708 lines
23 KiB
Plaintext
708 lines
23 KiB
Plaintext
PEP: 498
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Title: Literal String Interpolation
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Version: $Revision$
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Last-Modified: $Date$
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Author: Eric V. Smith <eric@trueblade.com>
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Status: Draft
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Type: Standards Track
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Content-Type: text/x-rst
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Created: 01-Aug-2015
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Python-Version: 3.6
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Post-History: 07-Aug-2015, 30-Aug-2015, 04-Sep-2015
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Abstract
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========
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Python supports multiple ways to format text strings. These include
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%-formatting [#]_, ``str.format()`` [#]_, and ``string.Template``
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[#]_. Each of these methods have their advantages, but in addition
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have disadvantages that make them cumbersome to use in practice. This
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PEP proposed to add a new string formatting mechanism: Literal String
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Interpolation. In this PEP, such strings will be referred to as
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"f-strings", taken from the leading character used to denote such
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strings, and standing for "formatted strings".
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This PEP does not propose to remove or deprecate any of the existing
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string formatting mechanisms.
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f-strings provide a way to embed expressions inside string literals,
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using a minimal syntax. It should be noted that an f-string is really
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an expression evaluated at run time, not a constant value. In Python
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source code, an f-string is a literal string, prefixed with 'f', which
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contains expressions inside braces. The expressions are replaced with
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their values. Some examples are::
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>>> import datetime
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>>> name = 'Fred'
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>>> age = 50
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>>> anniversary = datetime.date(1991, 10, 12)
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>>> f'My name is {name}, my age next year is {age+1}, my anniversary is {anniversary:%A, %B %d, %Y}.'
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'My name is Fred, my age next year is 51, my anniversary is Saturday, October 12, 1991.'
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>>> f'He said his name is {name!r}.'
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"He said his name is 'Fred'."
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A similar feature was proposed in PEP 215. PEP 215 proposed to support
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a subset of Python expressions, and did not support the type-specific
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string formatting (the ``__format__()`` method) which was introduced
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with PEP 3101.
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Rationale
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=========
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This PEP is driven by the desire to have a simpler way to format
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strings in Python. The existing ways of formatting are either error
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prone, inflexible, or cumbersome.
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%-formatting is limited as to the types it supports. Only ints, strs,
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and doubles can be formatted. All other types are either not
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supported, or converted to one of these types before formatting. In
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addition, there's a well-known trap where a single value is passed::
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>>> msg = 'disk failure'
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>>> 'error: %s' % msg
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'error: disk failure'
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But if msg were ever to be a tuple, the same code would fail::
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>>> msg = ('disk failure', 32)
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>>> 'error: %s' % msg
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Traceback (most recent call last):
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File "<stdin>", line 1, in <module>
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TypeError: not all arguments converted during string formatting
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To be defensive, the following code should be used::
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>>> 'error: %s' % (msg,)
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"error: ('disk failure', 32)"
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``str.format()`` was added to address some of these problems with
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%-formatting. In particular, it uses normal function call syntax (and
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therefor supports multiple parameters) and it is extensible through
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the ``__format__()`` method on the object being converted to a
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string. See PEP 3101 for a detailed rationale. This PEP reuses much of
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the ``str.format()`` syntax and machinery, in order to provide
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continuity with an existing Python string formatting mechanism.
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However, ``str.format()`` is not without its issues. Chief among them
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is its verbosity. For example, the text ``value`` is repeated here::
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>>> value = 4 * 20
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>>> 'The value is {value}.'.format(value=value)
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'The value is 80.'
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Even in its simplest form there is a bit of boilerplate, and the value
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that's inserted into the placeholder is sometimes far removed from
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where the placeholder is situated::
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>>> 'The value is {}.'.format(value)
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'The value is 80.'
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With an f-string, this becomes::
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>>> f'The value is {value}.'
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'The value is 80.'
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f-strings provide a concise, readable way to include the value of
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Python expressions inside strings.
