Add files using upload-large-folder tool

c4482c9 verified 10 months ago

9.56 kB

	:mod:`email` Package Architecture
	=================================

	Overview
	--------

	The email package consists of three major components:

	Model
	An object structure that represents an email message, and provides an
	API for creating, querying, and modifying a message.

	Parser
	Takes a sequence of characters or bytes and produces a model of the
	email message represented by those characters or bytes.

	Generator
	Takes a model and turns it into a sequence of characters or bytes. The
	sequence can either be intended for human consumption (a printable
	unicode string) or bytes suitable for transmission over the wire. In
	the latter case all data is properly encoded using the content transfer
	encodings specified by the relevant RFCs.

	Conceptually the package is organized around the model. The model provides both
	"external" APIs intended for use by application programs using the library,
	and "internal" APIs intended for use by the Parser and Generator components.
	This division is intentionally a bit fuzzy; the API described by this
	documentation is all a public, stable API. This allows for an application
	with special needs to implement its own parser and/or generator.

	In addition to the three major functional components, there is a third key
	component to the architecture:

	Policy
	An object that specifies various behavioral settings and carries
	implementations of various behavior-controlling methods.

	The Policy framework provides a simple and convenient way to control the
	behavior of the library, making it possible for the library to be used in a
	very flexible fashion while leveraging the common code required to parse,
	represent, and generate message-like objects. For example, in addition to the
	default :rfc:`5322` email message policy, we also have a policy that manages
	HTTP headers in a fashion compliant with :rfc:`2616`. Individual policy
	controls, such as the maximum line length produced by the generator, can also
	be controlled individually to meet specialized application requirements.


	The Model
	---------

	The message model is implemented by the :class:`~email.message.Message` class.
	The model divides a message into the two fundamental parts discussed by the
	RFC: the header section and the body. The `Message` object acts as a
	pseudo-dictionary of named headers. Its dictionary interface provides
	convenient access to individual headers by name. However, all headers are kept
	internally in an ordered list, so that the information about the order of the
	headers in the original message is preserved.

	The `Message` object also has a `payload` that holds the body. A `payload` can
	be one of two things: data, or a list of `Message` objects. The latter is used
	to represent a multipart MIME message. Lists can be nested arbitrarily deeply
	in order to represent the message, with all terminal leaves having non-list
	data payloads.


	Message Lifecycle
	-----------------

	The general lifecycle of a message is:

	Creation
	A `Message` object can be created by a Parser, or it can be
	instantiated as an empty message by an application.

	Manipulation
	The application may examine one or more headers, and/or the
	payload, and it may modify one or more headers and/or
	the payload. This may be done on the top level `Message`
	object, or on any sub-object.

	Finalization
	The Model is converted into a unicode or binary stream,
	or the model is discarded.



	Header Policy Control During Lifecycle
	--------------------------------------

	One of the major controls exerted by the Policy is the management of headers
	during the `Message` lifecycle. Most applications don't need to be aware of
	this.

	A header enters the model in one of two ways: via a Parser, or by being set to
	a specific value by an application program after the Model already exists.
	Similarly, a header exits the model in one of two ways: by being serialized by
	a Generator, or by being retrieved from a Model by an application program. The
	Policy object provides hooks for all four of these pathways.

	The model storage for headers is a list of (name, value) tuples.

	The Parser identifies headers during parsing, and passes them to the
	:meth:`~email.policy.Policy.header_source_parse` method of the Policy. The
	result of that method is the (name, value) tuple to be stored in the model.

	When an application program supplies a header value (for example, through the
	`Message` object `__setitem__` interface), the name and the value are passed to
	the :meth:`~email.policy.Policy.header_store_parse` method of the Policy, which
	returns the (name, value) tuple to be stored in the model.

	When an application program retrieves a header (through any of the dict or list
	interfaces of `Message`), the name and value are passed to the
	:meth:`~email.policy.Policy.header_fetch_parse` method of the Policy to
	obtain the value returned to the application.

