_LEAF|PTF_LEAFDATA );
|
|
pBt->pageSizeFixed = 1;
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
put4byte(&data[36 + 4*4], 1);
|
|
}
|
|
#endif
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Attempt to start a new transaction. A write-transaction
|
|
** is started if the second argument is nonzero, otherwise a read-
|
|
** transaction. If the second argument is 2 or more and exclusive
|
|
** transaction is started, meaning that no other process is allowed
|
|
** to access the database. A preexisting transaction may not be
|
|
** upgraded to exclusive by calling this routine a second time - the
|
|
** exclusivity flag only works for a new transaction.
|
|
**
|
|
** A write-transaction must be started before attempting any
|
|
** changes to the database. None of the following routines
|
|
** will work unless a transaction is started first:
|
|
**
|
|
** sqlite3BtreeCreateTable()
|
|
** sqlite3BtreeCreateIndex()
|
|
** sqlite3BtreeClearTable()
|
|
** sqlite3BtreeDropTable()
|
|
** sqlite3BtreeInsert()
|
|
** sqlite3BtreeDelete()
|
|
** sqlite3BtreeUpdateMeta()
|
|
**
|
|
** If an initial attempt to acquire the lock fails because of lock contention
|
|
** and the database was previously unlocked, then invoke the busy handler
|
|
** if there is one. But if there was previously a read-lock, do not
|
|
** invoke the busy handler - just return SQLITE_BUSY. SQLITE_BUSY is
|
|
** returned when there is already a read-lock in order to avoid a deadlock.
|
|
**
|
|
** Suppose there are two processes A and B. A has a read lock and B has
|
|
** a reserved lock. B tries to promote to exclusive but is blocked because
|
|
** of A's read lock. A tries to promote to reserved but is blocked by B.
|
|
** One or the other of the two processes must give way or there can be
|
|
** no progress. By returning SQLITE_BUSY and not invoking the busy callback
|
|
** when A already has a read lock, we encourage A to give up and let B
|
|
** proceed.
|
|
*/
|
|
int sqlite3BtreeBeginTrans(Btree *p, int wrflag){
|
|
BtShared *pBt = p->pBt;
|
|
int rc = SQLITE_OK;
|
|
|
|
btreeIntegrity(p);
|
|
|
|
/* If the btree is already in a write-transaction, or it
|
|
** is already in a read-transaction and a read-transaction
|
|
** is requested, this is a no-op.
|
|
*/
|
|
if( p->inTrans==TRANS_WRITE || (p->inTrans==TRANS_READ && !wrflag) ){
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/* Write transactions are not possible on a read-only database */
|
|
if( pBt->readOnly && wrflag ){
|
|
return SQLITE_READONLY;
|
|
}
|
|
|
|
/* If another database handle has already opened a write transaction
|
|
** on this shared-btree structure and a second write transaction is
|
|
** requested, return SQLITE_BUSY.
|
|
*/
|
|
if( pBt->inTransaction==TRANS_WRITE && wrflag ){
|
|
return SQLITE_BUSY;
|
|
}
|
|
|
|
do {
|
|
if( pBt->pPage1==0 ){
|
|
rc = lockBtree(pBt);
|
|
}
|
|
|
|
if( rc==SQLITE_OK && wrflag ){
|
|
rc = sqlite3pager_begin(pBt->pPage1->aData, wrflag>1);
|
|
if( rc==SQLITE_OK ){
|
|
rc = newDatabase(pBt);
|
|
}
|
|
}
|
|
|
|
if( rc==SQLITE_OK ){
|
|
if( wrflag ) pBt->inStmt = 0;
|
|
}else{
|
|
unlockBtreeIfUnused(pBt);
|
|
}
|
|
}while( rc==SQLITE_BUSY && pBt->inTransaction==TRANS_NONE &&
|
|
sqlite3InvokeBusyHandler(pBt->pBusyHandler) );
|
|
|
|
if( rc==SQLITE_OK ){
|
|
if( p->inTrans==TRANS_NONE ){
|
|
pBt->nTransaction++;
|
|
}
|
|
p->inTrans = (wrflag?TRANS_WRITE:TRANS_READ);
|
|
if( p->inTrans>pBt->inTransaction ){
|
|
pBt->inTransaction = p->inTrans;
|
|
}
|
|
}
|
|
|
|
btreeIntegrity(p);
|
|
return rc;
|
|
}
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
|
|
/*
|
|
** Set the pointer-map entries for all children of page pPage. Also, if
|
|
** pPage contains cells that point to overflow pages, set the pointer
|
|
** map entries for the overflow pages as well.
|
|
*/
|
|
static int setChildPtrmaps(MemPage *pPage){
|
|
int i; /* Counter variable */
|
|
int nCell; /* Number of cells in page pPage */
|
|
int rc = SQLITE_OK; /* Return code */
|
|
BtShared *pBt = pPage->pBt;
|
|
int isInitOrig = pPage->isInit;
|
|
Pgno pgno = pPage->pgno;
|
|
|
|
initPage(pPage, 0);
|
|
nCell = pPage->nCell;
|
|
|
|
for(i=0; i<nCell; i++){
|
|
u8 *pCell = findCell(pPage, i);
|
|
|
|
rc = ptrmapPutOvflPtr(pPage, pCell);
|
|
if( rc!=SQLITE_OK ){
|
|
goto set_child_ptrmaps_out;
|
|
}
|
|
|
|
if( !pPage->leaf ){
|
|
Pgno childPgno = get4byte(pCell);
|
|
rc = ptrmapPut(pBt, childPgno, PTRMAP_BTREE, pgno);
|
|
if( rc!=SQLITE_OK ) goto set_child_ptrmaps_out;
|
|
}
|
|
}
|
|
|
|
if( !pPage->leaf ){
|
|
Pgno childPgno = get4byte(&pPage->aData[pPage->hdrOffset+8]);
|
|
rc = ptrmapPut(pBt, childPgno, PTRMAP_BTREE, pgno);
|
|
}
|
|
|
|
set_child_ptrmaps_out:
|
|
pPage->isInit = isInitOrig;
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Somewhere on pPage, which is guarenteed to be a btree page, not an overflow
|
|
** page, is a pointer to page iFrom. Modify this pointer so that it points to
|
|
** iTo. Parameter eType describes the type of pointer to be modified, as
|
|
** follows:
|
|
**
|
|
** PTRMAP_BTREE: pPage is a btree-page. The pointer points at a child
|
|
** page of pPage.
|
|
**
|
|
** PTRMAP_OVERFLOW1: pPage is a btree-page. The pointer points at an overflow
|
|
** page pointed to by one of the cells on pPage.
|
|
**
|
|
** PTRMAP_OVERFLOW2: pPage is an overflow-page. The pointer points at the next
|
|
** overflow page in the list.
|
|
*/
|
|
static int modifyPagePointer(MemPage *pPage, Pgno iFrom, Pgno iTo, u8 eType){
|
|
if( eType==PTRMAP_OVERFLOW2 ){
|
|
/* The pointer is always the first 4 bytes of the page in this case. */
|
|
if( get4byte(pPage->aData)!=iFrom ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
put4byte(pPage->aData, iTo);
|
|
}else{
|
|
int isInitOrig = pPage->isInit;
|
|
int i;
|
|
int nCell;
|
|
|
|
initPage(pPage, 0);
|
|
nCell = pPage->nCell;
|
|
|
|
for(i=0; i<nCell; i++){
|
|
u8 *pCell = findCell(pPage, i);
|
|
if( eType==PTRMAP_OVERFLOW1 ){
|
|
CellInfo info;
|
|
parseCellPtr(pPage, pCell, &info);
|
|
if( info.iOverflow ){
|
|
if( iFrom==get4byte(&pCell[info.iOverflow]) ){
|
|
put4byte(&pCell[info.iOverflow], iTo);
|
|
break;
|
|
}
|
|
}
|
|
}else{
|
|
if( get4byte(pCell)==iFrom ){
|
|
put4byte(pCell, iTo);
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
|
|
if( i==nCell ){
|
|
if( eType!=PTRMAP_BTREE ||
|
|
get4byte(&pPage->aData[pPage->hdrOffset+8])!=iFrom ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
put4byte(&pPage->aData[pPage->hdrOffset+8], iTo);
|
|
}
|
|
|
|
pPage->isInit = isInitOrig;
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
|
|
/*
|
|
** Move the open database page pDbPage to location iFreePage in the
|
|
** database. The pDbPage reference remains valid.
|
|
*/
|
|
static int relocatePage(
|
|
BtShared *pBt, /* Btree */
|
|
MemPage *pDbPage, /* Open page to move */
|
|
u8 eType, /* Pointer map 'type' entry for pDbPage */
|
|
Pgno iPtrPage, /* Pointer map 'page-no' entry for pDbPage */
|
|
Pgno iFreePage /* The location to move pDbPage to */
|
|
){
|
|
MemPage *pPtrPage; /* The page that contains a pointer to pDbPage */
|
|
Pgno iDbPage = pDbPage->pgno;
|
|
Pager *pPager = pBt->pPager;
|
|
int rc;
|
|
|
|
assert( eType==PTRMAP_OVERFLOW2 || eType==PTRMAP_OVERFLOW1 ||
|
|
eType==PTRMAP_BTREE || eType==PTRMAP_ROOTPAGE );
|
|
|
|
/* Move page iDbPage from it's current location to page number iFreePage */
|
|
TRACE(("AUTOVACUUM: Moving %d to free page %d (ptr page %d type %d)\n",
|
|
iDbPage, iFreePage, iPtrPage, eType));
|
|
rc = sqlite3pager_movepage(pPager, pDbPage->aData, iFreePage);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
pDbPage->pgno = iFreePage;
|
|
|
|
/* If pDbPage was a btree-page, then it may have child pages and/or cells
|
|
** that point to overflow pages. The pointer map entries for all these
|
|
** pages need to be changed.
|
|
**
|
|
** If pDbPage is an overflow page, then the first 4 bytes may store a
|
|
** pointer to a subsequent overflow page. If this is the case, then
|
|
** the pointer map needs to be updated for the subsequent overflow page.
|
|
*/
|
|
if( eType==PTRMAP_BTREE || eType==PTRMAP_ROOTPAGE ){
|
|
rc = setChildPtrmaps(pDbPage);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
}else{
|
|
Pgno nextOvfl = get4byte(pDbPage->aData);
|
|
if( nextOvfl!=0 ){
|
|
rc = ptrmapPut(pBt, nextOvfl, PTRMAP_OVERFLOW2, iFreePage);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
}
|
|
}
|
|
|
|
/* Fix the database pointer on page iPtrPage that pointed at iDbPage so
|
|
** that it points at iFreePage. Also fix the pointer map entry for
|
|
** iPtrPage.
|
|
*/
|
|
if( eType!=PTRMAP_ROOTPAGE ){
|
|
rc = getPage(pBt, iPtrPage, &pPtrPage);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
rc = sqlite3pager_write(pPtrPage->aData);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(pPtrPage);
|
|
return rc;
|
|
}
|
|
rc = modifyPagePointer(pPtrPage, iDbPage, iFreePage, eType);
|
|
releasePage(pPtrPage);
|
|
if( rc==SQLITE_OK ){
|
|
rc = ptrmapPut(pBt, iFreePage, eType, iPtrPage);
|
|
}
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/* Forward declaration required by autoVacuumCommit(). */
|
|
static int allocatePage(BtShared *, MemPage **, Pgno *, Pgno, u8);
|
|
|
|
/*
|
|
** This routine is called prior to sqlite3pager_commit when a transaction
|
|
** is commited for an auto-vacuum database.
|
|
*/
|
|
static int autoVacuumCommit(BtShared *pBt, Pgno *nTrunc){
|
|
Pager *pPager = pBt->pPager;
|
|
Pgno nFreeList; /* Number of pages remaining on the free-list. */
|
|
int nPtrMap; /* Number of pointer-map pages deallocated */
|
|
Pgno origSize; /* Pages in the database file */
|
|
Pgno finSize; /* Pages in the database file after truncation */
|
|
int rc; /* Return code */
|
|
u8 eType;
|
|
int pgsz = pBt->pageSize; /* Page size for this database */
|
|
Pgno iDbPage; /* The database page to move */
|
|
MemPage *pDbMemPage = 0; /* "" */
|
|
Pgno iPtrPage; /* The page that contains a pointer to iDbPage */
|
|
Pgno iFreePage; /* The free-list page to move iDbPage to */
|
|
MemPage *pFreeMemPage = 0; /* "" */
|
|
|
|
#ifndef NDEBUG
|
|
int nRef = *sqlite3pager_stats(pPager);
|
|
#endif
|
|
|
|
assert( pBt->autoVacuum );
|
|
if( PTRMAP_ISPAGE(pBt, sqlite3pager_pagecount(pPager)) ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
|
|
/* Figure out how many free-pages are in the database. If there are no
|
|
** free pages, then auto-vacuum is a no-op.
|
|
*/
|
|
nFreeList = get4byte(&pBt->pPage1->aData[36]);
|
|
if( nFreeList==0 ){
|
|
*nTrunc = 0;
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/* This block figures out how many pages there are in the database
|
|
** now (variable origSize), and how many there will be after the
|
|
** truncation (variable finSize).
|
|
**
|
|
** The final size is the original size, less the number of free pages
|
|
** in the database, less any pointer-map pages that will no longer
|
|
** be required, less 1 if the pending-byte page was part of the database
|
|
** but is not after the truncation.
|
|
**/
|
|
origSize = sqlite3pager_pagecount(pPager);
|
|
if( origSize==PENDING_BYTE_PAGE(pBt) ){
|
|
origSize--;
|
|
}
|
|
nPtrMap = (nFreeList-origSize+PTRMAP_PAGENO(pBt, origSize)+pgsz/5)/(pgsz/5);
|
|
finSize = origSize - nFreeList - nPtrMap;
|
|
if( origSize>(Pgno)PENDING_BYTE_PAGE(pBt) && finSize<=(Pgno)PENDING_BYTE_PAGE(pBt) ){
|
|
finSize--;
|
|
}
|
|
while( PTRMAP_ISPAGE(pBt, finSize) || finSize==PENDING_BYTE_PAGE(pBt) ){
|
|
finSize--;
|
|
}
|
|
TRACE(("AUTOVACUUM: Begin (db size %d->%d)\n", origSize, finSize));
|
|
|
|
/* Variable 'finSize' will be the size of the file in pages after
|
|
** the auto-vacuum has completed (the current file size minus the number
|
|
** of pages on the free list). Loop through the pages that lie beyond
|
|
** this mark, and if they are not already on the free list, move them
|
|
** to a free page earlier in the file (somewhere before finSize).
|
|
*/
|
|
for( iDbPage=finSize+1; iDbPage<=origSize; iDbPage++ ){
|
|
/* If iDbPage is a pointer map page, or the pending-byte page, skip it. */
|
|
if( PTRMAP_ISPAGE(pBt, iDbPage) || iDbPage==PENDING_BYTE_PAGE(pBt) ){
|
|
continue;
|
|
}
|
|
|
|
rc = ptrmapGet(pBt, iDbPage, &eType, &iPtrPage);
|
|
if( rc!=SQLITE_OK ) goto autovacuum_out;
|
|
if( eType==PTRMAP_ROOTPAGE ){
|
|
rc = SQLITE_CORRUPT_BKPT;
|
|
goto autovacuum_out;
|
|
}
|
|
|
|
/* If iDbPage is free, do not swap it. */
|
|
if( eType==PTRMAP_FREEPAGE ){
|
|
continue;
|
|
}
|
|
rc = getPage(pBt, iDbPage, &pDbMemPage);
|
|
if( rc!=SQLITE_OK ) goto autovacuum_out;
|
|
|
|
/* Find the next page in the free-list that is not already at the end
|
|
** of the file. A page can be pulled off the free list using the
|
|
** allocatePage() routine.
|
|
*/
|
|
do{
|
|
if( pFreeMemPage ){
|
|
releasePage(pFreeMemPage);
|
|
pFreeMemPage = 0;
|
|
}
|
|
rc = allocatePage(pBt, &pFreeMemPage, &iFreePage, 0, 0);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(pDbMemPage);
|
|
goto autovacuum_out;
|
|
}
|
|
assert( iFreePage<=origSize );
|
|
}while( iFreePage>finSize );
|
|
releasePage(pFreeMemPage);
|
|
pFreeMemPage = 0;
|
|
|
|
/* Relocate the page into the body of the file. Note that although the
|
|
** page has moved within the database file, the pDbMemPage pointer
|
|
** remains valid. This means that this function can run without
|
|
** invalidating cursors open on the btree. This is important in
|
|
** shared-cache mode.
|
|
*/
|
|
rc = relocatePage(pBt, pDbMemPage, eType, iPtrPage, iFreePage);
|
|
releasePage(pDbMemPage);
|
|
if( rc!=SQLITE_OK ) goto autovacuum_out;
|
|
}
|
|
|
|
/* The entire free-list has been swapped to the end of the file. So
|
|
** truncate the database file to finSize pages and consider the
|
|
** free-list empty.
|
|
*/
|
|
rc = sqlite3pager_write(pBt->pPage1->aData);
|
|
if( rc!=SQLITE_OK ) goto autovacuum_out;
|
|
put4byte(&pBt->pPage1->aData[32], 0);
|
|
put4byte(&pBt->pPage1->aData[36], 0);
|
|
*nTrunc = finSize;
|
|
assert( finSize!=PENDING_BYTE_PAGE(pBt) );
|
|
|
|
autovacuum_out:
|
|
assert( nRef==*sqlite3pager_stats(pPager) );
|
|
if( rc!=SQLITE_OK ){
|
|
sqlite3pager_rollback(pPager);
|
|
}
|
|
return rc;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** Commit the transaction currently in progress.
|
|
**
|
|
** This will release the write lock on the database file. If there
|
|
** are no active cursors, it also releases the read lock.
|
|
*/
|
|
int sqlite3BtreeCommit(Btree *p){
|
|
BtShared *pBt = p->pBt;
|
|
|
|
btreeIntegrity(p);
|
|
|
|
/* If the handle has a write-transaction open, commit the shared-btrees
|
|
** transaction and set the shared state to TRANS_READ.
|
|
*/
|
|
if( p->inTrans==TRANS_WRITE ){
|
|
int rc;
|
|
assert( pBt->inTransaction==TRANS_WRITE );
|
|
assert( pBt->nTransaction>0 );
|
|
rc = sqlite3pager_commit(pBt->pPager);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
pBt->inTransaction = TRANS_READ;
|
|
pBt->inStmt = 0;
|
|
}
|
|
unlockAllTables(p);
|
|
|
|
/* If the handle has any kind of transaction open, decrement the transaction
|
|
** count of the shared btree. If the transaction count reaches 0, set
|
|
** the shared state to TRANS_NONE. The unlockBtreeIfUnused() call below
|
|
** will unlock the pager.
|
|
*/
|
|
if( p->inTrans!=TRANS_NONE ){
|
|
pBt->nTransaction--;
|
|
if( 0==pBt->nTransaction ){
|
|
pBt->inTransaction = TRANS_NONE;
|
|
}
|
|
}
|
|
|
|
/* Set the handles current transaction state to TRANS_NONE and unlock
|
|
** the pager if this call closed the only read or write transaction.
|
|
*/
|
|
p->inTrans = TRANS_NONE;
|
|
unlockBtreeIfUnused(pBt);
|
|
|
|
btreeIntegrity(p);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
#ifndef NDEBUG
|
|
/*
|
|
** Return the number of write-cursors open on this handle. This is for use
|
|
** in assert() expressions, so it is only compiled if NDEBUG is not
|
|
** defined.
|
|
*/
|
|
static int countWriteCursors(BtShared *pBt){
|
|
BtCursor *pCur;
|
|
int r = 0;
|
|
for(pCur=pBt->pCursor; pCur; pCur=pCur->pNext){
|
|
if( pCur->wrFlag ) r++;
|
|
}
|
|
return r;
|
|
}
|
|
#endif
|
|
|
|
#if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
|
|
/*
|
|
** Print debugging information about all cursors to standard output.
|
|
*/
|
|
void sqlite3BtreeCursorList(Btree *p){
|
|
BtCursor *pCur;
|
|
BtShared *pBt = p->pBt;
|
|
for(pCur=pBt->pCursor; pCur; pCur=pCur->pNext){
|
|
MemPage *pPage = pCur->pPage;
|
|
char *zMode = pCur->wrFlag ? "rw" : "ro";
|
|
sqlite3DebugPrintf("CURSOR %p rooted at %4d(%s) currently at %d.%d%s\n",
|
|
pCur, pCur->pgnoRoot, zMode,
|
|
pPage ? pPage->pgno : 0, pCur->idx,
|
|
(pCur->eState==CURSOR_VALID) ? "" : " eof"
|
|
);
|
|
}
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** Rollback the transaction in progress. All cursors will be
|
|
** invalided by this operation. Any attempt to use a cursor
|
|
** that was open at the beginning of this operation will result
|
|
** in an error.
|
|
**
|
|
** This will release the write lock on the database file. If there
|
|
** are no active cursors, it also releases the read lock.
|
|
*/
|
|
int sqlite3BtreeRollback(Btree *p){
|
|
int rc;
|
|
BtShared *pBt = p->pBt;
|
|
MemPage *pPage1;
|
|
|
|
rc = saveAllCursors(pBt, 0, 0);
|
|
#ifndef SQLITE_OMIT_SHARED_CACHE
|
|
if( rc!=SQLITE_OK ){
|
|
/* This is a horrible situation. An IO or malloc() error occured whilst
|
|
** trying to save cursor positions. If this is an automatic rollback (as
|
|
** the result of a constraint, malloc() failure or IO error) then
|
|
** the cache may be internally inconsistent (not contain valid trees) so
|
|
** we cannot simply return the error to the caller. Instead, abort
|
|
** all queries that may be using any of the cursors that failed to save.
|
|
*/
|
|
while( pBt->pCursor ){
|
|
sqlite3 *db = pBt->pCursor->pBtree->pSqlite;
|
|
if( db ){
|
|
sqlite3AbortOtherActiveVdbes(db, 0);
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
btreeIntegrity(p);
|
|
unlockAllTables(p);
|
|
|
|
if( p->inTrans==TRANS_WRITE ){
|
|
int rc2;
|
|
|
|
assert( TRANS_WRITE==pBt->inTransaction );
|
|
rc2 = sqlite3pager_rollback(pBt->pPager);
|
|
if( rc2!=SQLITE_OK ){
|
|
rc = rc2;
|
|
}
|
|
|
|
/* The rollback may have destroyed the pPage1->aData value. So
|
|
** call getPage() on page 1 again to make sure pPage1->aData is
|
|
** set correctly. */
|
|
if( getPage(pBt, 1, &pPage1)==SQLITE_OK ){
|
|
releasePage(pPage1);
|
|
}
|
|
assert( countWriteCursors(pBt)==0 );
|
|
pBt->inTransaction = TRANS_READ;
|
|
}
|
|
|
|
if( p->inTrans!=TRANS_NONE ){
|
|
assert( pBt->nTransaction>0 );
|
|
pBt->nTransaction--;
|
|
if( 0==pBt->nTransaction ){
|
|
pBt->inTransaction = TRANS_NONE;
|
|
}
|
|
}
|
|
|
|
p->inTrans = TRANS_NONE;
|
|
pBt->inStmt = 0;
|
|
unlockBtreeIfUnused(pBt);
|
|
|
|
btreeIntegrity(p);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Start a statement subtransaction. The subtransaction can
|
|
** can be rolled back independently of the main transaction.
|
|
** You must start a transaction before starting a subtransaction.
|
|
** The subtransaction is ended automatically if the main transaction
|
|
** commits or rolls back.
|
|
**
|
|
** Only one subtransaction may be active at a time. It is an error to try
|
|
** to start a new subtransaction if another subtransaction is already active.
|
|
**
|
|
** Statement subtransactions are used around individual SQL statements
|
|
** that are contained within a BEGIN...COMMIT block. If a constraint
|
|
** error occurs within the statement, the effect of that one statement
|
|
** can be rolled back without having to rollback the entire transaction.
|
|
*/
|
|
int sqlite3BtreeBeginStmt(Btree *p){
|
|
int rc;
|
|
BtShared *pBt = p->pBt;
|
|
if( (p->inTrans!=TRANS_WRITE) || pBt->inStmt ){
|
|
return pBt->readOnly ? SQLITE_READONLY : SQLITE_ERROR;
|
|
}
|
|
assert( pBt->inTransaction==TRANS_WRITE );
|
|
rc = pBt->readOnly ? SQLITE_OK : sqlite3pager_stmt_begin(pBt->pPager);
|
|
pBt->inStmt = 1;
|
|
return rc;
|
|
}
|
|
|
|
|
|
/*
|
|
** Commit the statment subtransaction currently in progress. If no
|
|
** subtransaction is active, this is a no-op.
|
|
*/
|
|
int sqlite3BtreeCommitStmt(Btree *p){
|
|
int rc;
|
|
BtShared *pBt = p->pBt;
|
|
if( pBt->inStmt && !pBt->readOnly ){
|
|
rc = sqlite3pager_stmt_commit(pBt->pPager);
|
|
}else{
|
|
rc = SQLITE_OK;
|
|
}
|
|
pBt->inStmt = 0;
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Rollback the active statement subtransaction. If no subtransaction
|
|
** is active this routine is a no-op.
|
|
**
|
|
** All cursors will be invalidated by this operation. Any attempt
|
|
** to use a cursor that was open at the beginning of this operation
|
|
** will result in an error.
|
|
*/
|
|
int sqlite3BtreeRollbackStmt(Btree *p){
|
|
int rc = SQLITE_OK;
|
|
BtShared *pBt = p->pBt;
|
|
sqlite3MallocDisallow();
|
|
if( pBt->inStmt && !pBt->readOnly ){
|
|
rc = sqlite3pager_stmt_rollback(pBt->pPager);
|
|
assert( countWriteCursors(pBt)==0 );
|
|
pBt->inStmt = 0;
|
|
}
|
|
sqlite3MallocAllow();
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Default key comparison function to be used if no comparison function
|
|
** is specified on the sqlite3BtreeCursor() call.
|
|
*/
|
|
static int dfltCompare(
|
|
void *NotUsed, /* User data is not used */
|
|
int n1, const void *p1, /* First key to compare */
|
|
int n2, const void *p2 /* Second key to compare */
|
|
){
|
|
int c;
|
|
c = memcmp(p1, p2, n1<n2 ? n1 : n2);
|
|
if( c==0 ){
|
|
c = n1 - n2;
|
|
}
|
|
return c;
|
|
}
|
|
|
|
/*
|
|
** Create a new cursor for the BTree whose root is on the page
|
|
** iTable. The act of acquiring a cursor gets a read lock on
|
|
** the database file.
|
|
**
|
|
** If wrFlag==0, then the cursor can only be used for reading.
|
|
** If wrFlag==1, then the cursor can be used for reading or for
|
|
** writing if other conditions for writing are also met. These
|
|
** are the conditions that must be met in order for writing to
|
|
** be allowed:
|
|
**
|
|
** 1: The cursor must have been opened with wrFlag==1
|
|
**
|
|
** 2: No other cursors may be open with wrFlag==0 on the same table
|
|
**
|
|
** 3: The database must be writable (not on read-only media)
|
|
**
|
|
** 4: There must be an active transaction.
|
|
**
|
|
** Condition 2 warrants further discussion. If any cursor is opened
|
|
** on a table with wrFlag==0, that prevents all other cursors from
|
|
** writing to that table. This is a kind of "read-lock". When a cursor
|
|
** is opened with wrFlag==0 it is guaranteed that the table will not
|
|
** change as long as the cursor is open. This allows the cursor to
|
|
** do a sequential scan of the table without having to worry about
|
|
** entries being inserted or deleted during the scan. Cursors should
|
|
** be opened with wrFlag==0 only if this read-lock property is needed.
|
|
** That is to say, cursors should be opened with wrFlag==0 only if they
|
|
** intend to use the sqlite3BtreeNext() system call. All other cursors
|
|
** should be opened with wrFlag==1 even if they never really intend
|
|
** to write.
|
|
**
|
|
** No checking is done to make sure that page iTable really is the
|
|
** root page of a b-tree. If it is not, then the cursor acquired
|
|
** will not work correctly.
|
|
**
|
|
** The comparison function must be logically the same for every cursor
|
|
** on a particular table. Changing the comparison function will result
|
|
** in incorrect operations. If the comparison function is NULL, a
|
|
** default comparison function is used. The comparison function is
|
|
** always ignored for INTKEY tables.
|
|
*/
|
|
int sqlite3BtreeCursor(
|
|
Btree *p, /* The btree */
|
|
int iTable, /* Root page of table to open */
|
|
int wrFlag, /* 1 to write. 0 read-only */
|
|
int (*xCmp)(void*,int,const void*,int,const void*), /* Key Comparison func */
|
|
void *pArg, /* First arg to xCompare() */
|
|
BtCursor **ppCur /* Write new cursor here */
|
|
){
|
|
int rc;
|
|
BtCursor *pCur;
|
|
BtShared *pBt = p->pBt;
|
|
|
|
*ppCur = 0;
|
|
if( wrFlag ){
|
|
if( pBt->readOnly ){
|
|
return SQLITE_READONLY;
|
|
}
|
|
if( checkReadLocks(pBt, iTable, 0) ){
|
|
return SQLITE_LOCKED;
|
|
}
|
|
}
|
|
|
|
if( pBt->pPage1==0 ){
|
|
rc = lockBtreeWithRetry(p);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
}
|
|
pCur = sqliteMalloc( sizeof(*pCur) );
|
|
if( pCur==0 ){
|
|
rc = SQLITE_NOMEM;
|
|
goto create_cursor_exception;
|
|
}
|
|
pCur->pgnoRoot = (Pgno)iTable;
|
|
if( iTable==1 && sqlite3pager_pagecount(pBt->pPager)==0 ){
|
|
rc = SQLITE_EMPTY;
|
|
goto create_cursor_exception;
|
|
}
|
|
rc = getAndInitPage(pBt, pCur->pgnoRoot, &pCur->pPage, 0);
|
|
if( rc!=SQLITE_OK ){
|
|
goto create_cursor_exception;
|
|
}
|
|
|
|
/* Now that no other errors can occur, finish filling in the BtCursor
|
|
** variables, link the cursor into the BtShared list and set *ppCur (the
|
|
** output argument to this function).
|
|
*/
|
|
pCur->xCompare = xCmp ? xCmp : dfltCompare;
|
|
pCur->pArg = pArg;
|
|
pCur->pBtree = p;
|
|
pCur->wrFlag = wrFlag;
|
|
pCur->pNext = pBt->pCursor;
|
|
if( pCur->pNext ){
|
|
pCur->pNext->pPrev = pCur;
|
|
}
|
|
pBt->pCursor = pCur;
|
|
pCur->eState = CURSOR_INVALID;
|
|
*ppCur = pCur;
|
|
|
|
return SQLITE_OK;
|
|
create_cursor_exception:
|
|
if( pCur ){
|
|
releasePage(pCur->pPage);
|
|
sqliteFree(pCur);
|
|
}
|
|
unlockBtreeIfUnused(pBt);
|
|
return rc;
|
|
}
|
|
|
|
#if 0 /* Not Used */
|
|
/*
|
|
** Change the value of the comparison function used by a cursor.
|
|
*/
|
|
void sqlite3BtreeSetCompare(
|
|
BtCursor *pCur, /* The cursor to whose comparison function is changed */
|
|
int(*xCmp)(void*,int,const void*,int,const void*), /* New comparison func */
|
|
void *pArg /* First argument to xCmp() */
|
|
){
|
|
pCur->xCompare = xCmp ? xCmp : dfltCompare;
|
|
pCur->pArg = pArg;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** Close a cursor. The read lock on the database file is released
|
|
** when the last cursor is closed.
|
|
*/
|
|
int sqlite3BtreeCloseCursor(BtCursor *pCur){
|
|
BtShared *pBt = pCur->pBtree->pBt;
|
|
restoreOrClearCursorPosition(pCur, 0);
|
|
if( pCur->pPrev ){
|
|
pCur->pPrev->pNext = pCur->pNext;
|
|
}else{
|
|
pBt->pCursor = pCur->pNext;
|
|
}
|
|
if( pCur->pNext ){
|
|
pCur->pNext->pPrev = pCur->pPrev;
|
|
}
|
|
releasePage(pCur->pPage);
|
|
unlockBtreeIfUnused(pBt);
|
|
sqliteFree(pCur);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Make a temporary cursor by filling in the fields of pTempCur.
|
|
** The temporary cursor is not on the cursor list for the Btree.
|
|
*/
|
|
static void getTempCursor(BtCursor *pCur, BtCursor *pTempCur){
|
|
memcpy(pTempCur, pCur, sizeof(*pCur));
|
|
pTempCur->pNext = 0;
|
|
pTempCur->pPrev = 0;
|
|
if( pTempCur->pPage ){
|
|
sqlite3pager_ref(pTempCur->pPage->aData);
|
|
}
|
|
}
|
|
|
|
/*
|
|
** Delete a temporary cursor such as was made by the CreateTemporaryCursor()
|
|
** function above.
|
|
*/
|
|
static void releaseTempCursor(BtCursor *pCur){
|
|
if( pCur->pPage ){
|
|
sqlite3pager_unref(pCur->pPage->aData);
|
|
}
|
|
}
|
|
|
|
/*
|
|
** Make sure the BtCursor.info field of the given cursor is valid.
|
|
** If it is not already valid, call parseCell() to fill it in.
|
|
**
|
|
** BtCursor.info is a cache of the information in the current cell.
|
|
** Using this cache reduces the number of calls to parseCell().
|
|
*/
|
|
static void getCellInfo(BtCursor *pCur){
|
|
if( pCur->info.nSize==0 ){
|
|
parseCell(pCur->pPage, pCur->idx, &pCur->info);
|
|
}else{
|
|
#ifndef NDEBUG
|
|
CellInfo info;
|
|
memset(&info, 0, sizeof(info));
|
|
parseCell(pCur->pPage, pCur->idx, &info);
|
|
assert( memcmp(&info, &pCur->info, sizeof(info))==0 );
|
|
#endif
|
|
}
|
|
}
|
|
|
|
/*
|
|
** Set *pSize to the size of the buffer needed to hold the value of
|
|
** the key for the current entry. If the cursor is not pointing
|
|
** to a valid entry, *pSize is set to 0.
|
|
**
|
|
** For a table with the INTKEY flag set, this routine returns the key
|
|
** itself, not the number of bytes in the key.
|
|
*/
|
|
int sqlite3BtreeKeySize(BtCursor *pCur, i64 *pSize){
|
|
int rc = restoreOrClearCursorPosition(pCur, 1);
|
|
if( rc==SQLITE_OK ){
|
|
assert( pCur->eState==CURSOR_INVALID || pCur->eState==CURSOR_VALID );
|
|
if( pCur->eState==CURSOR_INVALID ){
|
|
*pSize = 0;
|
|
}else{
|
|
getCellInfo(pCur);
|
|
*pSize = pCur->info.nKey;
|
|
}
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Set *pSize to the number of bytes of data in the entry the
|
|
** cursor currently points to. Always return SQLITE_OK.
|
|
** Failure is not possible. If the cursor is not currently
|
|
** pointing to an entry (which can happen, for example, if
|
|
** the database is empty) then *pSize is set to 0.
|
|
*/
|
|
int sqlite3BtreeDataSize(BtCursor *pCur, u32 *pSize){
|
|
int rc = restoreOrClearCursorPosition(pCur, 1);
|
|
if( rc==SQLITE_OK ){
|
|
assert( pCur->eState==CURSOR_INVALID || pCur->eState==CURSOR_VALID );
|
|
if( pCur->eState==CURSOR_INVALID ){
|
|
/* Not pointing at a valid entry - set *pSize to 0. */
|
|
*pSize = 0;
|
|
}else{
|
|
getCellInfo(pCur);
|
|
*pSize = pCur->info.nData;
|
|
}
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Read payload information from the entry that the pCur cursor is
|
|
** pointing to. Begin reading the payload at "offset" and read
|
|
** a total of "amt" bytes. Put the result in zBuf.
|
|
**
|
|
** This routine does not make a distinction between key and data.
|
|
** It just reads bytes from the payload area. Data might appear
|
|
** on the main page or be scattered out on multiple overflow pages.
|
|
*/
|
|
static int getPayload(
|
|
BtCursor *pCur, /* Cursor pointing to entry to read from */
|
|
int offset, /* Begin reading this far into payload */
|
|
int amt, /* Read this many bytes */
|
|
unsigned char *pBuf, /* Write the bytes into this buffer */
|
|
int skipKey /* offset begins at data if this is true */
|
|
){
|
|
unsigned char *aPayload;
|
|
Pgno nextPage;
|
|
int rc;
|
|
MemPage *pPage;
|
|
BtShared *pBt;
|
|
int ovflSize;
|
|
u32 nKey;
|
|
|
|
assert( pCur!=0 && pCur->pPage!=0 );
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
pBt = pCur->pBtree->pBt;
|
|
pPage = pCur->pPage;
|
|
pageIntegrity(pPage);
|
|
assert( pCur->idx>=0 && pCur->idx<pPage->nCell );
|
|
getCellInfo(pCur);
|
|
aPayload = pCur->info.pCell + pCur->info.nHeader;
|
|
if( pPage->intKey ){
|
|
nKey = 0;
|
|
}else{
|
|
nKey = (u32)pCur->info.nKey;
|
|
}
|
|
assert( offset>=0 );
|
|
if( skipKey ){
|
|
offset += nKey;
|
|
}
|
|
if( (u32)(offset+amt) > nKey+pCur->info.nData ){
|
|
return SQLITE_ERROR;
|
|
}
|
|
if( offset<pCur->info.nLocal ){
|
|
int a = amt;
|
|
if( a+offset>pCur->info.nLocal ){
|
|
a = pCur->info.nLocal - offset;
|
|
}
|
|
memcpy(pBuf, &aPayload[offset], a);
|
|
if( a==amt ){
|
|
return SQLITE_OK;
|
|
}
|
|
offset = 0;
|
|
pBuf += a;
|
|
amt -= a;
|
|
}else{
|
|
offset -= pCur->info.nLocal;
|
|
}
|
|
ovflSize = pBt->usableSize - 4;
|
|
if( amt>0 ){
|
|
nextPage = get4byte(&aPayload[pCur->info.nLocal]);
|
|
while( amt>0 && nextPage ){
|
|
rc = sqlite3pager_get(pBt->pPager, nextPage, (void**)&aPayload);
|
|
if( rc!=0 ){
|
|
return rc;
|
|
}
|
|
nextPage = get4byte(aPayload);
|
|
if( offset<ovflSize ){
|
|
int a = amt;
|
|
if( a + offset > ovflSize ){
|
|
a = ovflSize - offset;
|
|
}
|
|
memcpy(pBuf, &aPayload[offset+4], a);
|
|
offset = 0;
|
|
amt -= a;
|
|
pBuf += a;
|
|
}else{
|
|
offset -= ovflSize;
|
|
}
|
|
sqlite3pager_unref(aPayload);
|
|
}
|
|
}
|
|
|
|
if( amt>0 ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Read part of the key associated with cursor pCur. Exactly
|
|
** "amt" bytes will be transfered into pBuf[]. The transfer
|
|
** begins at "offset".
|
|
**
|
|
** Return SQLITE_OK on success or an error code if anything goes
|
|
** wrong. An error is returned if "offset+amt" is larger than
|
|
** the available payload.
|
|
*/
|
|
int sqlite3BtreeKey(BtCursor *pCur, u32 offset, u32 amt, void *pBuf){
|
|
int rc = restoreOrClearCursorPosition(pCur, 1);
|
|
if( rc==SQLITE_OK ){
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
assert( pCur->pPage!=0 );
|
|
if( pCur->pPage->intKey ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
assert( pCur->pPage->intKey==0 );
|
|
assert( pCur->idx>=0 && pCur->idx<pCur->pPage->nCell );
|
|
rc = getPayload(pCur, offset, amt, (unsigned char*)pBuf, 0);
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Read part of the data associated with cursor pCur. Exactly
|
|
** "amt" bytes will be transfered into pBuf[]. The transfer
|
|
** begins at "offset".
|
|
**
|
|
** Return SQLITE_OK on success or an error code if anything goes
|
|
** wrong. An error is returned if "offset+amt" is larger than
|
|
** the available payload.
|
|
*/
|
|
int sqlite3BtreeData(BtCursor *pCur, u32 offset, u32 amt, void *pBuf){
|
|
int rc = restoreOrClearCursorPosition(pCur, 1);
|
|
if( rc==SQLITE_OK ){
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
assert( pCur->pPage!=0 );
|
|
assert( pCur->idx>=0 && pCur->idx<pCur->pPage->nCell );
|
|
rc = getPayload(pCur, offset, amt, pBuf, 1);
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Return a pointer to payload information from the entry that the
|
|
** pCur cursor is pointing to. The pointer is to the beginning of
|
|
** the key if skipKey==0 and it points to the beginning of data if
|
|
** skipKey==1. The number of bytes of available key/data is written
|
|
** into *pAmt. If *pAmt==0, then the value returned will not be
|
|
** a valid pointer.
|
|
**
|
|
** This routine is an optimization. It is common for the entire key
|
|
** and data to fit on the local page and for there to be no overflow
|
|
** pages. When that is so, this routine can be used to access the
|
|
** key and data without making a copy. If the key and/or data spills
|
|
** onto overflow pages, then getPayload() must be used to reassembly
|
|
** the key/data and copy it into a preallocated buffer.
|
|
**
|
|
** The pointer returned by this routine looks directly into the cached
|
|
** page of the database. The data might change or move the next time
|
|
** any btree routine is called.
|
|
*/
|
|
static const unsigned char *fetchPayload(
|
|
BtCursor *pCur, /* Cursor pointing to entry to read from */
|
|
int *pAmt, /* Write the number of available bytes here */
|
|
int skipKey /* read beginning at data if this is true */
|
|
){
|
|
unsigned char *aPayload;
|
|
MemPage *pPage;
|
|
u32 nKey;
|
|
int nLocal;
|
|
|
|
assert( pCur!=0 && pCur->pPage!=0 );
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
pPage = pCur->pPage;
|
|
pageIntegrity(pPage);
|
|
assert( pCur->idx>=0 && pCur->idx<pPage->nCell );
|
|
getCellInfo(pCur);
|
|
aPayload = pCur->info.pCell;
|
|
aPayload += pCur->info.nHeader;
|
|
if( pPage->intKey ){
|
|
nKey = 0;
|
|
}else{
|
|
nKey = (u32)pCur->info.nKey;
|
|
}
|
|
if( skipKey ){
|
|
aPayload += nKey;
|
|
nLocal = pCur->info.nLocal - nKey;
|
|
}else{
|
|
nLocal = pCur->info.nLocal;
|
|
if( (u32)nLocal>nKey ){
|
|
nLocal = nKey;
|
|
}
|
|
}
|
|
*pAmt = nLocal;
|
|
return aPayload;
|
|
}
|
|
|
|
|
|
/*
|
|
** For the entry that cursor pCur is point to, return as
|
|
** many bytes of the key or data as are available on the local
|
|
** b-tree page. Write the number of available bytes into *pAmt.
|
|
**
|
|
** The pointer returned is ephemeral. The key/data may move
|
|
** or be destroyed on the next call to any Btree routine.
|
|
**
|
|
** These routines is used to get quick access to key and data
|
|
** in the common case where no overflow pages are used.
|
|
*/
|
|
const void *sqlite3BtreeKeyFetch(BtCursor *pCur, int *pAmt){
|
|
if( pCur->eState==CURSOR_VALID ){
|
|
return (const void*)fetchPayload(pCur, pAmt, 0);
|
|
}
|
|
return 0;
|
|
}
|
|
const void *sqlite3BtreeDataFetch(BtCursor *pCur, int *pAmt){
|
|
if( pCur->eState==CURSOR_VALID ){
|
|
return (const void*)fetchPayload(pCur, pAmt, 1);
|
|
}
|
|
return 0;
|
|
}
|
|
|
|
|
|
/*
|
|
** Move the cursor down to a new child page. The newPgno argument is the
|
|
** page number of the child page to move to.
|
|
*/
|
|
static int moveToChild(BtCursor *pCur, u32 newPgno){
|
|
int rc;
|
|
MemPage *pNewPage;
|
|
MemPage *pOldPage;
|
|
BtShared *pBt = pCur->pBtree->pBt;
|
|
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
rc = getAndInitPage(pBt, newPgno, &pNewPage, pCur->pPage);
|
|
if( rc ) return rc;
|
|
pageIntegrity(pNewPage);
|
|
pNewPage->idxParent = pCur->idx;
|
|
pOldPage = pCur->pPage;
|
|
pOldPage->idxShift = 0;
|
|
releasePage(pOldPage);
|
|
pCur->pPage = pNewPage;
|
|
pCur->idx = 0;
|
|
pCur->info.nSize = 0;
|
|
if( pNewPage->nCell<1 ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Return true if the page is the virtual root of its table.
|
|
**
|
|
** The virtual root page is the root page for most tables. But
|
|
** for the table rooted on page 1, sometime the real root page
|
|
** is empty except for the right-pointer. In such cases the
|
|
** virtual root page is the page that the right-pointer of page
|
|
** 1 is pointing to.
|
|
*/
|
|
static int isRootPage(MemPage *pPage){
|
|
MemPage *pParent = pPage->pParent;
|
|
if( pParent==0 ) return 1;
|
|
if( pParent->pgno>1 ) return 0;
|
|
if( get2byte(&pParent->aData[pParent->hdrOffset+3])==0 ) return 1;
|
|
return 0;
|
|
}
|
|
|
|
/*
|
|
** Move the cursor up to the parent page.
|
|
**
|
|
** pCur->idx is set to the cell index that contains the pointer
|
|
** to the page we are coming from. If we are coming from the
|
|
** right-most child page then pCur->idx is set to one more than
|
|
** the largest cell index.
|
|
*/
|
|
static void moveToParent(BtCursor *pCur){
|
|
MemPage *pParent;
|
|
MemPage *pPage;
|
|
int idxParent;
|
|
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
pPage = pCur->pPage;
|
|
assert( pPage!=0 );
|
|
assert( !isRootPage(pPage) );
|
|
pageIntegrity(pPage);
|
|
pParent = pPage->pParent;
|
|
assert( pParent!=0 );
|
|
pageIntegrity(pParent);
|
|
idxParent = pPage->idxParent;
|
|
sqlite3pager_ref(pParent->aData);
|
|
releasePage(pPage);
|
|
pCur->pPage = pParent;
|
|
pCur->info.nSize = 0;
|
|
assert( pParent->idxShift==0 );
|
|
pCur->idx = idxParent;
|
|
}
|
|
|
|
/*
|
|
** Move the cursor to the root page
|
|
*/
|
|
static int moveToRoot(BtCursor *pCur){
|
|
MemPage *pRoot;
|
|
int rc = SQLITE_OK;
|
|
BtShared *pBt = pCur->pBtree->pBt;
|
|
|
|
restoreOrClearCursorPosition(pCur, 0);
|
|
pRoot = pCur->pPage;
|
|
if( pRoot && pRoot->pgno==pCur->pgnoRoot ){
|
|
assert( pRoot->isInit );
|
|
}else{
|
|
if(
|
|
SQLITE_OK!=(rc = getAndInitPage(pBt, pCur->pgnoRoot, &pRoot, 0))
|
|
){
|
|
pCur->eState = CURSOR_INVALID;
|
|
return rc;
|
|
}
|
|
releasePage(pCur->pPage);
|
|
pageIntegrity(pRoot);
|
|
pCur->pPage = pRoot;
|
|
}
|
|
pCur->idx = 0;
|
|
pCur->info.nSize = 0;
|
|
if( pRoot->nCell==0 && !pRoot->leaf ){
|
|
Pgno subpage;
|
|
assert( pRoot->pgno==1 );
|
|
subpage = get4byte(&pRoot->aData[pRoot->hdrOffset+8]);
|
|
assert( subpage>0 );
|
|
pCur->eState = CURSOR_VALID;
|
|
rc = moveToChild(pCur, subpage);
|
|
}
|
|
pCur->eState = ((pCur->pPage->nCell>0)?CURSOR_VALID:CURSOR_INVALID);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Move the cursor down to the left-most leaf entry beneath the
|
|
** entry to which it is currently pointing.
|
|
**
|
|
** The left-most leaf is the one with the smallest key - the first
|
|
** in ascending order.
|
|
*/
|
|
static int moveToLeftmost(BtCursor *pCur){
|
|
Pgno pgno;
|
|
int rc;
|
|
MemPage *pPage;
|
|
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
while( !(pPage = pCur->pPage)->leaf ){
|
|
assert( pCur->idx>=0 && pCur->idx<pPage->nCell );
|
|
pgno = get4byte(findCell(pPage, pCur->idx));
|
|
rc = moveToChild(pCur, pgno);
|
|
if( rc ) return rc;
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Move the cursor down to the right-most leaf entry beneath the
|
|
** page to which it is currently pointing. Notice the difference
|
|
** between moveToLeftmost() and moveToRightmost(). moveToLeftmost()
|
|
** finds the left-most entry beneath the *entry* whereas moveToRightmost()
|
|
** finds the right-most entry beneath the *page*.
|
|
**
|
|
** The right-most entry is the one with the largest key - the last
|
|
** key in ascending order.
|
|
*/
|
|
static int moveToRightmost(BtCursor *pCur){
|
|
Pgno pgno;
|
|
int rc;
|
|
MemPage *pPage;
|
|
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
while( !(pPage = pCur->pPage)->leaf ){
|
|
pgno = get4byte(&pPage->aData[pPage->hdrOffset+8]);
|
|
pCur->idx = pPage->nCell;
|
|
rc = moveToChild(pCur, pgno);
|
|
if( rc ) return rc;
|
|
}
|
|
pCur->idx = pPage->nCell - 1;
|
|
pCur->info.nSize = 0;
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/* Move the cursor to the first entry in the table. Return SQLITE_OK
|
|
** on success. Set *pRes to 0 if the cursor actually points to something
|
|
** or set *pRes to 1 if the table is empty.
|
|
*/
|
|
int sqlite3BtreeFirst(BtCursor *pCur, int *pRes){
|
|
int rc;
|
|
rc = moveToRoot(pCur);
|
|
if( rc ) return rc;
|
|
if( pCur->eState==CURSOR_INVALID ){
|
|
assert( pCur->pPage->nCell==0 );
|
|
*pRes = 1;
|
|
return SQLITE_OK;
|
|
}
|
|
assert( pCur->pPage->nCell>0 );
|
|
*pRes = 0;
|
|
rc = moveToLeftmost(pCur);
|
|
return rc;
|
|
}
|
|
|
|
/* Move the cursor to the last entry in the table. Return SQLITE_OK
|
|
** on success. Set *pRes to 0 if the cursor actually points to something
|
|
** or set *pRes to 1 if the table is empty.
|
|
*/
|
|
int sqlite3BtreeLast(BtCursor *pCur, int *pRes){
|
|
int rc;
|
|
rc = moveToRoot(pCur);
|
|
if( rc ) return rc;
|
|
if( CURSOR_INVALID==pCur->eState ){
|
|
assert( pCur->pPage->nCell==0 );
|
|
*pRes = 1;
|
|
return SQLITE_OK;
|
|
}
|
|
assert( pCur->eState==CURSOR_VALID );
|
|
*pRes = 0;
|
|
rc = moveToRightmost(pCur);
|
|
return rc;
|
|
}
|
|
|
|
/* Move the cursor so that it points to an entry near pKey/nKey.
|
|
** Return a success code.
|
|
**
|
|
** For INTKEY tables, only the nKey parameter is used. pKey is
|
|
** ignored. For other tables, nKey is the number of bytes of data
|
|
** in pKey. The comparison function specified when the cursor was
|
|
** created is used to compare keys.
|
|
**
|
|
** If an exact match is not found, then the cursor is always
|
|
** left pointing at a leaf page which would hold the entry if it
|
|
** were present. The cursor might point to an entry that comes
|
|
** before or after the key.
|
|
**
|
|
** The result of comparing the key with the entry to which the
|
|
** cursor is written to *pRes if pRes!=NULL. The meaning of
|
|
** this value is as follows:
|
|
**
|
|
** *pRes<0 The cursor is left pointing at an entry that
|
|
** is smaller than pKey or if the table is empty
|
|
** and the cursor is therefore left point to nothing.
|
|
**
|
|
** *pRes==0 The cursor is left pointing at an entry that
|
|
** exactly matches pKey.
|
|
**
|
|
** *pRes>0 The cursor is left pointing at an entry that
|
|
** is larger than pKey.
|
|
*/
|
|
int sqlite3BtreeMoveto(BtCursor *pCur, const void *pKey, i64 nKey, int *pRes){
|
|
int rc;
|
|
int tryRightmost;
|
|
rc = moveToRoot(pCur);
|
|
if( rc ) return rc;
|
|
assert( pCur->pPage );
|
|
assert( pCur->pPage->isInit );
|
|
tryRightmost = pCur->pPage->intKey;
|
|
if( pCur->eState==CURSOR_INVALID ){
|
|
*pRes = -1;
|
|
assert( pCur->pPage->nCell==0 );
|
|
return SQLITE_OK;
|
|
}
|
|
for(;;){
|
|
int lwr, upr;
|
|
Pgno chldPg;
|
|
MemPage *pPage = pCur->pPage;
|
|
int c = -1; /* pRes return if table is empty must be -1 */
|
|
lwr = 0;
|
|
upr = pPage->nCell-1;
|
|
if( !pPage->intKey && pKey==0 ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
pageIntegrity(pPage);
|
|
while( lwr<=upr ){
|
|
void *pCellKey;
|
|
i64 nCellKey;
|
|
pCur->idx = (lwr+upr)/2;
|
|
pCur->info.nSize = 0;
|
|
if( pPage->intKey ){
|
|
u8 *pCell;
|
|
if( tryRightmost ){
|
|
pCur->idx = upr;
|
|
}
|
|
pCell = findCell(pPage, pCur->idx) + pPage->childPtrSize;
|
|
if( pPage->hasData ){
|
|
u32 dummy;
|
|
pCell += getVarint32(pCell, &dummy);
|
|
}
|
|
getVarint(pCell, (u64 *)&nCellKey);
|
|
if( nCellKey<nKey ){
|
|
c = -1;
|
|
}else if( nCellKey>nKey ){
|
|
c = +1;
|
|
tryRightmost = 0;
|
|
}else{
|
|
c = 0;
|
|
}
|
|
}else{
|
|
int available;
|
|
pCellKey = (void *)fetchPayload(pCur, &available, 0);
|
|
nCellKey = pCur->info.nKey;
|
|
if( available>=nCellKey ){
|
|
c = pCur->xCompare(pCur->pArg, (int)nCellKey, pCellKey, (int)nKey, pKey);
|
|
}else{
|
|
pCellKey = sqliteMallocRaw( (int)nCellKey );
|
|
if( pCellKey==0 ) return SQLITE_NOMEM;
|
|
rc = sqlite3BtreeKey(pCur, 0, (u32)nCellKey, (void *)pCellKey);
|
|
c = pCur->xCompare(pCur->pArg, (int)nCellKey, pCellKey, (int)nKey, pKey);
|
|
sqliteFree(pCellKey);
|
|
if( rc ) return rc;
|
|
}
|
|
}
|
|
if( c==0 ){
|
|
if( pPage->leafData && !pPage->leaf ){
|
|
lwr = pCur->idx;
|
|
upr = lwr - 1;
|
|
break;
|
|
}else{
|
|
if( pRes ) *pRes = 0;
|
|
return SQLITE_OK;
|
|
}
|
|
}
|
|
if( c<0 ){
|
|
lwr = pCur->idx+1;
|
|
}else{
|
|
upr = pCur->idx-1;
|
|
}
|
|
}
|
|
assert( lwr==upr+1 );
|
|
assert( pPage->isInit );
|
|
if( pPage->leaf ){
|
|
chldPg = 0;
|
|
}else if( lwr>=pPage->nCell ){
|
|
chldPg = get4byte(&pPage->aData[pPage->hdrOffset+8]);
|
|
}else{
|
|
chldPg = get4byte(findCell(pPage, lwr));
|
|
}
|
|
if( chldPg==0 ){
|
|
assert( pCur->idx>=0 && pCur->idx<pCur->pPage->nCell );
|
|
if( pRes ) *pRes = c;
|
|
return SQLITE_OK;
|
|
}
|
|
pCur->idx = lwr;
|
|
pCur->info.nSize = 0;
|
|
rc = moveToChild(pCur, chldPg);
|
|
if( rc ){
|
|
return rc;
|
|
}
|
|
}
|
|
/* NOT REACHED */
|
|
}
|
|
|
|
/*
|
|
** Return TRUE if the cursor is not pointing at an entry of the table.
|
|
**
|
|
** TRUE will be returned after a call to sqlite3BtreeNext() moves
|
|
** past the last entry in the table or sqlite3BtreePrev() moves past
|
|
** the first entry. TRUE is also returned if the table is empty.
|
|
*/
|
|
int sqlite3BtreeEof(BtCursor *pCur){
|
|
/* TODO: What if the cursor is in CURSOR_REQUIRESEEK but all table entries
|
|
** have been deleted? This API will need to change to return an error code
|
|
** as well as the boolean result value.
|
|
*/
|
|
return (CURSOR_VALID!=pCur->eState);
|
|
}
|
|
|
|
/*
|
|
** Advance the cursor to the next entry in the database. If
|
|
** successful then set *pRes=0. If the cursor
|
|
** was already pointing to the last entry in the database before
|
|
** this routine was called, then set *pRes=1.
|
|
*/
|
|
int sqlite3BtreeNext(BtCursor *pCur, int *pRes){
|
|
int rc;
|
|
MemPage *pPage;
|
|
|
|
#ifndef SQLITE_OMIT_SHARED_CACHE
|
|
rc = restoreOrClearCursorPosition(pCur, 1);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
if( pCur->skip>0 ){
|
|
pCur->skip = 0;
|
|
*pRes = 0;
|
|
return SQLITE_OK;
|
|
}
|
|
pCur->skip = 0;
|
|
#endif
|
|
|
|
assert( pRes!=0 );
|
|
pPage = pCur->pPage;
|
|
if( CURSOR_INVALID==pCur->eState ){
|
|
*pRes = 1;
|
|
return SQLITE_OK;
|
|
}
|
|
assert( pPage->isInit );
|
|
assert( pCur->idx<pPage->nCell );
|
|
|
|
pCur->idx++;
|
|
pCur->info.nSize = 0;
|
|
if( pCur->idx>=pPage->nCell ){
|
|
if( !pPage->leaf ){
|
|
rc = moveToChild(pCur, get4byte(&pPage->aData[pPage->hdrOffset+8]));
|
|
if( rc ) return rc;
|
|
rc = moveToLeftmost(pCur);
|
|
*pRes = 0;
|
|
return rc;
|
|
}
|
|
do{
|
|
if( isRootPage(pPage) ){
|
|
*pRes = 1;
|
|
pCur->eState = CURSOR_INVALID;
|
|
return SQLITE_OK;
|
|
}
|
|
moveToParent(pCur);
|
|
pPage = pCur->pPage;
|
|
}while( pCur->idx>=pPage->nCell );
|
|
*pRes = 0;
|
|
if( pPage->leafData ){
|
|
rc = sqlite3BtreeNext(pCur, pRes);
|
|
}else{
|
|
rc = SQLITE_OK;
|
|
}
|
|
return rc;
|
|
}
|
|
*pRes = 0;
|
|
if( pPage->leaf ){
|
|
return SQLITE_OK;
|
|
}
|
|
rc = moveToLeftmost(pCur);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Step the cursor to the back to the previous entry in the database. If
|
|
** successful then set *pRes=0. If the cursor
|
|
** was already pointing to the first entry in the database before
|
|
** this routine was called, then set *pRes=1.
|
|
*/
|
|
int sqlite3BtreePrevious(BtCursor *pCur, int *pRes){
|
|
int rc;
|
|
Pgno pgno;
|
|
MemPage *pPage;
|
|
|
|
#ifndef SQLITE_OMIT_SHARED_CACHE
|
|
rc = restoreOrClearCursorPosition(pCur, 1);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
if( pCur->skip<0 ){
|
|
pCur->skip = 0;
|
|
*pRes = 0;
|
|
return SQLITE_OK;
|
|
}
|
|
pCur->skip = 0;
|
|
#endif
|
|
|
|
if( CURSOR_INVALID==pCur->eState ){
|
|
*pRes = 1;
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
pPage = pCur->pPage;
|
|
assert( pPage->isInit );
|
|
assert( pCur->idx>=0 );
|
|
if( !pPage->leaf ){
|
|
pgno = get4byte( findCell(pPage, pCur->idx) );
|
|
rc = moveToChild(pCur, pgno);
|
|
if( rc ) return rc;
|
|
rc = moveToRightmost(pCur);
|
|
}else{
|
|
while( pCur->idx==0 ){
|
|
if( isRootPage(pPage) ){
|
|
pCur->eState = CURSOR_INVALID;
|
|
*pRes = 1;
|
|
return SQLITE_OK;
|
|
}
|
|
moveToParent(pCur);
|
|
pPage = pCur->pPage;
|
|
}
|
|
pCur->idx--;
|
|
pCur->info.nSize = 0;
|
|
if( pPage->leafData && !pPage->leaf ){
|
|
rc = sqlite3BtreePrevious(pCur, pRes);
|
|
}else{
|
|
rc = SQLITE_OK;
|
|
}
|
|
}
|
|
*pRes = 0;
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Allocate a new page from the database file.
|
|
**
|
|
** The new page is marked as dirty. (In other words, sqlite3pager_write()
|
|
** has already been called on the new page.) The new page has also
|
|
** been referenced and the calling routine is responsible for calling
|
|
** sqlite3pager_unref() on the new page when it is done.
|
|
**
|
|
** SQLITE_OK is returned on success. Any other return value indicates
|
|
** an error. *ppPage and *pPgno are undefined in the event of an error.
|
|
** Do not invoke sqlite3pager_unref() on *ppPage if an error is returned.
|
|
**
|
|
** If the "nearby" parameter is not 0, then a (feeble) effort is made to
|
|
** locate a page close to the page number "nearby". This can be used in an
|
|
** attempt to keep related pages close to each other in the database file,
|
|
** which in turn can make database access faster.
|
|
**
|
|
** If the "exact" parameter is not 0, and the page-number nearby exists
|
|
** anywhere on the free-list, then it is guarenteed to be returned. This
|
|
** is only used by auto-vacuum databases when allocating a new table.
|
|
*/
|
|
static int allocatePage(
|
|
BtShared *pBt,
|
|
MemPage **ppPage,
|
|
Pgno *pPgno,
|
|
Pgno nearby,
|
|
u8 exact
|
|
){
|
|
MemPage *pPage1;
|
|
int rc;
|
|
int n; /* Number of pages on the freelist */
|
|
int k; /* Number of leaves on the trunk of the freelist */
|
|
|
|
pPage1 = pBt->pPage1;
|
|
n = get4byte(&pPage1->aData[36]);
|
|
if( n>0 ){
|
|
/* There are pages on the freelist. Reuse one of those pages. */
|
|
MemPage *pTrunk = 0;
|
|
Pgno iTrunk;
|
|
MemPage *pPrevTrunk = 0;
|
|
u8 searchList = 0; /* If the free-list must be searched for 'nearby' */
|
|
|
|
/* If the 'exact' parameter was true and a query of the pointer-map
|
|
** shows that the page 'nearby' is somewhere on the free-list, then
|
|
** the entire-list will be searched for that page.
|
|
*/
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( exact ){
|
|
u8 eType;
|
|
assert( nearby>0 );
|
|
assert( pBt->autoVacuum );
|
|
rc = ptrmapGet(pBt, nearby, &eType, 0);
|
|
if( rc ) return rc;
|
|
if( eType==PTRMAP_FREEPAGE ){
|
|
searchList = 1;
|
|
}
|
|
*pPgno = nearby;
|
|
}
|
|
#endif
|
|
|
|
/* Decrement the free-list count by 1. Set iTrunk to the index of the
|
|
** first free-list trunk page. iPrevTrunk is initially 1.
|
|
*/
|
|
rc = sqlite3pager_write(pPage1->aData);
|
|
if( rc ) return rc;
|
|
put4byte(&pPage1->aData[36], n-1);
|
|
|
|
/* The code within this loop is run only once if the 'searchList' variable
|
|
** is not true. Otherwise, it runs once for each trunk-page on the
|
|
** free-list until the page 'nearby' is located.
|
|
*/
|
|
do {
|
|
pPrevTrunk = pTrunk;
|
|
if( pPrevTrunk ){
|
|
iTrunk = get4byte(&pPrevTrunk->aData[0]);
|
|
}else{
|
|
iTrunk = get4byte(&pPage1->aData[32]);
|
|
}
|
|
rc = getPage(pBt, iTrunk, &pTrunk);
|
|
if( rc ){
|
|
releasePage(pPrevTrunk);
|
|
return rc;
|
|
}
|
|
|
|
/* TODO: This should move to after the loop? */
|
|
rc = sqlite3pager_write(pTrunk->aData);
|
|
if( rc ){
|
|
releasePage(pTrunk);
|
|
releasePage(pPrevTrunk);
|
|
return rc;
|
|
}
|
|
|
|
k = get4byte(&pTrunk->aData[4]);
|
|
if( k==0 && !searchList ){
|
|
/* The trunk has no leaves and the list is not being searched.
|
|
** So extract the trunk page itself and use it as the newly
|
|
** allocated page */
|
|
assert( pPrevTrunk==0 );
|
|
*pPgno = iTrunk;
|
|
memcpy(&pPage1->aData[32], &pTrunk->aData[0], 4);
|
|
*ppPage = pTrunk;
|
|
pTrunk = 0;
|
|
TRACE(("ALLOCATE: %d trunk - %d free pages left\n", *pPgno, n-1));
|
|
}else if( k>pBt->usableSize/4 - 8 ){
|
|
/* Value of k is out of range. Database corruption */
|
|
return SQLITE_CORRUPT_BKPT;
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
}else if( searchList && nearby==iTrunk ){
|
|
/* The list is being searched and this trunk page is the page
|
|
** to allocate, regardless of whether it has leaves.
|
|
*/
|
|
assert( *pPgno==iTrunk );
|
|
*ppPage = pTrunk;
|
|
searchList = 0;
|
|
if( k==0 ){
|
|
if( !pPrevTrunk ){
|
|
memcpy(&pPage1->aData[32], &pTrunk->aData[0], 4);
|
|
}else{
|
|
memcpy(&pPrevTrunk->aData[0], &pTrunk->aData[0], 4);
|
|
}
|
|
}else{
|
|
/* The trunk page is required by the caller but it contains
|
|
** pointers to free-list leaves. The first leaf becomes a trunk
|
|
** page in this case.
|
|
*/
|
|
MemPage *pNewTrunk;
|
|
Pgno iNewTrunk = get4byte(&pTrunk->aData[8]);
|
|
rc = getPage(pBt, iNewTrunk, &pNewTrunk);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(pTrunk);
|
|
releasePage(pPrevTrunk);
|
|
return rc;
|
|
}
|
|
rc = sqlite3pager_write(pNewTrunk->aData);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(pNewTrunk);
|
|
releasePage(pTrunk);
|
|
releasePage(pPrevTrunk);
|
|
return rc;
|
|
}
|
|
memcpy(&pNewTrunk->aData[0], &pTrunk->aData[0], 4);
|
|
put4byte(&pNewTrunk->aData[4], k-1);
|
|
memcpy(&pNewTrunk->aData[8], &pTrunk->aData[12], (k-1)*4);
|
|
if( !pPrevTrunk ){
|
|
put4byte(&pPage1->aData[32], iNewTrunk);
|
|
}else{
|
|
put4byte(&pPrevTrunk->aData[0], iNewTrunk);
|
|
}
|
|
releasePage(pNewTrunk);
|
|
}
|
|
pTrunk = 0;
|
|
TRACE(("ALLOCATE: %d trunk - %d free pages left\n", *pPgno, n-1));
|
|
#endif
|
|
}else{
|
|
/* Extract a leaf from the trunk */
|
|
int closest;
|
|
Pgno iPage;
|
|
unsigned char *aData = pTrunk->aData;
|
|
if( nearby>0 ){
|
|
int i, dist;
|
|
closest = 0;
|
|
dist = get4byte(&aData[8]) - nearby;
|
|
if( dist<0 ) dist = -dist;
|
|
for(i=1; i<k; i++){
|
|
int d2 = get4byte(&aData[8+i*4]) - nearby;
|
|
if( d2<0 ) d2 = -d2;
|
|
if( d2<dist ){
|
|
closest = i;
|
|
dist = d2;
|
|
}
|
|
}
|
|
}else{
|
|
closest = 0;
|
|
}
|
|
|
|
iPage = get4byte(&aData[8+closest*4]);
|
|
if( !searchList || iPage==nearby ){
|
|
*pPgno = iPage;
|
|
if( *pPgno>(Pgno)sqlite3pager_pagecount(pBt->pPager) ){
|
|
/* Free page off the end of the file */
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
TRACE(("ALLOCATE: %d was leaf %d of %d on trunk %d"
|
|
": %d more free pages\n",
|
|
*pPgno, closest+1, k, pTrunk->pgno, n-1));
|
|
if( closest<k-1 ){
|
|
memcpy(&aData[8+closest*4], &aData[4+k*4], 4);
|
|
}
|
|
put4byte(&aData[4], k-1);
|
|
rc = getPage(pBt, *pPgno, ppPage);
|
|
if( rc==SQLITE_OK ){
|
|
sqlite3pager_dont_rollback((*ppPage)->aData);
|
|
rc = sqlite3pager_write((*ppPage)->aData);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(*ppPage);
|
|
}
|
|
}
|
|
searchList = 0;
|
|
}
|
|
}
|
|
releasePage(pPrevTrunk);
|
|
}while( searchList );
|
|
releasePage(pTrunk);
|
|
}else{
|
|
/* There are no pages on the freelist, so create a new page at the
|
|
** end of the file */
|
|
*pPgno = sqlite3pager_pagecount(pBt->pPager) + 1;
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum && PTRMAP_ISPAGE(pBt, *pPgno) ){
|
|
/* If *pPgno refers to a pointer-map page, allocate two new pages
|
|
** at the end of the file instead of one. The first allocated page
|
|
** becomes a new pointer-map page, the second is used by the caller.
|
|
*/
|
|
TRACE(("ALLOCATE: %d from end of file (pointer-map page)\n", *pPgno));
|
|
assert( *pPgno!=PENDING_BYTE_PAGE(pBt) );
|
|
(*pPgno)++;
|
|
}
|
|
#endif
|
|
|
|
assert( *pPgno!=PENDING_BYTE_PAGE(pBt) );
|
|
rc = getPage(pBt, *pPgno, ppPage);
|
|
if( rc ) return rc;
|
|
rc = sqlite3pager_write((*ppPage)->aData);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(*ppPage);
|
|
}
|
|
TRACE(("ALLOCATE: %d from end of file\n", *pPgno));
|
|
}
|
|
|
|
assert( *pPgno!=PENDING_BYTE_PAGE(pBt) );
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Add a page of the database file to the freelist.
