PEP: 511 Title: API for code transformers Version: $Revision$ Last-Modified: $Date$ Author: Victor Stinner Status: Rejected Type: Standards Track Content-Type: text/x-rst Created: 04-Jan-2016 Python-Version: 3.6 Rejection Notice ================ This PEP was rejected by its author. This PEP was seen as blessing new Python-like programming languages which are close but incompatible with the regular Python language. It was decided to not promote syntaxes incompatible with Python. This PEP was also seen as a nice tool to experiment new Python features, but it is already possible to experiment them without the PEP, only with importlib hooks. If a feature becomes useful, it should be directly part of Python, instead of depending on an third party Python module. Finally, this PEP was driven was the FAT Python optimization project which was abandoned in 2016, since it was not possible to show any significant speedup, but also because of the lack of time to implement the most advanced and complex optimizations. Abstract ======== Propose an API to register bytecode and AST transformers. Add also ``-o OPTIM_TAG`` command line option to change ``.pyc`` filenames, ``-o noopt`` disables the peephole optimizer. Raise an ``ImportError`` exception on import if the ``.pyc`` file is missing and the code transformers required to transform the code are missing. code transformers are not needed code transformed ahead of time (loaded from ``.pyc`` files). Rationale ========= Python does not provide a standard way to transform the code. Projects transforming the code use various hooks. The MacroPy project uses an import hook: it adds its own module finder in ``sys.meta_path`` to hook its AST transformer. Another option is to monkey-patch the builtin ``compile()`` function. There are even more options to hook a code transformer. Python 3.4 added a ``compile_source()`` method to ``importlib.abc.SourceLoader``. But code transformation is wider than just importing modules, see described use cases below. Writing an optimizer or a preprocessor is out of the scope of this PEP. Usage 1: AST optimizer ---------------------- Transforming an Abstract Syntax Tree (AST) is a convenient way to implement an optimizer. It's easier to work on the AST than working on the bytecode, AST contains more information and is more high level. Since the optimization can done ahead of time, complex but slow optimizations can be implemented. Example of optimizations which can be implemented with an AST optimizer: * `Copy propagation `_: replace ``x=1; y=x`` with ``x=1; y=1`` * `Constant folding `_: replace ``1+1`` with ``2`` * `Dead code elimination `_ Using guards (see the `PEP 510 `_), it is possible to implement a much wider choice of optimizations. Examples: * Simplify iterable: replace ``range(3)`` with ``(0, 1, 2)`` when used as iterable * `Loop unrolling `_ * Call pure builtins: replace ``len("abc")`` with ``3`` * Copy used builtin symbols to constants * See also `optimizations implemented in fatoptimizer `_, a static optimizer for Python 3.6. The following issues can be implemented with an AST optimizer: * `Issue #1346238 `_: A constant folding optimization pass for the AST * `Issue #2181 `_: optimize out local variables at end of function * `Issue #2499 `_: Fold unary + and not on constants * `Issue #4264 `_: Patch: optimize code to use LIST_APPEND instead of calling list.append * `Issue #7682 `_: Optimisation of if with constant expression * `Issue #10399 `_: AST Optimization: inlining of function calls * `Issue #11549 `_: Build-out an AST optimizer, moving some functionality out of the peephole optimizer * `Issue #17068 `_: peephole optimization for constant strings * `Issue #17430 `_: missed peephole optimization Usage 2: Preprocessor --------------------- A preprocessor can be easily implemented with an AST transformer. A preprocessor has various and different usages. Some examples: * Remove debug code like assertions and logs to make the code faster to run it for production. * `Tail-call Optimization `_ * Add profiling code * `Lazy evaluation `_: see `lazy_python `_ (bytecode transformer) and `lazy macro of MacroPy `_ (AST transformer) * Change dictionary literals into collection.OrderedDict instances * Declare constants: see `@asconstants of codetransformer `_ * Domain Specific Language (DSL) like SQL queries. The Python language itself doesn't need to be modified. Previous attempts to implement DSL for SQL like `PEP 335 - Overloadable Boolean Operators `_ was rejected. * Pattern Matching of functional languages * String