	When a Generator requests a header during serialization, the name and value are
	passed to the :meth:`~email.policy.Policy.fold` method of the Policy, which
	returns a string containing line breaks in the appropriate places. The
	:meth:`~email.policy.Policy.cte_type` Policy control determines whether or
	not Content Transfer Encoding is performed on the data in the header. There is
	also a :meth:`~email.policy.Policy.binary_fold` method for use by generators
	that produce binary output, which returns the folded header as binary data,
	possibly folded at different places than the corresponding string would be.


	Handling Binary Data
	--------------------

	In an ideal world all message data would conform to the RFCs, meaning that the
	parser could decode the message into the idealized unicode message that the
	sender originally wrote. In the real world, the email package must also be
	able to deal with badly formatted messages, including messages containing
	non-ASCII characters that either have no indicated character set or are not
	valid characters in the indicated character set.

	Since email messages are primarily text data, and operations on message data
	are primarily text operations (except for binary payloads of course), the model
	stores all text data as unicode strings. Un-decodable binary inside text
	data is handled by using the `surrogateescape` error handler of the ASCII
	codec. As with the binary filenames the error handler was introduced to
	handle, this allows the email package to "carry" the binary data received
	during parsing along until the output stage, at which time it is regenerated
	in its original form.

	This carried binary data is almost entirely an implementation detail. The one
	place where it is visible in the API is in the "internal" API. A Parser must
	do the `surrogateescape` encoding of binary input data, and pass that data to
	the appropriate Policy method. The "internal" interface used by the Generator
	to access header values preserves the `surrogateescaped` bytes. All other
	interfaces convert the binary data either back into bytes or into a safe form
	(losing information in some cases).


	Backward Compatibility
	----------------------

	The :class:`~email.policy.Policy.Compat32` Policy provides backward
	compatibility with version 5.1 of the email package. It does this via the
	following implementation of the four+1 Policy methods described above:

	header_source_parse
	Splits the first line on the colon to obtain the name, discards any spaces
	after the colon, and joins the remainder of the line with all of the
	remaining lines, preserving the linesep characters to obtain the value.
	Trailing carriage return and/or linefeed characters are stripped from the
	resulting value string.

	header_store_parse
	Returns the name and value exactly as received from the application.

	header_fetch_parse
	If the value contains any `surrogateescaped` binary data, return the value
	as a :class:`~email.header.Header` object, using the character set
	`unknown-8bit`. Otherwise just returns the value.

	fold
	Uses :class:`~email.header.Header`'s folding to fold headers in the
	same way the email5.1 generator did.

	binary_fold
	Same as fold, but encodes to 'ascii'.


	New Algorithm
	-------------

	header_source_parse
	Same as legacy behavior.

	header_store_parse
	Same as legacy behavior.

	header_fetch_parse
	If the value is already a header object, returns it. Otherwise, parses the
	value using the new parser, and returns the resulting object as the value.
	`surrogateescaped` bytes get turned into unicode unknown character code
	points.

	fold
	Uses the new header folding algorithm, respecting the policy settings.
	surrogateescaped bytes are encoded using the ``unknown-8bit`` charset for
	``cte_type=7bit`` or ``8bit``. Returns a string.

	At some point there will also be a ``cte_type=unicode``, and for that
	policy fold will serialize the idealized unicode message with RFC-like
	folding, converting any surrogateescaped bytes into the unicode
	unknown character glyph.

	binary_fold
	Uses the new header folding algorithm, respecting the policy settings.
	surrogateescaped bytes are encoded using the `unknown-8bit` charset for
	``cte_type=7bit``, and get turned back into bytes for ``cte_type=8bit``.
	Returns bytes.

	At some point there will also be a ``cte_type=unicode``, and for that
	policy binary_fold will serialize the message according to :rfc:``5335``.