#include "Python.h" #include "rotatingtree.h" /************************************************************/ /* Written by Brett Rosen and Ted Czotter */ struct _ProfilerEntry; /* represents a function called from another function */ typedef struct _ProfilerSubEntry { rotating_node_t header; _PyTime_t tt; _PyTime_t it; long callcount; long recursivecallcount; long recursionLevel; } ProfilerSubEntry; /* represents a function or user defined block */ typedef struct _ProfilerEntry { rotating_node_t header; PyObject *userObj; /* PyCodeObject, or a descriptive str for builtins */ _PyTime_t tt; /* total time in this entry */ _PyTime_t it; /* inline time in this entry (not in subcalls) */ long callcount; /* how many times this was called */ long recursivecallcount; /* how many times called recursively */ long recursionLevel; rotating_node_t *calls; } ProfilerEntry; typedef struct _ProfilerContext { _PyTime_t t0; _PyTime_t subt; struct _ProfilerContext *previous; ProfilerEntry *ctxEntry; } ProfilerContext; typedef struct { PyObject_HEAD rotating_node_t *profilerEntries; ProfilerContext *currentProfilerContext; ProfilerContext *freelistProfilerContext; int flags; PyObject *externalTimer; double externalTimerUnit; } ProfilerObject; #define POF_ENABLED 0x001 #define POF_SUBCALLS 0x002 #define POF_BUILTINS 0x004 #define POF_NOMEMORY 0x100 /*[clinic input] module _lsprof class _lsprof.Profiler "ProfilerObject *" "&ProfilerType" [clinic start generated code]*/ /*[clinic end generated code: output=da39a3ee5e6b4b0d input=e349ac952152f336]*/ #include "clinic/_lsprof.c.h" typedef struct { PyTypeObject *profiler_type; PyTypeObject *stats_entry_type; PyTypeObject *stats_subentry_type; } _lsprof_state; static inline _lsprof_state* _lsprof_get_state(PyObject *module) { void *state = PyModule_GetState(module); assert(state != NULL); return (_lsprof_state *)state; } /*** External Timers ***/ static _PyTime_t CallExternalTimer(ProfilerObject *pObj) { PyObject *o = _PyObject_CallNoArgs(pObj->externalTimer); if (o == NULL) { PyErr_WriteUnraisable(pObj->externalTimer); return 0; } _PyTime_t result; int err; if (pObj->externalTimerUnit > 0.0) { /* interpret the result as an integer that will be scaled in profiler_getstats() */ err = _PyTime_FromNanosecondsObject(&result, o); } else { /* interpret the result as a double measured in seconds. As the profiler works with _PyTime_t internally we convert it to a large integer */ err = _PyTime_FromSecondsObject(&result, o, _PyTime_ROUND_FLOOR); } Py_DECREF(o); if (err < 0) { PyErr_WriteUnraisable(pObj->externalTimer); return 0; } return result; } static inline _PyTime_t call_timer(ProfilerObject *pObj) { if (pObj->externalTimer != NULL) { return CallExternalTimer(pObj); } else { return _PyTime_GetPerfCounter(); } } /*** ProfilerObject ***/ static PyObject * normalizeUserObj(PyObject *obj) { PyCFunctionObject *fn; if (!PyCFunction_Check(obj)) { Py_INCREF(obj); return obj; } /* Replace built-in function objects with a descriptive string because of built-in methods -- keeping a reference to __self__ is probably not a good idea. */ fn = (PyCFunctionObject *)obj; if (fn->m_self == NULL) { /* built-in function: look up the module name */ PyObject *mod = fn->m_module; PyObject *modname = NULL; if (mod != NULL) { if (PyUnicode_Check(mod)) { modname = mod; Py_INCREF(modname); } else if (PyModule_Check(mod)) { modname = PyModule_GetNameObject(mod); if (modname == NULL) PyErr_Clear(); } } if (modname != NULL) { if (!_PyUnicode_EqualToASCIIString(modname, "builtins")) { PyObject *result; result = PyUnicode_FromFormat("<%U.