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137 lines
5.8 KiB
Markdown
137 lines
5.8 KiB
Markdown
# Frames
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Each call to a Python function has an activation record, commonly known as a
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"frame". It contains information about the function being executed, consisting
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of three conceptual sections:
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* Local variables (including arguments, cells and free variables)
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* Evaluation stack
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* Specials: The per-frame object references needed by the VM, including
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globals dict, code object, instruction pointer, stack depth, the
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previous frame, etc.
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The definition of the `_PyInterpreterFrame` struct is in
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[Include/internal/pycore_frame.h](../Include/internal/pycore_frame.h).
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# Allocation
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Python semantics allows frames to outlive the activation, so they need to
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be allocated outside the C call stack. To reduce overhead and improve locality
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of reference, most frames are allocated contiguously in a per-thread stack
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(see `_PyThreadState_PushFrame` in [Python/pystate.c](../Python/pystate.c)).
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Frames of generators and coroutines are embedded in the generator and coroutine
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objects, so are not allocated in the per-thread stack. See `PyGenObject` in
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[Include/internal/pycore_genobject.h](../Include/internal/pycore_genobject.h).
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## Layout
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Each activation record is laid out as:
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* Specials
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* Locals
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* Stack
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This seems to provide the best performance without excessive complexity.
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The specials have a fixed size, so the offset of the locals is know. The
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interpreter needs to hold two pointers, a frame pointer and a stack pointer.
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#### Alternative layout
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An alternative layout that was used for part of 3.11 alpha was:
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* Locals
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* Specials
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* Stack
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This has the advantage that no copying is required when making a call,
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as the arguments on the stack are (usually) already in the correct
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location for the parameters. However, it requires the VM to maintain
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an extra pointer for the locals, which can hurt performance.
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### Generators and Coroutines
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Generators and coroutines contain a `_PyInterpreterFrame`
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The specials sections contains the following pointers:
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* Globals dict
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* Builtins dict
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* Locals dict (not the "fast" locals, but the locals for eval and class creation)
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* Code object
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* Heap allocated `PyFrameObject` for this activation record, if any.
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* The function.
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The pointer to the function is not strictly required, but it is cheaper to
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store a strong reference to the function and borrowed references to the globals
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and builtins, than strong references to both globals and builtins.
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### Frame objects
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When creating a backtrace or when calling `sys._getframe()` the frame becomes
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visible to Python code. When this happens a new `PyFrameObject` is created
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and a strong reference to it placed in the `frame_obj` field of the specials
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section. The `frame_obj` field is initially `NULL`.
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The `PyFrameObject` may outlive a stack-allocated `_PyInterpreterFrame`.
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If it does then `_PyInterpreterFrame` is copied into the `PyFrameObject`,
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except the evaluation stack which must be empty at this point.
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The previous frame link is updated to reflect the new location of the frame.
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This mechanism provides the appearance of persistent, heap-allocated
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frames for each activation, but with low runtime overhead.
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### Generators and Coroutines
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Generators (objects of type `PyGen_Type`, `PyCoro_Type` or
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`PyAsyncGen_Type`) have a `_PyInterpreterFrame` embedded in them, so
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that they can be created with a single memory allocation.
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When such an embedded frame is iterated or awaited, it can be linked with
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frames on the per-thread stack via the linkage fields.
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If a frame object associated with a generator outlives the generator, then
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the embedded `_PyInterpreterFrame` is copied into the frame object (see
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`take_ownership()` in [Python/frame.c](../Python/frame.c)).
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### Field names
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Many of the fields in `_PyInterpreterFrame` were copied from the 3.10 `PyFrameObject`.
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Thus, some of the field names may be a bit misleading.
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For example the `f_globals` field has a `f_` prefix implying it belongs to the
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`PyFrameObject` struct, although it belongs to the `_PyInterpreterFrame` struct.
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We may rationalize this naming scheme for a later version.
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### Shim frames
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On entry to `_PyEval_EvalFrameDefault()` a shim `_PyInterpreterFrame` is pushed.
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This frame is stored on the C stack, and popped when `_PyEval_EvalFrameDefault()`
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returns. This extra frame is inserted so that `RETURN_VALUE`, `YIELD_VALUE`, and
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`RETURN_GENERATOR` do not need to check whether the current frame is the entry frame.
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The shim frame points to a special code object containing the `INTERPRETER_EXIT`
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instruction which cleans up the shim frame and returns.
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### The Instruction Pointer
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`_PyInterpreterFrame` has two fields which are used to maintain the instruction
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pointer: `instr_ptr` and `return_offset`.
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When a frame is executing, `instr_ptr` points to the instruction currently being
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executed. In a suspended frame, it points to the instruction that would execute
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if the frame were to resume. After `frame.f_lineno` is set, `instr_ptr` points to
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the next instruction to be executed. During a call to a python function,
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`instr_ptr` points to the call instruction, because this is what we would expect
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to see in an exception traceback.
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The `return_offset` field determines where a `RETURN` should go in the caller,
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relative to `instr_ptr`. It is only meaningful to the callee, so it needs to
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be set in any instruction that implements a call (to a Python function),
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including CALL, SEND and BINARY_SUBSCR_GETITEM, among others. If there is no
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callee, then return_offset is meaningless. It is necessary to have a separate
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field for the return offset because (1) if we apply this offset to `instr_ptr`
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while executing the `RETURN`, this is too early and would lose us information
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about the previous instruction which we could need for introspecting and
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debugging. (2) `SEND` needs to pass two offsets to the generator: one for
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`RETURN` and one for `YIELD`. It uses the `oparg` for one, and the
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`return_offset` for the other.
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