mirror of https://github.com/postgres/postgres
421 lines
13 KiB
Plaintext
421 lines
13 KiB
Plaintext
==========================================================================
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This module is deprecated in 7.4 version of PostgreSQL and will be
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obsoleted in 7.5. Please, use new tsearch2 contrib module.
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==========================================================================
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Tsearch contrib module contains implementation of new data type txtidx -
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a searchable data type (textual) with indexed access.
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All work was done by Teodor Sigaev (teodor@stack.net) and Oleg Bartunov
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(oleg@sai.msu.su).
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CHANGES:
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August 29, 2002
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Space usage and using CLUSTER command documented
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August 22, 2002
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Fix works with 'bad' queries
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August 13, 2002
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Use parser of OpenFTS v0.33.
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IMPORTANT NOTICE:
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This is a first step of our work on integration of OpenFTS
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full text search engine (http://openfts.sourceforge.net/) into
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PostgreSQL. It's based on our recent development of GiST
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(Generalized Search Tree) for PostgreSQL 7.2 (see our GiST page
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at http://www.sai.msu.su/~megera/postgres/gist/ for info about GiST)
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and will works only for PostgreSQL version 7.2 and later.
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We didn't try to implement a full-featured search engine with
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stable interfaces but rather experiment with various approaches.
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There are many issues remains (most of them just not documented or
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implemented) but we'd like to present a working prototype
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of full text search engine fully integrated into PostgreSQL to
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collect user's feedback and recommendations.
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INSTALLATION:
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cd contrib/tsearch
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gmake
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gmake install
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REGRESSION TEST:
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gmake installcheck
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USAGE:
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psql DATABASE < tsearch.sql (from contrib/tsearch)
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INTRODUCTION:
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This module provides an implementation of a new data type 'txtidx' which is
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a string of a space separated "words". "Words" with spaces
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should be enclosed in apostrophes and apostrophes inside a "word" should be
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escaped by backslash.
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This is quite different from OpenFTS approach which uses array
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of integers (ID of lexems) and requires storing of lexem-id pairs in database.
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One of the prominent benefit of this new approach is that it's possible now
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to perform full text search in a 'natural' way.
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Some examples:
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create table foo (
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titleidx txtidx
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);
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2 regular words:
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insert into foo values ( 'the are' );
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Word with space:
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insert into foo values ( 'the\\ are' );
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Words with apostrophe:
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insert into foo values ( 'value\'s this' );
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Complex word with apostrophe:
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insert into foo values ( 'value\'s this we \'PostgreSQL site\'' );
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select * from foo where titleidx @@ '\'PostgreSQL site\' | this';
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select * from foo where titleidx @@ 'value\'s | this';
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select * from foo where titleidx @@ '(the|this)&!we';
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test=# select 'two words'::txtidx;
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txtidx
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---------------
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'two' 'words'
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(1 row)
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test=# select 'single\\ word'::txtidx;
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txtidx
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---------------
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'single word'
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(1 row)
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FULL TEXT SEARCH:
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The basic idea of this data type is to use it for full text search inside
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database. If you have a 'text' column title and corresponding column
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titleidx of type 'txtidx', which contains the same information from
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text column, then search on title could be replaced by
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searching on titleidx which would be fast because of indexed access.
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As a real life example consider database with table 'titles' containing
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titles of mailing list postings in column 'title':
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create table titles (
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title text
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);
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Suppose, you already have a lot of titles and want to do full text search
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on them.
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First, you need to install contrib/tsearch module (see INSTALLATION and USAGE).
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Add column 'titleidx' of type txtidx, containing space separated words from
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title. It's possible to use function txt2txtidx(title) to fill 'titleidx'
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column (see notice 1):
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-- add titleidx column of type txtidx
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alter table titles add titleidx txtidx;
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update titles set titleidx=txt2txtidx(title);
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Create index on titleidx:
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create index t_idx on titles using gist(titleidx);
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and now you can search all titles with words 'patch' and 'gist':
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select title from titles where titleidx ## 'patch&gist';
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Here, ## is a new operation defined for type 'txtidx' which could use index
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(if exists) built on titleidx. This operator uses morphology to
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expand query, i.e.
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## 'patches&gist' will find titles with 'patch' and 'gist' also.
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If you want to provide query as is, use operator @@ instead:
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select title from titles where titleidx @@ 'patch&gist';
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but remember, that function txt2txtidx does uses morphology, so you need
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to fill column 'titleidx' using some another way. We hope in future releases
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provide more consistent and convenient interfaces.
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Query could contains boolean operators &,|,!,() with their usual meaning,
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for example: 'patch&gist&!cvs', 'patch|cvs'.
