mirror of https://github.com/python/cpython
1219 lines
46 KiB
ReStructuredText
1219 lines
46 KiB
ReStructuredText
********************************
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Functional Programming HOWTO
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********************************
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:Author: A. M. Kuchling
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:Release: 0.31
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In this document, we'll take a tour of Python's features suitable for
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implementing programs in a functional style. After an introduction to the
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concepts of functional programming, we'll look at language features such as
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:term:`iterator`\s and :term:`generator`\s and relevant library modules such as
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:mod:`itertools` and :mod:`functools`.
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Introduction
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============
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This section explains the basic concept of functional programming; if you're
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just interested in learning about Python language features, skip to the next
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section.
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Programming languages support decomposing problems in several different ways:
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* Most programming languages are **procedural**: programs are lists of
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instructions that tell the computer what to do with the program's input. C,
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Pascal, and even Unix shells are procedural languages.
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* In **declarative** languages, you write a specification that describes the
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problem to be solved, and the language implementation figures out how to
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perform the computation efficiently. SQL is the declarative language you're
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most likely to be familiar with; a SQL query describes the data set you want
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to retrieve, and the SQL engine decides whether to scan tables or use indexes,
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which subclauses should be performed first, etc.
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* **Object-oriented** programs manipulate collections of objects. Objects have
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internal state and support methods that query or modify this internal state in
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some way. Smalltalk and Java are object-oriented languages. C++ and Python
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are languages that support object-oriented programming, but don't force the
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use of object-oriented features.
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* **Functional** programming decomposes a problem into a set of functions.
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Ideally, functions only take inputs and produce outputs, and don't have any
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internal state that affects the output produced for a given input. Well-known
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functional languages include the ML family (Standard ML, OCaml, and other
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variants) and Haskell.
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The designers of some computer languages choose to emphasize one
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particular approach to programming. This often makes it difficult to
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write programs that use a different approach. Other languages are
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multi-paradigm languages that support several different approaches.
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Lisp, C++, and Python are multi-paradigm; you can write programs or
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libraries that are largely procedural, object-oriented, or functional
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in all of these languages. In a large program, different sections
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might be written using different approaches; the GUI might be
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object-oriented while the processing logic is procedural or
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functional, for example.
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In a functional program, input flows through a set of functions. Each function
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operates on its input and produces some output. Functional style discourages
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functions with side effects that modify internal state or make other changes
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that aren't visible in the function's return value. Functions that have no side
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effects at all are called **purely functional**. Avoiding side effects means
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not using data structures that get updated as a program runs; every function's
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output must only depend on its input.
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Some languages are very strict about purity and don't even have assignment
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statements such as ``a=3`` or ``c = a + b``, but it's difficult to avoid all
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side effects. Printing to the screen or writing to a disk file are side
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effects, for example. For example, in Python a call to the :func:`print` or
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:func:`time.sleep` function both return no useful value; they're only called for
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their side effects of sending some text to the screen or pausing execution for a
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second.
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Python programs written in functional style usually won't go to the extreme of
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avoiding all I/O or all assignments; instead, they'll provide a
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functional-appearing interface but will use non-functional features internally.
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For example, the implementation of a function will still use assignments to
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local variables, but won't modify global variables or have other side effects.
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Functional programming can be considered the opposite of object-oriented
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programming. Objects are little capsules containing some internal state along
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with a collection of method calls that let you modify this state, and programs
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consist of making the right set of state changes. Functional programming wants
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to avoid state changes as much as possible and works with data flowing between
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functions. In Python you might combine the two approaches by writing functions
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that take and return instances representing objects in your application (e-mail
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messages, transactions, etc.).
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Functional design may seem like an odd constraint to work under. Why should you
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avoid objects and side effects? There are theoretical and practical advantages
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to the functional style:
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* Formal provability.
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* Modularity.
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* Composability.
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* Ease of debugging and testing.
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Formal provability
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------------------
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A theoretical benefit is that it's easier to construct a mathematical proof that
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a functional program is correct.
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For a long time researchers have been interested in finding ways to
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mathematically prove programs correct. This is different from testing a program
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on numerous inputs and concluding that its output is usually correct, or reading
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a program's source code and concluding that the code looks right; the goal is
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instead a rigorous proof that a program produces the right result for all
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possible inputs.
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The technique used to prove programs correct is to write down **invariants**,
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properties of the input data and of the program's variables that are always
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true. For each line of code, you then show that if invariants X and Y are true
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**before** the line is executed, the slightly different invariants X' and Y' are
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true **after** the line is executed. This continues until you reach the end of
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the program, at which point the invariants should match the desired conditions
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on the program's output.
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Functional programming's avoidance of assignments arose because assignments are
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difficult to handle with this technique; assignments can break invariants that
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were true before the assignment without producing any new invariants that can be
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propagated onward.
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Unfortunately, proving programs correct is largely impractical and not relevant
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to Python software. Even trivial programs require proofs that are several pages
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long; the proof of correctness for a moderately complicated program would be
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enormous, and few or none of the programs you use daily (the Python interpreter,
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your XML parser, your web browser) could be proven correct. Even if you wrote
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down or generated a proof, there would then be the question of verifying the
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proof; maybe there's an error in it, and you wrongly believe you've proved the
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program correct.
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Modularity
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----------
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A more practical benefit of functional programming is that it forces you to
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break apart your problem into small pieces. Programs are more modular as a
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result. It's easier to specify and write a small function that does one thing
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than a large function that performs a complicated transformation. Small
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functions are also easier to read and to check for errors.
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Ease of debugging and testing
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-----------------------------
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Testing and debugging a functional-style program is easier.
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Debugging is simplified because functions are generally small and clearly
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specified. When a program doesn't work, each function is an interface point
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where you can check that the data are correct. You can look at the intermediate
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inputs and outputs to quickly isolate the function that's responsible for a bug.
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Testing is easier because each function is a potential subject for a unit test.
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Functions don't depend on system state that needs to be replicated before
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running a test; instead you only have to synthesize the right input and then
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check that the output matches expectations.
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Composability
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-------------
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As you work on a functional-style program, you'll write a number of functions
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with varying inputs and outputs. Some of these functions will be unavoidably
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specialized to a particular application, but others will be useful in a wide
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variety of programs. For example, a function that takes a directory path and
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returns all the XML files in the directory, or a function that takes a filename
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and returns its contents, can be applied to many different situations.
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Over time you'll form a personal library of utilities. Often you'll assemble
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new programs by arranging existing functions in a new configuration and writing
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a few functions specialized for the current task.
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Iterators
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=========
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I'll start by looking at a Python language feature that's an important
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foundation for writing functional-style programs: iterators.
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An iterator is an object representing a stream of data; this object returns the
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data one element at a time. A Python iterator must support a method called
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:meth:`~iterator.__next__` that takes no arguments and always returns the next
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element of the stream. If there are no more elements in the stream,
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:meth:`~iterator.__next__` must raise the :exc:`StopIteration` exception.
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Iterators don't have to be finite, though; it's perfectly reasonable to write
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an iterator that produces an infinite stream of data.
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The built-in :func:`iter` function takes an arbitrary object and tries to return
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an iterator that will return the object's contents or elements, raising
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:exc:`TypeError` if the object doesn't support iteration. Several of Python's
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built-in data types support iteration, the most common being lists and
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dictionaries. An object is called :term:`iterable` if you can get an iterator
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for it.
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You can experiment with the iteration interface manually:
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>>> L = [1,2,3]
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>>> it = iter(L)
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>>> it #doctest: +ELLIPSIS
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<...iterator object at ...>
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>>> it.__next__() # same as next(it)
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1
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>>> next(it)
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2
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>>> next(it)
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3
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>>> next(it)
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Traceback (most recent call last):
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File "<stdin>", line 1, in ?
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StopIteration
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>>>
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Python expects iterable objects in several different contexts, the most
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important being the :keyword:`for` statement. In the statement ``for X in Y``,
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Y must be an iterator or some object for which :func:`iter` can create an
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iterator. These two statements are equivalent::
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for i in iter(obj):
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print(i)
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for i in obj:
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print(i)
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Iterators can be materialized as lists or tuples by using the :func:`list` or
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:func:`tuple` constructor functions:
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>>> L = [1,2,3]
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>>> iterator = iter(L)
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>>> t = tuple(iterator)
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>>> t
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(1, 2, 3)
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Sequence unpacking also supports iterators: if you know an iterator will return
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N elements, you can unpack them into an N-tuple:
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>>> L = [1,2,3]
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>>> iterator = iter(L)
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>>> a,b,c = iterator
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>>> a,b,c
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(1, 2, 3)
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Built-in functions such as :func:`max` and :func:`min` can take a single
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iterator argument and will return the largest or smallest element. The ``"in"``
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and ``"not in"`` operators also support iterators: ``X in iterator`` is true if
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X is found in the stream returned by the iterator. You'll run into obvious
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problems if the iterator is infinite; :func:`max`, :func:`min`
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will never return, and if the element X never appears in the stream, the
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``"in"`` and ``"not in"`` operators won't return either.
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Note that you can only go forward in an iterator; there's no way to get the
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previous element, reset the iterator, or make a copy of it. Iterator objects
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can optionally provide these additional capabilities, but the iterator protocol
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only specifies the :meth:`~iterator.__next__` method. Functions may therefore
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consume all of the iterator's output, and if you need to do something different
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with the same stream, you'll have to create a new iterator.
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Data Types That Support Iterators
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---------------------------------
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We've already seen how lists and tuples support iterators. In fact, any Python
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sequence type, such as strings, will automatically support creation of an
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iterator.
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Calling :func:`iter` on a dictionary returns an iterator that will loop over the
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dictionary's keys::
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>>> m = {'Jan': 1, 'Feb': 2, 'Mar': 3, 'Apr': 4, 'May': 5, 'Jun': 6,
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... 'Jul': 7, 'Aug': 8, 'Sep': 9, 'Oct': 10, 'Nov': 11, 'Dec': 12}
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>>> for key in m: #doctest: +SKIP
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... print(key, m[key])
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Mar 3
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Feb 2
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Aug 8
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Sep 9
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Apr 4
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Jun 6
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Jul 7
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Jan 1
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May 5
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Nov 11
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Dec 12
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Oct 10
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Note that the order is essentially random, because it's based on the hash
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ordering of the objects in the dictionary.
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Applying :func:`iter` to a dictionary always loops over the keys, but
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dictionaries have methods that return other iterators. If you want to iterate
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over values or key/value pairs, you can explicitly call the
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:meth:`~dict.values` or :meth:`~dict.items` methods to get an appropriate
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iterator.
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The :func:`dict` constructor can accept an iterator that returns a finite stream
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of ``(key, value)`` tuples:
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>>> L = [('Italy', 'Rome'), ('France', 'Paris'), ('US', 'Washington DC')]
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>>> dict(iter(L)) #doctest: +SKIP
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{'Italy': 'Rome', 'US': 'Washington DC', 'France': 'Paris'}
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Files also support iteration by calling the :meth:`~io.TextIOBase.readline`
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method until there are no more lines in the file. This means you can read each
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line of a file like this::
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for line in file:
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# do something for each line
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...
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Sets can take their contents from an iterable and let you iterate over the set's
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elements::
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S = {2, 3, 5, 7, 11, 13}
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for i in S:
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print(i)
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Generator expressions and list comprehensions
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=============================================
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Two common operations on an iterator's output are 1) performing some operation
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for every element, 2) selecting a subset of elements that meet some condition.
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For example, given a list of strings, you might want to strip off trailing
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whitespace from each line or extract all the strings containing a given
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substring.
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List comprehensions and generator expressions (short form: "listcomps" and
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"genexps") are a concise notation for such operations, borrowed from the
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functional programming language Haskell (http://www.haskell.org/). You can strip
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all the whitespace from a stream of strings with the following code::
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line_list = [' line 1\n', 'line 2 \n', ...]
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# Generator expression -- returns iterator
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stripped_iter = (line.strip() for line in line_list)
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# List comprehension -- returns list
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stripped_list = [line.strip() for line in line_list]
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You can select only certain elements by adding an ``"if"`` condition::
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stripped_list = [line.strip() for line in line_list
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if line != ""]
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With a list comprehension, you get back a Python list; ``stripped_list`` is a
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list containing the resulting lines, not an iterator. Generator expressions
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return an iterator that computes the values as necessary, not needing to
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materialize all the values at once. This means that list comprehensions aren't
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useful if you're working with iterators that return an infinite stream or a very
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large amount of data. Generator expressions are preferable in these situations.
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Generator expressions are surrounded by parentheses ("()") and list
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comprehensions are surrounded by square brackets ("[]"). Generator expressions
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have the form::
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( expression for expr in sequence1
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if condition1
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for expr2 in sequence2
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if condition2
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for expr3 in sequence3 ...
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if condition3
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for exprN in sequenceN
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if conditionN )
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Again, for a list comprehension only the outside brackets are different (square
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brackets instead of parentheses).
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The elements of the generated output will be the successive values of
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``expression``. The ``if`` clauses are all optional; if present, ``expression``
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is only evaluated and added to the result when ``condition`` is true.
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Generator expressions always have to be written inside parentheses, but the
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parentheses signalling a function call also count. If you want to create an
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iterator that will be immediately passed to a function you can write::
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obj_total = sum(obj.count for obj in list_all_objects())
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The ``for...in`` clauses contain the sequences to be iterated over. The
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sequences do not have to be the same length, because they are iterated over from
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left to right, **not** in parallel. For each element in ``sequence1``,
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``sequence2`` is looped over from the beginning. ``sequence3`` is then looped
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over for each resulting pair of elements from ``sequence1`` and ``sequence2``.
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To put it another way, a list comprehension or generator expression is
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equivalent to the following Python code::
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for expr1 in sequence1:
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if not (condition1):
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continue # Skip this element
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for expr2 in sequence2:
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if not (condition2):
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continue # Skip this element
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...
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for exprN in sequenceN:
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if not (conditionN):
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continue # Skip this element
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# Output the value of
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# the expression.
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This means that when there are multiple ``for...in`` clauses but no ``if``
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clauses, the length of the resulting output will be equal to the product of the
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lengths of all the sequences. If you have two lists of length 3, the output
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list is 9 elements long:
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>>> seq1 = 'abc'
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>>> seq2 = (1,2,3)
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>>> [(x, y) for x in seq1 for y in seq2] #doctest: +NORMALIZE_WHITESPACE
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[('a', 1), ('a', 2), ('a', 3),
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('b', 1), ('b', 2), ('b', 3),
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('c', 1), ('c', 2), ('c', 3)]
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To avoid introducing an ambiguity into Python's grammar, if ``expression`` is
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creating a tuple, it must be surrounded with parentheses. The first list
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comprehension below is a syntax error, while the second one is correct::
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# Syntax error
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[x, y for x in seq1 for y in seq2]
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# Correct
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[(x, y) for x in seq1 for y in seq2]
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Generators
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==========
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Generators are a special class of functions that simplify the task of writing
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iterators. Regular functions compute a value and return it, but generators
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return an iterator that returns a stream of values.
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You're doubtless familiar with how regular function calls work in Python or C.
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When you call a function, it gets a private namespace where its local variables
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are created. When the function reaches a ``return`` statement, the local
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variables are destroyed and the value is returned to the caller. A later call
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to the same function creates a new private namespace and a fresh set of local
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variables. But, what if the local variables weren't thrown away on exiting a
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function? What if you could later resume the function where it left off? This
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is what generators provide; they can be thought of as resumable functions.
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Here's the simplest example of a generator function:
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>>> def generate_ints(N):
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... for i in range(N):
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... yield i
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Any function containing a :keyword:`yield` keyword is a generator function;
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this is detected by Python's :term:`bytecode` compiler which compiles the
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function specially as a result.
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When you call a generator function, it doesn't return a single value; instead it
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returns a generator object that supports the iterator protocol. On executing
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the ``yield`` expression, the generator outputs the value of ``i``, similar to a
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``return`` statement. The big difference between ``yield`` and a ``return``
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statement is that on reaching a ``yield`` the generator's state of execution is
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suspended and local variables are preserved. On the next call to the
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generator's :meth:`~generator.__next__` method, the function will resume
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executing.
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Here's a sample usage of the ``generate_ints()`` generator:
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>>> gen = generate_ints(3)
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>>> gen #doctest: +ELLIPSIS
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<generator object generate_ints at ...>
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>>> next(gen)
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0
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>>> next(gen)
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1
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>>> next(gen)
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2
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>>> next(gen)
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Traceback (most recent call last):
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File "stdin", line 1, in ?
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File "stdin", line 2, in generate_ints
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StopIteration
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You could equally write ``for i in generate_ints(5)``, or ``a,b,c =
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generate_ints(3)``.
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Inside a generator function, ``return value`` is semantically equivalent to
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``raise StopIteration(value)``. If no value is returned or the bottom of the
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function is reached, the procession of values ends and the generator cannot
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return any further values.
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You could achieve the effect of generators manually by writing your own class
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and storing all the local variables of the generator as instance variables. For
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example, returning a list of integers could be done by setting ``self.count`` to
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0, and having the :meth:`~iterator.__next__` method increment ``self.count`` and
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return it.
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However, for a moderately complicated generator, writing a corresponding class
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can be much messier.
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The test suite included with Python's library,
|
|
:source:`Lib/test/test_generators.py`, contains
|
|
a number of more interesting examples. Here's one generator that implements an
|
|
in-order traversal of a tree using generators recursively. ::
|
|
|
|
# A recursive generator that generates Tree leaves in in-order.
|
|
def inorder(t):
|
|
if t:
|
|
for x in inorder(t.left):
|
|
yield x
|
|
|
|
yield t.label
|
|
|
|
for x in inorder(t.right):
|
|
yield x
|
|
|
|
Two other examples in ``test_generators.py`` produce solutions for the N-Queens
|
|
problem (placing N queens on an NxN chess board so that no queen threatens
|
|
another) and the Knight's Tour (finding a route that takes a knight to every
|
|
square of an NxN chessboard without visiting any square twice).
|
|
|
|
|
|
|
|
Passing values into a generator
|
|
-------------------------------
|
|
|
|
In Python 2.4 and earlier, generators only produced output. Once a generator's
|
|
code was invoked to create an iterator, there was no way to pass any new
|
|
information into the function when its execution is resumed. You could hack
|
|
together this ability by making the generator look at a global variable or by
|
|
passing in some mutable object that callers then modify, but these approaches
|
|
are messy.
|
|
|
|
In Python 2.5 there's a simple way to pass values into a generator.
|
|
:keyword:`yield` became an expression, returning a value that can be assigned to
|
|
a variable or otherwise operated on::
|
|
|
|
val = (yield i)
|
|
|
|
I recommend that you **always** put parentheses around a ``yield`` expression
|
|
when you're doing something with the returned value, as in the above example.
|
|
The parentheses aren't always necessary, but it's easier to always add them
|
|
instead of having to remember when they're needed.
|
|
|
|
(:pep:`342` explains the exact rules, which are that a ``yield``-expression must
|
|
always be parenthesized except when it occurs at the top-level expression on the
|
|
right-hand side of an assignment. This means you can write ``val = yield i``
|
|
but have to use parentheses when there's an operation, as in ``val = (yield i)
|
|
+ 12``.)
|
|
|
|
Values are sent into a generator by calling its :meth:`send(value)
|
|
<generator.send>` method. This method resumes the generator's code and the
|
|
``yield`` expression returns the specified value. If the regular
|
|
:meth:`~generator.__next__` method is called, the ``yield`` returns ``None``.
|
|
|
|
Here's a simple counter that increments by 1 and allows changing the value of
|
|
the internal counter.
|
|
|
|
.. testcode::
|
|
|
|
def counter(maximum):
|
|
i = 0
|
|
while i < maximum:
|
|
val = (yield i)
|
|
# If value provided, change counter
|
|
if val is not None:
|
|
i = val
|
|
else:
|
|
i += 1
|
|
|
|
And here's an example of changing the counter:
|
|
|
|
>>> it = counter(10) #doctest: +SKIP
|
|
>>> next(it) #doctest: +SKIP
|
|
0
|
|
>>> next(it) #doctest: +SKIP
|
|
1
|
|
>>> it.send(8) #doctest: +SKIP
|
|
8
|
|
>>> next(it) #doctest: +SKIP
|
|
9
|
|
>>> next(it) #doctest: +SKIP
|
|
Traceback (most recent call last):
|
|
File "t.py", line 15, in ?
|
|
it.next()
|
|
StopIteration
|
|
|
|
Because ``yield`` will often be returning ``None``, you should always check for
|
|
this case. Don't just use its value in expressions unless you're sure that the
|
|
:meth:`~generator.send` method will be the only method used resume your
|
|
generator function.
|
|
|
|
In addition to :meth:`~generator.send`, there are two other methods on
|
|
generators:
|
|
|
|
* :meth:`throw(type, value=None, traceback=None) <generator.throw>` is used to
|
|
raise an exception inside the generator; the exception is raised by the
|
|
``yield`` expression where the generator's execution is paused.
|
|
|
|
* :meth:`~generator.close` raises a :exc:`GeneratorExit` exception inside the
|
|
generator to terminate the iteration. On receiving this exception, the
|
|
generator's code must either raise :exc:`GeneratorExit` or
|
|
:exc:`StopIteration`; catching the exception and doing anything else is
|
|
illegal and will trigger a :exc:`RuntimeError`. :meth:`~generator.close`
|
|
will also be called by Python's garbage collector when the generator is
|
|
garbage-collected.
|
|
|
|
If you need to run cleanup code when a :exc:`GeneratorExit` occurs, I suggest
|
|
using a ``try: ... finally:`` suite instead of catching :exc:`GeneratorExit`.
|
|
|
|
The cumulative effect of these changes is to turn generators from one-way
|
|
producers of information into both producers and consumers.
|
|
|
|
Generators also become **coroutines**, a more generalized form of subroutines.
|
|
Subroutines are entered at one point and exited at another point (the top of the
|
|
function, and a ``return`` statement), but coroutines can be entered, exited,
|
|
and resumed at many different points (the ``yield`` statements).
|
|
|
|
|
|
Built-in functions
|
|
==================
|
|
|
|
Let's look in more detail at built-in functions often used with iterators.
|
|
|
|
Two of Python's built-in functions, :func:`map` and :func:`filter` duplicate the
|
|
features of generator expressions:
|
|
|
|
:func:`map(f, iterA, iterB, ...) <map>` returns an iterator over the sequence
|
|
``f(iterA[0], iterB[0]), f(iterA[1], iterB[1]), f(iterA[2], iterB[2]), ...``.
|
|
|
|
>>> def upper(s):
|
|
... return s.upper()
|
|
|
|
>>> list(map(upper, ['sentence', 'fragment']))
|
|
['SENTENCE', 'FRAGMENT']
|
|
>>> [upper(s) for s in ['sentence', 'fragment']]
|
|
['SENTENCE', 'FRAGMENT']
|
|
|
|
You can of course achieve the same effect with a list comprehension.
|
|
|
|
:func:`filter(predicate, iter) <filter>` returns an iterator over all the
|
|
sequence elements that meet a certain condition, and is similarly duplicated by
|
|
list comprehensions. A **predicate** is a function that returns the truth
|
|
value of some condition; for use with :func:`filter`, the predicate must take a
|
|
single value.
