README.rst - platform/external/python/parse_type - Git at Google

 ===============================================================================
 parse_type
 ===============================================================================

 .. image:: https://img.shields.io/travis/jenisys/parse_type/master.svg
     :target: https://travis-ci.org/jenisys/parse_type
     :alt: Travis CI Build Status

 .. image:: https://img.shields.io/pypi/v/parse_type.svg
     :target: https://pypi.python.org/pypi/parse_type
     :alt: Latest Version

 .. image:: https://img.shields.io/pypi/dm/parse_type.svg
     :target: https://pypi.python.org/pypi/parse_type
     :alt: Downloads

 .. image:: https://img.shields.io/pypi/l/parse_type.svg
     :target: https://pypi.python.org/pypi/parse_type/
     :alt: License


 `parse_type`_ extends the `parse`_ module (opposite of `string.format()`_)
 with the following features:

 * build type converters for common use cases (enum/mapping, choice)
 * build a type converter with a cardinality constraint (0..1, 0..*, 1..*)
     from the type converter with cardinality=1.
 * compose a type converter from other type converters
 * an extended parser that supports the CardinalityField naming schema
     and creates missing type variants (0..1, 0..*, 1..*) from the
     primary type converter

 .. _parse_type: http://pypi.python.org/pypi/parse_type
 .. _parse:      http://pypi.python.org/pypi/parse
 .. _`string.format()`: http://docs.python.org/library/string.html#format-string-syntax


 Definitions
 -------------------------------------------------------------------------------

 *type converter*
     A type converter function that converts a textual representation
     of a value type into instance of this value type.
     In addition, a type converter function is often annotated with attributes
     that allows the `parse`_ module to use it in a generic way.
     A type converter is also called a *parse_type* (a definition used here).

 *cardinality field*
     A naming convention for related types that differ in cardinality.
     A cardinality field is a type name suffix in the format of a field.
     It allows parse format expression, ala::

         "{person:Person}"     #< Cardinality: 1    (one; the normal case)
         "{person:Person?}"    #< Cardinality: 0..1 (zero or one  = optional)
         "{persons:Person*}"   #< Cardinality: 0..* (zero or more = many0)
         "{persons:Person+}"   #< Cardinality: 1..* (one  or more = many)

     This naming convention mimics the relationship descriptions in UML diagrams.


 Basic Example
 -------------------------------------------------------------------------------

 Define an own type converter for numbers (integers):

 .. code-block:: python

     # -- USE CASE:
     def parse_number(text):
         return int(text)
     parse_number.pattern = r"\d+"  # -- REGULAR EXPRESSION pattern for type.

 This is equivalent to:

 .. code-block:: python

     import parse

     @parse.with_pattern(r"\d+")
     def parse_number(text):
          return int(text)
     assert hasattr(parse_number, "pattern")
     assert parse_number.pattern == r"\d+"


 .. code-block:: python

     # -- USE CASE: Use the type converter with the parse module.
     schema = "Hello {number:Number}"
     parser = parse.Parser(schema, dict(Number=parse_number))
     result = parser.parse("Hello 42")
     assert result is not None, "REQUIRE: text matches the schema."
     assert result["number"] == 42

     result = parser.parse("Hello XXX")
     assert result is None, "MISMATCH: text does not match the schema."

 .. hint::

     The described functionality above is standard functionality
     of the `parse`_ module. It serves as introduction for the remaining cases.


 Cardinality
 -------------------------------------------------------------------------------

 Create an type converter for "ManyNumbers" (List, separated with commas)
 with cardinality "1..* = 1+" (many) from the type converter for a "Number".

 .. code-block:: python

     # -- USE CASE: Create new type converter with a cardinality constraint.
     # CARDINALITY: many := one or more (1..*)
     from parse import Parser
     from parse_type import TypeBuilder
     parse_numbers = TypeBuilder.with_many(parse_number, listsep=",")

     schema = "List: {numbers:ManyNumbers}"
     parser = Parser(schema, dict(ManyNumbers=parse_numbers))
     result = parser.parse("List: 1, 2, 3")
     assert result["numbers"] == [1, 2, 3]


 Create an type converter for an "OptionalNumbers" with cardinality "0..1 = ?"
 (optional) from the type converter for a "Number".

 .. code-block:: python

     # -- USE CASE: Create new type converter with cardinality constraint.
     # CARDINALITY: optional := zero or one (0..1)
     from parse import Parser
     from parse_type import TypeBuilder

     parse_optional_number = TypeBuilder.with_optional(parse_number)
     schema = "Optional: {number:OptionalNumber}"
     parser = Parser(schema, dict(OptionalNumber=parse_optional_number))
     result = parser.parse("Optional: 42")
     assert result["number"] == 42
     result = parser.parse("Optional: ")
     assert result["number"] == None


 Enumeration (Name-to-Value Mapping)
 -------------------------------------------------------------------------------

 Create an type converter for an "Enumeration" from the description of
 the mapping as dictionary.

 .. code-block:: python

     # -- USE CASE: Create a type converter for an enumeration.
     from parse import Parser
     from parse_type import TypeBuilder

     parse_enum_yesno = TypeBuilder.make_enum({"yes": True, "no": False})
     parser = Parser("Answer: {answer:YesNo}", dict(YesNo=parse_enum_yesno))
     result = parser.parse("Answer: yes")
     assert result["answer"] == True


 Create an type converter for an "Enumeration" from the description of
 the mapping as an enumeration class (`Python 3.4 enum`_ or the `enum34`_
 backport; see also: `PEP-0435`_).

 .. code-block:: python

     # -- USE CASE: Create a type converter for enum34 enumeration class.
     # NOTE: Use Python 3.4 or enum34 backport.
     from parse import Parser
     from parse_type import TypeBuilder
     from enum import Enum

     class Color(Enum):
         red   = 1
         green = 2
         blue  = 3

     parse_enum_color = TypeBuilder.make_enum(Color)
     parser = Parser("Select: {color:Color}", dict(Color=parse_enum_color))
     result = parser.parse("Select: red")
     assert result["color"] is Color.red

 .. _`Python 3.4 enum`: http://docs.python.org/3.4/library/enum.html#module-enum
 .. _enum34:   http://pypi.python.org/pypi/enum34
 .. _PEP-0435: http://www.python.org/dev/peps/pep-0435


 Choice (Name Enumeration)
 -------------------------------------------------------------------------------

 A Choice data type allows to select one of several strings.

 Create an type converter for an "Choice" list, a list of unique names
 (as string).

 .. code-block:: python

     from parse import Parser
     from parse_type import TypeBuilder

     parse_choice_yesno = TypeBuilder.make_choice(["yes", "no"])
     schema = "Answer: {answer:ChoiceYesNo}"
     parser = Parser(schema, dict(ChoiceYesNo=parse_choice_yesno))
     result = parser.parse("Answer: yes")
     assert result["answer"] == "yes"


 Variant (Type Alternatives)
 -------------------------------------------------------------------------------

 Sometimes you need a type converter that can accept text for multiple
 type converter alternatives. This is normally called a "variant" (or: union).

 Create an type converter for an "Variant" type that accepts:

 * Numbers (positive numbers, as integer)
 * Color enum values (by name)

 .. code-block:: python

     from parse import Parser, with_pattern
     from parse_type import TypeBuilder
     from enum import Enum

     class Color(Enum):
         red   = 1
         green = 2
         blue  = 3

     @with_pattern(r"\d+")
     def parse_number(text):
         return int(text)

     # -- MAKE VARIANT: Alternatives of different type converters.
     parse_color = TypeBuilder.make_enum(Color)
     parse_variant = TypeBuilder.make_variant([parse_number, parse_color])
     schema = "Variant: {variant:Number_or_Color}"
     parser = Parser(schema, dict(Number_or_Color=parse_variant))

     # -- TEST VARIANT: With number, color and mismatch.
     result = parser.parse("Variant: 42")
     assert result["variant"] == 42
     result = parser.parse("Variant: blue")
     assert result["variant"] is Color.blue
     result = parser.parse("Variant: __MISMATCH__")
     assert not result


 Extended Parser with CardinalityField support
 -------------------------------------------------------------------------------

 The parser extends the ``parse.Parser`` and adds the following functionality:

 * supports the CardinalityField naming scheme
 * automatically creates missing type variants for types with
   a CardinalityField by using the primary type converter for cardinality=1
 * extends the provide type converter dictionary with new type variants.

 Example:

 .. code-block:: python

     # -- USE CASE: Parser with CardinalityField support.
     # NOTE: Automatically adds missing type variants with CardinalityField part.
     # USE:  parse_number() type converter from above.
     from parse_type.cfparse import Parser

     # -- PREPARE: parser, adds missing type variant for cardinality 1..* (many)
     type_dict = dict(Number=parse_number)
     schema = "List: {numbers:Number+}"
     parser = Parser(schema, type_dict)
     assert "Number+" in type_dict, "Created missing type variant based on: Number"

     # -- USE: parser.
     result = parser.parse("List: 1, 2, 3")
     assert result["numbers"] == [1, 2, 3]
	===============================================================================
	parse_type
	===============================================================================

	.. image:: https://img.shields.io/travis/jenisys/parse_type/master.svg
	:target: https://travis-ci.org/jenisys/parse_type
	:alt: Travis CI Build Status

	.. image:: https://img.shields.io/pypi/v/parse_type.svg
	:target: https://pypi.python.org/pypi/parse_type
	:alt: Latest Version

	.. image:: https://img.shields.io/pypi/dm/parse_type.svg
	:target: https://pypi.python.org/pypi/parse_type
	:alt: Downloads

	.. image:: https://img.shields.io/pypi/l/parse_type.svg
	:target: https://pypi.python.org/pypi/parse_type/
	:alt: License


	`parse_type`_ extends the `parse`_ module (opposite of `string.format()`_)
	with the following features:

	* build type converters for common use cases (enum/mapping, choice)
	* build a type converter with a cardinality constraint (0..1, 0.., 1..)
	from the type converter with cardinality=1.
	* compose a type converter from other type converters
	* an extended parser that supports the CardinalityField naming schema
	and creates missing type variants (0..1, 0.., 1..) from the
	primary type converter

	.. _parse_type: http://pypi.python.org/pypi/parse_type
	.. _parse: http://pypi.python.org/pypi/parse
	.. _`string.format()`: http://docs.python.org/library/string.html#format-string-syntax


	Definitions
	-------------------------------------------------------------------------------

	type converter
	A type converter function that converts a textual representation
	of a value type into instance of this value type.
	In addition, a type converter function is often annotated with attributes
	that allows the `parse`_ module to use it in a generic way.
	A type converter is also called a parse_type (a definition used here).

	cardinality field
	A naming convention for related types that differ in cardinality.
	A cardinality field is a type name suffix in the format of a field.
	It allows parse format expression, ala::

	"{person:Person}" #< Cardinality: 1 (one; the normal case)
	"{person:Person?}" #< Cardinality: 0..1 (zero or one = optional)
	"{persons:Person}" #< Cardinality: 0.. (zero or more = many0)
	"{persons:Person+}" #< Cardinality: 1..* (one or more = many)

	This naming convention mimics the relationship descriptions in UML diagrams.


	Basic Example
	-------------------------------------------------------------------------------

	Define an own type converter for numbers (integers):

	.. code-block:: python

	# -- USE CASE:
	def parse_number(text):
	return int(text)
	parse_number.pattern = r"\d+" # -- REGULAR EXPRESSION pattern for type.

	This is equivalent to:

	.. code-block:: python

	import parse

	@parse.with_pattern(r"\d+")
	def parse_number(text):
	return int(text)
	assert hasattr(parse_number, "pattern")
	assert parse_number.pattern == r"\d+"


	.. code-block:: python

	# -- USE CASE: Use the type converter with the parse module.
	schema = "Hello {number:Number}"
	parser = parse.Parser(schema, dict(Number=parse_number))
	result = parser.parse("Hello 42")
	assert result is not None, "REQUIRE: text matches the schema."
	assert result["number"] == 42

	result = parser.parse("Hello XXX")
	assert result is None, "MISMATCH: text does not match the schema."

	.. hint::

	The described functionality above is standard functionality
	of the `parse`_ module. It serves as introduction for the remaining cases.


	Cardinality
	-------------------------------------------------------------------------------

	Create an type converter for "ManyNumbers" (List, separated with commas)
	with cardinality "1..* = 1+" (many) from the type converter for a "Number".

	.. code-block:: python

	# -- USE CASE: Create new type converter with a cardinality constraint.
	# CARDINALITY: many := one or more (1..*)
	from parse import Parser
	from parse_type import TypeBuilder
	parse_numbers = TypeBuilder.with_many(parse_number, listsep=",")

	schema = "List: {numbers:ManyNumbers}"
	parser = Parser(schema, dict(ManyNumbers=parse_numbers))
	result = parser.parse("List: 1, 2, 3")
	assert result["numbers"] == [1, 2, 3]


	Create an type converter for an "OptionalNumbers" with cardinality "0..1 = ?"
	(optional) from the type converter for a "Number".

	.. code-block:: python

	# -- USE CASE: Create new type converter with cardinality constraint.
	# CARDINALITY: optional := zero or one (0..1)
	from parse import Parser
	from parse_type import TypeBuilder

	parse_optional_number = TypeBuilder.with_optional(parse_number)
	schema = "Optional: {number:OptionalNumber}"
	parser = Parser(schema, dict(OptionalNumber=parse_optional_number))
	result = parser.parse("Optional: 42")
	assert result["number"] == 42
	result = parser.parse("Optional: ")
	assert result["number"] == None


	Enumeration (Name-to-Value Mapping)
	-------------------------------------------------------------------------------

	Create an type converter for an "Enumeration" from the description of
	the mapping as dictionary.

