PEP 255 – Simple Generators
- PEP
- 255
- Title
- Simple Generators
- Author
- nas at arctrix.com (Neil Schemenauer), tim.peters at gmail.com (Tim Peters), magnus at hetland.org (Magnus Lie Hetland)
- Discussions-To
- python-iterators at lists.sourceforge.net
- Status
- Final
- Type
- Standards Track
- Requires
- 234
- Created
- 18-May-2001
- Python-Version
- 2.2
- Post-History
- 14-Jun-2001, 23-Jun-2001
Contents
- Abstract
- Motivation
- Specification: Yield
- Specification: Return
- Specification: Generators and Exception Propagation
- Specification: Try/Except/Finally
- Example
- Q & A
- Why not a new keyword instead of reusing
def
? - Why a new keyword for
yield
? Why not a builtin function instead? - Then why not some other special syntax without a new keyword?
- Why allow
return
at all? Why not force termination to be spelledraise StopIteration
? - Then why not allow an expression on
return
too?
- Why not a new keyword instead of reusing
- BDFL Pronouncements
- Reference Implementation
- Footnotes and References
- Copyright
Abstract
This PEP introduces the concept of generators to Python, as well as a new
statement used in conjunction with them, the yield
statement.
Motivation
When a producer function has a hard enough job that it requires maintaining state between values produced, most programming languages offer no pleasant and efficient solution beyond adding a callback function to the producer’s argument list, to be called with each value produced.
For example, tokenize.py
in the standard library takes this approach: the
caller must pass a tokeneater function to tokenize()
, called whenever
tokenize()
finds the next token. This allows tokenize to be coded in a
natural way, but programs calling tokenize are typically convoluted by the need
to remember between callbacks which token(s) were seen last. The tokeneater
function in tabnanny.py
is a good example of that, maintaining a state
machine in global variables, to remember across callbacks what it has already
seen and what it hopes to see next. This was difficult to get working
correctly, and is still difficult for people to understand. Unfortunately,
that’s typical of this approach.
An alternative would have been for tokenize to produce an entire parse of the Python program at once, in a large list. Then tokenize clients could be written in a natural way, using local variables and local control flow (such as loops and nested if statements) to keep track of their state. But this isn’t practical: programs can be very large, so no a priori bound can be placed on the memory needed to materialize the whole parse; and some tokenize clients only want to see whether something specific appears early in the program (e.g., a future statement, or, as is done in IDLE, just the first indented statement), and then parsing the whole program first is a severe waste of time.
Another alternative would be to make tokenize an iterator [1], delivering the
next token whenever its .next()
method is invoked. This is pleasant for the
caller in the same way a large list of results would be, but without the memory
and “what if I want to get out early?” drawbacks. However, this shifts the
burden on tokenize to remember its state between .next()
invocations, and
the reader need only glance at tokenize.tokenize_loop()
to realize what a
horrid chore that would be. Or picture a recursive algorithm for producing the
nodes of a general tree structure: to cast that into an iterator framework
requires removing the recursion manually and maintaining the state of the
traversal by hand.
A fourth option is to run the producer and consumer in separate threads. This allows both to maintain their states in natural ways, and so is pleasant for both. Indeed, Demo/threads/Generator.py in the Python source distribution provides a usable synchronized-communication class for doing that in a general way. This doesn’t work on platforms without threads, though, and is very slow on platforms that do (compared to what is achievable without threads).
A final option is to use the Stackless [2] [3] variant implementation of Python instead, which supports lightweight coroutines. This has much the same programmatic benefits as the thread option, but is much more efficient. However, Stackless is a controversial rethinking of the Python core, and it may not be possible for Jython to implement the same semantics. This PEP isn’t the place to debate that, so suffice it to say here that generators provide a useful subset of Stackless functionality in a way that fits easily into the current CPython implementation, and is believed to be relatively straightforward for other Python implementations.
