//===-- PythonDataObjects.cpp ------------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#ifdef LLDB_DISABLE_PYTHON
// Python is disabled in this build
#else
#include "lldb-python.h"
#include "PythonDataObjects.h"
#include "ScriptInterpreterPython.h"
#include "lldb/Core/Stream.h"
#include "lldb/Host/File.h"
#include "lldb/Interpreter/ScriptInterpreter.h"
#include <stdio.h>
using namespace lldb_private;
using namespace lldb;
void
StructuredPythonObject::Dump(Stream &s) const
{
s << "Python Obj: 0x" << GetValue();
}
//----------------------------------------------------------------------
// PythonObject
//----------------------------------------------------------------------
void
PythonObject::Dump(Stream &strm) const
{
if (m_py_obj)
{
FILE *file = ::tmpfile();
if (file)
{
::PyObject_Print (m_py_obj, file, 0);
const long length = ftell (file);
if (length)
{
::rewind(file);
std::vector<char> file_contents (length,'\0');
const size_t length_read = ::fread (file_contents.data(), 1, file_contents.size(), file);
if (length_read > 0)
strm.Write (file_contents.data(), length_read);
}
::fclose (file);
}
}
else
strm.PutCString ("NULL");
}
PyObjectType
PythonObject::GetObjectType() const
{
if (!IsAllocated())
return PyObjectType::None;
if (PythonModule::Check(m_py_obj))
return PyObjectType::Module;
if (PythonList::Check(m_py_obj))
return PyObjectType::List;
if (PythonTuple::Check(m_py_obj))
return PyObjectType::Tuple;
if (PythonDictionary::Check(m_py_obj))
return PyObjectType::Dictionary;
if (PythonString::Check(m_py_obj))
return PyObjectType::String;
#if PY_MAJOR_VERSION >= 3
if (PythonBytes::Check(m_py_obj))
return PyObjectType::Bytes;
#endif
if (PythonInteger::Check(m_py_obj))
return PyObjectType::Integer;
if (PythonFile::Check(m_py_obj))
return PyObjectType::File;
if (PythonCallable::Check(m_py_obj))
return PyObjectType::Callable;
return PyObjectType::Unknown;
}
PythonString
PythonObject::Repr() const
{
if (!m_py_obj)
return PythonString();
PyObject *repr = PyObject_Repr(m_py_obj);
if (!repr)
return PythonString();
return PythonString(PyRefType::Owned, repr);
}
PythonString
PythonObject::Str() const
{
if (!m_py_obj)
return PythonString();
PyObject *str = PyObject_Str(m_py_obj);
if (!str)
return PythonString();
return PythonString(PyRefType::Owned, str);
}
PythonObject
PythonObject::ResolveNameWithDictionary(llvm::StringRef name, const PythonDictionary &dict)
{
size_t dot_pos = name.find_first_of('.');
llvm::StringRef piece = name.substr(0, dot_pos);
PythonObject result = dict.GetItemForKey(PythonString(piece));
if (dot_pos == llvm::StringRef::npos)
{
// There was no dot, we're done.
return result;
}
// There was a dot. The remaining portion of the name should be looked up in
// the context of the object that was found in the dictionary.
return result.ResolveName(name.substr(dot_pos + 1));
}
PythonObject
PythonObject::ResolveName(llvm::StringRef name) const
{
// Resolve the name in the context of the specified object. If,
// for example, `this` refers to a PyModule, then this will look for
// `name` in this module. If `this` refers to a PyType, then it will
// resolve `name` as an attribute of that type. If `this` refers to
// an instance of an object, then it will resolve `name` as the value
// of the specified field.
//
// This function handles dotted names so that, for example, if `m_py_obj`
// refers to the `sys` module, and `name` == "path.append", then it
// will find the function `sys.path.append`.
size_t dot_pos = name.find_first_of('.');
if (dot_pos == llvm::StringRef::npos)
{
// No dots in the name, we should be able to find the value immediately
// as an attribute of `m_py_obj`.
return GetAttributeValue(name);
}
// Look up the first piece of the name, and resolve the rest as a child of that.
PythonObject parent = ResolveName(name.substr(0, dot_pos));
if (!parent.IsAllocated())
return PythonObject();
// Tail recursion.. should be optimized by the compiler
return parent.ResolveName(name.substr(dot_pos + 1));
}
bool
PythonObject::HasAttribute(llvm::StringRef attr) const
{
if (!IsValid())
return false;
PythonString py_attr(attr);
return !!PyObject_HasAttr(m_py_obj, py_attr.get());
}
PythonObject
PythonObject::GetAttributeValue(llvm::StringRef attr) const
{
if (!IsValid())
return PythonObject();
PythonString py_attr(attr);
if (!PyObject_HasAttr(m_py_obj, py_attr.get()))
return PythonObject();
return PythonObject(PyRefType::Owned,
PyObject_GetAttr(m_py_obj, py_attr.get()));
}
bool
PythonObject::IsNone() const
{
return m_py_obj == Py_None;
}
bool
PythonObject::IsValid() const
{
return m_py_obj != nullptr;
}
bool
PythonObject::IsAllocated() const
{
return IsValid() && !IsNone();
}
StructuredData::ObjectSP
PythonObject::CreateStructuredObject() const
{
switch (GetObjectType())
{
case PyObjectType::Dictionary:
return PythonDictionary(PyRefType::Borrowed, m_py_obj).CreateStructuredDictionary();
case PyObjectType::Integer:
return PythonInteger(PyRefType::Borrowed, m_py_obj).CreateStructuredInteger();
case PyObjectType::List:
return PythonList(PyRefType::Borrowed, m_py_obj).CreateStructuredArray();
case PyObjectType::String:
return PythonString(PyRefType::Borrowed, m_py_obj).CreateStructuredString();
case PyObjectType::Bytes:
return PythonBytes(PyRefType::Borrowed, m_py_obj).CreateStructuredString();
case PyObjectType::None:
return StructuredData::ObjectSP();
default:
return StructuredData::ObjectSP(new StructuredPythonObject(m_py_obj));
}
}
//----------------------------------------------------------------------
// PythonString
//----------------------------------------------------------------------
PythonBytes::PythonBytes() : PythonObject()
{
}
PythonBytes::PythonBytes(llvm::ArrayRef<uint8_t> bytes) : PythonObject()
{
SetBytes(bytes);
}
PythonBytes::PythonBytes(const uint8_t *bytes, size_t length) : PythonObject()
{
SetBytes(llvm::ArrayRef<uint8_t>(bytes, length));
}
PythonBytes::PythonBytes(PyRefType type, PyObject *py_obj) : PythonObject()
{
Reset(type, py_obj); // Use "Reset()" to ensure that py_obj is a string
}
PythonBytes::PythonBytes(const PythonBytes &object) : PythonObject(object)
{
}
PythonBytes::~PythonBytes()
{
}
bool
PythonBytes::Check(PyObject *py_obj)
{
if (!py_obj)
return false;
if (PyBytes_Check(py_obj))
return true;
return false;
}
void
PythonBytes::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonBytes::Check(py_obj))
{
PythonObject::Reset();
return;
}
// Calling PythonObject::Reset(const PythonObject&) will lead to stack overflow since it calls
// back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
llvm::ArrayRef<uint8_t>
PythonBytes::GetBytes() const
{
if (!IsValid())
return llvm::ArrayRef<uint8_t>();
Py_ssize_t size;
char *c;
PyBytes_AsStringAndSize(m_py_obj, &c, &size);
return llvm::ArrayRef<uint8_t>(reinterpret_cast<uint8_t *>(c), size);
}
size_t
PythonBytes::GetSize() const
{
if (!IsValid())
return 0;
return PyBytes_Size(m_py_obj);
}
void
PythonBytes::SetBytes(llvm::ArrayRef<uint8_t> bytes)
{
const char *data = reinterpret_cast<const char *>(bytes.data());
PyObject *py_bytes = PyBytes_FromStringAndSize(data, bytes.size());
PythonObject::Reset(PyRefType::Owned, py_bytes);
}
StructuredData::StringSP
PythonBytes::CreateStructuredString() const
{
StructuredData::StringSP result(new StructuredData::String);
Py_ssize_t size;
char *c;
PyBytes_AsStringAndSize(m_py_obj, &c, &size);
result->SetValue(std::string(c, size));
return result;
}
//----------------------------------------------------------------------
// PythonString
//----------------------------------------------------------------------
PythonString::PythonString(PyRefType type, PyObject *py_obj)
: PythonObject()
{
Reset(type, py_obj); // Use "Reset()" to ensure that py_obj is a string
}
PythonString::PythonString(const PythonString &object)
: PythonObject(object)
{
}
PythonString::PythonString(llvm::StringRef string)
: PythonObject()
{
SetString(string);
}
PythonString::PythonString(const char *string)
: PythonObject()
{
SetString(llvm::StringRef(string));
}
PythonString::PythonString()
: PythonObject()
{
}
PythonString::~PythonString ()
{
}
bool
PythonString::Check(PyObject *py_obj)
{
if (!py_obj)
return false;
if (PyUnicode_Check(py_obj))
return true;
#if PY_MAJOR_VERSION < 3
if (PyString_Check(py_obj))
return true;
#endif
return false;
}
void
PythonString::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonString::Check(py_obj))
{
PythonObject::Reset();
return;
}
#if PY_MAJOR_VERSION < 3
// In Python 2, Don't store PyUnicode objects directly, because we need
// access to their underlying character buffers which Python 2 doesn't
// provide.
if (PyUnicode_Check(py_obj))
result.Reset(PyRefType::Owned, PyUnicode_AsUTF8String(result.get()));
#endif
// Calling PythonObject::Reset(const PythonObject&) will lead to stack overflow since it calls
// back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
llvm::StringRef
PythonString::GetString() const
{
if (!IsValid())
return llvm::StringRef();
Py_ssize_t size;
char *c;
#if PY_MAJOR_VERSION >= 3
c = PyUnicode_AsUTF8AndSize(m_py_obj, &size);
#else
PyString_AsStringAndSize(m_py_obj, &c, &size);
#endif
return llvm::StringRef(c, size);
}
size_t
PythonString::GetSize() const
{
if (IsValid())
{
#if PY_MAJOR_VERSION >= 3
return PyUnicode_GetSize(m_py_obj);
#else
return PyString_Size(m_py_obj);
#endif
}
return 0;
}
void
PythonString::SetString (llvm::StringRef string)
{
#if PY_MAJOR_VERSION >= 3
PyObject *unicode = PyUnicode_FromStringAndSize(string.data(), string.size());
PythonObject::Reset(PyRefType::Owned, unicode);
#else
PyObject *str = PyString_FromStringAndSize(string.data(), string.size());
PythonObject::Reset(PyRefType::Owned, str);
#endif
}
StructuredData::StringSP
PythonString::CreateStructuredString() const
{
StructuredData::StringSP result(new StructuredData::String);
result->SetValue(GetString());
return result;
}
//----------------------------------------------------------------------
// PythonInteger
//----------------------------------------------------------------------
PythonInteger::PythonInteger()
: PythonObject()
{
}
PythonInteger::PythonInteger(PyRefType type, PyObject *py_obj)
: PythonObject()
{
Reset(type, py_obj); // Use "Reset()" to ensure that py_obj is a integer type
}
PythonInteger::PythonInteger(const PythonInteger &object)
: PythonObject(object)
{
}
PythonInteger::PythonInteger(int64_t value)
: PythonObject()
{
SetInteger(value);
}
PythonInteger::~PythonInteger ()
{
}
bool
PythonInteger::Check(PyObject *py_obj)
{
if (!py_obj)
return false;
#if PY_MAJOR_VERSION >= 3
// Python 3 does not have PyInt_Check. There is only one type of
// integral value, long.
return PyLong_Check(py_obj);
#else
return PyLong_Check(py_obj) || PyInt_Check(py_obj);
#endif
}
void
PythonInteger::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonInteger::Check(py_obj))
{
PythonObject::Reset();
return;
}
#if PY_MAJOR_VERSION < 3
// Always store this as a PyLong, which makes interoperability between
// Python 2.x and Python 3.x easier. This is only necessary in 2.x,
// since 3.x doesn't even have a PyInt.
if (PyInt_Check(py_obj))
{
// Since we converted the original object to a different type, the new
// object is an owned object regardless of the ownership semantics requested
// by the user.
result.Reset(PyRefType::Owned, PyLong_FromLongLong(PyInt_AsLong(py_obj)));
}
#endif
assert(PyLong_Check(result.get()) && "Couldn't get a PyLong from this PyObject");
// Calling PythonObject::Reset(const PythonObject&) will lead to stack overflow since it calls
// back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
int64_t
PythonInteger::GetInteger() const
{
if (m_py_obj)
{
assert(PyLong_Check(m_py_obj) && "PythonInteger::GetInteger has a PyObject that isn't a PyLong");
return PyLong_AsLongLong(m_py_obj);
}
return UINT64_MAX;
}
void
PythonInteger::SetInteger(int64_t value)
{
PythonObject::Reset(PyRefType::Owned, PyLong_FromLongLong(value));
}
StructuredData::IntegerSP
PythonInteger::CreateStructuredInteger() const
{
StructuredData::IntegerSP result(new StructuredData::Integer);
result->SetValue(GetInteger());
return result;
}
//----------------------------------------------------------------------
// PythonList
//----------------------------------------------------------------------
PythonList::PythonList(PyInitialValue value)
: PythonObject()
{
if (value == PyInitialValue::Empty)
Reset(PyRefType::Owned, PyList_New(0));
}
PythonList::PythonList(int list_size)
: PythonObject()
{
Reset(PyRefType::Owned, PyList_New(list_size));
}
PythonList::PythonList(PyRefType type, PyObject *py_obj)
: PythonObject()
{
Reset(type, py_obj); // Use "Reset()" to ensure that py_obj is a list
}
PythonList::PythonList(const PythonList &list)
: PythonObject(list)
{
}
PythonList::~PythonList ()
{
}
bool
PythonList::Check(PyObject *py_obj)
{
if (!py_obj)
return false;
return PyList_Check(py_obj);
}
void
PythonList::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonList::Check(py_obj))
{
PythonObject::Reset();
return;
}
// Calling PythonObject::Reset(const PythonObject&) will lead to stack overflow since it calls
// back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
uint32_t
PythonList::GetSize() const
{
if (IsValid())
return PyList_GET_SIZE(m_py_obj);
return 0;
}
PythonObject
PythonList::GetItemAtIndex(uint32_t index) const
{
if (IsValid())
return PythonObject(PyRefType::Borrowed, PyList_GetItem(m_py_obj, index));
return PythonObject();
}
void
PythonList::SetItemAtIndex(uint32_t index, const PythonObject &object)
{
if (IsAllocated() && object.IsValid())
{
// PyList_SetItem is documented to "steal" a reference, so we need to
// convert it to an owned reference by incrementing it.
Py_INCREF(object.get());
PyList_SetItem(m_py_obj, index, object.get());
}
}
void
PythonList::AppendItem(const PythonObject &object)
{
if (IsAllocated() && object.IsValid())
{
// `PyList_Append` does *not* steal a reference, so do not call `Py_INCREF`
// here like we do with `PyList_SetItem`.
PyList_Append(m_py_obj, object.get());
}
}
StructuredData::ArraySP
PythonList::CreateStructuredArray() const
{
StructuredData::ArraySP result(new StructuredData::Array);
uint32_t count = GetSize();
for (uint32_t i = 0; i < count; ++i)
{
PythonObject obj = GetItemAtIndex(i);
result->AddItem(obj.CreateStructuredObject());
}
return result;
}
//----------------------------------------------------------------------
// PythonTuple
//----------------------------------------------------------------------
PythonTuple::PythonTuple(PyInitialValue value)
: PythonObject()
{
if (value == PyInitialValue::Empty)
Reset(PyRefType::Owned, PyTuple_New(0));
}
PythonTuple::PythonTuple(int tuple_size)
: PythonObject()
{
Reset(PyRefType::Owned, PyTuple_New(tuple_size));
}
PythonTuple::PythonTuple(PyRefType type, PyObject *py_obj)
: PythonObject()
{
Reset(type, py_obj); // Use "Reset()" to ensure that py_obj is a tuple
}
PythonTuple::PythonTuple(const PythonTuple &tuple)
: PythonObject(tuple)
{
}
PythonTuple::PythonTuple(std::initializer_list<PythonObject> objects)
{
m_py_obj = PyTuple_New(objects.size());
uint32_t idx = 0;
for (auto object : objects)
{
if (object.IsValid())
SetItemAtIndex(idx, object);
idx++;
}
}
PythonTuple::PythonTuple(std::initializer_list<PyObject*> objects)
{
m_py_obj = PyTuple_New(objects.size());
uint32_t idx = 0;
for (auto py_object : objects)
{
PythonObject object(PyRefType::Borrowed, py_object);
if (object.IsValid())
SetItemAtIndex(idx, object);
idx++;
}
}
PythonTuple::~PythonTuple()
{
}
bool
PythonTuple::Check(PyObject *py_obj)
{
if (!py_obj)
return false;
return PyTuple_Check(py_obj);
}
void
PythonTuple::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonTuple::Check(py_obj))
{
PythonObject::Reset();
return;
}
// Calling PythonObject::Reset(const PythonObject&) will lead to stack overflow since it calls
// back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
uint32_t
PythonTuple::GetSize() const
{
if (IsValid())
return PyTuple_GET_SIZE(m_py_obj);
return 0;
}
PythonObject
PythonTuple::GetItemAtIndex(uint32_t index) const
{
if (IsValid())
return PythonObject(PyRefType::Borrowed, PyTuple_GetItem(m_py_obj, index));
return PythonObject();
}
void
PythonTuple::SetItemAtIndex(uint32_t index, const PythonObject &object)
{
if (IsAllocated() && object.IsValid())
{
// PyTuple_SetItem is documented to "steal" a reference, so we need to
// convert it to an owned reference by incrementing it.
Py_INCREF(object.get());
PyTuple_SetItem(m_py_obj, index, object.get());
}
}
StructuredData::ArraySP
PythonTuple::CreateStructuredArray() const
{
StructuredData::ArraySP result(new StructuredData::Array);
uint32_t count = GetSize();
for (uint32_t i = 0; i < count; ++i)
{
PythonObject obj = GetItemAtIndex(i);
result->AddItem(obj.CreateStructuredObject());
}
return result;
}
//----------------------------------------------------------------------
// PythonDictionary
//----------------------------------------------------------------------
PythonDictionary::PythonDictionary(PyInitialValue value)
: PythonObject()
{
if (value == PyInitialValue::Empty)
Reset(PyRefType::Owned, PyDict_New());
}
PythonDictionary::PythonDictionary(PyRefType type, PyObject *py_obj)
: PythonObject()
{
Reset(type, py_obj); // Use "Reset()" to ensure that py_obj is a dictionary
}
PythonDictionary::PythonDictionary(const PythonDictionary &object)
: PythonObject(object)
{
}
PythonDictionary::~PythonDictionary ()
{
}
bool
PythonDictionary::Check(PyObject *py_obj)
{
if (!py_obj)
return false;
return PyDict_Check(py_obj);
}
void
PythonDictionary::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonDictionary::Check(py_obj))
{
PythonObject::Reset();
return;
}
// Calling PythonObject::Reset(const PythonObject&) will lead to stack overflow since it calls
// back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
uint32_t
PythonDictionary::GetSize() const
{
if (IsValid())
return PyDict_Size(m_py_obj);
return 0;
}
PythonList
PythonDictionary::GetKeys() const
{
if (IsValid())
return PythonList(PyRefType::Owned, PyDict_Keys(m_py_obj));
return PythonList(PyInitialValue::Invalid);
}
PythonObject
PythonDictionary::GetItemForKey(const PythonObject &key) const
{
if (IsAllocated() && key.IsValid())
return PythonObject(PyRefType::Borrowed, PyDict_GetItem(m_py_obj, key.get()));
return PythonObject();
}
void
PythonDictionary::SetItemForKey(const PythonObject &key, const PythonObject &value)
{
if (IsAllocated() && key.IsValid() && value.IsValid())
PyDict_SetItem(m_py_obj, key.get(), value.get());
}
StructuredData::DictionarySP
PythonDictionary::CreateStructuredDictionary() const
{
StructuredData::DictionarySP result(new StructuredData::Dictionary);
PythonList keys(GetKeys());
uint32_t num_keys = keys.GetSize();
for (uint32_t i = 0; i < num_keys; ++i)
{
PythonObject key = keys.GetItemAtIndex(i);
PythonObject value = GetItemForKey(key);
StructuredData::ObjectSP structured_value = value.CreateStructuredObject();
result->AddItem(key.Str().GetString(), structured_value);
}
return result;
}
PythonModule::PythonModule() : PythonObject()
{
}
PythonModule::PythonModule(PyRefType type, PyObject *py_obj)
{
Reset(type, py_obj); // Use "Reset()" to ensure that py_obj is a module
}
PythonModule::PythonModule(const PythonModule &dict) : PythonObject(dict)
{
}
PythonModule::~PythonModule()
{
}
PythonModule
PythonModule::BuiltinsModule()
{
#if PY_MAJOR_VERSION >= 3
return AddModule("builtins");
#else
return AddModule("__builtin__");
#endif
}
PythonModule
PythonModule::MainModule()
{
return AddModule("__main__");
}
PythonModule
PythonModule::AddModule(llvm::StringRef module)
{
std::string str = module.str();
return PythonModule(PyRefType::Borrowed, PyImport_AddModule(str.c_str()));
}
PythonModule
PythonModule::ImportModule(llvm::StringRef module)
{
std::string str = module.str();
return PythonModule(PyRefType::Owned, PyImport_ImportModule(str.c_str()));
}
bool
PythonModule::Check(PyObject *py_obj)
{
if (!py_obj)
return false;
return PyModule_Check(py_obj);
}
void
PythonModule::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonModule::Check(py_obj))
{
PythonObject::Reset();
return;
}
// Calling PythonObject::Reset(const PythonObject&) will lead to stack overflow since it calls
// back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
PythonDictionary
PythonModule::GetDictionary() const
{
return PythonDictionary(PyRefType::Borrowed, PyModule_GetDict(m_py_obj));
}
PythonCallable::PythonCallable() : PythonObject()
{
}
PythonCallable::PythonCallable(PyRefType type, PyObject *py_obj)
{
Reset(type, py_obj); // Use "Reset()" to ensure that py_obj is a callable
}
PythonCallable::PythonCallable(const PythonCallable &callable)
: PythonObject(callable)
{
}
PythonCallable::~PythonCallable()
{
}
bool
PythonCallable::Check(PyObject *py_obj)
{
if (!py_obj)
return false;
return PyCallable_Check(py_obj);
}
void
PythonCallable::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonCallable::Check(py_obj))
{
PythonObject::Reset();
return;
}
// Calling PythonObject::Reset(const PythonObject&) will lead to stack overflow since it calls
// back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
PythonCallable::ArgInfo
PythonCallable::GetNumArguments() const
{
ArgInfo result = { 0, false, false };
if (!IsValid())
return result;
PyObject *py_func_obj = m_py_obj;
if (PyMethod_Check(py_func_obj))
py_func_obj = PyMethod_GET_FUNCTION(py_func_obj);
if (!py_func_obj)
return result;
PyCodeObject* code = (PyCodeObject*)PyFunction_GET_CODE(py_func_obj);
if (!code)
return result;
result.count = code->co_argcount;
result.has_varargs = !!(code->co_flags & CO_VARARGS);
result.has_kwargs = !!(code->co_flags & CO_VARKEYWORDS);
return result;
}
PythonObject
PythonCallable::operator ()()
{
return PythonObject(PyRefType::Owned,
PyObject_CallObject(m_py_obj, nullptr));
}
PythonObject
PythonCallable::operator ()(std::initializer_list<PyObject*> args)
{
PythonTuple arg_tuple(args);
return PythonObject(PyRefType::Owned,
PyObject_CallObject(m_py_obj, arg_tuple.get()));
}
PythonObject
PythonCallable::operator ()(std::initializer_list<PythonObject> args)
{
PythonTuple arg_tuple(args);
return PythonObject(PyRefType::Owned,
PyObject_CallObject(m_py_obj, arg_tuple.get()));
}
PythonFile::PythonFile()
: PythonObject()
{
}
PythonFile::PythonFile(File &file, const char *mode)
{
Reset(file, mode);
}
PythonFile::PythonFile(const char *path, const char *mode)
{
FILE *fp = nullptr;
fp = fopen(path, mode);
lldb_private::File file(fp, true);
Reset(file, mode);
}
PythonFile::PythonFile(PyRefType type, PyObject *o)
{
Reset(type, o);
}
PythonFile::~PythonFile()
{
}
bool
PythonFile::Check(PyObject *py_obj)
{
#if PY_MAJOR_VERSION < 3
return PyFile_Check(py_obj);
#else
// In Python 3, there is no `PyFile_Check`, and in fact PyFile is not even a
// first-class object type anymore. `PyFile_FromFd` is just a thin wrapper
// over `io.open()`, which returns some object derived from `io.IOBase`.
// As a result, the only way to detect a file in Python 3 is to check whether
// it inherits from `io.IOBase`. Since it is possible for non-files to also
// inherit from `io.IOBase`, we additionally verify that it has the `fileno`
// attribute, which should guarantee that it is backed by the file system.
PythonObject io_module(PyRefType::Owned, PyImport_ImportModule("io"));
PythonDictionary io_dict(PyRefType::Borrowed, PyModule_GetDict(io_module.get()));
PythonObject io_base_class = io_dict.GetItemForKey(PythonString("IOBase"));
PythonObject object_type(PyRefType::Owned, PyObject_Type(py_obj));
if (1 != PyObject_IsSubclass(object_type.get(), io_base_class.get()))
return false;
if (!object_type.HasAttribute("fileno"))
return false;
return true;
#endif
}
void
PythonFile::Reset(PyRefType type, PyObject *py_obj)
{
// Grab the desired reference type so that if we end up rejecting
// `py_obj` it still gets decremented if necessary.
PythonObject result(type, py_obj);
if (!PythonFile::Check(py_obj))
{
PythonObject::Reset();
return;
}
// Calling PythonObject::Reset(const PythonObject&) will lead to stack
// overflow since it calls back into the virtual implementation.
PythonObject::Reset(PyRefType::Borrowed, result.get());
}
void
PythonFile::Reset(File &file, const char *mode)
{
if (!file.IsValid())
{
Reset();
return;
}
char *cmode = const_cast<char *>(mode);
#if PY_MAJOR_VERSION >= 3
Reset(PyRefType::Owned,
PyFile_FromFd(file.GetDescriptor(), nullptr, cmode, -1, nullptr, "ignore", nullptr, 0));
#else
// Read through the Python source, doesn't seem to modify these strings
Reset(PyRefType::Owned,
PyFile_FromFile(file.GetStream(), const_cast<char *>(""), cmode, nullptr));
#endif
}
bool
PythonFile::GetUnderlyingFile(File &file) const
{
if (!IsValid())
return false;
file.Close();
// We don't own the file descriptor returned by this function, make sure the
// File object knows about that.
file.SetDescriptor(PyObject_AsFileDescriptor(m_py_obj), false);
return file.IsValid();
}
#endif