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| //===-- PythonDataObjects.h--------------------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// !! FIXME FIXME FIXME !!
//
// Python APIs nearly all can return an exception. They do this
// by returning NULL, or -1, or some such value and setting
// the exception state with PyErr_Set*(). Exceptions must be
// handled before further python API functions are called. Failure
// to do so will result in asserts on debug builds of python.
// It will also sometimes, but not usually result in crashes of
// release builds.
//
// Nearly all the code in this header does not handle python exceptions
// correctly. It should all be converted to return Expected<> or
// Error types to capture the exception.
//
// Everything in this file except functions that return Error or
// Expected<> is considered deprecated and should not be
// used in new code. If you need to use it, fix it first.
//
//
// TODOs for this file
//
// * Make all methods safe for exceptions.
//
// * Eliminate method signatures that must translate exceptions into
// empty objects or NULLs. Almost everything here should return
// Expected<>. It should be acceptable for certain operations that
// can never fail to assert instead, such as the creation of
// PythonString from a string literal.
//
// * Elimintate Reset(), and make all non-default constructors private.
// Python objects should be created with Retain<> or Take<>, and they
// should be assigned with operator=
//
// * Eliminate default constructors, make python objects always
// nonnull, and use optionals where necessary.
//
#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"
#include "lldb/Host/File.h"
#include "lldb/Utility/StructuredData.h"
#include "llvm/ADT/ArrayRef.h"
namespace lldb_private {
namespace python {
class PythonObject;
class PythonBytes;
class PythonString;
class PythonList;
class PythonDictionary;
class PythonInteger;
class PythonException;
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 Serialize(llvm::json::OStream &s) const override;
private:
DISALLOW_COPY_AND_ASSIGN(StructuredPythonObject);
};
enum class PyObjectType {
Unknown,
None,
Boolean,
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.
};
// Take a reference that you already own, and turn it into
// a PythonObject.
//
// Most python API methods will return a +1 reference
// if they succeed or NULL if and only if
// they set an exception. Use this to collect such return
// values, after checking for NULL.
//
// If T is not just PythonObject, then obj must be already be
// checked to be of the correct type.
template <typename T> T Take(PyObject *obj) {
assert(obj);
assert(!PyErr_Occurred());
T thing(PyRefType::Owned, obj);
assert(thing.IsValid());
return std::move(thing);
}
// Retain a reference you have borrowed, and turn it into
// a PythonObject.
//
// A minority of python APIs return a borrowed reference
// instead of a +1. They will also return NULL if and only
// if they set an exception. Use this to collect such return
// values, after checking for NULL.
//
// If T is not just PythonObject, then obj must be already be
// checked to be of the correct type.
template <typename T> T Retain(PyObject *obj) {
assert(obj);
assert(!PyErr_Occurred());
T thing(PyRefType::Borrowed, obj);
assert(thing.IsValid());
return std::move(thing);
}
// This class can be used like a utility function to convert from
// a llvm-friendly Twine into a null-terminated const char *,
// which is the form python C APIs want their strings in.
//
// Example:
// const llvm::Twine &some_twine;
// PyFoo_Bar(x, y, z, NullTerminated(some_twine));
//
// Why a class instead of a function? If the twine isn't already null
// terminated, it will need a temporary buffer to copy the string
// into. We need that buffer to stick around for the lifetime of the
// statement.
class NullTerminated {
const char *str;
llvm::SmallString<32> storage;
public:
NullTerminated(const llvm::Twine &twine) {
llvm::StringRef ref = twine.toNullTerminatedStringRef(storage);
str = ref.begin();
}
operator const char *() { return str; }
};
inline llvm::Error nullDeref() {
return llvm::createStringError(llvm::inconvertibleErrorCode(),
"A NULL PyObject* was dereferenced");
}
inline llvm::Error exception(const char *s = nullptr) {
return llvm::make_error<PythonException>(s);
}
inline llvm::Error keyError() {
return llvm::createStringError(llvm::inconvertibleErrorCode(),
"key not in dict");
}
enum class PyInitialValue { Invalid, Empty };
template <typename T, typename Enable = void> struct PythonFormat;
template <> struct PythonFormat<unsigned long long> {
static constexpr char format = 'K';
static auto get(unsigned long long value) { return value; }
};
template <> struct PythonFormat<long long> {
static constexpr char format = 'L';
static auto get(long long value) { return value; }
};
template <> struct PythonFormat<PyObject *> {
static constexpr char format = 'O';
static auto get(PyObject *value) { return value; }
};
template <typename T>
struct PythonFormat<
T, typename std::enable_if<std::is_base_of<PythonObject, T>::value>::type> {
static constexpr char format = 'O';
static auto get(const T &value) { return value.get(); }
};
class PythonObject {
public:
PythonObject() : m_py_obj(nullptr) {}
PythonObject(PyRefType type, PyObject *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 (m_py_obj && Py_IsInitialized() && type == PyRefType::Borrowed)
Py_XINCREF(m_py_obj);
}
PythonObject(const PythonObject &rhs)
: PythonObject(PyRefType::Borrowed, rhs.m_py_obj) {}
PythonObject(PythonObject &&rhs) {
m_py_obj = rhs.m_py_obj;
rhs.m_py_obj = nullptr;
}
~PythonObject() { Reset(); }
void Reset() {
if (m_py_obj && Py_IsInitialized())
Py_DECREF(m_py_obj);
m_py_obj = nullptr;
}
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=(PythonObject other) {
Reset();
m_py_obj = std::exchange(other.m_py_obj, nullptr);
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 IsNone() const { return m_py_obj == Py_None; }
bool IsValid() const { return m_py_obj != nullptr; }
bool IsAllocated() const { return IsValid() && !IsNone(); }
explicit operator bool() const { return IsValid() && !IsNone(); }
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:
#if PY_MAJOR_VERSION < 3
// The python 2 API declares some arguments as char* that should
// be const char *, but it doesn't actually modify them.
static char *py2_const_cast(const char *s) { return const_cast<char *>(s); }
#else
static const char *py2_const_cast(const char *s) { return s; }
#endif
public:
template <typename... T>
llvm::Expected<PythonObject> CallMethod(const char *name,
const T &... t) const {
const char format[] = {'(', PythonFormat<T>::format..., ')', 0};
PyObject *obj =
PyObject_CallMethod(m_py_obj, py2_const_cast(name),
py2_const_cast(format), PythonFormat<T>::get(t)...);
if (!obj)
return exception();
return python::Take<PythonObject>(obj);
}
template <typename... T>
llvm::Expected<PythonObject> Call(const T &... t) const {
const char format[] = {'(', PythonFormat<T>::format..., ')', 0};
PyObject *obj = PyObject_CallFunction(m_py_obj, py2_const_cast(format),
PythonFormat<T>::get(t)...);
if (!obj)
return exception();
return python::Take<PythonObject>(obj);
}
llvm::Expected<PythonObject> GetAttribute(const llvm::Twine &name) const {
if (!m_py_obj)
return nullDeref();
PyObject *obj = PyObject_GetAttrString(m_py_obj, NullTerminated(name));
if (!obj)
return exception();
return python::Take<PythonObject>(obj);
}
llvm::Expected<bool> IsTrue() {
if (!m_py_obj)
return nullDeref();
int r = PyObject_IsTrue(m_py_obj);
if (r < 0)
return exception();
return !!r;
}
llvm::Expected<long long> AsLongLong() {
if (!m_py_obj)
return nullDeref();
assert(!PyErr_Occurred());
long long r = PyLong_AsLongLong(m_py_obj);
if (PyErr_Occurred())
return exception();
return r;
}
llvm::Expected<bool> IsInstance(const PythonObject &cls) {
if (!m_py_obj || !cls.IsValid())
return nullDeref();
int r = PyObject_IsInstance(m_py_obj, cls.get());
if (r < 0)
return exception();
return !!r;
}
protected:
PyObject *m_py_obj;
};
// This is why C++ needs monads.
template <typename T> llvm::Expected<T> As(llvm::Expected<PythonObject> &&obj) {
if (!obj)
return obj.takeError();
if (!T::Check(obj.get().get()))
return llvm::createStringError(llvm::inconvertibleErrorCode(),
"type error");
return T(PyRefType::Borrowed, std::move(obj.get().get()));
}
template <> llvm::Expected<bool> As<bool>(llvm::Expected<PythonObject> &&obj);
template <>
llvm::Expected<long long> As<long long>(llvm::Expected<PythonObject> &&obj);
template <>
llvm::Expected<std::string> As<std::string>(llvm::Expected<PythonObject> &&obj);
template <class T> class TypedPythonObject : public PythonObject {
public:
// override to perform implicit type conversions on Reset
// This can be eliminated once we drop python 2 support.
static void Convert(PyRefType &type, PyObject *&py_obj) {}
TypedPythonObject(PyRefType type, PyObject *py_obj) {
if (!py_obj)
return;
T::Convert(type, py_obj);
if (T::Check(py_obj))
PythonObject::operator=(PythonObject(type, py_obj));
else if (type == PyRefType::Owned)
Py_DECREF(py_obj);
}
TypedPythonObject() {}
};
class PythonBytes : public TypedPythonObject<PythonBytes> {
public:
using TypedPythonObject::TypedPythonObject;
explicit PythonBytes(llvm::ArrayRef<uint8_t> bytes);
PythonBytes(const uint8_t *bytes, size_t length);
static bool Check(PyObject *py_obj);
llvm::ArrayRef<uint8_t> GetBytes() const;
size_t GetSize() const;
void SetBytes(llvm::ArrayRef<uint8_t> stringbytes);
StructuredData::StringSP CreateStructuredString() const;
};
class PythonByteArray : public TypedPythonObject<PythonByteArray> {
public:
using TypedPythonObject::TypedPythonObject;
explicit PythonByteArray(llvm::ArrayRef<uint8_t> bytes);
PythonByteArray(const uint8_t *bytes, size_t length);
PythonByteArray(const PythonBytes &object);
static bool Check(PyObject *py_obj);
llvm::ArrayRef<uint8_t> GetBytes() const;
size_t GetSize() const;
void SetBytes(llvm::ArrayRef<uint8_t> stringbytes);
StructuredData::StringSP CreateStructuredString() const;
};
class PythonString : public TypedPythonObject<PythonString> {
public:
using TypedPythonObject::TypedPythonObject;
static llvm::Expected<PythonString> FromUTF8(llvm::StringRef string);
PythonString() : TypedPythonObject() {} // MSVC requires this for some reason
explicit PythonString(llvm::StringRef string); // safe, null on error
static bool Check(PyObject *py_obj);
static void Convert(PyRefType &type, PyObject *&py_obj);
llvm::StringRef GetString() const; // safe, empty string on error
llvm::Expected<llvm::StringRef> AsUTF8() const;
size_t GetSize() const;
void SetString(llvm::StringRef string); // safe, null on error
StructuredData::StringSP CreateStructuredString() const;
};
class PythonInteger : public TypedPythonObject<PythonInteger> {
public:
using TypedPythonObject::TypedPythonObject;
PythonInteger() : TypedPythonObject() {} // MSVC requires this for some reason
explicit PythonInteger(int64_t value);
static bool Check(PyObject *py_obj);
static void Convert(PyRefType &type, PyObject *&py_obj);
int64_t GetInteger() const;
void SetInteger(int64_t value);
StructuredData::IntegerSP CreateStructuredInteger() const;
};
class PythonBoolean : public TypedPythonObject<PythonBoolean> {
public:
using TypedPythonObject::TypedPythonObject;
explicit PythonBoolean(bool value);
static bool Check(PyObject *py_obj);
bool GetValue() const;
void SetValue(bool value);
StructuredData::BooleanSP CreateStructuredBoolean() const;
};
class PythonList : public TypedPythonObject<PythonList> {
public:
using TypedPythonObject::TypedPythonObject;
PythonList() : TypedPythonObject() {} // MSVC requires this for some reason
explicit PythonList(PyInitialValue value);
explicit PythonList(int list_size);
static bool Check(PyObject *py_obj);
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 TypedPythonObject<PythonTuple> {
public:
using TypedPythonObject::TypedPythonObject;
explicit PythonTuple(PyInitialValue value);
explicit PythonTuple(int tuple_size);
PythonTuple(std::initializer_list<PythonObject> objects);
PythonTuple(std::initializer_list<PyObject *> objects);
static bool Check(PyObject *py_obj);
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 TypedPythonObject<PythonDictionary> {
public:
using TypedPythonObject::TypedPythonObject;
PythonDictionary() : TypedPythonObject() {} // MSVC requires this for some reason
explicit PythonDictionary(PyInitialValue value);
static bool Check(PyObject *py_obj);
uint32_t GetSize() const;
PythonList GetKeys() const;
PythonObject GetItemForKey(const PythonObject &key) const; // DEPRECATED
void SetItemForKey(const PythonObject &key,
const PythonObject &value); // DEPRECATED
llvm::Expected<PythonObject> GetItem(const PythonObject &key) const;
llvm::Expected<PythonObject> GetItem(const llvm::Twine &key) const;
llvm::Error SetItem(const PythonObject &key, const PythonObject &value) const;
llvm::Error SetItem(const llvm::Twine &key, const PythonObject &value) const;
StructuredData::DictionarySP CreateStructuredDictionary() const;
};
class PythonModule : public TypedPythonObject<PythonModule> {
public:
using TypedPythonObject::TypedPythonObject;
static bool Check(PyObject *py_obj);
static PythonModule BuiltinsModule();
static PythonModule MainModule();
static PythonModule AddModule(llvm::StringRef module);
// safe, returns invalid on error;
static PythonModule ImportModule(llvm::StringRef name) {
std::string s = name;
auto mod = Import(s.c_str());
if (!mod) {
llvm::consumeError(mod.takeError());
return PythonModule();
}
return std::move(mod.get());
}
static llvm::Expected<PythonModule> Import(const llvm::Twine &name);
llvm::Expected<PythonObject> Get(const llvm::Twine &name);
PythonDictionary GetDictionary() const;
};
class PythonCallable : public TypedPythonObject<PythonCallable> {
public:
using TypedPythonObject::TypedPythonObject;
struct ArgInfo {
/* the largest number of positional arguments this callable
* can accept, or UNBOUNDED, ie UINT_MAX if it's a varargs
* function and can accept an arbitrary number */
unsigned max_positional_args;
static constexpr unsigned UNBOUNDED = UINT_MAX; // FIXME c++17 inline
/* the number of positional arguments, including optional ones,
* and excluding varargs. If this is a bound method, then the
* count will still include a +1 for self.
*
* FIXME. That's crazy. This should be replaced with
* an accurate min and max for positional args.
*/
int count;
/* does the callable have positional varargs? */
bool has_varargs : 1; // FIXME delete this
};
static bool Check(PyObject *py_obj);
llvm::Expected<ArgInfo> GetArgInfo() const;
llvm::Expected<ArgInfo> GetInitArgInfo() const;
ArgInfo GetNumArguments() const; // DEPRECATED
// If the callable is a Py_Class, then find the number of arguments
// of the __init__ method.
ArgInfo GetNumInitArguments() const; // DEPRECATED
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 TypedPythonObject<PythonFile> {
public:
using TypedPythonObject::TypedPythonObject;
PythonFile() : TypedPythonObject() {} // MSVC requires this for some reason
static bool Check(PyObject *py_obj);
static llvm::Expected<PythonFile> FromFile(File &file,
const char *mode = nullptr);
llvm::Expected<lldb::FileSP> ConvertToFile(bool borrowed = false);
llvm::Expected<lldb::FileSP>
ConvertToFileForcingUseOfScriptingIOMethods(bool borrowed = false);
};
class PythonException : public llvm::ErrorInfo<PythonException> {
private:
PyObject *m_exception_type, *m_exception, *m_traceback;
PyObject *m_repr_bytes;
public:
static char ID;
const char *toCString() const;
PythonException(const char *caller = nullptr);
void Restore();
~PythonException();
void log(llvm::raw_ostream &OS) const override;
std::error_code convertToErrorCode() const override;
bool Matches(PyObject *exc) const;
std::string ReadBacktrace() const;
};
// This extracts the underlying T out of an Expected<T> and returns it.
// If the Expected is an Error instead of a T, that error will be converted
// into a python exception, and this will return a default-constructed T.
//
// This is appropriate for use right at the boundary of python calling into
// C++, such as in a SWIG typemap. In such a context you should simply
// check if the returned T is valid, and if it is, return a NULL back
// to python. This will result in the Error being raised as an exception
// from python code's point of view.
//
// For example:
// ```
// Expected<Foo *> efoop = some_cpp_function();
// Foo *foop = unwrapOrSetPythonException(efoop);
// if (!foop)
// return NULL;
// do_something(*foop);
//
// If the Error returned was itself created because a python exception was
// raised when C++ code called into python, then the original exception
// will be restored. Otherwise a simple string exception will be raised.
template <typename T> T unwrapOrSetPythonException(llvm::Expected<T> expected) {
if (expected)
return expected.get();
llvm::handleAllErrors(
expected.takeError(), [](PythonException &E) { E.Restore(); },
[](const llvm::ErrorInfoBase &E) {
PyErr_SetString(PyExc_Exception, E.message().c_str());
});
return T();
}
// This is only here to help incrementally migrate old, exception-unsafe
// code.
template <typename T> T unwrapIgnoringErrors(llvm::Expected<T> expected) {
if (expected)
return std::move(expected.get());
llvm::consumeError(expected.takeError());
return T();
}
llvm::Expected<PythonObject> runStringOneLine(const llvm::Twine &string,
const PythonDictionary &globals,
const PythonDictionary &locals);
llvm::Expected<PythonObject> runStringMultiLine(const llvm::Twine &string,
const PythonDictionary &globals,
const PythonDictionary &locals);
// Sometimes the best way to interact with a python interpreter is
// to run some python code. You construct a PythonScript with
// script string. The script assigns some function to `_function_`
// and you get a C++ callable object that calls the python function.
//
// Example:
//
// const char script[] = R"(
// def main(x, y):
// ....
// )";
//
// Expected<PythonObject> cpp_foo_wrapper(PythonObject x, PythonObject y) {
// // no need to synchronize access to this global, we already have the GIL
// static PythonScript foo(script)
// return foo(x, y);
// }
class PythonScript {
const char *script;
PythonCallable function;
llvm::Error Init();
public:
PythonScript(const char *script) : script(script), function() {}
template <typename... Args>
llvm::Expected<PythonObject> operator()(Args &&... args) {
if (llvm::Error error = Init())
return std::move(error);
return function.Call(std::forward<Args>(args)...);
}
};
} // namespace python
} // namespace lldb_private
#endif
#endif // LLDB_PLUGINS_SCRIPTINTERPRETER_PYTHON_PYTHONDATAOBJECTS_H
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