Interpolation, but `PEP 498 -- Literal String Interpolation `_ was merged into Python 3.6. `MacroPy `_ has a long list of examples and use cases. This PEP does not add any new code transformer. Using a code transformer will require an external module and to register it manually. See also `PyXfuscator `_: Python obfuscator, deobfuscator, and user-assisted decompiler. Usage 3: Disable all optimization --------------------------------- Ned Batchelder asked to add an option to disable the peephole optimizer because it makes code coverage more difficult to implement. See the discussion on the python-ideas mailing list: `Disable all peephole optimizations `_. This PEP adds a new ``-o noopt`` command line option to disable the peephole optimizer. In Python, it's as easy as:: sys.set_code_transformers([]) It will fix the `Issue #2506 `_: Add mechanism to disable optimizations. Usage 4: Write new bytecode optimizers in Python ------------------------------------------------ Python 3.6 optimizes the code using a peephole optimizer. By definition, a peephole optimizer has a narrow view of the code and so can only implement basic optimizations. The optimizer rewrites the bytecode. It is difficult to enhance it, because it written in C. With this PEP, it becomes possible to implement a new bytecode optimizer in pure Python and experiment new optimizations. Some optimizations are easier to implement on the AST like constant folding, but optimizations on the bytecode are still useful. For example, when the AST is compiled to bytecode, useless jumps can be emitted because the compiler is naive and does not try to optimize anything. Use Cases ========= This section give examples of use cases explaining when and how code transformers will be used. Interactive interpreter ----------------------- It will be possible to use code transformers with the interactive interpreter which is popular in Python and commonly used to demonstrate Python. The code is transformed at runtime and so the interpreter can be slower when expensive code transformers are used. Build a transformed package --------------------------- It will be possible to build a package of the transformed code. A transformer can have a configuration. The configuration is not stored in the package. All ``.pyc`` files of the package must be transformed with the same code transformers and the same transformers configuration. It is possible to build different ``.pyc`` files using different optimizer tags. Example: ``fat`` for the default configuration and ``fat_inline`` for a different configuration with function inlining enabled. A package can contain ``.pyc`` files with different optimizer tags. Install a package containing transformed .pyc files --------------------------------------------------- It will be possible to install a package which contains transformed ``.pyc`` files. All ``.pyc`` files with any optimizer tag contained in the package are installed, not only for the current optimizer tag. Build .pyc files when installing a package ------------------------------------------ If a package does not contain any ``.pyc`` files of the current optimizer tag (or some ``.pyc`` files are missing), the ``.pyc`` are created during the installation. Code transformers of the optimizer tag are required. Otherwise, the installation fails with an error. Execute transformed code ------------------------ It will be possible to execute transformed code. Raise an ``ImportError`` exception on import if the ``.pyc`` file of the current optimizer tag is missing and the code transformers required to transform the code are missing. The interesting point here is that code transformers are not needed to execute the transformed code if all required ``.pyc`` files are already available. Code transformer API ==================== A code transformer is a class with ``ast_transformer()`` and/or ``code_transformer()`` methods (API described below) and a ``name`` attribute. For efficiency, do not define a ``code_transformer()`` or ``ast_transformer()`` method if it does nothing. The ``name`` attribute (``str``) must be a short string used to identify an optimizer. It is used to build a ``.pyc`` filename. The name must not contain dots (``'.'