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Each operation ( ##, @@ ) requires appropriate query type -
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txtidx ## mquery_txt
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txtidx @@ query_txt
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To see what query actually will be used :
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test=# select 'patches&gist'::mquery_txt;
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mquery_txt
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------------------
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'patch' & 'gist'
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(1 row)
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test=# select 'patches&gist'::query_txt;
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query_txt
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--------------------
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'patches' & 'gist'
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(1 row)
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Notice the difference !
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You could use trigger to be sure column 'titleidx' is consistent
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with any changes in column 'title':
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create trigger txtidxupdate before update or insert on titles
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for each row execute procedure tsearch(titleidx, title);
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This trigger uses the same parser, dictionaries as function
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txt2txtidx (see notice 1).
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Current syntax allows creating trigger for several columns
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you want to be searchable:
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create trigger txtidxupdate before update or insert on titles
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for each row execute procedure tsearch(titleidx, title1, title2,... );
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Use function txtidxsize(titleidx) to get the number of "words" in column
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titleidx. To get total number of words in table titles:
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test=# select sum(txtidxsize(titleidx)) from titles;
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sum
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---------
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1917182
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(1 row)
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NOTICES:
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1.
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function txt2txtidx and trigger use parser, dictionaries coming with
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this contrib module on default. Parser is mostly the same as in OpenFTS and
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dictionaries are simple stemmers (sort of Lovin's stemmer which uses a
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longest match algorithm.) for english and russian languages. There is a perl
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script makedict/makedict.pl, which could be used to create specific
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dictionaries from files with endings and stop-words.
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Example files for english and russian languages are available
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from http://www.sai.msu.su/~megera/postgres/gist/tsearch/.
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Run script without parameters to see information about arguments and options.
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Example:
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cd makedict
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./makedict.pl -l LOCALNAME -e FILEENDINGS -s FILESTOPWORD \
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-o ../dict/YOURDICT.dct
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Another options of makedict.pl:
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-f do not execute tolower for any char
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-a function of checking stopword will be work after lemmatize,
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default is before
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You need to edit dict.h to use your dictionary and, probably,
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morph.c to change mapdict array.
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Don't forget to do
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make clean; make; make install
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2.
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txtidx doesn't preserve words ordering (this is not critical for searching)
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for performance reason, for example:
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test=# select 'page two'::txtidx;
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txtidx
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--------------
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'two' 'page'
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(1 row)
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3.
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Indexed access provided by txtidx data type isn't always good
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because of internal data structure we use (RD-Tree). Particularly,
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queries like '!gist' will be slower than just a sequential scan,
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because for such queries RD-Tree doesn't provides selectivity on internal
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nodes and all checks should be processed at leaf nodes, i.t. scan of
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full index. You may play with function query_tree to see how effective
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will be index usage:
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test=# select querytree( 'patch&gist'::query_txt );
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querytree
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------------------
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'patch' & 'gist'
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(1 row)
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This is an example of "good" query - index will effective for both words.
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test=# select querytree( 'patch&!gist'::query_txt );
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querytree
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-----------
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'patch'
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(1 row)
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This means that index is effective only to search word 'patch' and resulted
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rows will be checked against '!gist'.
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test=# select querytree( 'patch|!gist'::query_txt );
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querytree
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-----------
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T
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(1 row)
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test=# select querytree( '!gist'::query_txt );
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querytree
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-----------
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T
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(1 row)
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These two queries will be processed by scanning of full index !
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Very slow !
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4.
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Following selects produce the same result
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select title from titles where titleidx @@ 'patch&gist';
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select title from titles where titleidx @@ 'patch' and titleidx @@ 'gist';
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but the former will be more effective, because of internal optimization
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of query executor.
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TODO:
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Better configurability (as in OpenFTS)
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User's interfaces to parser, dictionaries ...
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Write documentation
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BENCHMARKS:
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We use test collection in our experiments which contains 377905
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titles from various mailing lists stored in our mailware
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project.
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All runs were performed on IBM ThinkPad T21 notebook with
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PIII 733 Mhz, 256 RAM, 20 Gb HDD, Linux 2.2.19, postgresql 7.2.dev
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We didn't do extensive benchmarking and all
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numbers provide for illustration. Actual performance
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is strongly depends on many factors (query, collection, dictionaries
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and hardware).
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Collection is available for download from
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http://www.sai.msu.su/~megera/postgres/gist/tsearch/mw_titles.gz
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(377905 titles from postgresql mailing lists, about 3Mb).
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0. install contrib/tsearch module
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1. createdb test
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2. psql test < tsearch.sql (from contrib/tsearch)
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3. zcat mw_titles.gz | psql test
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(it will creates table, copy test data and creates index)
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Database contains one table:
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test=# \d titles
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Table "titles"
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Column | Type | Modifiers
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----------+------------------------+-----------
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title | character varying(256) |
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titleidx | txtidx |
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Indexes: t_idx
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Index was created as:
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create index t_idx on titles using gist(titleidx);
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(notice: this operation takes about 14 minutes on my notebook)
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Typical select looks like:
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select title from titles where titleidx @@ 'patch&gist';
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Total number of lexems in collection : 1917182
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1. We trust index - we consider index is exact and no
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checking against tuples is necessary.
