PEP: 292 Title: Simpler String Substitutions Version: $Revision$ Last-Modified: $Date$ Author: barry@python.org (Barry A. Warsaw) Status: Draft Type: Standards Track Created: 18-Jun-2002 Python-Version: 2.3 Post-History: 18-Jun-2002 Abstract This PEP describes a simpler string substitution feature, also known as string interpolation. This PEP is "simpler" in two respects: 1. Python's current string substitution feature (commonly known as %-substitutions) is complicated and error prone. This PEP is simpler at the cost of less expressiveness. 2. PEP 215 proposed an alternative string interpolation feature, introducing a new `$' string prefix. PEP 292 is simpler than this because it involves no syntax changes and has much simpler rules for what substitutions can occur in the string. Rationale Python currently supports a string substitution (a.k.a. string interpolation) syntax based on C's printf() % formatting character[1]. While quite rich, %-formatting codes are also quite error prone, even for experienced Python programmers. A common mistake is to leave off the trailing format character, e.g. the `s' in "%(name)s". In addition, the rules for what can follow a % sign are fairly complex, while the usual application rarely needs such complexity. Also error prone is the right-hand side of the % operator: e.g. singleton tuples. Most scripts need to do some string interpolation, but most of those use simple `stringification' formats, i.e. %s or %(name)s This form should be made simpler and less error prone. A Simpler Proposal Here we propose the addition of a new string method, called .sub() which performs substitution of mapping values into a string with special substitution placeholders. These placeholders are introduced with the $ character. The following rules for $-placeholders apply: 1. $$ is an escape; it is replaced with a single $ 2. $identifier names a substitution placeholder matching a mapping key of "identifier". "identifier" must be a Python identifier as defined in [2]. The first non-identifier character after the $ character terminates this placeholder specification. 3. ${identifier} is equivalent to $identifier. It is required for when valid identifier characters follow the placeholder but are not part of the placeholder, e.g. "${noun}ification". No other characters have special meaning. The .sub() method takes an optional mapping (e.g. dictionary) where the keys match placeholders in the string, and the values are substituted for the placeholders. For example: '${name} was born in ${country}'.sub({'name': 'Guido', 'country': 'the Netherlands'}) returns 'Guido was born in the Netherlands' The mapping argument is optional; if it is omitted then the mapping is taken from the locals and globals of the context in which the .sub() method is executed. For example: def birth(self, name): country = self.countryOfOrigin[name] return '${name} was born in ${country}'.sub() birth('Guido') returns 'Guido was born in the Netherlands' Why `$' and Braces? The BDFL said it best: The $ means "substitution" in so many languages besides Perl that I wonder where you've been. [...] We're copying this from the shell. Security Issues Never use no-arg .sub() on strings that come from untrusted sources. It could be used to gain unauthorized information about variables in your local or global scope. Reference Implementation Here's a Python 2.2-based reference implementation. Of course the real implementation would be in C, would not require a string subclass, and would not be modeled on the existing %-interpolation feature. import sys import re class dstr(str): def sub(self, mapping=None): # Default mapping is locals/globals of caller if mapping is None: frame = sys._getframe(1) mapping = frame.f_globals.copy() mapping.update(frame.f_locals) def repl(m): return mapping[m.group(m.lastindex)] return re.sub(r'\$(?:([_a-z]\w*)|\{([_a-z]\w*)\})', repl, self) And here are some examples: s = dstr('${name} was born in ${country}') print s.sub({'name': 'Guido', 'country': 'the Netherlands'}) name = 'Barry' country = 'the USA' print s.sub() This will print "Guido was born in the Netherlands" followed by "Barry was born in the USA". Handling Missing Keys What should happen when one of the substitution keys is missing from the mapping (or the locals/globals namespace if no argument is given)? There are two possibilities: - We can simply allow the exception. - We can return the original substitution placeholder unchanged. An example of the first is: print dstr('${name} was born in ${country}').sub({'name': 'Bob'}) would raise: Traceback (most recent call last): File "sub.py", line 66, in ? print s.sub({'name': 'Bob'}) File "sub.py", line 26, in sub return EMPTYSTRING.join(filter(None, parts)) % mapping KeyError: country An example of the second is: print dstr('${name} was born in ${country}').sub({'name': 'Bob'}) would print: Bob was born in ${country} We could almost ignore the issue, since the latter example could be accomplished by passing in a "safe-dictionary" in instead of a normal dictionary, like so: class safedict(dict): def __getitem__(self, key): try: return dict.__getitem__(self, key) except KeyError: return '${%s}' % key so that d = safedict({'name': 'Bob'}) print dstr('${name} was born in ${country}').sub(d) would print: Bob was born in ${country} The one place where this won't work is when no arguments are given to the .sub() method. .sub() wouldn't know whether to wrap locals/globals in a safedict or not. This ambiguity can be solved in several ways: - we could have a parallel method called .safesub() which always wrapped its argument in a safedict() - .sub() could take an optional keyword argument flag which indicates whether to wrap the argument in a safedict or not. - .sub() could take an optional keyword argument which is a callable that would get called with the original mapping and return the mapping to be used for the substitution. By default, this callable would be the identity function, but you could easily pass in the safedict constructor instead. BDFL proto-pronouncement: Strongly in favor of raising the exception, with KeyError when a dict is used and NameError when locals/globals are used. There may not be sufficient use case for soft failures in the no-argument version. Open Issues, Comments, and Suggestions - Ka-Ping Yee makes the suggestion that .sub() should take keyword arguments instead of a dictionary, and that if a dictionary was to be passed in it should be done with **dict. For example: s = '${name} was born in ${country}' print s.sub(name='Guido', country='the Netherlands') or print s.sub(**{'name': 'Guido', 'country': 'the Netherlands'}) - Paul Prescod wonders whether having a method use sys._getframe() doesn't set a bad precedent. - Oren Tirosh suggests that .sub() take an optional argument which would be used as a default for missing keys. If the optional argument were not given, an exception would be raised. This may not play well with Ka-Ping's suggestion. - Other suggestions have been made as an alternative to a string method including: a builtin function, a function in a module, an operator (similar to "string % dict", e.g. "string / dict"). One strong argument for making it a built-in is given by Paul Prescod: "I really hate putting things in modules that will be needed in a Python programmer's second program (the one after "Hello world"). If this is to be the *simpler* way of doing introspection then getting at it should be simpler than getting at "%". $ is taught in hour 2, import is taught on day 2. Some people may never make it to the metaphorical day 2 if they are doing simple text processing in some kind of embedded-Python environment." - Should we take a cue from the `make' program and allow $(name) as an alternative (or instead of) ${name}? - Should we require a dictionary to the .sub() method? Some people feel that it could be a security risk allowing implicit access to globals/locals, even with the proper admonitions in the documentation. In that case, a new built-in would be necessary (because none of globals(), locals(), or vars() does the right the w.r.t. nested scopes, etc.). Chirstian Tismer has suggested allvars(). Perhaps allvars() should be a method on a frame object (too?)? - It has been suggested that using $ at all violates TOOWTDI. Some other suggestions include using the % sign in the following way: %{name} Comparison to PEP 215 PEP 215 describes an alternate proposal for string interpolation. Unlike that PEP, this one does not propose any new syntax for Python. All the proposed new features are embodied in a new string method. PEP 215 proposes a new string prefix representation such as $"" which signal to Python that a new type of string is present. $-strings would have to interact with the existing r-prefixes and u-prefixes, essentially doubling the number of string prefix combinations. PEP 215 also allows for arbitrary Python expressions inside the $-strings, so that you could do things like: import sys print $"sys = $sys, sys = $sys.modules['sys']" which would return sys = , sys = It's generally accepted that the rules in PEP 215 are safe in the sense that they introduce no new security issues (see PEP 215, "Security Issues" for details). However, the rules are still quite complex, and make it more difficult to see what exactly is the substitution placeholder in the original $-string. By design, this PEP does not provide as much interpolation power as PEP 215, however it is expected that the no-argument version of .sub() allows at least as much power with no loss of readability. BDFL Weathervane Guido lays out[3] what he feels are the real issues that need to be fleshed out in this PEP: - Compile-time vs. run-time parsing. I've become convinced that the compiler should do the parsing: this is the only way to make access to variables in nested scopes work, avoids security issues, and makes it easier to diagnose errors (e.g. in PyChecker). - How to support translation. Here the template must be replaced at run-time, but it is still desirable that the collection of available names is known at compile time (to avoid the security issues). - Optional formatting specifiers. I agree with Lalo that these should not be part of the interpolation syntax but need to be dealt with at a different level. I think these are only relevant for numeric data. Funny, there's still a (now-deprecated) module fpformat.py that supports arbitrary floating point formatting, and string.zfill() supports a bit of integer formatting. References [1] String Formatting Operations http://www.python.org/doc/current/lib/typesseq-strings.html [2] Identifiers and Keywords http://www.python.org/doc/current/ref/identifiers.html [3] Guido's python-dev posting from 21-Jul-2002 http://mail.python.org/pipermail/python-dev/2002-July/026397.html 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 End: