/* Execute compiled code */ /* XXX TO DO: XXX speed up searching for keywords by using a dictionary XXX document it! */ #include "Python.h" #include "pycore_abstract.h" // _PyIndex_Check() #include "pycore_call.h" // _PyObject_FastCallDictTstate() #include "pycore_ceval.h" // _PyEval_SignalAsyncExc() #include "pycore_code.h" #include "pycore_function.h" #include "pycore_initconfig.h" // _PyStatus_OK() #include "pycore_long.h" // _PyLong_GetZero() #include "pycore_object.h" // _PyObject_GC_TRACK() #include "pycore_moduleobject.h" // PyModuleObject #include "pycore_opcode.h" // EXTRA_CASES #include "pycore_pyerrors.h" // _PyErr_Fetch() #include "pycore_pylifecycle.h" // _PyErr_Print() #include "pycore_pymem.h" // _PyMem_IsPtrFreed() #include "pycore_pystate.h" // _PyInterpreterState_GET() #include "pycore_sysmodule.h" // _PySys_Audit() #include "pycore_tuple.h" // _PyTuple_ITEMS() #include "pycore_emscripten_signal.h" // _Py_CHECK_EMSCRIPTEN_SIGNALS #include "pycore_dict.h" #include "dictobject.h" #include "pycore_frame.h" #include "opcode.h" #include "pydtrace.h" #include "setobject.h" #include "structmember.h" // struct PyMemberDef, T_OFFSET_EX #include #include #ifdef Py_DEBUG /* For debugging the interpreter: */ # define LLTRACE 1 /* Low-level trace feature */ #endif #if !defined(Py_BUILD_CORE) # error "ceval.c must be build with Py_BUILD_CORE define for best performance" #endif #if !defined(Py_DEBUG) && !defined(Py_TRACE_REFS) // GH-89279: The MSVC compiler does not inline these static inline functions // in PGO build in _PyEval_EvalFrameDefault(), because this function is over // the limit of PGO, and that limit cannot be configured. // Define them as macros to make sure that they are always inlined by the // preprocessor. #undef Py_DECREF #define Py_DECREF(arg) \ do { \ PyObject *op = _PyObject_CAST(arg); \ if (--op->ob_refcnt == 0) { \ destructor dealloc = Py_TYPE(op)->tp_dealloc; \ (*dealloc)(op); \ } \ } while (0) #undef Py_XDECREF #define Py_XDECREF(arg) \ do { \ PyObject *xop = _PyObject_CAST(arg); \ if (xop != NULL) { \ Py_DECREF(xop); \ } \ } while (0) #undef Py_IS_TYPE #define Py_IS_TYPE(ob, type) \ (_PyObject_CAST(ob)->ob_type == (type)) #undef _Py_DECREF_SPECIALIZED #define _Py_DECREF_SPECIALIZED(arg, dealloc) \ do { \ PyObject *op = _PyObject_CAST(arg); \ if (--op->ob_refcnt == 0) { \ destructor d = (destructor)(dealloc); \ d(op); \ } \ } while (0) #endif // GH-89279: Similar to above, force inlining by using a macro. #if defined(_MSC_VER) && SIZEOF_INT == 4 #define _Py_atomic_load_relaxed_int32(ATOMIC_VAL) (assert(sizeof((ATOMIC_VAL)->_value) == 4), *((volatile int*)&((ATOMIC_VAL)->_value))) #else #define _Py_atomic_load_relaxed_int32(ATOMIC_VAL) _Py_atomic_load_relaxed(ATOMIC_VAL) #endif /* Forward declarations */ static PyObject *trace_call_function( PyThreadState *tstate, PyObject *callable, PyObject **stack, Py_ssize_t oparg, PyObject *kwnames); static PyObject * do_call_core( PyThreadState *tstate, PyObject *func, PyObject *callargs, PyObject *kwdict, int use_tracing); #ifdef LLTRACE static void dump_stack(_PyInterpreterFrame *frame, PyObject **stack_pointer) { PyObject **stack_base = _PyFrame_Stackbase(frame); PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); printf(" stack=["); for (PyObject **ptr = stack_base; ptr < stack_pointer; ptr++) { if (ptr != stack_base) { printf(", "); } if (PyObject_Print(*ptr, stdout, 0) != 0) { PyErr_Clear(); printf("<%s object at %p>", Py_TYPE(*ptr)->tp_name, (void *)(*ptr)); } } printf("]\n"); fflush(stdout); PyErr_Restore(type, value, traceback); } static void lltrace_instruction(_PyInterpreterFrame *frame, PyObject **stack_pointer, _Py_CODEUNIT *next_instr) { dump_stack(frame, stack_pointer); int oparg = _Py_OPARG(*next_instr); int opcode = _Py_OPCODE(*next_instr); const char *opname = _PyOpcode_OpName[opcode]; assert(opname != NULL); int offset = (int)(next_instr - _PyCode_CODE(frame->f_code)); if (HAS_ARG(opcode)) { printf("%d: %s %d\n", offset * 2, opname, oparg); } else { printf("%d: %s\n", offset * 2, opname); } fflush(stdout); } static void lltrace_resume_frame(_PyInterpreterFrame *frame) { PyFunctionObject *f = frame->f_func; if (f == NULL) { printf("\nResuming frame."); return; } PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); PyObject *name = f->func_qualname; if (name == NULL) { name = f->func_name; } printf("\nResuming frame"); if (name) { printf(" for "); if (PyObject_Print(name, stdout, 0) < 0) { PyErr_Clear(); } } if (f->func_module) { printf(" in module "); if (PyObject_Print(f->func_module, stdout, 0) < 0) { PyErr_Clear(); } } printf("\n"); fflush(stdout); PyErr_Restore(type, value, traceback); } #endif static int call_trace(Py_tracefunc, PyObject *, PyThreadState *, _PyInterpreterFrame *, int, PyObject *); static int call_trace_protected(Py_tracefunc, PyObject *, PyThreadState *, _PyInterpreterFrame *, int, PyObject *); static void call_exc_trace(Py_tracefunc, PyObject *, PyThreadState *, _PyInterpreterFrame *); static int maybe_call_line_trace(Py_tracefunc, PyObject *, PyThreadState *, _PyInterpreterFrame *, int); static void maybe_dtrace_line(_PyInterpreterFrame *, PyTraceInfo *, int); static void dtrace_function_entry(_PyInterpreterFrame *); static void dtrace_function_return(_PyInterpreterFrame *); static PyObject * import_name(PyThreadState *, _PyInterpreterFrame *, PyObject *, PyObject *, PyObject *); static PyObject * import_from(PyThreadState *, PyObject *, PyObject *); static int import_all_from(PyThreadState *, PyObject *, PyObject *); static void format_exc_check_arg(PyThreadState *, PyObject *, const char *, PyObject *); static void format_exc_unbound(PyThreadState *tstate, PyCodeObject *co, int oparg); static int check_args_iterable(PyThreadState *, PyObject *func, PyObject *vararg); static int check_except_type_valid(PyThreadState *tstate, PyObject* right); static int check_except_star_type_valid(PyThreadState *tstate, PyObject* right); static void format_kwargs_error(PyThreadState *, PyObject *func, PyObject *kwargs); static void format_awaitable_error(PyThreadState *, PyTypeObject *, int); static int get_exception_handler(PyCodeObject *, int, int*, int*, int*); static _PyInterpreterFrame * _PyEvalFramePushAndInit(PyThreadState *tstate, PyFunctionObject *func, PyObject *locals, PyObject* const* args, size_t argcount, PyObject *kwnames); static void _PyEvalFrameClearAndPop(PyThreadState *tstate, _PyInterpreterFrame *frame); #define NAME_ERROR_MSG \ "name '%.200s' is not defined" #define UNBOUNDLOCAL_ERROR_MSG \ "cannot access local variable '%s' where it is not associated with a value" #define UNBOUNDFREE_ERROR_MSG \ "cannot access free variable '%s' where it is not associated with a" \ " value in enclosing scope" #ifndef NDEBUG /* Ensure that tstate is valid: sanity check for PyEval_AcquireThread() and PyEval_RestoreThread(). Detect if tstate memory was freed. It can happen when a thread continues to run after Python finalization, especially daemon threads. */ static int is_tstate_valid(PyThreadState *tstate) { assert(!_PyMem_IsPtrFreed(tstate)); assert(!_PyMem_IsPtrFreed(tstate->interp)); return 1; } #endif /* This can set eval_breaker to 0 even though gil_drop_request became 1. We believe this is all right because the eval loop will release the GIL eventually anyway. */ static inline void COMPUTE_EVAL_BREAKER(PyInterpreterState *interp, struct _ceval_runtime_state *ceval, struct _ceval_state *ceval2) { _Py_atomic_store_relaxed(&ceval2->eval_breaker, _Py_atomic_load_relaxed_int32(&ceval2->gil_drop_request) | (_Py_atomic_load_relaxed_int32(&ceval->signals_pending) && _Py_ThreadCanHandleSignals(interp)) | (_Py_atomic_load_relaxed_int32(&ceval2->pending.calls_to_do) && _Py_ThreadCanHandlePendingCalls()) | ceval2->pending.async_exc); } static inline void SET_GIL_DROP_REQUEST(PyInterpreterState *interp) { struct _ceval_state *ceval2 = &interp->ceval; _Py_atomic_store_relaxed(&ceval2->gil_drop_request, 1); _Py_atomic_store_relaxed(&ceval2->eval_breaker, 1); } static inline void RESET_GIL_DROP_REQUEST(PyInterpreterState *interp) { struct _ceval_runtime_state *ceval = &interp->runtime->ceval; struct _ceval_state *ceval2 = &interp->ceval; _Py_atomic_store_relaxed(&ceval2->gil_drop_request, 0); COMPUTE_EVAL_BREAKER(interp, ceval, ceval2); } static inline void SIGNAL_PENDING_CALLS(PyInterpreterState *interp) { struct _ceval_runtime_state *ceval = &interp->runtime->ceval; struct _ceval_state *ceval2 = &interp->ceval; _Py_atomic_store_relaxed(&ceval2->pending.calls_to_do, 1); COMPUTE_EVAL_BREAKER(interp, ceval, ceval2); } static inline void UNSIGNAL_PENDING_CALLS(PyInterpreterState *interp) { struct _ceval_runtime_state *ceval = &interp->runtime->ceval; struct _ceval_state *ceval2 = &interp->ceval; _Py_atomic_store_relaxed(&ceval2->pending.calls_to_do, 0); COMPUTE_EVAL_BREAKER(interp, ceval, ceval2); } static inline void SIGNAL_PENDING_SIGNALS(PyInterpreterState *interp, int force) { struct _ceval_runtime_state *ceval = &interp->runtime->ceval; struct _ceval_state *ceval2 = &interp->ceval; _Py_atomic_store_relaxed(&ceval->signals_pending, 1); if (force) { _Py_atomic_store_relaxed(&ceval2->eval_breaker, 1); } else { /* eval_breaker is not set to 1 if thread_can_handle_signals() is false */ COMPUTE_EVAL_BREAKER(interp, ceval, ceval2); } } static inline void UNSIGNAL_PENDING_SIGNALS(PyInterpreterState *interp) { struct _ceval_runtime_state *ceval = &interp->runtime->ceval; struct _ceval_state *ceval2 = &interp->ceval; _Py_atomic_store_relaxed(&ceval->signals_pending, 0); COMPUTE_EVAL_BREAKER(interp, ceval, ceval2); } static inline void SIGNAL_ASYNC_EXC(PyInterpreterState *interp) { struct _ceval_state *ceval2 = &interp->ceval; ceval2->pending.async_exc = 1; _Py_atomic_store_relaxed(&ceval2->eval_breaker, 1); } static inline void UNSIGNAL_ASYNC_EXC(PyInterpreterState *interp) { struct _ceval_runtime_state *ceval = &interp->runtime->ceval; struct _ceval_state *ceval2 = &interp->ceval; ceval2->pending.async_exc = 0; COMPUTE_EVAL_BREAKER(interp, ceval, ceval2); } #ifdef HAVE_ERRNO_H #include #endif #include "ceval_gil.h" void _Py_NO_RETURN _Py_FatalError_TstateNULL(const char *func) { _Py_FatalErrorFunc(func, "the function must be called with the GIL held, " "but the GIL is released " "(the current Python thread state is NULL)"); } int _PyEval_ThreadsInitialized(_PyRuntimeState *runtime) { return gil_created(&runtime->ceval.gil); } int PyEval_ThreadsInitialized(void) { _PyRuntimeState *runtime = &_PyRuntime; return _PyEval_ThreadsInitialized(runtime); } PyStatus _PyEval_InitGIL(PyThreadState *tstate) { if (!_Py_IsMainInterpreter(tstate->interp)) { /* Currently, the GIL is shared by all interpreters, and only the main interpreter is responsible to create and destroy it. */ return _PyStatus_OK(); } struct _gil_runtime_state *gil = &tstate->interp->runtime->ceval.gil; assert(!gil_created(gil)); PyThread_init_thread(); create_gil(gil); take_gil(tstate); assert(gil_created(gil)); return _PyStatus_OK(); } void _PyEval_FiniGIL(PyInterpreterState *interp) { if (!_Py_IsMainInterpreter(interp)) { /* Currently, the GIL is shared by all interpreters, and only the main interpreter is responsible to create and destroy it. */ return; } struct _gil_runtime_state *gil = &interp->runtime->ceval.gil; if (!gil_created(gil)) { /* First Py_InitializeFromConfig() call: the GIL doesn't exist yet: do nothing. */ return; } destroy_gil(gil); assert(!gil_created(gil)); } void PyEval_InitThreads(void) { /* Do nothing: kept for backward compatibility */ } void _PyEval_Fini(void) { #ifdef Py_STATS _Py_PrintSpecializationStats(1); #endif } void PyEval_AcquireLock(void) { _PyRuntimeState *runtime = &_PyRuntime; PyThreadState *tstate = _PyRuntimeState_GetThreadState(runtime); _Py_EnsureTstateNotNULL(tstate); take_gil(tstate); } void PyEval_ReleaseLock(void) { _PyRuntimeState *runtime = &_PyRuntime; PyThreadState *tstate = _PyRuntimeState_GetThreadState(runtime); /* This function must succeed when the current thread state is NULL. We therefore avoid PyThreadState_Get() which dumps a fatal error in debug mode. */ struct _ceval_runtime_state *ceval = &runtime->ceval; struct _ceval_state *ceval2 = &tstate->interp->ceval; drop_gil(ceval, ceval2, tstate); } void _PyEval_ReleaseLock(PyThreadState *tstate) { struct _ceval_runtime_state *ceval = &tstate->interp->runtime->ceval; struct _ceval_state *ceval2 = &tstate->interp->ceval; drop_gil(ceval, ceval2, tstate); } void PyEval_AcquireThread(PyThreadState *tstate) { _Py_EnsureTstateNotNULL(tstate); take_gil(tstate); struct _gilstate_runtime_state *gilstate = &tstate->interp->runtime->gilstate; if (_PyThreadState_Swap(gilstate, tstate) != NULL) { Py_FatalError("non-NULL old thread state"); } } void PyEval_ReleaseThread(PyThreadState *tstate) { assert(is_tstate_valid(tstate)); _PyRuntimeState *runtime = tstate->interp->runtime; PyThreadState *new_tstate = _PyThreadState_Swap(&runtime->gilstate, NULL); if (new_tstate != tstate) { Py_FatalError("wrong thread state"); } struct _ceval_runtime_state *ceval = &runtime->ceval; struct _ceval_state *ceval2 = &tstate->interp->ceval; drop_gil(ceval, ceval2, tstate); } #ifdef HAVE_FORK /* This function is called from PyOS_AfterFork_Child to destroy all threads which are not running in the child process, and clear internal locks which might be held by those threads. */ PyStatus _PyEval_ReInitThreads(PyThreadState *tstate) { _PyRuntimeState *runtime = tstate->interp->runtime; struct _gil_runtime_state *gil = &runtime->ceval.gil; if (!gil_created(gil)) { return _PyStatus_OK(); } recreate_gil(gil); take_gil(tstate); struct _pending_calls *pending = &tstate->interp->ceval.pending; if (_PyThread_at_fork_reinit(&pending->lock) < 0) { return _PyStatus_ERR("Can't reinitialize pending calls lock"); } /* Destroy all threads except the current one */ _PyThreadState_DeleteExcept(runtime, tstate); return _PyStatus_OK(); } #endif /* This function is used to signal that async exceptions are waiting to be raised. */ void _PyEval_SignalAsyncExc(PyInterpreterState *interp) { SIGNAL_ASYNC_EXC(interp); } PyThreadState * PyEval_SaveThread(void) { _PyRuntimeState *runtime = &_PyRuntime; PyThreadState *tstate = _PyThreadState_Swap(&runtime->gilstate, NULL); _Py_EnsureTstateNotNULL(tstate); struct _ceval_runtime_state *ceval = &runtime->ceval; struct _ceval_state *ceval2 = &tstate->interp->ceval; assert(gil_created(&ceval->gil)); drop_gil(ceval, ceval2, tstate); return tstate; } void PyEval_RestoreThread(PyThreadState *tstate) { _Py_EnsureTstateNotNULL(tstate); take_gil(tstate); struct _gilstate_runtime_state *gilstate = &tstate->interp->runtime->gilstate; _PyThreadState_Swap(gilstate, tstate); } /* Mechanism whereby asynchronously executing callbacks (e.g. UNIX signal handlers or Mac I/O completion routines) can schedule calls to a function to be called synchronously. The synchronous function is called with one void* argument. It should return 0 for success or -1 for failure -- failure should be accompanied by an exception. If registry succeeds, the registry function returns 0; if it fails (e.g. due to too many pending calls) it returns -1 (without setting an exception condition). Note that because registry may occur from within signal handlers, or other asynchronous events, calling malloc() is unsafe! Any thread can schedule pending calls, but only the main thread will execute them. There is no facility to schedule calls to a particular thread, but that should be easy to change, should that ever be required. In that case, the static variables here should go into the python threadstate. */ void _PyEval_SignalReceived(PyInterpreterState *interp) { #ifdef MS_WINDOWS // bpo-42296: On Windows, _PyEval_SignalReceived() is called from a signal // handler which can run in a thread different than the Python thread, in // which case _Py_ThreadCanHandleSignals() is wrong. Ignore // _Py_ThreadCanHandleSignals() and always set eval_breaker to 1. // // The next eval_frame_handle_pending() call will call // _Py_ThreadCanHandleSignals() to recompute eval_breaker. int force = 1; #else int force = 0; #endif /* bpo-30703: Function called when the C signal handler of Python gets a signal. We cannot queue a callback using _PyEval_AddPendingCall() since that function is not async-signal-safe. */ SIGNAL_PENDING_SIGNALS(interp, force); } /* Push one item onto the queue while holding the lock. */ static int _push_pending_call(struct _pending_calls *pending, int (*func)(void *), void *arg) { int i = pending->last; int j = (i + 1) % NPENDINGCALLS; if (j == pending->first) { return -1; /* Queue full */ } pending->calls[i].func = func; pending->calls[i].arg = arg; pending->last = j; return 0; } /* Pop one item off the queue while holding the lock. */ static void _pop_pending_call(struct _pending_calls *pending, int (**func)(void *), void **arg) { int i = pending->first; if (i == pending->last) { return; /* Queue empty */ } *func = pending->calls[i].func; *arg = pending->calls[i].arg; pending->first = (i + 1) % NPENDINGCALLS; } /* This implementation is thread-safe. It allows scheduling to be made from any thread, and even from an executing callback. */ int _PyEval_AddPendingCall(PyInterpreterState *interp, int (*func)(void *), void *arg) { struct _pending_calls *pending = &interp->ceval.pending; /* Ensure that _PyEval_InitPendingCalls() was called and that _PyEval_FiniPendingCalls() is not called yet. */ assert(pending->lock != NULL); PyThread_acquire_lock(pending->lock, WAIT_LOCK); int result = _push_pending_call(pending, func, arg); PyThread_release_lock(pending->lock); /* signal main loop */ SIGNAL_PENDING_CALLS(interp); return result; } int Py_AddPendingCall(int (*func)(void *), void *arg) { /* Best-effort to support subinterpreters and calls with the GIL released. First attempt _PyThreadState_GET() since it supports subinterpreters. If the GIL is released, _PyThreadState_GET() returns NULL . In this case, use PyGILState_GetThisThreadState() which works even if the GIL is released. Sadly, PyGILState_GetThisThreadState() doesn't support subinterpreters: see bpo-10915 and bpo-15751. Py_AddPendingCall() doesn't require the caller to hold the GIL. */ PyThreadState *tstate = _PyThreadState_GET(); if (tstate == NULL) { tstate = PyGILState_GetThisThreadState(); } PyInterpreterState *interp; if (tstate != NULL) { interp = tstate->interp; } else { /* Last resort: use the main interpreter */ interp = _PyInterpreterState_Main(); } return _PyEval_AddPendingCall(interp, func, arg); } static int handle_signals(PyThreadState *tstate) { assert(is_tstate_valid(tstate)); if (!_Py_ThreadCanHandleSignals(tstate->interp)) { return 0; } UNSIGNAL_PENDING_SIGNALS(tstate->interp); if (_PyErr_CheckSignalsTstate(tstate) < 0) { /* On failure, re-schedule a call to handle_signals(). */ SIGNAL_PENDING_SIGNALS(tstate->interp, 0); return -1; } return 0; } static int make_pending_calls(PyInterpreterState *interp) { /* only execute pending calls on main thread */ if (!_Py_ThreadCanHandlePendingCalls()) { return 0; } /* don't perform recursive pending calls */ static int busy = 0; if (busy) { return 0; } busy = 1; /* unsignal before starting to call callbacks, so that any callback added in-between re-signals */ UNSIGNAL_PENDING_CALLS(interp); int res = 0; /* perform a bounded number of calls, in case of recursion */ struct _pending_calls *pending = &interp->ceval.pending; for (int i=0; ilock, WAIT_LOCK); _pop_pending_call(pending, &func, &arg); PyThread_release_lock(pending->lock); /* having released the lock, perform the callback */ if (func == NULL) { break; } res = func(arg); if (res) { goto error; } } busy = 0; return res; error: busy = 0; SIGNAL_PENDING_CALLS(interp); return res; } void _Py_FinishPendingCalls(PyThreadState *tstate) { assert(PyGILState_Check()); assert(is_tstate_valid(tstate)); struct _pending_calls *pending = &tstate->interp->ceval.pending; if (!_Py_atomic_load_relaxed_int32(&(pending->calls_to_do))) { return; } if (make_pending_calls(tstate->interp) < 0) { PyObject *exc, *val, *tb; _PyErr_Fetch(tstate, &exc, &val, &tb); PyErr_BadInternalCall(); _PyErr_ChainExceptions(exc, val, tb); _PyErr_Print(tstate); } } /* Py_MakePendingCalls() is a simple wrapper for the sake of backward-compatibility. */ int Py_MakePendingCalls(void) { assert(PyGILState_Check()); PyThreadState *tstate = _PyThreadState_GET(); assert(is_tstate_valid(tstate)); /* Python signal handler doesn't really queue a callback: it only signals that a signal was received, see _PyEval_SignalReceived(). */ int res = handle_signals(tstate); if (res != 0) { return res; } res = make_pending_calls(tstate->interp); if (res != 0) { return res; } return 0; } /* The interpreter's recursion limit */ void _PyEval_InitRuntimeState(struct _ceval_runtime_state *ceval) { _gil_initialize(&ceval->gil); } void _PyEval_InitState(struct _ceval_state *ceval, PyThread_type_lock pending_lock) { struct _pending_calls *pending = &ceval->pending; assert(pending->lock == NULL); pending->lock = pending_lock; } void _PyEval_FiniState(struct _ceval_state *ceval) { struct _pending_calls *pending = &ceval->pending; if (pending->lock != NULL) { PyThread_free_lock(pending->lock); pending->lock = NULL; } } int Py_GetRecursionLimit(void) { PyInterpreterState *interp = _PyInterpreterState_GET(); return interp->ceval.recursion_limit; } void Py_SetRecursionLimit(int new_limit) { PyInterpreterState *interp = _PyInterpreterState_GET(); interp->ceval.recursion_limit = new_limit; for (PyThreadState *p = interp->threads.head; p != NULL; p = p->next) { int depth = p->recursion_limit - p->recursion_remaining; p->recursion_limit = new_limit; p->recursion_remaining = new_limit - depth; } } /* The function _Py_EnterRecursiveCallTstate() only calls _Py_CheckRecursiveCall() if the recursion_depth reaches recursion_limit. */ int _Py_CheckRecursiveCall(PyThreadState *tstate, const char *where) { /* Check against global limit first. */ int depth = tstate->recursion_limit - tstate->recursion_remaining; if (depth < tstate->interp->ceval.recursion_limit) { tstate->recursion_limit = tstate->interp->ceval.recursion_limit; tstate->recursion_remaining = tstate->recursion_limit - depth; assert(tstate->recursion_remaining > 0); return 0; } #ifdef USE_STACKCHECK if (PyOS_CheckStack()) { ++tstate->recursion_remaining; _PyErr_SetString(tstate, PyExc_MemoryError, "Stack overflow"); return -1; } #endif if (tstate->recursion_headroom) { if (tstate->recursion_remaining < -50) { /* Overflowing while handling an overflow. Give up. */ Py_FatalError("Cannot recover from stack overflow."); } } else { if (tstate->recursion_remaining <= 0) { tstate->recursion_headroom++; _PyErr_Format(tstate, PyExc_RecursionError, "maximum recursion depth exceeded%s", where); tstate->recursion_headroom--; ++tstate->recursion_remaining; return -1; } } return 0; } static const binaryfunc binary_ops[] = { [NB_ADD] = PyNumber_Add, [NB_AND] = PyNumber_And, [NB_FLOOR_DIVIDE] = PyNumber_FloorDivide, [NB_LSHIFT] = PyNumber_Lshift, [NB_MATRIX_MULTIPLY] = PyNumber_MatrixMultiply, [NB_MULTIPLY] = PyNumber_Multiply, [NB_REMAINDER] = PyNumber_Remainder, [NB_OR] = PyNumber_Or, [NB_POWER] = _PyNumber_PowerNoMod, [NB_RSHIFT] = PyNumber_Rshift, [NB_SUBTRACT] = PyNumber_Subtract, [NB_TRUE_DIVIDE] = PyNumber_TrueDivide, [NB_XOR] = PyNumber_Xor, [NB_INPLACE_ADD] = PyNumber_InPlaceAdd, [NB_INPLACE_AND] = PyNumber_InPlaceAnd, [NB_INPLACE_FLOOR_DIVIDE] = PyNumber_InPlaceFloorDivide, [NB_INPLACE_LSHIFT] = PyNumber_InPlaceLshift, [NB_INPLACE_MATRIX_MULTIPLY] = PyNumber_InPlaceMatrixMultiply, [NB_INPLACE_MULTIPLY] = PyNumber_InPlaceMultiply, [NB_INPLACE_REMAINDER] = PyNumber_InPlaceRemainder, [NB_INPLACE_OR] = PyNumber_InPlaceOr, [NB_INPLACE_POWER] = _PyNumber_InPlacePowerNoMod, [NB_INPLACE_RSHIFT] = PyNumber_InPlaceRshift, [NB_INPLACE_SUBTRACT] = PyNumber_InPlaceSubtract, [NB_INPLACE_TRUE_DIVIDE] = PyNumber_InPlaceTrueDivide, [NB_INPLACE_XOR] = PyNumber_InPlaceXor, }; // PEP 634: Structural Pattern Matching // Return a tuple of values corresponding to keys, with error checks for // duplicate/missing keys. static PyObject* match_keys(PyThreadState *tstate, PyObject *map, PyObject *keys) { assert(PyTuple_CheckExact(keys)); Py_ssize_t nkeys = PyTuple_GET_SIZE(keys); if (!nkeys) { // No keys means no items. return PyTuple_New(0); } PyObject *seen = NULL; PyObject *dummy = NULL; PyObject *values = NULL; PyObject *get = NULL; // We use the two argument form of map.get(key, default) for two reasons: // - Atomically check for a key and get its value without error handling. // - Don't cause key creation or resizing in dict subclasses like // collections.defaultdict that define __missing__ (or similar). int meth_found = _PyObject_GetMethod(map, &_Py_ID(get), &get); if (get == NULL) { goto fail; } seen = PySet_New(NULL); if (seen == NULL) { goto fail; } // dummy = object() dummy = _PyObject_CallNoArgs((PyObject *)&PyBaseObject_Type); if (dummy == NULL) { goto fail; } values = PyTuple_New(nkeys); if (values == NULL) { goto fail; } for (Py_ssize_t i = 0; i < nkeys; i++) { PyObject *key = PyTuple_GET_ITEM(keys, i); if (PySet_Contains(seen, key) || PySet_Add(seen, key)) { if (!_PyErr_Occurred(tstate)) { // Seen it before! _PyErr_Format(tstate, PyExc_ValueError, "mapping pattern checks duplicate key (%R)", key); } goto fail; } PyObject *args[] = { map, key, dummy }; PyObject *value = NULL; if (meth_found) { value = PyObject_Vectorcall(get, args, 3, NULL); } else { value = PyObject_Vectorcall(get, &args[1], 2, NULL); } if (value == NULL) { goto fail; } if (value == dummy) { // key not in map! Py_DECREF(value); Py_DECREF(values); // Return None: Py_INCREF(Py_None); values = Py_None; goto done; } PyTuple_SET_ITEM(values, i, value); } // Success: done: Py_DECREF(get); Py_DECREF(seen); Py_DECREF(dummy); return values; fail: Py_XDECREF(get); Py_XDECREF(seen); Py_XDECREF(dummy); Py_XDECREF(values); return NULL; } // Extract a named attribute from the subject, with additional bookkeeping to // raise TypeErrors for repeated lookups. On failure, return NULL (with no // error set). Use _PyErr_Occurred(tstate) to disambiguate. static PyObject* match_class_attr(PyThreadState *tstate, PyObject *subject, PyObject *type, PyObject *name, PyObject *seen) { assert(PyUnicode_CheckExact(name)); assert(PySet_CheckExact(seen)); if (PySet_Contains(seen, name) || PySet_Add(seen, name)) { if (!_PyErr_Occurred(tstate)) { // Seen it before! _PyErr_Format(tstate, PyExc_TypeError, "%s() got multiple sub-patterns for attribute %R", ((PyTypeObject*)type)->tp_name, name); } return NULL; } PyObject *attr = PyObject_GetAttr(subject, name); if (attr == NULL && _PyErr_ExceptionMatches(tstate, PyExc_AttributeError)) { _PyErr_Clear(tstate); } return attr; } // On success (match), return a tuple of extracted attributes. On failure (no // match), return NULL. Use _PyErr_Occurred(tstate) to disambiguate. static PyObject* match_class(PyThreadState *tstate, PyObject *subject, PyObject *type, Py_ssize_t nargs, PyObject *kwargs) { if (!PyType_Check(type)) { const char *e = "called match pattern must be a type"; _PyErr_Format(tstate, PyExc_TypeError, e); return NULL; } assert(PyTuple_CheckExact(kwargs)); // First, an isinstance check: if (PyObject_IsInstance(subject, type) <= 0) { return NULL; } // So far so good: PyObject *seen = PySet_New(NULL); if (seen == NULL) { return NULL; } PyObject *attrs = PyList_New(0); if (attrs == NULL) { Py_DECREF(seen); return NULL; } // NOTE: From this point on, goto fail on failure: PyObject *match_args = NULL; // First, the positional subpatterns: if (nargs) { int match_self = 0; match_args = PyObject_GetAttrString(type, "__match_args__"); if (match_args) { if (!PyTuple_CheckExact(match_args)) { const char *e = "%s.__match_args__ must be a tuple (got %s)"; _PyErr_Format(tstate, PyExc_TypeError, e, ((PyTypeObject *)type)->tp_name, Py_TYPE(match_args)->tp_name); goto fail; } } else if (_PyErr_ExceptionMatches(tstate, PyExc_AttributeError)) { _PyErr_Clear(tstate); // _Py_TPFLAGS_MATCH_SELF is only acknowledged if the type does not // define __match_args__. This is natural behavior for subclasses: // it's as if __match_args__ is some "magic" value that is lost as // soon as they redefine it. match_args = PyTuple_New(0); match_self = PyType_HasFeature((PyTypeObject*)type, _Py_TPFLAGS_MATCH_SELF); } else { goto fail; } assert(PyTuple_CheckExact(match_args)); Py_ssize_t allowed = match_self ? 1 : PyTuple_GET_SIZE(match_args); if (allowed < nargs) { const char *plural = (allowed == 1) ? "" : "s"; _PyErr_Format(tstate, PyExc_TypeError, "%s() accepts %d positional sub-pattern%s (%d given)", ((PyTypeObject*)type)->tp_name, allowed, plural, nargs); goto fail; } if (match_self) { // Easy. Copy the subject itself, and move on to kwargs. PyList_Append(attrs, subject); } else { for (Py_ssize_t i = 0; i < nargs; i++) { PyObject *name = PyTuple_GET_ITEM(match_args, i); if (!PyUnicode_CheckExact(name)) { _PyErr_Format(tstate, PyExc_TypeError, "__match_args__ elements must be strings " "(got %s)", Py_TYPE(name)->tp_name); goto fail; } PyObject *attr = match_class_attr(tstate, subject, type, name, seen); if (attr == NULL) { goto fail; } PyList_Append(attrs, attr); Py_DECREF(attr); } } Py_CLEAR(match_args); } // Finally, the keyword subpatterns: for (Py_ssize_t i = 0; i < PyTuple_GET_SIZE(kwargs); i++) { PyObject *name = PyTuple_GET_ITEM(kwargs, i); PyObject *attr = match_class_attr(tstate, subject, type, name, seen); if (attr == NULL) { goto fail; } PyList_Append(attrs, attr); Py_DECREF(attr); } Py_SETREF(attrs, PyList_AsTuple(attrs)); Py_DECREF(seen); return attrs; fail: // We really don't care whether an error was raised or not... that's our // caller's problem. All we know is that the match failed. Py_XDECREF(match_args); Py_DECREF(seen); Py_DECREF(attrs); return NULL; } static int do_raise(PyThreadState *tstate, PyObject *exc, PyObject *cause); static int exception_group_match( PyObject* exc_value, PyObject *match_type, PyObject **match, PyObject **rest); static int unpack_iterable(PyThreadState *, PyObject *, int, int, PyObject **); PyObject * PyEval_EvalCode(PyObject *co, PyObject *globals, PyObject *locals) { PyThreadState *tstate = _PyThreadState_GET(); if (locals == NULL) { locals = globals; } PyObject *builtins = _PyEval_BuiltinsFromGlobals(tstate, globals); // borrowed ref if (builtins == NULL) { return NULL; } PyFrameConstructor desc = { .fc_globals = globals, .fc_builtins = builtins, .fc_name = ((PyCodeObject *)co)->co_name, .fc_qualname = ((PyCodeObject *)co)->co_name, .fc_code = co, .fc_defaults = NULL, .fc_kwdefaults = NULL, .fc_closure = NULL }; PyFunctionObject *func = _PyFunction_FromConstructor(&desc); if (func == NULL) { return NULL; } PyObject *res = _PyEval_Vector(tstate, func, locals, NULL, 0, NULL); Py_DECREF(func); return res; } /* Interpreter main loop */ PyObject * PyEval_EvalFrame(PyFrameObject *f) { /* Function kept for backward compatibility */ PyThreadState *tstate = _PyThreadState_GET(); return _PyEval_EvalFrame(tstate, f->f_frame, 0); } PyObject * PyEval_EvalFrameEx(PyFrameObject *f, int throwflag) { PyThreadState *tstate = _PyThreadState_GET(); return _PyEval_EvalFrame(tstate, f->f_frame, throwflag); } /* Handle signals, pending calls, GIL drop request and asynchronous exception */ static int eval_frame_handle_pending(PyThreadState *tstate) { _PyRuntimeState * const runtime = &_PyRuntime; struct _ceval_runtime_state *ceval = &runtime->ceval; /* Pending signals */ if (_Py_atomic_load_relaxed_int32(&ceval->signals_pending)) { if (handle_signals(tstate) != 0) { return -1; } } /* Pending calls */ struct _ceval_state *ceval2 = &tstate->interp->ceval; if (_Py_atomic_load_relaxed_int32(&ceval2->pending.calls_to_do)) { if (make_pending_calls(tstate->interp) != 0) { return -1; } } /* GIL drop request */ if (_Py_atomic_load_relaxed_int32(&ceval2->gil_drop_request)) { /* Give another thread a chance */ if (_PyThreadState_Swap(&runtime->gilstate, NULL) != tstate) { Py_FatalError("tstate mix-up"); } drop_gil(ceval, ceval2, tstate); /* Other threads may run now */ take_gil(tstate); if (_PyThreadState_Swap(&runtime->gilstate, tstate) != NULL) { Py_FatalError("orphan tstate"); } } /* Check for asynchronous exception. */ if (tstate->async_exc != NULL) { PyObject *exc = tstate->async_exc; tstate->async_exc = NULL; UNSIGNAL_ASYNC_EXC(tstate->interp); _PyErr_SetNone(tstate, exc); Py_DECREF(exc); return -1; } #ifdef MS_WINDOWS // bpo-42296: On Windows, _PyEval_SignalReceived() can be called in a // different thread than the Python thread, in which case // _Py_ThreadCanHandleSignals() is wrong. Recompute eval_breaker in the // current Python thread with the correct _Py_ThreadCanHandleSignals() // value. It prevents to interrupt the eval loop at every instruction if // the current Python thread cannot handle signals (if // _Py_ThreadCanHandleSignals() is false). COMPUTE_EVAL_BREAKER(tstate->interp, ceval, ceval2); #endif return 0; } /* Computed GOTOs, or the-optimization-commonly-but-improperly-known-as-"threaded code" using gcc's labels-as-values extension (http://gcc.gnu.org/onlinedocs/gcc/Labels-as-Values.html). The traditional bytecode evaluation loop uses a "switch" statement, which decent compilers will optimize as a single indirect branch instruction combined with a lookup table of jump addresses. However, since the indirect jump instruction is shared by all opcodes, the CPU will have a hard time making the right prediction for where to jump next (actually, it will be always wrong except in the uncommon case of a sequence of several identical opcodes). "Threaded code" in contrast, uses an explicit jump table and an explicit indirect jump instruction at the end of each opcode. Since the jump instruction is at a different address for each opcode, the CPU will make a separate prediction for each of these instructions, which is equivalent to predicting the second opcode of each opcode pair. These predictions have a much better chance to turn out valid, especially in small bytecode loops. A mispredicted branch on a modern CPU flushes the whole pipeline and can cost several CPU cycles (depending on the pipeline depth), and potentially many more instructions (depending on the pipeline width). A correctly predicted branch, however, is nearly free. At the time of this writing, the "threaded code" version is up to 15-20% faster than the normal "switch" version, depending on the compiler and the CPU architecture. NOTE: care must be taken that the compiler doesn't try to "optimize" the indirect jumps by sharing them between all opcodes. Such optimizations can be disabled on gcc by using the -fno-gcse flag (or possibly -fno-crossjumping). */ /* Use macros rather than inline functions, to make it as clear as possible * to the C compiler that the tracing check is a simple test then branch. * We want to be sure that the compiler knows this before it generates * the CFG. */ #ifdef WITH_DTRACE #define OR_DTRACE_LINE | (PyDTrace_LINE_ENABLED() ? 255 : 0) #else #define OR_DTRACE_LINE #endif #ifdef HAVE_COMPUTED_GOTOS #ifndef USE_COMPUTED_GOTOS #define USE_COMPUTED_GOTOS 1 #endif #else #if defined(USE_COMPUTED_GOTOS) && USE_COMPUTED_GOTOS #error "Computed gotos are not supported on this compiler." #endif #undef USE_COMPUTED_GOTOS #define USE_COMPUTED_GOTOS 0 #endif #ifdef Py_STATS #define INSTRUCTION_START(op) \ do { \ frame->prev_instr = next_instr++; \ OPCODE_EXE_INC(op); \ _py_stats.opcode_stats[lastopcode].pair_count[op]++; \ lastopcode = op; \ } while (0) #else #define INSTRUCTION_START(op) (frame->prev_instr = next_instr++) #endif #if USE_COMPUTED_GOTOS #define TARGET(op) TARGET_##op: INSTRUCTION_START(op); #define DISPATCH_GOTO() goto *opcode_targets[opcode] #else #define TARGET(op) case op: INSTRUCTION_START(op); #define DISPATCH_GOTO() goto dispatch_opcode #endif /* PRE_DISPATCH_GOTO() does lltrace if enabled. Normally a no-op */ #ifdef LLTRACE #define PRE_DISPATCH_GOTO() if (lltrace) { \ lltrace_instruction(frame, stack_pointer, next_instr); } #else #define PRE_DISPATCH_GOTO() ((void)0) #endif /* Do interpreter dispatch accounting for tracing and instrumentation */ #define DISPATCH() \ { \ NEXTOPARG(); \ PRE_DISPATCH_GOTO(); \ assert(cframe.use_tracing == 0 || cframe.use_tracing == 255); \ opcode |= cframe.use_tracing OR_DTRACE_LINE; \ DISPATCH_GOTO(); \ } #define DISPATCH_SAME_OPARG() \ { \ opcode = _Py_OPCODE(*next_instr); \ PRE_DISPATCH_GOTO(); \ opcode |= cframe.use_tracing OR_DTRACE_LINE; \ DISPATCH_GOTO(); \ } #define CHECK_EVAL_BREAKER() \ _Py_CHECK_EMSCRIPTEN_SIGNALS_PERIODICALLY(); \ if (_Py_atomic_load_relaxed_int32(eval_breaker)) { \ goto handle_eval_breaker; \ } /* Tuple access macros */ #ifndef Py_DEBUG #define GETITEM(v, i) PyTuple_GET_ITEM((PyTupleObject *)(v), (i)) #else #define GETITEM(v, i) PyTuple_GetItem((v), (i)) #endif /* Code access macros */ /* The integer overflow is checked by an assertion below. */ #define INSTR_OFFSET() ((int)(next_instr - first_instr)) #define NEXTOPARG() do { \ _Py_CODEUNIT word = *next_instr; \ opcode = _Py_OPCODE(word); \ oparg = _Py_OPARG(word); \ } while (0) #define JUMPTO(x) (next_instr = first_instr + (x)) #define JUMPBY(x) (next_instr += (x)) // Skip from a PRECALL over a CALL to the next instruction: #define SKIP_CALL() \ JUMPBY(INLINE_CACHE_ENTRIES_PRECALL + 1 + INLINE_CACHE_ENTRIES_CALL) /* Get opcode and oparg from original instructions, not quickened form. */ #define TRACING_NEXTOPARG() do { \ NEXTOPARG(); \ opcode = _PyOpcode_Deopt[opcode]; \ } while (0) /* OpCode prediction macros Some opcodes tend to come in pairs thus making it possible to predict the second code when the first is run. For example, COMPARE_OP is often followed by POP_JUMP_IF_FALSE or POP_JUMP_IF_TRUE. Verifying the prediction costs a single high-speed test of a register variable against a constant. If the pairing was good, then the processor's own internal branch predication has a high likelihood of success, resulting in a nearly zero-overhead transition to the next opcode. A successful prediction saves a trip through the eval-loop including its unpredictable switch-case branch. Combined with the processor's internal branch prediction, a successful PREDICT has the effect of making the two opcodes run as if they were a single new opcode with the bodies combined. If collecting opcode statistics, your choices are to either keep the predictions turned-on and interpret the results as if some opcodes had been combined or turn-off predictions so that the opcode frequency counter updates for both opcodes. Opcode prediction is disabled with threaded code, since the latter allows the CPU to record separate branch prediction information for each opcode. */ #define PREDICT_ID(op) PRED_##op #if USE_COMPUTED_GOTOS #define PREDICT(op) if (0) goto PREDICT_ID(op) #else #define PREDICT(op) \ do { \ _Py_CODEUNIT word = *next_instr; \ opcode = _Py_OPCODE(word) | cframe.use_tracing OR_DTRACE_LINE; \ if (opcode == op) { \ oparg = _Py_OPARG(word); \ INSTRUCTION_START(op); \ goto PREDICT_ID(op); \ } \ } while(0) #endif #define PREDICTED(op) PREDICT_ID(op): /* Stack manipulation macros */ /* The stack can grow at most MAXINT deep, as co_nlocals and co_stacksize are ints. */ #define STACK_LEVEL() ((int)(stack_pointer - _PyFrame_Stackbase(frame))) #define STACK_SIZE() (frame->f_code->co_stacksize) #define EMPTY() (STACK_LEVEL() == 0) #define TOP() (stack_pointer[-1]) #define SECOND() (stack_pointer[-2]) #define THIRD() (stack_pointer[-3]) #define FOURTH() (stack_pointer[-4]) #define PEEK(n) (stack_pointer[-(n)]) #define SET_TOP(v) (stack_pointer[-1] = (v)) #define SET_SECOND(v) (stack_pointer[-2] = (v)) #define BASIC_STACKADJ(n) (stack_pointer += n) #define BASIC_PUSH(v) (*stack_pointer++ = (v)) #define BASIC_POP() (*--stack_pointer) #ifdef Py_DEBUG #define PUSH(v) do { \ BASIC_PUSH(v); \ assert(STACK_LEVEL() <= STACK_SIZE()); \ } while (0) #define POP() (assert(STACK_LEVEL() > 0), BASIC_POP()) #define STACK_GROW(n) do { \ assert(n >= 0); \ BASIC_STACKADJ(n); \ assert(STACK_LEVEL() <= STACK_SIZE()); \ } while (0) #define STACK_SHRINK(n) do { \ assert(n >= 0); \ assert(STACK_LEVEL() >= n); \ BASIC_STACKADJ(-(n)); \ } while (0) #else #define PUSH(v) BASIC_PUSH(v) #define POP() BASIC_POP() #define STACK_GROW(n) BASIC_STACKADJ(n) #define STACK_SHRINK(n) BASIC_STACKADJ(-(n)) #endif /* Local variable macros */ #define GETLOCAL(i) (frame->localsplus[i]) /* The SETLOCAL() macro must not DECREF the local variable in-place and then store the new value; it must copy the old value to a temporary value, then store the new value, and then DECREF the temporary value. This is because it is possible that during the DECREF the frame is accessed by other code (e.g. a __del__ method or gc.collect()) and the variable would be pointing to already-freed memory. */ #define SETLOCAL(i, value) do { PyObject *tmp = GETLOCAL(i); \ GETLOCAL(i) = value; \ Py_XDECREF(tmp); } while (0) #define JUMP_TO_INSTRUCTION(op) goto PREDICT_ID(op) #define DEOPT_IF(cond, instname) if (cond) { goto miss; } #define GLOBALS() frame->f_globals #define BUILTINS() frame->f_builtins #define LOCALS() frame->f_locals /* Shared opcode macros */ // shared by LOAD_ATTR_MODULE and LOAD_METHOD_MODULE #define LOAD_MODULE_ATTR_OR_METHOD(attr_or_method) \ _PyAttrCache *cache = (_PyAttrCache *)next_instr; \ DEOPT_IF(!PyModule_CheckExact(owner), LOAD_##attr_or_method); \ PyDictObject *dict = (PyDictObject *)((PyModuleObject *)owner)->md_dict; \ assert(dict != NULL); \ DEOPT_IF(dict->ma_keys->dk_version != read_u32(cache->version), \ LOAD_##attr_or_method); \ assert(dict->ma_keys->dk_kind == DICT_KEYS_UNICODE); \ assert(cache->index < dict->ma_keys->dk_nentries); \ PyDictUnicodeEntry *ep = DK_UNICODE_ENTRIES(dict->ma_keys) + cache->index; \ res = ep->me_value; \ DEOPT_IF(res == NULL, LOAD_##attr_or_method); \ STAT_INC(LOAD_##attr_or_method, hit); \ Py_INCREF(res); #define TRACE_FUNCTION_EXIT() \ if (cframe.use_tracing) { \ if (trace_function_exit(tstate, frame, retval)) { \ Py_DECREF(retval); \ goto exit_unwind; \ } \ } #define DTRACE_FUNCTION_EXIT() \ if (PyDTrace_FUNCTION_RETURN_ENABLED()) { \ dtrace_function_return(frame); \ } #define TRACE_FUNCTION_UNWIND() \ if (cframe.use_tracing) { \ /* Since we are already unwinding, \ * we don't care if this raises */ \ trace_function_exit(tstate, frame, NULL); \ } #define TRACE_FUNCTION_ENTRY() \ if (cframe.use_tracing) { \ _PyFrame_SetStackPointer(frame, stack_pointer); \ int err = trace_function_entry(tstate, frame); \ stack_pointer = _PyFrame_GetStackPointer(frame); \ frame->stacktop = -1; \ if (err) { \ goto error; \ } \ } #define TRACE_FUNCTION_THROW_ENTRY() \ if (cframe.use_tracing) { \ assert(frame->stacktop >= 0); \ if (trace_function_entry(tstate, frame)) { \ goto exit_unwind; \ } \ } #define DTRACE_FUNCTION_ENTRY() \ if (PyDTrace_FUNCTION_ENTRY_ENABLED()) { \ dtrace_function_entry(frame); \ } #define ADAPTIVE_COUNTER_IS_ZERO(cache) \ (cache)->counter < (1<counter -= (1<c_tracefunc != NULL) { /* tstate->c_tracefunc, if defined, is a function that will be called on *every* entry to a code block. Its return value, if not None, is a function that will be called at the start of each executed line of code. (Actually, the function must return itself in order to continue tracing.) The trace functions are called with three arguments: a pointer to the current frame, a string indicating why the function is called, and an argument which depends on the situation. The global trace function is also called whenever an exception is detected. */ if (call_trace_protected(tstate->c_tracefunc, tstate->c_traceobj, tstate, frame, PyTrace_CALL, Py_None)) { /* Trace function raised an error */ return -1; } } if (tstate->c_profilefunc != NULL) { /* Similar for c_profilefunc, except it needn't return itself and isn't called for "line" events */ if (call_trace_protected(tstate->c_profilefunc, tstate->c_profileobj, tstate, frame, PyTrace_CALL, Py_None)) { /* Profile function raised an error */ return -1; } } return 0; } static int trace_function_exit(PyThreadState *tstate, _PyInterpreterFrame *frame, PyObject *retval) { if (tstate->c_tracefunc) { if (call_trace_protected(tstate->c_tracefunc, tstate->c_traceobj, tstate, frame, PyTrace_RETURN, retval)) { return -1; } } if (tstate->c_profilefunc) { if (call_trace_protected(tstate->c_profilefunc, tstate->c_profileobj, tstate, frame, PyTrace_RETURN, retval)) { return -1; } } return 0; } /* It is only between the PRECALL instruction and the following CALL, * that this has any meaning. */ typedef struct { PyObject *kwnames; } CallShape; // GH-89279: Must be a macro to be sure it's inlined by MSVC. #define is_method(stack_pointer, args) (PEEK((args)+2) != NULL) #define KWNAMES_LEN() \ (call_shape.kwnames == NULL ? 0 : ((int)PyTuple_GET_SIZE(call_shape.kwnames))) PyObject* _Py_HOT_FUNCTION _PyEval_EvalFrameDefault(PyThreadState *tstate, _PyInterpreterFrame *frame, int throwflag) { _Py_EnsureTstateNotNULL(tstate); CALL_STAT_INC(pyeval_calls); #if USE_COMPUTED_GOTOS /* Import the static jump table */ #include "opcode_targets.h" #endif #ifdef Py_STATS int lastopcode = 0; #endif // opcode is an 8-bit value to improve the code generated by MSVC // for the big switch below (in combination with the EXTRA_CASES macro). uint8_t opcode; /* Current opcode */ int oparg; /* Current opcode argument, if any */ _Py_atomic_int * const eval_breaker = &tstate->interp->ceval.eval_breaker; #ifdef LLTRACE int lltrace = 0; #endif _PyCFrame cframe; CallShape call_shape; call_shape.kwnames = NULL; // Borrowed reference. Reset by CALL instructions. /* WARNING: Because the _PyCFrame lives on the C stack, * but can be accessed from a heap allocated object (tstate) * strict stack discipline must be maintained. */ _PyCFrame *prev_cframe = tstate->cframe; cframe.use_tracing = prev_cframe->use_tracing; cframe.previous = prev_cframe; tstate->cframe = &cframe; frame->is_entry = true; /* Push frame */ frame->previous = prev_cframe->current_frame; cframe.current_frame = frame; /* support for generator.throw() */ if (throwflag) { if (_Py_EnterRecursiveCallTstate(tstate, "")) { tstate->recursion_remaining--; goto exit_unwind; } TRACE_FUNCTION_THROW_ENTRY(); DTRACE_FUNCTION_ENTRY(); goto resume_with_error; } /* Local "register" variables. * These are cached values from the frame and code object. */ PyObject *names; PyObject *consts; _Py_CODEUNIT *first_instr; _Py_CODEUNIT *next_instr; PyObject **stack_pointer; /* Sets the above local variables from the frame */ #define SET_LOCALS_FROM_FRAME() \ { \ PyCodeObject *co = frame->f_code; \ names = co->co_names; \ consts = co->co_consts; \ first_instr = _PyCode_CODE(co); \ } \ assert(_PyInterpreterFrame_LASTI(frame) >= -1); \ /* Jump back to the last instruction executed... */ \ next_instr = frame->prev_instr + 1; \ stack_pointer = _PyFrame_GetStackPointer(frame); \ /* Set stackdepth to -1. \ Update when returning or calling trace function. \ Having stackdepth <= 0 ensures that invalid \ values are not visible to the cycle GC. \ We choose -1 rather than 0 to assist debugging. \ */ \ frame->stacktop = -1; start_frame: if (_Py_EnterRecursiveCallTstate(tstate, "")) { tstate->recursion_remaining--; goto exit_unwind; } resume_frame: SET_LOCALS_FROM_FRAME(); #ifdef LLTRACE { int r = PyDict_Contains(GLOBALS(), &_Py_ID(__lltrace__)); if (r < 0) { goto exit_unwind; } lltrace = r; } if (lltrace) { lltrace_resume_frame(frame); } #endif #ifdef Py_DEBUG /* _PyEval_EvalFrameDefault() must not be called with an exception set, because it can clear it (directly or indirectly) and so the caller loses its exception */ assert(!_PyErr_Occurred(tstate)); #endif DISPATCH(); handle_eval_breaker: /* Do periodic things, like check for signals and async I/0. * We need to do reasonably frequently, but not too frequently. * All loops should include a check of the eval breaker. * We also check on return from any builtin function. */ if (eval_frame_handle_pending(tstate) != 0) { goto error; } DISPATCH(); { /* Start instructions */ #if USE_COMPUTED_GOTOS { #else dispatch_opcode: switch (opcode) { #endif /* BEWARE! It is essential that any operation that fails must goto error and that all operation that succeed call DISPATCH() ! */ TARGET(NOP) { DISPATCH(); } TARGET(RESUME) { _PyCode_Warmup(frame->f_code); JUMP_TO_INSTRUCTION(RESUME_QUICK); } TARGET(RESUME_QUICK) { PREDICTED(RESUME_QUICK); assert(tstate->cframe == &cframe); assert(frame == cframe.current_frame); if (_Py_atomic_load_relaxed_int32(eval_breaker) && oparg < 2) { goto handle_eval_breaker; } DISPATCH(); } TARGET(LOAD_CLOSURE) { /* We keep LOAD_CLOSURE so that the bytecode stays more readable. */ PyObject *value = GETLOCAL(oparg); if (value == NULL) { goto unbound_local_error; } Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(LOAD_FAST) { PyObject *value = GETLOCAL(oparg); if (value == NULL) { goto unbound_local_error; } Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(LOAD_CONST) { PREDICTED(LOAD_CONST); PyObject *value = GETITEM(consts, oparg); Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(STORE_FAST) { PREDICTED(STORE_FAST); PyObject *value = POP(); SETLOCAL(oparg, value); DISPATCH(); } TARGET(LOAD_FAST__LOAD_FAST) { PyObject *value = GETLOCAL(oparg); if (value == NULL) { goto unbound_local_error; } NEXTOPARG(); next_instr++; Py_INCREF(value); PUSH(value); value = GETLOCAL(oparg); if (value == NULL) { goto unbound_local_error; } Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(LOAD_FAST__LOAD_CONST) { PyObject *value = GETLOCAL(oparg); if (value == NULL) { goto unbound_local_error; } NEXTOPARG(); next_instr++; Py_INCREF(value); PUSH(value); value = GETITEM(consts, oparg); Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(STORE_FAST__LOAD_FAST) { PyObject *value = POP(); SETLOCAL(oparg, value); NEXTOPARG(); next_instr++; value = GETLOCAL(oparg); if (value == NULL) { goto unbound_local_error; } Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(STORE_FAST__STORE_FAST) { PyObject *value = POP(); SETLOCAL(oparg, value); NEXTOPARG(); next_instr++; value = POP(); SETLOCAL(oparg, value); DISPATCH(); } TARGET(LOAD_CONST__LOAD_FAST) { PyObject *value = GETITEM(consts, oparg); NEXTOPARG(); next_instr++; Py_INCREF(value); PUSH(value); value = GETLOCAL(oparg); if (value == NULL) { goto unbound_local_error; } Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(POP_TOP) { PyObject *value = POP(); Py_DECREF(value); DISPATCH(); } TARGET(PUSH_NULL) { /* Use BASIC_PUSH as NULL is not a valid object pointer */ BASIC_PUSH(NULL); DISPATCH(); } TARGET(UNARY_POSITIVE) { PyObject *value = TOP(); PyObject *res = PyNumber_Positive(value); Py_DECREF(value); SET_TOP(res); if (res == NULL) goto error; DISPATCH(); } TARGET(UNARY_NEGATIVE) { PyObject *value = TOP(); PyObject *res = PyNumber_Negative(value); Py_DECREF(value); SET_TOP(res); if (res == NULL) goto error; DISPATCH(); } TARGET(UNARY_NOT) { PyObject *value = TOP(); int err = PyObject_IsTrue(value); Py_DECREF(value); if (err == 0) { Py_INCREF(Py_True); SET_TOP(Py_True); DISPATCH(); } else if (err > 0) { Py_INCREF(Py_False); SET_TOP(Py_False); DISPATCH(); } STACK_SHRINK(1); goto error; } TARGET(UNARY_INVERT) { PyObject *value = TOP(); PyObject *res = PyNumber_Invert(value); Py_DECREF(value); SET_TOP(res); if (res == NULL) goto error; DISPATCH(); } TARGET(BINARY_OP_MULTIPLY_INT) { assert(cframe.use_tracing == 0); PyObject *left = SECOND(); PyObject *right = TOP(); DEOPT_IF(!PyLong_CheckExact(left), BINARY_OP); DEOPT_IF(!PyLong_CheckExact(right), BINARY_OP); STAT_INC(BINARY_OP, hit); PyObject *prod = _PyLong_Multiply((PyLongObject *)left, (PyLongObject *)right); SET_SECOND(prod); _Py_DECREF_SPECIALIZED(right, (destructor)PyObject_Free); _Py_DECREF_SPECIALIZED(left, (destructor)PyObject_Free); STACK_SHRINK(1); if (prod == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP); DISPATCH(); } TARGET(BINARY_OP_MULTIPLY_FLOAT) { assert(cframe.use_tracing == 0); PyObject *left = SECOND(); PyObject *right = TOP(); DEOPT_IF(!PyFloat_CheckExact(left), BINARY_OP); DEOPT_IF(!PyFloat_CheckExact(right), BINARY_OP); STAT_INC(BINARY_OP, hit); double dprod = ((PyFloatObject *)left)->ob_fval * ((PyFloatObject *)right)->ob_fval; PyObject *prod = PyFloat_FromDouble(dprod); SET_SECOND(prod); _Py_DECREF_SPECIALIZED(right, _PyFloat_ExactDealloc); _Py_DECREF_SPECIALIZED(left, _PyFloat_ExactDealloc); STACK_SHRINK(1); if (prod == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP); DISPATCH(); } TARGET(BINARY_OP_SUBTRACT_INT) { assert(cframe.use_tracing == 0); PyObject *left = SECOND(); PyObject *right = TOP(); DEOPT_IF(!PyLong_CheckExact(left), BINARY_OP); DEOPT_IF(!PyLong_CheckExact(right), BINARY_OP); STAT_INC(BINARY_OP, hit); PyObject *sub = _PyLong_Subtract((PyLongObject *)left, (PyLongObject *)right); SET_SECOND(sub); _Py_DECREF_SPECIALIZED(right, (destructor)PyObject_Free); _Py_DECREF_SPECIALIZED(left, (destructor)PyObject_Free); STACK_SHRINK(1); if (sub == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP); DISPATCH(); } TARGET(BINARY_OP_SUBTRACT_FLOAT) { assert(cframe.use_tracing == 0); PyObject *left = SECOND(); PyObject *right = TOP(); DEOPT_IF(!PyFloat_CheckExact(left), BINARY_OP); DEOPT_IF(!PyFloat_CheckExact(right), BINARY_OP); STAT_INC(BINARY_OP, hit); double dsub = ((PyFloatObject *)left)->ob_fval - ((PyFloatObject *)right)->ob_fval; PyObject *sub = PyFloat_FromDouble(dsub); SET_SECOND(sub); _Py_DECREF_SPECIALIZED(right, _PyFloat_ExactDealloc); _Py_DECREF_SPECIALIZED(left, _PyFloat_ExactDealloc); STACK_SHRINK(1); if (sub == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP); DISPATCH(); } TARGET(BINARY_OP_ADD_UNICODE) { assert(cframe.use_tracing == 0); PyObject *left = SECOND(); PyObject *right = TOP(); DEOPT_IF(!PyUnicode_CheckExact(left), BINARY_OP); DEOPT_IF(Py_TYPE(right) != Py_TYPE(left), BINARY_OP); STAT_INC(BINARY_OP, hit); PyObject *res = PyUnicode_Concat(left, right); STACK_SHRINK(1); SET_TOP(res); _Py_DECREF_SPECIALIZED(left, _PyUnicode_ExactDealloc); _Py_DECREF_SPECIALIZED(right, _PyUnicode_ExactDealloc); if (TOP() == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP); DISPATCH(); } TARGET(BINARY_OP_INPLACE_ADD_UNICODE) { assert(cframe.use_tracing == 0); PyObject *left = SECOND(); PyObject *right = TOP(); DEOPT_IF(!PyUnicode_CheckExact(left), BINARY_OP); DEOPT_IF(Py_TYPE(right) != Py_TYPE(left), BINARY_OP); _Py_CODEUNIT true_next = next_instr[INLINE_CACHE_ENTRIES_BINARY_OP]; assert(_Py_OPCODE(true_next) == STORE_FAST || _Py_OPCODE(true_next) == STORE_FAST__LOAD_FAST); PyObject **target_local = &GETLOCAL(_Py_OPARG(true_next)); DEOPT_IF(*target_local != left, BINARY_OP); STAT_INC(BINARY_OP, hit); /* Handle `left = left + right` or `left += right` for str. * * When possible, extend `left` in place rather than * allocating a new PyUnicodeObject. This attempts to avoid * quadratic behavior when one neglects to use str.join(). * * If `left` has only two references remaining (one from * the stack, one in the locals), DECREFing `left` leaves * only the locals reference, so PyUnicode_Append knows * that the string is safe to mutate. */ assert(Py_REFCNT(left) >= 2); _Py_DECREF_NO_DEALLOC(left); STACK_SHRINK(2); PyUnicode_Append(target_local, right); _Py_DECREF_SPECIALIZED(right, _PyUnicode_ExactDealloc); if (*target_local == NULL) { goto error; } // The STORE_FAST is already done. JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP + 1); DISPATCH(); } TARGET(BINARY_OP_ADD_FLOAT) { assert(cframe.use_tracing == 0); PyObject *left = SECOND(); PyObject *right = TOP(); DEOPT_IF(!PyFloat_CheckExact(left), BINARY_OP); DEOPT_IF(Py_TYPE(right) != Py_TYPE(left), BINARY_OP); STAT_INC(BINARY_OP, hit); double dsum = ((PyFloatObject *)left)->ob_fval + ((PyFloatObject *)right)->ob_fval; PyObject *sum = PyFloat_FromDouble(dsum); SET_SECOND(sum); _Py_DECREF_SPECIALIZED(right, _PyFloat_ExactDealloc); _Py_DECREF_SPECIALIZED(left, _PyFloat_ExactDealloc); STACK_SHRINK(1); if (sum == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP); DISPATCH(); } TARGET(BINARY_OP_ADD_INT) { assert(cframe.use_tracing == 0); PyObject *left = SECOND(); PyObject *right = TOP(); DEOPT_IF(!PyLong_CheckExact(left), BINARY_OP); DEOPT_IF(Py_TYPE(right) != Py_TYPE(left), BINARY_OP); STAT_INC(BINARY_OP, hit); PyObject *sum = _PyLong_Add((PyLongObject *)left, (PyLongObject *)right); SET_SECOND(sum); _Py_DECREF_SPECIALIZED(right, (destructor)PyObject_Free); _Py_DECREF_SPECIALIZED(left, (destructor)PyObject_Free); STACK_SHRINK(1); if (sum == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP); DISPATCH(); } TARGET(BINARY_SUBSCR) { PREDICTED(BINARY_SUBSCR); PyObject *sub = POP(); PyObject *container = TOP(); PyObject *res = PyObject_GetItem(container, sub); Py_DECREF(container); Py_DECREF(sub); SET_TOP(res); if (res == NULL) goto error; JUMPBY(INLINE_CACHE_ENTRIES_BINARY_SUBSCR); DISPATCH(); } TARGET(BINARY_SUBSCR_ADAPTIVE) { _PyBinarySubscrCache *cache = (_PyBinarySubscrCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *sub = TOP(); PyObject *container = SECOND(); next_instr--; if (_Py_Specialize_BinarySubscr(container, sub, next_instr) < 0) { next_instr++; goto error; } DISPATCH_SAME_OPARG(); } else { STAT_INC(BINARY_SUBSCR, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(BINARY_SUBSCR); } } TARGET(BINARY_SUBSCR_LIST_INT) { assert(cframe.use_tracing == 0); PyObject *sub = TOP(); PyObject *list = SECOND(); DEOPT_IF(!PyLong_CheckExact(sub), BINARY_SUBSCR); DEOPT_IF(!PyList_CheckExact(list), BINARY_SUBSCR); // Deopt unless 0 <= sub < PyList_Size(list) Py_ssize_t signed_magnitude = Py_SIZE(sub); DEOPT_IF(((size_t)signed_magnitude) > 1, BINARY_SUBSCR); assert(((PyLongObject *)_PyLong_GetZero())->ob_digit[0] == 0); Py_ssize_t index = ((PyLongObject*)sub)->ob_digit[0]; DEOPT_IF(index >= PyList_GET_SIZE(list), BINARY_SUBSCR); STAT_INC(BINARY_SUBSCR, hit); PyObject *res = PyList_GET_ITEM(list, index); assert(res != NULL); Py_INCREF(res); STACK_SHRINK(1); _Py_DECREF_SPECIALIZED(sub, (destructor)PyObject_Free); SET_TOP(res); Py_DECREF(list); JUMPBY(INLINE_CACHE_ENTRIES_BINARY_SUBSCR); DISPATCH(); } TARGET(BINARY_SUBSCR_TUPLE_INT) { assert(cframe.use_tracing == 0); PyObject *sub = TOP(); PyObject *tuple = SECOND(); DEOPT_IF(!PyLong_CheckExact(sub), BINARY_SUBSCR); DEOPT_IF(!PyTuple_CheckExact(tuple), BINARY_SUBSCR); // Deopt unless 0 <= sub < PyTuple_Size(list) Py_ssize_t signed_magnitude = Py_SIZE(sub); DEOPT_IF(((size_t)signed_magnitude) > 1, BINARY_SUBSCR); assert(((PyLongObject *)_PyLong_GetZero())->ob_digit[0] == 0); Py_ssize_t index = ((PyLongObject*)sub)->ob_digit[0]; DEOPT_IF(index >= PyTuple_GET_SIZE(tuple), BINARY_SUBSCR); STAT_INC(BINARY_SUBSCR, hit); PyObject *res = PyTuple_GET_ITEM(tuple, index); assert(res != NULL); Py_INCREF(res); STACK_SHRINK(1); _Py_DECREF_SPECIALIZED(sub, (destructor)PyObject_Free); SET_TOP(res); Py_DECREF(tuple); JUMPBY(INLINE_CACHE_ENTRIES_BINARY_SUBSCR); DISPATCH(); } TARGET(BINARY_SUBSCR_DICT) { assert(cframe.use_tracing == 0); PyObject *dict = SECOND(); DEOPT_IF(!PyDict_CheckExact(SECOND()), BINARY_SUBSCR); STAT_INC(BINARY_SUBSCR, hit); PyObject *sub = TOP(); PyObject *res = PyDict_GetItemWithError(dict, sub); if (res == NULL) { goto binary_subscr_dict_error; } Py_INCREF(res); STACK_SHRINK(1); Py_DECREF(sub); SET_TOP(res); Py_DECREF(dict); JUMPBY(INLINE_CACHE_ENTRIES_BINARY_SUBSCR); DISPATCH(); } TARGET(BINARY_SUBSCR_GETITEM) { DEOPT_IF(tstate->interp->eval_frame, BINARY_SUBSCR); PyObject *sub = TOP(); PyObject *container = SECOND(); _PyBinarySubscrCache *cache = (_PyBinarySubscrCache *)next_instr; uint32_t type_version = read_u32(cache->type_version); PyTypeObject *tp = Py_TYPE(container); DEOPT_IF(tp->tp_version_tag != type_version, BINARY_SUBSCR); assert(tp->tp_flags & Py_TPFLAGS_HEAPTYPE); PyObject *cached = ((PyHeapTypeObject *)tp)->_spec_cache.getitem; assert(PyFunction_Check(cached)); PyFunctionObject *getitem = (PyFunctionObject *)cached; DEOPT_IF(getitem->func_version != cache->func_version, BINARY_SUBSCR); PyCodeObject *code = (PyCodeObject *)getitem->func_code; size_t size = code->co_nlocalsplus + code->co_stacksize + FRAME_SPECIALS_SIZE; assert(code->co_argcount == 2); _PyInterpreterFrame *new_frame = _PyThreadState_BumpFramePointer(tstate, size); if (new_frame == NULL) { goto error; } CALL_STAT_INC(frames_pushed); Py_INCREF(getitem); _PyFrame_InitializeSpecials(new_frame, getitem, NULL, code->co_nlocalsplus); STACK_SHRINK(2); new_frame->localsplus[0] = container; new_frame->localsplus[1] = sub; for (int i = 2; i < code->co_nlocalsplus; i++) { new_frame->localsplus[i] = NULL; } _PyFrame_SetStackPointer(frame, stack_pointer); JUMPBY(INLINE_CACHE_ENTRIES_BINARY_SUBSCR); frame->prev_instr = next_instr - 1; new_frame->previous = frame; frame = cframe.current_frame = new_frame; CALL_STAT_INC(inlined_py_calls); goto start_frame; } TARGET(LIST_APPEND) { PyObject *v = POP(); PyObject *list = PEEK(oparg); if (_PyList_AppendTakeRef((PyListObject *)list, v) < 0) goto error; PREDICT(JUMP_BACKWARD_QUICK); DISPATCH(); } TARGET(SET_ADD) { PyObject *v = POP(); PyObject *set = PEEK(oparg); int err; err = PySet_Add(set, v); Py_DECREF(v); if (err != 0) goto error; PREDICT(JUMP_BACKWARD_QUICK); DISPATCH(); } TARGET(STORE_SUBSCR) { PREDICTED(STORE_SUBSCR); PyObject *sub = TOP(); PyObject *container = SECOND(); PyObject *v = THIRD(); int err; STACK_SHRINK(3); /* container[sub] = v */ err = PyObject_SetItem(container, sub, v); Py_DECREF(v); Py_DECREF(container); Py_DECREF(sub); if (err != 0) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_STORE_SUBSCR); DISPATCH(); } TARGET(STORE_SUBSCR_ADAPTIVE) { _PyStoreSubscrCache *cache = (_PyStoreSubscrCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *sub = TOP(); PyObject *container = SECOND(); next_instr--; if (_Py_Specialize_StoreSubscr(container, sub, next_instr) < 0) { next_instr++; goto error; } DISPATCH_SAME_OPARG(); } else { STAT_INC(STORE_SUBSCR, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(STORE_SUBSCR); } } TARGET(STORE_SUBSCR_LIST_INT) { assert(cframe.use_tracing == 0); PyObject *sub = TOP(); PyObject *list = SECOND(); PyObject *value = THIRD(); DEOPT_IF(!PyLong_CheckExact(sub), STORE_SUBSCR); DEOPT_IF(!PyList_CheckExact(list), STORE_SUBSCR); // Ensure nonnegative, zero-or-one-digit ints. DEOPT_IF(((size_t)Py_SIZE(sub)) > 1, STORE_SUBSCR); Py_ssize_t index = ((PyLongObject*)sub)->ob_digit[0]; // Ensure index < len(list) DEOPT_IF(index >= PyList_GET_SIZE(list), STORE_SUBSCR); STAT_INC(STORE_SUBSCR, hit); PyObject *old_value = PyList_GET_ITEM(list, index); PyList_SET_ITEM(list, index, value); STACK_SHRINK(3); assert(old_value != NULL); Py_DECREF(old_value); _Py_DECREF_SPECIALIZED(sub, (destructor)PyObject_Free); Py_DECREF(list); JUMPBY(INLINE_CACHE_ENTRIES_STORE_SUBSCR); DISPATCH(); } TARGET(STORE_SUBSCR_DICT) { assert(cframe.use_tracing == 0); PyObject *sub = TOP(); PyObject *dict = SECOND(); PyObject *value = THIRD(); DEOPT_IF(!PyDict_CheckExact(dict), STORE_SUBSCR); STACK_SHRINK(3); STAT_INC(STORE_SUBSCR, hit); int err = _PyDict_SetItem_Take2((PyDictObject *)dict, sub, value); Py_DECREF(dict); if (err != 0) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_STORE_SUBSCR); DISPATCH(); } TARGET(DELETE_SUBSCR) { PyObject *sub = TOP(); PyObject *container = SECOND(); int err; STACK_SHRINK(2); /* del container[sub] */ err = PyObject_DelItem(container, sub); Py_DECREF(container); Py_DECREF(sub); if (err != 0) goto error; DISPATCH(); } TARGET(PRINT_EXPR) { PyObject *value = POP(); PyObject *hook = _PySys_GetAttr(tstate, &_Py_ID(displayhook)); PyObject *res; if (hook == NULL) { _PyErr_SetString(tstate, PyExc_RuntimeError, "lost sys.displayhook"); Py_DECREF(value); goto error; } res = PyObject_CallOneArg(hook, value); Py_DECREF(value); if (res == NULL) goto error; Py_DECREF(res); DISPATCH(); } TARGET(RAISE_VARARGS) { PyObject *cause = NULL, *exc = NULL; switch (oparg) { case 2: cause = POP(); /* cause */ /* fall through */ case 1: exc = POP(); /* exc */ /* fall through */ case 0: if (do_raise(tstate, exc, cause)) { goto exception_unwind; } break; default: _PyErr_SetString(tstate, PyExc_SystemError, "bad RAISE_VARARGS oparg"); break; } goto error; } TARGET(RETURN_VALUE) { PyObject *retval = POP(); assert(EMPTY()); _PyFrame_SetStackPointer(frame, stack_pointer); TRACE_FUNCTION_EXIT(); DTRACE_FUNCTION_EXIT(); _Py_LeaveRecursiveCallTstate(tstate); if (!frame->is_entry) { // GH-99729: We need to unlink the frame *before* clearing it: _PyInterpreterFrame *dying = frame; frame = cframe.current_frame = dying->previous; _PyEvalFrameClearAndPop(tstate, dying); _PyFrame_StackPush(frame, retval); goto resume_frame; } /* Restore previous cframe and return. */ tstate->cframe = cframe.previous; tstate->cframe->use_tracing = cframe.use_tracing; assert(tstate->cframe->current_frame == frame->previous); assert(!_PyErr_Occurred(tstate)); return retval; } TARGET(GET_AITER) { unaryfunc getter = NULL; PyObject *iter = NULL; PyObject *obj = TOP(); PyTypeObject *type = Py_TYPE(obj); if (type->tp_as_async != NULL) { getter = type->tp_as_async->am_aiter; } if (getter != NULL) { iter = (*getter)(obj); Py_DECREF(obj); if (iter == NULL) { SET_TOP(NULL); goto error; } } else { SET_TOP(NULL); _PyErr_Format(tstate, PyExc_TypeError, "'async for' requires an object with " "__aiter__ method, got %.100s", type->tp_name); Py_DECREF(obj); goto error; } if (Py_TYPE(iter)->tp_as_async == NULL || Py_TYPE(iter)->tp_as_async->am_anext == NULL) { SET_TOP(NULL); _PyErr_Format(tstate, PyExc_TypeError, "'async for' received an object from __aiter__ " "that does not implement __anext__: %.100s", Py_TYPE(iter)->tp_name); Py_DECREF(iter); goto error; } SET_TOP(iter); DISPATCH(); } TARGET(GET_ANEXT) { unaryfunc getter = NULL; PyObject *next_iter = NULL; PyObject *awaitable = NULL; PyObject *aiter = TOP(); PyTypeObject *type = Py_TYPE(aiter); if (PyAsyncGen_CheckExact(aiter)) { awaitable = type->tp_as_async->am_anext(aiter); if (awaitable == NULL) { goto error; } } else { if (type->tp_as_async != NULL){ getter = type->tp_as_async->am_anext; } if (getter != NULL) { next_iter = (*getter)(aiter); if (next_iter == NULL) { goto error; } } else { _PyErr_Format(tstate, PyExc_TypeError, "'async for' requires an iterator with " "__anext__ method, got %.100s", type->tp_name); goto error; } awaitable = _PyCoro_GetAwaitableIter(next_iter); if (awaitable == NULL) { _PyErr_FormatFromCause( PyExc_TypeError, "'async for' received an invalid object " "from __anext__: %.100s", Py_TYPE(next_iter)->tp_name); Py_DECREF(next_iter); goto error; } else { Py_DECREF(next_iter); } } PUSH(awaitable); PREDICT(LOAD_CONST); DISPATCH(); } TARGET(GET_AWAITABLE) { PREDICTED(GET_AWAITABLE); PyObject *iterable = TOP(); PyObject *iter = _PyCoro_GetAwaitableIter(iterable); if (iter == NULL) { format_awaitable_error(tstate, Py_TYPE(iterable), oparg); } Py_DECREF(iterable); if (iter != NULL && PyCoro_CheckExact(iter)) { PyObject *yf = _PyGen_yf((PyGenObject*)iter); if (yf != NULL) { /* `iter` is a coroutine object that is being awaited, `yf` is a pointer to the current awaitable being awaited on. */ Py_DECREF(yf); Py_CLEAR(iter); _PyErr_SetString(tstate, PyExc_RuntimeError, "coroutine is being awaited already"); /* The code below jumps to `error` if `iter` is NULL. */ } } SET_TOP(iter); /* Even if it's NULL */ if (iter == NULL) { goto error; } PREDICT(LOAD_CONST); DISPATCH(); } TARGET(SEND) { assert(frame->is_entry); assert(STACK_LEVEL() >= 2); PyObject *v = POP(); PyObject *receiver = TOP(); PySendResult gen_status; PyObject *retval; if (tstate->c_tracefunc == NULL) { gen_status = PyIter_Send(receiver, v, &retval); } else { if (Py_IsNone(v) && PyIter_Check(receiver)) { retval = Py_TYPE(receiver)->tp_iternext(receiver); } else { retval = PyObject_CallMethodOneArg(receiver, &_Py_ID(send), v); } if (retval == NULL) { if (tstate->c_tracefunc != NULL && _PyErr_ExceptionMatches(tstate, PyExc_StopIteration)) call_exc_trace(tstate->c_tracefunc, tstate->c_traceobj, tstate, frame); if (_PyGen_FetchStopIterationValue(&retval) == 0) { gen_status = PYGEN_RETURN; } else { gen_status = PYGEN_ERROR; } } else { gen_status = PYGEN_NEXT; } } Py_DECREF(v); if (gen_status == PYGEN_ERROR) { assert(retval == NULL); goto error; } if (gen_status == PYGEN_RETURN) { assert(retval != NULL); Py_DECREF(receiver); SET_TOP(retval); JUMPBY(oparg); DISPATCH(); } assert(gen_status == PYGEN_NEXT); assert(retval != NULL); PUSH(retval); DISPATCH(); } TARGET(ASYNC_GEN_WRAP) { PyObject *v = TOP(); assert(frame->f_code->co_flags & CO_ASYNC_GENERATOR); PyObject *w = _PyAsyncGenValueWrapperNew(v); if (w == NULL) { goto error; } SET_TOP(w); Py_DECREF(v); DISPATCH(); } TARGET(YIELD_VALUE) { assert(frame->is_entry); PyObject *retval = POP(); _PyFrame_GetGenerator(frame)->gi_frame_state = FRAME_SUSPENDED; _PyFrame_SetStackPointer(frame, stack_pointer); TRACE_FUNCTION_EXIT(); DTRACE_FUNCTION_EXIT(); _Py_LeaveRecursiveCallTstate(tstate); /* Restore previous cframe and return. */ tstate->cframe = cframe.previous; tstate->cframe->use_tracing = cframe.use_tracing; assert(tstate->cframe->current_frame == frame->previous); assert(!_PyErr_Occurred(tstate)); return retval; } TARGET(POP_EXCEPT) { _PyErr_StackItem *exc_info = tstate->exc_info; PyObject *value = exc_info->exc_value; exc_info->exc_value = POP(); Py_XDECREF(value); DISPATCH(); } TARGET(RERAISE) { if (oparg) { PyObject *lasti = PEEK(oparg + 1); if (PyLong_Check(lasti)) { frame->prev_instr = first_instr + PyLong_AsLong(lasti); assert(!_PyErr_Occurred(tstate)); } else { assert(PyLong_Check(lasti)); _PyErr_SetString(tstate, PyExc_SystemError, "lasti is not an int"); goto error; } } PyObject *val = POP(); assert(val && PyExceptionInstance_Check(val)); PyObject *exc = Py_NewRef(PyExceptionInstance_Class(val)); PyObject *tb = PyException_GetTraceback(val); _PyErr_Restore(tstate, exc, val, tb); goto exception_unwind; } TARGET(PREP_RERAISE_STAR) { PyObject *excs = POP(); assert(PyList_Check(excs)); PyObject *orig = POP(); PyObject *val = _PyExc_PrepReraiseStar(orig, excs); Py_DECREF(excs); Py_DECREF(orig); if (val == NULL) { goto error; } PUSH(val); DISPATCH(); } TARGET(END_ASYNC_FOR) { PyObject *val = POP(); assert(val && PyExceptionInstance_Check(val)); if (PyErr_GivenExceptionMatches(val, PyExc_StopAsyncIteration)) { Py_DECREF(val); Py_DECREF(POP()); DISPATCH(); } else { PyObject *exc = Py_NewRef(PyExceptionInstance_Class(val)); PyObject *tb = PyException_GetTraceback(val); _PyErr_Restore(tstate, exc, val, tb); goto exception_unwind; } } TARGET(LOAD_ASSERTION_ERROR) { PyObject *value = PyExc_AssertionError; Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(LOAD_BUILD_CLASS) { PyObject *bc; if (PyDict_CheckExact(BUILTINS())) { bc = _PyDict_GetItemWithError(BUILTINS(), &_Py_ID(__build_class__)); if (bc == NULL) { if (!