PEP: 701 Title: Syntactic formalization of f-strings Author: Pablo Galindo , Batuhan Taskaya , Lysandros Nikolaou Discussions-To: Status: Draft Type: Standards Track Content-Type: text/x-rst Created: 15-Nov-2022 Python-Version: 3.12 Abstract ======== This document proposes to lift some of the restrictions originally formulated in :pep:`498` and to provide a formalized grammar for f-strings that can be integrated into the parser directly. The proposed syntactic formalization of f-strings will have some small side-effects on how f-strings are parsed and interpreted, allowing for a considerable number of advantages for end users and library developers, while also dramatically reducing the maintenance cost of the code dedicated to parsing f-strings. Motivation ========== When f-strings were originally introduced in :pep:`498`, the specification was provided without providing a formal grammar for f-strings. Additionally, the specification contains several restrictions that are imposed so the parsing of f-strings could be implemented into CPython without modifying the existing lexer. These limitations have been recognized previously and previous attempts have been made to lift them in :pep:`536`, but `none of this work was ever implemented`_. Some of these limitations (collected originally by :pep:`536`) are: #. It is impossible to use the quote character delimiting the f-string within the expression portion:: >>> f'Magic wand: { bag['wand'] }' ^ SyntaxError: invalid syntax #. A previously considered way around it would lead to escape sequences in executed code and is prohibited in f-strings:: >>> f'Magic wand { bag[\'wand\'] } string' SyntaxError: f-string expression portion cannot include a backslash #. Comments are forbidden even in multi-line f-strings:: >>> f'''A complex trick: { ... bag['bag'] # recursive bags! ... }''' SyntaxError: f-string expression part cannot include '#' #. Arbitrary nesting of expressions without expansion of escape sequences is available in every single other language employing a string interpolation method that uses expressions instead of just variable names, `per Wikipedia`_. These limitations serve no purpose from a language user perspective and can be lifted by giving f-literals a regular grammar without exceptions and implementing it using dedicated parse code. The other issue that f-strings have is that the current implementation in CPython relies on tokenising f-strings as ``STRING`` tokens and a post processing of these tokens. This has the following problems: #. It adds a considerable maintenance cost to the CPython parser. This is because the parsing code needs to be written by hand, which has historically led to a considerable number of inconsistencies and bugs. Writing and maintaining parsing code by hand in C has always been considered error prone and dangerous as it needs to deal with a lot of manual memory management over the original lexer buffers. #. The f-string parsing code is not able to use the new improved error message mechanisms that the new PEG parser, originally introduced in :pep:`617`, has allowed. The improvements that these error messages brought has been greatly celebrated but unfortunately f-strings cannot benefit from them because they are parsed in a separate piece of the parsing machinery. This is especially unfortunate, since there are several syntactical features of f-strings that can be confusing due to the different implicit tokenization that happens inside the expression part (for instance ``f"{y:=3}"`` is not an assignment expression). #. Other Python implementations have no way to know if they have implemented f-strings correctly because contrary to other language features, they are not part of the :ref:`official Python grammar `. This is important because several prominent alternative implementations are using CPython's PEG parser, `such as PyPy`_, and/or are basing their grammars on the official PEG grammar. The fact that f-strings use a separate parser prevents these alternative implementations from leveraging the official grammar and benefiting from improvements in error messages derived from the grammar. A version of this proposal was originally `discussed on Python-Dev`_ and `presented at the Python Language Summit 2022`_ where it was enthusiastically received. Rationale ========= By building on top of the new Python PEG Parser (:pep:`617`), this PEP proposes to redefine “f-strings”, especially emphasizing the clear separation of the string component and the expression (or replacement, ``{...}``) component. :pep:`498` summarizes the syntactical part of “f-strings” as the following: In Python source code, an f-string is a literal string, prefixed with ‘f’, which contains expressions inside braces. The expressions are replaced with their values. However, :pep:`498` also contained a formal list of exclusions on what can or cannot be contained inside the expression component (primarily due to the limitations of the existing parser). By clearly establishing the formal grammar, we now also have the ability to define the expression component of an f-string as truly "any applicable Python expression" (in that particular context) without being bound by the limitations imposed by the details of our implementation. The formalization effort and the premise above also has a significant benefit for Python programmers due to its ability to simplify and eliminate the obscure limitations. This reduces the mental burden and the cognitive complexity of f-string literals (as well as the Python language in general). #. The expression component can include any string literal that a normal Python expression can include. This opens up the possibility of nesting string literals (formatted or not) inside the expression component of an f-string with the same quote type (and length):: >>> f"These are the things: {", ".join(things)}" >>> f"{source.removesuffix(".py")}.c: $(srcdir)/{source}" >>> f"{f"{f"infinite"}"}" + " " + f"{f"nesting!!!"}" This choice not only allows for a more consistent and predictable behavior of what can be placed in f-strings but provides an intuitive way to manimulate string literals in a more flexible way without to having to fight the limitations of the implementation. #. Another issue that has felt unintuitive to most is the lack of support for backslashes within the expression component of an f-string. One example that keeps coming up is including a newline character in the expression part for joining containers. For example:: >>> a = ["hello", "world"] >>> f"{'\n'.join(a)}" File "", line 1 f"{'\n'.join(a)}" ^ SyntaxError: f-string expression part cannot include a backslash A common work-around for this was to either assign the newline to an intermediate variable or pre-create the whole string prior to creating the f-string:: >>> a = ["hello", "world"] >>> joined = '\n'.join(a) >>> f"{joined}" 'hello\nworld' It only feels natural to allow backslashes in the expression part now that the new PEG parser can easily support it. >>> a = ["hello", "world"] >>> f"{'\n'.join(a)}" 'hello\nworld' #. Before the changes proposed in this document, there was no explicit limit in how f-strings can be nested, but the fact that string quotes cannot be reused inside the expression component of f-strings made it impossible to nest f-strings arbitrarily. In fact, this is the most nested-fstring that can be written:: >>> f"""{f'''{f'{f"{1+1}"}'}'''}""" '2' As this PEP allows placing **any** valid Python expression inside the expression component of the f-strings, it is now possible to reuse quotes and therefore is possible to nest f-strings arbitrarily:: >>> f"{f"{f"{f"{f"{f"{1+1}"}"}"}"}"}" '2' Although this is just a consequence of allowing arbitrary expressions, the authors of this PEP do not believe that this is a fundamental benefit and we have decided that the language specification will not explicitly mandate that this nesting can be arbitrary. This is because allowing arbitrarily-deep nesting imposes a lot of extra complexity to the lexer implementation (particularly as lexer/parser pipelines need to allow "untokenizing" to support the 'f-string debugging expressions' and this is especially taxing when arbitrary nesting is allowed). Implementations are therefore free to impose a limit on the nesting depth if they need to. Note that this is not an uncommon situation, as the CPython implementation already imposes several limits all over the place, including a limit on the nesting depth of parentheses and brackets, a limit on the nesting of the blocks, a limit in the number of branches in ``if`` statements, a limit on the number of expressions in star-unpacking, etc. Specification ============= The formal proposed PEG grammar specification for f-strings is (see :pep:`617` for details on the syntax): .. code-block:: peg fstring | FSTRING_START fstring_middle* FSTRING_END fstring_middle | fstring_replacement_field | FSTRING_MIDDLE fstring_replacement_field | '{' (yield_expr | star_expressions) "="? [ "!" NAME ] [ ':' fstring_format_spec* ] '}' fstring_format_spec: | FSTRING_MIDDLE | fstring_replacement_field This PEP leaves up to the implementation the level of f-string nesting allowed. This means that limiting nesting is **not part of the language specification** but also the language specification **doesn't mandate arbitrary nesting**. Three new tokens are introduced: * ``FSTRING_START``: This token includes f-string character (``f``/``F``) and the open quote(s). * ``FSTRING_MIDDLE``: This token includes the text between the opening quote and the first expression brace (``{``) and the text between two expression braces (``}`` and ``{``). * ``FSTRING_END``: This token includes everything after the last expression brace (or the whole literal part if no expression exists) until the closing quote. These tokens are always string parts and they are semantically equivalent to the ``STRING`` token with the restrictions specified. These tokens must be produced by the lexer when lexing f-strings. This means that **the tokenizer cannot produce a single token for f-strings anymore**. How the lexer emits this token is **not specified** as this will heavily depend on every implementation (even the Python version of the lexer in the standard library is implemented differently to the one used by the PEG parser). As an example:: f'some words {a+b} more words {c+d} final words' will be tokenized as:: FSTRING_START - "f'" FSTRING_MIDDLE - 'some words ' LBRACE - '{' NAME - 'a' PLUS - '+' NAME - 'b' RBRACE - '}' FSTRING_MIDDLE - ' more words ' LBRACE - '{' NAME - 'c' PLUS - '+' NAME - 'd' RBRACE - '}' FSTRING_END - ' final words' (without the end quote) while ``f"""some words"""`` will be tokenized simply as:: FSTRING_START - 'f"""' FSTRING_END - 'some words' All restrictions mentioned in the PEP are lifted from f-literals, as explained below: * Expression portions may now contain strings delimited with the same kind of quote that is used to delimit the f-literal. * Backslashes may now appear within expressions just like anywhere else in Python code. In case of strings nested within f-literals, escape sequences are expanded when the innermost string is evaluated. * Comments, using the ``#`` character, are possible only in multi-line f-literals, since comments are terminated by the end of the line (which makes closing a single-line f-literal impossible) Backwards Compatibility ======================= This PEP is backwards compatible: any valid Python code will continue to be valid if this PEP is implemented and it will not change semantically. How to Teach This ================= As the concept of f-strings is already ubiquitous in the Python community, there is no fundamental need for users to learn anything new. However, as the formalized grammar allows some new possibilities, it is important that the formal grammar is added to the documentation and explained in detail, explicitly mentioning what constructs are possible since this PEP is aiming to avoid confusion. It is also beneficial to provide users with a simple framework for understanding what can be placed inside an f-string expression. In this case the authors think that this work will make it even simpler to explain this aspect of the language, since it can be summarized as: You can place any valid Python expression inside an f-string expression. With the changes in this PEP, there is no need to clarify that string quotes are limited to be different from the quotes of the enclosing string, because this is now allowed: as an arbitrary Python string can contain any possible choice of quotes, so can any f-string expression. Additionally there is no need to clarify that certain things are not allowed in the expression part because of implementation restructions such as comments, new line characters or backslashes. The only "surprising" difference is that as f-strings allow specifying a format, expressions that allow a ``:`` character at the top level still need to be enclosed in parenthesis. This is not new to this work, but it is important to emphasize that this restriction is still in place. This allows for an easier modification of the summary: You can place any valid Python expression inside an f-string expression, and everything after a ``:`` character at the top level will be identified as a format specification. Reference Implementation ======================== A reference implementation can be found in the implementation_ fork. Rejected Ideas ============== #. We have decided not to lift the restriction that some expression portions need to wrap ``':'`` and ``'!'`` in braces at the top level, e.g.:: >>> f'Useless use of lambdas: { lambda x: x*2 }' SyntaxError: unexpected EOF while parsing The reason is that this would this will introduce a considerable amount of complexity for no real benefit. This is due to the fact that the ``:`` character normally separates the f-string format specification. This format specification is currently tokenized as a string. As the tokenizer MUST tokenize what's on the right of the ``:`` as either a string or a stream of tokens, this won't allow the parser to differentiate between the different semantics as that would require the tokenizer to backtrack and produce a different set of tokens (this is, first try as a stream of tokens, and if it fails, try as a string for a format specifier). As there is no fundamental advantage in being able to allow lambdas and similar expressions at the top level, we have decided to keep the restriction that these must be parenthesized if needed:: >>> f'Useless use of lambdas: { (lambda x: x*2) }' Open Issues =========== None yet Footnotes ========= .. _official Python grammar: https://docs.python.org/3/reference/lexical_analysis.html#formatted-string-literals .. _none of this work was ever implemented: https://mail.python.org/archives/list/python-dev@python.org/thread/N43O4KNLZW4U7YZC4NVPCETZIVRDUVU2/#NM2A37THVIXXEYR4J5ZPTNLXGGUNFRLZ .. _such as PyPy: https://foss.heptapod.net/pypy/pypy/-/commit/fe120f89bf07e64a41de62b224e4a3d80e0fe0d4/pipelines?ref=branch%2Fpy3.9 .. _discussed on Python-Dev: https://mail.python.org/archives/list/python-dev@python.org/thread/54N3MOYVBDSJQZTU6MTCPLUPIFSDN5IS/#SAYU6SMP4KT7G7AQ6WVQYUDOSZPKHJMS .. _presented at the Python Language Summit 2022: https://pyfound.blogspot.com/2022/05/the-2022-python-language-summit-f.html .. _per Wikipedia: https://en.wikipedia.org/wiki/String_interpolation#Examples .. _implementation: https://github.com/we-like-parsers/cpython/tree/fstring-grammar Copyright ========= This document is placed in the public domain or under the CC0-1.0-Universal license, whichever is more permissive.