ltree
ltree
This module implements a data type ltree for representing
labels of data stored in a hierarchical tree-like structure.
Extensive facilities for searching through label trees are provided.
This module is considered trusted
, that is, it can be
installed by non-superusers who have CREATE privilege
on the current database.
Definitions
A label is a sequence of alphanumeric characters
and underscores (for example, in C locale the characters
A-Za-z0-9_ are allowed).
Labels must be less than 256 characters long.
Examples: 42, Personal_Services
A label path is a sequence of zero or more
labels separated by dots, for example L1.L2.L3, representing
a path from the root of a hierarchical tree to a particular node. The
length of a label path cannot exceed 65535 labels.
Example: Top.Countries.Europe.Russia
The ltree module provides several data types:
ltree stores a label path.
lquery represents a regular-expression-like pattern
for matching ltree values. A simple word matches that
label within a path. A star symbol (*) matches zero
or more labels. These can be joined with dots to form a pattern that
must match the whole label path. For example:
foo Match the exact label path foo
*.foo.* Match any label path containing the label foo
*.foo Match any label path whose last label is foo
Both star symbols and simple words can be quantified to restrict how many
labels they can match:
*{n} Match exactly n labels
*{n,} Match at least n labels
*{n,m} Match at least n but not more than m labels
*{,m} Match at most m labels — same as *{0,m}
foo{n,m} Match at least n but not more than m occurrences of foo
foo{,} Match any number of occurrences of foo, including zero
In the absence of any explicit quantifier, the default for a star symbol
is to match any number of labels (that is, {,}) while
the default for a non-star item is to match exactly once (that
is, {1}).
There are several modifiers that can be put at the end of a non-star
lquery item to make it match more than just the exact match:
@ Match case-insensitively, for example a@ matches A
* Match any label with this prefix, for example foo* matches foobar
% Match initial underscore-separated words
The behavior of % is a bit complicated. It tries to match
words rather than the entire label. For example
foo_bar% matches foo_bar_baz but not
foo_barbaz. If combined with *, prefix
matching applies to each word separately, for example
foo_bar%* matches foo1_bar2_baz but
not foo1_br2_baz.
Also, you can write several possibly-modified non-star items separated with
| (OR) to match any of those items, and you can put
! (NOT) at the start of a non-star group to match any
label that doesn't match any of the alternatives. A quantifier, if any,
goes at the end of the group; it means some number of matches for the
group as a whole (that is, some number of labels matching or not matching
any of the alternatives).
Here's an annotated example of lquery:
Top.*{0,2}.sport*@.!football|tennis{1,}.Russ*|Spain
a. b. c. d. e.
This query will match any label path that:
begins with the label Top
and next has zero to two labels before
a label beginning with the case-insensitive prefix sport
then has one or more labels, none of which
match football nor tennis
and then ends with a label beginning with Russ or
exactly matching Spain.
ltxtquery represents a full-text-search-like
pattern for matching ltree values. An
ltxtquery value contains words, possibly with the
modifiers @, *, % at the end;
the modifiers have the same meanings as in lquery.
Words can be combined with & (AND),
| (OR), ! (NOT), and parentheses.
The key difference from
lquery is that ltxtquery matches words without
regard to their position in the label path.
Here's an example ltxtquery:
Europe & Russia*@ & !Transportation
This will match paths that contain the label Europe and
any label beginning with Russia (case-insensitive),
but not paths containing the label Transportation.
The location of these words within the path is not important.
Also, when % is used, the word can be matched to any
underscore-separated word within a label, regardless of position.
Note: ltxtquery allows whitespace between symbols, but
ltree and lquery do not.
Operators and Functions
Type ltree has the usual comparison operators
=, <>,
<, >, <=, >=.
Comparison sorts in the order of a tree traversal, with the children
of a node sorted by label text. In addition, the specialized
operators shown in are available.
ltree Operators
Operator
Description
ltree @> ltree
boolean
Is left argument an ancestor of right (or equal)?
ltree <@ ltree
boolean
Is left argument a descendant of right (or equal)?
ltree ~ lquery
boolean
lquery ~ ltree
boolean
Does ltree match lquery?
ltree ? lquery[]
boolean
lquery[] ? ltree
boolean
Does ltree match any lquery in array?
ltree @ ltxtquery
boolean
ltxtquery @ ltree
boolean
Does ltree match ltxtquery?
ltree || ltree
ltree
Concatenates ltree paths.
ltree || text
ltree
text || ltree
ltree
Converts text to ltree and concatenates.
ltree[] @> ltree
boolean
ltree <@ ltree[]
boolean
Does array contain an ancestor of ltree?
ltree[] <@ ltree
boolean
ltree @> ltree[]
boolean
Does array contain a descendant of ltree?
