PEP: 501 Title: General purpose string interpolation Version: $Revision$ Last-Modified: $Date$ Author: Nick Coghlan Status: Draft Type: Standards Track Content-Type: text/x-rst Created: 08-Aug-2015 Python-Version: 3.6 Post-History: 08-Aug-2015 Abstract ======== PEP 498 proposes new syntactic support for string interpolation that is transparent to the compiler, allow name references from the interpolation operation full access to containing namespaces (as with any other expression), rather than being limited to explicitly name references. However, it only offers this capability for string formatting, making it likely we will see code like the following:: os.system(f"echo {user_message}") This kind of code is superficially elegant, but poses a significant problem if the interpolated value ``user_message`` is in fact provided by a user: it's an opening for a form of code injection attack, where the supplied user data has not been properly escaped before being passed to the ``os.system`` call. To address that problem (and a number of other concerns), this PEP proposes an alternative approach to compiler supported interpolation, based on a new ``__interpolate__`` magic method, and using a substitution syntax inspired by that used in ``string.Template`` and ES6 JavaScript, rather than adding a 4th substitution variable syntax to Python. Proposal ======== This PEP proposes that the new syntax:: value = !interpolator "Substitute $names and ${expressions} at runtime" be interpreted as:: _raw_template = "Substitute $names and ${expressions} at runtime" _parsed_fields = ( ("Substitute ", 0, "names", "", ""), (" and ", 1, "expressions", "", ""), (" at runtime", None, None, None, None), ) _field_values = (names, expressions) value = interpolator.__interpolate__(_raw_template, _parsed_fields, _field_values) Whitespace would be permitted between the interpolator name and the opening quote, but not required in most cases. The ``str`` builtin type would gain an ``__interpolate__`` implementation that supported the following ``str.format`` based semantics:: >>> import datetime >>> name = 'Jane' >>> age = 50 >>> anniversary = datetime.date(1991, 10, 12) >>> !str'My name is $name, my age next year is ${age+1}, my anniversary is ${anniversary:%A, %B %d, %Y}.' 'My name is Jane, my age next year is 51, my anniversary is Saturday, October 12, 1991.' >>> !str'She said her name is ${name!r}.' "She said her name is 'Jane'." The interpolation prefix could be used with single-quoted, double-quoted and triple quoted strings. It may also be used with raw strings, but in that case whitespace would be required between the interpolator name and the trailing string. This PEP does not propose to remove or deprecate any of the existing string formatting mechanisms, as those will remain valuable when formatting strings that are not present directly in the source code of the application. Rationale ========= PEP 498 makes interpolating values into strings with full access to Python's lexical namespace semantics simpler, but it does so at the cost of creating a situation where interpolating values into sensitive targets like SQL queries, shell commands and HTML templates will enjoy a much cleaner syntax when handled without regard for code injection attacks than when they are handled correctly. It also has the effect of introducing yet another syntax for substitution expressions into Python, when we already have 3 (``str.format``, ``bytes.__mod__`` and ``string.Template``) This PEP proposes to handle the latter issue by always specifying an explicit interpolator for interpolation operations, and the former by adopting the ``string.Template`` substitution syntax defined in PEP 292. The interpolation syntax devised for PEP 292 is deliberately simple so that the template strings can be extracted into an i18n message catalog, and passed to translators who may not themselves be developers. For these use cases, it is important that the interpolation syntax be as simple as possible, as the translators are responsible for preserving the substition markers, even as they translate the surrounding text. The PEP 292 syntax is also a common mesage catalog syntax already supporting by many commercial software translation support tools. PEP 498 correctly points out that the PEP 292 syntax isn't as flexible as that introduced for general purpose string formatting in PEP 3101, so this PEP adds that flexibility to the ``${ref}`` construct in PEP 292, and allows translation tools the option of rejecting usage of that more advanced syntax at runtime, rather than categorically rejecting it at compile time. The proposed permitted expressions, conversion specifiers, and format specifiers inside ``${ref}`` are exactly as defined in PEP 498. The specific proposal in this PEP is also deliberately close in both syntax and semantics to the general purpose interpolation syntax introduced to JavaScript in ES6, as we can reasonably expect a great many Python developers to be regularly switching back and forth between user interface code written in JavaScript and core application code written in Python. Specification ============= In source code, interpolation expressions are introduced by the new character ``!``. This is a new kind of expression, consisting of:: !DOTTED_NAME TEMPLATE_STRING Similar to ``yield`` expressions, this construct can be used without parentheses as a standalone expression statement, as the sole expression on the right hand side of an assignment or return statement, and as the sole argument to a function. In other situations, it requires containing parentheses to avoid ambiguity. The template string must be a Unicode string (byte strings are not permitted), and string literal concatenation operates as normal within the template string component of the expression. The template string is parsed into literals and expressions. Expressions appear as either identifiers prefixed with a single "$" character, or surrounded be a leading '${' and a trailing '}. The parts of the format string that are not expressions are separated out as string literals. While parsing the string, any doubled ``$$`` is replaced with a single ``$`` and is considered part of the literal text, rather than as introducing an expression. These components are then organised into a tuple of tuples, and passed to the ``__interpolate__`` method of the interpolator identified by the given name:: DOTTED_NAME.