PEP: 523 Title: Adding a frame evaluation API to CPython Version: $Revision$ Last-Modified: $Date$ Author: Brett Cannon , Dino Viehland Status: Draft Type: Standards Track Content-Type: text/x-rst Created: 16-May-2016 Post-History: 16-May-2016 Abstract ======== This PEP proposes to expand CPython's C API [#c-api]_ to allow for the specification of a per-interpreter function pointer to handle the evaluation of frames [#pyeval_evalframeex]_. This proposal also suggests adding a new field to code objects [#pycodeobject]_ to store arbitrary data for use by the frame evaluation function. Rationale ========= One place where flexibility has been lacking in Python is in the direct execution of Python code. While CPython's C API [#c-api]_ allows for constructing the data going into a frame object and then evaluating it via ``PyEval_EvalFrameEx()`` [#pyeval_evalframeex]_, control over the execution of Python code comes down to individual objects instead of a holistic control of execution at the frame level. While wanting to have influence over frame evaluation may seem a bit too low-level, it does open the possibility for things such as a method-level JIT to be introduced into CPython without CPython itself having to provide one. By allowing external C code to control frame evaluation, a JIT can participate in the execution of Python code at the key point where evaluation occurs. This then allows for a JIT to conditionally recompile Python bytecode to machine code as desired while still allowing for executing regular CPython bytecode when running the JIT is not desired. This can be accomplished by allowing interpreters to specify what function to call to evaluate a frame. And by placing the API at the frame evaluation level it allows for a complete view of the execution environment of the code for the JIT. This ability to specify a frame evaluation function also allows for other use-cases beyond just opening CPython up to a JIT. For instance, it would not be difficult to implement a tracing or profiling function at the call level with this API. While CPython does provide the ability to set a tracing or profiling function at the Python level, this would be able to match the data collection of the profiler and quite possibly be faster for tracing by simply skipping per-line tracing support. It also opens up the possibility of debugging where the frame evaluation function only performs special debugging work when it detects it is about to execute a specific code object. In that instance the bytecode could be theoretically rewritten in-place to inject a breakpoint function call at the proper point for help in debugging while not having to do a heavy-handed approach as required by ``sys.settrace()``. To help facilitate these use-cases, we are also proposing the adding of a "scratch space" on code objects via a new field. This will allow per-code object data to be stored with the code object itself for easy retrieval by the frame evaluation function as necessary. The field itself will simply be a ``PyObject *`` type so that any data stored in the field will participate in normal object memory management. Proposal ======== All proposed C API changes below will not be part of the stable ABI. Expanding ``PyCodeObject`` -------------------------- One field is to be added to the ``PyCodeObject`` struct [#pycodeobject]_:: typedef struct { ... PyObject *co_extra; /* "Scratch space" for the code object. */ } PyCodeObject; The ``co_extra`` will be ``NULL`` by default and will not be used by CPython itself. Third-party code is free to use the field as desired. Values stored in the field are expected to not be required in order for the code object to function, allowing the loss of the data of the field to be acceptable (this keeps the code object as immutable from a functionality point-of-view; this is slightly contentious and so is listed as an open issue in `Is co_extra needed?`_). The field will be freed like all other fields on ``PyCodeObject`` during deallocation using ``Py_XDECREF()``. It is not recommended that multiple users attempt to use the ``co_extra`` simultaneously. While a dictionary could theoretically be set to the field and various users could use a key specific to the project, there is still the issue of key collisions as well as performance degradation from using a dictionary lookup on every frame evaluation. Users are expected to do a type check to make sure that the field has not been previously set by someone else. Expanding ``PyInterpreterState`` -------------------------------- The entrypoint for the frame evalution function is per-interpreter:: // Same type signature as PyEval_EvalFrameEx(). typedef