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In this sense, ``string.Template`` and %-formatting have similar
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shortcomings to ``str.format()``, but also support fewer formatting
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options. In particular, they do not support the ``__format__``
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protocol, so that there is no way to control how a specific object is
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converted to a string, nor can it be extended to additional types that
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want to control how they are converted to strings (such as ``Decimal``
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and ``datetime``). This example is not possible with
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``string.Template``::
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>>> value = 1234
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>>> f'input={value:#0.6x}'
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'input=0x04d2'
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And neither %-formatting nor ``string.Template`` can control
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formatting such as::
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>>> date = datetime.date(1991, 10, 12)
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>>> f'{date} was on a {date:%A}'
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'1991-10-12 was on a Saturday'
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No use of globals() or locals()
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-------------------------------
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In the discussions on python-dev [#]_, a number of solutions where
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presented that used locals() and globals() or their equivalents. All
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of these have various problems. Among these are referencing variables
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that are not otherwise used in a closure. Consider::
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>>> def outer(x):
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... def inner():
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... return 'x={x}'.format_map(locals())
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... return inner
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...
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>>> outer(42)()
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Traceback (most recent call last):
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File "<stdin>", line 1, in <module>
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File "<stdin>", line 3, in inner
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KeyError: 'x'
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This returns an error because the compiler has not added a reference
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to x inside the closure. You need to manually add a reference to x in
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order for this to work::
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>>> def outer(x):
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... def inner():
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... x
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... return 'x={x}'.format_map(locals())
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... return inner
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...
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>>> outer(42)()
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'x=42'
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In addition, using locals() or globals() introduces an information
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leak. A called routine that has access to the callers locals() or
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globals() has access to far more information than needed to do the
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string interpolation.
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Guido stated [#]_ that any solution to better string interpolation
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would not use locals() or globals().
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Specification
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=============
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In source code, f-strings are string literals that are prefixed by the
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letter 'f'. 'f' may be combined with 'r', in either order, to produce
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raw f-string literals. 'f' may not be combined with 'b': this PEP does
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not propose to add binary f-strings. 'f' may also be combined with
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'u', in either order, although adding 'u' has no effect.
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When tokenizing source files, f-strings use the same rules as normal
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strings, raw strings, binary strings, and triple quoted strings. That
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is, the string must end with the same character that it started with:
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if it starts with a single quote it must end with a single quote, etc.
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This implies that any code that currently scans Python code looking
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for strings should be trivially modifiable to recognize f-strings
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(parsing within an f-string is another matter, of course).
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Once tokenized, f-strings are decoded. This will convert backslash
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escapes such as ``'\n'``, ``'\xhh'``, ``'\uxxxx'``, ``'\Uxxxxxxxx'``,
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and named unicode characters ``'\N{name}'`` into their associated
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Unicode characters [#]_.
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Up to this point, the processing of f-strings and normal strings is
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exactly the same.
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The difference is that f-strings are further parsed in to literals and
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expressions. Expressions appear within curly braces ``'{'`` and
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``'}'``. The parts of the string outside of braces are literals. The
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expressions are evaluated, formatted with the existing __format__
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protocol, then the results are concatenated together with the string
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literals. While scanning the string for expressions, any doubled
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braces ``'{{'`` or ``'}}'`` are replaced by the corresponding single
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brace. Doubled opening braces do not signify the start of an
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expression.
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Following the expression, an optional type conversion may be
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specified. The allowed conversions are ``'!s'``, ``'!r'``, or
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``'!a'``. These are treated the same as in ``str.format()``: ``'!s'``
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calls ``str()`` on the expression, ``'!r'`` calls ``repr()`` on the
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expression, and ``'!a'`` calls ``ascii()`` on the expression. These
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conversions are applied before the call to ``__format__``. The only
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reason to use ``'!s'`` is if you want to specify a format specifier
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that applies to ``str``, not to the type of the expression.
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Similar to ``str.format()``, optional format specifiers maybe be
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included inside the f-string, separated from the expression (or the
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type conversion, if specified) by a colon. If a format specifier is
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not provided, an empty string is used.
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So, an f-string looks like::
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f ' <text> { <expression> <optional !s, !r, or !a> <optional : format specifier> } text ... '
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The resulting expression's ``__format__`` method is called with the
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format specifier. The resulting value is used when building the value
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of the f-string.
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Expressions cannot contain ``':'`` or ``'!'`` outside of strings or
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parentheses, brackets, or braces. The exception is that the ``'!='``
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operator is allowed as a special case.
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Escape sequences
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----------------
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Scanning an f-string for expressions happens after escape sequences
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are decoded. Because ``hex(ord('{')) == 0x7b``, the f-string
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``f'\u007b4*10}'`` is decoded to ``f'{4*10}'``, which evaluates as
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the integer 40::
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>>> f'\u007b4*10}'
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'40'
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>>> f'\x7b4*10}'
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'40'
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>>> f'\x7b4*10\N{RIGHT CURLY BRACKET}'
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'40'
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These examples aren't generally useful, they're just to show that
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escape sequences are processed before f-strings are parsed for
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expressions.
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Note that the correct way to have a literal brace appear in the
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resulting string value is to double the brace::
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>>> f'{{ {4*10} }}'
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'{ 40 }'
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>>> f'{{{4*10}}}'
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'{40}'
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Code equivalence
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----------------
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The exact code used to implement f-strings is not specified. However,
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it is guaranteed that any embedded value that is converted to a string
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will use that value's ``__format__`` method. This is the same
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mechanism that ``str.format()`` uses to convert values to strings.
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For example, this code::
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f'abc{expr1:spec1}{expr2!r:spec2}def{expr3:!s}ghi'
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Might be be evaluated as::
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'abc' + expr1.__format__(spec1) + repr(expr2).__format__(spec2) + 'def' + str(spec3).__format__('') + 'ghi'
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Expression evaluation
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---------------------
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The expressions that are extracted from the string are evaluated in
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the context where the f-string appeared. This means the expression has
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full access to local and global variables. Any valid Python expression
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can be used, including function and method calls.
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Because the f-strings are evaluated where the string appears in the
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source code, there is no additional expressiveness available with
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f-strings. There are also no additional security concerns: you could
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have also just written the same expression, not inside of an
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f-string::
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>>> def foo():
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... return 20
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...
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>>> f'result={foo()}'
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'result=20'
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Is equivalent to::
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>>> 'result=' + str(foo())
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'result=20'
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Expressions are parsed with the equivalent of ``ast.parse('(' +
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expression + ')', '<fstring>', 'eval')`` [#]_.
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Note that since the expression is enclosed by implicit parentheses
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before evaluation, expressions can contain newlines. For example::
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>>> x = 0
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>>> f'''{x
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... +1}'''
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'1'
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>>> d = {0: 'zero'}
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>>> f'''{d[0
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... ]}'''
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'zero'
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Format specifiers
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-----------------
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Format specifiers may also contain evaluated expressions. This allows
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code such as::
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>>> width = 10
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>>> precision = 4
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>>> value = decimal.Decimal('12.34567')
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>>> f'result: {value:{width}.{precision}}'
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'result: 12.35'
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Once expressions in a format specifier are evaluated (if necessary),
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format specifiers are not interpreted by the f-string evaluator. Just
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as in ``str.format()``, they are merely passed in to the
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``__format__()`` method of the object being formatted.
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Concatenating strings
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---------------------
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Adjacent f-strings and regular strings are concatenated. Regular
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strings are concatenated at compile time, and f-strings are
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concatenated at run time. For example, the expression::
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>>> x = 10
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>>> y = 'hi'
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>>> 'a' 'b' f'{x}' '{c}' f'str<{y:^4}>' 'd' 'e'
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yields the value::
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'ab10{c}str< hi >de'
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While the exact method of this run time concatenation is unspecified,
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the above code might evaluate to::
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'ab' + x.__format__('') + '{c}' + 'str<' + y.__format__('^4') + 'de'
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Error handling
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--------------
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Either compile time or run time errors can occur when processing
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f-strings. Compile time errors are limited to those errors that can be
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detected when scanning an f-string. These errors all raise
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``SyntaxError``.
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Unmatched braces::
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>>> f'x={x'
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File "<stdin>", line 1
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SyntaxError: missing '}' in format string expression
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Invalid expressions::
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>>> f'x={!x}'
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File "<fstring>", line 1
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!x
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^
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SyntaxError: invalid syntax
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Run time errors occur when evaluating the expressions inside an
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f-string. Note that an f-string can be evaluated multiple times, and
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work sometimes and raise an error at other times::
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>>> d = {0:10, 1:20}
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>>> for i in range(3):
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... print(f'{i}:{d[i]}')
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...
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0:10
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1:20
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Traceback (most recent call last):
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File "<stdin>", line 2, in <module>
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KeyError: 2
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or::
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>>> for x in (32, 100, 'fifty'):
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... print(f'x = {x:+3}')
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...
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'x = +32'
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'x = +100'
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Traceback (most recent call last):
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File "<stdin>", line 2, in <module>
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ValueError: Sign not allowed in string format specifier
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Leading and trailing whitespace in expressions is ignored
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---------------------------------------------------------
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For ease of readability, leading and trailing whitespace in
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expressions is ignored.
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Evaluation order of expressions
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-------------------------------
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The expressions in an f-string are evaluated in left-to-right
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order. This is detectable only if the expressions have side effects::
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>>> def fn(l, incr):
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... result = l[0]
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... l[0] += incr
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... return result
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...
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>>> lst = [0]
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>>> f'{fn(lst,2)} {fn(lst,3)}'
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'0 2'
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>>> f'{fn(lst,2)} {fn(lst,3)}'
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'5 7'
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>>> lst
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[10]
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Discussion
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==========
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python-ideas discussion
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-----------------------
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Most of the discussions on python-ideas [#]_ focused on three issues:
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- How to denote f-strings,
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- How to specify the location of expressions in f-strings, and
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- Whether to allow full Python expressions.
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How to denote f-strings
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***********************
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Because the compiler must be involved in evaluating the expressions
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contained in the interpolated strings, there must be some way to
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denote to the compiler which strings should be evaluated. This PEP
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chose a leading ``'f'`` character preceding the string literal. This
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is similar to how ``'b'`` and ``'r'`` prefixes change the meaning of
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the string itself, at compile time. Other prefixes were suggested,
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such as ``'i'``. No option seemed better than the other, so ``'f'``
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was chosen.
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Another option was to support special functions, known to the
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compiler, such as ``Format()``. This seems like too much magic for
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Python: not only is there a chance for collision with existing
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identifiers, the PEP author feels that it's better to signify the
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magic with a string prefix character.
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How to specify the location of expressions in f-strings
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*******************************************************
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This PEP supports the same syntax as ``str.format()`` for
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distinguishing replacement text inside strings: expressions are
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contained inside braces. There were other options suggested, such as
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``string.Template``'s ``$identifier`` or ``${expression}``.
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While ``$identifier`` is no doubt more familiar to shell scripters and
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users of some other languages, in Python ``str.format()`` is heavily
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used. A quick search of Python's standard library shows only a handful
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of uses of ``string.Template``, but hundreds of uses of
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``str.format()``.
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Another proposed alternative was to have the substituted text between
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``\{`` and ``}`` or between ``\{`` and ``\}``. While this syntax would
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probably be desirable if all string literals were to support
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interpolation, this PEP only supports strings that are already marked
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with the leading ``'f'``. As such, the PEP is using unadorned braces
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to denoted substituted text, in order to leverage end user familiarity
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with ``str.format()``.
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Supporting full Python expressions
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**********************************
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Many people on the python-ideas discussion wanted support for either
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only single identifiers, or a limited subset of Python expressions
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(such as the subset supported by ``str.format()``). This PEP supports
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full Python expressions inside the braces. Without full expressions,
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some desirable usage would be cumbersome. For example::
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>>> f'Column={col_idx+1}'
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>>> f'number of items: {len(items)}'
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would become::
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>>> col_number = col_idx+1
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>>> f'Column={col_number}'
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>>> n_items = len(items)
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>>> f'number of items: {n_items}'
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While it's true that very ugly expressions could be included in the
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f-strings, this PEP takes the position that such uses should be
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addressed in a linter or code review::
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>>> f'mapping is { {a:b for (a, b) in ((1, 2), (3, 4))} }'
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'mapping is {1: 2, 3: 4}'
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Similar support in other languages
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----------------------------------
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Wikipedia has a good discussion of string interpolation in other
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programming languages [#]_. This feature is implemented in many
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languages, with a variety of syntaxes and restrictions.
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Differences between f-string and str.format expressions
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-------------------------------------------------------
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There is one small difference between the limited expressions allowed
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in ``str.format()`` and the full expressions allowed inside
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f-strings. The difference is in how index lookups are performed. In
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``str.format()``, index values that do not look like numbers are
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converted to strings::
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>>> d = {'a': 10, 'b': 20}
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>>> 'a={d[a]}'.format(d=d)
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'a=10'
|
||
|
||
Notice that the index value is converted to the string ``'a'`` when it
|
||
is looked up in the dict.
|
||
|
||
However, in f-strings, you would need to use a literal for the value
|
||
of ``'a'``::
|
||
|
||
>>> f'a={d["a"]}'
|
||
'a=10'
|
||
|
||
This difference is required because otherwise you would not be able to
|
||
use variables as index values::
|
||
|
||
>>> a = 'b'
|
||
>>> f'a={d[a]}'
|
||
'a=20'
|
||
|
||
See [#]_ for a further discussion. It was this observation that led to
|
||
full Python expressions being supported in f-strings.
|
||
|
||
Furthermore, the limited expressions that ``str.format()`` understands
|
||
need not be valid Python expressions. For example::
|
||
|
||
>>> '{i[";]}'.format(i={'";':4})
|
||
'4'
|
||
|
||
For this reason, the str.format() "expression parser" is not suitable
|
||
for use when implementing f-strings.
|
||
|
||
Triple-quoted f-strings
|
||
-----------------------
|
||
|
||
Triple quoted f-strings are allowed. These strings are parsed just as
|
||
normal triple-quoted strings are. After parsing and decoding, the
|
||
normal f-string logic is applied, and ``__format__()`` on each value
|
||
is called.
|
||
|
||
Raw f-strings
|
||
-------------
|
||
|
||
Raw and f-strings may be combined. For example they could be used to
|
||
build up regular expressions::
|
||
|
||
>>> header = 'Subject'
|
||
>>> fr'{header}:\s+'
|
||
'Subject:\\s+'
|
||
|
||
In addition, raw f-strings may be combined with triple-quoted strings.
|
||
|
||
No binary f-strings
|
||
-------------------
|
||
|
||
For the same reason that we don't support ``bytes.format()``, you may
|
||
not combine ``'f'`` with ``'b'`` string literals. The primary problem
|
||
is that an object's ``__format__()`` method may return Unicode data that
|
||
is not compatible with a bytes string.
|
||
|
||
Binary f-strings would first require a solution for
|
||
``bytes.format()``. This idea has been proposed in the past, most
|
||
recently in PEP 461 [#]_. The discussions of such a feature usually
|
||
suggest either
|
||
|
||
- adding a method such as ``__bformat__()`` so an object can control
|
||
how it is converted to bytes, or
|
||
|
||
- having ``bytes.format()`` not be as general purpose or extensible
|
||
as ``str.format()``.
|
||
|
||
Both of these remain as options in the future, if such functionality
|
||
is desired.
|
||
|
||
``!s``, ``!r``, and ``!a`` are redundant
|
||
----------------------------------------
|
||
|
||
The ``!s``, ``!r``, and ``!a`` conversions are not strictly
|
||
required. Because arbitrary expressions are allowed inside the
|
||
f-strings, this code::
|
||
|
||
>>> a = 'some string'
|
||
>>> f'{a!r}'
|
||
"'some string'"
|
||
|
||
Is identical to::
|
||
|
||
>>> f'{repr(a)}'
|
||
"'some string'"
|
||
|
||
Similarly, ``!s`` can be replaced by calls to ``str()`` and ``!a`` by
|
||
calls to ``ascii()``.
|
||
|
||
However, ``!s``, ``!r``, and ``!a`` are supported by this PEP in order
|
||
to minimize the differences with ``str.format()``. ``!s``, ``!r``, and
|
||
``!a`` are required in ``str.format()`` because it does not allow the
|
||
execution of arbitrary expressions.
|
||
|
||
Lambdas inside expressions
|
||
--------------------------
|
||
|
||
Because lambdas use the ``':'`` character, they cannot appear outside
|
||
of parenthesis in an expression. The colon is interpreted as the start
|
||
of the format specifier, which means the start of the lambda
|
||
expression is seen and is syntactically invalid. As there's no
|
||
practical use for a plain lambda in an f-string expression, this is
|
||
not seen as much of a limitation.
|
||
|
||
If you feel you must use lambdas, they may be used inside of parentheses::
|
||
|
||
>>> f'{(lambda x: x*2)(3)}'
|
||
'6'
|
||
|
||
Examples from Python's source code
|
||
==================================
|
||
|
||
Here are some examples from Python source code that currently use
|
||
``str.format()``, and how they would look with f-strings. This PEP
|
||
does not recommend wholesale converting to f-strings, these are just
|
||
examples of real-world usages of ``str.format()`` and how they'd look
|
||
if written from scratch using f-strings.
|
||
|
||
``Lib/asyncio/locks.py``::
|
||
|
||
extra = '{},waiters:{}'.format(extra, len(self._waiters))
|
||
extra = f'{extra},waiters:{len(self._waiters)}'
|
||
|
||
``Lib/configparser.py``::
|
||
|
||
message.append(" [line {0:2d}]".format(lineno))
|
||
message.append(f" [line {lineno:2d}]")
|
||
|
||
``Tools/clinic/clinic.py``::
|
||
|
||
methoddef_name = "{}_METHODDEF".format(c_basename.upper())
|
||
methoddef_name = f"{c_basename.upper()}_METHODDEF"
|
||
|
||
``python-config.py``::
|
||
|
||
print("Usage: {0} [{1}]".format(sys.argv[0], '|'.join('--'+opt for opt in valid_opts)), file=sys.stderr)
|
||
print(f"Usage: {sys.argv[0]} [{'|'.join('--'+opt for opt in valid_opts)}]", file=sys.stderr)
|
||
|
||
References
|
||
==========
|
||
|
||
.. [#] %-formatting
|
||
(https://docs.python.org/3/library/stdtypes.html#printf-style-string-formatting)
|
||
|
||
.. [#] str.format
|
||
(https://docs.python.org/3/library/string.html#formatstrings)
|
||
|
||
.. [#] string.Template documentation
|
||
(https://docs.python.org/3/library/string.html#template-strings)
|
||
|
||
.. [#] Formatting using locals() and globals()
|
||
(https://mail.python.org/pipermail/python-ideas/2015-July/034671.html)
|
||
|
||
.. [#] Avoid locals() and globals()
|
||
(https://mail.python.org/pipermail/python-ideas/2015-July/034701.html)
|
||
|
||
.. [#] String literal description
|
||
(https://docs.python.org/3/reference/lexical_analysis.html#string-and-bytes-literals)
|
||
|
||
.. [#] ast.parse() documentation
|
||
(https://docs.python.org/3/library/ast.html#ast.parse)
|
||
|
||
.. [#] Start of python-ideas discussion
|
||
(https://mail.python.org/pipermail/python-ideas/2015-July/034657.html)
|
||
|
||
.. [#] Wikipedia article on string interpolation
|
||
(https://en.wikipedia.org/wiki/String_interpolation)
|
||
|
||
.. [#] Differences in str.format() and f-string expressions
|
||
(https://mail.python.org/pipermail/python-ideas/2015-July/034726.html)
|
||
|
||
.. [#] PEP 461 rejects bytes.format()
|
||
(https://www.python.org/dev/peps/pep-0461/#proposed-variations)
|
||
|
||
Copyright
|
||
=========
|
||
|
||
This document has been placed in the public domain.
|
||
|
||
|
||
..
|
||
Local Variables:
|
||
mode: indented-text
|
||
indent-tabs-mode: nil
|
||
sentence-end-double-space: t
|
||
fill-column: 70
|
||
coding: utf-8
|
||
End:
|