JSON data types are for storing JSON (JavaScript Object Notation)
data, as specified in RFC
7159. Such data can also be stored as text
, but
the JSON data types have the advantage of enforcing that each
stored value is valid according to the JSON rules. There are also
assorted JSON-specific functions and operators available for data stored
in these data types; see Section 9.15.
There are two JSON data types: json
and jsonb
.
They accept almost identical sets of values as
input. The major practical difference is one of efficiency. The
json
data type stores an exact copy of the input text,
which processing functions must reparse on each execution; while
jsonb
data is stored in a decomposed binary format that
makes it slightly slower to input due to added conversion
overhead, but significantly faster to process, since no reparsing
is needed. jsonb
also supports indexing, which can be a
significant advantage.
Because the json
type stores an exact copy of the input text, it
will preserve semantically-insignificant white space between tokens, as
well as the order of keys within JSON objects. Also, if a JSON object
within the value contains the same key more than once, all the key/value
pairs are kept. (The processing functions consider the last value as the
operative one.) By contrast, jsonb
does not preserve white
space, does not preserve the order of object keys, and does not keep
duplicate object keys. If duplicate keys are specified in the input,
only the last value is kept.
In general, most applications should prefer to store JSON data as
jsonb
, unless there are quite specialized needs, such as
legacy assumptions about ordering of object keys.
PostgreSQL allows only one character set encoding per database. It is therefore not possible for the JSON types to conform rigidly to the JSON specification unless the database encoding is UTF8. Attempts to directly include characters that cannot be represented in the database encoding will fail; conversely, characters that can be represented in the database encoding but not in UTF8 will be allowed.
RFC 7159 permits JSON strings to contain Unicode escape sequences
denoted by \u
. In the input
function for the XXXX
json
type, Unicode escapes are allowed
regardless of the database encoding, and are checked only for syntactic
correctness (that is, that four hex digits follow \u
).
However, the input function for jsonb
is stricter: it disallows
Unicode escapes for non-ASCII characters (those above U+007F
)
unless the database encoding is UTF8. The jsonb
type also
rejects \u0000
(because that cannot be represented in
PostgreSQL's text
type), and it insists
that any use of Unicode surrogate pairs to designate characters outside
the Unicode Basic Multilingual Plane be correct. Valid Unicode escapes
are converted to the equivalent ASCII or UTF8 character for storage;
this includes folding surrogate pairs into a single character.
Many of the JSON processing functions described
in Section 9.15 will convert Unicode escapes to
regular characters, and will therefore throw the same types of errors
just described even if their input is of type json
not jsonb
. The fact that the json
input function does
not make these checks may be considered a historical artifact, although
it does allow for simple storage (without processing) of JSON Unicode
escapes in a non-UTF8 database encoding. In general, it is best to
avoid mixing Unicode escapes in JSON with a non-UTF8 database encoding,
if possible.
When converting textual JSON input into jsonb
, the primitive
types described by RFC 7159 are effectively mapped onto
native PostgreSQL types, as shown
in Table 8.23.
Therefore, there are some minor additional constraints on what
constitutes valid jsonb
data that do not apply to
the json
type, nor to JSON in the abstract, corresponding
to limits on what can be represented by the underlying data type.
Notably, jsonb
will reject numbers that are outside the
range of the PostgreSQL numeric
data
type, while json
will not. Such implementation-defined
restrictions are permitted by RFC 7159. However, in
practice such problems are far more likely to occur in other
implementations, as it is common to represent JSON's number
primitive type as IEEE 754 double precision floating point
(which RFC 7159 explicitly anticipates and allows for).
When using JSON as an interchange format with such systems, the danger
of losing numeric precision compared to data originally stored
by PostgreSQL should be considered.
Conversely, as noted in the table there are some minor restrictions on the input format of JSON primitive types that do not apply to the corresponding PostgreSQL types.
Table 8.23. JSON primitive types and corresponding PostgreSQL types
JSON primitive type | PostgreSQL type | Notes |
---|---|---|
string | text | \u0000 is disallowed, as are non-ASCII Unicode
escapes if database encoding is not UTF8 |
number | numeric | NaN and infinity values are disallowed |
boolean | boolean | Only lowercase true and false spellings are accepted |
null | (none) | SQL NULL is a different concept |
The input/output syntax for the JSON data types is as specified in RFC 7159.
The following are all valid json
(or jsonb
) expressions:
-- Simple scalar/primitive value -- Primitive values can be numbers, quoted strings, true, false, or null SELECT '5'::json; -- Array of zero or more elements (elements need not be of same type) SELECT '[1, 2, "foo", null]'::json; -- Object containing pairs of keys and values -- Note that object keys must always be quoted strings SELECT '{"bar": "baz", "balance": 7.77, "active": false}'::json; -- Arrays and objects can be nested arbitrarily SELECT '{"foo": [true, "bar"], "tags": {"a": 1, "b": null}}'::json;
As previously stated, when a JSON value is input and then printed without
any additional processing, json
outputs the same text that was
input, while jsonb
does not preserve semantically-insignificant
details such as whitespace. For example, note the differences here:
SELECT '{"bar": "baz", "balance": 7.77, "active":false}'::json; json ------------------------------------------------- {"bar": "baz", "balance": 7.77, "active":false} (1 row) SELECT '{"bar": "baz", "balance": 7.77, "active":false}'::jsonb; jsonb -------------------------------------------------- {"bar": "baz", "active": false, "balance": 7.77} (1 row)
One semantically-insignificant detail worth noting is that
in jsonb
, numbers will be printed according to the behavior of the
underlying numeric
type. In practice this means that numbers
entered with E
notation will be printed without it, for
example:
SELECT '{"reading": 1.230e-5}'::json, '{"reading": 1.230e-5}'::jsonb; json | jsonb -----------------------+------------------------- {"reading": 1.230e-5} | {"reading": 0.00001230} (1 row)
However, jsonb
will preserve trailing fractional zeroes, as seen
in this example, even though those are semantically insignificant for
purposes such as equality checks.
Representing data as JSON can be considerably more flexible than the traditional relational data model, which is compelling in environments where requirements are fluid. It is quite possible for both approaches to co-exist and complement each other within the same application. However, even for applications where maximal flexibility is desired, it is still recommended that JSON documents have a somewhat fixed structure. The structure is typically unenforced (though enforcing some business rules declaratively is possible), but having a predictable structure makes it easier to write queries that usefully summarize a set of “documents” (datums) in a table.
JSON data is subject to the same concurrency-control considerations as any other data type when stored in a table. Although storing large documents is practicable, keep in mind that any update acquires a row-level lock on the whole row. Consider limiting JSON documents to a manageable size in order to decrease lock contention among updating transactions. Ideally, JSON documents should each represent an atomic datum that business rules dictate cannot reasonably be further subdivided into smaller datums that could be modified independently.
jsonb
Containment and Existence
Testing containment is an important capability of
jsonb
. There is no parallel set of facilities for the
json
type. Containment tests whether
one jsonb
document has contained within it another one.
These examples return true except as noted:
-- Simple scalar/primitive values contain only the identical value:
SELECT '"foo"'::jsonb @> '"foo"'::jsonb;
-- The array on the right side is contained within the one on the left:
SELECT '[1, 2, 3]'::jsonb @> '[1, 3]'::jsonb;
-- Order of array elements is not significant, so this is also true:
SELECT '[1, 2, 3]'::jsonb @> '[3, 1]'::jsonb;
-- Duplicate array elements don't matter either:
SELECT '[1, 2, 3]'::jsonb @> '[1, 2, 2]'::jsonb;
-- The object with a single pair on the right side is contained
-- within the object on the left side:
SELECT '{"product": "PostgreSQL", "version": 9.4, "jsonb": true}'::jsonb @> '{"version": 9.4}'::jsonb;
-- The array on the right side is not considered contained within the
-- array on the left, even though a similar array is nested within it:
SELECT '[1, 2, [1, 3]]'::jsonb @> '[1, 3]'::jsonb; -- yields false
-- But with a layer of nesting, it is contained:
SELECT '[1, 2, [1, 3]]'::jsonb @> '[[1, 3]]'::jsonb;
-- Similarly, containment is not reported here:
SELECT '{"foo": {"bar": "baz"}}'::jsonb @> '{"bar": "baz"}'::jsonb; -- yields false
-- A top-level key and an empty object is contained:
SELECT '{"foo": {"bar": "baz"}}'::jsonb @> '{"foo": {}}'::jsonb;
The general principle is that the contained object must match the containing object as to structure and data contents, possibly after discarding some non-matching array elements or object key/value pairs from the containing object. But remember that the order of array elements is not significant when doing a containment match, and duplicate array elements are effectively considered only once.