That exhausts the current alternatives. Some other high-level languages provide pleasant solutions, notably iterators in Sather [4], which were inspired by iterators in CLU; and generators in Icon [5], a novel language where every expression is a generator. There are differences among these, but the basic idea is the same: provide a kind of function that can return an intermediate result (“the next value”) to its caller, but maintaining the function’s local state so that the function can be resumed again right where it left off. A very simple example:
def fib():
a, b = 0, 1
while 1:
yield b
a, b = b, a+b
When fib()
is first invoked, it sets a to 0 and b to 1, then yields b
back to its caller. The caller sees 1. When fib
is resumed, from its
point of view the yield
statement is really the same as, say, a print
statement: fib
continues after the yield with all local state intact. a
and b then become 1 and 1, and fib
loops back to the yield
, yielding
1 to its invoker. And so on. From fib
’s point of view it’s just
delivering a sequence of results, as if via callback. But from its caller’s
point of view, the fib
invocation is an iterable object that can be resumed
at will. As in the thread approach, this allows both sides to be coded in the
most natural ways; but unlike the thread approach, this can be done efficiently
and on all platforms. Indeed, resuming a generator should be no more expensive
than a function call.
The same kind of approach applies to many producer/consumer functions. For
example, tokenize.py
could yield the next token instead of invoking a
callback function with it as argument, and tokenize clients could iterate over
the tokens in a natural way: a Python generator is a kind of Python
iterator 1, but of an especially powerful kind.
Specification: Yield
A new statement is introduced:
yield_stmt: "yield" expression_list
yield
is a new keyword, so a future
statement 8 is needed to phase
this in: in the initial release, a module desiring to use generators must
include the line:
from __future__ import generators
near the top (see PEP 236 8) for details). Modules using the identifier
yield
without a future
statement will trigger warnings. In the
following release, yield
will be a language keyword and the future
statement will no longer be needed.
The yield
statement may only be used inside functions. A function that
contains a yield
statement is called a generator function. A generator
function is an ordinary function object in all respects, but has the new
CO_GENERATOR
flag set in the code object’s co_flags member.
When a generator function is called, the actual arguments are bound to function-local formal argument names in the usual way, but no code in the body of the function is executed. Instead a generator-iterator object is returned; this conforms to the iterator protocol 6, so in particular can be used in for-loops in a natural way. Note that when the intent is clear from context, the unqualified name “generator” may be used to refer either to a generator-function or a generator-iterator.
Each time the .next()
method of a generator-iterator is invoked, the code
in the body of the generator-function is executed until a yield
or
return
statement (see below) is encountered, or until the end of the body
is reached.
If a yield
statement is encountered, the state of the function is frozen,
and the value of expression_list is returned to .next()
’s caller. By
“frozen” we mean that all local state is retained, including the current
bindings of local variables, the instruction pointer, and the internal
evaluation stack: enough information is saved so that the next time
.next()
is invoked, the function can proceed exactly as if the yield
statement were just another external call.
Restriction: A yield
statement is not allowed in the try
clause of a
try/finally
construct. The difficulty is that there’s no guarantee the
generator will ever be resumed, hence no guarantee that the finally block will
ever get executed; that’s too much a violation of finally’s purpose to bear.
Restriction: A generator cannot be resumed while it is actively running:
>>> def g():
... i = me.next()
... yield i
>>> me = g()
>>> me.next()
Traceback (most recent call last):
...
File "<string>", line 2, in g
ValueError: generator already executing
Specification: Return
A generator function can also contain return statements of the form:
return
Note that an expression_list is not allowed on return statements in the body of a generator (although, of course, they may appear in the bodies of non-generator functions nested within the generator).
When a return statement is encountered, control proceeds as in any function
return, executing the appropriate finally
clauses (if any exist). Then a
StopIteration
exception is raised, signalling that the iterator is
exhausted. A StopIteration
exception is also raised if control flows off
the end of the generator without an explicit return.
Note that return means “I’m done, and have nothing interesting to return”, for both generator functions and non-generator functions.