%s>", modname, fn->m_ml->ml_name); Py_DECREF(modname); return result; } Py_DECREF(modname); } return PyUnicode_FromFormat("<%s>", fn->m_ml->ml_name); } else { /* built-in method: try to return repr(getattr(type(__self__), __name__)) */ PyObject *self = fn->m_self; PyObject *name = PyUnicode_FromString(fn->m_ml->ml_name); PyObject *modname = fn->m_module; if (name != NULL) { PyObject *mo = _PyType_Lookup(Py_TYPE(self), name); Py_XINCREF(mo); Py_DECREF(name); if (mo != NULL) { PyObject *res = PyObject_Repr(mo); Py_DECREF(mo); if (res != NULL) return res; } } /* Otherwise, use __module__ */ PyErr_Clear(); if (modname != NULL && PyUnicode_Check(modname)) return PyUnicode_FromFormat("", modname, fn->m_ml->ml_name); else return PyUnicode_FromFormat("", fn->m_ml->ml_name); } } static ProfilerEntry* newProfilerEntry(ProfilerObject *pObj, void *key, PyObject *userObj) { ProfilerEntry *self; self = (ProfilerEntry*) PyMem_Malloc(sizeof(ProfilerEntry)); if (self == NULL) { pObj->flags |= POF_NOMEMORY; return NULL; } userObj = normalizeUserObj(userObj); if (userObj == NULL) { PyErr_Clear(); PyMem_Free(self); pObj->flags |= POF_NOMEMORY; return NULL; } self->header.key = key; self->userObj = userObj; self->tt = 0; self->it = 0; self->callcount = 0; self->recursivecallcount = 0; self->recursionLevel = 0; self->calls = EMPTY_ROTATING_TREE; RotatingTree_Add(&pObj->profilerEntries, &self->header); return self; } static ProfilerEntry* getEntry(ProfilerObject *pObj, void *key) { return (ProfilerEntry*) RotatingTree_Get(&pObj->profilerEntries, key); } static ProfilerSubEntry * getSubEntry(ProfilerObject *pObj, ProfilerEntry *caller, ProfilerEntry* entry) { return (ProfilerSubEntry*) RotatingTree_Get(&caller->calls, (void *)entry); } static ProfilerSubEntry * newSubEntry(ProfilerObject *pObj, ProfilerEntry *caller, ProfilerEntry* entry) { ProfilerSubEntry *self; self = (ProfilerSubEntry*) PyMem_Malloc(sizeof(ProfilerSubEntry)); if (self == NULL) { pObj->flags |= POF_NOMEMORY; return NULL; } self->header.key = (void *)entry; self->tt = 0; self->it = 0; self->callcount = 0; self->recursivecallcount = 0; self->recursionLevel = 0; RotatingTree_Add(&caller->calls, &self->header); return self; } static int freeSubEntry(rotating_node_t *header, void *arg) { ProfilerSubEntry *subentry = (ProfilerSubEntry*) header; PyMem_Free(subentry); return 0; } static int freeEntry(rotating_node_t *header, void *arg) { ProfilerEntry *entry = (ProfilerEntry*) header; RotatingTree_Enum(entry->calls, freeSubEntry, NULL); Py_DECREF(entry->userObj); PyMem_Free(entry); return 0; } static void clearEntries(ProfilerObject *pObj) { RotatingTree_Enum(pObj->profilerEntries, freeEntry, NULL); pObj->profilerEntries = EMPTY_ROTATING_TREE; /* release the memory hold by the ProfilerContexts */ if (pObj->currentProfilerContext) { PyMem_Free(pObj->currentProfilerContext); pObj->currentProfilerContext = NULL; } while (pObj->freelistProfilerContext) { ProfilerContext *c = pObj->freelistProfilerContext; pObj->freelistProfilerContext = c->previous; PyMem_Free(c); } pObj->freelistProfilerContext = NULL; } static void initContext(ProfilerObject *pObj, ProfilerContext *self, ProfilerEntry *entry) { self->ctxEntry = entry; self->subt = 0; self->previous = pObj->currentProfilerContext; pObj->currentProfilerContext = self; ++entry->recursionLevel; if ((pObj->flags & POF_SUBCALLS) && self->previous) { /* find or create an entry for me in my caller's entry */ ProfilerEntry *caller = self->previous->ctxEntry; ProfilerSubEntry *subentry = getSubEntry(pObj, caller, entry); if (subentry == NULL) subentry = newSubEntry(pObj, caller, entry); if (subentry) ++subentry->recursionLevel; } self->t0 = call_timer(pObj); } static void Stop(ProfilerObject *pObj, ProfilerContext *self, ProfilerEntry *entry) { _PyTime_t tt = call_timer(pObj) - self->t0; _PyTime_t it = tt - self->subt; if (self->previous) self->previous->subt += tt; pObj->currentProfilerContext = self->previous; if (--entry->recursionLevel == 0) entry->tt += tt; else ++entry->recursivecallcount; entry->it += it; entry->callcount++; if ((pObj->flags & POF_SUBCALLS) && self->previous) { /* find or create an entry for me in my caller's entry */ ProfilerEntry *caller = self->previous->ctxEntry; ProfilerSubEntry *subentry = getSubEntry(pObj, caller, entry); if (subentry) { if (--subentry->recursionLevel == 0) subentry->tt += tt; else ++subentry->recursivecallcount; subentry->it += it; ++subentry->callcount; } } } static void ptrace_enter_call(PyObject *self, void *key, PyObject *userObj) { /* entering a call to the function identified by 'key' (which can be a PyCodeObject or a PyMethodDef pointer) */ ProfilerObject *pObj = (ProfilerObject*)self; ProfilerEntry *profEntry; ProfilerContext *pContext; /* In the case of entering a generator expression frame via a * throw (gen_send_ex(.., 1)), we may already have an * Exception set here. We must not mess around with this * exception, and some of the code under here assumes that * PyErr_* is its own to mess around with, so we have to * save and restore any current exception. */ PyObject *last_type, *last_value, *last_tb; PyErr_Fetch(&last_type, &last_value, &last_tb); profEntry = getEntry(pObj, key); if (profEntry == NULL) { profEntry = newProfilerEntry(pObj, key, userObj); if (profEntry == NULL) goto restorePyerr; } /* grab a ProfilerContext out of the free list */ pContext = pObj->freelistProfilerContext; if (pContext) { pObj->freelistProfilerContext = pContext->previous; } else { /* free list exhausted, allocate a new one */ pContext = (ProfilerContext*) PyMem_Malloc(sizeof(ProfilerContext)); if (pContext == NULL) { pObj->flags |= POF_NOMEMORY; goto restorePyerr; } } initContext(pObj, pContext, profEntry); restorePyerr: PyErr_Restore(last_type, last_value, last_tb); } static void ptrace_leave_call(PyObject *self, void *key) { /* leaving a call to the function identified by 'key' */ ProfilerObject *pObj = (ProfilerObject*)self; ProfilerEntry *profEntry; ProfilerContext *pContext; pContext = pObj->currentProfilerContext; if (pContext == NULL) return; profEntry = getEntry(pObj, key); if (profEntry) { Stop(pObj, pContext, profEntry); } else { pObj->currentProfilerContext = pContext->previous; } /* put pContext into the free list */ pContext->previous = pObj->freelistProfilerContext; pObj->freelistProfilerContext = pContext; } static int profiler_callback(PyObject *self, PyFrameObject *frame, int what, PyObject *arg) { switch (what) { /* the 'frame' of a called function is about to start its execution */ case PyTrace_CALL: { PyCodeObject *code = PyFrame_GetCode(frame); ptrace_enter_call(self, (void *)code, (PyObject *)code); Py_DECREF(code); break; } /* the 'frame' of a called function is about to finish (either normally or with an exception) */ case PyTrace_RETURN: { PyCodeObject *code = PyFrame_GetCode(frame); ptrace_leave_call(self, (void *)code); Py_DECREF(code); break; } /* case PyTrace_EXCEPTION: If the exception results in the function exiting, a PyTrace_RETURN event will be generated, so we don't need to handle it. */ /* the Python function 'frame' is issuing a call to the built-in function 'arg' */ case PyTrace_C_CALL: if ((((ProfilerObject *)self)->flags & POF_BUILTINS) && PyCFunction_Check(arg)) { ptrace_enter_call(self, ((PyCFunctionObject *)arg)->m_ml, arg); } break; /* the call to the built-in function 'arg' is returning into its caller 'frame' */ case PyTrace_C_RETURN: /* ...normally */ case PyTrace_C_EXCEPTION: /* ...with an exception set */ if ((((ProfilerObject *)self)->flags & POF_BUILTINS) && PyCFunction_Check(arg)) { ptrace_leave_call(self, ((PyCFunctionObject *)arg)->m_ml); } break; default: break; } return 0; } static int pending_exception(ProfilerObject *pObj) { if (pObj->flags & POF_NOMEMORY) { pObj->flags -= POF_NOMEMORY; PyErr_SetString(PyExc_MemoryError, "memory was exhausted while profiling"); return -1; } return 0; } /************************************************************/ static PyStructSequence_Field profiler_entry_fields[] = { {"code", "code object or built-in function name"}, {"callcount", "how many times this was called"}, {"reccallcount", "how many times called recursively"}, {"totaltime", "total time in this entry"}, {"inlinetime", "inline time in this entry (not in subcalls)"}, {"calls", "details of the calls"}, {0} }; static PyStructSequence_Field profiler_subentry_fields[] = { {"code", "called code object or built-in function name"}, {"callcount", "how many times this is called"}, {"reccallcount", "how many times this is called recursively"}, {"totaltime", "total time spent in this call"}, {"inlinetime", "inline time (not in further subcalls)"}, {0} }; static PyStructSequence_Desc profiler_entry_desc = { .name = "_lsprof.profiler_entry", .fields = profiler_entry_fields, .doc = NULL, .n_in_sequence = 6 }; static PyStructSequence_Desc profiler_subentry_desc = { .name = "_lsprof.profiler_subentry", .fields = profiler_subentry_fields, .doc = NULL, .n_in_sequence = 5 }; typedef struct { PyObject *list; PyObject *sublist; double factor; _lsprof_state *state; } statscollector_t; static int statsForSubEntry(rotating_node_t *node, void *arg) { ProfilerSubEntry *sentry = (ProfilerSubEntry*) node; statscollector_t *collect = (statscollector_t*) arg; ProfilerEntry *entry = (ProfilerEntry*) sentry->header.key; int err; PyObject *sinfo; sinfo = PyObject_CallFunction((PyObject*) collect->state->stats_subentry_type, "((Olldd))", entry->userObj, sentry->callcount, sentry->recursivecallcount, collect->factor * sentry->tt, collect->factor * sentry->it); if (sinfo == NULL) return -1; err = PyList_Append(collect->sublist, sinfo); Py_DECREF(sinfo); return err; } static int statsForEntry(rotating_node_t *node, void *arg) { ProfilerEntry *entry = (ProfilerEntry*) node; statscollector_t *collect = (statscollector_t*) arg; PyObject *info; int err; if (entry->callcount == 0) return 0; /* skip */ if (entry->calls != EMPTY_ROTATING_TREE) { collect->sublist = PyList_New(0); if (collect->sublist == NULL) return -1; if (RotatingTree_Enum(entry->calls, statsForSubEntry, collect) != 0) { Py_DECREF(collect->sublist); return -1; } } else { Py_INCREF(Py_None); collect->sublist = Py_None; } info = PyObject_CallFunction((PyObject*) collect->state->stats_entry_type, "((OllddO))", entry->userObj, entry->callcount, entry->recursivecallcount, collect->factor * entry->tt, collect->factor * entry->it, collect->sublist); Py_DECREF(collect->sublist); if (info == NULL) return -1; err = PyList_Append(collect->list, info); Py_DECREF(info); return err; } /*[clinic input] _lsprof.Profiler.getstats cls: defining_class list of profiler_entry objects. getstats() -> list of profiler_entry objects Return all information collected by the profiler. Each profiler_entry is a tuple-like object with the following attributes: code code object callcount how many times this was called reccallcount how many times called recursively totaltime total time in this entry inlinetime inline time in this entry (not in subcalls) calls details of the calls The calls attribute is either None or a list of profiler_subentry objects: code called code object callcount how many times this is called reccallcount how many times this is called recursively totaltime total time spent in this call inlinetime inline time (not in further subcalls) [clinic start generated code]*/ static PyObject * _lsprof_Profiler_getstats_impl(ProfilerObject *self, PyTypeObject *cls) /*[clinic end generated code: output=1806ef720019ee03 input=445e193ef4522902]*/ { statscollector_t collect; collect.state = PyType_GetModuleState(cls); if (pending_exception(self)) { return NULL; } if (!self->externalTimer || self->externalTimerUnit == 0.0) { _PyTime_t onesec = _PyTime_FromSeconds(1); collect.factor = (double)1 / onesec; } else { collect.factor = self->externalTimerUnit; } collect.list = PyList_New(0); if (collect.list == NULL) return NULL; if (RotatingTree_Enum(self->profilerEntries, statsForEntry, &collect) != 0) { Py_DECREF(collect.list); return NULL; } return collect.list; } static int setSubcalls(ProfilerObject *pObj, int nvalue) { if (nvalue == 0) pObj->flags &= ~POF_SUBCALLS; else if (nvalue > 0) pObj->flags |= POF_SUBCALLS; return 0; } static int setBuiltins(ProfilerObject *pObj, int nvalue) { if (nvalue == 0) pObj->flags &= ~POF_BUILTINS; else if (nvalue > 0) { pObj->flags |= POF_BUILTINS; } return 0; } PyDoc_STRVAR(enable_doc, "\ enable(subcalls=True, builtins=True)\n\ \n\ Start collecting profiling information.\n\ If 'subcalls' is True, also records for each function\n\ statistics separated according to its current caller.\n\ If 'builtins' is True, records the time spent in\n\ built-in functions separately from their caller.\n\ "); static PyObject* profiler_enable(ProfilerObject *self, PyObject *args, PyObject *kwds) { int subcalls = -1; int builtins = -1; static char *kwlist[] = {"subcalls", "builtins", 0}; if (!PyArg_ParseTupleAndKeywords(args, kwds, "|ii:enable", kwlist, &subcalls, &builtins)) return NULL; if (setSubcalls(self, subcalls) < 0 || setBuiltins(self, builtins) < 0) { return NULL; } PyThreadState *tstate = PyThreadState_GET(); if (_PyEval_SetProfile(tstate, profiler_callback, (PyObject*)self) < 0) { return NULL; } self->flags |= POF_ENABLED; Py_RETURN_NONE; } static void flush_unmatched(ProfilerObject *pObj) { while (pObj->currentProfilerContext) { ProfilerContext *pContext = pObj->currentProfilerContext; ProfilerEntry *profEntry= pContext->ctxEntry; if (profEntry) Stop(pObj, pContext, profEntry); else pObj->currentProfilerContext = pContext->previous; if (pContext) PyMem_Free(pContext); } } PyDoc_STRVAR(disable_doc, "\ disable()\n\ \n\ Stop collecting profiling information.\n\ "); static PyObject* profiler_disable(ProfilerObject *self, PyObject* noarg) { PyThreadState *tstate = PyThreadState_GET(); if (_PyEval_SetProfile(tstate, NULL, NULL) < 0) { return NULL; } self->flags &= ~POF_ENABLED; flush_unmatched(self); if (pending_exception(self)) { return NULL; } Py_RETURN_NONE; } PyDoc_STRVAR(clear_doc, "\ clear()\n\ \n\ Clear all profiling information collected so far.