JMESPath ======== .. image:: https://badges.gitter.im/Join Chat.svg :target: https://gitter.im/jmespath/chat .. image:: https://secure.travis-ci.org/jmespath/jmespath.py.png?branch=develop :target: http://travis-ci.org/jmespath/jmespath.py .. image:: https://codecov.io/github/jmespath/jmespath.py/coverage.svg?branch=develop :target: https://codecov.io/github/jmespath/jmespath.py?branch=develop JMESPath (pronounced "james path") allows you to declaratively specify how to extract elements from a JSON document. For example, given this document:: {"foo": {"bar": "baz"}} The jmespath expression ``foo.bar`` will return "baz". JMESPath also supports: Referencing elements in a list. Given the data:: {"foo": {"bar": ["one", "two"]}} The expression: ``foo.bar[0]`` will return "one". You can also reference all the items in a list using the ``*`` syntax:: {"foo": {"bar": [{"name": "one"}, {"name": "two"}]}} The expression: ``foo.bar[*].name`` will return ["one", "two"]. Negative indexing is also supported (-1 refers to the last element in the list). Given the data above, the expression ``foo.bar[-1].name`` will return "two". The ``*`` can also be used for hash types:: {"foo": {"bar": {"name": "one"}, "baz": {"name": "two"}}} The expression: ``foo.*.name`` will return ["one", "two"]. API === The ``jmespath.py`` library has two functions that operate on python data structures. You can use ``search`` and give it the jmespath expression and the data: .. code:: python >>> import jmespath >>> path = jmespath.search('foo.bar', {'foo': {'bar': 'baz'}}) 'baz' Similar to the ``re`` module, you can use the ``compile`` function to compile the JMESPath expression and use this parsed expression to perform repeated searches: .. code:: python >>> import jmespath >>> expression = jmespath.compile('foo.bar') >>> expression.search({'foo': {'bar': 'baz'}}) 'baz' >>> expression.search({'foo': {'bar': 'other'}}) 'other' This is useful if you're going to use the same jmespath expression to search multiple documents. This avoids having to reparse the JMESPath expression each time you search a new document. Options ------- You can provide an instance of ``jmespath.Options`` to control how a JMESPath expression is evaluated. The most common scenario for using an ``Options`` instance is if you want to have ordered output of your dict keys. To do this you can use either of these options: .. code:: python >>> import jmespath >>> jmespath.search('{a: a, b: b}, ... mydata, ... jmespath.Options(dict_cls=collections.OrderedDict)) >>> import jmespath >>> parsed = jmespath.compile('{a: a, b: b}') >>> parsed.search('{a: a, b: b}, ... mydata, ... jmespath.Options(dict_cls=collections.OrderedDict)) Custom Functions ~~~~~~~~~~~~~~~~ The JMESPath language has numerous `built-in functions `__, but it is also possible to add your own custom functions. Keep in mind that custom function support in jmespath.py is experimental and the API may change based on feedback. **If you have a custom function that you've found useful, consider submitting it to jmespath.site and propose that it be added to the JMESPath language.** You can submit proposals `here `__. To create custom functions: * Create a subclass of ``jmespath.functions.Functions``. * Create a method with the name ``_func_``. * Apply the ``jmespath.functions.signature`` decorator that indicates the expected types of the function arguments. * Provide an instance of your subclass in a ``jmespath.Options`` object. Below are a few examples: .. code:: python import jmespath from jmespath import functions # 1. Create a subclass of functions.Functions. # The function.Functions base class has logic # that introspects all of its methods and automatically # registers your custom functions in its function table. class CustomFunctions(functions.Functions): # 2 and 3. Create a function that starts with _func_ # and decorate it with @signature which indicates its # expected types. # In this example, we're creating a jmespath function # called "unique_letters" that accepts a single argument # with an expected type "string". @functions.signature({'types': ['string']}) def _func_unique_letters(self, s): # Given a string s, return a sorted # string of unique letters: 'ccbbadd' -> 'abcd' return ''.join(sorted(set(s))) # Here's another example. This is creating # a jmespath function called "my_add" that expects # two arguments, both of which should be of type number. @functions.signature({'types': ['number']}, {'types': ['number']}) def _func_my_add(self, x, y): return x + y # 4. Provide an instance of your subclass in a Options object. options = jmespath.Options(custom_functions=CustomFunctions()) # Provide this value to jmespath.search: # This will print 3 print( jmespath.search( 'my_add(`1`, `2`)', {}, options=options) ) # This will print "abcd" print( jmespath.search( 'foo.bar | unique_letters(@)', {'foo': {'bar': 'ccbbadd'}}, options=options) ) Again, if you come up with useful functions that you think make sense in the JMESPath language (and make sense to implement in all JMESPath libraries, not just python), please let us know at `jmespath.site `__. Specification ============= If you'd like to learn more about the JMESPath language, you can check out the `JMESPath tutorial `__. Also check out the `JMESPath examples page `__ for examples of more complex jmespath queries. The grammar is specified using ABNF, as described in `RFC4234 `_. You can find the most up to date `grammar for JMESPath here `__. You can read the full `JMESPath specification here `__. Testing ======= In addition to the unit tests for the jmespath modules, there is a ``tests/compliance`` directory that contains .json files with test cases. This allows other implementations to verify they are producing the correct output. Each json file is grouped by feature. Discuss ======= Join us on our `Gitter channel `__ if you want to chat or if you have any questions.