Note that return isn’t always equivalent to raising StopIteration
: the
difference lies in how enclosing try/except
constructs are treated. For
example,:
>>> def f1():
... try:
... return
... except:
... yield 1
>>> print list(f1())
[]
because, as in any function, return
simply exits, but:
>>> def f2():
... try:
... raise StopIteration
... except:
... yield 42
>>> print list(f2())
[42]
because StopIteration
is captured by a bare except
, as is any
exception.
Specification: Generators and Exception Propagation
If an unhandled exception– including, but not limited to, StopIteration
–is raised by, or passes through, a generator function, then the exception is
passed on to the caller in the usual way, and subsequent attempts to resume the
generator function raise StopIteration
. In other words, an unhandled
exception terminates a generator’s useful life.
Example (not idiomatic but to illustrate the point):
>>> def f():
... return 1/0
>>> def g():
... yield f() # the zero division exception propagates
... yield 42 # and we'll never get here
>>> k = g()
>>> k.next()
Traceback (most recent call last):
File "<stdin>", line 1, in ?
File "<stdin>", line 2, in g
File "<stdin>", line 2, in f
ZeroDivisionError: integer division or modulo by zero
>>> k.next() # and the generator cannot be resumed
Traceback (most recent call last):
File "<stdin>", line 1, in ?
StopIteration
>>>
Specification: Try/Except/Finally
As noted earlier, yield
is not allowed in the try
clause of a
try/finally
construct. A consequence is that generators should allocate
critical resources with great care. There is no restriction on yield
otherwise appearing in finally
clauses, except
clauses, or in the
try
clause of a try/except
construct:
>>> def f():
... try:
... yield 1
... try:
... yield 2
... 1/0
... yield 3 # never get here
... except ZeroDivisionError:
... yield 4
... yield 5
... raise
... except:
... yield 6
... yield 7 # the "raise" above stops this
... except:
... yield 8
... yield 9
... try:
... x = 12
... finally:
... yield 10
... yield 11
>>> print list(f())
[1, 2, 4, 5, 8, 9, 10, 11]
>>>
Example
# A binary tree class.
class Tree:
def __init__(self, label, left=None, right=None):
self.label = label
self.left = left
self.right = right
def __repr__(self, level=0, indent=" "):
s = level*indent + `self.label`
if self.left:
s = s + "\n" + self.left.__repr__(level+1, indent)
if self.right:
s = s + "\n" + self.right.__repr__(level+1, indent)
return s
def __iter__(self):
return inorder(self)
# Create a Tree from a list.
def tree(list):
n = len(list)
if n == 0:
return []
i = n / 2
return Tree(list[i], tree(list[:i]), tree(list[i+1:]))
# A recursive generator that generates Tree labels 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
# Show it off: create a tree.
t = tree("ABCDEFGHIJKLMNOPQRSTUVWXYZ")
# Print the nodes of the tree in in-order.
for x in t:
print x,
print
# A non-recursive generator.
def inorder(node):
stack = []
while node:
while node.left:
stack.append(node)
node = node.left
yield node.label
while not node.right:
try:
node = stack.pop()
except IndexError:
return
yield node.label
node = node.right
# Exercise the non-recursive generator.
for x in t:
print x,
print
Both output blocks display:
A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
Q & A
Why not a new keyword instead of reusing def
?
See BDFL Pronouncements section below.
Why a new keyword for yield
? Why not a builtin function instead?
Control flow is much better expressed via keyword in Python, and yield is a
control construct. It’s also believed that efficient implementation in Jython
requires that the compiler be able to determine potential suspension points at
compile-time, and a new keyword makes that easy. The CPython reference
implementation also exploits it heavily, to detect which functions are
generator-functions (although a new keyword in place of def
would solve
that for CPython – but people asking the “why a new keyword?” question don’t
want any new keyword).
Then why not some other special syntax without a new keyword?
For example, one of these instead of yield 3
:
return 3 and continue
return and continue 3
return generating 3
continue return 3
return >> , 3
from generator return 3
return >> 3
return << 3
>> 3
<< 3
* 3
Did I miss one <wink>? Out of hundreds of messages, I counted three
suggesting such an alternative, and extracted the above from them. It would be
nice not to need a new keyword, but nicer to make yield
very clear – I
don’t want to have to deduce that a yield is occurring from making sense of a
previously senseless sequence of keywords or operators. Still, if this
attracts enough interest, proponents should settle on a single consensus
suggestion, and Guido will Pronounce on it.
Why allow return
at all? Why not force termination to be spelled raise StopIteration
?
The mechanics of StopIteration
are low-level details, much like the
mechanics of IndexError
in Python 2.1: the implementation needs to do
something well-defined under the covers, and Python exposes these mechanisms
for advanced users. That’s not an argument for forcing everyone to work at
that level, though. return
means “I’m done” in any kind of function, and
that’s easy to explain and to use. Note that return
isn’t always equivalent
to raise StopIteration
in try/except construct, either (see the
“Specification: Return” section).
Then why not allow an expression on return
too?
Perhaps we will someday. In Icon, return expr
means both “I’m done”, and
“but I have one final useful value to return too, and this is it”. At the
start, and in the absence of compelling uses for return expr
, it’s simply
cleaner to use yield
exclusively for delivering values.
BDFL Pronouncements
Issue
Introduce another new keyword (say, gen
or generator
) in place
of def
, or otherwise alter the syntax, to distinguish generator-functions
from non-generator functions.
Con
In practice (how you think about them), generators are functions, but with the twist that they’re resumable. The mechanics of how they’re set up is a comparatively minor technical issue, and introducing a new keyword would unhelpfully overemphasize the mechanics of how generators get started (a vital but tiny part of a generator’s life).
Pro
In reality (how you think about them), generator-functions are actually
factory functions that produce generator-iterators as if by magic. In this
respect they’re radically different from non-generator functions, acting more
like a constructor than a function, so reusing def
is at best confusing.
A yield
statement buried in the body is not enough warning that the
semantics are so different.
BDFL
def
it stays. No argument on either side is totally convincing, so I
have consulted my language designer’s intuition. It tells me that the syntax
proposed in the PEP is exactly right - not too hot, not too cold. But, like
the Oracle at Delphi in Greek mythology, it doesn’t tell me why, so I don’t
have a rebuttal for the arguments against the PEP syntax. The best I can come
up with (apart from agreeing with the rebuttals … already made) is “FUD”.
If this had been part of the language from day one, I very much doubt it would
have made Andrew Kuchling’s “Python Warts” page.
Reference Implementation
The current implementation, in a preliminary state (no docs, but well tested and solid), is part of Python’s CVS development tree 9. Using this requires that you build Python from source.
This was derived from an earlier patch by Neil Schemenauer 7.
Footnotes and References
- 1
- PEP 234, Iterators, Yee, Van Rossum http://www.python.org/dev/peps/pep-0234/
- 2
- http://www.stackless.com/
- 3
- PEP 219, Stackless Python, McMillan http://www.python.org/dev/peps/pep-0219/
- 4
- “Iteration Abstraction in Sather” Murer, Omohundro, Stoutamire and Szyperski http://www.icsi.berkeley.edu/~sather/Publications/toplas.html
- 5
- http://www.cs.arizona.edu/icon/
- 6
- The concept of iterators is described in PEP 234. See [1] above.
- 7
- http://python.ca/nas/python/generator.diff
- 8 (1, 2)
- PEP 236, Back to the __future__, Peters http://www.python.org/dev/peps/pep-0236/
- 9
- To experiment with this implementation, check out Python from CVS
according to the instructions at http://sf.net/cvs/?group_id=5470
Note that the std test
Lib/test/test_generators.py
contains many examples, including all those in this PEP.
Copyright
This document has been placed in the public domain.
Source: https://github.com/python/peps/blob/master/pep-0255.txt
Last modified: 2019-04-16 14:50:15 GMT