|
|
|
|
>>> def is_even(x):
|
|
... return (x % 2) == 0
|
|
|
|
>>> list(filter(is_even, range(10)))
|
|
[0, 2, 4, 6, 8]
|
|
|
|
|
|
This can also be written as a list comprehension:
|
|
|
|
>>> list(x for x in range(10) if is_even(x))
|
|
[0, 2, 4, 6, 8]
|
|
|
|
|
|
:func:`enumerate(iter) <enumerate>` counts off the elements in the iterable,
|
|
returning 2-tuples containing the count and each element. ::
|
|
|
|
>>> for item in enumerate(['subject', 'verb', 'object']):
|
|
... print(item)
|
|
(0, 'subject')
|
|
(1, 'verb')
|
|
(2, 'object')
|
|
|
|
:func:`enumerate` is often used when looping through a list and recording the
|
|
indexes at which certain conditions are met::
|
|
|
|
f = open('data.txt', 'r')
|
|
for i, line in enumerate(f):
|
|
if line.strip() == '':
|
|
print('Blank line at line #%i' % i)
|
|
|
|
:func:`sorted(iterable, key=None, reverse=False) <sorted>` collects all the
|
|
elements of the iterable into a list, sorts the list, and returns the sorted
|
|
result. The *key*, and *reverse* arguments are passed through to the
|
|
constructed list's :meth:`~list.sort` method. ::
|
|
|
|
>>> import random
|
|
>>> # Generate 8 random numbers between [0, 10000)
|
|
>>> rand_list = random.sample(range(10000), 8)
|
|
>>> rand_list #doctest: +SKIP
|
|
[769, 7953, 9828, 6431, 8442, 9878, 6213, 2207]
|
|
>>> sorted(rand_list) #doctest: +SKIP
|
|
[769, 2207, 6213, 6431, 7953, 8442, 9828, 9878]
|
|
>>> sorted(rand_list, reverse=True) #doctest: +SKIP
|
|
[9878, 9828, 8442, 7953, 6431, 6213, 2207, 769]
|
|
|
|
(For a more detailed discussion of sorting, see the :ref:`sortinghowto`.)
|
|
|
|
|
|
The :func:`any(iter) <any>` and :func:`all(iter) <all>` built-ins look at the
|
|
truth values of an iterable's contents. :func:`any` returns ``True`` if any element
|
|
in the iterable is a true value, and :func:`all` returns ``True`` if all of the
|
|
elements are true values:
|
|
|
|
>>> any([0,1,0])
|
|
True
|
|
>>> any([0,0,0])
|
|
False
|
|
>>> any([1,1,1])
|
|
True
|
|
>>> all([0,1,0])
|
|
False
|
|
>>> all([0,0,0])
|
|
False
|
|
>>> all([1,1,1])
|
|
True
|
|
|
|
|
|
:func:`zip(iterA, iterB, ...) <zip>` takes one element from each iterable and
|
|
returns them in a tuple::
|
|
|
|
zip(['a', 'b', 'c'], (1, 2, 3)) =>
|
|
('a', 1), ('b', 2), ('c', 3)
|
|
|
|
It doesn't construct an in-memory list and exhaust all the input iterators
|
|
before returning; instead tuples are constructed and returned only if they're
|
|
requested. (The technical term for this behaviour is `lazy evaluation
|
|
<http://en.wikipedia.org/wiki/Lazy_evaluation>`__.)
|
|
|
|
This iterator is intended to be used with iterables that are all of the same
|
|
length. If the iterables are of different lengths, the resulting stream will be
|
|
the same length as the shortest iterable. ::
|
|
|
|
zip(['a', 'b'], (1, 2, 3)) =>
|
|
('a', 1), ('b', 2)
|
|
|
|
You should avoid doing this, though, because an element may be taken from the
|
|
longer iterators and discarded. This means you can't go on to use the iterators
|
|
further because you risk skipping a discarded element.
|
|
|
|
|
|
The itertools module
|
|
====================
|
|
|
|
The :mod:`itertools` module contains a number of commonly-used iterators as well
|
|
as functions for combining several iterators. This section will introduce the
|
|
module's contents by showing small examples.
|
|
|
|
The module's functions fall into a few broad classes:
|
|
|
|
* Functions that create a new iterator based on an existing iterator.
|
|
* Functions for treating an iterator's elements as function arguments.
|
|
* Functions for selecting portions of an iterator's output.
|
|
* A function for grouping an iterator's output.
|
|
|
|
Creating new iterators
|
|
----------------------
|
|
|
|
:func:`itertools.count(n) <itertools.count>` returns an infinite stream of
|
|
integers, increasing by 1 each time. You can optionally supply the starting
|
|
number, which defaults to 0::
|
|
|
|
itertools.count() =>
|
|
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, ...
|
|
itertools.count(10) =>
|
|
10, 11, 12, 13, 14, 15, 16, 17, 18, 19, ...
|
|
|
|
:func:`itertools.cycle(iter) <itertools.cycle>` saves a copy of the contents of
|
|
a provided iterable and returns a new iterator that returns its elements from
|
|
first to last. The new iterator will repeat these elements infinitely. ::
|
|
|
|
itertools.cycle([1,2,3,4,5]) =>
|
|
1, 2, 3, 4, 5, 1, 2, 3, 4, 5, ...
|
|
|
|
:func:`itertools.repeat(elem, [n]) <itertools.repeat>` returns the provided
|
|
element *n* times, or returns the element endlessly if *n* is not provided. ::
|
|
|
|
itertools.repeat('abc') =>
|
|
abc, abc, abc, abc, abc, abc, abc, abc, abc, abc, ...
|
|
itertools.repeat('abc', 5) =>
|
|
abc, abc, abc, abc, abc
|
|
|
|
:func:`itertools.chain(iterA, iterB, ...) <itertools.chain>` takes an arbitrary
|
|
number of iterables as input, and returns all the elements of the first
|
|
iterator, then all the elements of the second, and so on, until all of the
|
|
iterables have been exhausted. ::
|
|
|
|
itertools.chain(['a', 'b', 'c'], (1, 2, 3)) =>
|
|
a, b, c, 1, 2, 3
|
|
|
|
:func:`itertools.islice(iter, [start], stop, [step]) <itertools.islice>` returns
|
|
a stream that's a slice of the iterator. With a single *stop* argument, it
|
|
will return the first *stop* elements. If you supply a starting index, you'll
|
|
get *stop-start* elements, and if you supply a value for *step*, elements
|
|
will be skipped accordingly. Unlike Python's string and list slicing, you can't
|
|
use negative values for *start*, *stop*, or *step*. ::
|
|
|
|
itertools.islice(range(10), 8) =>
|
|
0, 1, 2, 3, 4, 5, 6, 7
|
|
itertools.islice(range(10), 2, 8) =>
|
|
2, 3, 4, 5, 6, 7
|
|
itertools.islice(range(10), 2, 8, 2) =>
|
|
2, 4, 6
|
|
|
|
:func:`itertools.tee(iter, [n]) <itertools.tee>` replicates an iterator; it
|
|
returns *n* independent iterators that will all return the contents of the
|
|
source iterator.
|
|
If you don't supply a value for *n*, the default is 2. Replicating iterators
|
|
requires saving some of the contents of the source iterator, so this can consume
|
|
significant memory if the iterator is large and one of the new iterators is
|
|
consumed more than the others. ::
|
|
|
|
itertools.tee( itertools.count() ) =>
|
|
iterA, iterB
|
|
|
|
where iterA ->
|
|
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, ...
|
|
|
|
and iterB ->
|
|
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, ...
|
|
|
|
|
|
Calling functions on elements
|
|
-----------------------------
|
|
|
|
The :mod:`operator` module contains a set of functions corresponding to Python's
|
|
operators. Some examples are :func:`operator.add(a, b) <operator.add>` (adds
|
|
two values), :func:`operator.ne(a, b) <operator.ne>` (same as ``a != b``), and
|
|
:func:`operator.attrgetter('id') <operator.attrgetter>`
|
|
(returns a callable that fetches the ``.id`` attribute).
|
|
|
|
:func:`itertools.starmap(func, iter) <itertools.starmap>` assumes that the
|
|
iterable will return a stream of tuples, and calls *func* using these tuples as
|
|
the arguments::
|
|
|
|
itertools.starmap(os.path.join,
|
|
[('/bin', 'python'), ('/usr', 'bin', 'java'),
|
|
('/usr', 'bin', 'perl'), ('/usr', 'bin', 'ruby')])
|
|
=>
|
|
/bin/python, /usr/bin/java, /usr/bin/perl, /usr/bin/ruby
|
|
|
|
|
|
Selecting elements
|
|
------------------
|
|
|
|
Another group of functions chooses a subset of an iterator's elements based on a
|
|
predicate.
|
|
|
|
:func:`itertools.filterfalse(predicate, iter) <itertools.filterfalse>` is the
|
|
opposite, returning all elements for which the predicate returns false::
|
|
|
|
itertools.filterfalse(is_even, itertools.count()) =>
|
|
1, 3, 5, 7, 9, 11, 13, 15, ...
|
|
|
|
:func:`itertools.takewhile(predicate, iter) <itertools.takewhile>` returns
|
|
elements for as long as the predicate returns true. Once the predicate returns
|
|
false, the iterator will signal the end of its results. ::
|
|
|
|
def less_than_10(x):
|
|
return x < 10
|
|
|
|
itertools.takewhile(less_than_10, itertools.count()) =>
|
|
0, 1, 2, 3, 4, 5, 6, 7, 8, 9
|
|
|
|
itertools.takewhile(is_even, itertools.count()) =>
|
|
0
|
|
|
|
:func:`itertools.dropwhile(predicate, iter) <itertools.dropwhile>` discards
|
|
elements while the predicate returns true, and then returns the rest of the
|
|
iterable's results. ::
|
|
|
|
itertools.dropwhile(less_than_10, itertools.count()) =>
|
|
10, 11, 12, 13, 14, 15, 16, 17, 18, 19, ...
|
|
|
|
itertools.dropwhile(is_even, itertools.count()) =>
|
|
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, ...
|
|
|
|
|
|
Grouping elements
|
|
-----------------
|
|
|
|
The last function I'll discuss, :func:`itertools.groupby(iter, key_func=None)
|
|
<itertools.groupby>`, is the most complicated. ``key_func(elem)`` is a function
|
|
that can compute a key value for each element returned by the iterable. If you
|
|
don't supply a key function, the key is simply each element itself.
|
|
|
|
:func:`~itertools.groupby` collects all the consecutive elements from the
|
|
underlying iterable that have the same key value, and returns a stream of
|
|
2-tuples containing a key value and an iterator for the elements with that key.
|
|
|
|
::
|
|
|
|
city_list = [('Decatur', 'AL'), ('Huntsville', 'AL'), ('Selma', 'AL'),
|
|
('Anchorage', 'AK'), ('Nome', 'AK'),
|
|
('Flagstaff', 'AZ'), ('Phoenix', 'AZ'), ('Tucson', 'AZ'),
|
|
...
|
|
]
|
|
|
|
def get_state(city_state):
|
|
return city_state[1]
|
|
|
|
itertools.groupby(city_list, get_state) =>
|
|
('AL', iterator-1),
|
|
('AK', iterator-2),
|
|
('AZ', iterator-3), ...
|
|
|
|
where
|
|
iterator-1 =>
|
|
('Decatur', 'AL'), ('Huntsville', 'AL'), ('Selma', 'AL')
|
|
iterator-2 =>
|
|
('Anchorage', 'AK'), ('Nome', 'AK')
|
|
iterator-3 =>
|
|
('Flagstaff', 'AZ'), ('Phoenix', 'AZ'), ('Tucson', 'AZ')
|
|
|
|
:func:`~itertools.groupby` assumes that the underlying iterable's contents will
|
|
already be sorted based on the key. Note that the returned iterators also use
|
|
the underlying iterable, so you have to consume the results of iterator-1 before
|
|
requesting iterator-2 and its corresponding key.
|
|
|
|
|
|
The functools module
|
|
====================
|
|
|
|
The :mod:`functools` module in Python 2.5 contains some higher-order functions.
|
|
A **higher-order function** takes one or more functions as input and returns a
|
|
new function. The most useful tool in this module is the
|
|
:func:`functools.partial` function.
|
|
|
|
For programs written in a functional style, you'll sometimes want to construct
|
|
variants of existing functions that have some of the parameters filled in.
|
|
Consider a Python function ``f(a, b, c)``; you may wish to create a new function
|
|
``g(b, c)`` that's equivalent to ``f(1, b, c)``; you're filling in a value for
|
|
one of ``f()``'s parameters. This is called "partial function application".
|
|
|
|
The constructor for :func:`~functools.partial` takes the arguments
|
|
``(function, arg1, arg2, ..., kwarg1=value1, kwarg2=value2)``. The resulting
|
|
object is callable, so you can just call it to invoke ``function`` with the
|
|
filled-in arguments.
|
|
|
|
Here's a small but realistic example::
|
|
|
|
import functools
|
|
|
|
def log(message, subsystem):
|
|
"""Write the contents of 'message' to the specified subsystem."""
|
|
print('%s: %s' % (subsystem, message))
|
|
...
|
|
|
|
server_log = functools.partial(log, subsystem='server')
|
|
server_log('Unable to open socket')
|
|
|
|
:func:`functools.reduce(func, iter, [initial_value]) <functools.reduce>`
|
|
cumulatively performs an operation on all the iterable's elements and,
|
|
therefore, can't be applied to infinite iterables. *func* must be a function
|
|
that takes two elements and returns a single value. :func:`functools.reduce`
|
|
takes the first two elements A and B returned by the iterator and calculates
|
|
``func(A, B)``. It then requests the third element, C, calculates
|
|
``func(func(A, B), C)``, combines this result with the fourth element returned,
|
|
and continues until the iterable is exhausted. If the iterable returns no
|
|
values at all, a :exc:`TypeError` exception is raised. If the initial value is
|
|
supplied, it's used as a starting point and ``func(initial_value, A)`` is the
|
|
first calculation. ::
|
|
|
|
>>> import operator, functools
|
|
>>> functools.reduce(operator.concat, ['A', 'BB', 'C'])
|
|
'ABBC'
|
|
>>> functools.reduce(operator.concat, [])
|
|
Traceback (most recent call last):
|
|
...
|
|
TypeError: reduce() of empty sequence with no initial value
|
|
>>> functools.reduce(operator.mul, [1,2,3], 1)
|
|
6
|
|
>>> functools.reduce(operator.mul, [], 1)
|
|
1
|
|
|
|
If you use :func:`operator.add` with :func:`functools.reduce`, you'll add up all the
|
|
elements of the iterable. This case is so common that there's a special
|
|
built-in called :func:`sum` to compute it:
|
|
|
|
>>> import functools
|
|
>>> functools.reduce(operator.add, [1,2,3,4], 0)
|
|
10
|
|
>>> sum([1,2,3,4])
|
|
10
|
|
>>> sum([])
|
|
0
|
|
|
|
For many uses of :func:`functools.reduce`, though, it can be clearer to just
|
|
write the obvious :keyword:`for` loop::
|
|
|
|
import functools
|
|
# Instead of:
|
|
product = functools.reduce(operator.mul, [1,2,3], 1)
|
|
|
|
# You can write:
|
|
product = 1
|
|
for i in [1,2,3]:
|
|
product *= i
|
|
|
|
|
|
The operator module
|
|
-------------------
|
|
|
|
The :mod:`operator` module was mentioned earlier. It contains a set of
|
|
functions corresponding to Python's operators. These functions are often useful
|
|
in functional-style code because they save you from writing trivial functions
|
|
that perform a single operation.
|
|
|
|
Some of the functions in this module are:
|
|
|
|
* Math operations: ``add()``, ``sub()``, ``mul()``, ``floordiv()``, ``abs()``, ...
|
|
* Logical operations: ``not_()``, ``truth()``.
|
|
* Bitwise operations: ``and_()``, ``or_()``, ``invert()``.
|
|
* Comparisons: ``eq()``, ``ne()``, ``lt()``, ``le()``, ``gt()``, and ``ge()``.
|
|
* Object identity: ``is_()``, ``is_not()``.
|
|
|
|
Consult the operator module's documentation for a complete list.
|
|
|
|
|
|
Small functions and the lambda expression
|
|
=========================================
|
|
|
|
When writing functional-style programs, you'll often need little functions that
|
|
act as predicates or that combine elements in some way.
|
|
|
|
If there's a Python built-in or a module function that's suitable, you don't
|
|
need to define a new function at all::
|
|
|
|
stripped_lines = [line.strip() for line in lines]
|
|
existing_files = filter(os.path.exists, file_list)
|
|
|
|
If the function you need doesn't exist, you need to write it. One way to write
|
|
small functions is to use the :keyword:`lambda` statement. ``lambda`` takes a
|
|
number of parameters and an expression combining these parameters, and creates
|
|
an anonymous function that returns the value of the expression::
|
|
|
|
adder = lambda x, y: x+y
|
|
|
|
print_assign = lambda name, value: name + '=' + str(value)
|
|
|
|
An alternative is to just use the ``def`` statement and define a function in the
|
|
usual way::
|
|
|
|
def adder(x, y):
|
|
return x + y
|
|
|
|
def print_assign(name, value):
|
|
return name + '=' + str(value)
|
|
|
|
Which alternative is preferable? That's a style question; my usual course is to
|
|
avoid using ``lambda``.