_PyErr_Occurred(tstate)) { _PyErr_SetString(tstate, PyExc_NameError, "__build_class__ not found"); } goto error; } Py_INCREF(bc); } else { bc = PyObject_GetItem(BUILTINS(), &_Py_ID(__build_class__)); if (bc == NULL) { if (_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) _PyErr_SetString(tstate, PyExc_NameError, "__build_class__ not found"); goto error; } } PUSH(bc); DISPATCH(); } TARGET(STORE_NAME) { PyObject *name = GETITEM(names, oparg); PyObject *v = POP(); PyObject *ns = LOCALS(); int err; if (ns == NULL) { _PyErr_Format(tstate, PyExc_SystemError, "no locals found when storing %R", name); Py_DECREF(v); goto error; } if (PyDict_CheckExact(ns)) err = PyDict_SetItem(ns, name, v); else err = PyObject_SetItem(ns, name, v); Py_DECREF(v); if (err != 0) goto error; DISPATCH(); } TARGET(DELETE_NAME) { PyObject *name = GETITEM(names, oparg); PyObject *ns = LOCALS(); int err; if (ns == NULL) { _PyErr_Format(tstate, PyExc_SystemError, "no locals when deleting %R", name); goto error; } err = PyObject_DelItem(ns, name); if (err != 0) { format_exc_check_arg(tstate, PyExc_NameError, NAME_ERROR_MSG, name); goto error; } DISPATCH(); } TARGET(UNPACK_SEQUENCE) { PREDICTED(UNPACK_SEQUENCE); PyObject *seq = POP(); PyObject **top = stack_pointer + oparg; if (!unpack_iterable(tstate, seq, oparg, -1, top)) { Py_DECREF(seq); goto error; } STACK_GROW(oparg); Py_DECREF(seq); JUMPBY(INLINE_CACHE_ENTRIES_UNPACK_SEQUENCE); DISPATCH(); } TARGET(UNPACK_SEQUENCE_ADAPTIVE) { assert(cframe.use_tracing == 0); _PyUnpackSequenceCache *cache = (_PyUnpackSequenceCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *seq = TOP(); next_instr--; _Py_Specialize_UnpackSequence(seq, next_instr, oparg); DISPATCH_SAME_OPARG(); } else { STAT_INC(UNPACK_SEQUENCE, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(UNPACK_SEQUENCE); } } TARGET(UNPACK_SEQUENCE_TWO_TUPLE) { PyObject *seq = TOP(); DEOPT_IF(!PyTuple_CheckExact(seq), UNPACK_SEQUENCE); DEOPT_IF(PyTuple_GET_SIZE(seq) != 2, UNPACK_SEQUENCE); STAT_INC(UNPACK_SEQUENCE, hit); SET_TOP(Py_NewRef(PyTuple_GET_ITEM(seq, 1))); PUSH(Py_NewRef(PyTuple_GET_ITEM(seq, 0))); Py_DECREF(seq); JUMPBY(INLINE_CACHE_ENTRIES_UNPACK_SEQUENCE); DISPATCH(); } TARGET(UNPACK_SEQUENCE_TUPLE) { PyObject *seq = TOP(); DEOPT_IF(!PyTuple_CheckExact(seq), UNPACK_SEQUENCE); DEOPT_IF(PyTuple_GET_SIZE(seq) != oparg, UNPACK_SEQUENCE); STAT_INC(UNPACK_SEQUENCE, hit); STACK_SHRINK(1); PyObject **items = _PyTuple_ITEMS(seq); while (oparg--) { PUSH(Py_NewRef(items[oparg])); } Py_DECREF(seq); JUMPBY(INLINE_CACHE_ENTRIES_UNPACK_SEQUENCE); DISPATCH(); } TARGET(UNPACK_SEQUENCE_LIST) { PyObject *seq = TOP(); DEOPT_IF(!PyList_CheckExact(seq), UNPACK_SEQUENCE); DEOPT_IF(PyList_GET_SIZE(seq) != oparg, UNPACK_SEQUENCE); STAT_INC(UNPACK_SEQUENCE, hit); STACK_SHRINK(1); PyObject **items = _PyList_ITEMS(seq); while (oparg--) { PUSH(Py_NewRef(items[oparg])); } Py_DECREF(seq); JUMPBY(INLINE_CACHE_ENTRIES_UNPACK_SEQUENCE); DISPATCH(); } TARGET(UNPACK_EX) { int totalargs = 1 + (oparg & 0xFF) + (oparg >> 8); PyObject *seq = POP(); PyObject **top = stack_pointer + totalargs; if (!unpack_iterable(tstate, seq, oparg & 0xFF, oparg >> 8, top)) { Py_DECREF(seq); goto error; } STACK_GROW(totalargs); Py_DECREF(seq); DISPATCH(); } TARGET(STORE_ATTR) { PREDICTED(STORE_ATTR); PyObject *name = GETITEM(names, oparg); PyObject *owner = TOP(); PyObject *v = SECOND(); int err; STACK_SHRINK(2); err = PyObject_SetAttr(owner, name, v); Py_DECREF(v); Py_DECREF(owner); if (err != 0) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_STORE_ATTR); DISPATCH(); } TARGET(DELETE_ATTR) { PyObject *name = GETITEM(names, oparg); PyObject *owner = POP(); int err; err = PyObject_SetAttr(owner, name, (PyObject *)NULL); Py_DECREF(owner); if (err != 0) goto error; DISPATCH(); } TARGET(STORE_GLOBAL) { PyObject *name = GETITEM(names, oparg); PyObject *v = POP(); int err; err = PyDict_SetItem(GLOBALS(), name, v); Py_DECREF(v); if (err != 0) goto error; DISPATCH(); } TARGET(DELETE_GLOBAL) { PyObject *name = GETITEM(names, oparg); int err; err = PyDict_DelItem(GLOBALS(), name); if (err != 0) { if (_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) { format_exc_check_arg(tstate, PyExc_NameError, NAME_ERROR_MSG, name); } goto error; } DISPATCH(); } TARGET(LOAD_NAME) { PyObject *name = GETITEM(names, oparg); PyObject *locals = LOCALS(); PyObject *v; if (locals == NULL) { _PyErr_Format(tstate, PyExc_SystemError, "no locals when loading %R", name); goto error; } if (PyDict_CheckExact(locals)) { v = PyDict_GetItemWithError(locals, name); if (v != NULL) { Py_INCREF(v); } else if (_PyErr_Occurred(tstate)) { goto error; } } else { v = PyObject_GetItem(locals, name); if (v == NULL) { if (!_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) goto error; _PyErr_Clear(tstate); } } if (v == NULL) { v = PyDict_GetItemWithError(GLOBALS(), name); if (v != NULL) { Py_INCREF(v); } else if (_PyErr_Occurred(tstate)) { goto error; } else { if (PyDict_CheckExact(BUILTINS())) { v = PyDict_GetItemWithError(BUILTINS(), name); if (v == NULL) { if (!_PyErr_Occurred(tstate)) { format_exc_check_arg( tstate, PyExc_NameError, NAME_ERROR_MSG, name); } goto error; } Py_INCREF(v); } else { v = PyObject_GetItem(BUILTINS(), name); if (v == NULL) { if (_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) { format_exc_check_arg( tstate, PyExc_NameError, NAME_ERROR_MSG, name); } goto error; } } } } PUSH(v); DISPATCH(); } TARGET(LOAD_GLOBAL) { PREDICTED(LOAD_GLOBAL); int push_null = oparg & 1; PEEK(0) = NULL; PyObject *name = GETITEM(names, oparg>>1); PyObject *v; if (PyDict_CheckExact(GLOBALS()) && PyDict_CheckExact(BUILTINS())) { v = _PyDict_LoadGlobal((PyDictObject *)GLOBALS(), (PyDictObject *)BUILTINS(), name); if (v == NULL) { if (!_PyErr_Occurred(tstate)) { /* _PyDict_LoadGlobal() returns NULL without raising * an exception if the key doesn't exist */ format_exc_check_arg(tstate, PyExc_NameError, NAME_ERROR_MSG, name); } goto error; } Py_INCREF(v); } else { /* Slow-path if globals or builtins is not a dict */ /* namespace 1: globals */ v = PyObject_GetItem(GLOBALS(), name); if (v == NULL) { if (!_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) { goto error; } _PyErr_Clear(tstate); /* namespace 2: builtins */ v = PyObject_GetItem(BUILTINS(), name); if (v == NULL) { if (_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) { format_exc_check_arg( tstate, PyExc_NameError, NAME_ERROR_MSG, name); } goto error; } } } /* Skip over inline cache */ JUMPBY(INLINE_CACHE_ENTRIES_LOAD_GLOBAL); STACK_GROW(push_null); PUSH(v); DISPATCH(); } TARGET(LOAD_GLOBAL_ADAPTIVE) { assert(cframe.use_tracing == 0); _PyLoadGlobalCache *cache = (_PyLoadGlobalCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *name = GETITEM(names, oparg>>1); next_instr--; if (_Py_Specialize_LoadGlobal(GLOBALS(), BUILTINS(), next_instr, name) < 0) { next_instr++; goto error; } DISPATCH_SAME_OPARG(); } else { STAT_INC(LOAD_GLOBAL, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(LOAD_GLOBAL); } } TARGET(LOAD_GLOBAL_MODULE) { assert(cframe.use_tracing == 0); DEOPT_IF(!PyDict_CheckExact(GLOBALS()), LOAD_GLOBAL); PyDictObject *dict = (PyDictObject *)GLOBALS(); _PyLoadGlobalCache *cache = (_PyLoadGlobalCache *)next_instr; uint32_t version = read_u32(cache->module_keys_version); DEOPT_IF(dict->ma_keys->dk_version != version, LOAD_GLOBAL); assert(DK_IS_UNICODE(dict->ma_keys)); PyDictUnicodeEntry *entries = DK_UNICODE_ENTRIES(dict->ma_keys); PyObject *res = entries[cache->index].me_value; DEOPT_IF(res == NULL, LOAD_GLOBAL); int push_null = oparg & 1; PEEK(0) = NULL; JUMPBY(INLINE_CACHE_ENTRIES_LOAD_GLOBAL); STAT_INC(LOAD_GLOBAL, hit); STACK_GROW(push_null+1); Py_INCREF(res); SET_TOP(res); DISPATCH(); } TARGET(LOAD_GLOBAL_BUILTIN) { assert(cframe.use_tracing == 0); DEOPT_IF(!PyDict_CheckExact(GLOBALS()), LOAD_GLOBAL); DEOPT_IF(!PyDict_CheckExact(BUILTINS()), LOAD_GLOBAL); PyDictObject *mdict = (PyDictObject *)GLOBALS(); PyDictObject *bdict = (PyDictObject *)BUILTINS(); _PyLoadGlobalCache *cache = (_PyLoadGlobalCache *)next_instr; uint32_t mod_version = read_u32(cache->module_keys_version); uint16_t bltn_version = cache->builtin_keys_version; DEOPT_IF(mdict->ma_keys->dk_version != mod_version, LOAD_GLOBAL); DEOPT_IF(bdict->ma_keys->dk_version != bltn_version, LOAD_GLOBAL); assert(DK_IS_UNICODE(bdict->ma_keys)); PyDictUnicodeEntry *entries = DK_UNICODE_ENTRIES(bdict->ma_keys); PyObject *res = entries[cache->index].me_value; DEOPT_IF(res == NULL, LOAD_GLOBAL); int push_null = oparg & 1; PEEK(0) = NULL; JUMPBY(INLINE_CACHE_ENTRIES_LOAD_GLOBAL); STAT_INC(LOAD_GLOBAL, hit); STACK_GROW(push_null+1); Py_INCREF(res); SET_TOP(res); DISPATCH(); } TARGET(DELETE_FAST) { PyObject *v = GETLOCAL(oparg); if (v != NULL) { SETLOCAL(oparg, NULL); DISPATCH(); } goto unbound_local_error; } TARGET(MAKE_CELL) { // "initial" is probably NULL but not if it's an arg (or set // via PyFrame_LocalsToFast() before MAKE_CELL has run). PyObject *initial = GETLOCAL(oparg); PyObject *cell = PyCell_New(initial); if (cell == NULL) { goto resume_with_error; } SETLOCAL(oparg, cell); DISPATCH(); } TARGET(DELETE_DEREF) { PyObject *cell = GETLOCAL(oparg); PyObject *oldobj = PyCell_GET(cell); if (oldobj != NULL) { PyCell_SET(cell, NULL); Py_DECREF(oldobj); DISPATCH(); } format_exc_unbound(tstate, frame->f_code, oparg); goto error; } TARGET(LOAD_CLASSDEREF) { PyObject *name, *value, *locals = LOCALS(); assert(locals); assert(oparg >= 0 && oparg < frame->f_code->co_nlocalsplus); name = PyTuple_GET_ITEM(frame->f_code->co_localsplusnames, oparg); if (PyDict_CheckExact(locals)) { value = PyDict_GetItemWithError(locals, name); if (value != NULL) { Py_INCREF(value); } else if (_PyErr_Occurred(tstate)) { goto error; } } else { value = PyObject_GetItem(locals, name); if (value == NULL) { if (!_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) { goto error; } _PyErr_Clear(tstate); } } if (!value) { PyObject *cell = GETLOCAL(oparg); value = PyCell_GET(cell); if (value == NULL) { format_exc_unbound(tstate, frame->f_code, oparg); goto error; } Py_INCREF(value); } PUSH(value); DISPATCH(); } TARGET(LOAD_DEREF) { PyObject *cell = GETLOCAL(oparg); PyObject *value = PyCell_GET(cell); if (value == NULL) { format_exc_unbound(tstate, frame->f_code, oparg); goto error; } Py_INCREF(value); PUSH(value); DISPATCH(); } TARGET(STORE_DEREF) { PyObject *v = POP(); PyObject *cell = GETLOCAL(oparg); PyObject *oldobj = PyCell_GET(cell); PyCell_SET(cell, v); Py_XDECREF(oldobj); DISPATCH(); } TARGET(COPY_FREE_VARS) { /* Copy closure variables to free variables */ PyCodeObject *co = frame->f_code; PyObject *closure = frame->f_func->func_closure; int offset = co->co_nlocals + co->co_nplaincellvars; assert(oparg == co->co_nfreevars); for (int i = 0; i < oparg; ++i) { PyObject *o = PyTuple_GET_ITEM(closure, i); Py_INCREF(o); frame->localsplus[offset + i] = o; } DISPATCH(); } TARGET(BUILD_STRING) { PyObject *str; str = _PyUnicode_JoinArray(&_Py_STR(empty), stack_pointer - oparg, oparg); if (str == NULL) goto error; while (--oparg >= 0) { PyObject *item = POP(); Py_DECREF(item); } PUSH(str); DISPATCH(); } TARGET(BUILD_TUPLE) { PyObject *tup = PyTuple_New(oparg); if (tup == NULL) goto error; while (--oparg >= 0) { PyObject *item = POP(); PyTuple_SET_ITEM(tup, oparg, item); } PUSH(tup); DISPATCH(); } TARGET(BUILD_LIST) { PyObject *list = PyList_New(oparg); if (list == NULL) goto error; while (--oparg >= 0) { PyObject *item = POP(); PyList_SET_ITEM(list, oparg, item); } PUSH(list); DISPATCH(); } TARGET(LIST_TO_TUPLE) { PyObject *list = POP(); PyObject *tuple = PyList_AsTuple(list); Py_DECREF(list); if (tuple == NULL) { goto error; } PUSH(tuple); DISPATCH(); } TARGET(LIST_EXTEND) { PyObject *iterable = POP(); PyObject *list = PEEK(oparg); PyObject *none_val = _PyList_Extend((PyListObject *)list, iterable); if (none_val == NULL) { if (_PyErr_ExceptionMatches(tstate, PyExc_TypeError) && (Py_TYPE(iterable)->tp_iter == NULL && !PySequence_Check(iterable))) { _PyErr_Clear(tstate); _PyErr_Format(tstate, PyExc_TypeError, "Value after * must be an iterable, not %.200s", Py_TYPE(iterable)->tp_name); } Py_DECREF(iterable); goto error; } Py_DECREF(none_val); Py_DECREF(iterable); DISPATCH(); } TARGET(SET_UPDATE) { PyObject *iterable = POP(); PyObject *set = PEEK(oparg); int err = _PySet_Update(set, iterable); Py_DECREF(iterable); if (err < 0) { goto error; } DISPATCH(); } TARGET(BUILD_SET) { PyObject *set = PySet_New(NULL); int err = 0; int i; if (set == NULL) goto error; for (i = oparg; i > 0; i--) { PyObject *item = PEEK(i); if (err == 0) err = PySet_Add(set, item); Py_DECREF(item); } STACK_SHRINK(oparg); if (err != 0) { Py_DECREF(set); goto error; } PUSH(set); DISPATCH(); } TARGET(BUILD_MAP) { PyObject *map = _PyDict_FromItems( &PEEK(2*oparg), 2, &PEEK(2*oparg - 1), 2, oparg); if (map == NULL) goto error; while (oparg--) { Py_DECREF(POP()); Py_DECREF(POP()); } PUSH(map); DISPATCH(); } TARGET(SETUP_ANNOTATIONS) { int err; PyObject *ann_dict; if (LOCALS() == NULL) { _PyErr_Format(tstate, PyExc_SystemError, "no locals found when setting up annotations"); goto error; } /* check if __annotations__ in locals()... */ if (PyDict_CheckExact(LOCALS())) { ann_dict = _PyDict_GetItemWithError(LOCALS(), &_Py_ID(__annotations__)); if (ann_dict == NULL) { if (_PyErr_Occurred(tstate)) { goto error; } /* ...if not, create a new one */ ann_dict = PyDict_New(); if (ann_dict == NULL) { goto error; } err = PyDict_SetItem(LOCALS(), &_Py_ID(__annotations__), ann_dict); Py_DECREF(ann_dict); if (err != 0) { goto error; } } } else { /* do the same if locals() is not a dict */ ann_dict = PyObject_GetItem(LOCALS(), &_Py_ID(__annotations__)); if (ann_dict == NULL) { if (!_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) { goto error; } _PyErr_Clear(tstate); ann_dict = PyDict_New(); if (ann_dict == NULL) { goto error; } err = PyObject_SetItem(LOCALS(), &_Py_ID(__annotations__), ann_dict); Py_DECREF(ann_dict); if (err != 0) { goto error; } } else { Py_DECREF(ann_dict); } } DISPATCH(); } TARGET(BUILD_CONST_KEY_MAP) { PyObject *map; PyObject *keys = TOP(); if (!PyTuple_CheckExact(keys) || PyTuple_GET_SIZE(keys) != (Py_ssize_t)oparg) { _PyErr_SetString(tstate, PyExc_SystemError, "bad BUILD_CONST_KEY_MAP keys argument"); goto error; } map = _PyDict_FromItems( &PyTuple_GET_ITEM(keys, 0), 1, &PEEK(oparg + 1), 1, oparg); if (map == NULL) { goto error; } Py_DECREF(POP()); while (oparg--) { Py_DECREF(POP()); } PUSH(map); DISPATCH(); } TARGET(DICT_UPDATE) { PyObject *update = POP(); PyObject *dict = PEEK(oparg); if (PyDict_Update(dict, update) < 0) { if (_PyErr_ExceptionMatches(tstate, PyExc_AttributeError)) { _PyErr_Format(tstate, PyExc_TypeError, "'%.200s' object is not a mapping", Py_TYPE(update)->tp_name); } Py_DECREF(update); goto error; } Py_DECREF(update); DISPATCH(); } TARGET(DICT_MERGE) { PyObject *update = POP(); PyObject *dict = PEEK(oparg); if (_PyDict_MergeEx(dict, update, 2) < 0) { format_kwargs_error(tstate, PEEK(2 + oparg), update); Py_DECREF(update); goto error; } Py_DECREF(update); PREDICT(CALL_FUNCTION_EX); DISPATCH(); } TARGET(MAP_ADD) { PyObject *value = TOP(); PyObject *key = SECOND(); PyObject *map; STACK_SHRINK(2); map = PEEK(oparg); /* dict */ assert(PyDict_CheckExact(map)); /* map[key] = value */ if (_PyDict_SetItem_Take2((PyDictObject *)map, key, value) != 0) { goto error; } PREDICT(JUMP_BACKWARD_QUICK); DISPATCH(); } TARGET(LOAD_ATTR) { PREDICTED(LOAD_ATTR); PyObject *name = GETITEM(names, oparg); PyObject *owner = TOP(); PyObject *res = PyObject_GetAttr(owner, name); if (res == NULL) { goto error; } Py_DECREF(owner); SET_TOP(res); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_ATTR); DISPATCH(); } TARGET(LOAD_ATTR_ADAPTIVE) { assert(cframe.use_tracing == 0); _PyAttrCache *cache = (_PyAttrCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *owner = TOP(); PyObject *name = GETITEM(names, oparg); next_instr--; if (_Py_Specialize_LoadAttr(owner, next_instr, name) < 0) { next_instr++; goto error; } DISPATCH_SAME_OPARG(); } else { STAT_INC(LOAD_ATTR, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(LOAD_ATTR); } } TARGET(LOAD_ATTR_INSTANCE_VALUE) { assert(cframe.use_tracing == 0); PyObject *owner = TOP(); PyObject *res; PyTypeObject *tp = Py_TYPE(owner); _PyAttrCache *cache = (_PyAttrCache *)next_instr; uint32_t type_version = read_u32(cache->version); assert(type_version != 0); DEOPT_IF(tp->tp_version_tag != type_version, LOAD_ATTR); assert(tp->tp_dictoffset < 0); assert(tp->tp_flags & Py_TPFLAGS_MANAGED_DICT); PyDictValues *values = *_PyObject_ValuesPointer(owner); DEOPT_IF(values == NULL, LOAD_ATTR); res = values->values[cache->index]; DEOPT_IF(res == NULL, LOAD_ATTR); STAT_INC(LOAD_ATTR, hit); Py_INCREF(res); SET_TOP(res); Py_DECREF(owner); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_ATTR); DISPATCH(); } TARGET(LOAD_ATTR_MODULE) { assert(cframe.use_tracing == 0); // shared with LOAD_METHOD_MODULE PyObject *owner = TOP(); PyObject *res; LOAD_MODULE_ATTR_OR_METHOD(ATTR); SET_TOP(res); Py_DECREF(owner); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_ATTR); DISPATCH(); } TARGET(LOAD_ATTR_WITH_HINT) { assert(cframe.use_tracing == 0); PyObject *owner = TOP(); PyObject *res; PyTypeObject *tp = Py_TYPE(owner); _PyAttrCache *cache = (_PyAttrCache *)next_instr; uint32_t type_version = read_u32(cache->version); assert(type_version != 0); DEOPT_IF(tp->tp_version_tag != type_version, LOAD_ATTR); assert(tp->tp_flags & Py_TPFLAGS_MANAGED_DICT); PyDictObject *dict = *(PyDictObject **)_PyObject_ManagedDictPointer(owner); DEOPT_IF(dict == NULL, LOAD_ATTR); assert(PyDict_CheckExact((PyObject *)dict)); PyObject *name = GETITEM(names, oparg); uint16_t hint = cache->index; DEOPT_IF(hint >= (size_t)dict->ma_keys->dk_nentries, LOAD_ATTR); if (DK_IS_UNICODE(dict->ma_keys)) { PyDictUnicodeEntry *ep = DK_UNICODE_ENTRIES(dict->ma_keys) + hint; DEOPT_IF(ep->me_key != name, LOAD_ATTR); res = ep->me_value; } else { PyDictKeyEntry *ep = DK_ENTRIES(dict->ma_keys) + hint; DEOPT_IF(ep->me_key != name, LOAD_ATTR); res = ep->me_value; } DEOPT_IF(res == NULL, LOAD_ATTR); STAT_INC(LOAD_ATTR, hit); Py_INCREF(res); SET_TOP(res); Py_DECREF(owner); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_ATTR); DISPATCH(); } TARGET(LOAD_ATTR_SLOT) { assert(cframe.use_tracing == 0); PyObject *owner = TOP(); PyObject *res; PyTypeObject *tp = Py_TYPE(owner); _PyAttrCache *cache = (_PyAttrCache *)next_instr; uint32_t type_version = read_u32(cache->version); assert(type_version != 0); DEOPT_IF(tp->tp_version_tag != type_version, LOAD_ATTR); char *addr = (char *)owner + cache->index; res = *(PyObject **)addr; DEOPT_IF(res == NULL, LOAD_ATTR); STAT_INC(LOAD_ATTR, hit); Py_INCREF(res); SET_TOP(res); Py_DECREF(owner); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_ATTR); DISPATCH(); } TARGET(STORE_ATTR_ADAPTIVE) { assert(cframe.use_tracing == 0); _PyAttrCache *cache = (_PyAttrCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *owner = TOP(); PyObject *name = GETITEM(names, oparg); next_instr--; if (_Py_Specialize_StoreAttr(owner, next_instr, name) < 0) { next_instr++; goto error; } DISPATCH_SAME_OPARG(); } else { STAT_INC(STORE_ATTR, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(STORE_ATTR); } } TARGET(STORE_ATTR_INSTANCE_VALUE) { assert(cframe.use_tracing == 0); PyObject *owner = TOP(); PyTypeObject *tp = Py_TYPE(owner); _PyAttrCache *cache = (_PyAttrCache *)next_instr; uint32_t type_version = read_u32(cache->version); assert(type_version != 0); DEOPT_IF(tp->tp_version_tag != type_version, STORE_ATTR); assert(tp->tp_flags & Py_TPFLAGS_MANAGED_DICT); PyDictValues *values = *_PyObject_ValuesPointer(owner); DEOPT_IF(values == NULL, STORE_ATTR); STAT_INC(STORE_ATTR, hit); Py_ssize_t index = cache->index; STACK_SHRINK(1); PyObject *value = POP(); PyObject *old_value = values->values[index]; values->values[index] = value; if (old_value == NULL) { _PyDictValues_AddToInsertionOrder(values, index); } else { Py_DECREF(old_value); } Py_DECREF(owner); JUMPBY(INLINE_CACHE_ENTRIES_STORE_ATTR); DISPATCH(); } TARGET(STORE_ATTR_WITH_HINT) { assert(cframe.use_tracing == 0); PyObject *owner = TOP(); PyTypeObject *tp = Py_TYPE(owner); _PyAttrCache *cache = (_PyAttrCache *)next_instr; uint32_t type_version = read_u32(cache->version); assert(type_version != 0); DEOPT_IF(tp->tp_version_tag != type_version, STORE_ATTR); assert(tp->tp_flags & Py_TPFLAGS_MANAGED_DICT); PyDictObject *dict = *(PyDictObject **)_PyObject_ManagedDictPointer(owner); DEOPT_IF(dict == NULL, STORE_ATTR); assert(PyDict_CheckExact((PyObject *)dict)); PyObject *name = GETITEM(names, oparg); uint16_t hint = cache->index; DEOPT_IF(hint >= (size_t)dict->ma_keys->dk_nentries, STORE_ATTR); PyObject *value, *old_value; if (DK_IS_UNICODE(dict->ma_keys)) { PyDictUnicodeEntry *ep = DK_UNICODE_ENTRIES(dict->ma_keys) + hint; DEOPT_IF(ep->me_key != name, STORE_ATTR); old_value = ep->me_value; DEOPT_IF(old_value == NULL, STORE_ATTR); STACK_SHRINK(1); value = POP(); ep->me_value = value; } else { PyDictKeyEntry *ep = DK_ENTRIES(dict->ma_keys) + hint; DEOPT_IF(ep->me_key != name, STORE_ATTR); old_value = ep->me_value; DEOPT_IF(old_value == NULL, STORE_ATTR); STACK_SHRINK(1); value = POP(); ep->me_value = value; } Py_DECREF(old_value); STAT_INC(STORE_ATTR, hit); /* Ensure dict is GC tracked if it needs to be */ if (!_PyObject_GC_IS_TRACKED(dict) && _PyObject_GC_MAY_BE_TRACKED(value)) { _PyObject_GC_TRACK(dict); } /* PEP 509 */ dict->ma_version_tag = DICT_NEXT_VERSION(); Py_DECREF(owner); JUMPBY(INLINE_CACHE_ENTRIES_STORE_ATTR); DISPATCH(); } TARGET(STORE_ATTR_SLOT) { assert(cframe.use_tracing == 0); PyObject *owner = TOP(); PyTypeObject *tp = Py_TYPE(owner); _PyAttrCache *cache = (_PyAttrCache *)next_instr; uint32_t type_version = read_u32(cache->version); assert(type_version != 0); DEOPT_IF(tp->tp_version_tag != type_version, STORE_ATTR); char *addr = (char *)owner + cache->index; STAT_INC(STORE_ATTR, hit); STACK_SHRINK(1); PyObject *value = POP(); PyObject *old_value = *(PyObject **)addr; *(PyObject **)addr = value; Py_XDECREF(old_value); Py_DECREF(owner); JUMPBY(INLINE_CACHE_ENTRIES_STORE_ATTR); DISPATCH(); } TARGET(COMPARE_OP) { PREDICTED(COMPARE_OP); assert(oparg <= Py_GE); PyObject *right = POP(); PyObject *left = TOP(); PyObject *res = PyObject_RichCompare(left, right, oparg); SET_TOP(res); Py_DECREF(left); Py_DECREF(right); if (res == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_COMPARE_OP); DISPATCH(); } TARGET(COMPARE_OP_ADAPTIVE) { assert(cframe.use_tracing == 0); _PyCompareOpCache *cache = (_PyCompareOpCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *right = TOP(); PyObject *left = SECOND(); next_instr--; _Py_Specialize_CompareOp(left, right, next_instr, oparg); DISPATCH_SAME_OPARG(); } else { STAT_INC(COMPARE_OP, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(COMPARE_OP); } } TARGET(COMPARE_OP_FLOAT_JUMP) { assert(cframe.use_tracing == 0); // Combined: COMPARE_OP (float ? float) + POP_JUMP_(direction)_IF_(true/false) _PyCompareOpCache *cache = (_PyCompareOpCache *)next_instr; int when_to_jump_mask = cache->mask; PyObject *right = TOP(); PyObject *left = SECOND(); DEOPT_IF(!PyFloat_CheckExact(left), COMPARE_OP); DEOPT_IF(!PyFloat_CheckExact(right), COMPARE_OP); double dleft = PyFloat_AS_DOUBLE(left); double dright = PyFloat_AS_DOUBLE(right); int sign = (dleft > dright) - (dleft < dright); DEOPT_IF(isnan(dleft), COMPARE_OP); DEOPT_IF(isnan(dright), COMPARE_OP); STAT_INC(COMPARE_OP, hit); JUMPBY(INLINE_CACHE_ENTRIES_COMPARE_OP); NEXTOPARG(); STACK_SHRINK(2); _Py_DECREF_SPECIALIZED(left, _PyFloat_ExactDealloc); _Py_DECREF_SPECIALIZED(right, _PyFloat_ExactDealloc); assert(opcode == POP_JUMP_FORWARD_IF_FALSE || opcode == POP_JUMP_BACKWARD_IF_FALSE || opcode == POP_JUMP_FORWARD_IF_TRUE || opcode == POP_JUMP_BACKWARD_IF_TRUE); int jump = (9 << (sign + 1)) & when_to_jump_mask; if (!jump) { next_instr++; } else if (jump >= 8) { assert(opcode == POP_JUMP_BACKWARD_IF_TRUE || opcode == POP_JUMP_BACKWARD_IF_FALSE); JUMPBY(1 - oparg); CHECK_EVAL_BREAKER(); } else { assert(opcode == POP_JUMP_FORWARD_IF_TRUE || opcode == POP_JUMP_FORWARD_IF_FALSE); JUMPBY(1 + oparg); } DISPATCH(); } TARGET(COMPARE_OP_INT_JUMP) { assert(cframe.use_tracing == 0); // Combined: COMPARE_OP (int ? int) + POP_JUMP_(direction)_IF_(true/false) _PyCompareOpCache *cache = (_PyCompareOpCache *)next_instr; int when_to_jump_mask = cache->mask; PyObject *right = TOP(); PyObject *left = SECOND(); DEOPT_IF(!PyLong_CheckExact(left), COMPARE_OP); DEOPT_IF(!PyLong_CheckExact(right), COMPARE_OP); DEOPT_IF((size_t)(Py_SIZE(left) + 1) > 2, COMPARE_OP); DEOPT_IF((size_t)(Py_SIZE(right) + 1) > 2, COMPARE_OP); STAT_INC(COMPARE_OP, hit); assert(Py_ABS(Py_SIZE(left)) <= 1 && Py_ABS(Py_SIZE(right)) <= 1); Py_ssize_t ileft = Py_SIZE(left) * ((PyLongObject *)left)->ob_digit[0]; Py_ssize_t iright = Py_SIZE(right) * ((PyLongObject *)right)->ob_digit[0]; int sign = (ileft > iright) - (ileft < iright); JUMPBY(INLINE_CACHE_ENTRIES_COMPARE_OP); NEXTOPARG(); STACK_SHRINK(2); _Py_DECREF_SPECIALIZED(left, (destructor)PyObject_Free); _Py_DECREF_SPECIALIZED(right, (destructor)PyObject_Free); assert(opcode == POP_JUMP_FORWARD_IF_FALSE || opcode == POP_JUMP_BACKWARD_IF_FALSE || opcode == POP_JUMP_FORWARD_IF_TRUE || opcode == POP_JUMP_BACKWARD_IF_TRUE); int jump = (9 << (sign + 1)) & when_to_jump_mask; if (!jump) { next_instr++; } else if (jump >= 8) { assert(opcode == POP_JUMP_BACKWARD_IF_TRUE || opcode == POP_JUMP_BACKWARD_IF_FALSE); JUMPBY(1 - oparg); CHECK_EVAL_BREAKER(); } else { assert(opcode == POP_JUMP_FORWARD_IF_TRUE || opcode == POP_JUMP_FORWARD_IF_FALSE); JUMPBY(1 + oparg); } DISPATCH(); } TARGET(COMPARE_OP_STR_JUMP) { assert(cframe.use_tracing == 0); // Combined: COMPARE_OP (str == str or str != str) + POP_JUMP_(direction)_IF_(true/false) _PyCompareOpCache *cache = (_PyCompareOpCache *)next_instr; int when_to_jump_mask = cache->mask; PyObject *right = TOP(); PyObject *left = SECOND(); DEOPT_IF(!PyUnicode_CheckExact(left), COMPARE_OP); DEOPT_IF(!PyUnicode_CheckExact(right), COMPARE_OP); STAT_INC(COMPARE_OP, hit); int res = _PyUnicode_Equal(left, right); if (res < 0) { goto error; } assert(oparg == Py_EQ || oparg == Py_NE); JUMPBY(INLINE_CACHE_ENTRIES_COMPARE_OP); NEXTOPARG(); assert(opcode == POP_JUMP_FORWARD_IF_FALSE || opcode == POP_JUMP_BACKWARD_IF_FALSE || opcode == POP_JUMP_FORWARD_IF_TRUE || opcode == POP_JUMP_BACKWARD_IF_TRUE); STACK_SHRINK(2); _Py_DECREF_SPECIALIZED(left, _PyUnicode_ExactDealloc); _Py_DECREF_SPECIALIZED(right, _PyUnicode_ExactDealloc); assert(res == 0 || res == 1); int sign = 1 - res; int jump = (9 << (sign + 1)) & when_to_jump_mask; if (!jump) { next_instr++; } else if (jump >= 8) { assert(opcode == POP_JUMP_BACKWARD_IF_TRUE || opcode == POP_JUMP_BACKWARD_IF_FALSE); JUMPBY(1 - oparg); CHECK_EVAL_BREAKER(); } else { assert(opcode == POP_JUMP_FORWARD_IF_TRUE || opcode == POP_JUMP_FORWARD_IF_FALSE); JUMPBY(1 + oparg); } DISPATCH(); } TARGET(IS_OP) { PyObject *right = POP(); PyObject *left = TOP(); int res = Py_Is(left, right) ^ oparg; PyObject *b = res ? Py_True : Py_False; Py_INCREF(b); SET_TOP(b); Py_DECREF(left); Py_DECREF(right); DISPATCH(); } TARGET(CONTAINS_OP) { PyObject *right = POP(); PyObject *left = POP(); int res = PySequence_Contains(right, left); Py_DECREF(left); Py_DECREF(right); if (res < 0) { goto error; } PyObject *b = (res^oparg) ? Py_True : Py_False; Py_INCREF(b); PUSH(b); DISPATCH(); } TARGET(CHECK_EG_MATCH) { PyObject *match_type = POP(); if (check_except_star_type_valid(tstate, match_type) < 0) { Py_DECREF(match_type); goto error; } PyObject *exc_value = TOP(); PyObject *match = NULL, *rest = NULL; int res = exception_group_match(exc_value, match_type, &match, &rest); Py_DECREF(match_type); if (res < 0) { goto error; } if (match == NULL || rest == NULL) { assert(match == NULL); assert(rest == NULL); goto error; } if (Py_IsNone(match)) { PUSH(match); Py_XDECREF(rest); } else { /* Total or partial match - update the stack from * [val] * to * [rest, match] * (rest can be Py_None) */ SET_TOP(rest); PUSH(match); PyErr_SetExcInfo(NULL, Py_NewRef(match), NULL); Py_DECREF(exc_value); } DISPATCH(); } TARGET(CHECK_EXC_MATCH) { PyObject *right = POP(); PyObject *left = TOP(); assert(PyExceptionInstance_Check(left)); if (check_except_type_valid(tstate, right) < 0) { Py_DECREF(right); goto error; } int res = PyErr_GivenExceptionMatches(left, right); Py_DECREF(right); PUSH(Py_NewRef(res ? Py_True : Py_False)); DISPATCH(); } TARGET(IMPORT_NAME) { PyObject *name = GETITEM(names, oparg); PyObject *fromlist = POP(); PyObject *level = TOP(); PyObject *res; res = import_name(tstate, frame, name, fromlist, level); Py_DECREF(level); Py_DECREF(fromlist); SET_TOP(res); if (res == NULL) goto error; DISPATCH(); } TARGET(IMPORT_STAR) { PyObject *from = POP(), *locals; int err; if (_PyFrame_FastToLocalsWithError(frame) < 0) { Py_DECREF(from); goto error; } locals = LOCALS(); if (locals == NULL) { _PyErr_SetString(tstate, PyExc_SystemError, "no locals found during 'import *'"); Py_DECREF(from); goto error; } err = import_all_from(tstate, locals, from); _PyFrame_LocalsToFast(frame, 0); Py_DECREF(from); if (err != 0) goto error; DISPATCH(); } TARGET(IMPORT_FROM) { PyObject *name = GETITEM(names, oparg); PyObject *from = TOP(); PyObject *res; res = import_from(tstate, from, name); PUSH(res); if (res == NULL) goto error; DISPATCH(); } TARGET(JUMP_FORWARD) { JUMPBY(oparg); DISPATCH(); } TARGET(JUMP_BACKWARD) { _PyCode_Warmup(frame->f_code); JUMP_TO_INSTRUCTION(JUMP_BACKWARD_QUICK); } TARGET(POP_JUMP_BACKWARD_IF_FALSE) { PREDICTED(POP_JUMP_BACKWARD_IF_FALSE); PyObject *cond = POP(); if (Py_IsTrue(cond)) { _Py_DECREF_NO_DEALLOC(cond); DISPATCH(); } if (Py_IsFalse(cond)) { _Py_DECREF_NO_DEALLOC(cond); JUMPBY(-oparg); CHECK_EVAL_BREAKER(); DISPATCH(); } int err = PyObject_IsTrue(cond); Py_DECREF(cond); if (err > 0) ; else if (err == 0) { JUMPBY(-oparg); CHECK_EVAL_BREAKER(); } else goto error; DISPATCH(); } TARGET(POP_JUMP_FORWARD_IF_FALSE) { PREDICTED(POP_JUMP_FORWARD_IF_FALSE); PyObject *cond = POP(); if (Py_IsTrue(cond)) { _Py_DECREF_NO_DEALLOC(cond); } else if (Py_IsFalse(cond)) { _Py_DECREF_NO_DEALLOC(cond); JUMPBY(oparg); } else { int err = PyObject_IsTrue(cond); Py_DECREF(cond); if (err > 0) ; else if (err == 0) { JUMPBY(oparg); } else goto error; } DISPATCH(); } TARGET(POP_JUMP_BACKWARD_IF_TRUE) { PyObject *cond = POP(); if (Py_IsFalse(cond)) { _Py_DECREF_NO_DEALLOC(cond); DISPATCH(); } if (Py_IsTrue(cond)) { _Py_DECREF_NO_DEALLOC(cond); JUMPBY(-oparg); CHECK_EVAL_BREAKER(); DISPATCH(); } int err = PyObject_IsTrue(cond); Py_DECREF(cond); if (err > 0) { JUMPBY(-oparg); CHECK_EVAL_BREAKER(); } else if (err == 0) ; else goto error; DISPATCH(); } TARGET(POP_JUMP_FORWARD_IF_TRUE) { PyObject *cond = POP(); if (Py_IsFalse(cond)) { _Py_DECREF_NO_DEALLOC(cond); } else if (Py_IsTrue(cond)) { _Py_DECREF_NO_DEALLOC(cond); JUMPBY(oparg); } else { int err = PyObject_IsTrue(cond); Py_DECREF(cond); if (err > 0) { JUMPBY(oparg); } else if (err == 0) ; else goto error; } DISPATCH(); } TARGET(POP_JUMP_BACKWARD_IF_NOT_NONE) { PyObject *value = POP(); if (!Py_IsNone(value)) { Py_DECREF(value); JUMPBY(-oparg); CHECK_EVAL_BREAKER(); DISPATCH(); } _Py_DECREF_NO_DEALLOC(value); DISPATCH(); } TARGET(POP_JUMP_FORWARD_IF_NOT_NONE) { PyObject *value = POP(); if (!Py_IsNone(value)) { JUMPBY(oparg); } Py_DECREF(value); DISPATCH(); } TARGET(POP_JUMP_BACKWARD_IF_NONE) { PyObject *value = POP(); if (Py_IsNone(value)) { _Py_DECREF_NO_DEALLOC(value); JUMPBY(-oparg); CHECK_EVAL_BREAKER(); } else { Py_DECREF(value); } DISPATCH(); } TARGET(POP_JUMP_FORWARD_IF_NONE) { PyObject *value = POP(); if (Py_IsNone(value)) { _Py_DECREF_NO_DEALLOC(value); JUMPBY(oparg); } else { Py_DECREF(value); } DISPATCH(); } TARGET(JUMP_IF_FALSE_OR_POP) { PyObject *cond = TOP(); int err; if (Py_IsTrue(cond)) { STACK_SHRINK(1); _Py_DECREF_NO_DEALLOC(cond); DISPATCH(); } if (Py_IsFalse(cond)) { JUMPBY(oparg); DISPATCH(); } err = PyObject_IsTrue(cond); if (err > 0) { STACK_SHRINK(1); Py_DECREF(cond); } else if (err == 0) JUMPBY(oparg); else goto error; DISPATCH(); } TARGET(JUMP_IF_TRUE_OR_POP) { PyObject *cond = TOP(); int err; if (Py_IsFalse(cond)) { STACK_SHRINK(1); _Py_DECREF_NO_DEALLOC(cond); DISPATCH(); } if (Py_IsTrue(cond)) { JUMPBY(oparg); DISPATCH(); } err = PyObject_IsTrue(cond); if (err > 0) { JUMPBY(oparg); } else if (err == 0) { STACK_SHRINK(1); Py_DECREF(cond); } else goto error; DISPATCH(); } TARGET(JUMP_BACKWARD_NO_INTERRUPT) { /* This bytecode is used in the `yield from` or `await` loop. * If there is an interrupt, we want it handled in the innermost * generator or coroutine, so we deliberately do not check it here. * (see bpo-30039). */ JUMPBY(-oparg); DISPATCH(); } TARGET(JUMP_BACKWARD_QUICK) { PREDICTED(JUMP_BACKWARD_QUICK); assert(oparg < INSTR_OFFSET()); JUMPBY(-oparg); CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(GET_LEN) { // PUSH(len(TOS)) Py_ssize_t len_i = PyObject_Length(TOP()); if (len_i < 0) { goto error; } PyObject *len_o = PyLong_FromSsize_t(len_i); if (len_o == NULL) { goto error; } PUSH(len_o); DISPATCH(); } TARGET(MATCH_CLASS) { // Pop TOS and TOS1. Set TOS to a tuple of attributes on success, or // None on failure. PyObject *names = POP(); PyObject *type = POP(); PyObject *subject = TOP(); assert(PyTuple_CheckExact(names)); PyObject *attrs = match_class(tstate, subject, type, oparg, names); Py_DECREF(names); Py_DECREF(type); if (attrs) { // Success! assert(PyTuple_CheckExact(attrs)); SET_TOP(attrs); } else if (_PyErr_Occurred(tstate)) { // Error! goto error; } else { // Failure! Py_INCREF(Py_None); SET_TOP(Py_None); } Py_DECREF(subject); DISPATCH(); } TARGET(MATCH_MAPPING) { PyObject *subject = TOP(); int match = Py_TYPE(subject)->tp_flags & Py_TPFLAGS_MAPPING; PyObject *res = match ? Py_True : Py_False; Py_INCREF(res); PUSH(res); PREDICT(POP_JUMP_FORWARD_IF_FALSE); PREDICT(POP_JUMP_BACKWARD_IF_FALSE); DISPATCH(); } TARGET(MATCH_SEQUENCE) { PyObject *subject = TOP(); int match = Py_TYPE(subject)->tp_flags & Py_TPFLAGS_SEQUENCE; PyObject *res = match ? Py_True : Py_False; Py_INCREF(res); PUSH(res); PREDICT(POP_JUMP_FORWARD_IF_FALSE); PREDICT(POP_JUMP_BACKWARD_IF_FALSE); DISPATCH(); } TARGET(MATCH_KEYS) { // On successful match, PUSH(values). Otherwise, PUSH(None). PyObject *keys = TOP(); PyObject *subject = SECOND(); PyObject *values_or_none = match_keys(tstate, subject, keys); if (values_or_none == NULL) { goto error; } PUSH(values_or_none); DISPATCH(); } TARGET(GET_ITER) { /* before: [obj]; after [getiter(obj)] */ PyObject *iterable = TOP(); PyObject *iter = PyObject_GetIter(iterable); Py_DECREF(iterable); SET_TOP(iter); if (iter == NULL) goto error; PREDICT(FOR_ITER); DISPATCH(); } TARGET(GET_YIELD_FROM_ITER) { /* before: [obj]; after [getiter(obj)] */ PyObject *iterable = TOP(); PyObject *iter; if (PyCoro_CheckExact(iterable)) { /* `iterable` is a coroutine */ if (!(frame->f_code->co_flags & (CO_COROUTINE | CO_ITERABLE_COROUTINE))) { /* and it is used in a 'yield from' expression of a regular generator. */ Py_DECREF(iterable); SET_TOP(NULL); _PyErr_SetString(tstate, PyExc_TypeError, "cannot 'yield from' a coroutine object " "in a non-coroutine generator"); goto error; } } else if (!PyGen_CheckExact(iterable)) { /* `iterable` is not a generator. */ iter = PyObject_GetIter(iterable); Py_DECREF(iterable); SET_TOP(iter); if (iter == NULL) goto error; } PREDICT(LOAD_CONST); DISPATCH(); } TARGET(FOR_ITER) { PREDICTED(FOR_ITER); /* before: [iter]; after: [iter, iter()] *or* [] */ PyObject *iter = TOP(); #ifdef Py_STATS extern int _PySpecialization_ClassifyIterator(PyObject *); _py_stats.opcode_stats[FOR_ITER].specialization.failure++; _py_stats.opcode_stats[FOR_ITER].specialization.failure_kinds[_PySpecialization_ClassifyIterator(iter)]++; #endif PyObject *next = (*Py_TYPE(iter)->tp_iternext)(iter); if (next != NULL) { PUSH(next); PREDICT(STORE_FAST); PREDICT(UNPACK_SEQUENCE); DISPATCH(); } if (_PyErr_Occurred(tstate)) { if (!_PyErr_ExceptionMatches(tstate, PyExc_StopIteration)) { goto error; } else if (tstate->c_tracefunc != NULL) { call_exc_trace(tstate->c_tracefunc, tstate->c_traceobj, tstate, frame); } _PyErr_Clear(tstate); } /* iterator ended normally */ STACK_SHRINK(1); Py_DECREF(iter); JUMPBY(oparg); DISPATCH(); } TARGET(BEFORE_ASYNC_WITH) { PyObject *mgr = TOP(); PyObject *res; PyObject *enter = _PyObject_LookupSpecial(mgr, &_Py_ID(__aenter__)); if (enter == NULL) { if (!_PyErr_Occurred(tstate)) { _PyErr_Format(tstate, PyExc_TypeError, "'%.200s' object does not support the " "asynchronous context manager protocol", Py_TYPE(mgr)->tp_name); } goto error; } PyObject *exit = _PyObject_LookupSpecial(mgr, &_Py_ID(__aexit__)); if (exit == NULL) { if (!_PyErr_Occurred(tstate)) { _PyErr_Format(tstate, PyExc_TypeError, "'%.200s' object does not support the " "asynchronous context manager protocol " "(missed __aexit__ method)", Py_TYPE(mgr)->tp_name); } Py_DECREF(enter); goto error; } SET_TOP(exit); Py_DECREF(mgr); res = _PyObject_CallNoArgs(enter); Py_DECREF(enter); if (res == NULL) goto error; PUSH(res); PREDICT(GET_AWAITABLE); DISPATCH(); } TARGET(BEFORE_WITH) { PyObject *mgr = TOP(); PyObject *res; PyObject *enter = _PyObject_LookupSpecial(mgr, &_Py_ID(__enter__)); if (enter == NULL) { if (!_PyErr_Occurred(tstate)) { _PyErr_Format(tstate, PyExc_TypeError, "'%.200s' object does not support the " "context manager protocol", Py_TYPE(mgr)->tp_name); } goto error; } PyObject *exit = _PyObject_LookupSpecial(mgr, &_Py_ID(__exit__)); if (exit == NULL) { if (!_PyErr_Occurred(tstate)) { _PyErr_Format(tstate, PyExc_TypeError, "'%.200s' object does not support the " "context manager protocol " "(missed __exit__ method)", Py_TYPE(mgr)->tp_name); } Py_DECREF(enter); goto error; } SET_TOP(exit); Py_DECREF(mgr); res = _PyObject_CallNoArgs(enter); Py_DECREF(enter); if (res == NULL) { goto error; } PUSH(res); DISPATCH(); } TARGET(WITH_EXCEPT_START) { /* At the top of the stack are 4 values: - TOP = exc_info() - SECOND = previous exception - THIRD: lasti of exception in exc_info() - FOURTH: the context.__exit__ bound method We call FOURTH(type(TOP), TOP, GetTraceback(TOP)). Then we push the __exit__ return value. */ PyObject *exit_func; PyObject *exc, *val, *tb, *res; val = TOP(); assert(val && PyExceptionInstance_Check(val)); exc = PyExceptionInstance_Class(val); tb = PyException_GetTraceback(val); Py_XDECREF(tb); assert(PyLong_Check(PEEK(3))); exit_func = PEEK(4); PyObject *stack[4] = {NULL, exc, val, tb}; res = PyObject_Vectorcall(exit_func, stack + 1, 3 | PY_VECTORCALL_ARGUMENTS_OFFSET, NULL); if (res == NULL) goto error; PUSH(res); DISPATCH(); } TARGET(PUSH_EXC_INFO) { PyObject *value = TOP(); _PyErr_StackItem *exc_info = tstate->exc_info; if (exc_info->exc_value != NULL) { SET_TOP(exc_info->exc_value); } else { Py_INCREF(Py_None); SET_TOP(Py_None); } Py_INCREF(value); PUSH(value); assert(PyExceptionInstance_Check(value)); exc_info->exc_value = value; DISPATCH(); } TARGET(LOAD_METHOD) { PREDICTED(LOAD_METHOD); /* Designed to work in tandem with PRECALL. */ PyObject *name = GETITEM(names, oparg); PyObject *obj = TOP(); PyObject *meth = NULL; int meth_found = _PyObject_GetMethod(obj, name, &meth); if (meth == NULL) { /* Most likely attribute wasn't found. */ goto error; } if (meth_found) { /* We can bypass temporary bound method object. meth is unbound method and obj is self. meth | self | arg1 | ... | argN */ SET_TOP(meth); PUSH(obj); // self } else { /* meth is not an unbound method (but a regular attr, or something was returned by a descriptor protocol). Set the second element of the stack to NULL, to signal PRECALL that it's not a method call. NULL | meth | arg1 | ... | argN */ SET_TOP(NULL); Py_DECREF(obj); PUSH(meth); } JUMPBY(INLINE_CACHE_ENTRIES_LOAD_METHOD); DISPATCH(); } TARGET(LOAD_METHOD_ADAPTIVE) { assert(cframe.use_tracing == 0); _PyLoadMethodCache *cache = (_PyLoadMethodCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *owner = TOP(); PyObject *name = GETITEM(names, oparg); next_instr--; if (_Py_Specialize_LoadMethod(owner, next_instr, name) < 0) { next_instr++; goto error; } DISPATCH_SAME_OPARG(); } else { STAT_INC(LOAD_METHOD, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(LOAD_METHOD); } } TARGET(LOAD_METHOD_WITH_VALUES) { /* LOAD_METHOD, with cached method object */ assert(cframe.use_tracing == 0); PyObject *self = TOP(); PyTypeObject *self_cls = Py_TYPE(self); _PyLoadMethodCache *cache = (_PyLoadMethodCache *)next_instr; uint32_t type_version = read_u32(cache->type_version); assert(type_version != 0); DEOPT_IF(self_cls->tp_version_tag != type_version, LOAD_METHOD); assert(self_cls->tp_flags & Py_TPFLAGS_MANAGED_DICT); PyDictObject *dict = *(PyDictObject**)_PyObject_ManagedDictPointer(self); DEOPT_IF(dict != NULL, LOAD_METHOD); PyHeapTypeObject *self_heap_type = (PyHeapTypeObject *)self_cls; DEOPT_IF(self_heap_type->ht_cached_keys->dk_version != read_u32(cache->keys_version), LOAD_METHOD); STAT_INC(LOAD_METHOD, hit); PyObject *res = read_obj(cache->descr); assert(res != NULL); assert(_PyType_HasFeature(Py_TYPE(res), Py_TPFLAGS_METHOD_DESCRIPTOR)); Py_INCREF(res); SET_TOP(res); PUSH(self); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_METHOD); DISPATCH(); } TARGET(LOAD_METHOD_WITH_DICT) { /* LOAD_METHOD, with a dict Can be either a managed dict, or a tp_dictoffset offset.*/ assert(cframe.use_tracing == 0); PyObject *self = TOP(); PyTypeObject *self_cls = Py_TYPE(self); _PyLoadMethodCache *cache = (_PyLoadMethodCache *)next_instr; DEOPT_IF(self_cls->tp_version_tag != read_u32(cache->type_version), LOAD_METHOD); /* Treat index as a signed 16 bit value */ int dictoffset = *(int16_t *)&cache->dict_offset; PyDictObject **dictptr = (PyDictObject**)(((char *)self)+dictoffset); assert( dictoffset == MANAGED_DICT_OFFSET || (dictoffset == self_cls->tp_dictoffset && dictoffset > 0) ); PyDictObject *dict = *dictptr; DEOPT_IF(dict == NULL, LOAD_METHOD); DEOPT_IF(dict->ma_keys->dk_version != read_u32(cache->keys_version), LOAD_METHOD); STAT_INC(LOAD_METHOD, hit); PyObject *res = read_obj(cache->descr); assert(res != NULL); assert(_PyType_HasFeature(Py_TYPE(res), Py_TPFLAGS_METHOD_DESCRIPTOR)); Py_INCREF(res); SET_TOP(res); PUSH(self); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_METHOD); DISPATCH(); } TARGET(LOAD_METHOD_NO_DICT) { assert(cframe.use_tracing == 0); PyObject *self = TOP(); PyTypeObject *self_cls = Py_TYPE(self); _PyLoadMethodCache *cache = (_PyLoadMethodCache *)next_instr; uint32_t type_version = read_u32(cache->type_version); DEOPT_IF(self_cls->tp_version_tag != type_version, LOAD_METHOD); assert(self_cls->tp_dictoffset == 0); STAT_INC(LOAD_METHOD, hit); PyObject *res = read_obj(cache->descr); assert(res != NULL); assert(_PyType_HasFeature(Py_TYPE(res), Py_TPFLAGS_METHOD_DESCRIPTOR)); Py_INCREF(res); SET_TOP(res); PUSH(self); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_METHOD); DISPATCH(); } TARGET(LOAD_METHOD_MODULE) { /* LOAD_METHOD, for module methods */ assert(cframe.use_tracing == 0); PyObject *owner = TOP(); PyObject *res; LOAD_MODULE_ATTR_OR_METHOD(METHOD); SET_TOP(NULL); Py_DECREF(owner); PUSH(res); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_METHOD); DISPATCH(); } TARGET(LOAD_METHOD_CLASS) { /* LOAD_METHOD, for class methods */ assert(cframe.use_tracing == 0); _PyLoadMethodCache *cache = (_PyLoadMethodCache *)next_instr; PyObject *cls = TOP(); DEOPT_IF(!PyType_Check(cls), LOAD_METHOD); uint32_t type_version = read_u32(cache->type_version); DEOPT_IF(((PyTypeObject *)cls)->tp_version_tag != type_version, LOAD_METHOD); assert(type_version != 0); STAT_INC(LOAD_METHOD, hit); PyObject *res = read_obj(cache->descr); assert(res != NULL); Py_INCREF(res); SET_TOP(NULL); Py_DECREF(cls); PUSH(res); JUMPBY(INLINE_CACHE_ENTRIES_LOAD_METHOD); DISPATCH(); } TARGET(PRECALL) { PREDICTED(PRECALL); /* Designed to work in tamdem with LOAD_METHOD. */ /* `meth` is NULL when LOAD_METHOD thinks that it's not a method call. Stack layout: ... | NULL | callable | arg1 | ... | argN ^- TOP() ^- (-oparg) ^- (-oparg-1) ^- (-oparg-2) `callable` will be POPed by call_function. NULL will will be POPed manually later. If `meth` isn't NULL, it's a method call. Stack layout: ... | method | self | arg1 | ... | argN ^- TOP() ^- (-oparg) ^- (-oparg-1) ^- (-oparg-2) `self` and `method` will be POPed by call_function. We'll be passing `oparg + 1` to call_function, to make it accept the `self` as a first argument. */ int is_meth = is_method(stack_pointer, oparg); int nargs = oparg + is_meth; /* Move ownership of reference from stack to call_shape * and make sure that NULL is cleared from stack */ PyObject *function = PEEK(nargs + 1); if (!is_meth && Py_TYPE(function) == &PyMethod_Type) { PyObject *meth = ((PyMethodObject *)function)->im_func; PyObject *self = ((PyMethodObject *)function)->im_self; Py_INCREF(meth); Py_INCREF(self); PEEK(oparg+1) = self; PEEK(oparg+2) = meth; Py_DECREF(function); } JUMPBY(INLINE_CACHE_ENTRIES_PRECALL); DISPATCH(); } TARGET(PRECALL_BOUND_METHOD) { DEOPT_IF(is_method(stack_pointer, oparg), PRECALL); PyObject *function = PEEK(oparg + 1); DEOPT_IF(Py_TYPE(function) != &PyMethod_Type, PRECALL); STAT_INC(PRECALL, hit); PyObject *meth = ((PyMethodObject *)function)->im_func; PyObject *self = ((PyMethodObject *)function)->im_self; Py_INCREF(meth); Py_INCREF(self); PEEK(oparg + 1) = self; PEEK(oparg + 2) = meth; Py_DECREF(function); JUMPBY(INLINE_CACHE_ENTRIES_PRECALL); DISPATCH(); } TARGET(PRECALL_PYFUNC) { int nargs = oparg + is_method(stack_pointer, oparg); PyObject *function = PEEK(nargs + 1); DEOPT_IF(Py_TYPE(function) != &PyFunction_Type, PRECALL); STAT_INC(PRECALL, hit); JUMPBY(INLINE_CACHE_ENTRIES_PRECALL); DISPATCH(); } TARGET(KW_NAMES) { assert(call_shape.kwnames == NULL); assert(oparg < PyTuple_GET_SIZE(consts)); call_shape.kwnames = GETITEM(consts, oparg); DISPATCH(); } TARGET(CALL) { int is_meth; call_function: is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; PyObject *function = PEEK(total_args + 1); int positional_args = total_args - KWNAMES_LEN(); // Check if the call can be inlined or not if (Py_TYPE(function) == &PyFunction_Type && tstate->interp->eval_frame == NULL) { int code_flags = ((PyCodeObject*)PyFunction_GET_CODE(function))->co_flags; PyObject *locals = code_flags & CO_OPTIMIZED ? NULL : PyFunction_GET_GLOBALS(function); STACK_SHRINK(total_args); _PyInterpreterFrame *new_frame = _PyEvalFramePushAndInit( tstate, (PyFunctionObject *)function, locals, stack_pointer, positional_args, call_shape.kwnames ); call_shape.kwnames = NULL; STACK_SHRINK(2-is_meth); // The frame has stolen all the arguments from the stack, // so there is no need to clean them up. if (new_frame == NULL) { goto error; } _PyFrame_SetStackPointer(frame, stack_pointer); JUMPBY(INLINE_CACHE_ENTRIES_CALL); frame->prev_instr = next_instr - 1; new_frame->previous = frame; cframe.current_frame = frame = new_frame; CALL_STAT_INC(inlined_py_calls); goto start_frame; } /* Callable is not a normal Python function */ PyObject *res; if (cframe.use_tracing) { res = trace_call_function( tstate, function, stack_pointer-total_args, positional_args, call_shape.kwnames); } else { res = PyObject_Vectorcall( function, stack_pointer-total_args, positional_args | PY_VECTORCALL_ARGUMENTS_OFFSET, call_shape.kwnames); } call_shape.kwnames = NULL; assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); Py_DECREF(function); /* Clear the stack */ STACK_SHRINK(total_args); for (int i = 0; i < total_args; i++) { Py_DECREF(stack_pointer[i]); } STACK_SHRINK(2-is_meth); PUSH(res); if (res == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_CALL); CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_ADAPTIVE) { _PyPrecallCache *cache = (_PyPrecallCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { next_instr--; int is_meth = is_method(stack_pointer, oparg); int nargs = oparg + is_meth; PyObject *callable = PEEK(nargs + 1); int err = _Py_Specialize_Precall(callable, next_instr, nargs, call_shape.kwnames, oparg); if (err < 0) { next_instr++; goto error; } DISPATCH_SAME_OPARG(); } else { STAT_INC(PRECALL, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(PRECALL); } } TARGET(CALL_ADAPTIVE) { _PyCallCache *cache = (_PyCallCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { next_instr--; int is_meth = is_method(stack_pointer, oparg); int nargs = oparg + is_meth; PyObject *callable = PEEK(nargs + 1); int err = _Py_Specialize_Call(callable, next_instr, nargs, call_shape.kwnames); if (err < 0) { next_instr++; goto error; } DISPATCH_SAME_OPARG(); } else { STAT_INC(CALL, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); goto call_function; } } TARGET(CALL_PY_EXACT_ARGS) { assert(call_shape.kwnames == NULL); DEOPT_IF(tstate->interp->eval_frame, CALL); _PyCallCache *cache = (_PyCallCache *)next_instr; int is_meth = is_method(stack_pointer, oparg); int argcount = oparg + is_meth; PyObject *callable = PEEK(argcount + 1); DEOPT_IF(!PyFunction_Check(callable), CALL); PyFunctionObject *func = (PyFunctionObject *)callable; DEOPT_IF(func->func_version != read_u32(cache->func_version), CALL); PyCodeObject *code = (PyCodeObject *)func->func_code; DEOPT_IF(code->co_argcount != argcount, CALL); STAT_INC(CALL, hit); _PyInterpreterFrame *new_frame = _PyFrame_Push(tstate, func); if (new_frame == NULL) { goto error; } CALL_STAT_INC(inlined_py_calls); STACK_SHRINK(argcount); for (int i = 0; i < argcount; i++) { new_frame->localsplus[i] = stack_pointer[i]; } for (int i = argcount; i < code->co_nlocalsplus; i++) { new_frame->localsplus[i] = NULL; } STACK_SHRINK(2-is_meth); _PyFrame_SetStackPointer(frame, stack_pointer); JUMPBY(INLINE_CACHE_ENTRIES_CALL); frame->prev_instr = next_instr - 1; new_frame->previous = frame; frame = cframe.current_frame = new_frame; goto start_frame; } TARGET(CALL_PY_WITH_DEFAULTS) { assert(call_shape.kwnames == NULL); DEOPT_IF(tstate->interp->eval_frame, CALL); _PyCallCache *cache = (_PyCallCache *)next_instr; int is_meth = is_method(stack_pointer, oparg); int argcount = oparg + is_meth; PyObject *callable = PEEK(argcount + 1); DEOPT_IF(!PyFunction_Check(callable), CALL); PyFunctionObject *func = (PyFunctionObject *)callable; DEOPT_IF(func->func_version != read_u32(cache->func_version), CALL); PyCodeObject *code = (PyCodeObject *)func->func_code; DEOPT_IF(argcount > code->co_argcount, CALL); int minargs = cache->min_args; DEOPT_IF(argcount < minargs, CALL); STAT_INC(CALL, hit); _PyInterpreterFrame *new_frame = _PyFrame_Push(tstate, func); if (new_frame == NULL) { goto