``), dashes (``'-'``) or directory separators: dots are used to separated fields in a ``.pyc`` filename and dashes areused to join code transformer names to build the optimizer tag. .. note:: It would be nice to pass the fully qualified name of a module in the *context* when an AST transformer is used to transform a module on import, but it looks like the information is not available in ``PyParser_ASTFromStringObject()``. code_transformer() method ------------------------- Prototype:: def code_transformer(self, code, context): ... new_code = ... ... return new_code Parameters: * *code*: code object * *context*: an object with an *optimize* attribute (``int``), the optimization level (0, 1 or 2). The value of the *optimize* attribute comes from the *optimize* parameter of the ``compile()`` function, it is equal to ``sys.flags.optimize`` by default. Each implementation of Python can add extra attributes to *context*. For example, on CPython, *context* will also have the following attribute: * *interactive* (``bool``): true if in interactive mode XXX add more flags? XXX replace flags int with a sub-namespace, or with specific attributes? The method must return a code object. The code transformer is run after the compilation to bytecode ast_transformer() method ------------------------ Prototype:: def ast_transformer(self, tree, context): ... return tree Parameters: * *tree*: an AST tree * *context*: an object with a ``filename`` attribute (``str``) It must return an AST tree. It can modify the AST tree in place, or create a new AST tree. The AST transformer is called after the creation of the AST by the parser and before the compilation to bytecode. New attributes may be added to *context* in the future. Changes ======= In short, add: * -o OPTIM_TAG command line option * sys.implementation.optim_tag * sys.get_code_transformers() * sys.set_code_transformers(transformers) * ast.PyCF_TRANSFORMED_AST API to get/set code transformers -------------------------------- Add new functions to register code transformers: * ``sys.set_code_transformers(transformers)``: set the list of code transformers and update ``sys.implementation.optim_tag`` * ``sys.get_code_transformers()``: get the list of code transformers. The order of code transformers matter. Running transformer A and then transformer B can give a different output than running transformer B an then transformer A. Example to prepend a new code transformer:: transformers = sys.get_code_transformers() transformers.insert(0, new_cool_transformer) sys.set_code_transformers(transformers) All AST transformers are run sequentially (ex: the second transformer gets the input of the first transformer), and then all bytecode transformers are run sequentially. Optimizer tag ------------- Changes: * Add ``sys.implementation.optim_tag`` (``str``): optimization tag. The default optimization tag is ``'opt'``. * Add a new ``-o OPTIM_TAG`` command line option to set ``sys.implementation.optim_tag``. Changes on ``importlib``: * ``importlib`` uses ``sys.implementation.optim_tag`` to build the ``.pyc`` filename to importing modules, instead of always using ``opt``. Remove also the special case for the optimizer level ``0`` with the default optimizer tag ``'opt'`` to simplify the code. * When loading a module, if the ``.pyc`` file is missing but the ``.py`` is available, the ``.py`` is only used if code optimizers have the same optimizer tag than the current tag, otherwise an ``ImportError`` exception is raised. Pseudo-code of a ``use_py()`` function to decide if a ``.py`` file can be compiled to import a module:: def transformers_tag(): transformers = sys.get_code_transformers() if not transformers: return 'noopt' return '-'.join(transformer.name for transformer in transformers) def use_py(): return (transformers_tag() == sys.implementation.optim_tag) The order of ``sys.get_code_transformers()`` matter. For example, the ``fat`` transformer followed by the ``pythran`` transformer gives the optimizer tag ``fat-pythran``. The behaviour of the ``importlib`` module is unchanged with the default optimizer tag (``'opt'``). Peephole optimizer ------------------ By default, ``sys.implementation.optim_tag`` is ``opt`` and ``sys.get_code_transformers()`` returns a list of one code transformer: the peephole optimizer (optimize the bytecode). Use ``-o noopt`` to disable the peephole optimizer. In this case, the optimizer tag is ``noopt`` and no code transformer is registered. Using the ``-o opt`` option has not effect. AST enhancements ---------------- Enhancements to simplify the implementation of AST transformers: * Add a new compiler flag ``PyCF_TRANSFORMED_AST`` to get the transformed AST. ``PyCF_ONLY_AST`` returns the AST before the transformers. Examples ======== .pyc filenames -------------- Example of ``.pyc`` filenames of the ``os`` module. With the default optimizer tag ``'opt'``: =========================== ================== .pyc filename Optimization level =========================== ================== ``os.cpython-36.opt-0.pyc`` 0 ``os.cpython-36.opt-1.pyc`` 1 ``os.cpython-36.opt-2.pyc`` 2 =========================== ================== With the ``'fat'`` optimizer tag: =========================== ================== .pyc filename Optimization level =========================== ================== ``os.cpython-36.fat-0.pyc`` 0 ``os.cpython-36.fat-1.pyc`` 1 ``os.cpython-36.fat-2.pyc`` 2 =========================== ================== Bytecode transformer -------------------- Scary bytecode transformer replacing all strings with ``"Ni! Ni! Ni!"``:: import sys import types class BytecodeTransformer: name = "knights_who_say_ni" def code_transformer(self, code, context): consts = ['Ni! Ni! Ni!' if isinstance(const, str) else const for const in code.co_consts] return types.CodeType(code.co_argcount, code.co_kwonlyargcount, code.co_nlocals, code.co_stacksize, code.co_flags, code.co_code, tuple(consts), code.co_names, code.co_varnames, code.co_filename, code.co_name, code.co_firstlineno, code.co_lnotab, code.co_freevars, code.co_cellvars) # replace existing code transformers with the new bytecode transformer sys.set_code_transformers([BytecodeTransformer()]) # execute code which will be transformed by code_transformer() exec("print('Hello World!')") Output:: Ni! Ni! Ni! AST transformer --------------- Similarly to the bytecode transformer example, the AST transformer also replaces all strings with ``"Ni! Ni! Ni!"``:: import ast import sys class KnightsWhoSayNi(ast.NodeTransformer): def visit_Str(self, node): node.s = 'Ni! Ni! Ni!' return node class ASTTransformer: name = "knights_who_say_ni" def __init__(self): self.transformer = KnightsWhoSayNi() def ast_transformer(self, tree, context): self.transformer.visit(tree) return tree # replace existing code transformers with the new AST transformer sys.set_code_transformers([ASTTransformer()]) # execute code which will be transformed by ast_transformer() exec("print('Hello World!')") Output:: Ni! Ni! Ni! Other Python implementations ============================ The PEP 511 should be implemented by all Python implementation, but the bytecode and the AST are not standardized. By the way, even between minor version of CPython, there are changes on the AST API. There are differences, but only minor differences. It is quite easy to write an AST transformer which works on Python 2.7 and Python 3.5 for example. Discussion ========== * `[Python-ideas] PEP 511: API for code transformers `_ (January 2016) * `[Python-Dev] AST optimizer implemented in Python `_ (August 2012) Prior Art ========= AST optimizers -------------- The Issue #17515 `"Add sys.setasthook() to allow to use a custom AST" optimizer `_ was a first attempt of API for code transformers, but specific to AST. In 2015, Victor Stinner wrote the `fatoptimizer `_ project, an AST optimizer specializing functions using guards. In 2014, Kevin Conway created the `PyCC `_ optimizer. In 2012, Victor Stinner wrote the `astoptimizer `_ project, an AST optimizer implementing various optimizations. Most interesting optimizations break the Python semantics since no guard is used to disable optimization if something changes. In 2011, Eugene Toder proposed to rewrite some peephole optimizations in a new AST optimizer: issue #11549, `Build-out an AST optimizer, moving some functionality out of the peephole optimizer `_. The patch adds ``ast.Lit`` (it was proposed to rename it to ``ast.Literal``). Python Preprocessors -------------------- * `MacroPy `_: MacroPy is an implementation of Syntactic Macros in the Python Programming Language. MacroPy provides a mechanism for user-defined functions (macros) to perform transformations on the abstract syntax tree (AST) of a Python program at import time. * `pypreprocessor `_: C-style preprocessor directives in Python, like ``#define`` and ``#ifdef`` Bytecode transformers --------------------- * `codetransformer `_: Bytecode transformers for CPython inspired by the ``ast`` module’s ``NodeTransformer``. * `byteplay `_: Byteplay lets you convert Python code objects into equivalent objects which are easy to play with, and lets you convert those objects back into living Python code objects. It's useful for applying crazy transformations on Python functions, and is also useful in learning Python byte code intricacies. See `byteplay documentation `_. See also: * `BytecodeAssembler `_ Copyright ========= This document has been placed in the public domain.