|
|
**
|
|
** sqlite3pager_unref() is NOT called for pPage.
|
|
*/
|
|
static int freePage(MemPage *pPage){
|
|
BtShared *pBt = pPage->pBt;
|
|
MemPage *pPage1 = pBt->pPage1;
|
|
int rc, n, k;
|
|
|
|
/* Prepare the page for freeing */
|
|
assert( pPage->pgno>1 );
|
|
pPage->isInit = 0;
|
|
releasePage(pPage->pParent);
|
|
pPage->pParent = 0;
|
|
|
|
/* Increment the free page count on pPage1 */
|
|
rc = sqlite3pager_write(pPage1->aData);
|
|
if( rc ) return rc;
|
|
n = get4byte(&pPage1->aData[36]);
|
|
put4byte(&pPage1->aData[36], n+1);
|
|
|
|
#ifdef SQLITE_SECURE_DELETE
|
|
/* If the SQLITE_SECURE_DELETE compile-time option is enabled, then
|
|
** always fully overwrite deleted information with zeros.
|
|
*/
|
|
rc = sqlite3pager_write(pPage->aData);
|
|
if( rc ) return rc;
|
|
memset(pPage->aData, 0, pPage->pBt->pageSize);
|
|
#endif
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/* If the database supports auto-vacuum, write an entry in the pointer-map
|
|
** to indicate that the page is free.
|
|
*/
|
|
if( pBt->autoVacuum ){
|
|
rc = ptrmapPut(pBt, pPage->pgno, PTRMAP_FREEPAGE, 0);
|
|
if( rc ) return rc;
|
|
}
|
|
#endif
|
|
|
|
if( n==0 ){
|
|
/* This is the first free page */
|
|
rc = sqlite3pager_write(pPage->aData);
|
|
if( rc ) return rc;
|
|
memset(pPage->aData, 0, 8);
|
|
put4byte(&pPage1->aData[32], pPage->pgno);
|
|
TRACE(("FREE-PAGE: %d first\n", pPage->pgno));
|
|
}else{
|
|
/* Other free pages already exist. Retrive the first trunk page
|
|
** of the freelist and find out how many leaves it has. */
|
|
MemPage *pTrunk;
|
|
rc = getPage(pBt, get4byte(&pPage1->aData[32]), &pTrunk);
|
|
if( rc ) return rc;
|
|
k = get4byte(&pTrunk->aData[4]);
|
|
if( k>=pBt->usableSize/4 - 8 ){
|
|
/* The trunk is full. Turn the page being freed into a new
|
|
** trunk page with no leaves. */
|
|
rc = sqlite3pager_write(pPage->aData);
|
|
if( rc ) return rc;
|
|
put4byte(pPage->aData, pTrunk->pgno);
|
|
put4byte(&pPage->aData[4], 0);
|
|
put4byte(&pPage1->aData[32], pPage->pgno);
|
|
TRACE(("FREE-PAGE: %d new trunk page replacing %d\n",
|
|
pPage->pgno, pTrunk->pgno));
|
|
}else{
|
|
/* Add the newly freed page as a leaf on the current trunk */
|
|
rc = sqlite3pager_write(pTrunk->aData);
|
|
if( rc ) return rc;
|
|
put4byte(&pTrunk->aData[4], k+1);
|
|
put4byte(&pTrunk->aData[8+k*4], pPage->pgno);
|
|
#ifndef SQLITE_SECURE_DELETE
|
|
sqlite3pager_dont_write(pBt->pPager, pPage->pgno);
|
|
#endif
|
|
TRACE(("FREE-PAGE: %d leaf on trunk page %d\n",pPage->pgno,pTrunk->pgno));
|
|
}
|
|
releasePage(pTrunk);
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Free any overflow pages associated with the given Cell.
|
|
*/
|
|
static int clearCell(MemPage *pPage, unsigned char *pCell){
|
|
BtShared *pBt = pPage->pBt;
|
|
CellInfo info;
|
|
Pgno ovflPgno;
|
|
int rc;
|
|
|
|
parseCellPtr(pPage, pCell, &info);
|
|
if( info.iOverflow==0 ){
|
|
return SQLITE_OK; /* No overflow pages. Return without doing anything */
|
|
}
|
|
ovflPgno = get4byte(&pCell[info.iOverflow]);
|
|
while( ovflPgno!=0 ){
|
|
MemPage *pOvfl;
|
|
if( ovflPgno>(Pgno)sqlite3pager_pagecount(pBt->pPager) ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
rc = getPage(pBt, ovflPgno, &pOvfl);
|
|
if( rc ) return rc;
|
|
ovflPgno = get4byte(pOvfl->aData);
|
|
rc = freePage(pOvfl);
|
|
sqlite3pager_unref(pOvfl->aData);
|
|
if( rc ) return rc;
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Create the byte sequence used to represent a cell on page pPage
|
|
** and write that byte sequence into pCell[]. Overflow pages are
|
|
** allocated and filled in as necessary. The calling procedure
|
|
** is responsible for making sure sufficient space has been allocated
|
|
** for pCell[].
|
|
**
|
|
** Note that pCell does not necessary need to point to the pPage->aData
|
|
** area. pCell might point to some temporary storage. The cell will
|
|
** be constructed in this temporary area then copied into pPage->aData
|
|
** later.
|
|
*/
|
|
static int fillInCell(
|
|
MemPage *pPage, /* The page that contains the cell */
|
|
unsigned char *pCell, /* Complete text of the cell */
|
|
const void *pKey, i64 nKey, /* The key */
|
|
const void *pData,int nData, /* The data */
|
|
int *pnSize /* Write cell size here */
|
|
){
|
|
int nPayload;
|
|
const u8 *pSrc;
|
|
int nSrc, n, rc;
|
|
int spaceLeft;
|
|
MemPage *pOvfl = 0;
|
|
MemPage *pToRelease = 0;
|
|
unsigned char *pPrior;
|
|
unsigned char *pPayload;
|
|
BtShared *pBt = pPage->pBt;
|
|
Pgno pgnoOvfl = 0;
|
|
int nHeader;
|
|
CellInfo info;
|
|
|
|
/* Fill in the header. */
|
|
nHeader = 0;
|
|
if( !pPage->leaf ){
|
|
nHeader += 4;
|
|
}
|
|
if( pPage->hasData ){
|
|
nHeader += putVarint(&pCell[nHeader], nData);
|
|
}else{
|
|
nData = 0;
|
|
}
|
|
nHeader += putVarint(&pCell[nHeader], *(u64*)&nKey);
|
|
parseCellPtr(pPage, pCell, &info);
|
|
assert( info.nHeader==nHeader );
|
|
assert( info.nKey==nKey );
|
|
assert( info.nData==nData );
|
|
|
|
/* Fill in the payload */
|
|
nPayload = nData;
|
|
if( pPage->intKey ){
|
|
pSrc = pData;
|
|
nSrc = nData;
|
|
nData = 0;
|
|
}else{
|
|
nPayload += (int)nKey;
|
|
pSrc = pKey;
|
|
nSrc = (int)nKey;
|
|
}
|
|
*pnSize = info.nSize;
|
|
spaceLeft = info.nLocal;
|
|
pPayload = &pCell[nHeader];
|
|
pPrior = &pCell[info.iOverflow];
|
|
|
|
while( nPayload>0 ){
|
|
if( spaceLeft==0 ){
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
Pgno pgnoPtrmap = pgnoOvfl; /* Overflow page pointer-map entry page */
|
|
#endif
|
|
rc = allocatePage(pBt, &pOvfl, &pgnoOvfl, pgnoOvfl, 0);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/* If the database supports auto-vacuum, and the second or subsequent
|
|
** overflow page is being allocated, add an entry to the pointer-map
|
|
** for that page now. The entry for the first overflow page will be
|
|
** added later, by the insertCell() routine.
|
|
*/
|
|
if( pBt->autoVacuum && pgnoPtrmap!=0 && rc==SQLITE_OK ){
|
|
rc = ptrmapPut(pBt, pgnoOvfl, PTRMAP_OVERFLOW2, pgnoPtrmap);
|
|
}
|
|
#endif
|
|
if( rc ){
|
|
releasePage(pToRelease);
|
|
/* clearCell(pPage, pCell); */
|
|
return rc;
|
|
}
|
|
put4byte(pPrior, pgnoOvfl);
|
|
releasePage(pToRelease);
|
|
pToRelease = pOvfl;
|
|
pPrior = pOvfl->aData;
|
|
put4byte(pPrior, 0);
|
|
pPayload = &pOvfl->aData[4];
|
|
spaceLeft = pBt->usableSize - 4;
|
|
}
|
|
n = nPayload;
|
|
if( n>spaceLeft ) n = spaceLeft;
|
|
if( n>nSrc ) n = nSrc;
|
|
assert( pSrc );
|
|
memcpy(pPayload, pSrc, n);
|
|
nPayload -= n;
|
|
pPayload += n;
|
|
pSrc += n;
|
|
nSrc -= n;
|
|
spaceLeft -= n;
|
|
if( nSrc==0 ){
|
|
nSrc = nData;
|
|
pSrc = pData;
|
|
}
|
|
}
|
|
releasePage(pToRelease);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Change the MemPage.pParent pointer on the page whose number is
|
|
** given in the second argument so that MemPage.pParent holds the
|
|
** pointer in the third argument.
|
|
*/
|
|
static int reparentPage(BtShared *pBt, Pgno pgno, MemPage *pNewParent, int idx){
|
|
MemPage *pThis;
|
|
unsigned char *aData;
|
|
|
|
assert( pNewParent!=0 );
|
|
if( pgno==0 ) return SQLITE_OK;
|
|
assert( pBt->pPager!=0 );
|
|
aData = sqlite3pager_lookup(pBt->pPager, pgno);
|
|
if( aData ){
|
|
pThis = (MemPage*)&aData[pBt->pageSize];
|
|
assert( pThis->aData==aData );
|
|
if( pThis->isInit ){
|
|
if( pThis->pParent!=pNewParent ){
|
|
if( pThis->pParent ) sqlite3pager_unref(pThis->pParent->aData);
|
|
pThis->pParent = pNewParent;
|
|
sqlite3pager_ref(pNewParent->aData);
|
|
}
|
|
pThis->idxParent = idx;
|
|
}
|
|
sqlite3pager_unref(aData);
|
|
}
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
return ptrmapPut(pBt, pgno, PTRMAP_BTREE, pNewParent->pgno);
|
|
}
|
|
#endif
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
|
|
|
|
/*
|
|
** Change the pParent pointer of all children of pPage to point back
|
|
** to pPage.
|
|
**
|
|
** In other words, for every child of pPage, invoke reparentPage()
|
|
** to make sure that each child knows that pPage is its parent.
|
|
**
|
|
** This routine gets called after you memcpy() one page into
|
|
** another.
|
|
*/
|
|
static int reparentChildPages(MemPage *pPage){
|
|
int i;
|
|
BtShared *pBt = pPage->pBt;
|
|
int rc = SQLITE_OK;
|
|
|
|
if( pPage->leaf ) return SQLITE_OK;
|
|
|
|
for(i=0; i<pPage->nCell; i++){
|
|
u8 *pCell = findCell(pPage, i);
|
|
if( !pPage->leaf ){
|
|
rc = reparentPage(pBt, get4byte(pCell), pPage, i);
|
|
if( rc!=SQLITE_OK ) return rc;
|
|
}
|
|
}
|
|
if( !pPage->leaf ){
|
|
rc = reparentPage(pBt, get4byte(&pPage->aData[pPage->hdrOffset+8]),
|
|
pPage, i);
|
|
pPage->idxShift = 0;
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Remove the i-th cell from pPage. This routine effects pPage only.
|
|
** The cell content is not freed or deallocated. It is assumed that
|
|
** the cell content has been copied someplace else. This routine just
|
|
** removes the reference to the cell from pPage.
|
|
**
|
|
** "sz" must be the number of bytes in the cell.
|
|
*/
|
|
static void dropCell(MemPage *pPage, int idx, int sz){
|
|
int i; /* Loop counter */
|
|
int pc; /* Offset to cell content of cell being deleted */
|
|
u8 *data; /* pPage->aData */
|
|
u8 *ptr; /* Used to move bytes around within data[] */
|
|
|
|
assert( idx>=0 && idx<pPage->nCell );
|
|
assert( sz==cellSize(pPage, idx) );
|
|
assert( sqlite3pager_iswriteable(pPage->aData) );
|
|
data = pPage->aData;
|
|
ptr = &data[pPage->cellOffset + 2*idx];
|
|
pc = get2byte(ptr);
|
|
assert( pc>10 && pc+sz<=pPage->pBt->usableSize );
|
|
freeSpace(pPage, pc, sz);
|
|
for(i=idx+1; i<pPage->nCell; i++, ptr+=2){
|
|
ptr[0] = ptr[2];
|
|
ptr[1] = ptr[3];
|
|
}
|
|
pPage->nCell--;
|
|
put2byte(&data[pPage->hdrOffset+3], pPage->nCell);
|
|
pPage->nFree += 2;
|
|
pPage->idxShift = 1;
|
|
}
|
|
|
|
/*
|
|
** Insert a new cell on pPage at cell index "i". pCell points to the
|
|
** content of the cell.
|
|
**
|
|
** If the cell content will fit on the page, then put it there. If it
|
|
** will not fit, then make a copy of the cell content into pTemp if
|
|
** pTemp is not null. Regardless of pTemp, allocate a new entry
|
|
** in pPage->aOvfl[] and make it point to the cell content (either
|
|
** in pTemp or the original pCell) and also record its index.
|
|
** Allocating a new entry in pPage->aCell[] implies that
|
|
** pPage->nOverflow is incremented.
|
|
**
|
|
** If nSkip is non-zero, then do not copy the first nSkip bytes of the
|
|
** cell. The caller will overwrite them after this function returns. If
|
|
** nSkip is non-zero, then pCell may not point to an invalid memory location
|
|
** (but pCell+nSkip is always valid).
|
|
*/
|
|
static int insertCell(
|
|
MemPage *pPage, /* Page into which we are copying */
|
|
int i, /* New cell becomes the i-th cell of the page */
|
|
u8 *pCell, /* Content of the new cell */
|
|
int sz, /* Bytes of content in pCell */
|
|
u8 *pTemp, /* Temp storage space for pCell, if needed */
|
|
u8 nSkip /* Do not write the first nSkip bytes of the cell */
|
|
){
|
|
int idx; /* Where to write new cell content in data[] */
|
|
int j; /* Loop counter */
|
|
int top; /* First byte of content for any cell in data[] */
|
|
int end; /* First byte past the last cell pointer in data[] */
|
|
int ins; /* Index in data[] where new cell pointer is inserted */
|
|
int hdr; /* Offset into data[] of the page header */
|
|
int cellOffset; /* Address of first cell pointer in data[] */
|
|
u8 *data; /* The content of the whole page */
|
|
u8 *ptr; /* Used for moving information around in data[] */
|
|
|
|
assert( i>=0 && i<=pPage->nCell+pPage->nOverflow );
|
|
assert( sz==cellSizePtr(pPage, pCell) );
|
|
assert( sqlite3pager_iswriteable(pPage->aData) );
|
|
if( pPage->nOverflow || sz+2>pPage->nFree ){
|
|
if( pTemp ){
|
|
memcpy(pTemp+nSkip, pCell+nSkip, sz-nSkip);
|
|
pCell = pTemp;
|
|
}
|
|
j = pPage->nOverflow++;
|
|
assert( j<sizeof(pPage->aOvfl)/sizeof(pPage->aOvfl[0]) );
|
|
pPage->aOvfl[j].pCell = pCell;
|
|
pPage->aOvfl[j].idx = i;
|
|
pPage->nFree = 0;
|
|
}else{
|
|
data = pPage->aData;
|
|
hdr = pPage->hdrOffset;
|
|
top = get2byte(&data[hdr+5]);
|
|
cellOffset = pPage->cellOffset;
|
|
end = cellOffset + 2*pPage->nCell + 2;
|
|
ins = cellOffset + 2*i;
|
|
if( end > top - sz ){
|
|
int rc = defragmentPage(pPage);
|
|
if( rc!=SQLITE_OK ) return rc;
|
|
top = get2byte(&data[hdr+5]);
|
|
assert( end + sz <= top );
|
|
}
|
|
idx = allocateSpace(pPage, sz);
|
|
assert( idx>0 );
|
|
assert( end <= get2byte(&data[hdr+5]) );
|
|
pPage->nCell++;
|
|
pPage->nFree -= 2;
|
|
memcpy(&data[idx+nSkip], pCell+nSkip, sz-nSkip);
|
|
for(j=end-2, ptr=&data[j]; j>ins; j-=2, ptr-=2){
|
|
ptr[0] = ptr[-2];
|
|
ptr[1] = ptr[-1];
|
|
}
|
|
put2byte(&data[ins], idx);
|
|
put2byte(&data[hdr+3], pPage->nCell);
|
|
pPage->idxShift = 1;
|
|
pageIntegrity(pPage);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pPage->pBt->autoVacuum ){
|
|
/* The cell may contain a pointer to an overflow page. If so, write
|
|
** the entry for the overflow page into the pointer map.
|
|
*/
|
|
CellInfo info;
|
|
parseCellPtr(pPage, pCell, &info);
|
|
if( (info.nData+(pPage->intKey?0:info.nKey))>info.nLocal ){
|
|
Pgno pgnoOvfl = get4byte(&pCell[info.iOverflow]);
|
|
int rc = ptrmapPut(pPage->pBt, pgnoOvfl, PTRMAP_OVERFLOW1, pPage->pgno);
|
|
if( rc!=SQLITE_OK ) return rc;
|
|
}
|
|
}
|
|
#endif
|
|
}
|
|
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Add a list of cells to a page. The page should be initially empty.
|
|
** The cells are guaranteed to fit on the page.
|
|
*/
|
|
static void assemblePage(
|
|
MemPage *pPage, /* The page to be assemblied */
|
|
int nCell, /* The number of cells to add to this page */
|
|
u8 **apCell, /* Pointers to cell bodies */
|
|
int *aSize /* Sizes of the cells */
|
|
){
|
|
int i; /* Loop counter */
|
|
int totalSize; /* Total size of all cells */
|
|
int hdr; /* Index of page header */
|
|
int cellptr; /* Address of next cell pointer */
|
|
int cellbody; /* Address of next cell body */
|
|
u8 *data; /* Data for the page */
|
|
|
|
assert( pPage->nOverflow==0 );
|
|
totalSize = 0;
|
|
for(i=0; i<nCell; i++){
|
|
totalSize += aSize[i];
|
|
}
|
|
assert( totalSize+2*nCell<=pPage->nFree );
|
|
assert( pPage->nCell==0 );
|
|
cellptr = pPage->cellOffset;
|
|
data = pPage->aData;
|
|
hdr = pPage->hdrOffset;
|
|
put2byte(&data[hdr+3], nCell);
|
|
if( nCell ){
|
|
cellbody = allocateSpace(pPage, totalSize);
|
|
assert( cellbody>0 );
|
|
assert( pPage->nFree >= 2*nCell );
|
|
pPage->nFree -= 2*nCell;
|
|
for(i=0; i<nCell; i++){
|
|
put2byte(&data[cellptr], cellbody);
|
|
memcpy(&data[cellbody], apCell[i], aSize[i]);
|
|
cellptr += 2;
|
|
cellbody += aSize[i];
|
|
}
|
|
assert( cellbody==pPage->pBt->usableSize );
|
|
}
|
|
pPage->nCell = nCell;
|
|
}
|
|
|
|
/*
|
|
** The following parameters determine how many adjacent pages get involved
|
|
** in a balancing operation. NN is the number of neighbors on either side
|
|
** of the page that participate in the balancing operation. NB is the
|
|
** total number of pages that participate, including the target page and
|
|
** NN neighbors on either side.
|
|
**
|
|
** The minimum value of NN is 1 (of course). Increasing NN above 1
|
|
** (to 2 or 3) gives a modest improvement in SELECT and DELETE performance
|
|
** in exchange for a larger degradation in INSERT and UPDATE performance.
|
|
** The value of NN appears to give the best results overall.
|
|
*/
|
|
#define NN 1 /* Number of neighbors on either side of pPage */
|
|
#define NB (NN*2+1) /* Total pages involved in the balance */
|
|
|
|
/* Forward reference */
|
|
static int balance(MemPage*, int);
|
|
|
|
#ifndef SQLITE_OMIT_QUICKBALANCE
|
|
/*
|
|
** This version of balance() handles the common special case where
|
|
** a new entry is being inserted on the extreme right-end of the
|
|
** tree, in other words, when the new entry will become the largest
|
|
** entry in the tree.
|
|
**
|
|
** Instead of trying balance the 3 right-most leaf pages, just add
|
|
** a new page to the right-hand side and put the one new entry in
|
|
** that page. This leaves the right side of the tree somewhat
|
|
** unbalanced. But odds are that we will be inserting new entries
|
|
** at the end soon afterwards so the nearly empty page will quickly
|
|
** fill up. On average.
|
|
**
|
|
** pPage is the leaf page which is the right-most page in the tree.
|
|
** pParent is its parent. pPage must have a single overflow entry
|
|
** which is also the right-most entry on the page.
|
|
*/
|
|
static int balance_quick(MemPage *pPage, MemPage *pParent){
|
|
int rc;
|
|
MemPage *pNew;
|
|
Pgno pgnoNew;
|
|
u8 *pCell;
|
|
int szCell;
|
|
CellInfo info;
|
|
BtShared *pBt = pPage->pBt;
|
|
int parentIdx = pParent->nCell; /* pParent new divider cell index */
|
|
int parentSize; /* Size of new divider cell */
|
|
u8 parentCell[64]; /* Space for the new divider cell */
|
|
|
|
/* Allocate a new page. Insert the overflow cell from pPage
|
|
** into it. Then remove the overflow cell from pPage.
|
|
*/
|
|
rc = allocatePage(pBt, &pNew, &pgnoNew, 0, 0);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
pCell = pPage->aOvfl[0].pCell;
|
|
szCell = cellSizePtr(pPage, pCell);
|
|
zeroPage(pNew, pPage->aData[0]);
|
|
assemblePage(pNew, 1, &pCell, &szCell);
|
|
pPage->nOverflow = 0;
|
|
|
|
/* Set the parent of the newly allocated page to pParent. */
|
|
pNew->pParent = pParent;
|
|
sqlite3pager_ref(pParent->aData);
|
|
|
|
/* pPage is currently the right-child of pParent. Change this
|
|
** so that the right-child is the new page allocated above and
|
|
** pPage is the next-to-right child.
|
|
*/
|
|
assert( pPage->nCell>0 );
|
|
parseCellPtr(pPage, findCell(pPage, pPage->nCell-1), &info);
|
|
rc = fillInCell(pParent, parentCell, 0, info.nKey, 0, 0, &parentSize);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
assert( parentSize<64 );
|
|
rc = insertCell(pParent, parentIdx, parentCell, parentSize, 0, 4);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
put4byte(findOverflowCell(pParent,parentIdx), pPage->pgno);
|
|
put4byte(&pParent->aData[pParent->hdrOffset+8], pgnoNew);
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/* If this is an auto-vacuum database, update the pointer map
|
|
** with entries for the new page, and any pointer from the
|
|
** cell on the page to an overflow page.
|
|
*/
|
|
if( pBt->autoVacuum ){
|
|
rc = ptrmapPut(pBt, pgnoNew, PTRMAP_BTREE, pParent->pgno);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
rc = ptrmapPutOvfl(pNew, 0);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
}
|
|
#endif
|
|
|
|
/* Release the reference to the new page and balance the parent page,
|
|
** in case the divider cell inserted caused it to become overfull.
|
|
*/
|
|
releasePage(pNew);
|
|
return balance(pParent, 0);
|
|
}
|
|
#endif /* SQLITE_OMIT_QUICKBALANCE */
|
|
|
|
/*
|
|
** The ISAUTOVACUUM macro is used within balance_nonroot() to determine
|
|
** if the database supports auto-vacuum or not. Because it is used
|
|
** within an expression that is an argument to another macro
|
|
** (sqliteMallocRaw), it is not possible to use conditional compilation.
|
|
** So, this macro is defined instead.
|
|
*/
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
#define ISAUTOVACUUM (pBt->autoVacuum)
|
|
#else
|
|
#define ISAUTOVACUUM 0
|
|
#endif
|
|
|
|
/*
|
|
** This routine redistributes Cells on pPage and up to NN*2 siblings
|
|
** of pPage so that all pages have about the same amount of free space.
|
|
** Usually NN siblings on either side of pPage is used in the balancing,
|
|
** though more siblings might come from one side if pPage is the first
|
|
** or last child of its parent. If pPage has fewer than 2*NN siblings
|
|
** (something which can only happen if pPage is the root page or a
|
|
** child of root) then all available siblings participate in the balancing.
|
|
**
|
|
** The number of siblings of pPage might be increased or decreased by one or
|
|
** two in an effort to keep pages nearly full but not over full. The root page
|
|
** is special and is allowed to be nearly empty. If pPage is
|
|
** the root page, then the depth of the tree might be increased
|
|
** or decreased by one, as necessary, to keep the root page from being
|
|
** overfull or completely empty.
|
|
**
|
|
** Note that when this routine is called, some of the Cells on pPage
|
|
** might not actually be stored in pPage->aData[]. This can happen
|
|
** if the page is overfull. Part of the job of this routine is to
|
|
** make sure all Cells for pPage once again fit in pPage->aData[].
|
|
**
|
|
** In the course of balancing the siblings of pPage, the parent of pPage
|
|
** might become overfull or underfull. If that happens, then this routine
|
|
** is called recursively on the parent.
|
|
**
|
|
** If this routine fails for any reason, it might leave the database
|
|
** in a corrupted state. So if this routine fails, the database should
|
|
** be rolled back.
|
|
*/
|
|
static int balance_nonroot(MemPage *pPage){
|
|
MemPage *pParent; /* The parent of pPage */
|
|
BtShared *pBt; /* The whole database */
|
|
int nCell = 0; /* Number of cells in apCell[] */
|
|
int nMaxCells = 0; /* Allocated size of apCell, szCell, aFrom. */
|
|
int nOld; /* Number of pages in apOld[] */
|
|
int nNew; /* Number of pages in apNew[] */
|
|
int nDiv; /* Number of cells in apDiv[] */
|
|
int i, j, k; /* Loop counters */
|
|
int idx; /* Index of pPage in pParent->aCell[] */
|
|
int nxDiv; /* Next divider slot in pParent->aCell[] */
|
|
int rc; /* The return code */
|
|
int leafCorrection; /* 4 if pPage is a leaf. 0 if not */
|
|
int leafData; /* True if pPage is a leaf of a LEAFDATA tree */
|
|
int usableSpace; /* Bytes in pPage beyond the header */
|
|
int pageFlags; /* Value of pPage->aData[0] */
|
|
int subtotal; /* Subtotal of bytes in cells on one page */
|
|
int iSpace = 0; /* First unused byte of aSpace[] */
|
|
MemPage *apOld[NB]; /* pPage and up to two siblings */
|
|
Pgno pgnoOld[NB]; /* Page numbers for each page in apOld[] */
|
|
MemPage *apCopy[NB]; /* Private copies of apOld[] pages */
|
|
MemPage *apNew[NB+2]; /* pPage and up to NB siblings after balancing */
|
|
Pgno pgnoNew[NB+2]; /* Page numbers for each page in apNew[] */
|
|
u8 *apDiv[NB]; /* Divider cells in pParent */
|
|
int cntNew[NB+2]; /* Index in aCell[] of cell after i-th page */
|
|
int szNew[NB+2]; /* Combined size of cells place on i-th page */
|
|
u8 **apCell = 0; /* All cells begin balanced */
|
|
int *szCell; /* Local size of all cells in apCell[] */
|
|
u8 *aCopy[NB]; /* Space for holding data of apCopy[] */
|
|
u8 *aSpace; /* Space to hold copies of dividers cells */
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
u8 *aFrom = 0;
|
|
#endif
|
|
|
|
/*
|
|
** Find the parent page.
|
|
*/
|
|
assert( pPage->isInit );
|
|
assert( sqlite3pager_iswriteable(pPage->aData) );
|
|
pBt = pPage->pBt;
|
|
pParent = pPage->pParent;
|
|
assert( pParent );
|
|
if( SQLITE_OK!=(rc = sqlite3pager_write(pParent->aData)) ){
|
|
return rc;
|
|
}
|
|
TRACE(("BALANCE: begin page %d child of %d\n", pPage->pgno, pParent->pgno));
|
|
|
|
#ifndef SQLITE_OMIT_QUICKBALANCE
|
|
/*
|
|
** A special case: If a new entry has just been inserted into a
|
|
** table (that is, a btree with integer keys and all data at the leaves)
|
|
** and the new entry is the right-most entry in the tree (it has the
|
|
** largest key) then use the special balance_quick() routine for
|
|
** balancing. balance_quick() is much faster and results in a tighter
|
|
** packing of data in the common case.
|
|
*/
|
|
if( pPage->leaf &&
|
|
pPage->intKey &&
|
|
pPage->leafData &&
|
|
pPage->nOverflow==1 &&
|
|
pPage->aOvfl[0].idx==pPage->nCell &&
|
|
pPage->pParent->pgno!=1 &&
|
|
get4byte(&pParent->aData[pParent->hdrOffset+8])==pPage->pgno
|
|
){
|
|
/*
|
|
** TODO: Check the siblings to the left of pPage. It may be that
|
|
** they are not full and no new page is required.
|
|
*/
|
|
return balance_quick(pPage, pParent);
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** Find the cell in the parent page whose left child points back
|
|
** to pPage. The "idx" variable is the index of that cell. If pPage
|
|
** is the rightmost child of pParent then set idx to pParent->nCell
|
|
*/
|
|
if( pParent->idxShift ){
|
|
Pgno pgno;
|
|
pgno = pPage->pgno;
|
|
assert( pgno==sqlite3pager_pagenumber(pPage->aData) );
|
|
for(idx=0; idx<pParent->nCell; idx++){
|
|
if( get4byte(findCell(pParent, idx))==pgno ){
|
|
break;
|
|
}
|
|
}
|
|
assert( idx<pParent->nCell
|
|
|| get4byte(&pParent->aData[pParent->hdrOffset+8])==pgno );
|
|
}else{
|
|
idx = pPage->idxParent;
|
|
}
|
|
|
|
/*
|
|
** Initialize variables so that it will be safe to jump
|
|
** directly to balance_cleanup at any moment.
|
|
*/
|
|
nOld = nNew = 0;
|
|
sqlite3pager_ref(pParent->aData);
|
|
|
|
/*
|
|
** Find sibling pages to pPage and the cells in pParent that divide
|
|
** the siblings. An attempt is made to find NN siblings on either
|
|
** side of pPage. More siblings are taken from one side, however, if
|
|
** pPage there are fewer than NN siblings on the other side. If pParent
|
|
** has NB or fewer children then all children of pParent are taken.
|
|
*/
|
|
nxDiv = idx - NN;
|
|
if( nxDiv + NB > pParent->nCell ){
|
|
nxDiv = pParent->nCell - NB + 1;
|
|
}
|
|
if( nxDiv<0 ){
|
|
nxDiv = 0;
|
|
}
|
|
nDiv = 0;
|
|
for(i=0, k=nxDiv; i<NB; i++, k++){
|
|
if( k<pParent->nCell ){
|
|
apDiv[i] = findCell(pParent, k);
|
|
nDiv++;
|
|
assert( !pParent->leaf );
|
|
pgnoOld[i] = get4byte(apDiv[i]);
|
|
}else if( k==pParent->nCell ){
|
|
pgnoOld[i] = get4byte(&pParent->aData[pParent->hdrOffset+8]);
|
|
}else{
|
|
break;
|
|
}
|
|
rc = getAndInitPage(pBt, pgnoOld[i], &apOld[i], pParent);
|
|
if( rc ) goto balance_cleanup;
|
|
apOld[i]->idxParent = k;
|
|
apCopy[i] = 0;
|
|
assert( i==nOld );
|
|
nOld++;
|
|
nMaxCells += 1+apOld[i]->nCell+apOld[i]->nOverflow;
|
|
}
|
|
|
|
/* Make nMaxCells a multiple of 2 in order to preserve 8-byte
|
|
** alignment */
|
|
nMaxCells = (nMaxCells + 1)&~1;
|
|
|
|
/*
|
|
** Allocate space for memory structures
|
|
*/
|
|
apCell = sqliteMallocRaw(
|
|
nMaxCells*sizeof(u8*) /* apCell */
|
|
+ nMaxCells*sizeof(int) /* szCell */
|
|
+ ROUND8(sizeof(MemPage))*NB /* aCopy */
|
|
+ pBt->pageSize*(5+NB) /* aSpace */
|
|
+ (ISAUTOVACUUM ? nMaxCells : 0) /* aFrom */
|
|
);
|
|
if( apCell==0 ){
|
|
rc = SQLITE_NOMEM;
|
|
goto balance_cleanup;
|
|
}
|
|
szCell = (int*)&apCell[nMaxCells];
|
|
aCopy[0] = (u8*)&szCell[nMaxCells];
|
|
assert( ((aCopy[0] - (u8*)apCell) & 7)==0 ); /* 8-byte alignment required */
|
|
for(i=1; i<NB; i++){
|
|
aCopy[i] = &aCopy[i-1][pBt->pageSize+ROUND8(sizeof(MemPage))];
|
|
assert( ((aCopy[i] - (u8*)apCell) & 7)==0 ); /* 8-byte alignment required */
|
|
}
|
|
aSpace = &aCopy[NB-1][pBt->pageSize+ROUND8(sizeof(MemPage))];
|
|
assert( ((aSpace - (u8*)apCell) & 7)==0 ); /* 8-byte alignment required */
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
aFrom = &aSpace[5*pBt->pageSize];
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** Make copies of the content of pPage and its siblings into aOld[].
|
|
** The rest of this function will use data from the copies rather
|
|
** that the original pages since the original pages will be in the
|
|
** process of being overwritten.
|
|
*/
|
|
for(i=0; i<nOld; i++){
|
|
MemPage *p = apCopy[i] = (MemPage*)&aCopy[i][pBt->pageSize];
|
|
p->aData = &((u8*)p)[-pBt->pageSize];
|
|
memcpy(p->aData, apOld[i]->aData, pBt->pageSize + sizeof(MemPage));
|
|
/* The memcpy() above changes the value of p->aData so we have to
|
|
** set it again. */
|
|
p->aData = &((u8*)p)[-pBt->pageSize];
|
|
}
|
|
|
|
/*
|
|
** Load pointers to all cells on sibling pages and the divider cells
|
|
** into the local apCell[] array. Make copies of the divider cells
|
|
** into space obtained form aSpace[] and remove the the divider Cells
|
|
** from pParent.
|
|
**
|
|
** If the siblings are on leaf pages, then the child pointers of the
|
|
** divider cells are stripped from the cells before they are copied
|
|
** into aSpace[]. In this way, all cells in apCell[] are without
|
|
** child pointers. If siblings are not leaves, then all cell in
|
|
** apCell[] include child pointers. Either way, all cells in apCell[]
|
|
** are alike.
|
|
**
|
|
** leafCorrection: 4 if pPage is a leaf. 0 if pPage is not a leaf.
|
|
** leafData: 1 if pPage holds key+data and pParent holds only keys.
|
|
*/
|
|
nCell = 0;
|
|
leafCorrection = pPage->leaf*4;
|
|
leafData = pPage->leafData && pPage->leaf;
|
|
for(i=0; i<nOld; i++){
|
|
MemPage *pOld = apCopy[i];
|
|
int limit = pOld->nCell+pOld->nOverflow;
|
|
for(j=0; j<limit; j++){
|
|
assert( nCell<nMaxCells );
|
|
apCell[nCell] = findOverflowCell(pOld, j);
|
|
szCell[nCell] = cellSizePtr(pOld, apCell[nCell]);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
int a;
|
|
aFrom[nCell] = i;
|
|
for(a=0; a<pOld->nOverflow; a++){
|
|
if( pOld->aOvfl[a].pCell==apCell[nCell] ){
|
|
aFrom[nCell] = 0xFF;
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
nCell++;
|
|
}
|
|
if( i<nOld-1 ){
|
|
int sz = cellSizePtr(pParent, apDiv[i]);
|
|
if( leafData ){
|
|
/* With the LEAFDATA flag, pParent cells hold only INTKEYs that
|
|
** are duplicates of keys on the child pages. We need to remove
|
|
** the divider cells from pParent, but the dividers cells are not
|
|
** added to apCell[] because they are duplicates of child cells.
|
|
*/
|
|
dropCell(pParent, nxDiv, sz);
|
|
}else{
|
|
u8 *pTemp;
|
|
assert( nCell<nMaxCells );
|
|
szCell[nCell] = sz;
|
|
pTemp = &aSpace[iSpace];
|
|
iSpace += sz;
|
|
assert( iSpace<=pBt->pageSize*5 );
|
|
memcpy(pTemp, apDiv[i], sz);
|
|
apCell[nCell] = pTemp+leafCorrection;
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
aFrom[nCell] = 0xFF;
|
|
}
|
|
#endif
|
|
dropCell(pParent, nxDiv, sz);
|
|
szCell[nCell] -= leafCorrection;
|
|
assert( get4byte(pTemp)==pgnoOld[i] );
|
|
if( !pOld->leaf ){
|
|
assert( leafCorrection==0 );
|
|
/* The right pointer of the child page pOld becomes the left
|
|
** pointer of the divider cell */
|
|
memcpy(apCell[nCell], &pOld->aData[pOld->hdrOffset+8], 4);
|
|
}else{
|
|
assert( leafCorrection==4 );
|
|
}
|
|
nCell++;
|
|
}
|
|
}
|
|
}
|
|
|
|
/*
|
|
** Figure out the number of pages needed to hold all nCell cells.
|
|
** Store this number in "k". Also compute szNew[] which is the total
|
|
** size of all cells on the i-th page and cntNew[] which is the index
|
|
** in apCell[] of the cell that divides page i from page i+1.
|
|
** cntNew[k] should equal nCell.
|
|
**
|
|
** Values computed by this block:
|
|
**
|
|
** k: The total number of sibling pages
|
|
** szNew[i]: Spaced used on the i-th sibling page.
|
|
** cntNew[i]: Index in apCell[] and szCell[] for the first cell to
|
|
** the right of the i-th sibling page.
|
|
** usableSpace: Number of bytes of space available on each sibling.
|
|
**
|
|
*/
|
|
usableSpace = pBt->usableSize - 12 + leafCorrection;
|
|
for(subtotal=k=i=0; i<nCell; i++){
|
|
assert( i<nMaxCells );
|
|
subtotal += szCell[i] + 2;
|
|
if( subtotal > usableSpace ){
|
|
szNew[k] = subtotal - szCell[i];
|
|
cntNew[k] = i;
|
|
if( leafData ){ i--; }
|
|
subtotal = 0;
|
|
k++;
|
|
}
|
|
}
|
|
szNew[k] = subtotal;
|
|
cntNew[k] = nCell;
|
|
k++;
|
|
|
|
/*
|
|
** The packing computed by the previous block is biased toward the siblings
|
|
** on the left side. The left siblings are always nearly full, while the
|
|
** right-most sibling might be nearly empty. This block of code attempts
|
|
** to adjust the packing of siblings to get a better balance.
|
|
**
|
|
** This adjustment is more than an optimization. The packing above might
|
|
** be so out of balance as to be illegal. For example, the right-most
|
|
** sibling might be completely empty. This adjustment is not optional.
|
|
*/
|
|
for(i=k-1; i>0; i--){
|
|
int szRight = szNew[i]; /* Size of sibling on the right */
|
|
int szLeft = szNew[i-1]; /* Size of sibling on the left */
|
|
int r; /* Index of right-most cell in left sibling */
|
|
int d; /* Index of first cell to the left of right sibling */
|
|
|
|
r = cntNew[i-1] - 1;
|
|
d = r + 1 - leafData;
|
|
assert( d<nMaxCells );
|
|
assert( r<nMaxCells );
|
|
while( szRight==0 || szRight+szCell[d]+2<=szLeft-(szCell[r]+2) ){
|
|
szRight += szCell[d] + 2;
|
|
szLeft -= szCell[r] + 2;
|
|
cntNew[i-1]--;
|
|
r = cntNew[i-1] - 1;
|
|
d = r + 1 - leafData;
|
|
}
|
|
szNew[i] = szRight;
|
|
szNew[i-1] = szLeft;
|
|
}
|
|
|
|
/* Either we found one or more cells (cntnew[0])>0) or we are the
|
|
** a virtual root page. A virtual root page is when the real root
|
|
** page is page 1 and we are the only child of that page.
|
|
*/
|
|
assert( cntNew[0]>0 || (pParent->pgno==1 && pParent->nCell==0) );
|
|
|
|
/*
|
|
** Allocate k new pages. Reuse old pages where possible.
|
|
*/
|
|
assert( pPage->pgno>1 );
|
|
pageFlags = pPage->aData[0];
|
|
for(i=0; i<k; i++){
|
|
MemPage *pNew;
|
|
if( i<nOld ){
|
|
pNew = apNew[i] = apOld[i];
|
|
pgnoNew[i] = pgnoOld[i];
|
|
apOld[i] = 0;
|
|
rc = sqlite3pager_write(pNew->aData);
|
|
if( rc ) goto balance_cleanup;
|
|
}else{
|
|
assert( i>0 );
|
|
rc = allocatePage(pBt, &pNew, &pgnoNew[i], pgnoNew[i-1], 0);
|
|
if( rc ) goto balance_cleanup;
|
|
apNew[i] = pNew;
|
|
}
|
|
nNew++;
|
|
zeroPage(pNew, pageFlags);
|
|
}
|
|
|
|
/* Free any old pages that were not reused as new pages.
|
|
*/
|
|
while( i<nOld ){
|
|
rc = freePage(apOld[i]);
|
|
if( rc ) goto balance_cleanup;
|
|
releasePage(apOld[i]);
|
|
apOld[i] = 0;
|
|
i++;
|
|
}
|
|
|
|
/*
|
|
** Put the new pages in accending order. This helps to
|
|
** keep entries in the disk file in order so that a scan
|
|
** of the table is a linear scan through the file. That
|
|
** in turn helps the operating system to deliver pages
|
|
** from the disk more rapidly.
|
|
**
|
|
** An O(n^2) insertion sort algorithm is used, but since
|
|
** n is never more than NB (a small constant), that should
|
|
** not be a problem.
|
|
**
|
|
** When NB==3, this one optimization makes the database
|
|
** about 25% faster for large insertions and deletions.
|
|
*/
|
|
for(i=0; i<k-1; i++){
|
|
int minV = pgnoNew[i];
|
|
int minI = i;
|
|
for(j=i+1; j<k; j++){
|
|
if( pgnoNew[j]<(unsigned)minV ){
|
|
minI = j;
|
|
minV = pgnoNew[j];
|
|
}
|
|
}
|
|
if( minI>i ){
|
|
int t;
|
|
MemPage *pT;
|
|
t = pgnoNew[i];
|
|
pT = apNew[i];
|
|
pgnoNew[i] = pgnoNew[minI];
|
|
apNew[i] = apNew[minI];
|
|
pgnoNew[minI] = t;
|
|
apNew[minI] = pT;
|
|
}
|
|
}
|
|
TRACE(("BALANCE: old: %d %d %d new: %d(%d) %d(%d) %d(%d) %d(%d) %d(%d)\n",
|
|
pgnoOld[0],
|
|
nOld>=2 ? pgnoOld[1] : 0,
|
|
nOld>=3 ? pgnoOld[2] : 0,
|
|
pgnoNew[0], szNew[0],
|
|
nNew>=2 ? pgnoNew[1] : 0, nNew>=2 ? szNew[1] : 0,
|
|
nNew>=3 ? pgnoNew[2] : 0, nNew>=3 ? szNew[2] : 0,
|
|
nNew>=4 ? pgnoNew[3] : 0, nNew>=4 ? szNew[3] : 0,
|
|
nNew>=5 ? pgnoNew[4] : 0, nNew>=5 ? szNew[4] : 0));
|
|
|
|
/*
|
|
** Evenly distribute the data in apCell[] across the new pages.
|
|
** Insert divider cells into pParent as necessary.
|
|
*/
|
|
j = 0;
|
|
for(i=0; i<nNew; i++){
|
|
/* Assemble the new sibling page. */
|
|
MemPage *pNew = apNew[i];
|
|
assert( j<nMaxCells );
|
|
assert( pNew->pgno==pgnoNew[i] );
|
|
assemblePage(pNew, cntNew[i]-j, &apCell[j], &szCell[j]);
|
|
assert( pNew->nCell>0 || (nNew==1 && cntNew[0]==0) );
|
|
assert( pNew->nOverflow==0 );
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/* If this is an auto-vacuum database, update the pointer map entries
|
|
** that point to the siblings that were rearranged. These can be: left
|
|
** children of cells, the right-child of the page, or overflow pages
|
|
** pointed to by cells.
|
|
*/
|
|
if( pBt->autoVacuum ){
|
|
for(k=j; k<cntNew[i]; k++){
|
|
assert( k<nMaxCells );
|
|
if( aFrom[k]==0xFF || apCopy[aFrom[k]]->pgno!=pNew->pgno ){
|
|
rc = ptrmapPutOvfl(pNew, k-j);
|
|
if( rc!=SQLITE_OK ){
|
|
goto balance_cleanup;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
|
|
j = cntNew[i];
|
|
|
|
/* If the sibling page assembled above was not the right-most sibling,
|
|
** insert a divider cell into the parent page.
|
|
*/
|
|
if( i<nNew-1 && j<nCell ){
|
|
u8 *pCell;
|
|
u8 *pTemp;
|
|
int sz;
|
|
|
|
assert( j<nMaxCells );
|
|
pCell = apCell[j];
|
|
sz = szCell[j] + leafCorrection;
|
|
if( !pNew->leaf ){
|
|
memcpy(&pNew->aData[8], pCell, 4);
|
|
pTemp = 0;
|
|
}else if( leafData ){
|
|
/* If the tree is a leaf-data tree, and the siblings are leaves,
|
|
** then there is no divider cell in apCell[]. Instead, the divider
|
|
** cell consists of the integer key for the right-most cell of
|
|
** the sibling-page assembled above only.
|
|
*/
|
|
CellInfo info;
|
|
j--;
|
|
parseCellPtr(pNew, apCell[j], &info);
|
|
pCell = &aSpace[iSpace];
|
|
fillInCell(pParent, pCell, 0, info.nKey, 0, 0, &sz);
|
|
iSpace += sz;
|
|
assert( iSpace<=pBt->pageSize*5 );
|
|
pTemp = 0;
|
|
}else{
|
|
pCell -= 4;
|
|
pTemp = &aSpace[iSpace];
|
|
iSpace += sz;
|
|
assert( iSpace<=pBt->pageSize*5 );
|
|
}
|
|
rc = insertCell(pParent, nxDiv, pCell, sz, pTemp, 4);
|
|
if( rc!=SQLITE_OK ) goto balance_cleanup;
|
|
put4byte(findOverflowCell(pParent,nxDiv), pNew->pgno);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/* If this is an auto-vacuum database, and not a leaf-data tree,
|
|
** then update the pointer map with an entry for the overflow page
|
|
** that the cell just inserted points to (if any).
|
|
*/
|
|
if( pBt->autoVacuum && !leafData ){
|
|
rc = ptrmapPutOvfl(pParent, nxDiv);
|
|
if( rc!=SQLITE_OK ){
|
|
goto balance_cleanup;
|
|
}
|
|
}
|
|
#endif
|
|
j++;
|
|
nxDiv++;
|
|
}
|
|
}
|
|
assert( j==nCell );
|
|
assert( nOld>0 );
|
|
assert( nNew>0 );
|
|
if( (pageFlags & PTF_LEAF)==0 ){
|
|
memcpy(&apNew[nNew-1]->aData[8], &apCopy[nOld-1]->aData[8], 4);
|
|
}
|
|
if( nxDiv==pParent->nCell+pParent->nOverflow ){
|
|
/* Right-most sibling is the right-most child of pParent */
|
|
put4byte(&pParent->aData[pParent->hdrOffset+8], pgnoNew[nNew-1]);
|
|
}else{
|
|
/* Right-most sibling is the left child of the first entry in pParent
|
|
** past the right-most divider entry */
|
|
put4byte(findOverflowCell(pParent, nxDiv), pgnoNew[nNew-1]);