As a special exception to the general principle that the structures must match, an array may contain a primitive value:
-- This array contains the primitive string value: SELECT '["foo", "bar"]'::jsonb @> '"bar"'::jsonb; -- This exception is not reciprocal -- non-containment is reported here: SELECT '"bar"'::jsonb @> '["bar"]'::jsonb; -- yields false
jsonb
also has an existence operator, which is
a variation on the theme of containment: it tests whether a string
(given as a text
value) appears as an object key or array
element at the top level of the jsonb
value.
These examples return true except as noted:
-- String exists as array element: SELECT '["foo", "bar", "baz"]'::jsonb ? 'bar'; -- String exists as object key: SELECT '{"foo": "bar"}'::jsonb ? 'foo'; -- Object values are not considered: SELECT '{"foo": "bar"}'::jsonb ? 'bar'; -- yields false -- As with containment, existence must match at the top level: SELECT '{"foo": {"bar": "baz"}}'::jsonb ? 'bar'; -- yields false -- A string is considered to exist if it matches a primitive JSON string: SELECT '"foo"'::jsonb ? 'foo';
JSON objects are better suited than arrays for testing containment or existence when there are many keys or elements involved, because unlike arrays they are internally optimized for searching, and do not need to be searched linearly.
Because JSON containment is nested, an appropriate query can skip
explicit selection of sub-objects. As an example, suppose that we have
a doc
column containing objects at the top level, with
most objects containing tags
fields that contain arrays of
sub-objects. This query finds entries in which sub-objects containing
both "term":"paris"
and "term":"food"
appear,
while ignoring any such keys outside the tags
array:
SELECT doc->'site_name' FROM websites WHERE doc @> '{"tags":[{"term":"paris"}, {"term":"food"}]}';
One could accomplish the same thing with, say,
SELECT doc->'site_name' FROM websites WHERE doc->'tags' @> '[{"term":"paris"}, {"term":"food"}]';
but that approach is less flexible, and often less efficient as well.
On the other hand, the JSON existence operator is not nested: it will only look for the specified key or array element at top level of the JSON value.
The various containment and existence operators, along with all other JSON operators and functions are documented in Section 9.15.
jsonb
Indexing
GIN indexes can be used to efficiently search for
keys or key/value pairs occurring within a large number of
jsonb
documents (datums).
Two GIN “operator classes” are provided, offering different
performance and flexibility trade-offs.
The default GIN operator class for jsonb
supports queries with
top-level key-exists operators ?
, ?&
and ?|
operators and path/value-exists operator
@>
.
(For details of the semantics that these operators
implement, see Table 9.44.)
An example of creating an index with this operator class is:
CREATE INDEX idxgin ON api USING GIN (jdoc);
The non-default GIN operator class jsonb_path_ops
supports indexing the @>
operator only.
An example of creating an index with this operator class is:
CREATE INDEX idxginp ON api USING GIN (jdoc jsonb_path_ops);
Consider the example of a table that stores JSON documents retrieved from a third-party web service, with a documented schema definition. A typical document is:
{ "guid": "9c36adc1-7fb5-4d5b-83b4-90356a46061a", "name": "Angela Barton", "is_active": true, "company": "Magnafone", "address": "178 Howard Place, Gulf, Washington, 702", "registered": "2009-11-07T08:53:22 +08:00", "latitude": 19.793713, "longitude": 86.513373, "tags": [ "enim", "aliquip", "qui" ] }
We store these documents in a table named api
,
in a jsonb
column named jdoc
.