PyObject* (__stdcall *PyFrameEvalFunction)(PyFrameObject*, int); typedef struct { ... PyFrameEvalFunction eval_frame; } PyInterpreterState; By default, the ``eval_frame`` field will be initialized to a function pointer that represents what ``PyEval_EvalFrameEx()`` currently is (called ``PyEval_EvalFrameDefault()``, discussed later in this PEP). Third-party code may then set their own frame evaluation function instead to control the execution of Python code. A pointer comparison can be used to detect if the field is set to ``PyEval_EvalFrameDefault()`` and thus has not been mutated yet. Changes to ``Python/ceval.c`` ----------------------------- ``PyEval_EvalFrameEx()`` [#pyeval_evalframeex]_ as it currently stands will be renamed to ``PyEval_EvalFrameDefault()``. The new ``PyEval_EvalFrameEx()`` will then become:: PyObject * PyEval_EvalFrameEx(PyFrameObject *frame, int throwflag) { PyThreadState *tstate = PyThreadState_GET(); return tstate->interp->eval_frame(frame, throwflag); } This allows third-party code to place themselves directly in the path of Python code execution while being backwards-compatible with code already using the pre-existing C API. Updating ``python-gdb.py`` -------------------------- The generated ``python-gdb.py`` file used for Python support in GDB makes some hard-coded assumptions about ``PyEval_EvalFrameEx()``, e.g. the names of local variables. It will need to be updated to work with the proposed changes. Performance impact ================== As this PEP is proposing an API to add pluggability, performance impact is considered only in the case where no third-party code has made any changes. Several runs of pybench [#pybench]_ consistently showed no performance cost from the API change alone. A run of the Python benchmark suite [#py-benchmarks]_ showed no measurable cost in performance. In terms of memory impact, since there are typically not many CPython interpreters executing in a single process that means the impact of ``co_extra`` being added to ``PyCodeObject`` is the only worry. According to [#code-object-count]_, a run of the Python test suite results in about 72,395 code objects being created. On a 64-bit CPU that would result in 579,160 bytes of extra memory being used if all code objects were alive at once and had nothing set in their ``co_extra`` fields. Example Usage ============= A JIT for CPython ----------------- Pyjion '''''' The Pyjion project [#pyjion]_ has used this proposed API to implement a JIT for CPython using the CoreCLR's JIT [#coreclr]_. Each code object has its ``co_extra`` field set to a ``PyjionJittedCode`` object which stores four pieces of information: 1. Execution count 2. A boolean representing whether a previous attempt to JIT failed 3. A function pointer to a trampoline (which can be type tracing or not) 4. A void pointer to any JIT-compiled machine code The frame evaluation function has (roughly) the following algorithm:: def eval_frame(frame, throw_flag): pyjion_code = frame.code.co_extra if not pyjion_code: frame.code.co_extra = PyjionJittedCode() elif not pyjion_code.jit_failed: if not pyjion_code.jit_code: return pyjion_code.eval(pyjion_code.jit_code, frame) elif pyjion_code.exec_count > 20_000: if jit_compile(frame): return pyjion_code.eval(pyjion_code.jit_code, frame) else: pyjion_code.jit_failed = True pyjion_code.exec_count += 1 return PyEval_EvalFrameDefault(frame, throw_flag) The key point, though, is that all of this work and logic is separate from CPython and yet with the proposed API changes it is able to provide a JIT that is compliant with Python semantics (as of this writing, performance is almost equivalent to CPython without the new API). This means there's nothing technically preventing others from implementing their own JITs for CPython by utilizing the proposed API. Other JITs '''''''''' It should be mentioned that the Pyston team was consulted on an earlier version of this PEP that was more JIT-specific and they were not interested in utilizing the changes proposed because they want control over memory layout they had no interest in directly supporting CPython itself. An informal discusion with a developer on the PyPy team led to a similar comment. Numba [#numba]_, on the other hand, suggested that they would be interested in the proposed change in a post-1.0 future for themselves [#numba-interest]_. The experimental Coconut JIT [#coconut]_ could have benefitted from this PEP. In private conversations with Coconut's creator we were told that our API was probably superior to the one they developed for Coconut to add JIT support to CPython. Debugging --------- In conversations with the Python Tools for Visual Studio