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update pg_amop set amopreqcheck = false where amopclaid =
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(select oid from pg_opclass where opcname = 'gist_txtidx_ops');
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using gist indices
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1: titleidx @@ 'patch&gist' 0.000u 0.000s 0m0.054s 0.00%
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2: titleidx @@ 'patch&gist' 0.020u 0.000s 0m0.045s 44.82%
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3: titleidx @@ 'patch&gist' 0.000u 0.000s 0m0.044s 0.00%
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using gist indices (morph)
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1: titleidx ## 'patch&gist' 0.000u 0.010s 0m0.046s 21.62%
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2: titleidx ## 'patch&gist' 0.010u 0.010s 0m0.046s 43.47%
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3: titleidx ## 'patch&gist' 0.000u 0.000s 0m0.046s 0.00%
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disable gist index
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1: titleidx @@ 'patch&gist' 0.000u 0.010s 0m1.601s 0.62%
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2: titleidx @@ 'patch&gist' 0.000u 0.000s 0m1.607s 0.00%
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3: titleidx @@ 'patch&gist' 0.010u 0.000s 0m1.607s 0.62%
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traditional like
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1: title ~* 'gist' and title ~* 'patch' 0.010u 0.000s 0m9.206s 0.10%
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2: title ~* 'gist' and title ~* 'patch' 0.000u 0.010s 0m9.205s 0.10%
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3: title ~* 'gist' and title ~* 'patch' 0.010u 0.000s 0m9.208s 0.10%
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2. Need to check results against tuples to avoid possible hash collision.
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update pg_amop set amopreqcheck = true where amopclaid =
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(select oid from pg_opclass where opcname = 'gist_txtidx_ops');
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using gist indices
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1: titleidx @@ 'patch&gist' 0.010u 0.000s 0m0.052s 19.26%
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2: titleidx @@ 'patch&gist' 0.000u 0.000s 0m0.045s 0.00%
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3: titleidx @@ 'patch&gist' 0.010u 0.000s 0m0.045s 22.39%
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using gist indices (morph)
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1: titleidx ## 'patch&gist' 0.000u 0.000s 0m0.046s 0.00%
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2: titleidx ## 'patch&gist' 0.000u 0.010s 0m0.046s 21.75%
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3: titleidx ## 'patch&gist' 0.020u 0.000s 0m0.047s 42.13%
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There are no visible difference between these 2 cases but your
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mileage may vary.
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NOTES:
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1. The size of txtidx column should be lesser than size of corresponding column.
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Below some real numbers from test database (link above).
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a) After loading data
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-rw------- 1 postgres users 23191552 Aug 29 14:08 53016937
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-rw------- 1 postgres users 81059840 Aug 29 14:08 52639027
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Table titles (52639027) occupies 80Mb, index on txtidx column (53016937)
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occupies 22Mb. Use contrib/oid2name to get mappings from oid to names.
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After doing
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test=# select title into titles_tmp from titles;
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SELECT
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I got size of table 'titles' without txtidx field
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-rw------- 1 postgres users 30105600 Aug 29 14:14 53016938
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So, txtidx column itself occupies about 50Mb.
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b) after running 'vacuum full analyze' I got:
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-rw------- 1 postgres users 30105600 Aug 29 14:26 53016938
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-rw------- 1 postgres users 36880384 Aug 29 14:26 53016937
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-rw------- 1 postgres users 51494912 Aug 29 14:26 52639027
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53016938 = titles_tmp
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So, actual size of 'txtidx' field is 20 Mb ! "quod erat demonstrandum"
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2. CLUSTER command is highly recommended if you need fast searching.
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For example:
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test=# cluster t_idx on titles;
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BUT ! In 7.2 CLUSTER command forgets about other indices and permissions,
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so you need be carefull and rebuild these indices and restore permissions
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after clustering. Also, clustering isn't dynamic, so you'd need to
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use CLUSTER from time to time. In 7.3 CLUSTER command should works
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fine.
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after clustering:
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-rw------- 1 postgres users 23404544 Aug 29 14:59 53394850
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-rw------- 1 postgres users 30105600 Aug 29 14:26 53016938
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-rw------- 1 postgres users 50995200 Aug 29 14:45 53394845
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pg@zen:/usr/local/pgsql/data/base/52638986$ oid2name -d test
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All tables from database "test":
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---------------------------------
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53394850 = t_idx
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53394845 = titles
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53016938 = titles_tmp
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