src/third_party/llvm-project/lldb/source/Plugins/ScriptInterpreter/Python/PythonDataObjects.h - cobalt - Git at Google

 //===-- PythonDataObjects.h--------------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLDB_PLUGINS_SCRIPTINTERPRETER_PYTHON_PYTHONDATAOBJECTS_H
 #define LLDB_PLUGINS_SCRIPTINTERPRETER_PYTHON_PYTHONDATAOBJECTS_H

 #ifndef LLDB_DISABLE_PYTHON

 // LLDB Python header must be included first
 #include "lldb-python.h"

 // C Includes
 // C++ Includes
 // Other libraries and framework includes
 // Project includes
 #include "lldb/Utility/Flags.h"

 #include "lldb/Host/File.h"
 #include "lldb/Interpreter/OptionValue.h"
 #include "lldb/Utility/ConstString.h"
 #include "lldb/Utility/StructuredData.h"
 #include "lldb/lldb-defines.h"

 #include "llvm/ADT/ArrayRef.h"

 namespace lldb_private {

 class PythonBytes;
 class PythonString;
 class PythonList;
 class PythonDictionary;
 class PythonInteger;

 class StructuredPythonObject : public StructuredData::Generic {
 public:
   StructuredPythonObject() : StructuredData::Generic() {}

   StructuredPythonObject(void *obj) : StructuredData::Generic(obj) {
     Py_XINCREF(GetValue());
   }

   ~StructuredPythonObject() override {
     if (Py_IsInitialized())
       Py_XDECREF(GetValue());
     SetValue(nullptr);
   }

   bool IsValid() const override { return GetValue() && GetValue() != Py_None; }

   void Dump(Stream &s, bool pretty_print = true) const override;

 private:
   DISALLOW_COPY_AND_ASSIGN(StructuredPythonObject);
 };

 enum class PyObjectType {
   Unknown,
   None,
   Integer,
   Dictionary,
   List,
   String,
   Bytes,
   ByteArray,
   Module,
   Callable,
   Tuple,
   File
 };

 enum class PyRefType {
   Borrowed, // We are not given ownership of the incoming PyObject.
             // We cannot safely hold it without calling Py_INCREF.
   Owned     // We have ownership of the incoming PyObject.  We should
             // not call Py_INCREF.
 };

 enum class PyInitialValue { Invalid, Empty };

 class PythonObject {
 public:
   PythonObject() : m_py_obj(nullptr) {}

   PythonObject(PyRefType type, PyObject *py_obj) : m_py_obj(nullptr) {
     Reset(type, py_obj);
   }

   PythonObject(const PythonObject &rhs) : m_py_obj(nullptr) { Reset(rhs); }

   virtual ~PythonObject() { Reset(); }

   void Reset() {
     // Avoid calling the virtual method since it's not necessary
     // to actually validate the type of the PyObject if we're
     // just setting to null.
     if (Py_IsInitialized())
       Py_XDECREF(m_py_obj);
     m_py_obj = nullptr;
   }

   void Reset(const PythonObject &rhs) {
     // Avoid calling the virtual method if it's not necessary
     // to actually validate the type of the PyObject.
     if (!rhs.IsValid())
       Reset();
     else
       Reset(PyRefType::Borrowed, rhs.m_py_obj);
   }

   // PythonObject is implicitly convertible to PyObject *, which will call the
   // wrong overload.  We want to explicitly disallow this, since a PyObject
   // *always* owns its reference.  Therefore the overload which takes a
   // PyRefType doesn't make sense, and the copy constructor should be used.
   void Reset(PyRefType type, const PythonObject &ref) = delete;

   virtual void Reset(PyRefType type, PyObject *py_obj) {
     if (py_obj == m_py_obj)
       return;

     if (Py_IsInitialized())
       Py_XDECREF(m_py_obj);

     m_py_obj = py_obj;

     // If this is a borrowed reference, we need to convert it to
     // an owned reference by incrementing it.  If it is an owned
     // reference (for example the caller allocated it with PyDict_New()
     // then we must *not* increment it.
     if (Py_IsInitialized() && type == PyRefType::Borrowed)
       Py_XINCREF(m_py_obj);
   }

   void Dump() const {
     if (m_py_obj)
       _PyObject_Dump(m_py_obj);
     else
       puts("NULL");
   }

   void Dump(Stream &strm) const;

   PyObject *get() const { return m_py_obj; }

   PyObject *release() {
     PyObject *result = m_py_obj;
     m_py_obj = nullptr;
     return result;
   }

   PythonObject &operator=(const PythonObject &other) {
     Reset(PyRefType::Borrowed, other.get());
     return *this;
   }

   PyObjectType GetObjectType() const;

   PythonString Repr() const;

   PythonString Str() const;

   static PythonObject ResolveNameWithDictionary(llvm::StringRef name,
                                                 const PythonDictionary &dict);

   template <typename T>
   static T ResolveNameWithDictionary(llvm::StringRef name,
                                      const PythonDictionary &dict) {
     return ResolveNameWithDictionary(name, dict).AsType<T>();
   }

   PythonObject ResolveName(llvm::StringRef name) const;

   template <typename T> T ResolveName(llvm::StringRef name) const {
     return ResolveName(name).AsType<T>();
   }

   bool HasAttribute(llvm::StringRef attribute) const;

   PythonObject GetAttributeValue(llvm::StringRef attribute) const;

   bool IsValid() const;

   bool IsAllocated() const;

   bool IsNone() const;

   template <typename T> T AsType() const {
     if (!T::Check(m_py_obj))
       return T();
     return T(PyRefType::Borrowed, m_py_obj);
   }

   StructuredData::ObjectSP CreateStructuredObject() const;

 protected:
   PyObject *m_py_obj;
 };

 class PythonBytes : public PythonObject {
 public:
   PythonBytes();
   explicit PythonBytes(llvm::ArrayRef<uint8_t> bytes);
   PythonBytes(const uint8_t *bytes, size_t length);
   PythonBytes(PyRefType type, PyObject *o);
   PythonBytes(const PythonBytes &object);

   ~PythonBytes() override;

   static bool Check(PyObject *py_obj);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   llvm::ArrayRef<uint8_t> GetBytes() const;

   size_t GetSize() const;

   void SetBytes(llvm::ArrayRef<uint8_t> stringbytes);

   StructuredData::StringSP CreateStructuredString() const;
 };

 class PythonByteArray : public PythonObject {
 public:
   PythonByteArray();
   explicit PythonByteArray(llvm::ArrayRef<uint8_t> bytes);
   PythonByteArray(const uint8_t *bytes, size_t length);
   PythonByteArray(PyRefType type, PyObject *o);
   PythonByteArray(const PythonBytes &object);

   ~PythonByteArray() override;

   static bool Check(PyObject *py_obj);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   llvm::ArrayRef<uint8_t> GetBytes() const;

   size_t GetSize() const;

   void SetBytes(llvm::ArrayRef<uint8_t> stringbytes);

   StructuredData::StringSP CreateStructuredString() const;
 };

 class PythonString : public PythonObject {
 public:
   PythonString();
   explicit PythonString(llvm::StringRef string);
   explicit PythonString(const char *string);
   PythonString(PyRefType type, PyObject *o);
   PythonString(const PythonString &object);

   ~PythonString() override;

   static bool Check(PyObject *py_obj);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   llvm::StringRef GetString() const;

   size_t GetSize() const;

   void SetString(llvm::StringRef string);

   StructuredData::StringSP CreateStructuredString() const;
 };

 class PythonInteger : public PythonObject {
 public:
   PythonInteger();
   explicit PythonInteger(int64_t value);
   PythonInteger(PyRefType type, PyObject *o);
   PythonInteger(const PythonInteger &object);

   ~PythonInteger() override;

   static bool Check(PyObject *py_obj);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   int64_t GetInteger() const;

   void SetInteger(int64_t value);

   StructuredData::IntegerSP CreateStructuredInteger() const;
 };

 class PythonList : public PythonObject {
 public:
   PythonList() {}
   explicit PythonList(PyInitialValue value);
   explicit PythonList(int list_size);
   PythonList(PyRefType type, PyObject *o);
   PythonList(const PythonList &list);

   ~PythonList() override;

   static bool Check(PyObject *py_obj);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   uint32_t GetSize() const;

   PythonObject GetItemAtIndex(uint32_t index) const;

   void SetItemAtIndex(uint32_t index, const PythonObject &object);

   void AppendItem(const PythonObject &object);

   StructuredData::ArraySP CreateStructuredArray() const;
 };

 class PythonTuple : public PythonObject {
 public:
   PythonTuple() {}
   explicit PythonTuple(PyInitialValue value);
   explicit PythonTuple(int tuple_size);
   PythonTuple(PyRefType type, PyObject *o);
   PythonTuple(const PythonTuple &tuple);
   PythonTuple(std::initializer_list<PythonObject> objects);
   PythonTuple(std::initializer_list<PyObject *> objects);

   ~PythonTuple() override;

   static bool Check(PyObject *py_obj);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   uint32_t GetSize() const;

   PythonObject GetItemAtIndex(uint32_t index) const;

   void SetItemAtIndex(uint32_t index, const PythonObject &object);

   StructuredData::ArraySP CreateStructuredArray() const;
 };

 class PythonDictionary : public PythonObject {
 public:
   PythonDictionary() {}
   explicit PythonDictionary(PyInitialValue value);
   PythonDictionary(PyRefType type, PyObject *o);
   PythonDictionary(const PythonDictionary &dict);

   ~PythonDictionary() override;

   static bool Check(PyObject *py_obj);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   uint32_t GetSize() const;

   PythonList GetKeys() const;

   PythonObject GetItemForKey(const PythonObject &key) const;
   void SetItemForKey(const PythonObject &key, const PythonObject &value);

   StructuredData::DictionarySP CreateStructuredDictionary() const;
 };

 class PythonModule : public PythonObject {
 public:
   PythonModule();
   PythonModule(PyRefType type, PyObject *o);
   PythonModule(const PythonModule &dict);

   ~PythonModule() override;

   static bool Check(PyObject *py_obj);

   static PythonModule BuiltinsModule();

   static PythonModule MainModule();

   static PythonModule AddModule(llvm::StringRef module);

   static PythonModule ImportModule(llvm::StringRef module);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   PythonDictionary GetDictionary() const;
 };

 class PythonCallable : public PythonObject {
 public:
   struct ArgInfo {
     size_t count;
     bool is_bound_method : 1;
     bool has_varargs : 1;
     bool has_kwargs : 1;
   };

   PythonCallable();
   PythonCallable(PyRefType type, PyObject *o);
   PythonCallable(const PythonCallable &dict);

   ~PythonCallable() override;

   static bool Check(PyObject *py_obj);

   // Bring in the no-argument base class version
   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;

   ArgInfo GetNumArguments() const;

   PythonObject operator()();

   PythonObject operator()(std::initializer_list<PyObject *> args);

   PythonObject operator()(std::initializer_list<PythonObject> args);

   template <typename Arg, typename... Args>
   PythonObject operator()(const Arg &arg, Args... args) {
     return operator()({arg, args...});
   }
 };

 class PythonFile : public PythonObject {
 public:
   PythonFile();
   PythonFile(File &file, const char *mode);
   PythonFile(const char *path, const char *mode);
   PythonFile(PyRefType type, PyObject *o);

   ~PythonFile() override;

   static bool Check(PyObject *py_obj);

   using PythonObject::Reset;

   void Reset(PyRefType type, PyObject *py_obj) override;
   void Reset(File &file, const char *mode);

   static uint32_t GetOptionsFromMode(llvm::StringRef mode);

   bool GetUnderlyingFile(File &file) const;
 };

 } // namespace lldb_private

 #endif

 #endif // LLDB_PLUGINS_SCRIPTINTERPRETER_PYTHON_PYTHONDATAOBJECTS_H
	//===-- PythonDataObjects.h--------------------------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLDB_PLUGINS_SCRIPTINTERPRETER_PYTHON_PYTHONDATAOBJECTS_H
	#define LLDB_PLUGINS_SCRIPTINTERPRETER_PYTHON_PYTHONDATAOBJECTS_H

	#ifndef LLDB_DISABLE_PYTHON

	// LLDB Python header must be included first
	#include "lldb-python.h"

	// C Includes
	// C++ Includes
	// Other libraries and framework includes
	// Project includes
	#include "lldb/Utility/Flags.h"

	#include "lldb/Host/File.h"
	#include "lldb/Interpreter/OptionValue.h"
	#include "lldb/Utility/ConstString.h"
	#include "lldb/Utility/StructuredData.h"
	#include "lldb/lldb-defines.h"

	#include "llvm/ADT/ArrayRef.h"

	namespace lldb_private {

	class PythonBytes;
	class PythonString;
	class PythonList;
	class PythonDictionary;
	class PythonInteger;

	class StructuredPythonObject : public StructuredData::Generic {
	public:
	StructuredPythonObject() : StructuredData::Generic() {}

	StructuredPythonObject(void *obj) : StructuredData::Generic(obj) {
	Py_XINCREF(GetValue());
	}

	~StructuredPythonObject() override {
	if (Py_IsInitialized())
	Py_XDECREF(GetValue());
	SetValue(nullptr);
	}

	bool IsValid() const override { return GetValue() && GetValue() != Py_None; }

	void Dump(Stream &s, bool pretty_print = true) const override;

	private:
	DISALLOW_COPY_AND_ASSIGN(StructuredPythonObject);
	};

	enum class PyObjectType {
	Unknown,
	None,
	Integer,
	Dictionary,
	List,
	String,
	Bytes,
	ByteArray,
	Module,
	Callable,
	Tuple,
	File
	};

	enum class PyRefType {
	Borrowed, // We are not given ownership of the incoming PyObject.
	// We cannot safely hold it without calling Py_INCREF.
	Owned // We have ownership of the incoming PyObject. We should
	// not call Py_INCREF.
	};

	enum class PyInitialValue { Invalid, Empty };

	class PythonObject {
	public:
	PythonObject() : m_py_obj(nullptr) {}

	PythonObject(PyRefType type, PyObject *py_obj) : m_py_obj(nullptr) {
	Reset(type, py_obj);
	}

	PythonObject(const PythonObject &rhs) : m_py_obj(nullptr) { Reset(rhs); }

	virtual ~PythonObject() { Reset(); }

	void Reset() {
	// Avoid calling the virtual method since it's not necessary
	// to actually validate the type of the PyObject if we're
	// just setting to null.
	if (Py_IsInitialized())
	Py_XDECREF(m_py_obj);
	m_py_obj = nullptr;
	}

	void Reset(const PythonObject &rhs) {
	// Avoid calling the virtual method if it's not necessary
	// to actually validate the type of the PyObject.
	if (!rhs.IsValid())
	Reset();
	else
	Reset(PyRefType::Borrowed, rhs.m_py_obj);
	}

	// PythonObject is implicitly convertible to PyObject *, which will call the
	// wrong overload. We want to explicitly disallow this, since a PyObject
	// always owns its reference. Therefore the overload which takes a
	// PyRefType doesn't make sense, and the copy constructor should be used.
	void Reset(PyRefType type, const PythonObject &ref) = delete;

	virtual void Reset(PyRefType type, PyObject *py_obj) {
	if (py_obj == m_py_obj)
	return;

	if (Py_IsInitialized())
	Py_XDECREF(m_py_obj);

	m_py_obj = py_obj;

	// If this is a borrowed reference, we need to convert it to
	// an owned reference by incrementing it. If it is an owned
	// reference (for example the caller allocated it with PyDict_New()
	// then we must not increment it.
	if (Py_IsInitialized() && type == PyRefType::Borrowed)
	Py_XINCREF(m_py_obj);
	}

	void Dump() const {
	if (m_py_obj)
	_PyObject_Dump(m_py_obj);
	else
	puts("NULL");
	}

	void Dump(Stream &strm) const;

	PyObject *get() const { return m_py_obj; }

	PyObject *release() {
	PyObject *result = m_py_obj;
	m_py_obj = nullptr;
	return result;
	}

	PythonObject &operator=(const PythonObject &other) {
	Reset(PyRefType::Borrowed, other.get());
	return *this;
	}

	PyObjectType GetObjectType() const;

	PythonString Repr() const;

	PythonString Str() const;

	static PythonObject ResolveNameWithDictionary(llvm::StringRef name,
	const PythonDictionary &dict);

	template <typename T>
	static T ResolveNameWithDictionary(llvm::StringRef name,
	const PythonDictionary &dict) {
	return ResolveNameWithDictionary(name, dict).AsType<T>();
	}

	PythonObject ResolveName(llvm::StringRef name) const;

	template <typename T> T ResolveName(llvm::StringRef name) const {
	return ResolveName(name).AsType<T>();
	}

	bool HasAttribute(llvm::StringRef attribute) const;

	PythonObject GetAttributeValue(llvm::StringRef attribute) const;

	bool IsValid() const;

	bool IsAllocated() const;

	bool IsNone() const;

	template <typename T> T AsType() const {
	if (!T::Check(m_py_obj))
	return T();
	return T(PyRefType::Borrowed, m_py_obj);
	}

	StructuredData::ObjectSP CreateStructuredObject() const;

	protected:
	PyObject *m_py_obj;
	};

	class PythonBytes : public PythonObject {
	public:
	PythonBytes();
	explicit PythonBytes(llvm::ArrayRef<uint8_t> bytes);
	PythonBytes(const uint8_t *bytes, size_t length);
	PythonBytes(PyRefType type, PyObject *o);
	PythonBytes(const PythonBytes &object);

	~PythonBytes() override;

	static bool Check(PyObject *py_obj);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	llvm::ArrayRef<uint8_t> GetBytes() const;

	size_t GetSize() const;

	void SetBytes(llvm::ArrayRef<uint8_t> stringbytes);

	StructuredData::StringSP CreateStructuredString() const;
	};

	class PythonByteArray : public PythonObject {
	public:
	PythonByteArray();
	explicit PythonByteArray(llvm::ArrayRef<uint8_t> bytes);
	PythonByteArray(const uint8_t *bytes, size_t length);
	PythonByteArray(PyRefType type, PyObject *o);
	PythonByteArray(const PythonBytes &object);

	~PythonByteArray() override;

	static bool Check(PyObject *py_obj);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	llvm::ArrayRef<uint8_t> GetBytes() const;

	size_t GetSize() const;

	void SetBytes(llvm::ArrayRef<uint8_t> stringbytes);

	StructuredData::StringSP CreateStructuredString() const;
	};

	class PythonString : public PythonObject {
	public:
	PythonString();
	explicit PythonString(llvm::StringRef string);
	explicit PythonString(const char *string);
	PythonString(PyRefType type, PyObject *o);
	PythonString(const PythonString &object);

	~PythonString() override;

	static bool Check(PyObject *py_obj);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	llvm::StringRef GetString() const;

	size_t GetSize() const;

	void SetString(llvm::StringRef string);

	StructuredData::StringSP CreateStructuredString() const;
	};

	class PythonInteger : public PythonObject {
	public:
	PythonInteger();
	explicit PythonInteger(int64_t value);
	PythonInteger(PyRefType type, PyObject *o);
	PythonInteger(const PythonInteger &object);

	~PythonInteger() override;

	static bool Check(PyObject *py_obj);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	int64_t GetInteger() const;

	void SetInteger(int64_t value);

	StructuredData::IntegerSP CreateStructuredInteger() const;
	};

	class PythonList : public PythonObject {
	public:
	PythonList() {}
	explicit PythonList(PyInitialValue value);
	explicit PythonList(int list_size);
	PythonList(PyRefType type, PyObject *o);
	PythonList(const PythonList &list);

	~PythonList() override;

	static bool Check(PyObject *py_obj);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	uint32_t GetSize() const;

	PythonObject GetItemAtIndex(uint32_t index) const;

	void SetItemAtIndex(uint32_t index, const PythonObject &object);

	void AppendItem(const PythonObject &object);

	StructuredData::ArraySP CreateStructuredArray() const;
	};

	class PythonTuple : public PythonObject {
	public:
	PythonTuple() {}
	explicit PythonTuple(PyInitialValue value);
	explicit PythonTuple(int tuple_size);
	PythonTuple(PyRefType type, PyObject *o);
	PythonTuple(const PythonTuple &tuple);
	PythonTuple(std::initializer_list<PythonObject> objects);
	PythonTuple(std::initializer_list<PyObject *> objects);

	~PythonTuple() override;

	static bool Check(PyObject *py_obj);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	uint32_t GetSize() const;

	PythonObject GetItemAtIndex(uint32_t index) const;

	void SetItemAtIndex(uint32_t index, const PythonObject &object);

	StructuredData::ArraySP CreateStructuredArray() const;
	};

	class PythonDictionary : public PythonObject {
	public:
	PythonDictionary() {}
	explicit PythonDictionary(PyInitialValue value);
	PythonDictionary(PyRefType type, PyObject *o);
	PythonDictionary(const PythonDictionary &dict);

	~PythonDictionary() override;

	static bool Check(PyObject *py_obj);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	uint32_t GetSize() const;

	PythonList GetKeys() const;

	PythonObject GetItemForKey(const PythonObject &key) const;
	void SetItemForKey(const PythonObject &key, const PythonObject &value);

	StructuredData::DictionarySP CreateStructuredDictionary() const;
	};

	class PythonModule : public PythonObject {
	public:
	PythonModule();
	PythonModule(PyRefType type, PyObject *o);
	PythonModule(const PythonModule &dict);

	~PythonModule() override;

	static bool Check(PyObject *py_obj);

	static PythonModule BuiltinsModule();

	static PythonModule MainModule();

	static PythonModule AddModule(llvm::StringRef module);

	static PythonModule ImportModule(llvm::StringRef module);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	PythonDictionary GetDictionary() const;
	};

	class PythonCallable : public PythonObject {
	public:
	struct ArgInfo {
	size_t count;
	bool is_bound_method : 1;
	bool has_varargs : 1;
	bool has_kwargs : 1;
	};

	PythonCallable();
	PythonCallable(PyRefType type, PyObject *o);
	PythonCallable(const PythonCallable &dict);

	~PythonCallable() override;

	static bool Check(PyObject *py_obj);

	// Bring in the no-argument base class version
	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;

	ArgInfo GetNumArguments() const;

	PythonObject operator()();

	PythonObject operator()(std::initializer_list<PyObject *> args);

	PythonObject operator()(std::initializer_list<PythonObject> args);

	template <typename Arg, typename... Args>
	PythonObject operator()(const Arg &arg, Args... args) {
	return operator()({arg, args...});
	}
	};

	class PythonFile : public PythonObject {
	public:
	PythonFile();
	PythonFile(File &file, const char *mode);
	PythonFile(const char path, const char mode);
	PythonFile(PyRefType type, PyObject *o);

	~PythonFile() override;

	static bool Check(PyObject *py_obj);

	using PythonObject::Reset;

	void Reset(PyRefType type, PyObject *py_obj) override;
	void Reset(File &file, const char *mode);

	static uint32_t GetOptionsFromMode(llvm::StringRef mode);

	bool GetUnderlyingFile(File &file) const;
	};

	} // namespace lldb_private

	#endif

	#endif // LLDB_PLUGINS_SCRIPTINTERPRETER_PYTHON_PYTHONDATAOBJECTS_H