	.. code-block:: python

	# -- USE CASE: Create a type converter for an enumeration.
	from parse import Parser
	from parse_type import TypeBuilder

	parse_enum_yesno = TypeBuilder.make_enum({"yes": True, "no": False})
	parser = Parser("Answer: {answer:YesNo}", dict(YesNo=parse_enum_yesno))
	result = parser.parse("Answer: yes")
	assert result["answer"] == True


	Create an type converter for an "Enumeration" from the description of
	the mapping as an enumeration class (`Python 3.4 enum`_ or the `enum34`_
	backport; see also: `PEP-0435`_).

	.. code-block:: python

	# -- USE CASE: Create a type converter for enum34 enumeration class.
	# NOTE: Use Python 3.4 or enum34 backport.
	from parse import Parser
	from parse_type import TypeBuilder
	from enum import Enum

	class Color(Enum):
	red = 1
	green = 2
	blue = 3

	parse_enum_color = TypeBuilder.make_enum(Color)
	parser = Parser("Select: {color:Color}", dict(Color=parse_enum_color))
	result = parser.parse("Select: red")
	assert result["color"] is Color.red

	.. _`Python 3.4 enum`: http://docs.python.org/3.4/library/enum.html#module-enum
	.. _enum34: http://pypi.python.org/pypi/enum34
	.. _PEP-0435: http://www.python.org/dev/peps/pep-0435


	Choice (Name Enumeration)
	-------------------------------------------------------------------------------

	A Choice data type allows to select one of several strings.

	Create an type converter for an "Choice" list, a list of unique names
	(as string).

	.. code-block:: python

	from parse import Parser
	from parse_type import TypeBuilder

	parse_choice_yesno = TypeBuilder.make_choice(["yes", "no"])
	schema = "Answer: {answer:ChoiceYesNo}"
	parser = Parser(schema, dict(ChoiceYesNo=parse_choice_yesno))
	result = parser.parse("Answer: yes")
	assert result["answer"] == "yes"


	Variant (Type Alternatives)
	-------------------------------------------------------------------------------

	Sometimes you need a type converter that can accept text for multiple
	type converter alternatives. This is normally called a "variant" (or: union).

	Create an type converter for an "Variant" type that accepts:

	* Numbers (positive numbers, as integer)
	* Color enum values (by name)

	.. code-block:: python

	from parse import Parser, with_pattern
	from parse_type import TypeBuilder
	from enum import Enum

	class Color(Enum):
	red = 1
	green = 2
	blue = 3

	@with_pattern(r"\d+")
	def parse_number(text):
	return int(text)

	# -- MAKE VARIANT: Alternatives of different type converters.
	parse_color = TypeBuilder.make_enum(Color)
	parse_variant = TypeBuilder.make_variant([parse_number, parse_color])
	schema = "Variant: {variant:Number_or_Color}"
	parser = Parser(schema, dict(Number_or_Color=parse_variant))

	# -- TEST VARIANT: With number, color and mismatch.
	result = parser.parse("Variant: 42")
	assert result["variant"] == 42
	result = parser.parse("Variant: blue")
	assert result["variant"] is Color.blue
	result = parser.parse("Variant: __MISMATCH__")
	assert not result



	Extended Parser with CardinalityField support
	-------------------------------------------------------------------------------

	The parser extends the ``parse.Parser`` and adds the following functionality:

	* supports the CardinalityField naming scheme
	* automatically creates missing type variants for types with
	a CardinalityField by using the primary type converter for cardinality=1
	* extends the provide type converter dictionary with new type variants.

	Example:

	.. code-block:: python

	# -- USE CASE: Parser with CardinalityField support.
	# NOTE: Automatically adds missing type variants with CardinalityField part.
	# USE: parse_number() type converter from above.
	from parse_type.cfparse import Parser

	# -- PREPARE: parser, adds missing type variant for cardinality 1..* (many)
	type_dict = dict(Number=parse_number)
	schema = "List: {numbers:Number+}"
	parser = Parser(schema, type_dict)
	assert "Number+" in type_dict, "Created missing type variant based on: Number"

	# -- USE: parser.
	result = parser.parse("List: 1, 2, 3")
	assert result["numbers"] == [1, 2, 3]