If a GIN index is created on this column,
queries like the following can make use of the index:
-- Find documents in which the key "company" has value "Magnafone" SELECT jdoc->'guid', jdoc->'name' FROM api WHERE jdoc @> '{"company": "Magnafone"}';
However, the index could not be used for queries like the
following, because though the operator ?
is indexable,
it is not applied directly to the indexed column jdoc
:
-- Find documents in which the key "tags" contains key or array element "qui" SELECT jdoc->'guid', jdoc->'name' FROM api WHERE jdoc -> 'tags' ? 'qui';
Still, with appropriate use of expression indexes, the above
query can use an index. If querying for particular items within
the "tags"
key is common, defining an index like this
may be worthwhile:
CREATE INDEX idxgintags ON api USING GIN ((jdoc -> 'tags'));
Now, the WHERE
clause jdoc -> 'tags' ? 'qui'
will be recognized as an application of the indexable
operator ?
to the indexed
expression jdoc -> 'tags'
.
(More information on expression indexes can be found in Section 11.7.)
Another approach to querying is to exploit containment, for example:
-- Find documents in which the key "tags" contains array element "qui" SELECT jdoc->'guid', jdoc->'name' FROM api WHERE jdoc @> '{"tags": ["qui"]}';
A simple GIN index on the jdoc
column can support this
query. But note that such an index will store copies of every key and
value in the jdoc
column, whereas the expression index
of the previous example stores only data found under
the tags
key. While the simple-index approach is far more
flexible (since it supports queries about any key), targeted expression
indexes are likely to be smaller and faster to search than a simple
index.
Although the jsonb_path_ops
operator class supports
only queries with the @>
operator, it has notable
performance advantages over the default operator
class jsonb_ops
. A jsonb_path_ops
index is usually much smaller than a jsonb_ops
index over the same data, and the specificity of searches is better,
particularly when queries contain keys that appear frequently in the
data. Therefore search operations typically perform better
than with the default operator class.
The technical difference between a jsonb_ops
and a jsonb_path_ops
GIN index is that the former
creates independent index items for each key and value in the data,
while the latter creates index items only for each value in the
data.
[6]
Basically, each jsonb_path_ops
index item is
a hash of the value and the key(s) leading to it; for example to index
{"foo": {"bar": "baz"}}
, a single index item would
be created incorporating all three of foo
, bar
,
and baz
into the hash value. Thus a containment query
looking for this structure would result in an extremely specific index
search; but there is no way at all to find out whether foo
appears as a key. On the other hand, a jsonb_ops
index would create three index items representing foo
,
bar
, and baz
separately; then to do the
containment query, it would look for rows containing all three of
these items. While GIN indexes can perform such an AND search fairly
efficiently, it will still be less specific and slower than the
equivalent jsonb_path_ops
search, especially if
there are a very large number of rows containing any single one of the
three index items.
A disadvantage of the jsonb_path_ops
approach is
that it produces no index entries for JSON structures not containing
any values, such as {"a": {}}
. If a search for
documents containing such a structure is requested, it will require a
full-index scan, which is quite slow. jsonb_path_ops
is
therefore ill-suited for applications that often perform such searches.
jsonb
also supports btree
and hash
indexes. These are usually useful only if it's important to check
equality of complete JSON documents.
The btree
ordering for jsonb
datums is seldom
of great interest, but for completeness it is:
Object
>Array
>Boolean
>Number
>String
>Null
Object with n pairs
>object with n - 1 pairs
Array with n elements
>array with n - 1 elements
Objects with equal numbers of pairs are compared in the order:
key-1
,value-1
,key-2
...
Note that object keys are compared in their storage order; in particular, since shorter keys are stored before longer keys, this can lead to results that might be unintuitive, such as:
{ "aa": 1, "c": 1} > {"b": 1, "d": 1}
Similarly, arrays with equal numbers of elements are compared in the order:
element-1
,element-2
...
Primitive JSON values are compared using the same comparison rules as for the underlying PostgreSQL data type. Strings are compared using the default database collation.
Additional extensions are available that implement transforms for the
jsonb
type for different procedural languages.
The extensions for PL/Perl are called jsonb_plperl
and
jsonb_plperlu
. If you use them, jsonb
values are mapped to Perl arrays, hashes, and scalars, as appropriate.
The extensions for PL/Python are called jsonb_plpythonu
,
jsonb_plpython2u
, and
jsonb_plpython3u
(see Section 46.1 for the PL/Python naming convention). If you
use them, jsonb
values are mapped to Python dictionaries,
lists, and scalars, as appropriate.
[6] For this purpose, the term “value” includes array elements, though JSON terminology sometimes considers array elements distinct from values within objects.