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  • GiST and GIN Index Types

    PostgreSQL: Documentation: 8.3: GiST and GIN Index Types

    12.9. GiST and GIN Index
    Types

    There are two kinds of indexes that can be used to speed up
    full text searches. Note that indexes are not mandatory for full
    text searching, but in cases where a column is searched on a
    regular basis, an index will usually be desirable.

           CREATE INDEX name ON table USING gist(column);
    

    Creates a GiST (Generalized Search Tree)-based index.
    The column can be of
    tsvector or tsquery type.

           CREATE INDEX name ON table USING gin(column);
    

    Creates a GIN (Generalized Inverted Index)-based index.
    The column must be of
    tsvector type.

    There are substantial performance differences between the two
    index types, so it is important to understand which to use.

    A GiST index is lossy, meaning that
    the index may produce false matches, and it is necessary to check
    the actual table row to eliminate such false matches.
    PostgreSQL does this
    automatically; for example, in the query plan below, the
    Filter: line indicates the index output
    will be rechecked:

    EXPLAIN SELECT * FROM apod WHERE textsearch @@ to_tsquery('supernovae');
                                   QUERY PLAN
    -------------------------------------------------------------------------
     Index Scan using textsearch_gidx on apod  (cost=0.00..12.29 rows=2 width=1469)
       Index Cond: (textsearch @@ '''supernova'''::tsquery)
       Filter: (textsearch @@ '''supernova'''::tsquery)
    

    GiST indexes are lossy because each document is represented in
    the index by a fixed-length signature. The signature is generated
    by hashing each word into a random bit in an n-bit string, with
    all these bits OR-ed together to produce an n-bit document
    signature. When two words hash to the same bit position there
    will be a false match. If all words in the query have matches
    (real or false) then the table row must be retrieved to see if
    the match is correct.

    Lossiness causes performance degradation due to useless
    fetches of table records that turn out to be false matches. Since
    random access to table records is slow, this limits the
    usefulness of GiST indexes. The likelihood of false matches
    depends on several factors, in particular the number of unique
    words, so using dictionaries to reduce this number is
    recommended.

    GIN indexes are not lossy but their performance depends
    logarithmically on the number of unique words.

    Actually, GIN indexes store only the words (lexemes) of
    tsvector values, and not their weight
    labels. Thus, while a GIN index can be considered non-lossy for a
    query that does not specify weights, it is lossy for one that
    does. Thus a table row recheck is needed when using a query that
    involves weights. Unfortunately, in the current design of
    PostgreSQL, whether a recheck is
    needed is a static property of a particular operator, and not
    something that can be enabled or disabled on-the-fly depending on
    the values given to the operator. To deal with this situation
    without imposing the overhead of rechecks on queries that do not
    need them, the following approach has been adopted:

    • The standard text match operator @@ is marked as non-lossy for GIN indexes.

    • An additional match operator @@@
      is provided, and marked as lossy for GIN indexes. This
      operator behaves exactly like @@
      otherwise.

    • When a GIN index search is initiated with the @@ operator, the index support code will throw
      an error if the query specifies any weights. This protects
      against giving wrong answers due to failure to recheck the
      weights.

    In short, you must use @@@ rather
    than @@ to perform GIN index searches on
    queries that involve weight restrictions. For queries that do not
    have weight restrictions, either operator will work, but
    @@ will be faster. This awkwardness will
    probably be addressed in a future release of PostgreSQL.

    In choosing which index type to use, GiST or GIN, consider
    these performance differences:

    • GIN index lookups are about three times faster than
      GiST

    • GIN indexes take about three times longer to build than
      GiST

    • GIN indexes are about ten times slower to update than
      GiST

    • GIN indexes are two-to-three times larger than GiST

    As a rule of thumb, GIN
    indexes are best for static data because lookups are faster. For
    dynamic data, GiST indexes are faster to update. Specifically,
    GiST indexes are very good for
    dynamic data and fast if the number of unique words (lexemes) is
    under 100,000, while GIN
    indexes will handle 100,000+ lexemes better but are slower to
    update.

    Note that GIN index build
    time can often be improved by increasing maintenance_work_mem,
    while GiST index build time is
    not sensitive to that parameter.

    Partitioning of big collections and the proper use of GiST and
    GIN indexes allows the implementation of very fast searches with
    online update. Partitioning can be done at the database level
    using table inheritance and constraint_exclusion, or by distributing documents
    over servers and collecting search results using the contrib/dblink extension module. The latter is
    possible because ranking functions use only local
    information.

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  • 原文地址:https://www.cnblogs.com/lexus/p/2543331.html
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