|
|
}
|
|
|
|
/*
|
|
** Reparent children of all cells.
|
|
*/
|
|
for(i=0; i<nNew; i++){
|
|
rc = reparentChildPages(apNew[i]);
|
|
if( rc!=SQLITE_OK ) goto balance_cleanup;
|
|
}
|
|
rc = reparentChildPages(pParent);
|
|
if( rc!=SQLITE_OK ) goto balance_cleanup;
|
|
|
|
/*
|
|
** Balance the parent page. Note that the current page (pPage) might
|
|
** have been added to the freelist so it might no longer be initialized.
|
|
** But the parent page will always be initialized.
|
|
*/
|
|
assert( pParent->isInit );
|
|
/* assert( pPage->isInit ); // No! pPage might have been added to freelist */
|
|
/* pageIntegrity(pPage); // No! pPage might have been added to freelist */
|
|
rc = balance(pParent, 0);
|
|
|
|
/*
|
|
** Cleanup before returning.
|
|
*/
|
|
balance_cleanup:
|
|
sqliteFree(apCell);
|
|
for(i=0; i<nOld; i++){
|
|
releasePage(apOld[i]);
|
|
}
|
|
for(i=0; i<nNew; i++){
|
|
releasePage(apNew[i]);
|
|
}
|
|
releasePage(pParent);
|
|
TRACE(("BALANCE: finished with %d: old=%d new=%d cells=%d\n",
|
|
pPage->pgno, nOld, nNew, nCell));
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** This routine is called for the root page of a btree when the root
|
|
** page contains no cells. This is an opportunity to make the tree
|
|
** shallower by one level.
|
|
*/
|
|
static int balance_shallower(MemPage *pPage){
|
|
MemPage *pChild; /* The only child page of pPage */
|
|
Pgno pgnoChild; /* Page number for pChild */
|
|
int rc = SQLITE_OK; /* Return code from subprocedures */
|
|
BtShared *pBt; /* The main BTree structure */
|
|
int mxCellPerPage; /* Maximum number of cells per page */
|
|
u8 **apCell; /* All cells from pages being balanced */
|
|
int *szCell; /* Local size of all cells */
|
|
|
|
assert( pPage->pParent==0 );
|
|
assert( pPage->nCell==0 );
|
|
pBt = pPage->pBt;
|
|
mxCellPerPage = MX_CELL(pBt);
|
|
apCell = sqliteMallocRaw( mxCellPerPage*(sizeof(u8*)+sizeof(int)) );
|
|
if( apCell==0 ) return SQLITE_NOMEM;
|
|
szCell = (int*)&apCell[mxCellPerPage];
|
|
if( pPage->leaf ){
|
|
/* The table is completely empty */
|
|
TRACE(("BALANCE: empty table %d\n", pPage->pgno));
|
|
}else{
|
|
/* The root page is empty but has one child. Transfer the
|
|
** information from that one child into the root page if it
|
|
** will fit. This reduces the depth of the tree by one.
|
|
**
|
|
** If the root page is page 1, it has less space available than
|
|
** its child (due to the 100 byte header that occurs at the beginning
|
|
** of the database fle), so it might not be able to hold all of the
|
|
** information currently contained in the child. If this is the
|
|
** case, then do not do the transfer. Leave page 1 empty except
|
|
** for the right-pointer to the child page. The child page becomes
|
|
** the virtual root of the tree.
|
|
*/
|
|
pgnoChild = get4byte(&pPage->aData[pPage->hdrOffset+8]);
|
|
assert( pgnoChild>0 );
|
|
assert( pgnoChild<=sqlite3pager_pagecount(pPage->pBt->pPager) );
|
|
rc = getPage(pPage->pBt, pgnoChild, &pChild);
|
|
if( rc ) goto end_shallow_balance;
|
|
if( pPage->pgno==1 ){
|
|
rc = initPage(pChild, pPage);
|
|
if( rc ) goto end_shallow_balance;
|
|
assert( pChild->nOverflow==0 );
|
|
if( pChild->nFree>=100 ){
|
|
/* The child information will fit on the root page, so do the
|
|
** copy */
|
|
int i;
|
|
zeroPage(pPage, pChild->aData[0]);
|
|
for(i=0; i<pChild->nCell; i++){
|
|
apCell[i] = findCell(pChild,i);
|
|
szCell[i] = cellSizePtr(pChild, apCell[i]);
|
|
}
|
|
assemblePage(pPage, pChild->nCell, apCell, szCell);
|
|
/* Copy the right-pointer of the child to the parent. */
|
|
put4byte(&pPage->aData[pPage->hdrOffset+8],
|
|
get4byte(&pChild->aData[pChild->hdrOffset+8]));
|
|
freePage(pChild);
|
|
TRACE(("BALANCE: child %d transfer to page 1\n", pChild->pgno));
|
|
}else{
|
|
/* The child has more information that will fit on the root.
|
|
** The tree is already balanced. Do nothing. */
|
|
TRACE(("BALANCE: child %d will not fit on page 1\n", pChild->pgno));
|
|
}
|
|
}else{
|
|
memcpy(pPage->aData, pChild->aData, pPage->pBt->usableSize);
|
|
pPage->isInit = 0;
|
|
pPage->pParent = 0;
|
|
rc = initPage(pPage, 0);
|
|
assert( rc==SQLITE_OK );
|
|
freePage(pChild);
|
|
TRACE(("BALANCE: transfer child %d into root %d\n",
|
|
pChild->pgno, pPage->pgno));
|
|
}
|
|
rc = reparentChildPages(pPage);
|
|
assert( pPage->nOverflow==0 );
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
int i;
|
|
for(i=0; i<pPage->nCell; i++){
|
|
rc = ptrmapPutOvfl(pPage, i);
|
|
if( rc!=SQLITE_OK ){
|
|
goto end_shallow_balance;
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
if( rc!=SQLITE_OK ) goto end_shallow_balance;
|
|
releasePage(pChild);
|
|
}
|
|
end_shallow_balance:
|
|
sqliteFree(apCell);
|
|
return rc;
|
|
}
|
|
|
|
|
|
/*
|
|
** The root page is overfull
|
|
**
|
|
** When this happens, Create a new child page and copy the
|
|
** contents of the root into the child. Then make the root
|
|
** page an empty page with rightChild pointing to the new
|
|
** child. Finally, call balance_internal() on the new child
|
|
** to cause it to split.
|
|
*/
|
|
static int balance_deeper(MemPage *pPage){
|
|
int rc; /* Return value from subprocedures */
|
|
MemPage *pChild; /* Pointer to a new child page */
|
|
Pgno pgnoChild; /* Page number of the new child page */
|
|
BtShared *pBt; /* The BTree */
|
|
int usableSize; /* Total usable size of a page */
|
|
u8 *data; /* Content of the parent page */
|
|
u8 *cdata; /* Content of the child page */
|
|
int hdr; /* Offset to page header in parent */
|
|
int brk; /* Offset to content of first cell in parent */
|
|
|
|
assert( pPage->pParent==0 );
|
|
assert( pPage->nOverflow>0 );
|
|
pBt = pPage->pBt;
|
|
rc = allocatePage(pBt, &pChild, &pgnoChild, pPage->pgno, 0);
|
|
if( rc ) return rc;
|
|
assert( sqlite3pager_iswriteable(pChild->aData) );
|
|
usableSize = pBt->usableSize;
|
|
data = pPage->aData;
|
|
hdr = pPage->hdrOffset;
|
|
brk = get2byte(&data[hdr+5]);
|
|
cdata = pChild->aData;
|
|
memcpy(cdata, &data[hdr], pPage->cellOffset+2*pPage->nCell-hdr);
|
|
memcpy(&cdata[brk], &data[brk], usableSize-brk);
|
|
assert( pChild->isInit==0 );
|
|
rc = initPage(pChild, pPage);
|
|
if( rc ) goto balancedeeper_out;
|
|
memcpy(pChild->aOvfl, pPage->aOvfl, pPage->nOverflow*sizeof(pPage->aOvfl[0]));
|
|
pChild->nOverflow = pPage->nOverflow;
|
|
if( pChild->nOverflow ){
|
|
pChild->nFree = 0;
|
|
}
|
|
assert( pChild->nCell==pPage->nCell );
|
|
zeroPage(pPage, pChild->aData[0] & ~PTF_LEAF);
|
|
put4byte(&pPage->aData[pPage->hdrOffset+8], pgnoChild);
|
|
TRACE(("BALANCE: copy root %d into %d\n", pPage->pgno, pChild->pgno));
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
int i;
|
|
rc = ptrmapPut(pBt, pChild->pgno, PTRMAP_BTREE, pPage->pgno);
|
|
if( rc ) goto balancedeeper_out;
|
|
for(i=0; i<pChild->nCell; i++){
|
|
rc = ptrmapPutOvfl(pChild, i);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
}
|
|
}
|
|
#endif
|
|
rc = balance_nonroot(pChild);
|
|
|
|
balancedeeper_out:
|
|
releasePage(pChild);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Decide if the page pPage needs to be balanced. If balancing is
|
|
** required, call the appropriate balancing routine.
|
|
*/
|
|
static int balance(MemPage *pPage, int insert){
|
|
int rc = SQLITE_OK;
|
|
if( pPage->pParent==0 ){
|
|
if( pPage->nOverflow>0 ){
|
|
rc = balance_deeper(pPage);
|
|
}
|
|
if( rc==SQLITE_OK && pPage->nCell==0 ){
|
|
rc = balance_shallower(pPage);
|
|
}
|
|
}else{
|
|
if( pPage->nOverflow>0 ||
|
|
(!insert && pPage->nFree>pPage->pBt->usableSize*2/3) ){
|
|
rc = balance_nonroot(pPage);
|
|
}
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** This routine checks all cursors that point to table pgnoRoot.
|
|
** If any of those cursors other than pExclude were opened with
|
|
** wrFlag==0 then this routine returns SQLITE_LOCKED. If all
|
|
** cursors that point to pgnoRoot were opened with wrFlag==1
|
|
** then this routine returns SQLITE_OK.
|
|
**
|
|
** In addition to checking for read-locks (where a read-lock
|
|
** means a cursor opened with wrFlag==0) this routine also moves
|
|
** all cursors other than pExclude so that they are pointing to the
|
|
** first Cell on root page. This is necessary because an insert
|
|
** or delete might change the number of cells on a page or delete
|
|
** a page entirely and we do not want to leave any cursors
|
|
** pointing to non-existant pages or cells.
|
|
*/
|
|
static int checkReadLocks(BtShared *pBt, Pgno pgnoRoot, BtCursor *pExclude){
|
|
BtCursor *p;
|
|
for(p=pBt->pCursor; p; p=p->pNext){
|
|
u32 flags = (p->pBtree->pSqlite ? p->pBtree->pSqlite->flags : 0);
|
|
if( p->pgnoRoot!=pgnoRoot || p==pExclude ) continue;
|
|
if( p->wrFlag==0 && flags&SQLITE_ReadUncommitted ) continue;
|
|
if( p->wrFlag==0 ) return SQLITE_LOCKED;
|
|
if( p->pPage->pgno!=p->pgnoRoot ){
|
|
moveToRoot(p);
|
|
}
|
|
}
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Insert a new record into the BTree. The key is given by (pKey,nKey)
|
|
** and the data is given by (pData,nData). The cursor is used only to
|
|
** define what table the record should be inserted into. The cursor
|
|
** is left pointing at a random location.
|
|
**
|
|
** For an INTKEY table, only the nKey value of the key is used. pKey is
|
|
** ignored. For a ZERODATA table, the pData and nData are both ignored.
|
|
*/
|
|
int sqlite3BtreeInsert(
|
|
BtCursor *pCur, /* Insert data into the table of this cursor */
|
|
const void *pKey, i64 nKey, /* The key of the new record */
|
|
const void *pData, int nData /* The data of the new record */
|
|
){
|
|
int rc;
|
|
int loc;
|
|
int szNew;
|
|
MemPage *pPage;
|
|
BtShared *pBt = pCur->pBtree->pBt;
|
|
unsigned char *oldCell;
|
|
unsigned char *newCell = 0;
|
|
|
|
if( pBt->inTransaction!=TRANS_WRITE ){
|
|
/* Must start a transaction before doing an insert */
|
|
return pBt->readOnly ? SQLITE_READONLY : SQLITE_ERROR;
|
|
}
|
|
assert( !pBt->readOnly );
|
|
if( !pCur->wrFlag ){
|
|
return SQLITE_PERM; /* Cursor not open for writing */
|
|
}
|
|
if( checkReadLocks(pBt, pCur->pgnoRoot, pCur) ){
|
|
return SQLITE_LOCKED; /* The table pCur points to has a read lock */
|
|
}
|
|
|
|
/* Save the positions of any other cursors open on this table */
|
|
restoreOrClearCursorPosition(pCur, 0);
|
|
if(
|
|
SQLITE_OK!=(rc = saveAllCursors(pBt, pCur->pgnoRoot, pCur)) ||
|
|
SQLITE_OK!=(rc = sqlite3BtreeMoveto(pCur, pKey, nKey, &loc))
|
|
){
|
|
return rc;
|
|
}
|
|
|
|
pPage = pCur->pPage;
|
|
assert( pPage->intKey || nKey>=0 );
|
|
assert( pPage->leaf || !pPage->leafData );
|
|
TRACE(("INSERT: table=%d nkey=%lld ndata=%d page=%d %s\n",
|
|
pCur->pgnoRoot, nKey, nData, pPage->pgno,
|
|
loc==0 ? "overwrite" : "new entry"));
|
|
assert( pPage->isInit );
|
|
rc = sqlite3pager_write(pPage->aData);
|
|
if( rc ) return rc;
|
|
newCell = sqliteMallocRaw( MX_CELL_SIZE(pBt) );
|
|
if( newCell==0 ) return SQLITE_NOMEM;
|
|
rc = fillInCell(pPage, newCell, pKey, nKey, pData, nData, &szNew);
|
|
if( rc ) goto end_insert;
|
|
assert( szNew==cellSizePtr(pPage, newCell) );
|
|
assert( szNew<=MX_CELL_SIZE(pBt) );
|
|
if( loc==0 && CURSOR_VALID==pCur->eState ){
|
|
int szOld;
|
|
assert( pCur->idx>=0 && pCur->idx<pPage->nCell );
|
|
oldCell = findCell(pPage, pCur->idx);
|
|
if( !pPage->leaf ){
|
|
memcpy(newCell, oldCell, 4);
|
|
}
|
|
szOld = cellSizePtr(pPage, oldCell);
|
|
rc = clearCell(pPage, oldCell);
|
|
if( rc ) goto end_insert;
|
|
dropCell(pPage, pCur->idx, szOld);
|
|
}else if( loc<0 && pPage->nCell>0 ){
|
|
assert( pPage->leaf );
|
|
pCur->idx++;
|
|
pCur->info.nSize = 0;
|
|
}else{
|
|
assert( pPage->leaf );
|
|
}
|
|
rc = insertCell(pPage, pCur->idx, newCell, szNew, 0, 0);
|
|
if( rc!=SQLITE_OK ) goto end_insert;
|
|
rc = balance(pPage, 1);
|
|
/* sqlite3BtreePageDump(pCur->pBt, pCur->pgnoRoot, 1); */
|
|
/* fflush(stdout); */
|
|
if( rc==SQLITE_OK ){
|
|
moveToRoot(pCur);
|
|
}
|
|
end_insert:
|
|
sqliteFree(newCell);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Delete the entry that the cursor is pointing to. The cursor
|
|
** is left pointing at a random location.
|
|
*/
|
|
int sqlite3BtreeDelete(BtCursor *pCur){
|
|
MemPage *pPage = pCur->pPage;
|
|
unsigned char *pCell;
|
|
int rc;
|
|
Pgno pgnoChild = 0;
|
|
BtShared *pBt = pCur->pBtree->pBt;
|
|
|
|
assert( pPage->isInit );
|
|
if( pBt->inTransaction!=TRANS_WRITE ){
|
|
/* Must start a transaction before doing a delete */
|
|
return pBt->readOnly ? SQLITE_READONLY : SQLITE_ERROR;
|
|
}
|
|
assert( !pBt->readOnly );
|
|
if( pCur->idx >= pPage->nCell ){
|
|
return SQLITE_ERROR; /* The cursor is not pointing to anything */
|
|
}
|
|
if( !pCur->wrFlag ){
|
|
return SQLITE_PERM; /* Did not open this cursor for writing */
|
|
}
|
|
if( checkReadLocks(pBt, pCur->pgnoRoot, pCur) ){
|
|
return SQLITE_LOCKED; /* The table pCur points to has a read lock */
|
|
}
|
|
|
|
/* Restore the current cursor position (a no-op if the cursor is not in
|
|
** CURSOR_REQUIRESEEK state) and save the positions of any other cursors
|
|
** open on the same table. Then call sqlite3pager_write() on the page
|
|
** that the entry will be deleted from.
|
|
*/
|
|
if(
|
|
(rc = restoreOrClearCursorPosition(pCur, 1))!=0 ||
|
|
(rc = saveAllCursors(pBt, pCur->pgnoRoot, pCur))!=0 ||
|
|
(rc = sqlite3pager_write(pPage->aData))!=0
|
|
){
|
|
return rc;
|
|
}
|
|
|
|
/* Locate the cell within it's page and leave pCell pointing to the
|
|
** data. The clearCell() call frees any overflow pages associated with the
|
|
** cell. The cell itself is still intact.
|
|
*/
|
|
pCell = findCell(pPage, pCur->idx);
|
|
if( !pPage->leaf ){
|
|
pgnoChild = get4byte(pCell);
|
|
}
|
|
rc = clearCell(pPage, pCell);
|
|
if( rc ) return rc;
|
|
|
|
if( !pPage->leaf ){
|
|
/*
|
|
** The entry we are about to delete is not a leaf so if we do not
|
|
** do something we will leave a hole on an internal page.
|
|
** We have to fill the hole by moving in a cell from a leaf. The
|
|
** next Cell after the one to be deleted is guaranteed to exist and
|
|
** to be a leaf so we can use it.
|
|
*/
|
|
BtCursor leafCur;
|
|
unsigned char *pNext;
|
|
int szNext = 0; /* The compiler warning is wrong: szNext is always
|
|
** initialized before use. Adding an extra initialization
|
|
** to silence the compiler slows down the code. */
|
|
int notUsed;
|
|
unsigned char *tempCell = 0;
|
|
assert( !pPage->leafData );
|
|
getTempCursor(pCur, &leafCur);
|
|
rc = sqlite3BtreeNext(&leafCur, ¬Used);
|
|
if( rc!=SQLITE_OK ){
|
|
if( rc!=SQLITE_NOMEM ){
|
|
rc = SQLITE_CORRUPT_BKPT;
|
|
}
|
|
}
|
|
if( rc==SQLITE_OK ){
|
|
rc = sqlite3pager_write(leafCur.pPage->aData);
|
|
}
|
|
if( rc==SQLITE_OK ){
|
|
TRACE(("DELETE: table=%d delete internal from %d replace from leaf %d\n",
|
|
pCur->pgnoRoot, pPage->pgno, leafCur.pPage->pgno));
|
|
dropCell(pPage, pCur->idx, cellSizePtr(pPage, pCell));
|
|
pNext = findCell(leafCur.pPage, leafCur.idx);
|
|
szNext = cellSizePtr(leafCur.pPage, pNext);
|
|
assert( MX_CELL_SIZE(pBt)>=szNext+4 );
|
|
tempCell = sqliteMallocRaw( MX_CELL_SIZE(pBt) );
|
|
if( tempCell==0 ){
|
|
rc = SQLITE_NOMEM;
|
|
}
|
|
}
|
|
if( rc==SQLITE_OK ){
|
|
rc = insertCell(pPage, pCur->idx, pNext-4, szNext+4, tempCell, 0);
|
|
}
|
|
if( rc==SQLITE_OK ){
|
|
put4byte(findOverflowCell(pPage, pCur->idx), pgnoChild);
|
|
rc = balance(pPage, 0);
|
|
}
|
|
if( rc==SQLITE_OK ){
|
|
dropCell(leafCur.pPage, leafCur.idx, szNext);
|
|
rc = balance(leafCur.pPage, 0);
|
|
}
|
|
sqliteFree(tempCell);
|
|
releaseTempCursor(&leafCur);
|
|
}else{
|
|
TRACE(("DELETE: table=%d delete from leaf %d\n",
|
|
pCur->pgnoRoot, pPage->pgno));
|
|
dropCell(pPage, pCur->idx, cellSizePtr(pPage, pCell));
|
|
rc = balance(pPage, 0);
|
|
}
|
|
if( rc==SQLITE_OK ){
|
|
moveToRoot(pCur);
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Create a new BTree table. Write into *piTable the page
|
|
** number for the root page of the new table.
|
|
**
|
|
** The type of type is determined by the flags parameter. Only the
|
|
** following values of flags are currently in use. Other values for
|
|
** flags might not work:
|
|
**
|
|
** BTREE_INTKEY|BTREE_LEAFDATA Used for SQL tables with rowid keys
|
|
** BTREE_ZERODATA Used for SQL indices
|
|
*/
|
|
int sqlite3BtreeCreateTable(Btree *p, int *piTable, int flags){
|
|
BtShared *pBt = p->pBt;
|
|
MemPage *pRoot;
|
|
Pgno pgnoRoot;
|
|
int rc;
|
|
if( pBt->inTransaction!=TRANS_WRITE ){
|
|
/* Must start a transaction first */
|
|
return pBt->readOnly ? SQLITE_READONLY : SQLITE_ERROR;
|
|
}
|
|
assert( !pBt->readOnly );
|
|
|
|
/* It is illegal to create a table if any cursors are open on the
|
|
** database. This is because in auto-vacuum mode the backend may
|
|
** need to move a database page to make room for the new root-page.
|
|
** If an open cursor was using the page a problem would occur.
|
|
*/
|
|
if( pBt->pCursor ){
|
|
return SQLITE_LOCKED;
|
|
}
|
|
|
|
#ifdef SQLITE_OMIT_AUTOVACUUM
|
|
rc = allocatePage(pBt, &pRoot, &pgnoRoot, 1, 0);
|
|
if( rc ) return rc;
|
|
#else
|
|
if( pBt->autoVacuum ){
|
|
Pgno pgnoMove; /* Move a page here to make room for the root-page */
|
|
MemPage *pPageMove; /* The page to move to. */
|
|
|
|
/* Read the value of meta[3] from the database to determine where the
|
|
** root page of the new table should go. meta[3] is the largest root-page
|
|
** created so far, so the new root-page is (meta[3]+1).
|
|
*/
|
|
rc = sqlite3BtreeGetMeta(p, 4, &pgnoRoot);
|
|
if( rc!=SQLITE_OK ) return rc;
|
|
pgnoRoot++;
|
|
|
|
/* The new root-page may not be allocated on a pointer-map page, or the
|
|
** PENDING_BYTE page.
|
|
*/
|
|
if( pgnoRoot==PTRMAP_PAGENO(pBt, pgnoRoot) ||
|
|
pgnoRoot==PENDING_BYTE_PAGE(pBt) ){
|
|
pgnoRoot++;
|
|
}
|
|
assert( pgnoRoot>=3 );
|
|
|
|
/* Allocate a page. The page that currently resides at pgnoRoot will
|
|
** be moved to the allocated page (unless the allocated page happens
|
|
** to reside at pgnoRoot).
|
|
*/
|
|
rc = allocatePage(pBt, &pPageMove, &pgnoMove, pgnoRoot, 1);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
|
|
if( pgnoMove!=pgnoRoot ){
|
|
u8 eType;
|
|
Pgno iPtrPage;
|
|
|
|
releasePage(pPageMove);
|
|
rc = getPage(pBt, pgnoRoot, &pRoot);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
rc = ptrmapGet(pBt, pgnoRoot, &eType, &iPtrPage);
|
|
if( rc!=SQLITE_OK || eType==PTRMAP_ROOTPAGE || eType==PTRMAP_FREEPAGE ){
|
|
releasePage(pRoot);
|
|
return rc;
|
|
}
|
|
assert( eType!=PTRMAP_ROOTPAGE );
|
|
assert( eType!=PTRMAP_FREEPAGE );
|
|
rc = sqlite3pager_write(pRoot->aData);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(pRoot);
|
|
return rc;
|
|
}
|
|
rc = relocatePage(pBt, pRoot, eType, iPtrPage, pgnoMove);
|
|
releasePage(pRoot);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
rc = getPage(pBt, pgnoRoot, &pRoot);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
rc = sqlite3pager_write(pRoot->aData);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(pRoot);
|
|
return rc;
|
|
}
|
|
}else{
|
|
pRoot = pPageMove;
|
|
}
|
|
|
|
/* Update the pointer-map and meta-data with the new root-page number. */
|
|
rc = ptrmapPut(pBt, pgnoRoot, PTRMAP_ROOTPAGE, 0);
|
|
if( rc ){
|
|
releasePage(pRoot);
|
|
return rc;
|
|
}
|
|
rc = sqlite3BtreeUpdateMeta(p, 4, pgnoRoot);
|
|
if( rc ){
|
|
releasePage(pRoot);
|
|
return rc;
|
|
}
|
|
|
|
}else{
|
|
rc = allocatePage(pBt, &pRoot, &pgnoRoot, 1, 0);
|
|
if( rc ) return rc;
|
|
}
|
|
#endif
|
|
assert( sqlite3pager_iswriteable(pRoot->aData) );
|
|
zeroPage(pRoot, flags | PTF_LEAF);
|
|
sqlite3pager_unref(pRoot->aData);
|
|
*piTable = (int)pgnoRoot;
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Erase the given database page and all its children. Return
|
|
** the page to the freelist.
|
|
*/
|
|
static int clearDatabasePage(
|
|
BtShared *pBt, /* The BTree that contains the table */
|
|
Pgno pgno, /* Page number to clear */
|
|
MemPage *pParent, /* Parent page. NULL for the root */
|
|
int freePageFlag /* Deallocate page if true */
|
|
){
|
|
MemPage *pPage = 0;
|
|
int rc;
|
|
unsigned char *pCell;
|
|
int i;
|
|
|
|
if( pgno>(Pgno)sqlite3pager_pagecount(pBt->pPager) ){
|
|
return SQLITE_CORRUPT_BKPT;
|
|
}
|
|
|
|
rc = getAndInitPage(pBt, pgno, &pPage, pParent);
|
|
if( rc ) goto cleardatabasepage_out;
|
|
rc = sqlite3pager_write(pPage->aData);
|
|
if( rc ) goto cleardatabasepage_out;
|
|
for(i=0; i<pPage->nCell; i++){
|
|
pCell = findCell(pPage, i);
|
|
if( !pPage->leaf ){
|
|
rc = clearDatabasePage(pBt, get4byte(pCell), pPage->pParent, 1);
|
|
if( rc ) goto cleardatabasepage_out;
|
|
}
|
|
rc = clearCell(pPage, pCell);
|
|
if( rc ) goto cleardatabasepage_out;
|
|
}
|
|
if( !pPage->leaf ){
|
|
rc = clearDatabasePage(pBt, get4byte(&pPage->aData[8]), pPage->pParent, 1);
|
|
if( rc ) goto cleardatabasepage_out;
|
|
}
|
|
if( freePageFlag ){
|
|
rc = freePage(pPage);
|
|
}else{
|
|
zeroPage(pPage, pPage->aData[0] | PTF_LEAF);
|
|
}
|
|
|
|
cleardatabasepage_out:
|
|
releasePage(pPage);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Delete all information from a single table in the database. iTable is
|
|
** the page number of the root of the table. After this routine returns,
|
|
** the root page is empty, but still exists.
|
|
**
|
|
** This routine will fail with SQLITE_LOCKED if there are any open
|
|
** read cursors on the table. Open write cursors are moved to the
|
|
** root of the table.
|
|
*/
|
|
int sqlite3BtreeClearTable(Btree *p, int iTable){
|
|
int rc;
|
|
BtCursor *pCur;
|
|
BtShared *pBt = p->pBt;
|
|
sqlite3 *db = p->pSqlite;
|
|
if( p->inTrans!=TRANS_WRITE ){
|
|
return pBt->readOnly ? SQLITE_READONLY : SQLITE_ERROR;
|
|
}
|
|
|
|
/* If this connection is not in read-uncommitted mode and currently has
|
|
** a read-cursor open on the table being cleared, return SQLITE_LOCKED.
|
|
*/
|
|
if( 0==db || 0==(db->flags&SQLITE_ReadUncommitted) ){
|
|
for(pCur=pBt->pCursor; pCur; pCur=pCur->pNext){
|
|
if( pCur->pBtree==p && pCur->pgnoRoot==(Pgno)iTable ){
|
|
if( 0==pCur->wrFlag ){
|
|
return SQLITE_LOCKED;
|
|
}
|
|
moveToRoot(pCur);
|
|
}
|
|
}
|
|
}
|
|
|
|
/* Save the position of all cursors open on this table */
|
|
if( SQLITE_OK!=(rc = saveAllCursors(pBt, iTable, 0)) ){
|
|
return rc;
|
|
}
|
|
|
|
return clearDatabasePage(pBt, (Pgno)iTable, 0, 0);
|
|
}
|
|
|
|
/*
|
|
** Erase all information in a table and add the root of the table to
|
|
** the freelist. Except, the root of the principle table (the one on
|
|
** page 1) is never added to the freelist.
|
|
**
|
|
** This routine will fail with SQLITE_LOCKED if there are any open
|
|
** cursors on the table.
|
|
**
|
|
** If AUTOVACUUM is enabled and the page at iTable is not the last
|
|
** root page in the database file, then the last root page
|
|
** in the database file is moved into the slot formerly occupied by
|
|
** iTable and that last slot formerly occupied by the last root page
|
|
** is added to the freelist instead of iTable. In this say, all
|
|
** root pages are kept at the beginning of the database file, which
|
|
** is necessary for AUTOVACUUM to work right. *piMoved is set to the
|
|
** page number that used to be the last root page in the file before
|
|
** the move. If no page gets moved, *piMoved is set to 0.
|
|
** The last root page is recorded in meta[3] and the value of
|
|
** meta[3] is updated by this procedure.
|
|
*/
|
|
int sqlite3BtreeDropTable(Btree *p, int iTable, int *piMoved){
|
|
int rc;
|
|
MemPage *pPage = 0;
|
|
BtShared *pBt = p->pBt;
|
|
|
|
if( p->inTrans!=TRANS_WRITE ){
|
|
return pBt->readOnly ? SQLITE_READONLY : SQLITE_ERROR;
|
|
}
|
|
|
|
/* It is illegal to drop a table if any cursors are open on the
|
|
** database. This is because in auto-vacuum mode the backend may
|
|
** need to move another root-page to fill a gap left by the deleted
|
|
** root page. If an open cursor was using this page a problem would
|
|
** occur.
|
|
*/
|
|
if( pBt->pCursor ){
|
|
return SQLITE_LOCKED;
|
|
}
|
|
|
|
rc = getPage(pBt, (Pgno)iTable, &pPage);
|
|
if( rc ) return rc;
|
|
rc = sqlite3BtreeClearTable(p, iTable);
|
|
if( rc ){
|
|
releasePage(pPage);
|
|
return rc;
|
|
}
|
|
|
|
*piMoved = 0;
|
|
|
|
if( iTable>1 ){
|
|
#ifdef SQLITE_OMIT_AUTOVACUUM
|
|
rc = freePage(pPage);
|
|
releasePage(pPage);
|
|
#else
|
|
if( pBt->autoVacuum ){
|
|
Pgno maxRootPgno;
|
|
rc = sqlite3BtreeGetMeta(p, 4, &maxRootPgno);
|
|
if( rc!=SQLITE_OK ){
|
|
releasePage(pPage);
|
|
return rc;
|
|
}
|
|
|
|
if( iTable==maxRootPgno ){
|
|
/* If the table being dropped is the table with the largest root-page
|
|
** number in the database, put the root page on the free list.
|
|
*/
|
|
rc = freePage(pPage);
|
|
releasePage(pPage);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
}else{
|
|
/* The table being dropped does not have the largest root-page
|
|
** number in the database. So move the page that does into the
|
|
** gap left by the deleted root-page.
|
|
*/
|
|
MemPage *pMove;
|
|
releasePage(pPage);
|
|
rc = getPage(pBt, maxRootPgno, &pMove);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
rc = relocatePage(pBt, pMove, PTRMAP_ROOTPAGE, 0, iTable);
|
|
releasePage(pMove);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
rc = getPage(pBt, maxRootPgno, &pMove);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
rc = freePage(pMove);
|
|
releasePage(pMove);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
*piMoved = maxRootPgno;
|
|
}
|
|
|
|
/* Set the new 'max-root-page' value in the database header. This
|
|
** is the old value less one, less one more if that happens to
|
|
** be a root-page number, less one again if that is the
|
|
** PENDING_BYTE_PAGE.
|
|
*/
|
|
maxRootPgno--;
|
|
if( maxRootPgno==PENDING_BYTE_PAGE(pBt) ){
|
|
maxRootPgno--;
|
|
}
|
|
if( maxRootPgno==PTRMAP_PAGENO(pBt, maxRootPgno) ){
|
|
maxRootPgno--;
|
|
}
|
|
assert( maxRootPgno!=PENDING_BYTE_PAGE(pBt) );
|
|
|
|
rc = sqlite3BtreeUpdateMeta(p, 4, maxRootPgno);
|
|
}else{
|
|
rc = freePage(pPage);
|
|
releasePage(pPage);
|
|
}
|
|
#endif
|
|
}else{
|
|
/* If sqlite3BtreeDropTable was called on page 1. */
|
|
zeroPage(pPage, PTF_INTKEY|PTF_LEAF );
|
|
releasePage(pPage);
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
|
|
/*
|
|
** Read the meta-information out of a database file. Meta[0]
|
|
** is the number of free pages currently in the database. Meta[1]
|
|
** through meta[15] are available for use by higher layers. Meta[0]
|
|
** is read-only, the others are read/write.
|
|
**
|
|
** The schema layer numbers meta values differently. At the schema
|
|
** layer (and the SetCookie and ReadCookie opcodes) the number of
|
|
** free pages is not visible. So Cookie[0] is the same as Meta[1].
|
|
*/
|
|
int sqlite3BtreeGetMeta(Btree *p, int idx, u32 *pMeta){
|
|
int rc;
|
|
unsigned char *pP1;
|
|
BtShared *pBt = p->pBt;
|
|
|
|
/* Reading a meta-data value requires a read-lock on page 1 (and hence
|
|
** the sqlite_master table. We grab this lock regardless of whether or
|
|
** not the SQLITE_ReadUncommitted flag is set (the table rooted at page
|
|
** 1 is treated as a special case by queryTableLock() and lockTable()).
|
|
*/
|
|
rc = queryTableLock(p, 1, READ_LOCK);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
|
|
assert( idx>=0 && idx<=15 );
|
|
rc = sqlite3pager_get(pBt->pPager, 1, (void**)&pP1);
|
|
if( rc ) return rc;
|
|
*pMeta = get4byte(&pP1[36 + idx*4]);
|
|
sqlite3pager_unref(pP1);
|
|
|
|
/* If autovacuumed is disabled in this build but we are trying to
|
|
** access an autovacuumed database, then make the database readonly.
|
|
*/
|
|
#ifdef SQLITE_OMIT_AUTOVACUUM
|
|
if( idx==4 && *pMeta>0 ) pBt->readOnly = 1;
|
|
#endif
|
|
|
|
/* Grab the read-lock on page 1. */
|
|
rc = lockTable(p, 1, READ_LOCK);
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** Write meta-information back into the database. Meta[0] is
|
|
** read-only and may not be written.
|
|
*/
|
|
int sqlite3BtreeUpdateMeta(Btree *p, int idx, u32 iMeta){
|
|
BtShared *pBt = p->pBt;
|
|
unsigned char *pP1;
|
|
int rc;
|
|
assert( idx>=1 && idx<=15 );
|
|
if( p->inTrans!=TRANS_WRITE ){
|
|
return pBt->readOnly ? SQLITE_READONLY : SQLITE_ERROR;
|
|
}
|
|
assert( pBt->pPage1!=0 );
|
|
pP1 = pBt->pPage1->aData;
|
|
rc = sqlite3pager_write(pP1);
|
|
if( rc ) return rc;
|
|
put4byte(&pP1[36 + idx*4], iMeta);
|
|
return SQLITE_OK;
|
|
}
|
|
|
|
/*
|
|
** Return the flag byte at the beginning of the page that the cursor
|
|
** is currently pointing to.
|
|
*/
|
|
int sqlite3BtreeFlags(BtCursor *pCur){
|
|
/* TODO: What about CURSOR_REQUIRESEEK state? Probably need to call
|
|
** restoreOrClearCursorPosition() here.
|
|
*/
|
|
MemPage *pPage = pCur->pPage;
|
|
return pPage ? pPage->aData[pPage->hdrOffset] : 0;
|
|
}
|
|
|
|
#ifdef SQLITE_DEBUG
|
|
/*
|
|
** Print a disassembly of the given page on standard output. This routine
|
|
** is used for debugging and testing only.
|
|
*/
|
|
static int btreePageDump(BtShared *pBt, int pgno, int recursive, MemPage *pParent){
|
|
int rc;
|
|
MemPage *pPage;
|
|
int i, j, c;
|
|
int nFree;
|
|
u16 idx;
|
|
int hdr;
|
|
int nCell;
|
|
int isInit;
|
|
unsigned char *data;
|
|
char range[20];
|
|
unsigned char payload[20];
|
|
|
|
rc = getPage(pBt, (Pgno)pgno, &pPage);
|
|
isInit = pPage->isInit;
|
|
if( pPage->isInit==0 ){
|
|
initPage(pPage, pParent);
|
|
}
|
|
if( rc ){
|
|
return rc;
|
|
}
|
|
hdr = pPage->hdrOffset;
|
|
data = pPage->aData;
|
|
c = data[hdr];
|
|
pPage->intKey = (c & (PTF_INTKEY|PTF_LEAFDATA))!=0;
|
|
pPage->zeroData = (c & PTF_ZERODATA)!=0;
|
|
pPage->leafData = (c & PTF_LEAFDATA)!=0;
|
|
pPage->leaf = (c & PTF_LEAF)!=0;
|
|
pPage->hasData = !(pPage->zeroData || (!pPage->leaf && pPage->leafData));
|
|
nCell = get2byte(&data[hdr+3]);
|
|
sqlite3DebugPrintf("PAGE %d: flags=0x%02x frag=%d parent=%d\n", pgno,
|
|
data[hdr], data[hdr+7],
|
|
(pPage->isInit && pPage->pParent) ? pPage->pParent->pgno : 0);
|
|
assert( hdr == (pgno==1 ? 100 : 0) );
|
|
idx = hdr + 12 - pPage->leaf*4;
|
|
for(i=0; i<nCell; i++){
|
|
CellInfo info;
|
|
Pgno child;
|
|
unsigned char *pCell;
|
|
int sz;
|
|
int addr;
|
|
|
|
addr = get2byte(&data[idx + 2*i]);
|
|
pCell = &data[addr];
|
|
parseCellPtr(pPage, pCell, &info);
|
|
sz = info.nSize;
|
|
sprintf(range,"%d..%d", addr, addr+sz-1);
|
|
if( pPage->leaf ){
|
|
child = 0;
|
|
}else{
|
|
child = get4byte(pCell);
|
|
}
|
|
sz = info.nData;
|
|
if( !pPage->intKey ) sz += info.nKey;
|
|
if( sz>sizeof(payload)-1 ) sz = sizeof(payload)-1;
|
|
memcpy(payload, &pCell[info.nHeader], sz);
|
|
for(j=0; j<sz; j++){
|
|
if( payload[j]<0x20 || payload[j]>0x7f ) payload[j] = '.';
|
|
}
|
|
payload[sz] = 0;
|
|
sqlite3DebugPrintf(
|
|
"cell %2d: i=%-10s chld=%-4d nk=%-4lld nd=%-4d payload=%s\n",
|
|
i, range, child, info.nKey, info.nData, payload
|
|
);
|
|
}
|
|
if( !pPage->leaf ){
|
|
sqlite3DebugPrintf("right_child: %d\n", get4byte(&data[hdr+8]));
|
|
}
|
|
nFree = 0;
|
|
i = 0;
|
|
idx = get2byte(&data[hdr+1]);
|
|
while( idx>0 && idx<pPage->pBt->usableSize ){
|
|
int sz = get2byte(&data[idx+2]);
|
|
sprintf(range,"%d..%d", idx, idx+sz-1);
|
|
nFree += sz;
|
|
sqlite3DebugPrintf("freeblock %2d: i=%-10s size=%-4d total=%d\n",
|
|
i, range, sz, nFree);
|
|
idx = get2byte(&data[idx]);
|
|
i++;
|
|
}
|
|
if( idx!=0 ){
|
|
sqlite3DebugPrintf("ERROR: next freeblock index out of range: %d\n", idx);
|
|
}
|
|
if( recursive && !pPage->leaf ){
|
|
for(i=0; i<nCell; i++){
|
|
unsigned char *pCell = findCell(pPage, i);
|
|
btreePageDump(pBt, get4byte(pCell), 1, pPage);
|
|
idx = get2byte(pCell);
|
|
}
|
|
btreePageDump(pBt, get4byte(&data[hdr+8]), 1, pPage);
|
|
}
|
|
pPage->isInit = isInit;
|
|
sqlite3pager_unref(data);
|
|
fflush(stdout);
|
|
return SQLITE_OK;
|
|
}
|
|
int sqlite3BtreePageDump(Btree *p, int pgno, int recursive){
|
|
return btreePageDump(p->pBt, pgno, recursive, 0);
|
|
}
|
|
#endif
|
|
|
|
#if defined(SQLITE_TEST) && defined(SQLITE_DEBUG)
|
|
/*
|
|
** Fill aResult[] with information about the entry and page that the
|
|
** cursor is pointing to.
|
|
**
|
|
** aResult[0] = The page number
|
|
** aResult[1] = The entry number
|
|
** aResult[2] = Total number of entries on this page
|
|
** aResult[3] = Cell size (local payload + header)
|
|
** aResult[4] = Number of free bytes on this page
|
|
** aResult[5] = Number of free blocks on the page
|
|
** aResult[6] = Total payload size (local + overflow)
|
|
** aResult[7] = Header size in bytes
|
|
** aResult[8] = Local payload size
|
|
** aResult[9] = Parent page number
|
|
**
|
|
** This routine is used for testing and debugging only.
|
|
*/
|
|
int sqlite3BtreeCursorInfo(BtCursor *pCur, int *aResult, int upCnt){
|
|
int cnt, idx;
|
|
MemPage *pPage = pCur->pPage;
|
|
BtCursor tmpCur;
|
|
|
|
int rc = restoreOrClearCursorPosition(pCur, 1);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
|
|
pageIntegrity(pPage);
|
|
assert( pPage->isInit );
|
|
getTempCursor(pCur, &tmpCur);
|
|
while( upCnt-- ){
|
|
moveToParent(&tmpCur);
|
|
}
|
|
pPage = tmpCur.pPage;
|
|
pageIntegrity(pPage);
|
|
aResult[0] = sqlite3pager_pagenumber(pPage->aData);
|
|
assert( aResult[0]==pPage->pgno );
|
|
aResult[1] = tmpCur.idx;
|
|
aResult[2] = pPage->nCell;
|
|
if( tmpCur.idx>=0 && tmpCur.idx<pPage->nCell ){
|
|
getCellInfo(&tmpCur);
|
|
aResult[3] = tmpCur.info.nSize;
|
|
aResult[6] = tmpCur.info.nData;
|
|
aResult[7] = tmpCur.info.nHeader;
|
|
aResult[8] = tmpCur.info.nLocal;
|
|
}else{
|
|
aResult[3] = 0;
|
|
aResult[6] = 0;
|
|
aResult[7] = 0;
|
|
aResult[8] = 0;
|
|
}
|
|
aResult[4] = pPage->nFree;
|
|
cnt = 0;
|
|
idx = get2byte(&pPage->aData[pPage->hdrOffset+1]);
|
|
while( idx>0 && idx<pPage->pBt->usableSize ){
|
|
cnt++;
|
|
idx = get2byte(&pPage->aData[idx]);
|
|
}
|
|
aResult[5] = cnt;
|
|
if( pPage->pParent==0 || isRootPage(pPage) ){
|
|
aResult[9] = 0;
|
|
}else{
|
|
aResult[9] = pPage->pParent->pgno;
|
|
}
|
|
releaseTempCursor(&tmpCur);
|
|
return SQLITE_OK;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** Return the pager associated with a BTree. This routine is used for
|
|
** testing and debugging only.
|
|
*/
|
|
Pager *sqlite3BtreePager(Btree *p){
|
|
return p->pBt->pPager;
|
|
}
|
|
|
|
/*
|
|
** This structure is passed around through all the sanity checking routines
|
|
** in order to keep track of some global state information.
|
|
*/
|
|
typedef struct IntegrityCk IntegrityCk;
|
|
struct IntegrityCk {
|
|
BtShared *pBt; /* The tree being checked out */
|
|
Pager *pPager; /* The associated pager. Also accessible by pBt->pPager */
|
|
int nPage; /* Number of pages in the database */
|
|
int *anRef; /* Number of times each page is referenced */
|
|
char *zErrMsg; /* An error message. NULL of no errors seen. */
|
|
};
|
|
|
|
#ifndef SQLITE_OMIT_INTEGRITY_CHECK
|
|
/*
|
|
** Append a message to the error message string.
|
|
*/
|
|
static void checkAppendMsg(
|
|
IntegrityCk *pCheck,
|
|
char *zMsg1,
|
|
const char *zFormat,
|
|
...
|
|
){
|
|
va_list ap;
|
|
char *zMsg2;
|
|
va_start(ap, zFormat);
|
|
zMsg2 = sqlite3VMPrintf(zFormat, ap);
|
|
va_end(ap);
|
|
if( zMsg1==0 ) zMsg1 = "";
|
|
if( pCheck->zErrMsg ){
|
|
char *zOld = pCheck->zErrMsg;
|
|
pCheck->zErrMsg = 0;
|
|
sqlite3SetString(&pCheck->zErrMsg, zOld, "\n", zMsg1, zMsg2, (char*)0);
|
|
sqliteFree(zOld);
|
|
}else{
|
|
sqlite3SetString(&pCheck->zErrMsg, zMsg1, zMsg2, (char*)0);
|
|
}
|
|
sqliteFree(zMsg2);
|
|
}
|
|
#endif /* SQLITE_OMIT_INTEGRITY_CHECK */
|
|
|
|
#ifndef SQLITE_OMIT_INTEGRITY_CHECK
|
|
/*
|
|
** Add 1 to the reference count for page iPage. If this is the second
|
|
** reference to the page, add an error message to pCheck->zErrMsg.
|
|
** Return 1 if there are 2 ore more references to the page and 0 if
|
|
** if this is the first reference to the page.
|
|
**
|
|
** Also check that the page number is in bounds.
|
|
*/
|
|
static int checkRef(IntegrityCk *pCheck, int iPage, char *zContext){
|
|
if( iPage==0 ) return 1;
|
|
if( iPage>pCheck->nPage || iPage<0 ){
|
|
checkAppendMsg(pCheck, zContext, "invalid page number %d", iPage);
|
|
return 1;
|
|
}
|
|
if( pCheck->anRef[iPage]==1 ){
|
|
checkAppendMsg(pCheck, zContext, "2nd reference to page %d", iPage);
|
|
return 1;
|
|
}
|
|
return (pCheck->anRef[iPage]++)>1;
|
|
}
|
|
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
/*
|
|
** Check that the entry in the pointer-map for page iChild maps to
|
|
** page iParent, pointer type ptrType. If not, append an error message
|
|
** to pCheck.
|
|
*/
|
|
static void checkPtrmap(
|
|
IntegrityCk *pCheck, /* Integrity check context */
|
|
Pgno iChild, /* Child page number */
|
|
u8 eType, /* Expected pointer map type */
|
|
Pgno iParent, /* Expected pointer map parent page number */
|
|
char *zContext /* Context description (used for error msg) */
|
|
){
|
|
int rc;
|
|
u8 ePtrmapType;
|
|
Pgno iPtrmapParent;
|
|
|
|
rc = ptrmapGet(pCheck->pBt, iChild, &ePtrmapType, &iPtrmapParent);
|
|
if( rc!=SQLITE_OK ){
|
|
checkAppendMsg(pCheck, zContext, "Failed to read ptrmap key=%d", iChild);
|
|
return;
|
|
}
|
|
|
|
if( ePtrmapType!=eType || iPtrmapParent!=iParent ){
|
|
checkAppendMsg(pCheck, zContext,
|
|
"Bad ptr map entry key=%d expected=(%d,%d) got=(%d,%d)",
|
|
iChild, eType, iParent, ePtrmapType, iPtrmapParent);
|
|
}
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** Check the integrity of the freelist or of an overflow page list.