|
|
|
|
One reason for my preference is that ``lambda`` is quite limited in the
|
|
functions it can define. The result has to be computable as a single
|
|
expression, which means you can't have multiway ``if... elif... else``
|
|
comparisons or ``try... except`` statements. If you try to do too much in a
|
|
``lambda`` statement, you'll end up with an overly complicated expression that's
|
|
hard to read. Quick, what's the following code doing? ::
|
|
|
|
import functools
|
|
total = functools.reduce(lambda a, b: (0, a[1] + b[1]), items)[1]
|
|
|
|
You can figure it out, but it takes time to disentangle the expression to figure
|
|
out what's going on. Using a short nested ``def`` statements makes things a
|
|
little bit better::
|
|
|
|
import functools
|
|
def combine(a, b):
|
|
return 0, a[1] + b[1]
|
|
|
|
total = functools.reduce(combine, items)[1]
|
|
|
|
But it would be best of all if I had simply used a ``for`` loop::
|
|
|
|
total = 0
|
|
for a, b in items:
|
|
total += b
|
|
|
|
Or the :func:`sum` built-in and a generator expression::
|
|
|
|
total = sum(b for a,b in items)
|
|
|
|
Many uses of :func:`functools.reduce` are clearer when written as ``for`` loops.
|
|
|
|
Fredrik Lundh once suggested the following set of rules for refactoring uses of
|
|
``lambda``:
|
|
|
|
1. Write a lambda function.
|
|
2. Write a comment explaining what the heck that lambda does.
|
|
3. Study the comment for a while, and think of a name that captures the essence
|
|
of the comment.
|
|
4. Convert the lambda to a def statement, using that name.
|
|
5. Remove the comment.
|
|
|
|
I really like these rules, but you're free to disagree
|
|
about whether this lambda-free style is better.
|
|
|
|
|
|
Revision History and Acknowledgements
|
|
=====================================
|
|
|
|
The author would like to thank the following people for offering suggestions,
|
|
corrections and assistance with various drafts of this article: Ian Bicking,
|
|
Nick Coghlan, Nick Efford, Raymond Hettinger, Jim Jewett, Mike Krell, Leandro
|
|
Lameiro, Jussi Salmela, Collin Winter, Blake Winton.
|
|
|
|
Version 0.1: posted June 30 2006.
|
|
|
|
Version 0.11: posted July 1 2006. Typo fixes.
|
|
|
|
Version 0.2: posted July 10 2006. Merged genexp and listcomp sections into one.
|
|
Typo fixes.
|
|
|
|
Version 0.21: Added more references suggested on the tutor mailing list.
|
|
|
|
Version 0.30: Adds a section on the ``functional`` module written by Collin
|
|
Winter; adds short section on the operator module; a few other edits.
|
|
|
|
|
|
References
|
|
==========
|
|
|
|
General
|
|
-------
|
|
|
|
**Structure and Interpretation of Computer Programs**, by Harold Abelson and
|
|
Gerald Jay Sussman with Julie Sussman. Full text at
|
|
http://mitpress.mit.edu/sicp/. In this classic textbook of computer science,
|
|
chapters 2 and 3 discuss the use of sequences and streams to organize the data
|
|
flow inside a program. The book uses Scheme for its examples, but many of the
|
|
design approaches described in these chapters are applicable to functional-style
|
|
Python code.
|
|
|
|
http://www.defmacro.org/ramblings/fp.html: A general introduction to functional
|
|
programming that uses Java examples and has a lengthy historical introduction.
|
|
|
|
http://en.wikipedia.org/wiki/Functional_programming: General Wikipedia entry
|
|
describing functional programming.
|
|
|
|
http://en.wikipedia.org/wiki/Coroutine: Entry for coroutines.
|
|
|
|
http://en.wikipedia.org/wiki/Currying: Entry for the concept of currying.
|
|
|
|
Python-specific
|
|
---------------
|
|
|
|
http://gnosis.cx/TPiP/: The first chapter of David Mertz's book
|
|
:title-reference:`Text Processing in Python` discusses functional programming
|
|
for text processing, in the section titled "Utilizing Higher-Order Functions in
|
|
Text Processing".
|
|
|
|
Mertz also wrote a 3-part series of articles on functional programming
|
|
for IBM's DeveloperWorks site; see
|
|
`part 1 <http://www.ibm.com/developerworks/linux/library/l-prog/index.html>`__,
|
|
`part 2 <http://www.ibm.com/developerworks/linux/library/l-prog2/index.html>`__, and
|
|
`part 3 <http://www.ibm.com/developerworks/linux/library/l-prog3/index.html>`__,
|
|
|
|
|
|
Python documentation
|
|
--------------------
|
|
|
|
Documentation for the :mod:`itertools` module.
|
|
|
|
Documentation for the :mod:`operator` module.
|
|
|
|
:pep:`289`: "Generator Expressions"
|
|
|
|
:pep:`342`: "Coroutines via Enhanced Generators" describes the new generator
|
|
features in Python 2.5.
|
|
|
|
.. comment
|
|
|
|
Topics to place
|
|
-----------------------------
|
|
|
|
XXX os.walk()
|
|
|
|
XXX Need a large example.
|
|
|
|
But will an example add much? I'll post a first draft and see
|
|
what the comments say.
|
|
|
|
.. comment
|
|
|
|
Original outline:
|
|
Introduction
|
|
Idea of FP
|
|
Programs built out of functions
|
|
Functions are strictly input-output, no internal state
|
|
Opposed to OO programming, where objects have state
|
|
|
|
Why FP?
|
|
Formal provability
|
|
Assignment is difficult to reason about
|
|
Not very relevant to Python
|
|
Modularity
|
|
Small functions that do one thing
|
|
Debuggability:
|
|
Easy to test due to lack of state
|
|
Easy to verify output from intermediate steps
|
|
Composability
|
|
You assemble a toolbox of functions that can be mixed
|
|
|
|
Tackling a problem
|
|
Need a significant example
|
|
|
|
Iterators
|
|
Generators
|
|
The itertools module
|
|
List comprehensions
|
|
Small functions and the lambda statement
|
|
Built-in functions
|
|
map
|
|
filter
|
|
|
|
.. comment
|
|
|
|
Handy little function for printing part of an iterator -- used
|
|
while writing this document.
|
|
|
|
import itertools
|
|
def print_iter(it):
|
|
slice = itertools.islice(it, 10)
|
|
for elem in slice[:-1]:
|
|
sys.stdout.write(str(elem))
|
|
sys.stdout.write(', ')
|
|
print(elem[-1])
|
|
|
|
|