team (PTVS) [#ptvs]_, they thought they would find these API changes useful for implementing more performant debugging. As mentioned in the Rationale_ section, this API would allow for switching on debugging functionality only in frames where it is needed. This could allow for either skipping information that ``sys.settrace()`` normally provides and even go as far as to dynamically rewrite bytecode prior to execution to inject e.g. breakpoints in the bytecode. It also turns out that Google has provided a very similar API internally for years. It has been used for performant debugging purposes. Implementation ============== A set of patches implementing the proposed API is available through the Pyjion project [#pyjion]_. In its current form it has more changes to CPython than just this proposed API, but that is for ease of development instead of strict requirements to accomplish its goals. Open Issues =========== Allow ``eval_frame`` to be ``NULL`` ----------------------------------- Currently the frame evaluation function is expected to always be set. It could very easily simply default to ``NULL`` instead which would signal to use ``PyEval_EvalFrameDefault()``. The current proposal of not special-casing the field seemed the most straight-forward, but it does require that the field not accidentally be cleared, else a crash may occur. Is co_extra needed? ------------------- While discussing this PEP at PyCon US 2016, some core developers expressed their worry of the ``co_extra`` field making code objects mutable. The thinking seemed to be that having a field that was mutated after the creation of the code object made the object seem mutable, even though no other aspect of code objects changed. The view of this PEP is that the `co_extra` field doesn't change the fact that code objects are immutable. The field is specified in this PEP as to not contain information required to make the code object usable, making it more of a caching field. It could be viewed as similar to the UTF-8 cache that string objects have internally; strings are still considered immutable even though they have a field that is conditionally set. The field is also not strictly necessary. While the field greatly simplifies attaching extra information to code objects, other options such as keeping a mapping of code object memory addresses to what would have been kept in ``co_extra`` or perhaps using a weak reference of the data on the code object and then iterating through the weak references until the attached data is found is possible. But obviously all of these solutions are not as simple or performant as adding the ``co_extra`` field. Rejected Ideas ============== A JIT-specific C API -------------------- Originally this PEP was going to propose a much larger API change which was more JIT-specific. After soliciting feedback from the Numba team [#numba]_, though, it became clear that the API was unnecessarily large. The realization was made that all that was truly needed was the opportunity to provide a trampoline function to handle execution of Python code that had been JIT-compiled and a way to attach that compiled machine code along with other critical data to the corresponding Python code object. Once it was shown that there was no loss in functionality or in performance while minimizing the API changes required, the proposal was changed to its current form. References ========== .. [#pyjion] Pyjion project (https://github.com/microsoft/pyjion) .. [#c-api] CPython's C API (https://docs.python.org/3/c-api/index.html) .. [#pycodeobject] ``PyCodeObject`` (https://docs.python.org/3/c-api/code.html#c.PyCodeObject) .. [#coreclr] .NET Core Runtime (CoreCLR) (https://github.com/dotnet/coreclr) .. [#pyeval_evalframeex] ``PyEval_EvalFrameEx()`` (https://docs.python.org/3/c-api/veryhigh.html?highlight=pyframeobject#c.PyEval_EvalFrameEx) .. [#numba] Numba (http://numba.pydata.org/) .. [#numba-interest] numba-users mailing list: "Would the C API for a JIT entrypoint being proposed by Pyjion help out Numba?" (https://groups.google.com/a/continuum.io/forum/#!topic/numba-users/yRl_0t8-m1g) .. [#code-object-count] [Python-Dev] Opcode cache in ceval loop (https://mail.python.org/pipermail/python-dev/2016-February/143025.html) .. [#py-benchmarks] Python benchmark suite (https://hg.python.org/benchmarks) .. [#pyston] Pyston (http://pyston.org) .. [#pypy] PyPy (http://pypy.org/) .. [#ptvs] Python Tools for Visual Studio (http://microsoft.github.io/PTVS/) .. [#coconut] Coconut (https://github.com/davidmalcolm/coconut) .. [#pybench] pybench (https://hg.python.org/cpython/file/default/Tools/pybench) 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: