/* * Special implementations of built-in functions and methods. * * Optional optimisations for builtins are in Optimize.c. * * General object operations and protocols are in ObjectHandling.c. */ //////////////////// Globals.proto //////////////////// static PyObject* __Pyx_Globals(void); /*proto*/ //////////////////// Globals //////////////////// //@requires: ObjectHandling.c::GetAttr // This is a stub implementation until we have something more complete. // Currently, we only handle the most common case of a read-only dict // of Python names. Supporting cdef names in the module and write // access requires a rewrite as a dedicated class. static PyObject* __Pyx_Globals(void) { return __Pyx_NewRef(NAMED_CGLOBAL(moddict_cname)); } //////////////////// PyExecGlobals.proto //////////////////// static PyObject* __Pyx_PyExecGlobals(PyObject*); //////////////////// PyExecGlobals //////////////////// //@requires: PyExec static PyObject* __Pyx_PyExecGlobals(PyObject* code) { return __Pyx_PyExec2(code, NAMED_CGLOBAL(moddict_cname)); } //////////////////// PyExec.proto //////////////////// static PyObject* __Pyx_PyExec3(PyObject*, PyObject*, PyObject*); static CYTHON_INLINE PyObject* __Pyx_PyExec2(PyObject*, PyObject*); //////////////////// PyExec //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyExec2(PyObject* o, PyObject* globals) { return __Pyx_PyExec3(o, globals, NULL); } static PyObject* __Pyx_PyExec3(PyObject* o, PyObject* globals, PyObject* locals) { PyObject* result; #if !CYTHON_COMPILING_IN_LIMITED_API PyObject* s = 0; char *code = 0; #endif if (!globals || globals == Py_None) { globals = NAMED_CGLOBAL(moddict_cname); } #if !CYTHON_COMPILING_IN_LIMITED_API // In Limited API we just use exec builtin which already has this else if (unlikely(!PyDict_Check(globals))) { __Pyx_TypeName globals_type_name = __Pyx_PyType_GetFullyQualifiedName(Py_TYPE(globals)); PyErr_Format(PyExc_TypeError, "exec() arg 2 must be a dict, not " __Pyx_FMT_TYPENAME, globals_type_name); __Pyx_DECREF_TypeName(globals_type_name); goto bad; } #endif if (!locals || locals == Py_None) { locals = globals; } #if !CYTHON_COMPILING_IN_LIMITED_API if (__Pyx_PyDict_GetItemStr(globals, PYIDENT("__builtins__")) == NULL) { if (unlikely(PyDict_SetItem(globals, PYIDENT("__builtins__"), PyEval_GetBuiltins()) < 0)) goto bad; } if (PyCode_Check(o)) { if (unlikely(__Pyx_PyCode_HasFreeVars((PyCodeObject *)o))) { PyErr_SetString(PyExc_TypeError, "code object passed to exec() may not contain free variables"); goto bad; } #if CYTHON_COMPILING_IN_PYPY && PYPY_VERSION_NUM < 0x07030400 result = PyEval_EvalCode((PyCodeObject *)o, globals, locals); #else result = PyEval_EvalCode(o, globals, locals); #endif } else { PyCompilerFlags cf; cf.cf_flags = 0; #if PY_VERSION_HEX >= 0x030800A3 cf.cf_feature_version = PY_MINOR_VERSION; #endif if (PyUnicode_Check(o)) { cf.cf_flags = PyCF_SOURCE_IS_UTF8; s = PyUnicode_AsUTF8String(o); if (unlikely(!s)) goto bad; o = s; } else if (unlikely(!PyBytes_Check(o))) { __Pyx_TypeName o_type_name = __Pyx_PyType_GetFullyQualifiedName(Py_TYPE(o)); PyErr_Format(PyExc_TypeError, "exec: arg 1 must be string, bytes or code object, got " __Pyx_FMT_TYPENAME, o_type_name); __Pyx_DECREF_TypeName(o_type_name); goto bad; } code = PyBytes_AS_STRING(o); if (PyEval_MergeCompilerFlags(&cf)) { result = PyRun_StringFlags(code, Py_file_input, globals, locals, &cf); } else { result = PyRun_String(code, Py_file_input, globals, locals); } Py_XDECREF(s); } return result; bad: Py_XDECREF(s); return 0; #else // CYTHON_COMPILING_IN_LIMITED_API { // For the limited API we just defer to the actual builtin // (after setting up globals and locals) - there's too much we can't do otherwise PyObject *builtins, *exec, *exec_str; builtins = PyEval_GetBuiltins(); if (!builtins) return NULL; exec_str = PyUnicode_FromStringAndSize("exec", 4); if (!exec_str) return NULL; exec = PyObject_GetItem(builtins, exec_str); Py_DECREF(exec_str); if (!exec) return NULL; result = PyObject_CallFunctionObjArgs(exec, o, globals, locals, NULL); Py_DECREF(exec); return result; } #endif } //////////////////// GetAttr3.proto //////////////////// static CYTHON_INLINE PyObject *__Pyx_GetAttr3(PyObject *, PyObject *, PyObject *); /*proto*/ //////////////////// GetAttr3 //////////////////// //@requires: ObjectHandling.c::PyObjectGetAttrStr //@requires: Exceptions.c::PyThreadStateGet //@requires: Exceptions.c::PyErrFetchRestore //@requires: Exceptions.c::PyErrExceptionMatches #if __PYX_LIMITED_VERSION_HEX < 0x030d0000 static PyObject *__Pyx_GetAttr3Default(PyObject *d) { __Pyx_PyThreadState_declare __Pyx_PyThreadState_assign if (unlikely(!__Pyx_PyErr_ExceptionMatches(PyExc_AttributeError))) return NULL; __Pyx_PyErr_Clear(); Py_INCREF(d); return d; } #endif static CYTHON_INLINE PyObject *__Pyx_GetAttr3(PyObject *o, PyObject *n, PyObject *d) { PyObject *r; #if __PYX_LIMITED_VERSION_HEX >= 0x030d0000 int res = PyObject_GetOptionalAttr(o, n, &r); // On failure (res == -1), r is set to NULL. return (res != 0) ? r : __Pyx_NewRef(d); #else #if CYTHON_USE_TYPE_SLOTS if (likely(PyUnicode_Check(n))) { r = __Pyx_PyObject_GetAttrStrNoError(o, n); if (unlikely(!r) && likely(!PyErr_Occurred())) { r = __Pyx_NewRef(d); } return r; } #endif r = PyObject_GetAttr(o, n); return (likely(r)) ? r : __Pyx_GetAttr3Default(d); #endif } //////////////////// HasAttr.proto //////////////////// #if __PYX_LIMITED_VERSION_HEX >= 0x030d0000 #define __Pyx_HasAttr(o, n) PyObject_HasAttrWithError(o, n) #else static CYTHON_INLINE int __Pyx_HasAttr(PyObject *, PyObject *); /*proto*/ #endif //////////////////// HasAttr //////////////////// //@requires: ObjectHandling.c::PyObjectGetAttrStrNoError #if __PYX_LIMITED_VERSION_HEX < 0x030d0000 static CYTHON_INLINE int __Pyx_HasAttr(PyObject *o, PyObject *n) { PyObject *r; if (unlikely(!PyUnicode_Check(n))) { PyErr_SetString(PyExc_TypeError, "hasattr(): attribute name must be string"); return -1; } r = __Pyx_PyObject_GetAttrStrNoError(o, n); if (!r) { return (unlikely(PyErr_Occurred())) ? -1 : 0; } else { Py_DECREF(r); return 1; } } #endif //////////////////// Intern.proto //////////////////// static PyObject* __Pyx_Intern(PyObject* s); /* proto */ //////////////////// Intern //////////////////// //@requires: ObjectHandling.c::RaiseUnexpectedTypeError static PyObject* __Pyx_Intern(PyObject* s) { if (unlikely(!PyUnicode_CheckExact(s))) { __Pyx_RaiseUnexpectedTypeError("str", s); return NULL; } Py_INCREF(s); PyUnicode_InternInPlace(&s); return s; } //////////////////// abs_longlong.proto //////////////////// static CYTHON_INLINE PY_LONG_LONG __Pyx_abs_longlong(PY_LONG_LONG x) { #if defined (__cplusplus) && __cplusplus >= 201103L return std::abs(x); #elif defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L return llabs(x); #elif defined (_MSC_VER) // abs() is defined for long, but 64-bits type on MSVC is long long. // Use MS-specific _abs64() instead, which returns the original (negative) value for abs(-MAX-1) return _abs64(x); #elif defined (__GNUC__) // gcc or clang on 64 bit windows. return __builtin_llabs(x); #else if (sizeof(PY_LONG_LONG) <= sizeof(Py_ssize_t)) return __Pyx_sst_abs(x); return (x<0) ? -x : x; #endif } //////////////////// py_abs.proto //////////////////// #if CYTHON_USE_PYLONG_INTERNALS static PyObject *__Pyx_PyLong_AbsNeg(PyObject *num);/*proto*/ #define __Pyx_PyNumber_Absolute(x) \ ((likely(PyLong_CheckExact(x))) ? \ (likely(__Pyx_PyLong_IsNonNeg(x)) ? __Pyx_NewRef(x) : __Pyx_PyLong_AbsNeg(x)) : \ PyNumber_Absolute(x)) #else #define __Pyx_PyNumber_Absolute(x) PyNumber_Absolute(x) #endif //////////////////// py_abs //////////////////// #if CYTHON_USE_PYLONG_INTERNALS static PyObject *__Pyx_PyLong_AbsNeg(PyObject *n) { #if PY_VERSION_HEX >= 0x030C00A7 if (likely(__Pyx_PyLong_IsCompact(n))) { return PyLong_FromSize_t(__Pyx_PyLong_CompactValueUnsigned(n)); } #else if (likely(Py_SIZE(n) == -1)) { // digits are unsigned return PyLong_FromUnsignedLong(__Pyx_PyLong_Digits(n)[0]); } #endif #if CYTHON_COMPILING_IN_CPYTHON { PyObject *copy = _PyLong_Copy((PyLongObject*)n); if (likely(copy)) { #if PY_VERSION_HEX >= 0x030C00A7 // clear the sign bits to set the sign from SIGN_NEGATIVE (2) to positive (0) ((PyLongObject*)copy)->long_value.lv_tag ^= ((PyLongObject*)copy)->long_value.lv_tag & _PyLong_SIGN_MASK; #else // negate the size to swap the sign __Pyx_SET_SIZE(copy, -Py_SIZE(copy)); #endif } return copy; } #else return PyNumber_Negative(n); #endif } #endif //////////////////// pow2.proto //////////////////// #define __Pyx_PyNumber_Power2(a, b) PyNumber_Power(a, b, Py_None) //////////////////// divmod_int.proto ////////////////// const {{RETURN_TYPE}} __Pyx_divmod_ERROR_VALUE_{{CFUNC_SUFFIX}} = {-1, -1}; static CYTHON_INLINE {{RETURN_TYPE}} __Pyx_divmod_{{CFUNC_SUFFIX}}({{TYPE}} a, {{TYPE}} b); /*proto*/ //////////////////// divmod_int ////////////////// static CYTHON_INLINE {{RETURN_TYPE}} __Pyx_divmod_{{CFUNC_SUFFIX}}({{TYPE}} a, {{TYPE}} b) { // Python and C/C++ use different algorithms in calculating quotients and remainders. // This results in different answers between Python and C/C++ // when the dividend is negative and the divisor is positive and vice versa. {{TYPE}} q, r; if (unlikely(b == 0)) { {{if NOGIL}}PyGILState_STATE gilstate = PyGILState_Ensure();{{endif}} PyErr_SetString(PyExc_ZeroDivisionError, "division by zero"); {{if NOGIL}}PyGILState_Release(gilstate);{{endif}} return __Pyx_divmod_ERROR_VALUE_{{CFUNC_SUFFIX}}; } else if (a == 0) { q = 0; r = 0; } else if ((a < 0) != (b < 0)) { // see CMath.c :: DivInt and ModInt utility code q = a / b; r = a - q * b; {{TYPE}} adapt_python = ((r != 0) & ((r < 0) ^ (b < 0))); q -= adapt_python; r += adapt_python * b; } else { q = a / b; r = a % b; } {{RETURN_TYPE}} c_result = {q, r}; return c_result; } //////////////////// divmod_float.proto ////////////////// const {{RETURN_TYPE}} __Pyx_divmod_ERROR_VALUE_{{CFUNC_SUFFIX}} = {-1.0, -1.0}; static CYTHON_INLINE {{RETURN_TYPE}} __Pyx_divmod_{{CFUNC_SUFFIX}}({{TYPE}} a, {{TYPE}} b); /*proto*/ //////////////////// divmod_float ////////////////// static CYTHON_INLINE {{RETURN_TYPE}} __Pyx_divmod_{{CFUNC_SUFFIX}}({{TYPE}} a, {{TYPE}} b) { // Python and C/C++ use different algorithms in calculating quotients and remainders. // This results in different answers between Python and C/C++ // when the dividend is negative and the divisor is positive and vice versa. // Adapted from CPython 3.14: floatobject.c / _float_div_mod() {{TYPE}} q, r, div; if (unlikely(b == 0.0)) { {{if NOGIL}}PyGILState_STATE gilstate = PyGILState_Ensure();{{endif}} PyErr_SetString(PyExc_ZeroDivisionError, "division by zero"); {{if NOGIL}}PyGILState_Release(gilstate);{{endif}} return __Pyx_divmod_ERROR_VALUE_{{CFUNC_SUFFIX}}; } r = fmod{{MATH_SUFFIX}}(a, b); // fmod is typically exact, so a-mod is *mathematically* an // exact multiple of b. But this is fp arithmetic, and fp // a - mod is an approximation; the result is that div may // not be an exact integral value after the division, although // it will always be very close to one. div = (a - r) / b; if (r) { // ensure the remainder has the same sign as the denominator if ((b < 0) != (r < 0)) { r += b; div -= 1.0; } } else { // the remainder is zero, and in the presence of signed zeroes // fmod returns different results across platforms; ensure // it has the same sign as the denominator. r = copysign{{MATH_SUFFIX}}(0.0, b); } // snap quotient to nearest integral value if (div) { q = floor{{MATH_SUFFIX}}(div); if (div - q > 0.5) { q += 1.0; } } else { // div is zero - get the same sign as the true quotient q = copysign{{MATH_SUFFIX}}(0.0, a / b); /* zero w/ sign of a/b */ } {{RETURN_TYPE}} c_result = {q, r}; return c_result; } //////////////////// int_pyucs4.proto //////////////////// static CYTHON_INLINE int __Pyx_int_from_UCS4(Py_UCS4 uchar); //////////////////// int_pyucs4 //////////////////// static int __Pyx_int_from_UCS4(Py_UCS4 uchar) { // Fast path for ascii digits if (likely(uchar >= (Py_UCS4)'0' && uchar <= (Py_UCS4)'9')) { return uchar - (Py_UCS4)'0'; } #if CYTHON_COMPILING_IN_LIMITED_API PyObject *u = PyUnicode_FromOrdinal(uchar); if (unlikely(!u)) return -1; PyObject *l = PyObject_CallFunctionObjArgs((PyObject*)(&PyLong_Type), u, NULL); Py_DECREF(u); if (unlikely(!l)) return -1; #if __PYX_LIMITED_VERSION_HEX >= 0x030d0000 int result = PyLong_AsInt(l); #else // just don't handle overflow - it's very difficult to see how we'll get it from // a single digit. int result = (int)PyLong_AsLong(l); #endif Py_DECREF(l); return result; #else int digit = Py_UNICODE_TODECIMAL(uchar); if (unlikely(digit < 0)) { PyErr_Format(PyExc_ValueError, "invalid literal for int() with base 10: '%c'", (int) uchar); return -1; } return digit; #endif } //////////////////// float_pyucs4.proto //////////////////// static CYTHON_INLINE double __Pyx_double_from_UCS4(Py_UCS4 uchar); //////////////////// float_pyucs4 //////////////////// static double __Pyx_double_from_UCS4(Py_UCS4 uchar) { // fast path for "just an ascii digit" if (likely(uchar >= (Py_UCS4)'0' && uchar <= (Py_UCS4)'9')) { return uchar - (Py_UCS4)'0'; } #if CYTHON_COMPILING_IN_LIMITED_API PyObject *u = PyUnicode_FromOrdinal(uchar); if (unlikely(!u)) return -1.0; PyObject *f = PyFloat_FromString(u); Py_DECREF(u); if (unlikely(!f)) return -1.0; double result = PyFloat_AsDouble(f); Py_DECREF(f); return result; #else // ...TONUMERIC would initially seem to be a better fit. // However, that accepts things like the "half" symbol, while // float(string) rejects those. double digit = Py_UNICODE_TODECIMAL(uchar); if (unlikely(digit < 0.0)) { PyErr_Format(PyExc_ValueError, "could not convert string to float: '%c'", (int) uchar); return -1.0; } return digit; #endif } //////////////////// object_ord.proto //////////////////// //@requires: TypeConversion.c::UnicodeAsUCS4 #define __Pyx_PyObject_Ord(c) \ (likely(PyUnicode_Check(c)) ? (long)__Pyx_PyUnicode_AsPy_UCS4(c) : __Pyx__PyObject_Ord(c)) static long __Pyx__PyObject_Ord(PyObject* c); /*proto*/ //////////////////// object_ord //////////////////// static long __Pyx__PyObject_Ord(PyObject* c) { Py_ssize_t size; if (PyBytes_Check(c)) { size = __Pyx_PyBytes_GET_SIZE(c); if (likely(size == 1)) { #if CYTHON_ASSUME_SAFE_MACROS return (unsigned char) PyBytes_AS_STRING(c)[0]; #else char *data = PyBytes_AsString(c); if (unlikely(!data)) return -1; return (unsigned char) data[0]; #endif } #if !CYTHON_ASSUME_SAFE_SIZE else if (unlikely(size < 0)) return -1; #endif } else if (PyByteArray_Check(c)) { size = __Pyx_PyByteArray_GET_SIZE(c); if (likely(size == 1)) { #if CYTHON_ASSUME_SAFE_MACROS return (unsigned char) PyByteArray_AS_STRING(c)[0]; #else char *data = PyByteArray_AsString(c); if (unlikely(!data)) return -1; return (unsigned char) data[0]; #endif } #if !CYTHON_ASSUME_SAFE_SIZE else if (unlikely(size < 0)) return -1; #endif } else { // FIXME: support character buffers - but CPython doesn't support them either __Pyx_TypeName c_type_name = __Pyx_PyType_GetFullyQualifiedName(Py_TYPE(c)); PyErr_Format(PyExc_TypeError, "ord() expected string of length 1, but " __Pyx_FMT_TYPENAME " found", c_type_name); __Pyx_DECREF_TypeName(c_type_name); return (long)(Py_UCS4)-1; } PyErr_Format(PyExc_TypeError, "ord() expected a character, but string of length %zd found", size); return (long)(Py_UCS4)-1; } //////////////////// py_dict_keys.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_Keys(PyObject* d); /*proto*/ //////////////////// py_dict_keys //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_Keys(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "keys", d); } //////////////////// py_dict_values.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_Values(PyObject* d); /*proto*/ //////////////////// py_dict_values //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_Values(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "values", d); } //////////////////// py_dict_items.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_Items(PyObject* d); /*proto*/ //////////////////// py_dict_items //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_Items(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "items", d); } //////////////////// py_dict_iterkeys.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_IterKeys(PyObject* d); /*proto*/ //////////////////// py_dict_iterkeys //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_IterKeys(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "keys", d); } //////////////////// py_dict_itervalues.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_IterValues(PyObject* d); /*proto*/ //////////////////// py_dict_itervalues //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_IterValues(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "values", d); } //////////////////// py_dict_iteritems.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_IterItems(PyObject* d); /*proto*/ //////////////////// py_dict_iteritems //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_IterItems(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "items", d); } //////////////////// py_dict_viewkeys.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_ViewKeys(PyObject* d); /*proto*/ //////////////////// py_dict_viewkeys //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_ViewKeys(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "keys", d); } //////////////////// py_dict_viewvalues.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_ViewValues(PyObject* d); /*proto*/ //////////////////// py_dict_viewvalues //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_ViewValues(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "values", d); } //////////////////// py_dict_viewitems.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_ViewItems(PyObject* d); /*proto*/ //////////////////// py_dict_viewitems //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyDict_ViewItems(PyObject* d) { return CALL_UNBOUND_METHOD(PyDict_Type, "items", d); } //////////////////// pyfrozenset_new.proto //////////////////// static CYTHON_INLINE PyObject* __Pyx_PyFrozenSet_New(PyObject* it); //////////////////// pyfrozenset_new //////////////////// //@requires: ObjectHandling.c::PyObjectCallNoArg static CYTHON_INLINE PyObject* __Pyx_PyFrozenSet_New(PyObject* it) { if (it) { PyObject* result; #if CYTHON_COMPILING_IN_PYPY // PyPy currently lacks PyFrozenSet_CheckExact() and PyFrozenSet_New() PyObject* args; args = PyTuple_Pack(1, it); if (unlikely(!args)) return NULL; result = PyObject_Call((PyObject*)&PyFrozenSet_Type, args, NULL); Py_DECREF(args); return result; #else if (PyFrozenSet_CheckExact(it)) { Py_INCREF(it); return it; } result = PyFrozenSet_New(it); if (unlikely(!result)) return NULL; if ((__PYX_LIMITED_VERSION_HEX >= 0x030A0000) #if CYTHON_COMPILING_IN_LIMITED_API || __Pyx_get_runtime_version() >= 0x030A0000 #endif ) return result; { Py_ssize_t size = __Pyx_PySet_GET_SIZE(result); if (likely(size > 0)) return result; #if !CYTHON_ASSUME_SAFE_SIZE if (unlikely(size < 0)) { Py_DECREF(result); return NULL; } #endif } // empty frozenset is a singleton (on Python <3.10) // seems wasteful, but CPython does the same Py_DECREF(result); #endif } return __Pyx_PyObject_CallNoArg((PyObject*) &PyFrozenSet_Type); } //////////////////// PySet_Update.proto //////////////////// static CYTHON_INLINE int __Pyx_PySet_Update(PyObject* set, PyObject* it); /*proto*/ //////////////////// PySet_Update //////////////////// static CYTHON_INLINE int __Pyx_PySet_Update(PyObject* set, PyObject* it) { PyObject *retval; #if CYTHON_USE_TYPE_SLOTS && !CYTHON_COMPILING_IN_PYPY if (PyAnySet_Check(it)) { Py_ssize_t size = __Pyx_PySet_GET_SIZE(it); #if !CYTHON_ASSUME_SAFE_SIZE if (unlikely(size < 0)) return -1; #endif if (size == 0) return 0; // fast and safe case: CPython will update our result set and return it retval = PySet_Type.tp_as_number->nb_inplace_or(set, it); if (likely(retval == set)) { Py_DECREF(retval); return 0; } if (unlikely(!retval)) return -1; // unusual result, fall through to set.update() call below Py_DECREF(retval); } #endif retval = CALL_UNBOUND_METHOD(PySet_Type, "update", set, it); if (unlikely(!retval)) return -1; Py_DECREF(retval); return 0; } ///////////////// memoryview_get_from_buffer.proto //////////////////// #if !CYTHON_COMPILING_IN_LIMITED_API #define __Pyx_PyMemoryView_Get_{{name}}(o) PyMemoryView_GET_BUFFER(o)->{{name}} #else {{py: out_types = dict( ndim='int', readonly='int', len='Py_ssize_t', itemsize='Py_ssize_t') }} // can't get format like this unfortunately. It's unicode via getattr {{py: out_type = out_types[name]}} static {{out_type}} __Pyx_PyMemoryView_Get_{{name}}(PyObject *obj); /* proto */ #endif ////////////// memoryview_get_from_buffer ///////////////////////// #if !CYTHON_COMPILING_IN_LIMITED_API #else {{py: out_types = dict( ndim='int', readonly='int', len='Py_ssize_t', itemsize='Py_ssize_t') }} {{py: out_type = out_types[name]}} static {{out_type}} __Pyx_PyMemoryView_Get_{{name}}(PyObject *obj) { {{out_type}} result; PyObject *attr = PyObject_GetAttr(obj, PYIDENT("{{name}}")); if (!attr) { goto bad; } {{if out_type == 'int'}} // I'm not worrying about overflow here because // ultimately it comes from a C struct that's an int result = PyLong_AsLong(attr); {{elif out_type == 'Py_ssize_t'}} result = PyLong_AsSsize_t(attr); {{endif}} Py_DECREF(attr); return result; bad: Py_XDECREF(attr); return -1; } #endif ////////////// PySliceAccessors.proto ///////////////////////// #if CYTHON_COMPILING_IN_LIMITED_API #define __Pyx_PySlice_Start(o) PyObject_GetAttr(o, PYIDENT("start")) #define __Pyx_PySlice_Stop(o) PyObject_GetAttr(o, PYIDENT("stop")) #define __Pyx_PySlice_Step(o) PyObject_GetAttr(o, PYIDENT("step")) #elif CYTHON_COMPILING_IN_GRAAL // Graal defines it's own accessor functions #define __Pyx_PySlice_Start(o) __Pyx_NewRef(PySlice_Start((PySliceObject*)o)) #define __Pyx_PySlice_Stop(o) __Pyx_NewRef(PySlice_Stop((PySliceObject*)o)) #define __Pyx_PySlice_Step(o) __Pyx_NewRef(PySlice_Step((PySliceObject*)o)) #else #define __Pyx_PySlice_Start(o) __Pyx_NewRef(((PySliceObject*)o)->start) #define __Pyx_PySlice_Stop(o) __Pyx_NewRef(((PySliceObject*)o)->stop) #define __Pyx_PySlice_Step(o) __Pyx_NewRef(((PySliceObject*)o)->step) #endif