ltree[] ~ lquery
boolean
lquery ~ ltree[]
boolean
Does array contain any path matching lquery?
ltree[] ? lquery[]
boolean
lquery[] ? ltree[]
boolean
Does ltree array contain any path matching
any lquery?
ltree[] @ ltxtquery
boolean
ltxtquery @ ltree[]
boolean
Does array contain any path matching ltxtquery?
ltree[] ?@> ltree
ltree
Returns first array entry that is an ancestor of ltree,
or NULL if none.
ltree[] ?<@ ltree
ltree
Returns first array entry that is a descendant of ltree,
or NULL if none.
ltree[] ?~ lquery
ltree
Returns first array entry that matches lquery,
or NULL if none.
ltree[] ?@ ltxtquery
ltree
Returns first array entry that matches ltxtquery,
or NULL if none.
The operators <@, @>,
@ and ~ have analogues
^<@, ^@>, ^@,
^~, which are the same except they do not use
indexes. These are useful only for testing purposes.
The available functions are shown in .
ltree Functions
Function
Description
Example(s)
subltree
subltree ( ltree, start integer, end integer )
ltree
Returns subpath of ltree from
position start to
position end-1 (counting from 0).
subltree('Top.Child1.Child2', 1, 2)
Child1
subpath
subpath ( ltree, offset integer, len integer )
ltree
Returns subpath of ltree starting at
position offset, with
length len. If offset
is negative, subpath starts that far from the end of the path.
If len is negative, leaves that many labels off
the end of the path.
subpath('Top.Child1.Child2', 0, 2)
Top.Child1
subpath ( ltree, offset integer )
ltree
Returns subpath of ltree starting at
position offset, extending to end of path.
If offset is negative, subpath starts that far
from the end of the path.
subpath('Top.Child1.Child2', 1)
Child1.Child2
nlevel
nlevel ( ltree )
integer
Returns number of labels in path.
nlevel('Top.Child1.Child2')
3
index
index ( a ltree, b ltree )
integer
Returns position of first occurrence of b in
a, or -1 if not found.
index('0.1.2.3.5.4.5.6.8.5.6.8', '5.6')
6
index ( a ltree, b ltree, offset integer )
integer
Returns position of first occurrence of b
in a, or -1 if not found. The search starts at
position offset;
negative offset means
start -offset labels from the end of the path.
index('0.1.2.3.5.4.5.6.8.5.6.8', '5.6', -4)
9
text2ltree
text2ltree ( text )
ltree
Casts text to ltree.
ltree2text
ltree2text ( ltree )
text
Casts ltree to text.
lca
lca ( ltree , ltree , ... )
ltree
Computes longest common ancestor of paths
(up to 8 arguments are supported).
lca('1.2.3', '1.2.3.4.5.6')
1.2
lca ( ltree[] )
ltree
Computes longest common ancestor of paths in array.
lca(array['1.2.3'::ltree,'1.2.3.4'])
1.2
Indexes
ltree supports several types of indexes that can speed
up the indicated operators:
B-tree index over ltree:
<, <=, =,
>=, >
GiST index over ltree (gist_ltree_ops
opclass):
<, <=, =,
>=, >,
@>, <@,
@, ~, ?
gist_ltree_ops GiST opclass approximates a set of
path labels as a bitmap signature. Its optional integer parameter
siglen determines the
signature length in bytes. The default signature length is 8 bytes.
The length must be a positive multiple of int alignment
(4 bytes on most machines)) up to 2024. Longer
signatures lead to a more precise search (scanning a smaller fraction of the index and
fewer heap pages), at the cost of a larger index.
Example of creating such an index with the default signature length of 8 bytes:
CREATE INDEX path_gist_idx ON test USING GIST (path);
Example of creating such an index with a signature length of 100 bytes:
CREATE INDEX path_gist_idx ON test USING GIST (path gist_ltree_ops(siglen=100));
GiST index over ltree[] (gist__ltree_ops
opclass):
ltree[] <@ ltree, ltree @> ltree[],
@, ~, ?
gist__ltree_ops GiST opclass works similarly to
gist_ltree_ops and also takes signature length as
a parameter. The default value of siglen in
gist__ltree_ops is 28 bytes.
Example of creating such an index with the default signature length of 28 bytes:
CREATE INDEX path_gist_idx ON test USING GIST (array_path);
Example of creating such an index with a signature length of 100 bytes:
CREATE INDEX path_gist_idx ON test USING GIST (array_path gist__ltree_ops(siglen=100));
Note: This index type is lossy.
