non-Pre-PEP: Syntactic replacement of built-in types with user-defined callables.
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Hi all, Built-in types such as float, string, or list are first-class citizens in Python sourcefiles, having syntactic support: myfloat = 1.0 mystring = "my string" mylist = [1,2,4,8] mydict = {1:"a", 2:"b", 3:"c"} myset = {1,2,3} User-defined classes are second-class citizens, requiring data to be manually converted from a type: mydecimal = Decimal("1.00000000000000001") myrope = Rope("my rope") myblist = BList([1,2,4,8]) myordereddict = OrderedDict((1,"a"), (2, "b"), (3, "c")) myfrozenset = frozenset([1,2,3]) If there's only one or two conversions needed in a file, then such conversion is not particularly burdensome, but if one wants to consistently use (say) decimals throughout a file then the ability to use a literal syntax makes for prettier source. Some languages have open types, allowing the addition of methods to built-in types. This is not considered desired behaviour for Python, since modifications made in one module can potentially affect code in other modules. A typedef is syntactic sugar to allow user-defined replacements to be treated as first-class citizens in code. They affect only the module in which they appear and do not modify the original type. To be typedeffable, something must be a builtin type, have a constant/syntactic representation, and be callable. Hence, typedeffable types would be limited to complex, dict, float, int, ?object?, list, slice, set, string, and tuple. No modification is made to __builtins__ or types, so conversion and/or reference to the original type is still possible. The syntax for a typedef is: from MODULE typedef ADAPTOR as TYPE OR typedef BUILTINADAPTOR as TYPE Syntactic constants of a given type are then wrapped with a call: ADAPTOR(SOURCELITERAL) where SOURCELITERAL is the string that appears in the sourcecode eg: from decimal typedef Decimal as float i = 1.000000000000000000000000000001 translates as: from decimal import Decimal as float i = Decimal("1.000000000000000000000000000001") Syntactic collections of a given type are always provided with a list of objects, eg: from decimal typedef Decimal as float from blist typedef BList as list i = 1.000000000000000000000000000001 b = [1.1, 4.2] translates as: from decimal import Decimal as float from blist import BList as list b = Blist([Decimal("1.1"), Decimal("4.2")]) and from collections typedef OrderedDict as dict d = {1:"a", 2:"b", 3:"c"} as: from collections import OrderedDict as dict d = OrderedDict([(1,"a"), (2,"b"), (3,"c")]) A typedef appears at the start of a module immediately after any __future__ imports. As no adaptors can be defined in a module before a typedef and typedefs are in no way a forward declaration, "typedef ADAPTOR as TYPE" only works for builtins, since to do otherwise would lead to one of two unpalatable options; either: a/ definition of adaptors would have to be allowed pre-typedef, which would allow them to be buried in code, making them far easier to miss; or b/ adaptors would be defined after the typedef, which means that you'd have to handle: typedef float as float def float(): pass or: typedef MyObject as object class MyObject(object): pass or: typedef myfloat as float x = 1.1 def myfloat(): pass It is true that if a valid typedef is made, the type can be redefined within the module; but the "consenting adults" rule applies -- it's possible to redefine str and float multiple times within a module as well, but that isn't recommended either (and the typedef at the top of the module at least indicates that non-standard behaviour is to be expected) It is a SyntaxError to typedef the same type more than once: from decimal typedef Decimal as float from types typedef FloatType as float #SyntaxError("Type 'float' already redefined.") Spelling: "typedef" is prettier than "pragma", and less likely to be in use than "use" but its behaviour is somewhat different from C's typedef, so perhaps another term may be preferred. Theoretical Performance Differences: Since a typedef is purely syntactic sugar, and all tranformational work would be done at compilation, running code should be no slower (there should be no new opcodes necessary) and by default no faster that performing manual conversion (though they may assist an optimisation). Unless optimisation magic is available, performance-critical code should be careful when typedeffing not to use typedeffed literals in inner loops. I know it's considered polite to provide code, but any implementation would have to be in C, so please accept this extremely fake dummy implementation which in no way resembles the way things really work as a poor substitute: typedefs = { FLOATTYPE: None, INTTYPE: None, LISTTYPE: None, DICTTYPE: None, ... } while True line = lines.next() type, module, adaptor = parsetypedef(line) if type is None: break if typedefs[type] is not None: raise SyntaxError("Typedef redef") typedefs[type] = adaptor if module is not None: emit_bytecode_for_import_from(type, module, adaptor) else: emit_bytecode_for_assignment(type, adaptor) parse([line] + lines) ... def emit_float(...): if typedefs[FLOATTYPE] is not None: emit_constant(typedefs[FLOATTYPE][0], stringliteral) else: ... # standard behaviour def emit_list(...): if typedefs[LISTTYPE] is not None: emit(LOADGLOBAL, typedefs[LISTTYPE]) # standard behaviour if typedefs[LISTTYPE] is not None: emit(CALL_FUNCTION) # standard behaviour All rights are assigned to the Python Software Foundation
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Taro