__interpolate__(TEMPLATE_STRING, , ) The template string field tuple is inspired by the interface of ``string.Formatter.parse``, and consists of a series of 5-tuples each containing: * a leading string literal (may be the empty string) * the substitution field position (zero-based enumeration) * the substitution expression text * the substitution conversion specifier (as defined by str.format) * the substitution format specifier (as defined by str.format) If a given substition field has no leading literal section, format specifier or conversion specifier, then the corresponding elements in the tuple are the empty string. If the final part of the string has no trailing substitution field, then the field number, format specifier and conversion specifier will all be ``None``. The expression text is simply the text of each interpolated expression, as it appeared in the original string, but without the leading and/or surrounding expression markers. The substitution field values tuple is created by evaluating the interpolated expressions in the exact runtime context where the interpolation expression appears in the source code. For the following example interpolation expression:: !str 'abc${expr1:spec1}${expr2!r:spec2}def${expr3:!s}ghi $ident $$jkl' the parsed fields tuple would be:: ( ('abc', 0, 'expr1', '', 'spec1'), ('', 1, 'expr2', 'r', 'spec2'), (def', 2, 'expr3', 's', ''), ('ghi', 3, 'ident', '', ''), ('$jkl', None, None, None, None) ) While the field values tuple would be:: (expr1, expr2, expr3, ident) The parsed fields tuple can be constant folded at compile time, while the expression values tuple will always need to be constructed at runtime. The ``str.__interpolate__`` implementation would have the following semantics, with field processing being defined in terms of the ``format`` builtin and ``str.format`` conversion specifiers:: _converter = string.Formatter().convert_field def __interpolate__(raw_template, fields, values): template_parts = [] for leading_text, field_num, expr, conversion, format_spec in fields: template_parts.append(leading_text) if field_num is not None: value = values[field_num] if conversion: value = _converter(value, conversion) field_text = format(value, format_spec) template_parts.append(field_str) return "".join(template_parts) Writing custom interpolators ---------------------------- To simplify the process of writing custom interpolators, it is proposed to add a new builtin decorator, ``interpolator``, which would be defined as:: def interpolator(f): f.__interpolate__ = f.__call__ return f This allows new interpolators to be written as:: @interpolator def my_custom_interpolator(raw_template, parsed_fields, field_values): ... Expression evaluation --------------------- The subexpressions that are extracted from the interpolation expression are evaluated in the context where the interpolation expression appears. This means the expression has full access to local, nonlocal and global variables. Any valid Python expression can be used inside ``${}``, including function and method calls. References without the surrounding braces are limited to looking up single identifiers. Because the substitution expressions are evaluated where the string appears in the source code, there are no additional security concerns related to the contents of the expression itself, as you could have also just written the same expression and used runtime field parsing:: >>> bar=10 >>> def foo(data): ... return data + 20 ... >>> !str 'input=$bar, output=${foo(bar)}' 'input=10, output=30' Is essentially equivalent to:: >>> 'input={}, output={}'.format(bar, foo(bar)) 'input=10, output=30' Handling code injection attacks ------------------------------- The proposed interpolation expressions make it potentially attractive to write code like the following:: myquery = !str "SELECT $column FROM $table;" mycommand = !str "cat $filename" mypage = !str "$content" These all represent potential vectors for code injection attacks, if any of the variables being interpolated happen to come from an untrusted source. The specific proposal in this PEP is designed to make it straightforward to write use case specific interpolators that take care of quoting interpolated values appropriately for the relevant security context:: myquery = !sql "SELECT $column FROM $table;" mycommand = !sh "cat $filename" mypage = !html "$content" This PEP does not cover adding such interpolators to the standard library, but instead ensures they can be readily provided by third party libraries. (Although it's tempting to propose adding __interpolate__ implementations to ``subprocess.call``, ``subprocess.check_call`` and ``subprocess.check_output``) Format and conversion specifiers -------------------------------- Aside from separating them out from the substitution expression, format and conversion specifiers are otherwise treated as opaque strings by the interpolation template parser - assigning semantics to those (or, alternatively, prohibiting their use) is handled at runtime by the specified interpolator. Error handling -------------- Either compile time or run time errors can occur when processing interpolation expressions. Compile time errors are limited to those errors that can be detected when parsing a template string into its component tuples. These errors all raise SyntaxError. Unmatched braces:: >>> !str 'x=${x' File "", line 1 SyntaxError: missing '}' in interpolation expression Invalid expressions:: >>> !str 'x=${!x}' File "", line 1 !x ^ SyntaxError: invalid syntax Run time errors occur when evaluating the expressions inside an template string. See PEP 498 for some examples. Different interpolators may also impose additional runtime constraints on acceptable interpolated expressions and other formatting details, which will be reported as runtime exceptions. Internationalising interpolated strings ======================================= Since this PEP derives its interpolation syntax from the internationalisation focused PEP 292, it's worth considering the potential implications this PEP may have for the internationalisation use case. Internationalisation enters the picture by writing a custom interpolator that performs internationalisation. For example, the following implementation would delegate interpolation calls to ``string.Template``:: @interpolator def i18n(template, fields, values): translated = gettext.gettext(template) value_map = _build_interpolation_map(fields, values) return string.Template(translated).safe_substitute(value_map) def _build_interpolation_map(fields, values): field_values = {} for literal_text, field_num, expr, conversion, format_spec in fields: assert expr.isidentifier() and not conversion and not format_spec if field_num is not None: field_values[expr] = values[field_num] return field_values And would then be invoked as:: print(!i18n "This is a $translated $message") Any actual implementation would need to address other issues (most notably message catalog extraction), but this gives the general idea of what might be possible. It's also worth noting that one of the benefits of the ``$`` based substitution syntax in this PEP is its compatibility with Mozilla's `l20n syntax `__, which uses ``{{ name }}`` for global substitution, and ``{{ $user }}`` for local context substitution. With the syntax in this PEP, an l20n interpolator could be written as:: translated = !l20n "{{ $user }} is running {{ appname }}" With the syntax proposed in PEP 498 (and neglecting the difficulty of doing catalog lookups using PEP 498's semantics), the necessary brace escaping would make the string look like this in order to interpolating the user variable while preserving all of the expected braces:: interpolated = "{{{{ ${user} }}}} is running {{{{ appname }}}}" Possible integration with the logging module ============================================ One of the challenges with the logging module has been that previously been unable to devise a reasonable migration strategy away from the use of printf-style formatting. The runtime parsing and interpolation overhead for logging messages also poses a problem for extensive logging of runtime events for monitoring purposes. While beyond the scope of this initial PEP, the proposal described here could potentially be applied to the logging module's event reporting APIs, permitting relevant details to be captured using forms like:: !logging.debug "Event: $event; Details: $data" !logging.critical "Error: $error; Details: $data" Discussion ========== Refer to PEP 498 for additional discussion, as several of the points there also apply to this PEP. Compatibility with IPython magic strings ---------------------------------------- IPython uses "!" to introduce custom interactive constructs. These are only used at statement level, and could continue to be special cased in the IPython runtime. This existing usage *did* help inspire the syntax proposed in this PEP. Preserving the raw template string ---------------------------------- Earlier versions of this PEP failed to make the raw template string available to interpolators. This greatly complicated the i18n example, as it needed to reconstruct the original template to pass to the message catalog lookup. Using a magic method rather than a global name lookup ----------------------------------------------------- Earlier versions of this PEP used an ``__interpolate__`` builtin, rather than a magic method on an explicitly named interpolator. Naming the interpolator eliminated a lot of the complexity otherwise associated with shadowing the builtin function in order to modify the semantics of interpolation. Relative order of conversion and format specifier in parsed fields ------------------------------------------------------------------ The relative order of the conversion specifier and the format specifier in the substitution field 5-tuple is defined to match the order they appear in the format string, which is unfortunately the inverse of the way they appear in the ``string.Formatter.parse`` 4-tuple. I consider this a design defect in ``string.Formatter.parse``, so I think it's worth fixing it in for the customer interpolator API, since the tuple already has other differences (like including both the field position number *and* the text of the expression). Using call syntax to support keyword-only parameters ---------------------------------------------------- The logging examples could potentially be better written as:: !logging.debug("Event: $event; Details: $data") !logging.critical("Error: $error; Details: $data") The key benefit this would provide is access to keyword arguments, so you could write: !logging.critical("Error: $error; Details: $data", exc_info=True) In this version, an interpolation expression would largely be syntactically equivalent to a normal function call, except that it would be restricted to accepting a single string literal as its sole position argument. 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) .. [#] PEP 215: String Interpolation (https://www.python.org/dev/peps/pep-0215/) .. [#] PEP 292: Simpler String Substitutions (https://www.python.org/dev/peps/pep-0292/) .. [#] PEP 3101: Advanced String Formatting (https://www.python.org/dev/peps/pep-3101/) .. [#] PEP 498: Literal string formatting (https://www.python.org/dev/peps/pep-0498/) .. [#] string.Formatter.parse (https://docs.python.org/3/library/string.html#string.Formatter.parse) 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: