// Licensed to the Apache Software Foundation (ASF) under one // or more contributor license agreements. See the NOTICE file // distributed with this work for additional information // regarding copyright ownership. The ASF licenses this file // to you under the Apache License, Version 2.0 (the // "License"); you may not use this file except in compliance // with the License. You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, // software distributed under the License is distributed on an // "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY // KIND, either express or implied. See the License for the // specific language governing permissions and limitations // under the License. // helpers.h includes a NumPy header, so we include this first #include "arrow/python/numpy_interop.h" #include "arrow/python/helpers.h" #include #include #include #include #include "arrow/python/common.h" #include "arrow/python/decimal.h" #include "arrow/type_fwd.h" #include "arrow/util/checked_cast.h" #include "arrow/util/logging.h" namespace arrow { using internal::checked_cast; namespace py { #define GET_PRIMITIVE_TYPE(NAME, FACTORY) \ case Type::NAME: \ return FACTORY() std::shared_ptr GetPrimitiveType(Type::type type) { switch (type) { case Type::NA: return null(); GET_PRIMITIVE_TYPE(UINT8, uint8); GET_PRIMITIVE_TYPE(INT8, int8); GET_PRIMITIVE_TYPE(UINT16, uint16); GET_PRIMITIVE_TYPE(INT16, int16); GET_PRIMITIVE_TYPE(UINT32, uint32); GET_PRIMITIVE_TYPE(INT32, int32); GET_PRIMITIVE_TYPE(UINT64, uint64); GET_PRIMITIVE_TYPE(INT64, int64); GET_PRIMITIVE_TYPE(DATE32, date32); GET_PRIMITIVE_TYPE(DATE64, date64); GET_PRIMITIVE_TYPE(BOOL, boolean); GET_PRIMITIVE_TYPE(HALF_FLOAT, float16); GET_PRIMITIVE_TYPE(FLOAT, float32); GET_PRIMITIVE_TYPE(DOUBLE, float64); GET_PRIMITIVE_TYPE(BINARY, binary); GET_PRIMITIVE_TYPE(STRING, utf8); GET_PRIMITIVE_TYPE(LARGE_BINARY, large_binary); GET_PRIMITIVE_TYPE(LARGE_STRING, large_utf8); GET_PRIMITIVE_TYPE(BINARY_VIEW, binary_view); GET_PRIMITIVE_TYPE(STRING_VIEW, utf8_view); GET_PRIMITIVE_TYPE(INTERVAL_MONTH_DAY_NANO, month_day_nano_interval); default: return nullptr; } } PyObject* PyHalf_FromHalf(npy_half value) { PyObject* result = PyArrayScalar_New(Half); if (result != NULL) { PyArrayScalar_ASSIGN(result, Half, value); } return result; } Status PyFloat_AsHalf(PyObject* obj, npy_half* out) { if (PyArray_IsScalar(obj, Half)) { *out = PyArrayScalar_VAL(obj, Half); return Status::OK(); } else { // XXX: cannot use npy_double_to_half() without linking with Numpy return Status::TypeError("Expected np.float16 instance"); } } namespace internal { std::string PyBytes_AsStdString(PyObject* obj) { DCHECK(PyBytes_Check(obj)); return std::string(PyBytes_AS_STRING(obj), PyBytes_GET_SIZE(obj)); } Status PyUnicode_AsStdString(PyObject* obj, std::string* out) { DCHECK(PyUnicode_Check(obj)); Py_ssize_t size; // The utf-8 representation is cached on the unicode object const char* data = PyUnicode_AsUTF8AndSize(obj, &size); RETURN_IF_PYERROR(); *out = std::string(data, size); return Status::OK(); } std::string PyObject_StdStringRepr(PyObject* obj) { OwnedRef unicode_ref(PyObject_Repr(obj)); OwnedRef bytes_ref; if (unicode_ref) { bytes_ref.reset( PyUnicode_AsEncodedString(unicode_ref.obj(), "utf8", "backslashreplace")); } if (!bytes_ref) { PyErr_Clear(); std::stringstream ss; ss << "tp_name << "' repr() failed>"; return ss.str(); } return PyBytes_AsStdString(bytes_ref.obj()); } Status PyObject_StdStringStr(PyObject* obj, std::string* out) { OwnedRef string_ref(PyObject_Str(obj)); RETURN_IF_PYERROR(); return PyUnicode_AsStdString(string_ref.obj(), out); } Result IsModuleImported(const std::string& module_name) { // PyImport_GetModuleDict returns with a borrowed reference OwnedRef key(PyUnicode_FromString(module_name.c_str())); auto is_imported = PyDict_Contains(PyImport_GetModuleDict(), key.obj()); RETURN_IF_PYERROR(); return is_imported; } Status ImportModule(const std::string& module_name, OwnedRef* ref) { PyObject* module = PyImport_ImportModule(module_name.c_str()); RETURN_IF_PYERROR(); ref->reset(module); return Status::OK(); } Status ImportFromModule(PyObject* module, const std::string& name, OwnedRef* ref) { PyObject* attr = PyObject_GetAttrString(module, name.c_str()); RETURN_IF_PYERROR(); ref->reset(attr); return Status::OK(); } namespace { Status IntegerOverflowStatus(PyObject* obj, const std::string& overflow_message) { if (overflow_message.empty()) { std::string obj_as_stdstring; RETURN_NOT_OK(PyObject_StdStringStr(obj, &obj_as_stdstring)); return Status::Invalid("Value ", obj_as_stdstring, " too large to fit in C integer type"); } else { return Status::Invalid(overflow_message); } } Result PyObjectToPyInt(PyObject* obj) { // Try to call __index__ or __int__ on `obj` // (starting from Python 3.10, the latter isn't done anymore by PyLong_AsLong*). OwnedRef ref(PyNumber_Index(obj)); if (ref) { return std::move(ref); } PyErr_Clear(); const auto nb = Py_TYPE(obj)->tp_as_number; if (nb && nb->nb_int) { ref.reset(nb->nb_int(obj)); if (!ref) { RETURN_IF_PYERROR(); } DCHECK(ref); return std::move(ref); } return Status::TypeError( "object of type ", PyObject_StdStringRepr(reinterpret_cast(Py_TYPE(obj))), " cannot be converted to int"); } // Extract C signed int from Python object template ::value, Int> = 0> Status CIntFromPythonImpl(PyObject* obj, Int* out, const std::string& overflow_message) { static_assert(sizeof(Int) <= sizeof(long long), // NOLINT "integer type larger than long long"); OwnedRef ref; if (!PyLong_Check(obj)) { ARROW_ASSIGN_OR_RAISE(ref, PyObjectToPyInt(obj)); obj = ref.obj(); } if (sizeof(Int) > sizeof(long)) { // NOLINT const auto value = PyLong_AsLongLong(obj); if (ARROW_PREDICT_FALSE(value == -1)) { RETURN_IF_PYERROR(); } if (ARROW_PREDICT_FALSE(value < std::numeric_limits::min() || value > std::numeric_limits::max())) { return IntegerOverflowStatus(obj, overflow_message); } *out = static_cast(value); } else { const auto value = PyLong_AsLong(obj); if (ARROW_PREDICT_FALSE(value == -1)) { RETURN_IF_PYERROR(); } if (ARROW_PREDICT_FALSE(value < std::numeric_limits::min() || value > std::numeric_limits::max())) { return IntegerOverflowStatus(obj, overflow_message); } *out = static_cast(value); } return Status::OK(); } // Extract C unsigned int from Python object template ::value, Int> = 0> Status CIntFromPythonImpl(PyObject* obj, Int* out, const std::string& overflow_message) { static_assert(sizeof(Int) <= sizeof(unsigned long long), // NOLINT "integer type larger than unsigned long long"); OwnedRef ref; if (!PyLong_Check(obj)) { ARROW_ASSIGN_OR_RAISE(ref, PyObjectToPyInt(obj)); obj = ref.obj(); } if (sizeof(Int) > sizeof(unsigned long)) { // NOLINT const auto value = PyLong_AsUnsignedLongLong(obj); if (ARROW_PREDICT_FALSE(value == static_cast(-1))) { RETURN_IF_PYERROR(); } if (ARROW_PREDICT_FALSE(value > std::numeric_limits::max())) { return IntegerOverflowStatus(obj, overflow_message); } *out = static_cast(value); } else { const auto value = PyLong_AsUnsignedLong(obj); if (ARROW_PREDICT_FALSE(value == static_cast(-1))) { RETURN_IF_PYERROR(); } if (ARROW_PREDICT_FALSE(value > std::numeric_limits::max())) { return IntegerOverflowStatus(obj, overflow_message); } *out = static_cast(value); } return Status::OK(); } } // namespace template Status CIntFromPython(PyObject* obj, Int* out, const std::string& overflow_message) { if (PyBool_Check(obj)) { return Status::TypeError("Expected integer, got bool"); } return CIntFromPythonImpl(obj, out, overflow_message); } template Status CIntFromPython(PyObject*, int8_t*, const std::string&); template Status CIntFromPython(PyObject*, int16_t*, const std::string&); template Status CIntFromPython(PyObject*, int32_t*, const std::string&); template Status CIntFromPython(PyObject*, int64_t*, const std::string&); template Status CIntFromPython(PyObject*, uint8_t*, const std::string&); template Status CIntFromPython(PyObject*, uint16_t*, const std::string&); template Status CIntFromPython(PyObject*, uint32_t*, const std::string&); template Status CIntFromPython(PyObject*, uint64_t*, const std::string&); inline bool MayHaveNaN(PyObject* obj) { // Some core types can be very quickly type-checked and do not allow NaN values const int64_t non_nan_tpflags = Py_TPFLAGS_LONG_SUBCLASS | Py_TPFLAGS_LIST_SUBCLASS | Py_TPFLAGS_TUPLE_SUBCLASS | Py_TPFLAGS_BYTES_SUBCLASS | Py_TPFLAGS_UNICODE_SUBCLASS | Py_TPFLAGS_DICT_SUBCLASS | Py_TPFLAGS_BASE_EXC_SUBCLASS | Py_TPFLAGS_TYPE_SUBCLASS; return !PyType_HasFeature(Py_TYPE(obj), non_nan_tpflags); } bool PyFloat_IsNaN(PyObject* obj) { return PyFloat_Check(obj) && std::isnan(PyFloat_AsDouble(obj)); } namespace { static bool pandas_static_initialized = false; // Once initialized, these variables hold borrowed references to Pandas static data. // We should not use OwnedRef here because Python destructors would be // called on a finalized interpreter. static PyObject* pandas_NA = nullptr; static PyObject* pandas_NaT = nullptr; static PyObject* pandas_Timedelta = nullptr; static PyObject* pandas_Timestamp = nullptr; static PyTypeObject* pandas_NaTType = nullptr; static PyObject* pandas_DateOffset = nullptr; } // namespace void InitPandasStaticData() { // NOTE: This is called with the GIL held. We needn't (and shouldn't, // to avoid deadlocks) use an additional C++ lock (ARROW-10519). if (pandas_static_initialized) { return; } OwnedRef pandas; // Import pandas Status s = ImportModule("pandas", &pandas); if (!s.ok()) { return; } // Since ImportModule can release the GIL, another thread could have // already initialized the static data. if (pandas_static_initialized) { return; } OwnedRef ref; // set NaT sentinel and its type if (ImportFromModule(pandas.obj(), "NaT", &ref).ok()) { pandas_NaT = ref.obj(); // PyObject_Type returns a new reference but we trust that pandas.NaT will // outlive our use of this PyObject* pandas_NaTType = Py_TYPE(ref.obj()); } // retain a reference to Timedelta if (ImportFromModule(pandas.obj(), "Timedelta", &ref).ok()) { pandas_Timedelta = ref.obj(); } // retain a reference to Timestamp if (ImportFromModule(pandas.obj(), "Timestamp", &ref).ok()) { pandas_Timestamp = ref.obj(); } // if pandas.NA exists, retain a reference to it if (ImportFromModule(pandas.obj(), "NA", &ref).ok()) { pandas_NA = ref.obj(); } // Import DateOffset type if (ImportFromModule(pandas.obj(), "DateOffset", &ref).ok()) { pandas_DateOffset = ref.obj(); } pandas_static_initialized = true; } bool PandasObjectIsNull(PyObject* obj) { if (!MayHaveNaN(obj)) { return false; } if (obj == Py_None) { return true; } if (PyFloat_IsNaN(obj) || (pandas_NA && obj == pandas_NA) || (pandas_NaTType && PyObject_TypeCheck(obj, pandas_NaTType)) || (internal::PyDecimal_Check(obj) && internal::PyDecimal_ISNAN(obj))) { return true; } return false; } bool IsPandasTimedelta(PyObject* obj) { return pandas_Timedelta && PyObject_IsInstance(obj, pandas_Timedelta); } bool IsPandasTimestamp(PyObject* obj) { return pandas_Timestamp && PyObject_IsInstance(obj, pandas_Timestamp); } PyObject* BorrowPandasDataOffsetType() { return pandas_DateOffset; } Status InvalidValue(PyObject* obj, const std::string& why) { auto obj_as_str = PyObject_StdStringRepr(obj); return Status::Invalid("Could not convert ", std::move(obj_as_str), " with type ", Py_TYPE(obj)->tp_name, ": ", why); } Status InvalidType(PyObject* obj, const std::string& why) { auto obj_as_str = PyObject_StdStringRepr(obj); return Status::TypeError("Could not convert ", std::move(obj_as_str), " with type ", Py_TYPE(obj)->tp_name, ": ", why); } Status UnboxIntegerAsInt64(PyObject* obj, int64_t* out) { if (PyLong_Check(obj)) { int overflow = 0; *out = PyLong_AsLongLongAndOverflow(obj, &overflow); if (overflow) { return Status::Invalid("PyLong is too large to fit int64"); } } else if (PyArray_IsScalar(obj, Byte)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, UByte)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, Short)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, UShort)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, Int)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, UInt)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, Long)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, ULong)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, LongLong)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, Int64)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, ULongLong)) { *out = reinterpret_cast(obj)->obval; } else if (PyArray_IsScalar(obj, UInt64)) { *out = reinterpret_cast(obj)->obval; } else { return Status::Invalid("Integer scalar type not recognized"); } return Status::OK(); } Status IntegerScalarToDoubleSafe(PyObject* obj, double* out) { int64_t value = 0; RETURN_NOT_OK(UnboxIntegerAsInt64(obj, &value)); constexpr int64_t kDoubleMax = 1LL << 53; constexpr int64_t kDoubleMin = -(1LL << 53); if (value < kDoubleMin || value > kDoubleMax) { return Status::Invalid("Integer value ", value, " is outside of the range exactly", " representable by a IEEE 754 double precision value"); } *out = static_cast(value); return Status::OK(); } Status IntegerScalarToFloat32Safe(PyObject* obj, float* out) { int64_t value = 0; RETURN_NOT_OK(UnboxIntegerAsInt64(obj, &value)); constexpr int64_t kFloatMax = 1LL << 24; constexpr int64_t kFloatMin = -(1LL << 24); if (value < kFloatMin || value > kFloatMax) { return Status::Invalid("Integer value ", value, " is outside of the range exactly", " representable by a IEEE 754 single precision value"); } *out = static_cast(value); return Status::OK(); } void DebugPrint(PyObject* obj) { std::string repr = PyObject_StdStringRepr(obj); PySys_WriteStderr("%s\n", repr.c_str()); } } // namespace internal } // namespace py } // namespace arrow