error; } CALL_STAT_INC(inlined_py_calls); STACK_SHRINK(argcount); for (int i = 0; i < argcount; i++) { new_frame->localsplus[i] = stack_pointer[i]; } for (int i = argcount; i < code->co_argcount; i++) { PyObject *def = PyTuple_GET_ITEM(func->func_defaults, i - minargs); Py_INCREF(def); new_frame->localsplus[i] = def; } for (int i = code->co_argcount; i < code->co_nlocalsplus; i++) { new_frame->localsplus[i] = NULL; } STACK_SHRINK(2-is_meth); _PyFrame_SetStackPointer(frame, stack_pointer); JUMPBY(INLINE_CACHE_ENTRIES_CALL); frame->prev_instr = next_instr - 1; new_frame->previous = frame; frame = cframe.current_frame = new_frame; goto start_frame; } TARGET(PRECALL_NO_KW_TYPE_1) { assert(call_shape.kwnames == NULL); assert(cframe.use_tracing == 0); assert(oparg == 1); DEOPT_IF(is_method(stack_pointer, 1), PRECALL); PyObject *obj = TOP(); PyObject *callable = SECOND(); DEOPT_IF(callable != (PyObject *)&PyType_Type, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyObject *res = Py_NewRef(Py_TYPE(obj)); Py_DECREF(callable); Py_DECREF(obj); STACK_SHRINK(2); SET_TOP(res); DISPATCH(); } TARGET(PRECALL_NO_KW_STR_1) { assert(call_shape.kwnames == NULL); assert(cframe.use_tracing == 0); assert(oparg == 1); DEOPT_IF(is_method(stack_pointer, 1), PRECALL); PyObject *callable = PEEK(2); DEOPT_IF(callable != (PyObject *)&PyUnicode_Type, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyObject *arg = TOP(); PyObject *res = PyObject_Str(arg); Py_DECREF(arg); Py_DECREF(&PyUnicode_Type); STACK_SHRINK(2); SET_TOP(res); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_NO_KW_TUPLE_1) { assert(call_shape.kwnames == NULL); assert(oparg == 1); DEOPT_IF(is_method(stack_pointer, 1), PRECALL); PyObject *callable = PEEK(2); DEOPT_IF(callable != (PyObject *)&PyTuple_Type, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyObject *arg = TOP(); PyObject *res = PySequence_Tuple(arg); Py_DECREF(arg); Py_DECREF(&PyTuple_Type); STACK_SHRINK(2); SET_TOP(res); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_BUILTIN_CLASS) { int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; int kwnames_len = KWNAMES_LEN(); PyObject *callable = PEEK(total_args + 1); DEOPT_IF(!PyType_Check(callable), PRECALL); PyTypeObject *tp = (PyTypeObject *)callable; DEOPT_IF(tp->tp_vectorcall == NULL, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); STACK_SHRINK(total_args); PyObject *res = tp->tp_vectorcall((PyObject *)tp, stack_pointer, total_args-kwnames_len, call_shape.kwnames); call_shape.kwnames = NULL; /* Free the arguments. */ for (int i = 0; i < total_args; i++) { Py_DECREF(stack_pointer[i]); } Py_DECREF(tp); STACK_SHRINK(1-is_meth); SET_TOP(res); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_NO_KW_BUILTIN_O) { assert(cframe.use_tracing == 0); /* Builtin METH_O functions */ assert(call_shape.kwnames == NULL); int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; DEOPT_IF(total_args != 1, PRECALL); PyObject *callable = PEEK(total_args + 1); DEOPT_IF(!PyCFunction_CheckExact(callable), PRECALL); DEOPT_IF(PyCFunction_GET_FLAGS(callable) != METH_O, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyCFunction cfunc = PyCFunction_GET_FUNCTION(callable); // This is slower but CPython promises to check all non-vectorcall // function calls. if (_Py_EnterRecursiveCallTstate(tstate, " while calling a Python object")) { goto error; } PyObject *arg = TOP(); PyObject *res = _PyCFunction_TrampolineCall(cfunc, PyCFunction_GET_SELF(callable), arg); _Py_LeaveRecursiveCallTstate(tstate); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); Py_DECREF(arg); Py_DECREF(callable); STACK_SHRINK(2-is_meth); SET_TOP(res); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_NO_KW_BUILTIN_FAST) { assert(cframe.use_tracing == 0); /* Builtin METH_FASTCALL functions, without keywords */ assert(call_shape.kwnames == NULL); int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; PyObject *callable = PEEK(total_args + 1); DEOPT_IF(!PyCFunction_CheckExact(callable), PRECALL); DEOPT_IF(PyCFunction_GET_FLAGS(callable) != METH_FASTCALL, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyCFunction cfunc = PyCFunction_GET_FUNCTION(callable); STACK_SHRINK(total_args); /* res = func(self, args, nargs) */ PyObject *res = ((_PyCFunctionFast)(void(*)(void))cfunc)( PyCFunction_GET_SELF(callable), stack_pointer, total_args); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); /* Free the arguments. */ for (int i = 0; i < total_args; i++) { Py_DECREF(stack_pointer[i]); } STACK_SHRINK(2-is_meth); PUSH(res); Py_DECREF(callable); if (res == NULL) { /* Not deopting because this doesn't mean our optimization was wrong. `res` can be NULL for valid reasons. Eg. getattr(x, 'invalid'). In those cases an exception is set, so we must handle it. */ goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_BUILTIN_FAST_WITH_KEYWORDS) { assert(cframe.use_tracing == 0); /* Builtin METH_FASTCALL | METH_KEYWORDS functions */ int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; PyObject *callable = PEEK(total_args + 1); DEOPT_IF(!PyCFunction_CheckExact(callable), PRECALL); DEOPT_IF(PyCFunction_GET_FLAGS(callable) != (METH_FASTCALL | METH_KEYWORDS), PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); STACK_SHRINK(total_args); /* res = func(self, args, nargs, kwnames) */ _PyCFunctionFastWithKeywords cfunc = (_PyCFunctionFastWithKeywords)(void(*)(void)) PyCFunction_GET_FUNCTION(callable); PyObject *res = cfunc( PyCFunction_GET_SELF(callable), stack_pointer, total_args - KWNAMES_LEN(), call_shape.kwnames ); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); call_shape.kwnames = NULL; /* Free the arguments. */ for (int i = 0; i < total_args; i++) { Py_DECREF(stack_pointer[i]); } STACK_SHRINK(2-is_meth); PUSH(res); Py_DECREF(callable); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_NO_KW_LEN) { assert(cframe.use_tracing == 0); assert(call_shape.kwnames == NULL); /* len(o) */ int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; DEOPT_IF(total_args != 1, PRECALL); PyObject *callable = PEEK(total_args + 1); PyInterpreterState *interp = _PyInterpreterState_GET(); DEOPT_IF(callable != interp->callable_cache.len, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyObject *arg = TOP(); Py_ssize_t len_i = PyObject_Length(arg); if (len_i < 0) { goto error; } PyObject *res = PyLong_FromSsize_t(len_i); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); STACK_SHRINK(2-is_meth); SET_TOP(res); Py_DECREF(callable); Py_DECREF(arg); if (res == NULL) { goto error; } DISPATCH(); } TARGET(PRECALL_NO_KW_ISINSTANCE) { assert(cframe.use_tracing == 0); assert(call_shape.kwnames == NULL); /* isinstance(o, o2) */ int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; PyObject *callable = PEEK(total_args + 1); DEOPT_IF(total_args != 2, PRECALL); PyInterpreterState *interp = _PyInterpreterState_GET(); DEOPT_IF(callable != interp->callable_cache.isinstance, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyObject *cls = POP(); PyObject *inst = TOP(); int retval = PyObject_IsInstance(inst, cls); if (retval < 0) { Py_DECREF(cls); goto error; } PyObject *res = PyBool_FromLong(retval); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); STACK_SHRINK(2-is_meth); SET_TOP(res); Py_DECREF(inst); Py_DECREF(cls); Py_DECREF(callable); if (res == NULL) { goto error; } DISPATCH(); } TARGET(PRECALL_NO_KW_LIST_APPEND) { assert(cframe.use_tracing == 0); assert(call_shape.kwnames == NULL); assert(oparg == 1); PyObject *callable = PEEK(3); PyInterpreterState *interp = _PyInterpreterState_GET(); DEOPT_IF(callable != interp->callable_cache.list_append, PRECALL); PyObject *list = SECOND(); DEOPT_IF(!PyList_Check(list), PRECALL); STAT_INC(PRECALL, hit); PyObject *arg = POP(); if (_PyList_AppendTakeRef((PyListObject *)list, arg) < 0) { goto error; } STACK_SHRINK(2); Py_DECREF(list); Py_DECREF(callable); // PRECALL + CALL + POP_TOP JUMPBY(INLINE_CACHE_ENTRIES_PRECALL + 1 + INLINE_CACHE_ENTRIES_CALL + 1); assert(_Py_OPCODE(next_instr[-1]) == POP_TOP); DISPATCH(); } TARGET(PRECALL_NO_KW_METHOD_DESCRIPTOR_O) { assert(call_shape.kwnames == NULL); int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; PyMethodDescrObject *callable = (PyMethodDescrObject *)PEEK(total_args + 1); DEOPT_IF(total_args != 2, PRECALL); DEOPT_IF(!Py_IS_TYPE(callable, &PyMethodDescr_Type), PRECALL); PyMethodDef *meth = callable->d_method; DEOPT_IF(meth->ml_flags != METH_O, PRECALL); PyObject *arg = TOP(); PyObject *self = SECOND(); DEOPT_IF(!Py_IS_TYPE(self, callable->d_common.d_type), PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyCFunction cfunc = meth->ml_meth; // This is slower but CPython promises to check all non-vectorcall // function calls. if (_Py_EnterRecursiveCallTstate(tstate, " while calling a Python object")) { goto error; } PyObject *res = _PyCFunction_TrampolineCall(cfunc, self, arg); _Py_LeaveRecursiveCallTstate(tstate); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); Py_DECREF(self); Py_DECREF(arg); STACK_SHRINK(oparg + 1); SET_TOP(res); Py_DECREF(callable); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_METHOD_DESCRIPTOR_FAST_WITH_KEYWORDS) { int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; PyMethodDescrObject *callable = (PyMethodDescrObject *)PEEK(total_args + 1); DEOPT_IF(!Py_IS_TYPE(callable, &PyMethodDescr_Type), PRECALL); PyMethodDef *meth = callable->d_method; DEOPT_IF(meth->ml_flags != (METH_FASTCALL|METH_KEYWORDS), PRECALL); PyTypeObject *d_type = callable->d_common.d_type; PyObject *self = PEEK(total_args); DEOPT_IF(!Py_IS_TYPE(self, d_type), PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); int nargs = total_args-1; STACK_SHRINK(nargs); _PyCFunctionFastWithKeywords cfunc = (_PyCFunctionFastWithKeywords)(void(*)(void))meth->ml_meth; PyObject *res = cfunc(self, stack_pointer, nargs - KWNAMES_LEN(), call_shape.kwnames); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); call_shape.kwnames = NULL; /* Free the arguments. */ for (int i = 0; i < nargs; i++) { Py_DECREF(stack_pointer[i]); } Py_DECREF(self); STACK_SHRINK(2-is_meth); SET_TOP(res); Py_DECREF(callable); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_NO_KW_METHOD_DESCRIPTOR_NOARGS) { assert(call_shape.kwnames == NULL); assert(oparg == 0 || oparg == 1); int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; DEOPT_IF(total_args != 1, PRECALL); PyMethodDescrObject *callable = (PyMethodDescrObject *)SECOND(); DEOPT_IF(!Py_IS_TYPE(callable, &PyMethodDescr_Type), PRECALL); PyMethodDef *meth = callable->d_method; PyObject *self = TOP(); DEOPT_IF(!Py_IS_TYPE(self, callable->d_common.d_type), PRECALL); DEOPT_IF(meth->ml_flags != METH_NOARGS, PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); PyCFunction cfunc = meth->ml_meth; // This is slower but CPython promises to check all non-vectorcall // function calls. if (_Py_EnterRecursiveCallTstate(tstate, " while calling a Python object")) { goto error; } PyObject *res = _PyCFunction_TrampolineCall(cfunc, self, NULL); _Py_LeaveRecursiveCallTstate(tstate); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); Py_DECREF(self); STACK_SHRINK(oparg + 1); SET_TOP(res); Py_DECREF(callable); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(PRECALL_NO_KW_METHOD_DESCRIPTOR_FAST) { assert(call_shape.kwnames == NULL); int is_meth = is_method(stack_pointer, oparg); int total_args = oparg + is_meth; PyMethodDescrObject *callable = (PyMethodDescrObject *)PEEK(total_args + 1); /* Builtin METH_FASTCALL methods, without keywords */ DEOPT_IF(!Py_IS_TYPE(callable, &PyMethodDescr_Type), PRECALL); PyMethodDef *meth = callable->d_method; DEOPT_IF(meth->ml_flags != METH_FASTCALL, PRECALL); PyObject *self = PEEK(total_args); DEOPT_IF(!Py_IS_TYPE(self, callable->d_common.d_type), PRECALL); STAT_INC(PRECALL, hit); SKIP_CALL(); _PyCFunctionFast cfunc = (_PyCFunctionFast)(void(*)(void))meth->ml_meth; int nargs = total_args-1; STACK_SHRINK(nargs); PyObject *res = cfunc(self, stack_pointer, nargs); assert((res != NULL) ^ (_PyErr_Occurred(tstate) != NULL)); /* Clear the stack of the arguments. */ for (int i = 0; i < nargs; i++) { Py_DECREF(stack_pointer[i]); } Py_DECREF(self); STACK_SHRINK(2-is_meth); SET_TOP(res); Py_DECREF(callable); if (res == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(CALL_FUNCTION_EX) { PREDICTED(CALL_FUNCTION_EX); PyObject *func, *callargs, *kwargs = NULL, *result; if (oparg & 0x01) { kwargs = POP(); if (!PyDict_CheckExact(kwargs)) { PyObject *d = PyDict_New(); if (d == NULL) goto error; if (_PyDict_MergeEx(d, kwargs, 2) < 0) { Py_DECREF(d); format_kwargs_error(tstate, SECOND(), kwargs); Py_DECREF(kwargs); goto error; } Py_DECREF(kwargs); kwargs = d; } assert(PyDict_CheckExact(kwargs)); } callargs = POP(); func = TOP(); if (!PyTuple_CheckExact(callargs)) { if (check_args_iterable(tstate, func, callargs) < 0) { Py_DECREF(callargs); goto error; } Py_SETREF(callargs, PySequence_Tuple(callargs)); if (callargs == NULL) { goto error; } } assert(PyTuple_CheckExact(callargs)); result = do_call_core(tstate, func, callargs, kwargs, cframe.use_tracing); Py_DECREF(func); Py_DECREF(callargs); Py_XDECREF(kwargs); STACK_SHRINK(1); assert(TOP() == NULL); SET_TOP(result); if (result == NULL) { goto error; } CHECK_EVAL_BREAKER(); DISPATCH(); } TARGET(MAKE_FUNCTION) { PyObject *codeobj = POP(); PyFunctionObject *func = (PyFunctionObject *) PyFunction_New(codeobj, GLOBALS()); Py_DECREF(codeobj); if (func == NULL) { goto error; } if (oparg & 0x08) { assert(PyTuple_CheckExact(TOP())); func->func_closure = POP(); } if (oparg & 0x04) { assert(PyTuple_CheckExact(TOP())); func->func_annotations = POP(); } if (oparg & 0x02) { assert(PyDict_CheckExact(TOP())); func->func_kwdefaults = POP(); } if (oparg & 0x01) { assert(PyTuple_CheckExact(TOP())); func->func_defaults = POP(); } PUSH((PyObject *)func); DISPATCH(); } TARGET(RETURN_GENERATOR) { PyGenObject *gen = (PyGenObject *)_Py_MakeCoro(frame->f_func); if (gen == NULL) { goto error; } assert(EMPTY()); _PyFrame_SetStackPointer(frame, stack_pointer); _PyInterpreterFrame *gen_frame = (_PyInterpreterFrame *)gen->gi_iframe; _PyFrame_Copy(frame, gen_frame); assert(frame->frame_obj == NULL); gen->gi_frame_state = FRAME_CREATED; gen_frame->owner = FRAME_OWNED_BY_GENERATOR; _Py_LeaveRecursiveCallTstate(tstate); if (!frame->is_entry) { _PyInterpreterFrame *prev = frame->previous; _PyThreadState_PopFrame(tstate, frame); frame = cframe.current_frame = prev; _PyFrame_StackPush(frame, (PyObject *)gen); goto resume_frame; } /* Make sure that frame is in a valid state */ frame->stacktop = 0; frame->f_locals = NULL; Py_INCREF(frame->f_func); Py_INCREF(frame->f_code); /* Restore previous cframe and return. */ tstate->cframe = cframe.previous; tstate->cframe->use_tracing = cframe.use_tracing; assert(tstate->cframe->current_frame == frame->previous); assert(!_PyErr_Occurred(tstate)); return (PyObject *)gen; } TARGET(BUILD_SLICE) { PyObject *start, *stop, *step, *slice; if (oparg == 3) step = POP(); else step = NULL; stop = POP(); start = TOP(); slice = PySlice_New(start, stop, step); Py_DECREF(start); Py_DECREF(stop); Py_XDECREF(step); SET_TOP(slice); if (slice == NULL) goto error; DISPATCH(); } TARGET(FORMAT_VALUE) { /* Handles f-string value formatting. */ PyObject *result; PyObject *fmt_spec; PyObject *value; PyObject *(*conv_fn)(PyObject *); int which_conversion = oparg & FVC_MASK; int have_fmt_spec = (oparg & FVS_MASK) == FVS_HAVE_SPEC; fmt_spec = have_fmt_spec ? POP() : NULL; value = POP(); /* See if any conversion is specified. */ switch (which_conversion) { case FVC_NONE: conv_fn = NULL; break; case FVC_STR: conv_fn = PyObject_Str; break; case FVC_REPR: conv_fn = PyObject_Repr; break; case FVC_ASCII: conv_fn = PyObject_ASCII; break; default: _PyErr_Format(tstate, PyExc_SystemError, "unexpected conversion flag %d", which_conversion); goto error; } /* If there's a conversion function, call it and replace value with that result. Otherwise, just use value, without conversion. */ if (conv_fn != NULL) { result = conv_fn(value); Py_DECREF(value); if (result == NULL) { Py_XDECREF(fmt_spec); goto error; } value = result; } /* If value is a unicode object, and there's no fmt_spec, then we know the result of format(value) is value itself. In that case, skip calling format(). I plan to move this optimization in to PyObject_Format() itself. */ if (PyUnicode_CheckExact(value) && fmt_spec == NULL) { /* Do nothing, just transfer ownership to result. */ result = value; } else { /* Actually call format(). */ result = PyObject_Format(value, fmt_spec); Py_DECREF(value); Py_XDECREF(fmt_spec); if (result == NULL) { goto error; } } PUSH(result); DISPATCH(); } TARGET(COPY) { assert(oparg != 0); PyObject *peek = PEEK(oparg); Py_INCREF(peek); PUSH(peek); DISPATCH(); } TARGET(BINARY_OP) { PREDICTED(BINARY_OP); PyObject *rhs = POP(); PyObject *lhs = TOP(); assert(0 <= oparg); assert((unsigned)oparg < Py_ARRAY_LENGTH(binary_ops)); assert(binary_ops[oparg]); PyObject *res = binary_ops[oparg](lhs, rhs); Py_DECREF(lhs); Py_DECREF(rhs); SET_TOP(res); if (res == NULL) { goto error; } JUMPBY(INLINE_CACHE_ENTRIES_BINARY_OP); DISPATCH(); } TARGET(BINARY_OP_ADAPTIVE) { assert(cframe.use_tracing == 0); _PyBinaryOpCache *cache = (_PyBinaryOpCache *)next_instr; if (ADAPTIVE_COUNTER_IS_ZERO(cache)) { PyObject *lhs = SECOND(); PyObject *rhs = TOP(); next_instr--; _Py_Specialize_BinaryOp(lhs, rhs, next_instr, oparg, &GETLOCAL(0)); DISPATCH_SAME_OPARG(); } else { STAT_INC(BINARY_OP, deferred); DECREMENT_ADAPTIVE_COUNTER(cache); JUMP_TO_INSTRUCTION(BINARY_OP); } } TARGET(SWAP) { assert(oparg != 0); PyObject *top = TOP(); SET_TOP(PEEK(oparg)); PEEK(oparg) = top; DISPATCH(); } TARGET(EXTENDED_ARG) { assert(oparg); oparg <<= 8; oparg |= _Py_OPARG(*next_instr); // We might be tracing. To avoid breaking tracing guarantees in // quickened instructions, always deoptimize the next opcode: opcode = _PyOpcode_Deopt[_Py_OPCODE(*next_instr)]; PRE_DISPATCH_GOTO(); // CPython hasn't traced the following instruction historically // (DO_TRACING would clobber our extended oparg anyways), so just // skip our usual cframe.use_tracing check before dispatch. Also, // make sure the next instruction isn't a RESUME, since that needs // to trace properly (and shouldn't have an extended arg anyways): assert(opcode != RESUME); DISPATCH_GOTO(); } TARGET(EXTENDED_ARG_QUICK) { assert(cframe.use_tracing == 0); assert(oparg); int oldoparg = oparg; NEXTOPARG(); oparg |= oldoparg << 8; DISPATCH_GOTO(); } TARGET(CACHE) { Py_UNREACHABLE(); } #if USE_COMPUTED_GOTOS TARGET_DO_TRACING: #else case DO_TRACING: #endif { assert(cframe.use_tracing); assert(tstate->tracing == 0); if (INSTR_OFFSET() >= frame->f_code->_co_firsttraceable) { int instr_prev = _PyInterpreterFrame_LASTI(frame); frame->prev_instr = next_instr; TRACING_NEXTOPARG(); if (opcode == RESUME) { if (oparg < 2) { CHECK_EVAL_BREAKER(); } /* Call tracing */ TRACE_FUNCTION_ENTRY(); DTRACE_FUNCTION_ENTRY(); } else { /* line-by-line tracing support */ if (PyDTrace_LINE_ENABLED()) { maybe_dtrace_line(frame, &tstate->trace_info, instr_prev); } if (cframe.use_tracing && tstate->c_tracefunc != NULL && !tstate->tracing) { int err; /* see maybe_call_line_trace() for expository comments */ _PyFrame_SetStackPointer(frame, stack_pointer); err = maybe_call_line_trace(tstate->c_tracefunc, tstate->c_traceobj, tstate, frame, instr_prev); // Reload possibly changed frame fields: stack_pointer = _PyFrame_GetStackPointer(frame); frame->stacktop = -1; // next_instr is only reloaded if tracing *does not* raise. // This is consistent with the behavior of older Python // versions. If a trace function sets a new f_lineno and // *then* raises, we use the *old* location when searching // for an exception handler, displaying the traceback, and // so on: if (err) { // next_instr wasn't incremented at the start of this // instruction. Increment it before handling the error, // so that it looks the same as a "normal" instruction: next_instr++; goto error; } // Reload next_instr. Don't increment it, though, since // we're going to re-dispatch to the "true" instruction now: next_instr = frame->prev_instr; } } } TRACING_NEXTOPARG(); PRE_DISPATCH_GOTO(); DISPATCH_GOTO(); } #if USE_COMPUTED_GOTOS _unknown_opcode: #else EXTRA_CASES // From opcode.h, a 'case' for each unused opcode #endif /* Tell C compilers not to hold the opcode variable in the loop. next_instr points the current instruction without TARGET(). */ opcode = _Py_OPCODE(*next_instr); fprintf(stderr, "XXX lineno: %d, opcode: %d\n", _PyInterpreterFrame_GetLine(frame), opcode); _PyErr_SetString(tstate, PyExc_SystemError, "unknown opcode"); goto error; } /* End instructions */ /* This should never be reached. Every opcode should end with DISPATCH() or goto error. */ Py_UNREACHABLE(); /* Specialization misses */ miss: { STAT_INC(opcode, miss); opcode = _PyOpcode_Deopt[opcode]; STAT_INC(opcode, miss); /* The counter is always the first cache entry: */ _Py_CODEUNIT *counter = (_Py_CODEUNIT *)next_instr; *counter -= 1; if (*counter == 0) { int adaptive_opcode = _PyOpcode_Adaptive[opcode]; assert(adaptive_opcode); _Py_SET_OPCODE(next_instr[-1], adaptive_opcode); STAT_INC(opcode, deopt); *counter = adaptive_counter_start(); } next_instr--; DISPATCH_GOTO(); } binary_subscr_dict_error: { PyObject *sub = POP(); if (!_PyErr_Occurred(tstate)) { _PyErr_SetKeyError(sub); } Py_DECREF(sub); goto error; } unbound_local_error: { format_exc_check_arg(tstate, PyExc_UnboundLocalError, UNBOUNDLOCAL_ERROR_MSG, PyTuple_GetItem(frame->f_code->co_localsplusnames, oparg) ); goto error; } error: call_shape.kwnames = NULL; /* Double-check exception status. */ #ifdef NDEBUG if (!_PyErr_Occurred(tstate)) { _PyErr_SetString(tstate, PyExc_SystemError, "error return without exception set"); } #else assert(_PyErr_Occurred(tstate)); #endif /* Log traceback info. */ if (!_PyFrame_IsIncomplete(frame)) { PyFrameObject *f = _PyFrame_GetFrameObject(frame); if (f != NULL) { PyTraceBack_Here(f); } } if (tstate->c_tracefunc != NULL) { /* Make sure state is set to FRAME_UNWINDING for tracing */ call_exc_trace(tstate->c_tracefunc, tstate->c_traceobj, tstate, frame); } exception_unwind: { /* We can't use frame->f_lasti here, as RERAISE may have set it */ int offset = INSTR_OFFSET()-1; int level, handler, lasti; if (get_exception_handler(frame->f_code, offset, &level, &handler, &lasti) == 0) { // No handlers, so exit. assert(_PyErr_Occurred(tstate)); /* Pop remaining stack entries. */ PyObject **stackbase = _PyFrame_Stackbase(frame); while (stack_pointer > stackbase) { PyObject *o = POP(); Py_XDECREF(o); } assert(STACK_LEVEL() == 0); _PyFrame_SetStackPointer(frame, stack_pointer); TRACE_FUNCTION_UNWIND(); DTRACE_FUNCTION_EXIT(); goto exit_unwind; } assert(STACK_LEVEL() >= level); PyObject **new_top = _PyFrame_Stackbase(frame) + level; while (stack_pointer > new_top) { PyObject *v = POP(); Py_XDECREF(v); } PyObject *exc, *val, *tb; if (lasti) { int frame_lasti = _PyInterpreterFrame_LASTI(frame); PyObject *lasti = PyLong_FromLong(frame_lasti); if (lasti == NULL) { goto exception_unwind; } PUSH(lasti); } _PyErr_Fetch(tstate, &exc, &val, &tb); /* Make the raw exception data available to the handler, so a program can emulate the Python main loop. */ _PyErr_NormalizeException(tstate, &exc, &val, &tb); if (tb != NULL) PyException_SetTraceback(val, tb); else PyException_SetTraceback(val, Py_None); Py_XDECREF(tb); Py_XDECREF(exc); PUSH(val); JUMPTO(handler); /* Resume normal execution */ DISPATCH(); } } exit_unwind: assert(_PyErr_Occurred(tstate)); _Py_LeaveRecursiveCallTstate(tstate); if (frame->is_entry) { /* Restore previous cframe and exit */ tstate->cframe = cframe.previous; tstate->cframe->use_tracing = cframe.use_tracing; assert(tstate->cframe->current_frame == frame->previous); return NULL; } // GH-99729: We need to unlink the frame *before* clearing it: _PyInterpreterFrame *dying = frame; frame = cframe.current_frame = dying->previous; _PyEvalFrameClearAndPop(tstate, dying); resume_with_error: SET_LOCALS_FROM_FRAME(); goto error; } static void format_missing(PyThreadState *tstate, const char *kind, PyCodeObject *co, PyObject *names, PyObject *qualname) { int err; Py_ssize_t len = PyList_GET_SIZE(names); PyObject *name_str, *comma, *tail, *tmp; assert(PyList_CheckExact(names)); assert(len >= 1); /* Deal with the joys of natural language. */ switch (len) { case 1: name_str = PyList_GET_ITEM(names, 0); Py_INCREF(name_str); break; case 2: name_str = PyUnicode_FromFormat("%U and %U", PyList_GET_ITEM(names, len - 2), PyList_GET_ITEM(names, len - 1)); break; default: tail = PyUnicode_FromFormat(", %U, and %U", PyList_GET_ITEM(names, len - 2), PyList_GET_ITEM(names, len - 1)); if (tail == NULL) return; /* Chop off the last two objects in the list. This shouldn't actually fail, but we can't be too careful. */ err = PyList_SetSlice(names, len - 2, len, NULL); if (err == -1) { Py_DECREF(tail); return; } /* Stitch everything up into a nice comma-separated list. */ comma = PyUnicode_FromString(", "); if (comma == NULL) { Py_DECREF(tail); return; } tmp = PyUnicode_Join(comma, names); Py_DECREF(comma); if (tmp == NULL) { Py_DECREF(tail); return; } name_str = PyUnicode_Concat(tmp, tail); Py_DECREF(tmp); Py_DECREF(tail); break; } if (name_str == NULL) return; _PyErr_Format(tstate, PyExc_TypeError, "%U() missing %i required %s argument%s: %U", qualname, len, kind, len == 1 ? "" : "s", name_str); Py_DECREF(name_str); } static void missing_arguments(PyThreadState *tstate, PyCodeObject *co, Py_ssize_t missing, Py_ssize_t defcount, PyObject **localsplus, PyObject *qualname) { Py_ssize_t i, j = 0; Py_ssize_t start, end; int positional = (defcount != -1); const char *kind = positional ? "positional" : "keyword-only"; PyObject *missing_names; /* Compute the names of the arguments that are missing. */ missing_names = PyList_New(missing); if (missing_names == NULL) return; if (positional) { start = 0; end = co->co_argcount - defcount; } else { start = co->co_argcount; end = start + co->co_kwonlyargcount; } for (i = start; i < end; i++) { if (localsplus[i] == NULL) { PyObject *raw = PyTuple_GET_ITEM(co->co_localsplusnames, i); PyObject *name = PyObject_Repr(raw); if (name == NULL) { Py_DECREF(missing_names); return; } PyList_SET_ITEM(missing_names, j++, name); } } assert(j == missing); format_missing(tstate, kind, co, missing_names, qualname); Py_DECREF(missing_names); } static void too_many_positional(PyThreadState *tstate, PyCodeObject *co, Py_ssize_t given, PyObject *defaults, PyObject **localsplus, PyObject *qualname) { int plural; Py_ssize_t kwonly_given = 0; Py_ssize_t i; PyObject *sig, *kwonly_sig; Py_ssize_t co_argcount = co->co_argcount; assert((co->co_flags & CO_VARARGS) == 0); /* Count missing keyword-only args. */ for (i = co_argcount; i < co_argcount + co->co_kwonlyargcount; i++) { if (localsplus[i] != NULL) { kwonly_given++; } } Py_ssize_t defcount = defaults == NULL ? 0 : PyTuple_GET_SIZE(defaults); if (defcount) { Py_ssize_t atleast = co_argcount - defcount; plural = 1; sig = PyUnicode_FromFormat("from %zd to %zd", atleast, co_argcount); } else { plural = (co_argcount != 1); sig = PyUnicode_FromFormat("%zd", co_argcount); } if (sig == NULL) return; if (kwonly_given) { const char *format = " positional argument%s (and %zd keyword-only argument%s)"; kwonly_sig = PyUnicode_FromFormat(format, given != 1 ? "s" : "", kwonly_given, kwonly_given != 1 ? "s" : ""); if (kwonly_sig == NULL) { Py_DECREF(sig); return; } } else { /* This will not fail. */ kwonly_sig = PyUnicode_FromString(""); assert(kwonly_sig != NULL); } _PyErr_Format(tstate, PyExc_TypeError, "%U() takes %U positional argument%s but %zd%U %s given", qualname, sig, plural ? "s" : "", given, kwonly_sig, given == 1 && !kwonly_given ? "was" : "were"); Py_DECREF(sig); Py_DECREF(kwonly_sig); } static int positional_only_passed_as_keyword(PyThreadState *tstate, PyCodeObject *co, Py_ssize_t kwcount, PyObject* kwnames, PyObject *qualname) { int posonly_conflicts = 0; PyObject* posonly_names = PyList_New(0); if (posonly_names == NULL) { goto fail; } for(int k=0; k < co->co_posonlyargcount; k++){ PyObject* posonly_name = PyTuple_GET_ITEM(co->co_localsplusnames, k); for (int k2=0; k2 0) { if(PyList_Append(posonly_names, kwname) != 0) { goto fail; } posonly_conflicts++; } else if (cmp < 0) { goto fail; } } } if (posonly_conflicts) { PyObject* comma = PyUnicode_FromString(", "); if (comma == NULL) { goto fail; } PyObject* error_names = PyUnicode_Join(comma, posonly_names); Py_DECREF(comma); if (error_names == NULL) { goto fail; } _PyErr_Format(tstate, PyExc_TypeError, "%U() got some positional-only arguments passed" " as keyword arguments: '%U'", qualname, error_names); Py_DECREF(error_names); goto fail; } Py_DECREF(posonly_names); return 0; fail: Py_XDECREF(posonly_names); return 1; } static inline unsigned char * scan_back_to_entry_start(unsigned char *p) { for (; (p[0]&128) == 0; p--); return p; } static inline unsigned char * skip_to_next_entry(unsigned char *p, unsigned char *end) { while (p < end && ((p[0] & 128) == 0)) { p++; } return p; } #define MAX_LINEAR_SEARCH 40 static int get_exception_handler(PyCodeObject *code, int index, int *level, int *handler, int *lasti) { unsigned char *start = (unsigned char *)PyBytes_AS_STRING(code->co_exceptiontable); unsigned char *end = start + PyBytes_GET_SIZE(code->co_exceptiontable); /* Invariants: * start_table == end_table OR * start_table points to a legal entry and end_table points * beyond the table or to a legal entry that is after index. */ if (end - start > MAX_LINEAR_SEARCH) { int offset; parse_varint(start, &offset); if (offset > index) { return 0; } do { unsigned char * mid = start + ((end-start)>>1); mid = scan_back_to_entry_start(mid); parse_varint(mid, &offset); if (offset > index) { end = mid; } else { start = mid; } } while (end - start > MAX_LINEAR_SEARCH); } unsigned char *scan = start; while (scan < end) { int start_offset, size; scan = parse_varint(scan, &start_offset); if (start_offset > index) { break; } scan = parse_varint(scan, &size); if (start_offset + size > index) { scan = parse_varint(scan, handler); int depth_and_lasti; parse_varint(scan, &depth_and_lasti); *level = depth_and_lasti >> 1; *lasti = depth_and_lasti & 1; return 1; } scan = skip_to_next_entry(scan, end); } return 0; } static int initialize_locals(PyThreadState *tstate, PyFunctionObject *func, PyObject **localsplus, PyObject *const *args, Py_ssize_t argcount, PyObject *kwnames) { PyCodeObject *co = (PyCodeObject*)func->func_code; const Py_ssize_t total_args = co->co_argcount + co->co_kwonlyargcount; /* Create a dictionary for keyword parameters (**kwags) */ PyObject *kwdict; Py_ssize_t i; if (co->co_flags & CO_VARKEYWORDS) { kwdict = PyDict_New(); if (kwdict == NULL) { goto fail_pre_positional; } i = total_args; if (co->co_flags & CO_VARARGS) { i++; } assert(localsplus[i] == NULL); localsplus[i] = kwdict; } else { kwdict = NULL; } /* Copy all positional arguments into local variables */ Py_ssize_t j, n; if (argcount > co->co_argcount) { n = co->co_argcount; } else { n = argcount; } for (j = 0; j < n; j++) { PyObject *x = args[j]; assert(localsplus[j] == NULL); localsplus[j] = x; } /* Pack other positional arguments into the *args argument */ if (co->co_flags & CO_VARARGS) { PyObject *u = NULL; if (argcount == n) { u = Py_NewRef(&_Py_SINGLETON(tuple_empty)); } else { assert(args != NULL); u = _PyTuple_FromArraySteal(args + n, argcount - n); } if (u == NULL) { goto fail_post_positional; } assert(localsplus[total_args] == NULL); localsplus[total_args] = u; } else if (argcount > n) { /* Too many postional args. Error is reported later */ for (j = n; j < argcount; j++) { Py_DECREF(args[j]); } } /* Handle keyword arguments */ if (kwnames != NULL) { Py_ssize_t kwcount = PyTuple_GET_SIZE(kwnames); for (i = 0; i < kwcount; i++) { PyObject **co_varnames; PyObject *keyword = PyTuple_GET_ITEM(kwnames, i); PyObject *value = args[i+argcount]; Py_ssize_t j; if (keyword == NULL || !PyUnicode_Check(keyword)) { _PyErr_Format(tstate, PyExc_TypeError, "%U() keywords must be strings", func->func_qualname); goto kw_fail; } /* Speed hack: do raw pointer compares. As names are normally interned this should almost always hit. */ co_varnames = ((PyTupleObject *)(co->co_localsplusnames))->ob_item; for (j = co->co_posonlyargcount; j < total_args; j++) { PyObject *varname = co_varnames[j]; if (varname == keyword) { goto kw_found; } } /* Slow fallback, just in case */ for (j = co->co_posonlyargcount; j < total_args; j++) { PyObject *varname = co_varnames[j]; int cmp = PyObject_RichCompareBool( keyword, varname, Py_EQ); if (cmp > 0) { goto kw_found; } else if (cmp < 0) { goto kw_fail; } } assert(j >= total_args); if (kwdict == NULL) { if (co->co_posonlyargcount && positional_only_passed_as_keyword(tstate, co, kwcount, kwnames, func->func_qualname)) { goto kw_fail; } _PyErr_Format(tstate, PyExc_TypeError, "%U() got an unexpected keyword argument '%S'", func->func_qualname, keyword); goto kw_fail; } if (PyDict_SetItem(kwdict, keyword, value) == -1) { goto kw_fail; } Py_DECREF(value); continue; kw_fail: for (;i < kwcount; i++) { PyObject *value = args[i+argcount]; Py_DECREF(value); } goto fail_post_args; kw_found: if (localsplus[j] != NULL) { _PyErr_Format(tstate, PyExc_TypeError, "%U() got multiple values for argument '%S'", func->func_qualname, keyword); goto kw_fail; } localsplus[j] = value; } } /* Check the number of positional arguments */ if ((argcount > co->co_argcount) && !(co->co_flags & CO_VARARGS)) { too_many_positional(tstate, co, argcount, func->func_defaults, localsplus, func->func_qualname); goto fail_post_args; } /* Add missing positional arguments (copy default values from defs) */ if (argcount < co->co_argcount) { Py_ssize_t defcount = func->func_defaults == NULL ? 0 : PyTuple_GET_SIZE(func->func_defaults); Py_ssize_t m = co->co_argcount - defcount; Py_ssize_t missing = 0; for (i = argcount; i < m; i++) { if (localsplus[i] == NULL) { missing++; } } if (missing) { missing_arguments(tstate, co, missing, defcount, localsplus, func->func_qualname); goto fail_post_args; } if (n > m) i = n - m; else i = 0; if (defcount) { PyObject **defs = &PyTuple_GET_ITEM(func->func_defaults, 0); for (; i < defcount; i++) { if (localsplus[m+i] == NULL) { PyObject *def = defs[i]; Py_INCREF(def); localsplus[m+i] = def; } } } } /* Add missing keyword arguments (copy default values from kwdefs) */ if (co->co_kwonlyargcount > 0) { Py_ssize_t missing = 0; for (i = co->co_argcount; i < total_args; i++) { if (localsplus[i] != NULL) continue; PyObject *varname = PyTuple_GET_ITEM(co->co_localsplusnames, i); if (func->func_kwdefaults != NULL) { PyObject *def = PyDict_GetItemWithError(func->func_kwdefaults, varname); if (def) { Py_INCREF(def); localsplus[i] = def; continue; } else if (_PyErr_Occurred(tstate)) { goto fail_post_args; } } missing++; } if (missing) { missing_arguments(tstate, co, missing, -1, localsplus, func->func_qualname); goto fail_post_args; } } return 0; fail_pre_positional: for (j = 0; j < argcount; j++) { Py_DECREF(args[j]); } /* fall through */ fail_post_positional: if (kwnames) { Py_ssize_t kwcount = PyTuple_GET_SIZE(kwnames); for (j = argcount; j < argcount+kwcount; j++) { Py_DECREF(args[j]); } } /* fall through */ fail_post_args: return -1; } /* Consumes references to func and all the args */ static _PyInterpreterFrame * _PyEvalFramePushAndInit(PyThreadState *tstate, PyFunctionObject *func, PyObject *locals, PyObject* const* args, size_t argcount, PyObject *kwnames) { PyCodeObject * code = (PyCodeObject *)func->func_code; size_t size = code->co_nlocalsplus + code->co_stacksize + FRAME_SPECIALS_SIZE; CALL_STAT_INC(frames_pushed); _PyInterpreterFrame *frame = _PyThreadState_BumpFramePointer(tstate, size); if (frame == NULL) { goto fail; } _PyFrame_InitializeSpecials(frame, func, locals, code->co_nlocalsplus); PyObject **localsarray = &frame->localsplus[0]; for (int i = 0; i < code->co_nlocalsplus; i++) { localsarray[i] = NULL; } if (initialize_locals(tstate, func, localsarray, args, argcount, kwnames)) { assert(frame->owner != FRAME_OWNED_BY_GENERATOR); _PyEvalFrameClearAndPop(tstate, frame); return NULL; } return frame; fail: /* Consume the references */ for (size_t i = 0; i < argcount; i++) { Py_DECREF(args[i]); } if (kwnames) { Py_ssize_t kwcount = PyTuple_GET_SIZE(kwnames); for (Py_ssize_t i = 0; i < kwcount; i++) { Py_DECREF(args[i+argcount]); } } PyErr_NoMemory(); return NULL; } static void _PyEvalFrameClearAndPop(PyThreadState *tstate, _PyInterpreterFrame * frame) { // Make sure that this is, indeed, the top frame. We can't check this in // _PyThreadState_PopFrame, since f_code is already cleared at that point: assert((PyObject **)frame + frame->f_code->co_nlocalsplus + frame->f_code->co_stacksize + FRAME_SPECIALS_SIZE == tstate->datastack_top); tstate->recursion_remaining--; assert(frame->frame_obj == NULL || frame->frame_obj->f_frame == frame); assert(frame->owner == FRAME_OWNED_BY_THREAD); _PyFrame_Clear(frame); tstate->recursion_remaining++; _PyThreadState_PopFrame(tstate, frame); } PyObject * _PyEval_Vector(PyThreadState *tstate, PyFunctionObject *func, PyObject *locals, PyObject* const* args, size_t argcount, PyObject *kwnames) { /* _PyEvalFramePushAndInit consumes the references * to func and all its arguments */ Py_INCREF(func); for (size_t i = 0; i < argcount; i++) { Py_INCREF(args[i]); } if (kwnames) { Py_ssize_t kwcount = PyTuple_GET_SIZE(kwnames); for (Py_ssize_t i = 0; i < kwcount; i++) { Py_INCREF(args[i+argcount]); } } _PyInterpreterFrame *frame = _PyEvalFramePushAndInit( tstate, func, locals, args, argcount, kwnames); if (frame == NULL) { return NULL; } PyObject *retval = _PyEval_EvalFrame(tstate, frame, 0); assert( _PyFrame_GetStackPointer(frame) == _PyFrame_Stackbase(frame) || _PyFrame_GetStackPointer(frame) == frame->localsplus ); _PyEvalFrameClearAndPop(tstate, frame); return retval; } /* Legacy API */ PyObject * PyEval_EvalCodeEx(PyObject *_co, PyObject *globals, PyObject *locals, PyObject *const *args, int argcount, PyObject *const *kws, int kwcount, PyObject *const *defs, int defcount, PyObject *kwdefs, PyObject *closure) { PyThreadState *tstate = _PyThreadState_GET(); PyObject *res = NULL; PyObject *defaults = _PyTuple_FromArray(defs, defcount); if (defaults == NULL) { return NULL; } PyObject *builtins = _PyEval_BuiltinsFromGlobals(tstate, globals); // borrowed ref if (builtins == NULL) { Py_DECREF(defaults); return NULL; } if (locals == NULL) { locals = globals; } PyObject *kwnames = NULL; PyObject *const *allargs; PyObject **newargs = NULL; PyFunctionObject *func = NULL; if (kwcount == 0) { allargs = args; } else { kwnames = PyTuple_New(kwcount); if (kwnames == NULL) { goto fail; } newargs = PyMem_Malloc(sizeof(PyObject *)*(kwcount+argcount)); if (newargs == NULL) { goto fail; } for (int i = 0; i < argcount; i++) { newargs[i] = args[i]; } for (int i = 0; i < kwcount; i++) { Py_INCREF(kws[2*i]); PyTuple_SET_ITEM(kwnames, i, kws[2*i]); newargs[argcount+i] = kws[2*i+1]; } allargs = newargs; } PyFrameConstructor constr = { .fc_globals = globals, .fc_builtins = builtins, .fc_name = ((PyCodeObject *)_co)->co_name, .fc_qualname = ((PyCodeObject *)_co)->co_name, .fc_code = _co, .fc_defaults = defaults, .fc_kwdefaults = kwdefs, .fc_closure = closure }; func = _PyFunction_FromConstructor(&constr); if (func == NULL) { goto fail; } res = _PyEval_Vector(tstate, func, locals, allargs, argcount, kwnames); fail: Py_XDECREF(func); Py_XDECREF(kwnames); PyMem_Free(newargs); Py_DECREF(defaults); return res; } /* Logic for the raise statement (too complicated for inlining). This *consumes* a reference count to each of its arguments. */ static int do_raise(PyThreadState *tstate, PyObject *exc, PyObject *cause) { PyObject *type = NULL, *value = NULL; if (exc == NULL) { /* Reraise */ _PyErr_StackItem *exc_info = _PyErr_GetTopmostException(tstate); value = exc_info->exc_value; if (Py_IsNone(value) || value == NULL) { _PyErr_SetString(tstate, PyExc_RuntimeError, "No active exception to reraise"); return 0; } assert(PyExceptionInstance_Check(value)); type = PyExceptionInstance_Class(value); Py_XINCREF(type); Py_XINCREF(value); PyObject *tb = PyException_GetTraceback(value); /* new ref */ _PyErr_Restore(tstate, type, value, tb); return 1; } /* We support the following forms of raise: raise raise raise */ if (PyExceptionClass_Check(exc)) { type = exc; value = _PyObject_CallNoArgs(exc); if (value == NULL) goto raise_error; if (!PyExceptionInstance_Check(value)) { _PyErr_Format(tstate, PyExc_TypeError, "calling %R should have returned an instance of " "BaseException, not %R", type, Py_TYPE(value)); goto raise_error; } } else if (PyExceptionInstance_Check(exc)) { value = exc; type = PyExceptionInstance_Class(exc); Py_INCREF(type); } else { /* Not something you can raise. You get an exception anyway, just not what you specified :-) */ Py_DECREF(exc); _PyErr_SetString(tstate, PyExc_TypeError, "exceptions must derive from BaseException"); goto raise_error; } assert(type != NULL); assert(value != NULL); if (cause) { PyObject *fixed_cause; if (PyExceptionClass_Check(cause)) { fixed_cause = _PyObject_CallNoArgs(cause); if (fixed_cause == NULL) goto raise_error; Py_DECREF(cause); } else if (PyExceptionInstance_Check(cause)) { fixed_cause = cause; } else if (Py_IsNone(cause)) { Py_DECREF(cause); fixed_cause = NULL; } else { _PyErr_SetString(tstate, PyExc_TypeError, "exception causes must derive from " "BaseException"); goto raise_error; } PyException_SetCause(value, fixed_cause); } _PyErr_SetObject(tstate, type, value); /* _PyErr_SetObject incref's its arguments */ Py_DECREF(value); Py_DECREF(type); return 0; raise_error: Py_XDECREF(value); Py_XDECREF(type); Py_XDECREF(cause); return 0; } /* Logic for matching an exception in an except* clause (too complicated for inlining). */ static int exception_group_match(PyObject* exc_value, PyObject *match_type, PyObject **match, PyObject **rest) { if (Py_IsNone(exc_value)) { *match = Py_NewRef(Py_None); *rest = Py_NewRef(Py_None); return 0; } assert(PyExceptionInstance_Check(exc_value)); if (PyErr_GivenExceptionMatches(exc_value, match_type)) { /* Full match of exc itself */ bool is_eg = _PyBaseExceptionGroup_Check(exc_value); if (is_eg) { *match = Py_NewRef(exc_value); } else { /* naked exception - wrap it */ PyObject *excs = PyTuple_Pack(1, exc_value); if (excs == NULL) { return -1; } PyObject *wrapped = _PyExc_CreateExceptionGroup("", excs); Py_DECREF(excs); if (wrapped == NULL) { return -1; } *match = wrapped; } *rest = Py_NewRef(Py_None); return 0; } /* exc_value does not match match_type. * Check for partial match if it's an exception group. */ if (_PyBaseExceptionGroup_Check(exc_value)) { PyObject *pair = PyObject_CallMethod(exc_value, "split", "(O)", match_type); if (pair == NULL) { return -1; } assert(PyTuple_CheckExact(pair)); assert(PyTuple_GET_SIZE(pair) == 2); *match = Py_NewRef(PyTuple_GET_ITEM(pair, 0)); *rest = Py_NewRef(PyTuple_GET_ITEM(pair, 1)); Py_DECREF(pair); return 0; } /* no match */ *match = Py_NewRef(Py_None); *rest = Py_NewRef(Py_None); return 0; } /* Iterate v argcnt times and store the results on the stack (via decreasing sp). Return 1 for success, 0 if error. If argcntafter == -1, do a simple unpack. If it is >= 0, do an unpack with a variable target. */ static int unpack_iterable(PyThreadState *tstate, PyObject *v, int argcnt, int argcntafter, PyObject **sp) { int i = 0, j = 0; Py_ssize_t ll = 0; PyObject *it; /* iter(v) */ PyObject *w; PyObject *l = NULL; /* variable list */ assert(v != NULL); it = PyObject_GetIter(v); if (it == NULL) { if (_PyErr_ExceptionMatches(tstate, PyExc_TypeError) && Py_TYPE(v)->tp_iter == NULL && !PySequence_Check(v)) { _PyErr_Format(tstate, PyExc_TypeError, "cannot unpack non-iterable %.200s object", Py_TYPE(v)->tp_name); } return 0; } for (; i < argcnt; i++) { w = PyIter_Next(it); if (w == NULL) { /* Iterator done, via error or exhaustion. */ if (!_PyErr_Occurred(tstate)) { if (argcntafter == -1) { _PyErr_Format(tstate, PyExc_ValueError, "not enough values to unpack " "(expected %d, got %d)", argcnt, i); } else { _PyErr_Format(tstate, PyExc_ValueError, "not enough values to unpack " "(expected at least %d, got %d)", argcnt + argcntafter, i); } } goto Error; } *--sp = w; } if (argcntafter == -1) { /* We better have exhausted the iterator now. */ w = PyIter_Next(it); if (w == NULL) { if (_PyErr_Occurred(tstate)) goto Error; Py_DECREF(it); return 1; } Py_DECREF(w); _PyErr_Format(tstate, PyExc_ValueError, "too many values to unpack (expected %d)", argcnt); goto Error; } l = PySequence_List(it); if (l == NULL) goto Error; *--sp = l; i++; ll = PyList_GET_SIZE(l); if (ll < argcntafter) { _PyErr_Format(tstate, PyExc_ValueError, "not enough values to unpack (expected at least %d, got %zd)", argcnt + argcntafter, argcnt + ll); goto Error; } /* Pop the "after-variable" args off the list. */ for (j = argcntafter; j > 0; j--, i++) { *--sp = PyList_GET_ITEM(l, ll - j); } /* Resize the list. */ Py_SET_SIZE(l, ll - argcntafter); Py_DECREF(it); return 1; Error: for (; i > 0; i--, sp++) Py_DECREF(*sp); Py_XDECREF(it); return 0; } static void call_exc_trace(Py_tracefunc func, PyObject *self, PyThreadState *tstate, _PyInterpreterFrame *f) { PyObject *type, *value, *traceback, *orig_traceback, *arg; int err; _PyErr_Fetch(tstate, &type, &value, &orig_traceback); if (value == NULL) { value = Py_None; Py_INCREF(value); } _PyErr_NormalizeException(tstate, &type, &value, &orig_traceback); traceback = (orig_traceback != NULL) ? orig_traceback : Py_None; arg = PyTuple_Pack(3, type, value, traceback); if (arg == NULL) { _PyErr_Restore(tstate, type, value, orig_traceback); return; } err = call_trace(func, self, tstate, f, PyTrace_EXCEPTION, arg); Py_DECREF(arg); if (err == 0) { _PyErr_Restore(tstate, type, value, orig_traceback); } else { Py_XDECREF(type); Py_XDECREF(value); Py_XDECREF(orig_traceback); } } static int call_trace_protected(Py_tracefunc func, PyObject *obj, PyThreadState *tstate, _PyInterpreterFrame *frame, int what, PyObject *arg) { PyObject *type, *value, *traceback; int err; _PyErr_Fetch(tstate, &type, &value, &traceback); err = call_trace(func, obj, tstate, frame, what, arg); if (err == 0) { _PyErr_Restore(tstate, type, value, traceback); return 0; } else { Py_XDECREF(type); Py_XDECREF(value); Py_XDECREF(traceback); return -1; } } static void initialize_trace_info(PyTraceInfo *trace_info, _PyInterpreterFrame *frame) { PyCodeObject *code = frame->f_code; if (trace_info->code != code) { trace_info->code = code; _PyCode_InitAddressRange(code, &trace_info->bounds); } } void PyThreadState_EnterTracing(PyThreadState *tstate) { tstate->tracing++; tstate->cframe->use_tracing = 0; } void PyThreadState_LeaveTracing(PyThreadState *tstate) { assert(tstate->tracing > 0 && tstate->cframe->use_tracing == 0); tstate->tracing--; _PyThreadState_UpdateTracingState(tstate); } static int call_trace(Py_tracefunc func, PyObject *obj, PyThreadState *tstate, _PyInterpreterFrame *frame, int what, PyObject *arg) { int result; if (tstate->tracing) { return 0; } PyFrameObject *f = _PyFrame_GetFrameObject(frame); if (f == NULL) { return -1; } int old_what = tstate->tracing_what; tstate->tracing_what = what; PyThreadState_EnterTracing(tstate); assert(_PyInterpreterFrame_LASTI(frame) >= 0); if (_PyCode_InitLineArray(frame->f_code)) { return -1; } f->f_lineno = _PyCode_LineNumberFromArray(frame->f_code, _PyInterpreterFrame_LASTI(frame)); result = func(obj, f, what, arg); f->f_lineno = 0; PyThreadState_LeaveTracing(tstate); tstate->tracing_what = old_what; return result; } PyObject* _PyEval_CallTracing(PyObject *func, PyObject *args) { // Save and disable tracing PyThreadState *tstate = _PyThreadState_GET(); int save_tracing = tstate->tracing; int save_use_tracing = tstate->cframe->use_tracing; tstate->tracing = 0; // Call the tracing function PyObject *result = PyObject_Call(func, args, NULL); // Restore tracing tstate->tracing = save_tracing; tstate->cframe->use_tracing = save_use_tracing; return result; } /* See Objects/lnotab_notes.txt for a description of how tracing works. */ static int maybe_call_line_trace(Py_tracefunc func, PyObject *obj, PyThreadState *tstate, _PyInterpreterFrame *frame, int instr_prev) { int result = 0; /* If the last instruction falls at the start of a line or if it represents a jump backwards, update the frame's line number and then call the trace function if we're tracing source lines. */ if (_PyCode_InitLineArray(frame->f_code)) { return -1; } int lastline; if (instr_prev <= frame->f_code->_co_firsttraceable) { lastline = -1; } else { lastline = _PyCode_LineNumberFromArray(frame->f_code, instr_prev); } int line = _PyCode_LineNumberFromArray(frame->f_code, _PyInterpreterFrame_LASTI(frame)); PyFrameObject *f = _PyFrame_GetFrameObject(frame); if (f == NULL) { return -1; } if (line != -1 && f->f_trace_lines) { /* Trace backward edges (except in 'yield from') or if line number has changed */ int trace = line != lastline || (_PyInterpreterFrame_LASTI(frame) < instr_prev && // SEND has no quickened forms, so no need to use _PyOpcode_Deopt // here: _Py_OPCODE(*frame->prev_instr) != SEND); if (trace) { result = call_trace(func, obj, tstate, frame, PyTrace_LINE, Py_None); } } /* Always emit an opcode event if we're tracing all opcodes. */ if (f->f_trace_opcodes && result == 0) { result = call_trace(func, obj, tstate, frame, PyTrace_OPCODE, Py_None); } return result; } int _PyEval_SetProfile(PyThreadState *tstate, Py_tracefunc func, PyObject *arg) { assert(is_tstate_valid(tstate)); /* The caller must hold the GIL */ assert(PyGILState_Check()); static int reentrant = 0; if (reentrant) { _PyErr_SetString(tstate, PyExc_RuntimeError, "Cannot install a profile function " "while another profile function is being installed"); reentrant = 0; return -1; } reentrant = 1; /* Call _PySys_Audit() in the context of the current thread state, even if tstate is not the current thread state. */ PyThreadState *current_tstate = _PyThreadState_GET(); if (_PySys_Audit(current_tstate, "sys.setprofile", NULL) < 0) { reentrant = 0; return -1; } PyObject *profileobj = tstate->c_profileobj; tstate->c_profilefunc = NULL; tstate->c_profileobj = NULL; /* Must make sure that tracing is not ignored if 'profileobj' is freed */ _PyThreadState_UpdateTracingState(tstate); Py_XDECREF(profileobj); Py_XINCREF(arg); tstate->c_profileobj = arg; tstate->c_profilefunc = func; /* Flag that tracing or profiling is turned on */ _PyThreadState_UpdateTracingState(tstate); reentrant = 0; return 0; } void PyEval_SetProfile(Py_tracefunc func, PyObject *arg) { PyThreadState *tstate = _PyThreadState_GET(); if (_PyEval_SetProfile(tstate, func, arg) < 0) { /* Log _PySys_Audit() error */ _PyErr_WriteUnraisableMsg("in PyEval_SetProfile", NULL); } } int _PyEval_SetTrace(PyThreadState *tstate, Py_tracefunc func, PyObject *arg) { assert(is_tstate_valid(tstate)); /* The caller must hold the GIL */ assert(PyGILState_Check()); static int reentrant = 0; if (reentrant) { _PyErr_SetString(tstate, PyExc_RuntimeError, "Cannot install a trace function " "while another trace function is being installed"); reentrant = 0; return -1; } reentrant = 1; /* Call _PySys_Audit() in the context of the current thread state, even if tstate is not the current thread state. */ PyThreadState *current_tstate = _PyThreadState_GET(); if (_PySys_Audit(current_tstate, "sys.settrace", NULL) < 0) { reentrant = 0; return -1; } PyObject *traceobj = tstate->c_traceobj; tstate->c_tracefunc = NULL; tstate->c_traceobj = NULL; /* Must make sure that profiling is not ignored if 'traceobj' is freed */ _PyThreadState_UpdateTracingState(tstate); Py_XINCREF(arg); Py_XDECREF(traceobj); tstate->c_traceobj = arg; tstate->c_tracefunc = func; /* Flag that tracing or profiling is turned on */ _PyThreadState_UpdateTracingState(tstate); reentrant = 0; return 0; } void PyEval_SetTrace(Py_tracefunc func, PyObject *arg) { PyThreadState *tstate = _PyThreadState_GET(); if (_PyEval_SetTrace(tstate, func, arg) < 0) { /* Log _PySys_Audit() error */ _PyErr_WriteUnraisableMsg("in PyEval_SetTrace", NULL); } } int _PyEval_SetCoroutineOriginTrackingDepth(int depth) { PyThreadState *tstate = _PyThreadState_GET(); if (depth < 0) { _PyErr_SetString(tstate, PyExc_ValueError, "depth must be >= 0"); return -1; } tstate->coroutine_origin_tracking_depth = depth; return 0; } int _PyEval_GetCoroutineOriginTrackingDepth(void) { PyThreadState *tstate = _PyThreadState_GET(); return tstate->coroutine_origin_tracking_depth; } int _PyEval_SetAsyncGenFirstiter(PyObject *firstiter) { PyThreadState *tstate = _PyThreadState_GET(); if (_PySys_Audit(tstate, "sys.set_asyncgen_hook_firstiter", NULL) < 0) { return -1; } Py_XINCREF(firstiter); Py_XSETREF(tstate->async_gen_firstiter, firstiter); return 0; } PyObject * _PyEval_GetAsyncGenFirstiter(void) { PyThreadState *tstate = _PyThreadState_GET(); return tstate->async_gen_firstiter; } int _PyEval_SetAsyncGenFinalizer(PyObject *finalizer) { PyThreadState *tstate = _PyThreadState_GET(); if (_PySys_Audit(tstate, "sys.set_asyncgen_hook_finalizer", NULL) < 0) { return -1; } Py_XINCREF(finalizer); Py_XSETREF(tstate->async_gen_finalizer, finalizer); return 0; } PyObject * _PyEval_GetAsyncGenFinalizer(void) { PyThreadState *tstate = _PyThreadState_GET(); return tstate->async_gen_finalizer; } _PyInterpreterFrame * _PyEval_GetFrame(void) { PyThreadState *tstate = _PyThreadState_GET(); return tstate->cframe->current_frame; } PyFrameObject * PyEval_GetFrame(void) { _PyInterpreterFrame *frame = _PyEval_GetFrame(); while (frame && _PyFrame_IsIncomplete(frame)) { frame = frame->previous; } if (frame == NULL) { return NULL; } PyFrameObject *f = _PyFrame_GetFrameObject(frame); if (f == NULL) { PyErr_Clear(); } return f; } PyObject * _PyEval_GetBuiltins(PyThreadState *tstate) { _PyInterpreterFrame *frame = tstate->cframe->current_frame; if (frame != NULL) { return frame->f_builtins; } return tstate->interp->builtins; } PyObject * PyEval_GetBuiltins(void) { PyThreadState *tstate = _PyThreadState_GET(); return _PyEval_GetBuiltins(tstate); } /* Convenience function to get a builtin from its name */ PyObject * _PyEval_GetBuiltin(PyObject *name) { PyThreadState *tstate = _PyThreadState_GET(); PyObject *attr = PyDict_GetItemWithError(PyEval_GetBuiltins(), name); if (attr) { Py_INCREF(attr); } else if (!_PyErr_Occurred(tstate)) { _PyErr_SetObject(tstate, PyExc_AttributeError, name); } return attr; } PyObject * _PyEval_GetBuiltinId(_Py_Identifier *name) { return _PyEval_GetBuiltin(_PyUnicode_FromId(name)); } PyObject * PyEval_GetLocals(void) { PyThreadState *tstate = _PyThreadState_GET(); _PyInterpreterFrame *current_frame = tstate->cframe->current_frame; if (current_frame == NULL) { _PyErr_SetString(tstate, PyExc_SystemError, "frame does not exist"); return NULL; } if (_PyFrame_FastToLocalsWithError(current_frame) < 0) { return NULL; } PyObject *locals = current_frame->f_locals; assert(locals != NULL); return locals; } PyObject * PyEval_GetGlobals(void) { PyThreadState *tstate = _PyThreadState_GET(); _PyInterpreterFrame *current_frame = tstate->cframe->current_frame; if (current_frame == NULL) { return NULL; } return current_frame->f_globals; } int PyEval_MergeCompilerFlags(PyCompilerFlags *cf) { PyThreadState *tstate = _PyThreadState_GET(); _PyInterpreterFrame *current_frame = tstate->cframe->current_frame; int result = cf->cf_flags != 0; if (current_frame != NULL) { const int codeflags = current_frame->f_code->co_flags; const int compilerflags = codeflags & PyCF_MASK; if (compilerflags) { result = 1; cf->cf_flags |= compilerflags; } } return result; } const char * PyEval_GetFuncName(PyObject *func) { if (PyMethod_Check(func)) return PyEval_GetFuncName(PyMethod_GET_FUNCTION(func)); else if (PyFunction_Check(func)) return PyUnicode_AsUTF8(((PyFunctionObject*)func)->func_name); else if (PyCFunction_Check(func)) return ((PyCFunctionObject*)func)->m_ml->ml_name; else return Py_TYPE(func)->tp_name; } const char * PyEval_GetFuncDesc(PyObject *func) { if (PyMethod_Check(func)) return "()"; else if (PyFunction_Check(func)) return "()"; else if (PyCFunction_Check(func)) return "()"; else return " object"; } #define C_TRACE(x, call) \ if (use_tracing && tstate->c_profilefunc) { \ if (call_trace(tstate->c_profilefunc, tstate->c_profileobj, \ tstate, tstate->cframe->current_frame, \ PyTrace_C_CALL, func)) { \ x = NULL; \ } \ else { \ x = call; \ if (tstate->c_profilefunc != NULL) { \ if (x == NULL) { \ call_trace_protected(tstate->c_profilefunc, \ tstate->c_profileobj, \ tstate, tstate->cframe->current_frame, \ PyTrace_C_EXCEPTION, func); \ /* XXX should pass (type, value, tb) */ \ } else { \ if (call_trace(tstate->c_profilefunc, \ tstate->c_profileobj, \ tstate, tstate->cframe->current_frame, \ PyTrace_C_RETURN, func)) { \ Py_DECREF(x); \ x = NULL; \ } \ } \ } \ } \ } else { \ x = call; \ } static PyObject * trace_call_function(PyThreadState *tstate, PyObject *func, PyObject **args, Py_ssize_t nargs, PyObject *kwnames) { int use_tracing = 1; PyObject *x; if (PyCFunction_CheckExact(func) || PyCMethod_CheckExact(func)) { C_TRACE(x, PyObject_Vectorcall(func, args, nargs, kwnames)); return x; } else if (Py_IS_TYPE(func, &PyMethodDescr_Type) && nargs > 0) { /* We need to create a temporary bound method as argument for profiling. If nargs == 0, then this cannot work because we have no "self". In any case, the call itself would raise TypeError (foo needs an argument), so we just skip profiling. */ PyObject *self = args[0]; func = Py_TYPE(func)->tp_descr_get(func, self, (PyObject*)Py_TYPE(self)); if (func == NULL) { return NULL; } C_TRACE(x, PyObject_Vectorcall(func, args+1, nargs-1, kwnames)); Py_DECREF(func); return x; } return PyObject_Vectorcall(func, args, nargs | PY_VECTORCALL_ARGUMENTS_OFFSET, kwnames); } static PyObject * do_call_core(PyThreadState *tstate, PyObject *func, PyObject *callargs, PyObject *kwdict, int use_tracing ) { PyObject *result; if (PyCFunction_CheckExact(func) || PyCMethod_CheckExact(func)) { C_TRACE(result, PyObject_Call(func, callargs, kwdict)); return result; } else if (Py_IS_TYPE(func, &PyMethodDescr_Type)) { Py_ssize_t nargs = PyTuple_GET_SIZE(callargs); if (nargs > 0 && use_tracing) { /* We need to create a temporary bound method as argument for profiling. If nargs == 0, then this cannot work because we have no "self". In any case, the call itself would raise TypeError (foo needs an argument), so we just skip profiling. */ PyObject *self = PyTuple_GET_ITEM(callargs, 0); func = Py_TYPE(func)->tp_descr_get(func, self, (PyObject*)Py_TYPE(self)); if (func == NULL) { return NULL; } C_TRACE(result, _PyObject_FastCallDictTstate( tstate, func, &_PyTuple_ITEMS(callargs)[1], nargs - 1, kwdict)); Py_DECREF(func); return result; } } return PyObject_Call(func, callargs, kwdict); } /* Extract a slice index from a PyLong or an object with the nb_index slot defined, and store in *pi. Silently reduce values larger than PY_SSIZE_T_MAX to PY_SSIZE_T_MAX, and silently boost values less than PY_SSIZE_T_MIN to PY_SSIZE_T_MIN. Return 0 on error, 1 on success. */ int _PyEval_SliceIndex(PyObject *v, Py_ssize_t *pi) { PyThreadState *tstate = _PyThreadState_GET(); if (!Py_IsNone(v)) { Py_ssize_t x; if (_PyIndex_Check(v)) { x = PyNumber_AsSsize_t(v, NULL); if (x == -1 && _PyErr_Occurred(tstate)) return 0; } else { _PyErr_SetString(tstate, PyExc_TypeError, "slice indices must be integers or " "None or have an __index__ method"); return 0; } *pi = x; } return 1; } int _PyEval_SliceIndexNotNone(PyObject *v, Py_ssize_t *pi) { PyThreadState *tstate = _PyThreadState_GET(); Py_ssize_t x; if (_PyIndex_Check(v)) { x = PyNumber_AsSsize_t(v, NULL); if (x == -1 && _PyErr_Occurred(tstate)) return 0; } else { _PyErr_SetString(tstate, PyExc_TypeError, "slice indices must be integers or " "have an __index__ method"); return 0; } *pi = x; return 1; } static PyObject * import_name(PyThreadState *tstate, _PyInterpreterFrame *frame, PyObject *name, PyObject *fromlist, PyObject *level) { PyObject *import_func, *res; PyObject* stack[5]; import_func = _PyDict_GetItemWithError(frame->f_builtins, &_Py_ID(__import__)); if (import_func == NULL) { if (!_PyErr_Occurred(tstate)) { _PyErr_SetString(tstate, PyExc_ImportError, "__import__ not found"); } return NULL; } PyObject *locals = frame->f_locals; /* Fast path for not overloaded __import__. */ if (import_func == tstate->interp->import_func) { int ilevel = _PyLong_AsInt(level); if (ilevel == -1 && _PyErr_Occurred(tstate)) { return NULL; } res = PyImport_ImportModuleLevelObject( name, frame->f_globals, locals == NULL ? Py_None :locals, fromlist, ilevel); return res; } Py_INCREF(import_func); stack[0] = name; stack[1] = frame->f_globals; stack[2] = locals == NULL ? Py_None : locals; stack[3] = fromlist; stack[4] = level; res = _PyObject_FastCall(import_func, stack, 5); Py_DECREF(import_func); return res; } static PyObject * import_from(PyThreadState *tstate, PyObject *v, PyObject *name) { PyObject *x; PyObject *fullmodname, *pkgname, *pkgpath, *pkgname_or_unknown, *errmsg; if (_PyObject_LookupAttr(v, name, &x) != 0) { return x; } /* Issue #17636: in case this failed because of a circular relative import, try to fallback on reading the module directly from sys.modules. */ pkgname = PyObject_GetAttr(v, &_Py_ID(__name__)); if (pkgname == NULL) { goto error; } if (!PyUnicode_Check(pkgname)) { Py_CLEAR(pkgname); goto error; } fullmodname = PyUnicode_FromFormat("%U.%U", pkgname, name); if (fullmodname == NULL) { Py_DECREF(pkgname); return NULL; } x = PyImport_GetModule(fullmodname); Py_DECREF(fullmodname); if (x == NULL && !_PyErr_Occurred(tstate)) { goto error; } Py_DECREF(pkgname); return x; error: pkgpath = PyModule_GetFilenameObject(v); if (pkgname == NULL) { pkgname_or_unknown = PyUnicode_FromString(""); if (pkgname_or_unknown == NULL) { Py_XDECREF(pkgpath); return NULL; } } else { pkgname_or_unknown = pkgname; } if (pkgpath == NULL || !PyUnicode_Check(pkgpath)) { _PyErr_Clear(tstate); errmsg = PyUnicode_FromFormat( "cannot import name %R from %R (unknown location)", name, pkgname_or_unknown ); /* NULL checks for errmsg and pkgname done by PyErr_SetImportError. */ PyErr_SetImportError(errmsg, pkgname, NULL); } else { PyObject *spec = PyObject_GetAttr(v, &_Py_ID(__spec__)); const char *fmt = _PyModuleSpec_IsInitializing(spec) ? "cannot import name %R from partially initialized module %R " "(most likely due to a circular import) (%S)" : "cannot import name %R from %R (%S)"; Py_XDECREF(spec); errmsg = PyUnicode_FromFormat(fmt, name, pkgname_or_unknown, pkgpath); /* NULL checks for errmsg and pkgname done by PyErr_SetImportError. */ PyErr_SetImportError(errmsg, pkgname, pkgpath); } Py_XDECREF(errmsg); Py_XDECREF(pkgname_or_unknown); Py_XDECREF(pkgpath); return NULL; } static int import_all_from(PyThreadState *tstate, PyObject *locals, PyObject *v) { PyObject *all, *dict, *name, *value; int skip_leading_underscores = 0; int pos, err; if (_PyObject_LookupAttr(v, &_Py_ID(__all__), &all) < 0) { return -1; /* Unexpected error */ } if (all == NULL) { if (_PyObject_LookupAttr(v, &_Py_ID(__dict__), &dict) < 0) { return -1; } if (dict == NULL) { _PyErr_SetString(tstate, PyExc_ImportError, "from-import-* object has no __dict__ and no __all__"); return -1; } all = PyMapping_Keys(dict); Py_DECREF(dict); if (all == NULL) return -1; skip_leading_underscores = 1; } for (pos = 0, err = 0; ; pos++) { name = PySequence_GetItem(all, pos); if (name == NULL) { if (!_PyErr_ExceptionMatches(tstate, PyExc_IndexError)) { err = -1; } else { _PyErr_Clear(tstate); } break; } if (!PyUnicode_Check(name)) { PyObject *modname = PyObject_GetAttr(v, &_Py_ID(__name__)); if (modname == NULL) { Py_DECREF(name); err = -1; break; } if (!PyUnicode_Check(modname)) { _PyErr_Format(tstate, PyExc_TypeError, "module __name__ must be a string, not %.100s", Py_TYPE(modname)->tp_name); } else { _PyErr_Format(tstate, PyExc_TypeError, "%s in %U.%s must be str, not %.100s", skip_leading_underscores ? "Key" : "Item", modname, skip_leading_underscores ? "__dict__" : "__all__", Py_TYPE(name)->tp_name); } Py_DECREF(modname); Py_DECREF(name); err = -1; break; } if (skip_leading_underscores) { if (PyUnicode_READY(name) == -1) { Py_DECREF(name); err = -1; break; } if (PyUnicode_READ_CHAR(name, 0) == '_') { Py_DECREF(name); continue; } } value = PyObject_GetAttr(v, name); if (value == NULL) err = -1; else if (PyDict_CheckExact(locals)) err = PyDict_SetItem(locals, name, value); else err = PyObject_SetItem(locals, name, value); Py_DECREF(name); Py_XDECREF(value); if (err != 0) break; } Py_DECREF(all); return err; } #define CANNOT_CATCH_MSG "catching classes that do not inherit from "\ "BaseException is not allowed" #define CANNOT_EXCEPT_STAR_EG "catching ExceptionGroup with except* "\ "is not allowed. Use except instead." static int check_except_type_valid(PyThreadState *tstate, PyObject* right) { if (PyTuple_Check(right)) { Py_ssize_t i, length; length = PyTuple_GET_SIZE(right); for (i = 0; i < length; i++) { PyObject *exc = PyTuple_GET_ITEM(right, i); if (!PyExceptionClass_Check(exc)) { _PyErr_SetString(tstate, PyExc_TypeError, CANNOT_CATCH_MSG); return -1; } } } else { if (!PyExceptionClass_Check(right)) { _PyErr_SetString(tstate, PyExc_TypeError, CANNOT_CATCH_MSG); return -1; } } return 0; } static int check_except_star_type_valid(PyThreadState *tstate, PyObject* right) { if (check_except_type_valid(tstate, right) < 0) { return -1; } /* reject except *ExceptionGroup */ int is_subclass = 0; if (PyTuple_Check(right)) { Py_ssize_t length = PyTuple_GET_SIZE(right); for (Py_ssize_t i = 0; i < length; i++) { PyObject *exc = PyTuple_GET_ITEM(right, i); is_subclass = PyObject_IsSubclass(exc, PyExc_BaseExceptionGroup); if (is_subclass < 0) { return -1; } if (is_subclass) { break; } } } else { is_subclass = PyObject_IsSubclass(right, PyExc_BaseExceptionGroup); if (is_subclass < 0) { return -1; } } if (is_subclass) { _PyErr_SetString(tstate, PyExc_TypeError, CANNOT_EXCEPT_STAR_EG); return -1; } return 0; } static int check_args_iterable(PyThreadState *tstate, PyObject *func, PyObject *args) { if (Py_TYPE(args)->tp_iter == NULL && !PySequence_Check(args)) { /* check_args_iterable() may be called with a live exception: * clear it to prevent calling _PyObject_FunctionStr() with an * exception set. */ _PyErr_Clear(tstate); PyObject *funcstr = _PyObject_FunctionStr(func); if (funcstr != NULL) { _PyErr_Format(tstate, PyExc_TypeError, "%U argument after * must be an iterable, not %.200s", funcstr, Py_TYPE(args)->tp_name); Py_DECREF(funcstr); } return -1; } return 0; } static void format_kwargs_error(PyThreadState *tstate, PyObject *func, PyObject *kwargs) { /* _PyDict_MergeEx raises attribute * error (percolated from an attempt * to get 'keys' attribute) instead of * a type error if its second argument * is not a mapping. */ if (_PyErr_ExceptionMatches(tstate, PyExc_AttributeError)) { _PyErr_Clear(tstate); PyObject *funcstr = _PyObject_FunctionStr(func); if (funcstr != NULL) { _PyErr_Format( tstate, PyExc_TypeError, "%U argument after ** must be a mapping, not %.200s", funcstr, Py_TYPE(kwargs)->tp_name); Py_DECREF(funcstr); } } else if (_PyErr_ExceptionMatches(tstate, PyExc_KeyError)) { PyObject *exc, *val, *tb; _PyErr_Fetch(tstate, &exc, &val, &tb); if (val && PyTuple_Check(val) && PyTuple_GET_SIZE(val) == 1) { _PyErr_Clear(tstate); PyObject *funcstr = _PyObject_FunctionStr(func); if (funcstr != NULL) { PyObject *key = PyTuple_GET_ITEM(val, 0); _PyErr_Format( tstate, PyExc_TypeError, "%U got multiple values for keyword argument '%S'", funcstr, key); Py_DECREF(funcstr); } Py_XDECREF(exc); Py_XDECREF(val); Py_XDECREF(tb); } else { _PyErr_Restore(tstate, exc, val, tb); } } } static void format_exc_check_arg(PyThreadState *tstate, PyObject *exc, const char *format_str, PyObject *obj) { const char *obj_str; if (!obj) return; obj_str = PyUnicode_AsUTF8(obj); if (!obj_str) return; _PyErr_Format(tstate, exc, format_str, obj_str); if (exc == PyExc_NameError) { // Include the name in the NameError exceptions to offer suggestions later. PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); PyErr_NormalizeException(&type, &value, &traceback); if (PyErr_GivenExceptionMatches(value, PyExc_NameError)) { PyNameErrorObject* exc = (PyNameErrorObject*) value; if (exc->name == NULL) { // We do not care if this fails because we are going to restore the // NameError anyway. (void)PyObject_SetAttr(value, &_Py_ID(name), obj); } } PyErr_Restore(type, value, traceback); } } static void format_exc_unbound(PyThreadState *tstate, PyCodeObject *co, int oparg) { PyObject *name; /* Don't stomp existing exception */ if (_PyErr_Occurred(tstate)) return; name = PyTuple_GET_ITEM(co->co_localsplusnames, oparg); if (oparg < co->co_nplaincellvars + co->co_nlocals) { format_exc_check_arg(tstate, PyExc_UnboundLocalError, UNBOUNDLOCAL_ERROR_MSG, name); } else { format_exc_check_arg(tstate, PyExc_NameError, UNBOUNDFREE_ERROR_MSG, name); } } static void format_awaitable_error(PyThreadState *tstate, PyTypeObject *type, int oparg) { if (type->tp_as_async == NULL || type->tp_as_async->am_await == NULL) { if (oparg == 1) { _PyErr_Format(tstate, PyExc_TypeError, "'async with' received an object from __aenter__ " "that does not implement __await__: %.100s", type->tp_name); } else if (oparg == 2) { _PyErr_Format(tstate, PyExc_TypeError, "'async with' received an object from __aexit__ " "that does not implement __await__: %.100s", type->tp_name); } } } #ifdef Py_STATS static PyObject * getarray(uint64_t a[256]) { int i; PyObject *l = PyList_New(256); if (l == NULL) return NULL; for (i = 0; i < 256; i++) { PyObject *x = PyLong_FromUnsignedLongLong(a[i]); if (x == NULL) { Py_DECREF(l); return NULL; } PyList_SET_ITEM(l, i, x); } for (i = 0; i < 256; i++) a[i] = 0; return l; } PyObject * _Py_GetDXProfile(PyObject *self, PyObject *args) { int i; PyObject *l = PyList_New(257); if (l == NULL) return NULL; for (i = 0; i < 256; i++) { PyObject *x = getarray(_py_stats.opcode_stats[i].pair_count); if (x == NULL) { Py_DECREF(l); return NULL; } PyList_SET_ITEM(l, i, x); } PyObject *counts = PyList_New(256); if (counts == NULL) { Py_DECREF(l); return NULL; } for (i = 0; i < 256; i++) { PyObject *x = PyLong_FromUnsignedLongLong( _py_stats.opcode_stats[i].execution_count); if (x == NULL) { Py_DECREF(counts); Py_DECREF(l); return NULL; } PyList_SET_ITEM(counts, i, x); } PyList_SET_ITEM(l, 256, counts); return l; } #endif Py_ssize_t _PyEval_RequestCodeExtraIndex(freefunc free) { PyInterpreterState *interp = _PyInterpreterState_GET(); Py_ssize_t new_index; if (interp->co_extra_user_count == MAX_CO_EXTRA_USERS - 1) { return -1; } new_index = interp->co_extra_user_count++; interp->co_extra_freefuncs[new_index] = free; return new_index; } static void dtrace_function_entry(_PyInterpreterFrame *frame) { const char *filename; const char *funcname; int lineno; PyCodeObject *code = frame->f_code; filename = PyUnicode_AsUTF8(code->co_filename); funcname = PyUnicode_AsUTF8(code->co_name); lineno = _PyInterpreterFrame_GetLine(frame); PyDTrace_FUNCTION_ENTRY(filename, funcname, lineno); } static void dtrace_function_return(_PyInterpreterFrame *frame) { const char *filename; const char *funcname; int lineno; PyCodeObject *code = frame->f_code; filename = PyUnicode_AsUTF8(code->co_filename); funcname = PyUnicode_AsUTF8(code->co_name); lineno = _PyInterpreterFrame_GetLine(frame); PyDTrace_FUNCTION_RETURN(filename, funcname, lineno); } /* DTrace equivalent of maybe_call_line_trace. */ static void maybe_dtrace_line(_PyInterpreterFrame *frame, PyTraceInfo *trace_info, int instr_prev) { const char *co_filename, *co_name; /* If the last instruction executed isn't in the current instruction window, reset the window. */ initialize_trace_info(trace_info, frame); int lastline = _PyCode_CheckLineNumber(instr_prev*sizeof(_Py_CODEUNIT), &trace_info->bounds); int addr = _PyInterpreterFrame_LASTI(frame) * sizeof(_Py_CODEUNIT); int line = _PyCode_CheckLineNumber(addr, &trace_info->bounds); if (line != -1) { /* Trace backward edges or first instruction of a new line */ if (_PyInterpreterFrame_LASTI(frame) < instr_prev || (line != lastline && addr == trace_info->bounds.ar_start)) { co_filename = PyUnicode_AsUTF8(frame->f_code->co_filename); if (!co_filename) { co_filename = "?"; } co_name = PyUnicode_AsUTF8(frame->f_code->co_name); if (!co_name) { co_name = "?"; } PyDTrace_LINE(co_filename, co_name, line); } } } /* Implement Py_EnterRecursiveCall() and Py_LeaveRecursiveCall() as functions for the limited API. */ #undef Py_EnterRecursiveCall int Py_EnterRecursiveCall(const char *where) { return _Py_EnterRecursiveCall(where); } #undef Py_LeaveRecursiveCall void Py_LeaveRecursiveCall(void) { _Py_LeaveRecursiveCall(); }