Example
This example uses the following data (also available in file
contrib/ltree/ltreetest.sql in the source distribution):
CREATE TABLE test (path ltree);
INSERT INTO test VALUES ('Top');
INSERT INTO test VALUES ('Top.Science');
INSERT INTO test VALUES ('Top.Science.Astronomy');
INSERT INTO test VALUES ('Top.Science.Astronomy.Astrophysics');
INSERT INTO test VALUES ('Top.Science.Astronomy.Cosmology');
INSERT INTO test VALUES ('Top.Hobbies');
INSERT INTO test VALUES ('Top.Hobbies.Amateurs_Astronomy');
INSERT INTO test VALUES ('Top.Collections');
INSERT INTO test VALUES ('Top.Collections.Pictures');
INSERT INTO test VALUES ('Top.Collections.Pictures.Astronomy');
INSERT INTO test VALUES ('Top.Collections.Pictures.Astronomy.Stars');
INSERT INTO test VALUES ('Top.Collections.Pictures.Astronomy.Galaxies');
INSERT INTO test VALUES ('Top.Collections.Pictures.Astronomy.Astronauts');
CREATE INDEX path_gist_idx ON test USING GIST (path);
CREATE INDEX path_idx ON test USING BTREE (path);
Now, we have a table test populated with data describing
the hierarchy shown below:
Top
/ | \
Science Hobbies Collections
/ | \
Astronomy Amateurs_Astronomy Pictures
/ \ |
Astrophysics Cosmology Astronomy
/ | \
Galaxies Stars Astronauts
We can do inheritance:
ltreetest=> SELECT path FROM test WHERE path <@ 'Top.Science';
path
------------------------------------
Top.Science
Top.Science.Astronomy
Top.Science.Astronomy.Astrophysics
Top.Science.Astronomy.Cosmology
(4 rows)
Here are some examples of path matching:
ltreetest=> SELECT path FROM test WHERE path ~ '*.Astronomy.*';
path
-----------------------------------------------
Top.Science.Astronomy
Top.Science.Astronomy.Astrophysics
Top.Science.Astronomy.Cosmology
Top.Collections.Pictures.Astronomy
Top.Collections.Pictures.Astronomy.Stars
Top.Collections.Pictures.Astronomy.Galaxies
Top.Collections.Pictures.Astronomy.Astronauts
(7 rows)
ltreetest=> SELECT path FROM test WHERE path ~ '*.!pictures@.Astronomy.*';
path
------------------------------------
Top.Science.Astronomy
Top.Science.Astronomy.Astrophysics
Top.Science.Astronomy.Cosmology
(3 rows)
Here are some examples of full text search:
ltreetest=> SELECT path FROM test WHERE path @ 'Astro*% & !pictures@';
path
------------------------------------
Top.Science.Astronomy
Top.Science.Astronomy.Astrophysics
Top.Science.Astronomy.Cosmology
Top.Hobbies.Amateurs_Astronomy
(4 rows)
ltreetest=> SELECT path FROM test WHERE path @ 'Astro* & !pictures@';
path
------------------------------------
Top.Science.Astronomy
Top.Science.Astronomy.Astrophysics
Top.Science.Astronomy.Cosmology
(3 rows)
Path construction using functions:
ltreetest=> SELECT subpath(path,0,2)||'Space'||subpath(path,2) FROM test WHERE path <@ 'Top.Science.Astronomy';
?column?
------------------------------------------
Top.Science.Space.Astronomy
Top.Science.Space.Astronomy.Astrophysics
Top.Science.Space.Astronomy.Cosmology
(3 rows)
We could simplify this by creating an SQL function that inserts a label
at a specified position in a path:
CREATE FUNCTION ins_label(ltree, int, text) RETURNS ltree
AS 'select subpath($1,0,$2) || $3 || subpath($1,$2);'
LANGUAGE SQL IMMUTABLE;
ltreetest=> SELECT ins_label(path,2,'Space') FROM test WHERE path <@ 'Top.Science.Astronomy';
ins_label
------------------------------------------
Top.Science.Space.Astronomy
Top.Science.Space.Astronomy.Astrophysics
Top.Science.Space.Astronomy.Cosmology
(3 rows)
Transforms
The ltree_plpython3u extension implements transforms for
the ltree type for PL/Python. If installed and specified when
creating a function, ltree values are mapped to Python lists.
(The reverse is currently not supported, however.)
It is strongly recommended that the transform extension be installed in
the same schema as ltree. Otherwise there are
installation-time security hazards if a transform extension's schema
contains objects defined by a hostile user.
Authors
All work was done by Teodor Sigaev (teodor@stack.net) and
Oleg Bartunov (oleg@sai.msu.su). See
for
additional information. Authors would like to thank Eugeny Rodichev for
helpful discussions. Comments and bug reports are welcome.