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901 lines (805 loc) · 36.8 KB
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using System;
using System.Collections.Generic;
using System.Linq;
using System.Reflection;
using System.Reflection.Emit;
using System.Resources;
using System.Runtime.InteropServices;
using System.Threading.Tasks;
namespace Python.Runtime
{
/// <summary>
/// Managed class that provides the implementation for reflected types.
/// Managed classes and value types are represented in Python by actual
/// Python type objects. Each of those type objects is associated with
/// an instance of ClassObject, which provides its implementation.
/// </summary>
/// <remarks>
/// interface used to identify which C# types were dynamically created as python subclasses
/// </remarks>
public interface IPythonDerivedType
{
}
[Serializable]
internal class ClassDerivedObject : ClassObject
{
private static Dictionary<string, AssemblyBuilder> assemblyBuilders;
private static Dictionary<Tuple<string, string>, ModuleBuilder> moduleBuilders;
static ClassDerivedObject()
{
assemblyBuilders = new Dictionary<string, AssemblyBuilder>();
moduleBuilders = new Dictionary<Tuple<string, string>, ModuleBuilder>();
}
public static void Reset()
{
assemblyBuilders = new Dictionary<string, AssemblyBuilder>();
moduleBuilders = new Dictionary<Tuple<string, string>, ModuleBuilder>();
}
internal ClassDerivedObject(Type tp) : base(tp)
{
}
/// <summary>
/// Implements __new__ for derived classes of reflected classes.
/// </summary>
public new static IntPtr tp_new(IntPtr tp, IntPtr args, IntPtr kw)
{
var cls = GetManagedObject(tp) as ClassDerivedObject;
// call the managed constructor
object obj = cls.binder.InvokeRaw(IntPtr.Zero, args, kw);
if (obj == null)
{
return IntPtr.Zero;
}
// return the pointer to the python object
// (this indirectly calls ClassDerivedObject.ToPython)
return Converter.ToPython(obj, cls.GetType());
}
public new static void tp_dealloc(IntPtr ob)
{
var self = (CLRObject)GetManagedObject(ob);
// don't let the python GC destroy this object
Runtime.PyObject_GC_UnTrack(self.pyHandle);
// The python should now have a ref count of 0, but we don't actually want to
// deallocate the object until the C# object that references it is destroyed.
// So we don't call PyObject_GC_Del here and instead we set the python
// reference to a weak reference so that the C# object can be collected.
GCHandle gc = GCHandle.Alloc(self, GCHandleType.Weak);
Marshal.WriteIntPtr(self.pyHandle, ObjectOffset.magic(self.tpHandle), (IntPtr)gc);
self.gcHandle.Free();
self.gcHandle = gc;
}
/// <summary>
/// Called from Converter.ToPython for types that are python subclasses of managed types.
/// The referenced python object is returned instead of a new wrapper.
/// </summary>
internal static IntPtr ToPython(IPythonDerivedType obj)
{
// derived types have a __pyobj__ field that gets set to the python
// object in the overridden constructor
FieldInfo fi = obj.GetType().GetField("__pyobj__");
var self = (CLRObject)fi.GetValue(obj);
Runtime.XIncref(self.pyHandle);
// when the C# constructor creates the python object it starts as a weak
// reference with a reference count of 0. Now we're passing this object
// to Python the reference count needs to be incremented and the reference
// needs to be replaced with a strong reference to stop the C# object being
// collected while Python still has a reference to it.
if (Runtime.Refcount(self.pyHandle) == 1)
{
#if PYTHON_WITH_PYDEBUG
Runtime._Py_NewReference(self.pyHandle);
#endif
GCHandle gc = GCHandle.Alloc(self, GCHandleType.Normal);
Marshal.WriteIntPtr(self.pyHandle, ObjectOffset.magic(self.tpHandle), (IntPtr)gc);
self.gcHandle.Free();
self.gcHandle = gc;
// now the object has a python reference it's safe for the python GC to track it
Runtime.PyObject_GC_Track(self.pyHandle);
}
return self.pyHandle;
}
/// <summary>
/// Creates a new managed type derived from a base type with any virtual
/// methods overridden to call out to python if the associated python
/// object has overridden the method.
/// </summary>
internal static Type CreateDerivedType(string name,
Type baseType,
IntPtr py_dict,
string namespaceStr,
string assemblyName,
string moduleName = "Python.Runtime.Dynamic.dll")
{
if (null != namespaceStr)
{
name = namespaceStr + "." + name;
}
if (null == assemblyName)
{
assemblyName = "Python.Runtime.Dynamic";
}
ModuleBuilder moduleBuilder = GetModuleBuilder(assemblyName, moduleName);
Type baseClass = baseType;
var interfaces = new List<Type> { typeof(IPythonDerivedType) };
// if the base type is an interface then use System.Object as the base class
// and add the base type to the list of interfaces this new class will implement.
if (baseType.IsInterface)
{
interfaces.Add(baseType);
baseClass = typeof(object);
}
TypeBuilder typeBuilder = moduleBuilder.DefineType(name,
TypeAttributes.Public | TypeAttributes.Class,
baseClass,
interfaces.ToArray());
// add a field for storing the python object pointer
// FIXME: fb not used
FieldBuilder fb = typeBuilder.DefineField("__pyobj__", typeof(CLRObject), FieldAttributes.Public);
// override any constructors
ConstructorInfo[] constructors = baseClass.GetConstructors();
foreach (ConstructorInfo ctor in constructors)
{
AddConstructor(ctor, baseType, typeBuilder);
}
// Override any properties explicitly overridden in python
var pyProperties = new HashSet<string>();
if (py_dict != IntPtr.Zero && Runtime.PyDict_Check(py_dict))
{
Runtime.XIncref(py_dict);
using (var dict = new PyDict(py_dict))
using (PyObject keys = dict.Keys())
{
foreach (PyObject pyKey in keys)
{
using (PyObject value = dict[pyKey])
{
if (value.HasAttr("_clr_property_type_"))
{
string propertyName = pyKey.ToString();
pyProperties.Add(propertyName);
// Add the property to the type
AddPythonProperty(propertyName, value, typeBuilder);
}
}
}
}
}
// override any virtual methods not already overridden by the properties above
MethodInfo[] methods = baseType.GetMethods();
var virtualMethods = new HashSet<string>();
foreach (MethodInfo method in methods)
{
if (!method.Attributes.HasFlag(MethodAttributes.Virtual) |
method.Attributes.HasFlag(MethodAttributes.Final))
{
continue;
}
// skip if this property has already been overridden
if ((method.Name.StartsWith("get_") || method.Name.StartsWith("set_"))
&& pyProperties.Contains(method.Name.Substring(4)))
{
continue;
}
// keep track of the virtual methods redirected to the python instance
virtualMethods.Add(method.Name);
// override the virtual method to call out to the python method, if there is one.
AddVirtualMethod(method, baseType, typeBuilder);
}
// Add any additional methods and properties explicitly exposed from Python.
if (py_dict != IntPtr.Zero && Runtime.PyDict_Check(py_dict))
{
Runtime.XIncref(py_dict);
using (var dict = new PyDict(py_dict))
using (PyObject keys = dict.Keys())
{
foreach (PyObject pyKey in keys)
{
using (PyObject value = dict[pyKey])
{
if (value.HasAttr("_clr_return_type_") && value.HasAttr("_clr_arg_types_"))
{
string methodName = pyKey.ToString();
// if this method has already been redirected to the python method skip it
if (virtualMethods.Contains(methodName))
{
continue;
}
// Add the method to the type
AddPythonMethod(methodName, value, typeBuilder);
}
}
}
}
}
// add the destructor so the python object created in the constructor gets destroyed
MethodBuilder methodBuilder = typeBuilder.DefineMethod("Finalize",
MethodAttributes.Family |
MethodAttributes.Virtual |
MethodAttributes.HideBySig,
CallingConventions.Standard,
typeof(void),
Type.EmptyTypes);
ILGenerator il = methodBuilder.GetILGenerator();
il.Emit(OpCodes.Ldarg_0);
il.Emit(OpCodes.Call, typeof(PythonDerivedType).GetMethod("Finalize"));
il.Emit(OpCodes.Ldarg_0);
il.Emit(OpCodes.Call, baseClass.GetMethod("Finalize", BindingFlags.NonPublic | BindingFlags.Instance));
il.Emit(OpCodes.Ret);
Type type = typeBuilder.CreateType();
// scan the assembly so the newly added class can be imported
Assembly assembly = Assembly.GetAssembly(type);
AssemblyManager.ScanAssembly(assembly);
// FIXME: assemblyBuilder not used
AssemblyBuilder assemblyBuilder = assemblyBuilders[assemblyName];
return type;
}
/// <summary>
/// Add a constructor override that calls the python ctor after calling the base type constructor.
/// </summary>
/// <param name="ctor">constructor to be called before calling the python ctor</param>
/// <param name="baseType">Python callable object</param>
/// <param name="typeBuilder">TypeBuilder for the new type the ctor is to be added to</param>
private static void AddConstructor(ConstructorInfo ctor, Type baseType, TypeBuilder typeBuilder)
{
ParameterInfo[] parameters = ctor.GetParameters();
Type[] parameterTypes = (from param in parameters select param.ParameterType).ToArray();
// create a method for calling the original constructor
string baseCtorName = "_" + baseType.Name + "__cinit__";
MethodBuilder methodBuilder = typeBuilder.DefineMethod(baseCtorName,
MethodAttributes.Public |
MethodAttributes.Final |
MethodAttributes.HideBySig,
typeof(void),
parameterTypes);
// emit the assembly for calling the original method using call instead of callvirt
ILGenerator il = methodBuilder.GetILGenerator();
il.Emit(OpCodes.Ldarg_0);
for (var i = 0; i < parameters.Length; ++i)
{
il.Emit(OpCodes.Ldarg, i + 1);
}
il.Emit(OpCodes.Call, ctor);
il.Emit(OpCodes.Ret);
// override the original method with a new one that dispatches to python
ConstructorBuilder cb = typeBuilder.DefineConstructor(MethodAttributes.Public |
MethodAttributes.ReuseSlot |
MethodAttributes.HideBySig,
ctor.CallingConvention,
parameterTypes);
il = cb.GetILGenerator();
il.DeclareLocal(typeof(object[]));
il.Emit(OpCodes.Ldarg_0);
il.Emit(OpCodes.Ldstr, baseCtorName);
il.Emit(OpCodes.Ldc_I4, parameters.Length);
il.Emit(OpCodes.Newarr, typeof(object));
il.Emit(OpCodes.Stloc_0);
for (var i = 0; i < parameters.Length; ++i)
{
il.Emit(OpCodes.Ldloc_0);
il.Emit(OpCodes.Ldc_I4, i);
il.Emit(OpCodes.Ldarg, i + 1);
if (parameterTypes[i].IsValueType)
{
il.Emit(OpCodes.Box, parameterTypes[i]);
}
il.Emit(OpCodes.Stelem, typeof(object));
}
il.Emit(OpCodes.Ldloc_0);
il.Emit(OpCodes.Call, typeof(PythonDerivedType).GetMethod("InvokeCtor"));
il.Emit(OpCodes.Ret);
}
/// <summary>
/// Add a virtual method override that checks for an override on the python instance
/// and calls it, otherwise fall back to the base class method.
/// </summary>
/// <param name="method">virtual method to be overridden</param>
/// <param name="baseType">Python callable object</param>
/// <param name="typeBuilder">TypeBuilder for the new type the method is to be added to</param>
private static void AddVirtualMethod(MethodInfo method, Type baseType, TypeBuilder typeBuilder)
{
ParameterInfo[] parameters = method.GetParameters();
Type[] parameterTypes = (from param in parameters select param.ParameterType).ToArray();
// If the method isn't abstract create a method for calling the original method
string baseMethodName = null;
if (!method.IsAbstract)
{
baseMethodName = "_" + baseType.Name + "__" + method.Name;
MethodBuilder baseMethodBuilder = typeBuilder.DefineMethod(baseMethodName,
MethodAttributes.Public |
MethodAttributes.Final |
MethodAttributes.HideBySig,
method.ReturnType,
parameterTypes);
// emit the assembly for calling the original method using call instead of callvirt
ILGenerator baseIl = baseMethodBuilder.GetILGenerator();
baseIl.Emit(OpCodes.Ldarg_0);
for (var i = 0; i < parameters.Length; ++i)
{
baseIl.Emit(OpCodes.Ldarg, i + 1);
}
baseIl.Emit(OpCodes.Call, method);
baseIl.Emit(OpCodes.Ret);
}
// override the original method with a new one that dispatches to python
MethodBuilder methodBuilder = typeBuilder.DefineMethod(method.Name,
MethodAttributes.Public |
MethodAttributes.ReuseSlot |
MethodAttributes.Virtual |
MethodAttributes.HideBySig,
method.CallingConvention,
method.ReturnType,
parameterTypes);
ILGenerator il = methodBuilder.GetILGenerator();
il.DeclareLocal(typeof(object[]));
il.Emit(OpCodes.Ldarg_0);
il.Emit(OpCodes.Ldstr, method.Name);
// don't fall back to the base type's method if it's abstract
if (null != baseMethodName)
{
il.Emit(OpCodes.Ldstr, baseMethodName);
}
else
{
il.Emit(OpCodes.Ldnull);
}
il.Emit(OpCodes.Ldc_I4, parameters.Length);
il.Emit(OpCodes.Newarr, typeof(object));
il.Emit(OpCodes.Stloc_0);
for (var i = 0; i < parameters.Length; ++i)
{
il.Emit(OpCodes.Ldloc_0);
il.Emit(OpCodes.Ldc_I4, i);
il.Emit(OpCodes.Ldarg, i + 1);
if (parameterTypes[i].IsValueType)
{
il.Emit(OpCodes.Box, parameterTypes[i]);
}
il.Emit(OpCodes.Stelem, typeof(object));
}
il.Emit(OpCodes.Ldloc_0);
if (method.ReturnType == typeof(void))
{
il.Emit(OpCodes.Call, typeof(PythonDerivedType).GetMethod("InvokeMethodVoid"));
}
else
{
il.Emit(OpCodes.Call,
typeof(PythonDerivedType).GetMethod("InvokeMethod").MakeGenericMethod(method.ReturnType));
}
il.Emit(OpCodes.Ret);
}
/// <summary>
/// Python method may have the following function attributes set to control how they're exposed:
/// - _clr_return_type_ - method return type (required)
/// - _clr_arg_types_ - list of method argument types (required)
/// - _clr_method_name_ - method name, if different from the python method name (optional)
/// </summary>
/// <param name="methodName">Method name to add to the type</param>
/// <param name="func">Python callable object</param>
/// <param name="typeBuilder">TypeBuilder for the new type the method/property is to be added to</param>
private static void AddPythonMethod(string methodName, PyObject func, TypeBuilder typeBuilder)
{
if (func.HasAttr("_clr_method_name_"))
{
using (PyObject pyMethodName = func.GetAttr("_clr_method_name_"))
{
methodName = pyMethodName.ToString();
}
}
using (PyObject pyReturnType = func.GetAttr("_clr_return_type_"))
using (PyObject pyArgTypes = func.GetAttr("_clr_arg_types_"))
{
var returnType = pyReturnType.AsManagedObject(typeof(Type)) as Type;
if (returnType == null)
{
returnType = typeof(void);
}
if (!pyArgTypes.IsIterable())
{
throw new ArgumentException("_clr_arg_types_ must be a list or tuple of CLR types");
}
var argTypes = new List<Type>();
foreach (PyObject pyArgType in pyArgTypes)
{
var argType = pyArgType.AsManagedObject(typeof(Type)) as Type;
if (argType == null)
{
throw new ArgumentException("_clr_arg_types_ must be a list or tuple of CLR types");
}
argTypes.Add(argType);
}
// add the method to call back into python
MethodAttributes methodAttribs = MethodAttributes.Public |
MethodAttributes.Virtual |
MethodAttributes.ReuseSlot |
MethodAttributes.HideBySig;
MethodBuilder methodBuilder = typeBuilder.DefineMethod(methodName,
methodAttribs,
returnType,
argTypes.ToArray());
ILGenerator il = methodBuilder.GetILGenerator();
il.DeclareLocal(typeof(object[]));
il.Emit(OpCodes.Ldarg_0);
il.Emit(OpCodes.Ldstr, methodName);
il.Emit(OpCodes.Ldnull); // don't fall back to the base type's method
il.Emit(OpCodes.Ldc_I4, argTypes.Count);
il.Emit(OpCodes.Newarr, typeof(object));
il.Emit(OpCodes.Stloc_0);
for (var i = 0; i < argTypes.Count; ++i)
{
il.Emit(OpCodes.Ldloc_0);
il.Emit(OpCodes.Ldc_I4, i);
il.Emit(OpCodes.Ldarg, i + 1);
if (argTypes[i].IsValueType)
{
il.Emit(OpCodes.Box, argTypes[i]);
}
il.Emit(OpCodes.Stelem, typeof(object));
}
il.Emit(OpCodes.Ldloc_0);
if (returnType == typeof(void))
{
il.Emit(OpCodes.Call, typeof(PythonDerivedType).GetMethod("InvokeMethodVoid"));
}
else
{
il.Emit(OpCodes.Call,
typeof(PythonDerivedType).GetMethod("InvokeMethod").MakeGenericMethod(returnType));
}
il.Emit(OpCodes.Ret);
}
}
/// <summary>
/// Python properties may have the following function attributes set to control how they're exposed:
/// - _clr_property_type_ - property type (required)
/// </summary>
/// <param name="propertyName">Property name to add to the type</param>
/// <param name="func">Python property object</param>
/// <param name="typeBuilder">TypeBuilder for the new type the method/property is to be added to</param>
private static void AddPythonProperty(string propertyName, PyObject func, TypeBuilder typeBuilder)
{
// add the method to call back into python
MethodAttributes methodAttribs = MethodAttributes.Public |
MethodAttributes.Virtual |
MethodAttributes.ReuseSlot |
MethodAttributes.HideBySig |
MethodAttributes.SpecialName;
using (PyObject pyPropertyType = func.GetAttr("_clr_property_type_"))
{
var propertyType = pyPropertyType.AsManagedObject(typeof(Type)) as Type;
if (propertyType == null)
{
throw new ArgumentException("_clr_property_type must be a CLR type");
}
PropertyBuilder propertyBuilder = typeBuilder.DefineProperty(propertyName,
PropertyAttributes.None,
propertyType,
null);
if (func.HasAttr("fget"))
{
using (PyObject pyfget = func.GetAttr("fget"))
{
if (pyfget.IsTrue())
{
MethodBuilder methodBuilder = typeBuilder.DefineMethod("get_" + propertyName,
methodAttribs,
propertyType,
null);
ILGenerator il = methodBuilder.GetILGenerator();
il.Emit(OpCodes.Ldarg_0);
il.Emit(OpCodes.Ldstr, propertyName);
il.Emit(OpCodes.Call,
typeof(PythonDerivedType).GetMethod("InvokeGetProperty").MakeGenericMethod(propertyType));
il.Emit(OpCodes.Ret);
propertyBuilder.SetGetMethod(methodBuilder);
}
}
}
if (func.HasAttr("fset"))
{
using (PyObject pyset = func.GetAttr("fset"))
{
if (pyset.IsTrue())
{
MethodBuilder methodBuilder = typeBuilder.DefineMethod("set_" + propertyName,
methodAttribs,
null,
new[] { propertyType });
ILGenerator il = methodBuilder.GetILGenerator();
il.Emit(OpCodes.Ldarg_0);
il.Emit(OpCodes.Ldstr, propertyName);
il.Emit(OpCodes.Ldarg_1);
il.Emit(OpCodes.Call,
typeof(PythonDerivedType).GetMethod("InvokeSetProperty").MakeGenericMethod(propertyType));
il.Emit(OpCodes.Ret);
propertyBuilder.SetSetMethod(methodBuilder);
}
}
}
}
}
private static ModuleBuilder GetModuleBuilder(string assemblyName, string moduleName)
{
// find or create a dynamic assembly and module
AppDomain domain = AppDomain.CurrentDomain;
ModuleBuilder moduleBuilder;
if (moduleBuilders.ContainsKey(Tuple.Create(assemblyName, moduleName)))
{
moduleBuilder = moduleBuilders[Tuple.Create(assemblyName, moduleName)];
}
else
{
AssemblyBuilder assemblyBuilder;
if (assemblyBuilders.ContainsKey(assemblyName))
{
assemblyBuilder = assemblyBuilders[assemblyName];
}
else
{
assemblyBuilder = domain.DefineDynamicAssembly(new AssemblyName(assemblyName),
AssemblyBuilderAccess.Run);
assemblyBuilders[assemblyName] = assemblyBuilder;
}
moduleBuilder = assemblyBuilder.DefineDynamicModule(moduleName);
moduleBuilders[Tuple.Create(assemblyName, moduleName)] = moduleBuilder;
}
return moduleBuilder;
}
}
/// <summary>
/// PythonDerivedType contains static methods used by the dynamically created
/// derived type that allow it to call back into python from overridden virtual
/// methods, and also handle the construction and destruction of the python
/// object.
/// </summary>
/// <remarks>
/// This has to be public as it's called from methods on dynamically built classes
/// potentially in other assemblies.
/// </remarks>
public class PythonDerivedType
{
/// <summary>
/// This is the implementation of the overridden methods in the derived
/// type. It looks for a python method with the same name as the method
/// on the managed base class and if it exists and isn't the managed
/// method binding (i.e. it has been overridden in the derived python
/// class) it calls it, otherwise it calls the base method.
/// </summary>
public static T InvokeMethod<T>(IPythonDerivedType obj, string methodName, string origMethodName, object[] args)
{
FieldInfo fi = obj.GetType().GetField("__pyobj__");
var self = (CLRObject)fi.GetValue(obj);
if (null != self)
{
var disposeList = new List<PyObject>();
IntPtr gs = Runtime.PyGILState_Ensure();
try
{
Runtime.XIncref(self.pyHandle);
var pyself = new PyObject(self.pyHandle);
disposeList.Add(pyself);
Runtime.XIncref(Runtime.PyNone);
var pynone = new PyObject(Runtime.PyNone);
disposeList.Add(pynone);
PyObject method = pyself.GetAttr(methodName, pynone);
disposeList.Add(method);
if (method.Handle != Runtime.PyNone)
{
// if the method hasn't been overridden then it will be a managed object
ManagedType managedMethod = ManagedType.GetManagedObject(method.Handle);
if (null == managedMethod)
{
var pyargs = new PyObject[args.Length];
for (var i = 0; i < args.Length; ++i)
{
pyargs[i] = new PyObject(Converter.ToPythonImplicit(args[i]));
disposeList.Add(pyargs[i]);
}
PyObject py_result = method.Invoke(pyargs);
disposeList.Add(py_result);
return (T)py_result.AsManagedObject(typeof(T));
}
}
}
finally
{
foreach (PyObject x in disposeList)
{
x?.Dispose();
}
Runtime.PyGILState_Release(gs);
}
}
if (origMethodName == null)
{
throw new NotImplementedException("Python object does not have a '" + methodName + "' method");
}
return (T)obj.GetType().InvokeMember(origMethodName,
BindingFlags.InvokeMethod,
null,
obj,
args);
}
public static void InvokeMethodVoid(IPythonDerivedType obj, string methodName, string origMethodName,
object[] args)
{
FieldInfo fi = obj.GetType().GetField("__pyobj__");
var self = (CLRObject)fi.GetValue(obj);
if (null != self)
{
var disposeList = new List<PyObject>();
IntPtr gs = Runtime.PyGILState_Ensure();
try
{
Runtime.XIncref(self.pyHandle);
var pyself = new PyObject(self.pyHandle);
disposeList.Add(pyself);
Runtime.XIncref(Runtime.PyNone);
var pynone = new PyObject(Runtime.PyNone);
disposeList.Add(pynone);
PyObject method = pyself.GetAttr(methodName, pynone);
disposeList.Add(method);
if (method.Handle != Runtime.PyNone)
{
// if the method hasn't been overridden then it will be a managed object
ManagedType managedMethod = ManagedType.GetManagedObject(method.Handle);
if (null == managedMethod)
{
var pyargs = new PyObject[args.Length];
for (var i = 0; i < args.Length; ++i)
{
pyargs[i] = new PyObject(Converter.ToPythonImplicit(args[i]));
disposeList.Add(pyargs[i]);
}
PyObject py_result = method.Invoke(pyargs);
disposeList.Add(py_result);
return;
}
}
}
finally
{
foreach (PyObject x in disposeList)
{
x?.Dispose();
}
Runtime.PyGILState_Release(gs);
}
}
if (origMethodName == null)
{
throw new NotImplementedException($"Python object does not have a '{methodName}' method");
}
obj.GetType().InvokeMember(origMethodName,
BindingFlags.InvokeMethod,
null,
obj,
args);
}
public static T InvokeGetProperty<T>(IPythonDerivedType obj, string propertyName)
{
FieldInfo fi = obj.GetType().GetField("__pyobj__");
var self = (CLRObject)fi.GetValue(obj);
if (null == self)
{
throw new NullReferenceException("Instance must be specified when getting a property");
}
IntPtr gs = Runtime.PyGILState_Ensure();
try
{
Runtime.XIncref(self.pyHandle);
using (var pyself = new PyObject(self.pyHandle))
using (PyObject pyvalue = pyself.GetAttr(propertyName))
{
return (T)pyvalue.AsManagedObject(typeof(T));
}
}
finally
{
Runtime.PyGILState_Release(gs);
}
}
public static void InvokeSetProperty<T>(IPythonDerivedType obj, string propertyName, T value)
{
FieldInfo fi = obj.GetType().GetField("__pyobj__");
var self = (CLRObject)fi.GetValue(obj);
if (null == self)
{
throw new NullReferenceException("Instance must be specified when setting a property");
}
IntPtr gs = Runtime.PyGILState_Ensure();
try
{
Runtime.XIncref(self.pyHandle);
using (var pyself = new PyObject(self.pyHandle))
using (var pyvalue = new PyObject(Converter.ToPythonImplicit(value)))
{
pyself.SetAttr(propertyName, pyvalue);
}
}
finally
{
Runtime.PyGILState_Release(gs);
}
}
public static void InvokeCtor(IPythonDerivedType obj, string origCtorName, object[] args)
{
// call the base constructor
obj.GetType().InvokeMember(origCtorName,
BindingFlags.InvokeMethod,
null,
obj,
args);
CLRObject self = null;
IntPtr gs = Runtime.PyGILState_Ensure();
try
{
// create the python object
IntPtr type = TypeManager.GetTypeHandle(obj.GetType());
self = new CLRObject(obj, type);
// set __pyobj__ to self and deref the python object which will allow this
// object to be collected.
FieldInfo fi = obj.GetType().GetField("__pyobj__");
fi.SetValue(obj, self);
}
finally
{
// Decrement the python object's reference count.
// This doesn't actually destroy the object, it just sets the reference to this object
// to be a weak reference and it will be destroyed when the C# object is destroyed.
if (null != self)
{
Runtime.XDecref(self.pyHandle);
}
Runtime.PyGILState_Release(gs);
}
}
public static void Finalize(IPythonDerivedType obj)
{
FieldInfo fi = obj.GetType().GetField("__pyobj__");
var self = (CLRObject)fi.GetValue(obj);
// If python's been terminated then just free the gchandle.
lock (Runtime.IsFinalizingLock)
{
if (0 == Runtime.Py_IsInitialized() || Runtime.IsFinalizing)
{
self.gcHandle.Free();
return;
}
}
// delete the python object in an async task as we may not be able to acquire
// the GIL immediately and we don't want to block the GC thread.
// FIXME: t isn't used
Task t = Task.Factory.StartNew(() =>
{
lock (Runtime.IsFinalizingLock)
{
// If python's been terminated then just free the gchandle.
if (0 == Runtime.Py_IsInitialized() || Runtime.IsFinalizing)
{
self.gcHandle.Free();
return;
}
IntPtr gs = Runtime.PyGILState_Ensure();
try
{
// the C# object is being destroyed which must mean there are no more
// references to the Python object as well so now we can dealloc the
// python object.
IntPtr dict = Marshal.ReadIntPtr(self.pyHandle, ObjectOffset.TypeDictOffset(self.tpHandle));
if (dict != IntPtr.Zero)
{
Runtime.XDecref(dict);
}
Runtime.PyObject_GC_Del(self.pyHandle);
self.gcHandle.Free();
}
finally
{
Runtime.PyGILState_Release(gs);
}
}
});
}
}
}