%PDF- %PDF-
Direktori : /opt/hc_python/lib64/python3.8/site-packages/greenlet/ |
Current File : //opt/hc_python/lib64/python3.8/site-packages/greenlet/greenlet.cpp |
/* -*- indent-tabs-mode: nil; tab-width: 4; -*- */ /* Format with: * clang-format -i --style=file src/greenlet/greenlet.c * * * Fix missing braces with: * clang-tidy src/greenlet/greenlet.c -fix -checks="readability-braces-around-statements" */ #include <cstdlib> #include <string> #include <algorithm> #include <exception> #define PY_SSIZE_T_CLEAN #include <Python.h> #include "structmember.h" // PyMemberDef #include "greenlet_internal.hpp" // Code after this point can assume access to things declared in stdint.h, // including the fixed-width types. This goes for the platform-specific switch functions // as well. #include "greenlet_refs.hpp" #include "greenlet_slp_switch.hpp" #include "greenlet_thread_support.hpp" #include "TGreenlet.hpp" #include "TGreenletGlobals.cpp" #include "TGreenlet.cpp" #include "TMainGreenlet.cpp" #include "TUserGreenlet.cpp" #include "TBrokenGreenlet.cpp" #include "TExceptionState.cpp" #include "TPythonState.cpp" #include "TStackState.cpp" #include "TThreadState.hpp" #include "TThreadStateCreator.hpp" #include "TThreadStateDestroy.cpp" #include "PyGreenlet.cpp" #include "PyGreenletUnswitchable.cpp" #include "CObjects.cpp" using greenlet::LockGuard; using greenlet::LockInitError; using greenlet::PyErrOccurred; using greenlet::Require; using greenlet::g_handle_exit; using greenlet::single_result; using greenlet::Greenlet; using greenlet::UserGreenlet; using greenlet::MainGreenlet; using greenlet::BrokenGreenlet; using greenlet::ThreadState; using greenlet::PythonState; // ******* Implementation of things from included files template<typename T, greenlet::refs::TypeChecker TC> greenlet::refs::_BorrowedGreenlet<T, TC>& greenlet::refs::_BorrowedGreenlet<T, TC>::operator=(const greenlet::refs::BorrowedObject& other) { this->_set_raw_pointer(static_cast<PyObject*>(other)); return *this; } template <typename T, greenlet::refs::TypeChecker TC> inline greenlet::refs::_BorrowedGreenlet<T, TC>::operator Greenlet*() const noexcept { if (!this->p) { return nullptr; } return reinterpret_cast<PyGreenlet*>(this->p)->pimpl; } template<typename T, greenlet::refs::TypeChecker TC> greenlet::refs::_BorrowedGreenlet<T, TC>::_BorrowedGreenlet(const BorrowedObject& p) : BorrowedReference<T, TC>(nullptr) { this->_set_raw_pointer(p.borrow()); } template <typename T, greenlet::refs::TypeChecker TC> inline greenlet::refs::_OwnedGreenlet<T, TC>::operator Greenlet*() const noexcept { if (!this->p) { return nullptr; } return reinterpret_cast<PyGreenlet*>(this->p)->pimpl; } #ifdef __clang__ # pragma clang diagnostic push # pragma clang diagnostic ignored "-Wmissing-field-initializers" # pragma clang diagnostic ignored "-Wwritable-strings" #elif defined(__GNUC__) # pragma GCC diagnostic push // warning: ISO C++ forbids converting a string constant to ‘char*’ // (The python APIs aren't const correct and accept writable char*) # pragma GCC diagnostic ignored "-Wwrite-strings" #endif /*********************************************************** A PyGreenlet is a range of C stack addresses that must be saved and restored in such a way that the full range of the stack contains valid data when we switch to it. Stack layout for a greenlet: | ^^^ | | older data | | | stack_stop . |_______________| . | | . | greenlet data | . | in stack | . * |_______________| . . _____________ stack_copy + stack_saved . | | | | . | data | |greenlet data| . | unrelated | | saved | . | to | | in heap | stack_start . | this | . . |_____________| stack_copy | greenlet | | | | newer data | | vvv | Note that a greenlet's stack data is typically partly at its correct place in the stack, and partly saved away in the heap, but always in the above configuration: two blocks, the more recent one in the heap and the older one still in the stack (either block may be empty). Greenlets are chained: each points to the previous greenlet, which is the one that owns the data currently in the C stack above my stack_stop. The currently running greenlet is the first element of this chain. The main (initial) greenlet is the last one. Greenlets whose stack is entirely in the heap can be skipped from the chain. The chain is not related to execution order, but only to the order in which bits of C stack happen to belong to greenlets at a particular point in time. The main greenlet doesn't have a stack_stop: it is responsible for the complete rest of the C stack, and we don't know where it begins. We use (char*) -1, the largest possible address. States: stack_stop == NULL && stack_start == NULL: did not start yet stack_stop != NULL && stack_start == NULL: already finished stack_stop != NULL && stack_start != NULL: active The running greenlet's stack_start is undefined but not NULL. ***********************************************************/ /***********************************************************/ /* Some functions must not be inlined: * slp_restore_state, when inlined into slp_switch might cause it to restore stack over its own local variables * slp_save_state, when inlined would add its own local variables to the saved stack, wasting space * slp_switch, cannot be inlined for obvious reasons * g_initialstub, when inlined would receive a pointer into its own stack frame, leading to incomplete stack save/restore g_initialstub is a member function and declared virtual so that the compiler always calls it through a vtable. slp_save_state and slp_restore_state are also member functions. They are called from trampoline functions that themselves are declared as not eligible for inlining. */ extern "C" { static int GREENLET_NOINLINE(slp_save_state_trampoline)(char* stackref) { return switching_thread_state->slp_save_state(stackref); } static void GREENLET_NOINLINE(slp_restore_state_trampoline)() { switching_thread_state->slp_restore_state(); } } /***********************************************************/ #include "PyModule.cpp" static PyObject* greenlet_internal_mod_init() noexcept { static void* _PyGreenlet_API[PyGreenlet_API_pointers]; try { CreatedModule m(greenlet_module_def); Require(PyType_Ready(&PyGreenlet_Type)); Require(PyType_Ready(&PyGreenletUnswitchable_Type)); mod_globs = new greenlet::GreenletGlobals; ThreadState::init(); m.PyAddObject("greenlet", PyGreenlet_Type); m.PyAddObject("UnswitchableGreenlet", PyGreenletUnswitchable_Type); m.PyAddObject("error", mod_globs->PyExc_GreenletError); m.PyAddObject("GreenletExit", mod_globs->PyExc_GreenletExit); m.PyAddObject("GREENLET_USE_GC", 1); m.PyAddObject("GREENLET_USE_TRACING", 1); m.PyAddObject("GREENLET_USE_CONTEXT_VARS", 1L); m.PyAddObject("GREENLET_USE_STANDARD_THREADING", 1L); OwnedObject clocks_per_sec = OwnedObject::consuming(PyLong_FromSsize_t(CLOCKS_PER_SEC)); m.PyAddObject("CLOCKS_PER_SEC", clocks_per_sec); /* also publish module-level data as attributes of the greentype. */ // XXX: This is weird, and enables a strange pattern of // confusing the class greenlet with the module greenlet; with // the exception of (possibly) ``getcurrent()``, this // shouldn't be encouraged so don't add new items here. for (const char* const* p = copy_on_greentype; *p; p++) { OwnedObject o = m.PyRequireAttr(*p); PyDict_SetItemString(PyGreenlet_Type.tp_dict, *p, o.borrow()); } /* * Expose C API */ /* types */ _PyGreenlet_API[PyGreenlet_Type_NUM] = (void*)&PyGreenlet_Type; /* exceptions */ _PyGreenlet_API[PyExc_GreenletError_NUM] = (void*)mod_globs->PyExc_GreenletError; _PyGreenlet_API[PyExc_GreenletExit_NUM] = (void*)mod_globs->PyExc_GreenletExit; /* methods */ _PyGreenlet_API[PyGreenlet_New_NUM] = (void*)PyGreenlet_New; _PyGreenlet_API[PyGreenlet_GetCurrent_NUM] = (void*)PyGreenlet_GetCurrent; _PyGreenlet_API[PyGreenlet_Throw_NUM] = (void*)PyGreenlet_Throw; _PyGreenlet_API[PyGreenlet_Switch_NUM] = (void*)PyGreenlet_Switch; _PyGreenlet_API[PyGreenlet_SetParent_NUM] = (void*)PyGreenlet_SetParent; /* Previously macros, but now need to be functions externally. */ _PyGreenlet_API[PyGreenlet_MAIN_NUM] = (void*)Extern_PyGreenlet_MAIN; _PyGreenlet_API[PyGreenlet_STARTED_NUM] = (void*)Extern_PyGreenlet_STARTED; _PyGreenlet_API[PyGreenlet_ACTIVE_NUM] = (void*)Extern_PyGreenlet_ACTIVE; _PyGreenlet_API[PyGreenlet_GET_PARENT_NUM] = (void*)Extern_PyGreenlet_GET_PARENT; /* XXX: Note that our module name is ``greenlet._greenlet``, but for backwards compatibility with existing C code, we need the _C_API to be directly in greenlet. */ const NewReference c_api_object(Require( PyCapsule_New( (void*)_PyGreenlet_API, "greenlet._C_API", NULL))); m.PyAddObject("_C_API", c_api_object); assert(c_api_object.REFCNT() == 2); // cerr << "Sizes:" // << "\n\tGreenlet : " << sizeof(Greenlet) // << "\n\tUserGreenlet : " << sizeof(UserGreenlet) // << "\n\tMainGreenlet : " << sizeof(MainGreenlet) // << "\n\tExceptionState : " << sizeof(greenlet::ExceptionState) // << "\n\tPythonState : " << sizeof(greenlet::PythonState) // << "\n\tStackState : " << sizeof(greenlet::StackState) // << "\n\tSwitchingArgs : " << sizeof(greenlet::SwitchingArgs) // << "\n\tOwnedObject : " << sizeof(greenlet::refs::OwnedObject) // << "\n\tBorrowedObject : " << sizeof(greenlet::refs::BorrowedObject) // << "\n\tPyGreenlet : " << sizeof(PyGreenlet) // << endl; return m.borrow(); // But really it's the main reference. } catch (const LockInitError& e) { PyErr_SetString(PyExc_MemoryError, e.what()); return NULL; } catch (const PyErrOccurred&) { return NULL; } } extern "C" { PyMODINIT_FUNC PyInit__greenlet(void) { return greenlet_internal_mod_init(); } }; // extern C #ifdef __clang__ # pragma clang diagnostic pop #elif defined(__GNUC__) # pragma GCC diagnostic pop #endif