|
|
** Verify that the number of pages on the list is N.
|
|
*/
|
|
static void checkList(
|
|
IntegrityCk *pCheck, /* Integrity checking context */
|
|
int isFreeList, /* True for a freelist. False for overflow page list */
|
|
int iPage, /* Page number for first page in the list */
|
|
int N, /* Expected number of pages in the list */
|
|
char *zContext /* Context for error messages */
|
|
){
|
|
int i;
|
|
int expected = N;
|
|
int iFirst = iPage;
|
|
while( N-- > 0 ){
|
|
unsigned char *pOvfl;
|
|
if( iPage<1 ){
|
|
checkAppendMsg(pCheck, zContext,
|
|
"%d of %d pages missing from overflow list starting at %d",
|
|
N+1, expected, iFirst);
|
|
break;
|
|
}
|
|
if( checkRef(pCheck, iPage, zContext) ) break;
|
|
if( sqlite3pager_get(pCheck->pPager, (Pgno)iPage, (void**)&pOvfl) ){
|
|
checkAppendMsg(pCheck, zContext, "failed to get page %d", iPage);
|
|
break;
|
|
}
|
|
if( isFreeList ){
|
|
int n = get4byte(&pOvfl[4]);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pCheck->pBt->autoVacuum ){
|
|
checkPtrmap(pCheck, iPage, PTRMAP_FREEPAGE, 0, zContext);
|
|
}
|
|
#endif
|
|
if( n>pCheck->pBt->usableSize/4-8 ){
|
|
checkAppendMsg(pCheck, zContext,
|
|
"freelist leaf count too big on page %d", iPage);
|
|
N--;
|
|
}else{
|
|
for(i=0; i<n; i++){
|
|
Pgno iFreePage = get4byte(&pOvfl[8+i*4]);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pCheck->pBt->autoVacuum ){
|
|
checkPtrmap(pCheck, iFreePage, PTRMAP_FREEPAGE, 0, zContext);
|
|
}
|
|
#endif
|
|
checkRef(pCheck, iFreePage, zContext);
|
|
}
|
|
N -= n;
|
|
}
|
|
}
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
else{
|
|
/* If this database supports auto-vacuum and iPage is not the last
|
|
** page in this overflow list, check that the pointer-map entry for
|
|
** the following page matches iPage.
|
|
*/
|
|
if( pCheck->pBt->autoVacuum && N>0 ){
|
|
i = get4byte(pOvfl);
|
|
checkPtrmap(pCheck, i, PTRMAP_OVERFLOW2, iPage, zContext);
|
|
}
|
|
}
|
|
#endif
|
|
iPage = get4byte(pOvfl);
|
|
sqlite3pager_unref(pOvfl);
|
|
}
|
|
}
|
|
#endif /* SQLITE_OMIT_INTEGRITY_CHECK */
|
|
|
|
#ifndef SQLITE_OMIT_INTEGRITY_CHECK
|
|
/*
|
|
** Do various sanity checks on a single page of a tree. Return
|
|
** the tree depth. Root pages return 0. Parents of root pages
|
|
** return 1, and so forth.
|
|
**
|
|
** These checks are done:
|
|
**
|
|
** 1. Make sure that cells and freeblocks do not overlap
|
|
** but combine to completely cover the page.
|
|
** NO 2. Make sure cell keys are in order.
|
|
** NO 3. Make sure no key is less than or equal to zLowerBound.
|
|
** NO 4. Make sure no key is greater than or equal to zUpperBound.
|
|
** 5. Check the integrity of overflow pages.
|
|
** 6. Recursively call checkTreePage on all children.
|
|
** 7. Verify that the depth of all children is the same.
|
|
** 8. Make sure this page is at least 33% full or else it is
|
|
** the root of the tree.
|
|
*/
|
|
static int checkTreePage(
|
|
IntegrityCk *pCheck, /* Context for the sanity check */
|
|
int iPage, /* Page number of the page to check */
|
|
MemPage *pParent, /* Parent page */
|
|
char *zParentContext /* Parent context */
|
|
){
|
|
MemPage *pPage;
|
|
int i, rc, depth, d2, pgno, cnt;
|
|
int hdr, cellStart;
|
|
int nCell;
|
|
u8 *data;
|
|
BtShared *pBt;
|
|
int usableSize;
|
|
char zContext[100];
|
|
char *hit;
|
|
|
|
sprintf(zContext, "Page %d: ", iPage);
|
|
|
|
/* Check that the page exists
|
|
*/
|
|
pBt = pCheck->pBt;
|
|
usableSize = pBt->usableSize;
|
|
if( iPage==0 ) return 0;
|
|
if( checkRef(pCheck, iPage, zParentContext) ) return 0;
|
|
if( (rc = getPage(pBt, (Pgno)iPage, &pPage))!=0 ){
|
|
checkAppendMsg(pCheck, zContext,
|
|
"unable to get the page. error code=%d", rc);
|
|
return 0;
|
|
}
|
|
if( (rc = initPage(pPage, pParent))!=0 ){
|
|
checkAppendMsg(pCheck, zContext, "initPage() returns error code %d", rc);
|
|
releasePage(pPage);
|
|
return 0;
|
|
}
|
|
|
|
/* Check out all the cells.
|
|
*/
|
|
depth = 0;
|
|
for(i=0; i<pPage->nCell; i++){
|
|
u8 *pCell;
|
|
int sz;
|
|
CellInfo info;
|
|
|
|
/* Check payload overflow pages
|
|
*/
|
|
sprintf(zContext, "On tree page %d cell %d: ", iPage, i);
|
|
pCell = findCell(pPage,i);
|
|
parseCellPtr(pPage, pCell, &info);
|
|
sz = info.nData;
|
|
if( !pPage->intKey ) sz += (int)info.nKey;
|
|
if( sz>info.nLocal ){
|
|
int nPage = (sz - info.nLocal + usableSize - 5)/(usableSize - 4);
|
|
Pgno pgnoOvfl = get4byte(&pCell[info.iOverflow]);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
checkPtrmap(pCheck, pgnoOvfl, PTRMAP_OVERFLOW1, iPage, zContext);
|
|
}
|
|
#endif
|
|
checkList(pCheck, 0, pgnoOvfl, nPage, zContext);
|
|
}
|
|
|
|
/* Check sanity of left child page.
|
|
*/
|
|
if( !pPage->leaf ){
|
|
pgno = get4byte(pCell);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
checkPtrmap(pCheck, pgno, PTRMAP_BTREE, iPage, zContext);
|
|
}
|
|
#endif
|
|
d2 = checkTreePage(pCheck,pgno,pPage,zContext);
|
|
if( i>0 && d2!=depth ){
|
|
checkAppendMsg(pCheck, zContext, "Child page depth differs");
|
|
}
|
|
depth = d2;
|
|
}
|
|
}
|
|
if( !pPage->leaf ){
|
|
pgno = get4byte(&pPage->aData[pPage->hdrOffset+8]);
|
|
sprintf(zContext, "On page %d at right child: ", iPage);
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
checkPtrmap(pCheck, pgno, PTRMAP_BTREE, iPage, 0);
|
|
}
|
|
#endif
|
|
checkTreePage(pCheck, pgno, pPage, zContext);
|
|
}
|
|
|
|
/* Check for complete coverage of the page
|
|
*/
|
|
data = pPage->aData;
|
|
hdr = pPage->hdrOffset;
|
|
hit = sqliteMalloc( usableSize );
|
|
if( hit ){
|
|
memset(hit, 1, get2byte(&data[hdr+5]));
|
|
nCell = get2byte(&data[hdr+3]);
|
|
cellStart = hdr + 12 - 4*pPage->leaf;
|
|
for(i=0; i<nCell; i++){
|
|
int pc = get2byte(&data[cellStart+i*2]);
|
|
int size = cellSizePtr(pPage, &data[pc]);
|
|
int j;
|
|
if( (pc+size-1)>=usableSize || pc<0 ){
|
|
checkAppendMsg(pCheck, 0,
|
|
"Corruption detected in cell %d on page %d",i,iPage,0);
|
|
}else{
|
|
for(j=pc+size-1; j>=pc; j--) hit[j]++;
|
|
}
|
|
}
|
|
for(cnt=0, i=get2byte(&data[hdr+1]); i>0 && i<usableSize && cnt<10000;
|
|
cnt++){
|
|
int size = get2byte(&data[i+2]);
|
|
int j;
|
|
if( (i+size-1)>=usableSize || i<0 ){
|
|
checkAppendMsg(pCheck, 0,
|
|
"Corruption detected in cell %d on page %d",i,iPage,0);
|
|
}else{
|
|
for(j=i+size-1; j>=i; j--) hit[j]++;
|
|
}
|
|
i = get2byte(&data[i]);
|
|
}
|
|
for(i=cnt=0; i<usableSize; i++){
|
|
if( hit[i]==0 ){
|
|
cnt++;
|
|
}else if( hit[i]>1 ){
|
|
checkAppendMsg(pCheck, 0,
|
|
"Multiple uses for byte %d of page %d", i, iPage);
|
|
break;
|
|
}
|
|
}
|
|
if( cnt!=data[hdr+7] ){
|
|
checkAppendMsg(pCheck, 0,
|
|
"Fragmented space is %d byte reported as %d on page %d",
|
|
cnt, data[hdr+7], iPage);
|
|
}
|
|
}
|
|
sqliteFree(hit);
|
|
|
|
releasePage(pPage);
|
|
return depth+1;
|
|
}
|
|
#endif /* SQLITE_OMIT_INTEGRITY_CHECK */
|
|
|
|
#ifndef SQLITE_OMIT_INTEGRITY_CHECK
|
|
/*
|
|
** This routine does a complete check of the given BTree file. aRoot[] is
|
|
** an array of pages numbers were each page number is the root page of
|
|
** a table. nRoot is the number of entries in aRoot.
|
|
**
|
|
** If everything checks out, this routine returns NULL. If something is
|
|
** amiss, an error message is written into memory obtained from malloc()
|
|
** and a pointer to that error message is returned. The calling function
|
|
** is responsible for freeing the error message when it is done.
|
|
*/
|
|
char *sqlite3BtreeIntegrityCheck(Btree *p, int *aRoot, int nRoot){
|
|
int i;
|
|
int nRef;
|
|
IntegrityCk sCheck;
|
|
BtShared *pBt = p->pBt;
|
|
|
|
nRef = *sqlite3pager_stats(pBt->pPager);
|
|
if( lockBtreeWithRetry(p)!=SQLITE_OK ){
|
|
return sqliteStrDup("Unable to acquire a read lock on the database");
|
|
}
|
|
sCheck.pBt = pBt;
|
|
sCheck.pPager = pBt->pPager;
|
|
sCheck.nPage = sqlite3pager_pagecount(sCheck.pPager);
|
|
if( sCheck.nPage==0 ){
|
|
unlockBtreeIfUnused(pBt);
|
|
return 0;
|
|
}
|
|
sCheck.anRef = sqliteMallocRaw( (sCheck.nPage+1)*sizeof(sCheck.anRef[0]) );
|
|
if( !sCheck.anRef ){
|
|
unlockBtreeIfUnused(pBt);
|
|
return sqlite3MPrintf("Unable to malloc %d bytes",
|
|
(sCheck.nPage+1)*sizeof(sCheck.anRef[0]));
|
|
}
|
|
for(i=0; i<=sCheck.nPage; i++){ sCheck.anRef[i] = 0; }
|
|
i = PENDING_BYTE_PAGE(pBt);
|
|
if( i<=sCheck.nPage ){
|
|
sCheck.anRef[i] = 1;
|
|
}
|
|
sCheck.zErrMsg = 0;
|
|
|
|
/* Check the integrity of the freelist
|
|
*/
|
|
checkList(&sCheck, 1, get4byte(&pBt->pPage1->aData[32]),
|
|
get4byte(&pBt->pPage1->aData[36]), "Main freelist: ");
|
|
|
|
/* Check all the tables.
|
|
*/
|
|
for(i=0; i<nRoot; i++){
|
|
if( aRoot[i]==0 ) continue;
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum && aRoot[i]>1 ){
|
|
checkPtrmap(&sCheck, aRoot[i], PTRMAP_ROOTPAGE, 0, 0);
|
|
}
|
|
#endif
|
|
checkTreePage(&sCheck, aRoot[i], 0, "List of tree roots: ");
|
|
}
|
|
|
|
/* Make sure every page in the file is referenced
|
|
*/
|
|
for(i=1; i<=sCheck.nPage; i++){
|
|
#ifdef SQLITE_OMIT_AUTOVACUUM
|
|
if( sCheck.anRef[i]==0 ){
|
|
checkAppendMsg(&sCheck, 0, "Page %d is never used", i);
|
|
}
|
|
#else
|
|
/* If the database supports auto-vacuum, make sure no tables contain
|
|
** references to pointer-map pages.
|
|
*/
|
|
if( sCheck.anRef[i]==0 &&
|
|
(PTRMAP_PAGENO(pBt, i)!=i || !pBt->autoVacuum) ){
|
|
checkAppendMsg(&sCheck, 0, "Page %d is never used", i);
|
|
}
|
|
if( sCheck.anRef[i]!=0 &&
|
|
(PTRMAP_PAGENO(pBt, i)==i && pBt->autoVacuum) ){
|
|
checkAppendMsg(&sCheck, 0, "Pointer map page %d is referenced", i);
|
|
}
|
|
#endif
|
|
}
|
|
|
|
/* Make sure this analysis did not leave any unref() pages
|
|
*/
|
|
unlockBtreeIfUnused(pBt);
|
|
if( nRef != *sqlite3pager_stats(pBt->pPager) ){
|
|
checkAppendMsg(&sCheck, 0,
|
|
"Outstanding page count goes from %d to %d during this analysis",
|
|
nRef, *sqlite3pager_stats(pBt->pPager)
|
|
);
|
|
}
|
|
|
|
/* Clean up and report errors.
|
|
*/
|
|
sqliteFree(sCheck.anRef);
|
|
return sCheck.zErrMsg;
|
|
}
|
|
#endif /* SQLITE_OMIT_INTEGRITY_CHECK */
|
|
|
|
/*
|
|
** Return the full pathname of the underlying database file.
|
|
*/
|
|
const char *sqlite3BtreeGetFilename(Btree *p){
|
|
assert( p->pBt->pPager!=0 );
|
|
return sqlite3pager_filename(p->pBt->pPager);
|
|
}
|
|
|
|
/*
|
|
** Return the pathname of the directory that contains the database file.
|
|
*/
|
|
const char *sqlite3BtreeGetDirname(Btree *p){
|
|
assert( p->pBt->pPager!=0 );
|
|
return sqlite3pager_dirname(p->pBt->pPager);
|
|
}
|
|
|
|
/*
|
|
** Return the pathname of the journal file for this database. The return
|
|
** value of this routine is the same regardless of whether the journal file
|
|
** has been created or not.
|
|
*/
|
|
const char *sqlite3BtreeGetJournalname(Btree *p){
|
|
assert( p->pBt->pPager!=0 );
|
|
return sqlite3pager_journalname(p->pBt->pPager);
|
|
}
|
|
|
|
#ifndef SQLITE_OMIT_VACUUM
|
|
/*
|
|
** Copy the complete content of pBtFrom into pBtTo. A transaction
|
|
** must be active for both files.
|
|
**
|
|
** The size of file pBtFrom may be reduced by this operation.
|
|
** If anything goes wrong, the transaction on pBtFrom is rolled back.
|
|
*/
|
|
int sqlite3BtreeCopyFile(Btree *pTo, Btree *pFrom){
|
|
int rc = SQLITE_OK;
|
|
Pgno i, nPage, nToPage, iSkip;
|
|
|
|
BtShared *pBtTo = pTo->pBt;
|
|
BtShared *pBtFrom = pFrom->pBt;
|
|
|
|
if( pTo->inTrans!=TRANS_WRITE || pFrom->inTrans!=TRANS_WRITE ){
|
|
return SQLITE_ERROR;
|
|
}
|
|
if( pBtTo->pCursor ) return SQLITE_BUSY;
|
|
nToPage = sqlite3pager_pagecount(pBtTo->pPager);
|
|
nPage = sqlite3pager_pagecount(pBtFrom->pPager);
|
|
iSkip = PENDING_BYTE_PAGE(pBtTo);
|
|
for(i=1; rc==SQLITE_OK && i<=nPage; i++){
|
|
void *pPage;
|
|
if( i==iSkip ) continue;
|
|
rc = sqlite3pager_get(pBtFrom->pPager, i, &pPage);
|
|
if( rc ) break;
|
|
rc = sqlite3pager_overwrite(pBtTo->pPager, i, pPage);
|
|
if( rc ) break;
|
|
sqlite3pager_unref(pPage);
|
|
}
|
|
for(i=nPage+1; rc==SQLITE_OK && i<=nToPage; i++){
|
|
void *pPage;
|
|
if( i==iSkip ) continue;
|
|
rc = sqlite3pager_get(pBtTo->pPager, i, &pPage);
|
|
if( rc ) break;
|
|
rc = sqlite3pager_write(pPage);
|
|
sqlite3pager_unref(pPage);
|
|
sqlite3pager_dont_write(pBtTo->pPager, i);
|
|
}
|
|
if( !rc && nPage<nToPage ){
|
|
rc = sqlite3pager_truncate(pBtTo->pPager, nPage);
|
|
}
|
|
if( rc ){
|
|
sqlite3BtreeRollback(pTo);
|
|
}
|
|
return rc;
|
|
}
|
|
#endif /* SQLITE_OMIT_VACUUM */
|
|
|
|
/*
|
|
** Return non-zero if a transaction is active.
|
|
*/
|
|
int sqlite3BtreeIsInTrans(Btree *p){
|
|
return (p && (p->inTrans==TRANS_WRITE));
|
|
}
|
|
|
|
/*
|
|
** Return non-zero if a statement transaction is active.
|
|
*/
|
|
int sqlite3BtreeIsInStmt(Btree *p){
|
|
return (p->pBt && p->pBt->inStmt);
|
|
}
|
|
|
|
/*
|
|
** This call is a no-op if no write-transaction is currently active on pBt.
|
|
**
|
|
** Otherwise, sync the database file for the btree pBt. zMaster points to
|
|
** the name of a master journal file that should be written into the
|
|
** individual journal file, or is NULL, indicating no master journal file
|
|
** (single database transaction).
|
|
**
|
|
** When this is called, the master journal should already have been
|
|
** created, populated with this journal pointer and synced to disk.
|
|
**
|
|
** Once this is routine has returned, the only thing required to commit
|
|
** the write-transaction for this database file is to delete the journal.
|
|
*/
|
|
int sqlite3BtreeSync(Btree *p, const char *zMaster){
|
|
int rc = SQLITE_OK;
|
|
if( p->inTrans==TRANS_WRITE ){
|
|
BtShared *pBt = p->pBt;
|
|
Pgno nTrunc = 0;
|
|
#ifndef SQLITE_OMIT_AUTOVACUUM
|
|
if( pBt->autoVacuum ){
|
|
rc = autoVacuumCommit(pBt, &nTrunc);
|
|
if( rc!=SQLITE_OK ){
|
|
return rc;
|
|
}
|
|
}
|
|
#endif
|
|
rc = sqlite3pager_sync(pBt->pPager, zMaster, nTrunc);
|
|
}
|
|
return rc;
|
|
}
|
|
|
|
/*
|
|
** This function returns a pointer to a blob of memory associated with
|
|
** a single shared-btree. The memory is used by client code for it's own
|
|
** purposes (for example, to store a high-level schema associated with
|
|
** the shared-btree). The btree layer manages reference counting issues.
|
|
**
|
|
** The first time this is called on a shared-btree, nBytes bytes of memory
|
|
** are allocated, zeroed, and returned to the caller. For each subsequent
|
|
** call the nBytes parameter is ignored and a pointer to the same blob
|
|
** of memory returned.
|
|
**
|
|
** Just before the shared-btree is closed, the function passed as the
|
|
** xFree argument when the memory allocation was made is invoked on the
|
|
** blob of allocated memory. This function should not call sqliteFree()
|
|
** on the memory, the btree layer does that.
|
|
*/
|
|
void *sqlite3BtreeSchema(Btree *p, int nBytes, void(*xFree)(void *)){
|
|
BtShared *pBt = p->pBt;
|
|
if( !pBt->pSchema ){
|
|
pBt->pSchema = sqliteMalloc(nBytes);
|
|
pBt->xFreeSchema = xFree;
|
|
}
|
|
return pBt->pSchema;
|
|
}
|
|
|
|
/*
|
|
** Return true if another user of the same shared btree as the argument
|
|
** handle holds an exclusive lock on the sqlite_master table.
|
|
*/
|
|
int sqlite3BtreeSchemaLocked(Btree *p){
|
|
return (queryTableLock(p, MASTER_ROOT, READ_LOCK)!=SQLITE_OK);
|
|
}
|
|
|
|
|
|
#ifndef SQLITE_OMIT_SHARED_CACHE
|
|
/*
|
|
** Obtain a lock on the table whose root page is iTab. The
|
|
** lock is a write lock if isWritelock is true or a read lock
|
|
** if it is false.
|
|
*/
|
|
int sqlite3BtreeLockTable(Btree *p, int iTab, u8 isWriteLock){
|
|
int rc = SQLITE_OK;
|
|
u8 lockType = (isWriteLock?WRITE_LOCK:READ_LOCK);
|
|
rc = queryTableLock(p, iTab, lockType);
|
|
if( rc==SQLITE_OK ){
|
|
rc = lockTable(p, iTab, lockType);
|
|
}
|
|
return rc;
|
|
}
|
|
#endif
|
|
|
|
/*
|
|
** The following debugging interface has to be in this file (rather
|
|
** than in, for example, test1.c) so that it can get access to
|
|
** the definition of BtShared.
|
|
*/
|
|
#if defined(SQLITE_DEBUG) && defined(TCLSH)
|
|
#include <tcl.h>
|
|
int sqlite3_shared_cache_report(
|
|
void * clientData,
|
|
Tcl_Interp *interp,
|
|
int objc,
|
|
Tcl_Obj *CONST objv[]
|
|
){
|
|
#ifndef SQLITE_OMIT_SHARED_CACHE
|
|
const ThreadData *pTd = sqlite3ThreadDataReadOnly();
|
|
if( pTd->useSharedData ){
|
|
BtShared *pBt;
|
|
Tcl_Obj *pRet = Tcl_NewObj();
|
|
for(pBt=pTd->pBtree; pBt; pBt=pBt->pNext){
|
|
const char *zFile = sqlite3pager_filename(pBt->pPager);
|
|
Tcl_ListObjAppendElement(interp, pRet, Tcl_NewStringObj(zFile, -1));
|
|
Tcl_ListObjAppendElement(interp, pRet, Tcl_NewIntObj(pBt->nRef));
|
|
}
|
|
Tcl_SetObjResult(interp, pRet);
|
|
}
|
|
#endif
|
|
return TCL_OK;
|
|
}
|
|
#endif
|