\n\ "); static PyObject* profiler_clear(ProfilerObject *pObj, PyObject* noarg) { clearEntries(pObj); Py_RETURN_NONE; } static int profiler_traverse(ProfilerObject *op, visitproc visit, void *arg) { Py_VISIT(Py_TYPE(op)); return 0; } static void profiler_dealloc(ProfilerObject *op) { if (op->flags & POF_ENABLED) { PyThreadState *tstate = PyThreadState_GET(); if (_PyEval_SetProfile(tstate, NULL, NULL) < 0) { PyErr_WriteUnraisable((PyObject *)op); } } flush_unmatched(op); clearEntries(op); Py_XDECREF(op->externalTimer); PyTypeObject *tp = Py_TYPE(op); tp->tp_free(op); Py_DECREF(tp); } static int profiler_init(ProfilerObject *pObj, PyObject *args, PyObject *kw) { PyObject *timer = NULL; double timeunit = 0.0; int subcalls = 1; int builtins = 1; static char *kwlist[] = {"timer", "timeunit", "subcalls", "builtins", 0}; if (!PyArg_ParseTupleAndKeywords(args, kw, "|Odii:Profiler", kwlist, &timer, &timeunit, &subcalls, &builtins)) return -1; if (setSubcalls(pObj, subcalls) < 0 || setBuiltins(pObj, builtins) < 0) return -1; pObj->externalTimerUnit = timeunit; Py_XINCREF(timer); Py_XSETREF(pObj->externalTimer, timer); return 0; } static PyMethodDef profiler_methods[] = { _LSPROF_PROFILER_GETSTATS_METHODDEF {"enable", (PyCFunction)(void(*)(void))profiler_enable, METH_VARARGS | METH_KEYWORDS, enable_doc}, {"disable", (PyCFunction)profiler_disable, METH_NOARGS, disable_doc}, {"clear", (PyCFunction)profiler_clear, METH_NOARGS, clear_doc}, {NULL, NULL} }; PyDoc_STRVAR(profiler_doc, "\ Profiler(timer=None, timeunit=None, subcalls=True, builtins=True)\n\ \n\ Builds a profiler object using the specified timer function.\n\ The default timer is a fast built-in one based on real time.\n\ For custom timer functions returning integers, timeunit can\n\ be a float specifying a scale (i.e. how long each integer unit\n\ is, in seconds).\n\ "); static PyType_Slot _lsprof_profiler_type_spec_slots[] = { {Py_tp_doc, (void *)profiler_doc}, {Py_tp_methods, profiler_methods}, {Py_tp_dealloc, profiler_dealloc}, {Py_tp_init, profiler_init}, {Py_tp_traverse, profiler_traverse}, {0, 0} }; static PyType_Spec _lsprof_profiler_type_spec = { .name = "_lsprof.Profiler", .basicsize = sizeof(ProfilerObject), .flags = (Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE | Py_TPFLAGS_HAVE_GC | Py_TPFLAGS_IMMUTABLETYPE), .slots = _lsprof_profiler_type_spec_slots, }; static PyMethodDef moduleMethods[] = { {NULL, NULL} }; static int _lsprof_traverse(PyObject *module, visitproc visit, void *arg) { _lsprof_state *state = _lsprof_get_state(module); Py_VISIT(state->profiler_type); Py_VISIT(state->stats_entry_type); Py_VISIT(state->stats_subentry_type); return 0; } static int _lsprof_clear(PyObject *module) { _lsprof_state *state = _lsprof_get_state(module); Py_CLEAR(state->profiler_type); Py_CLEAR(state->stats_entry_type); Py_CLEAR(state->stats_subentry_type); return 0; } static void _lsprof_free(void *module) { _lsprof_clear((PyObject *)module); } static int _lsprof_exec(PyObject *module) { _lsprof_state *state = PyModule_GetState(module); state->profiler_type = (PyTypeObject *)PyType_FromModuleAndSpec( module, &_lsprof_profiler_type_spec, NULL); if (state->profiler_type == NULL) { return -1; } if (PyModule_AddType(module, state->profiler_type) < 0) { return -1; } state->stats_entry_type = PyStructSequence_NewType(&profiler_entry_desc); if (state->stats_entry_type == NULL) { return -1; } if (PyModule_AddType(module, state->stats_entry_type) < 0) { return -1; } state->stats_subentry_type = PyStructSequence_NewType(&profiler_subentry_desc); if (state->stats_subentry_type == NULL) { return -1; } if (PyModule_AddType(module, state->stats_subentry_type) < 0) { return -1; } return 0; } static PyModuleDef_Slot _lsprofslots[] = { {Py_mod_exec, _lsprof_exec}, {0, NULL} }; static struct PyModuleDef _lsprofmodule = { PyModuleDef_HEAD_INIT, .m_name = "_lsprof", .m_doc = "Fast profiler", .m_size = sizeof(_lsprof_state), .m_methods = moduleMethods, .m_slots = _lsprofslots, .m_traverse = _lsprof_traverse, .m_clear = _lsprof_clear, .m_free = _lsprof_free }; PyMODINIT_FUNC PyInit__lsprof(void) { return PyModuleDef_Init(&_lsprofmodule); }