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#ifndef GREENLET_PYTHON_STATE_CPP #define GREENLET_PYTHON_STATE_CPP #include <Python.h> #include "TGreenlet.hpp" namespace greenlet { PythonState::PythonState() : _top_frame() #if GREENLET_USE_CFRAME ,cframe(nullptr) ,use_tracing(0) #endif #if GREENLET_PY312 ,py_recursion_depth(0) ,c_recursion_depth(0) #else ,recursion_depth(0) #endif #if GREENLET_PY313 ,delete_later(nullptr) #else ,trash_delete_nesting(0) #endif #if GREENLET_PY311 ,current_frame(nullptr) ,datastack_chunk(nullptr) ,datastack_top(nullptr) ,datastack_limit(nullptr) #endif { #if GREENLET_USE_CFRAME /* The PyThreadState->cframe pointer usually points to memory on the stack, alloceted in a call into PyEval_EvalFrameDefault. Initially, before any evaluation begins, it points to the initial PyThreadState object's ``root_cframe`` object, which is statically allocated for the lifetime of the thread. A greenlet can last for longer than a call to PyEval_EvalFrameDefault, so we can't set its ``cframe`` pointer to be the current ``PyThreadState->cframe``; nor could we use one from the greenlet parent for the same reason. Yet a further no: we can't allocate one scoped to the greenlet and then destroy it when the greenlet is deallocated, because inside the interpreter the _PyCFrame objects form a linked list, and that too can result in accessing memory beyond its dynamic lifetime (if the greenlet doesn't actually finish before it dies, its entry could still be in the list). Using the ``root_cframe`` is problematic, though, because its members are never modified by the interpreter and are set to 0, meaning that its ``use_tracing`` flag is never updated. We don't want to modify that value in the ``root_cframe`` ourself: it *shouldn't* matter much because we should probably never get back to the point where that's the only cframe on the stack; even if it did matter, the major consequence of an incorrect value for ``use_tracing`` is that if its true the interpreter does some extra work --- however, it's just good code hygiene. Our solution: before a greenlet runs, after its initial creation, it uses the ``root_cframe`` just to have something to put there. However, once the greenlet is actually switched to for the first time, ``g_initialstub`` (which doesn't actually "return" while the greenlet is running) stores a new _PyCFrame on its local stack, and copies the appropriate values from the currently running _PyCFrame; this is then made the _PyCFrame for the newly-minted greenlet. ``g_initialstub`` then proceeds to call ``glet.run()``, which results in ``PyEval_...`` adding the _PyCFrame to the list. Switches continue as normal. Finally, when the greenlet finishes, the call to ``glet.run()`` returns and the _PyCFrame is taken out of the linked list and the stack value is now unused and free to expire. XXX: I think we can do better. If we're deallocing in the same thread, can't we traverse the list and unlink our frame? Can we just keep a reference to the thread state in case we dealloc in another thread? (Is that even possible if we're still running and haven't returned from g_initialstub?) */ this->cframe = &PyThreadState_GET()->root_cframe; #endif } inline void PythonState::may_switch_away() noexcept { #if GREENLET_PY311 // PyThreadState_GetFrame is probably going to have to allocate a // new frame object. That may trigger garbage collection. Because // we call this during the early phases of a switch (it doesn't // matter to which greenlet, as this has a global effect), if a GC // triggers a switch away, two things can happen, both bad: // - We might not get switched back to, halting forward progress. // this is pathological, but possible. // - We might get switched back to with a different set of // arguments or a throw instead of a switch. That would corrupt // our state (specifically, PyErr_Occurred() and this->args() // would no longer agree). // // Thus, when we call this API, we need to have GC disabled. // This method serves as a bottleneck we call when maybe beginning // a switch. In this way, it is always safe -- no risk of GC -- to // use ``_GetFrame()`` whenever we need to, just as it was in // <=3.10 (because subsequent calls will be cached and not // allocate memory). GCDisabledGuard no_gc; Py_XDECREF(PyThreadState_GetFrame(PyThreadState_GET())); #endif } void PythonState::operator<<(const PyThreadState *const tstate) noexcept { this->_context.steal(tstate->context); #if GREENLET_USE_CFRAME /* IMPORTANT: ``cframe`` is a pointer into the STACK. Thus, because the call to ``slp_switch()`` changes the contents of the stack, you cannot read from ``ts_current->cframe`` after that call and necessarily get the same values you get from reading it here. Anything you need to restore from now to then must be saved in a global/threadlocal variable (because we can't use stack variables here either). For things that need to persist across the switch, use `will_switch_from`. */ this->cframe = tstate->cframe; #if !GREENLET_PY312 this->use_tracing = tstate->cframe->use_tracing; #endif #endif // GREENLET_USE_CFRAME #if GREENLET_PY311 #if GREENLET_PY312 this->py_recursion_depth = tstate->py_recursion_limit - tstate->py_recursion_remaining; this->c_recursion_depth = Py_C_RECURSION_LIMIT - tstate->c_recursion_remaining; #else // not 312 this->recursion_depth = tstate->recursion_limit - tstate->recursion_remaining; #endif // GREENLET_PY312 #if GREENLET_PY313 this->current_frame = tstate->current_frame; #elif GREENLET_USE_CFRAME this->current_frame = tstate->cframe->current_frame; #endif this->datastack_chunk = tstate->datastack_chunk; this->datastack_top = tstate->datastack_top; this->datastack_limit = tstate->datastack_limit; PyFrameObject *frame = PyThreadState_GetFrame((PyThreadState *)tstate); Py_XDECREF(frame); // PyThreadState_GetFrame gives us a new // reference. this->_top_frame.steal(frame); #if GREENLET_PY313 this->delete_later = Py_XNewRef(tstate->delete_later); #elif GREENLET_PY312 this->trash_delete_nesting = tstate->trash.delete_nesting; #else // not 312 this->trash_delete_nesting = tstate->trash_delete_nesting; #endif // GREENLET_PY312 #else // Not 311 this->recursion_depth = tstate->recursion_depth; this->_top_frame.steal(tstate->frame); this->trash_delete_nesting = tstate->trash_delete_nesting; #endif // GREENLET_PY311 } #if GREENLET_PY312 void GREENLET_NOINLINE(PythonState::unexpose_frames)() { if (!this->top_frame()) { return; } // See GreenletState::expose_frames() and the comment on frames_were_exposed // for more information about this logic. _PyInterpreterFrame *iframe = this->_top_frame->f_frame; while (iframe != nullptr) { _PyInterpreterFrame *prev_exposed = iframe->previous; assert(iframe->frame_obj); memcpy(&iframe->previous, &iframe->frame_obj->_f_frame_data[0], sizeof(void *)); iframe = prev_exposed; } } #else void PythonState::unexpose_frames() {} #endif void PythonState::operator>>(PyThreadState *const tstate) noexcept { tstate->context = this->_context.relinquish_ownership(); /* Incrementing this value invalidates the contextvars cache, which would otherwise remain valid across switches */ tstate->context_ver++; #if GREENLET_USE_CFRAME tstate->cframe = this->cframe; /* If we were tracing, we need to keep tracing. There should never be the possibility of hitting the root_cframe here. See note above about why we can't just copy this from ``origin->cframe->use_tracing``. */ #if !GREENLET_PY312 tstate->cframe->use_tracing = this->use_tracing; #endif #endif // GREENLET_USE_CFRAME #if GREENLET_PY311 #if GREENLET_PY312 tstate->py_recursion_remaining = tstate->py_recursion_limit - this->py_recursion_depth; tstate->c_recursion_remaining = Py_C_RECURSION_LIMIT - this->c_recursion_depth; this->unexpose_frames(); #else // \/ 3.11 tstate->recursion_remaining = tstate->recursion_limit - this->recursion_depth; #endif // GREENLET_PY312 #if GREENLET_PY313 tstate->current_frame = this->current_frame; #elif GREENLET_USE_CFRAME tstate->cframe->current_frame = this->current_frame; #endif tstate->datastack_chunk = this->datastack_chunk; tstate->datastack_top = this->datastack_top; tstate->datastack_limit = this->datastack_limit; this->_top_frame.relinquish_ownership(); #if GREENLET_PY313 Py_XDECREF(tstate->delete_later); tstate->delete_later = this->delete_later; Py_CLEAR(this->delete_later); #elif GREENLET_PY312 tstate->trash.delete_nesting = this->trash_delete_nesting; #else // not 3.12 tstate->trash_delete_nesting = this->trash_delete_nesting; #endif // GREENLET_PY312 #else // not 3.11 tstate->frame = this->_top_frame.relinquish_ownership(); tstate->recursion_depth = this->recursion_depth; tstate->trash_delete_nesting = this->trash_delete_nesting; #endif // GREENLET_PY311 } inline void PythonState::will_switch_from(PyThreadState *const origin_tstate) noexcept { #if GREENLET_USE_CFRAME && !GREENLET_PY312 // The weird thing is, we don't actually save this for an // effect on the current greenlet, it's saved for an // effect on the target greenlet. That is, we want // continuity of this setting across the greenlet switch. this->use_tracing = origin_tstate->cframe->use_tracing; #endif } void PythonState::set_initial_state(const PyThreadState* const tstate) noexcept { this->_top_frame = nullptr; #if GREENLET_PY312 this->py_recursion_depth = tstate->py_recursion_limit - tstate->py_recursion_remaining; // XXX: TODO: Comment from a reviewer: // Should this be ``Py_C_RECURSION_LIMIT - tstate->c_recursion_remaining``? // But to me it looks more like that might not be the right // initialization either? this->c_recursion_depth = tstate->py_recursion_limit - tstate->py_recursion_remaining; #elif GREENLET_PY311 this->recursion_depth = tstate->recursion_limit - tstate->recursion_remaining; #else this->recursion_depth = tstate->recursion_depth; #endif } // TODO: Better state management about when we own the top frame. int PythonState::tp_traverse(visitproc visit, void* arg, bool own_top_frame) noexcept { Py_VISIT(this->_context.borrow()); if (own_top_frame) { Py_VISIT(this->_top_frame.borrow()); } return 0; } void PythonState::tp_clear(bool own_top_frame) noexcept { PythonStateContext::tp_clear(); // If we get here owning a frame, // we got dealloc'd without being finished. We may or may not be // in the same thread. if (own_top_frame) { this->_top_frame.CLEAR(); } } #if GREENLET_USE_CFRAME void PythonState::set_new_cframe(_PyCFrame& frame) noexcept { frame = *PyThreadState_GET()->cframe; /* Make the target greenlet refer to the stack value. */ this->cframe = &frame; /* And restore the link to the previous frame so this one gets unliked appropriately. */ this->cframe->previous = &PyThreadState_GET()->root_cframe; } #endif const PythonState::OwnedFrame& PythonState::top_frame() const noexcept { return this->_top_frame; } void PythonState::did_finish(PyThreadState* tstate) noexcept { #if GREENLET_PY311 // See https://github.com/gevent/gevent/issues/1924 and // https://github.com/python-greenlet/greenlet/issues/328. In // short, Python 3.11 allocates memory for frames as a sort of // linked list that's kept as part of PyThreadState in the // ``datastack_chunk`` member and friends. These are saved and // restored as part of switching greenlets. // // When we initially switch to a greenlet, we set those to NULL. // That causes the frame management code to treat this like a // brand new thread and start a fresh list of chunks, beginning // with a new "root" chunk. As we make calls in this greenlet, // those chunks get added, and as calls return, they get popped. // But the frame code (pystate.c) is careful to make sure that the // root chunk never gets popped. // // Thus, when a greenlet exits for the last time, there will be at // least a single root chunk that we must be responsible for // deallocating. // // The complex part is that these chunks are allocated and freed // using ``_PyObject_VirtualAlloc``/``Free``. Those aren't public // functions, and they aren't exported for linking. It so happens // that we know they are just thin wrappers around the Arena // allocator, so we can use that directly to deallocate in a // compatible way. // // CAUTION: Check this implementation detail on every major version. // // It might be nice to be able to do this in our destructor, but // can we be sure that no one else is using that memory? Plus, as // described below, our pointers may not even be valid anymore. As // a special case, there is one time that we know we can do this, // and that's from the destructor of the associated UserGreenlet // (NOT main greenlet) PyObjectArenaAllocator alloc; _PyStackChunk* chunk = nullptr; if (tstate) { // We really did finish, we can never be switched to again. chunk = tstate->datastack_chunk; // Unfortunately, we can't do much sanity checking. Our // this->datastack_chunk pointer is out of date (evaluation may // have popped down through it already) so we can't verify that // we deallocate it. I don't think we can even check datastack_top // for the same reason. PyObject_GetArenaAllocator(&alloc); tstate->datastack_chunk = nullptr; tstate->datastack_limit = nullptr; tstate->datastack_top = nullptr; } else if (this->datastack_chunk) { // The UserGreenlet (NOT the main greenlet!) is being deallocated. If we're // still holding a stack chunk, it's garbage because we know // we can never switch back to let cPython clean it up. // Because the last time we got switched away from, and we // haven't run since then, we know our chain is valid and can // be dealloced. chunk = this->datastack_chunk; PyObject_GetArenaAllocator(&alloc); } if (alloc.free && chunk) { // In case the arena mechanism has been torn down already. while (chunk) { _PyStackChunk *prev = chunk->previous; chunk->previous = nullptr; alloc.free(alloc.ctx, chunk, chunk->size); chunk = prev; } } this->datastack_chunk = nullptr; this->datastack_limit = nullptr; this->datastack_top = nullptr; #endif } }; // namespace greenlet #endif // GREENLET_PYTHON_STATE_CPP