Documentation Source Text

Artifact Content

Artifact 4bda585fb78b72f50950b92bb810eed97b9ae749:

<title>SQLite FTS3 Extension</title>

hd_keywords *fts3 FTS3
source [file join $::DOC pages fancyformat.tcl]
fancyformat_document "SQLite FTS3 Extension" {} {

<h2 style="margin-left:1.0em"> Overview</h2>

[h1 "Introduction to FTS3"]

  The FTS3 extension module allows users to create special tables with a 
  built-in full-text index (hereafter "FTS3 tables"). The full-text index
  allows the user to efficiently query the database for all rows that contain
  one or more instances specified word (hereafter a "token", even if the table
  contains many large documents.

  For example, if each of the 517430 documents in the 
  "<a href="">Enron E-Mail Dataset</a>"
  is inserted into both the FTS3 table and the ordinary SQLite table
  created using the following SQL script:

[Code {
  CREATE VIRTUAL TABLE enrondata1 USING fts3(content TEXT);     /* FTS3 table */
  CREATE TABLE enrondata2(content TEXT);                        /* Ordinary table */

  Then either of the two queries below may be executed to find the number of
  documents in the database that contain the word "linux" (351). Using one
  desktop PC hardware configuration, the query on the FTS3 table returns in
  approximately 0.03 seconds, versus 22.5 for querying the ordinary table.

[Code {
  SELECT count(*) FROM enrondata1 WHERE content MATCH 'linux';  /* 0.03 seconds */
  SELECT count(*) FROM enrondata2 WHERE content LIKE '%linux%'; /* 22.5 seconds */

  Of course, the two queries above are not entirely equivalent. For example
  the LIKE query matches rows that contain terms such as "linuxophobe"
  or "EnterpriseLinux" (as it happens, the Enron E-Mail Dataset does not
  actually contain any such terms), whereas the MATCH query on the FTS3 table
  selects only those rows that contain "linux" as a discreet token. Both 
  searches are case-insensitive. The FTS3 table consumes around 2006 MB on
  disk compared to just 1453 MB for the ordinary table. Using the same
  hardware configuration used to perform the SELECT queries above, the FTS3
  table took just over 39 minutes to populate, versus 25 for the ordinary

[h1 "Compiling and Enabling FTS3"]

  Although FTS3 is distributed as part of the SQLite source code, it is not
  enabled by default. To build SQLite with FTS3 functionality enabled, define
  the preprocessor macro \[SQLITE_ENABLE_FTS3\] when compiling. New applications
  should also define the \[SQLITE_ENABLE_FTS3_PARENTHESIS\] macro to enable the
  advanced query syntax (see below). Usually, this is done by adding the 
  following two switches to the compiler command line:

[Code {

  If using the amalgamation autoconf based build system, setting the CPPFLAGS
  environment variable while running the 'configure' script is an easy
  way to set these macros. For example, the following command:

[Code {
  CPPFLAGS="-DSQLITE_ENABLE_FTS3 -DSQLITE_ENABLE_FTS3_PARENTHESIS" ./configure &lt;configure options&gt;

  where <i>&lt;configure options&gt;</i> are those options normally passed to
  the configure script, if any.

  Because FTS3 is a virtual table, it is incompatible with the

  If an SQLite build does not include FTS3, then any attempt to prepare an
  SQL statement to create an FTS3 table or to drop or access an existing 
  FTS3 table in any way will fail. The error message returned will be similar 
  to "no such module: fts3".

[h1 "MATCH Expression Syntax"]

[h2 "Advanced Query Syntax"]

[h2 "Legacy Query Syntax"]

[h1 "Auxillary functions - Snippets and Offsets"]

[h1 "Custom Tokenizers" customtokenizer {custom tokenizer}]

[h1 "Data Structures"]

  This section describes at a high-level the way the FTS3 module stores its
  index and content in the database. It is <b>not necessary to read or 
  understand the material in this section in order to use FTS3</b> in an 
  application. However, it may be useful to application developers attempting 
  to analyze and understand FTS3 performance characteristics, or to developers 
  contemplating enhancements to the existing FTS3 feature set.

  For each FTS3 virtual table in a database, three real (non-virtual) tables 
  are created to store the underlying data. The real tables are named "%_content",
  "%_segdir" and "%_segments", where "%" is replaced by the name supplied by
  the user for the FTS3 virtual table.

  The leftmost column of the "%_content" table is an INTEGER PRIMARY KEY field
  named "docid". Following this is one column for each column of the FTS3
  virtual table as declared by the user, named by prepending the column name
  supplied by the user with "c<i>N</i>", where <i>N</i> is the index of the 
  column within the table, numbered from left to right starting with 1. Data
  types supplied as part of the virtual table declaration are not used as
  part of the %_content table declaration. For example:

[Code {
  /* Virtual table declaration */

  /* Corresponding %_content table declaration */
  CREATE TABLE abc_content(docid INTEGER PRIMARY KEY, c1a, c2b, c2c);

  The %_content table contains the unadulterated data inserted by the user 
  into the FTS3 virtual table by the user. If the user does not explicitly
  supply a "docid" value when inserting records, one is selected automatically
  by the system.

  The two remaining tables, %_segments and %_segdir, are used to store the 
  full-text index. Conceptually, this index is a lookup table that maps each 
  term (word) to the set of docid values corresponding to records in the 
  %_content table that contain one or more occurrences of the term. To
  retrieve all documents that contain a specified term, the FTS3 module
  queries this index to determine the set of docid values for records that
  contain the term, then retrieves the required documents from the %_content
  table. Regardless of the schema of the FTS3 virtual table, the %_segments
  and %_segdir tables are always created as follows:

[Code {
  CREATE TABLE %_segments(
    blockid INTEGER PRIMARY KEY,       /* B-tree node id */
    block blob                         /* B-tree node data */

  CREATE TABLE %_segdir(
    level INTEGER,
    idx INTEGER,
    start_block INTEGER,               /* Blockid of first node in %_segments */
    leaves_end_block INTEGER,          /* Blockid of last leaf node in %_segments */
    end_block INTEGER,                 /* Blockid of last node in %_segments */
    root BLOB,                         /* B-tree root node */
    PRIMARY KEY(level, idx)

  The schema depicted above is not designed to store the full-text index 
  directly. Instead, it is used to one or more b-tree structures. There
  is one b-tree for each row in the %_segdir table. The %_segdir table
  row contains the root node and various meta-data associated with the
  b-tree structure, and the %_segments table contains all other (non-root)
  b-tree nodes. Each b-tree is referred to as a "segment". Once it has
  been created, a segment b-tree is never updated (although it may be
  deleted altogether).

  The keys used by each segment b-tree are terms (words). As well as the
  key, each segment b-tree entry has an associated "doclist" (document list).
  A doclist consists of zero or more entries, where each entry consists of:

  <li> A docid (document id), and
  <li> A list of term offsets, one for each occurrence of the term within
       the document. A term offset indicates the number of tokens (words)
       that occur before the term in question, not the number of characters
       or bytes. For example, the term offset of the term "war" in the
       phrase "Ancestral voices prophesying war!" is 3.

  Entries within a doclist are sorted by docid. Positions within a doclist
  entry are stored in ascending order.

  The contents of the logical full-text index is found by merging the
  contents of all segment b-trees. If a term is present in more than one
  segment b-tree, then it maps to the union of each individual doclist. If,
  for a single term, the same docid occurs in more than one doclist, then only
  the doclist that is part of the most recently created segment b-tree is 
  considered valid. 

  Multiple b-tree structures are used instead of a single b-tree to reduce
  the cost of inserting records into FTS3 tables. When a new record is 
  inserted into an FTS3 table that already contains a lot of data, it is
  likely that many of the terms in the new record are already present in
  a large number of existing records. If a single b-tree were used, then
  large doclist structures would have to be loaded from the database,
  amended to include the new docid and term-offset list, then written back
  to the database. Using multiple b-tree tables allows this to be avoided
  by creating a new b-tree which can be merged with the existing b-tree
  (or b-trees) later on. Merging of b-tree structures can be performed as
  a background task, or once a certain number of separate b-tree structures
  have been accumulated. Of course, this scheme makes queries more expensive
  (as the FTS3 code may have to look up individual terms in more than one
  b-tree and merge the results), but it has been found that in practice this
  overhead is often negligible.
[h2 "Variable Length Integer (varint) Format"]

  Integer values stored as part of segment b-tree nodes are encoded using the
  FTS3 varint format. This encoding is similar, but <b>not identical</b>, to the
  the <a href="fileformat.html#varint_format">SQLite varint format</a>.

  An encoded FTS3 varint consumes between one and ten bytes of space. The
  number of bytes required is determined by the sign and magnitude of the
  integer value encoded. More accurately, the number of bytes used to store
  the encoded integer depends on the position of the most significant set bit
  in the 64-bit twos-compliment representation of the integer value. Negative
  values always have the most significant bit set (the sign bit), and so are
  always stored using the full ten bytes. Positive integer values may be
  stored using less space.

  The final byte of an encoded FTS3 varint has its most significant bit 
  cleared. All preceding bytes have the most significant bit set. Data
  is stored in the remaining seven least signficant bits of each byte.
  The first byte of the encoded representation contains the least significant
  seven bits of the encoded integer value. The second byte of the encoded
  representation, if it is present, contains the seven next least significant
  bits of the integer value, and so on. The following table contains examples
  of encoded integer values:

  [Tr]<th>Decimal<th>Hexadecimal<th width=100%>Encoded Representation
  [Tr]<td>200815<td>0x000000000003106F<td>0x9C 0xA0 0x0C
  [Tr]<td>-1<td>0xFFFFFFFFFFFFFFFF<td>0xFF 0xFF 0xFF 0xFF 0xFF 0xFF 0xFF 0xFF 0xFF 0x01

[h2 "Segment B-Tree Format"]

  Segment b-trees are prefix-compressed b+-trees. There is one segment b-tree
  for each row in the %_segdir table (see above). The root node of the segment
  b-tree is stored as a blob in the "root" field of the corresponding row
  of the %_segdir table. All other nodes (if any exist) are stored in the 
  "blob" column of the %_segments table. Nodes within the %_segments table are
  identified by the integer value in the blockid field of the corresponding
  row. The following table describes the fields of the %_segdir table:

  [Tr]<th>Column           <th width=100%>Interpretion
  [Tr]<td>level            <td> 
    Between them, the contents of the "level" and "idx" fields define the
    relative age of the segment b-tree. The smaller the value stored in the
    "level" field, the more recently the segment b-tree was created. If two
    segment b-trees are of the same "level", the segment with the larger
    value stored in the "idx" column is more recent. The PRIMARY KEY constraint
    on the %_segdir table prevents any two segments from having the same value
    for both the "level" and "idx" fields.
  [Tr]<td>idx              <td> See above.
  [Tr]<td>start_block      <td>
    The blockid that corresponds to the node with the smallest blockid that 
    belongs to this segment b-tree. Or zero if the entire segment b-tree
    fits on the root node. If it exists, this node is always a leaf node.
  [Tr]<td>leaves_end_block <td>
    The blockid that corresponds to the leaf node with the largest blockid 
    that belongs to this segment b-tree. Or zero if the entire segment b-tree
    fits on the root node.
  [Tr]<td>end_block <td>
    The blockid that corresponds to the interior node with the largest 
    blockid that belongs to this segment b-tree.  Or zero if the entire segment
    b-tree fits on the root node. If it exists, this node is always an
    interior node.
  [Tr]<td>root             <td>
    Blob containing the root node of the segment b-tree.

  Apart from the root node, the nodes that make up a single segment b-tree are
  always stored using a contiguous sequence of blockids. Furthermore, the
  nodes that make up a single level of the b-tree are themselves stored as
  a contiguous block, in b-tree order. The contiguous sequence of blockids
  used to store the b-tree leaves are allocated starting with the blockid
  value stored in the "start_block" column of the corresponding %_segdir row,
  and finishing at the blockid value stored in the "leaves_end_block"
  field of the same row. It is therefore possible to iterate through all the
  leaves of a segment b-tree, in key order, by traversing the %_segments 
  table in blockid order from "start_block" to "leaves_end_block".  

[h3 "Segment B-Tree Leaf Nodes"]

  The following diagram depicts the format of a segment b-tree leaf node.

[Fig fts3_leaf_node.png "Segment B-Tree Leaf Node Format"]

  The first term stored on each node ("Term 1" in the figure above) is
  stored verbatim. Each subsequent term is prefix-compressed with respect
  to its predecessor. Terms are stored within a page in sorted (memcmp)

[h3 "Segment B-Tree Interior Nodes"]

  The following diagram depicts the format of a segment b-tree interior 
  (non-leaf) node.

[Fig fts3_interior_node.png "Segment B-Tree Interior Node Format"]

[h2 "Doclist Format"]

  A doclist consists of an array of 64-bit signed integers, serialized using
  the FTS3 varint format. Each doclist entry is made up of a series of two 
  or more integers, as follows:

  <li> The docid value. The first entry in a doclist contains the literal docid
       value. The first field of each subsequent doclist entry contains the 
       difference between the new docid and the previous one (always a positive 
  <li> Zero or more term-offset lists. A term-offset list is present for each
       column of the FTS3 virtual table that contains the term. A term-offset
       list consists of the following:
       <li> Constant value 1. This field is omitted for any term-offset list
            associated with column 0.
       <li> The column number (1 for the second leftmost column, etc.). This
            field is omitted for any term-offset list associated with column 0.
       <li> A list of term-offsets, sorted from smallest to largest. Instead
            of storing the term-offset value literally, each integer stored 
            is the difference between the current term-offset and the previous 
            one (or zero if the current term-offset is the first), plus 2.
  <li> Constant value 0.

[Fig fts3_doclist2.png "FTS3 Doclist Format"]

[Fig fts3_doclist.png "FTS3 Doclist Entry Format"]

  For doclists for which the term appears in more than one column of the FTS3
  virtual table, term-offset lists within the doclist are stored in column 
  number order. This ensures that the term-offset list associated with 
  column 0 (if any) is always first, allowing the first two fields of the
  term-offset list to be omitted in this case.