|
static private ToManagedValue ( |
||
| value | ||
| obType | ||
| result | Object | |
| setError | bool | |
| return | bool | |
private static ExceptionDispatchInfo?TryGetDispatchInfo(BorrowedReference exception)
{
if (exception.IsNull)
{
return(null);
}
var pyInfo = Runtime.PyObject_GetAttrString(exception, Exceptions.DispatchInfoAttribute);
if (pyInfo.IsNull())
{
if (Exceptions.ExceptionMatches(Exceptions.AttributeError))
{
Exceptions.Clear();
}
return(null);
}
try
{
if (Converter.ToManagedValue(pyInfo, typeof(ExceptionDispatchInfo), out object result, setError: false))
{
return((ExceptionDispatchInfo)result);
}
return(null);
}
finally
{
pyInfo.Dispose();
}
}
/// <summary>
/// Return a managed object for the given Python object, taking funny
/// byref types into account.
/// </summary>
internal static bool ToManaged(IntPtr value, Type type,
out object result, bool setError)
{
if (type.IsByRef)
{
type = type.GetElementType();
}
return(Converter.ToManagedValue(value, type, out result, setError));
}
internal static IntPtr CreateSubType(IntPtr py_name, IntPtr py_base_type, IntPtr py_dict)
{
// Utility to create a subtype of a managed type with the ability for the
// a python subtype able to override the managed implementation
string name = Runtime.GetManagedString(py_name);
// the derived class can have class attributes __assembly__ and __module__ which
// control the name of the assembly and module the new type is created in.
object assembly = null;
object namespaceStr = null;
var disposeList = new List <PyObject>();
try
{
var assemblyKey = new PyObject(Converter.ToPython("__assembly__", typeof(string)));
disposeList.Add(assemblyKey);
if (0 != Runtime.PyMapping_HasKey(py_dict, assemblyKey.Handle))
{
var pyAssembly = new PyObject(Runtime.PyDict_GetItem(py_dict, assemblyKey.Handle));
Runtime.XIncref(pyAssembly.Handle);
disposeList.Add(pyAssembly);
if (!Converter.ToManagedValue(pyAssembly.Handle, typeof(string), out assembly, false))
{
throw new InvalidCastException("Couldn't convert __assembly__ value to string");
}
}
var namespaceKey = new PyObject(Converter.ToPythonImplicit("__namespace__"));
disposeList.Add(namespaceKey);
if (0 != Runtime.PyMapping_HasKey(py_dict, namespaceKey.Handle))
{
var pyNamespace = new PyObject(Runtime.PyDict_GetItem(py_dict, namespaceKey.Handle));
Runtime.XIncref(pyNamespace.Handle);
disposeList.Add(pyNamespace);
if (!Converter.ToManagedValue(pyNamespace.Handle, typeof(string), out namespaceStr, false))
{
throw new InvalidCastException("Couldn't convert __namespace__ value to string");
}
}
}
finally
{
foreach (PyObject o in disposeList)
{
o.Dispose();
}
}
// create the new managed type subclassing the base managed type
var baseClass = ManagedType.GetManagedObject(py_base_type) as ClassBase;
if (null == baseClass)
{
return(Exceptions.RaiseTypeError("invalid base class, expected CLR class type"));
}
try
{
Type subType = ClassDerivedObject.CreateDerivedType(name,
baseClass.type,
py_dict,
(string)namespaceStr,
(string)assembly);
// create the new ManagedType and python type
ClassBase subClass = ClassManager.GetClass(subType);
IntPtr py_type = GetTypeHandle(subClass, subType);
// by default the class dict will have all the C# methods in it, but as this is a
// derived class we want the python overrides in there instead if they exist.
IntPtr cls_dict = Marshal.ReadIntPtr(py_type, TypeOffset.tp_dict);
Runtime.PyDict_Update(cls_dict, py_dict);
return(py_type);
}
catch (Exception e)
{
return(Exceptions.RaiseTypeError(e.Message));
}
}
internal static IntPtr CreateSubType(IntPtr py_name, IntPtr py_base_type, IntPtr py_dict)
{
var dictRef = new BorrowedReference(py_dict);
// Utility to create a subtype of a managed type with the ability for the
// a python subtype able to override the managed implementation
string name = Runtime.GetManagedString(py_name);
// the derived class can have class attributes __assembly__ and __module__ which
// control the name of the assembly and module the new type is created in.
object assembly = null;
object namespaceStr = null;
using (var assemblyKey = new PyString("__assembly__"))
{
var assemblyPtr = Runtime.PyDict_GetItemWithError(dictRef, assemblyKey.Reference);
if (assemblyPtr.IsNull)
{
if (Exceptions.ErrorOccurred())
{
return(IntPtr.Zero);
}
}
else if (!Converter.ToManagedValue(assemblyPtr, typeof(string), out assembly, true))
{
return(Exceptions.RaiseTypeError("Couldn't convert __assembly__ value to string"));
}
using (var namespaceKey = new PyString("__namespace__"))
{
var pyNamespace = Runtime.PyDict_GetItemWithError(dictRef, namespaceKey.Reference);
if (pyNamespace.IsNull)
{
if (Exceptions.ErrorOccurred())
{
return(IntPtr.Zero);
}
}
else if (!Converter.ToManagedValue(pyNamespace, typeof(string), out namespaceStr, true))
{
return(Exceptions.RaiseTypeError("Couldn't convert __namespace__ value to string"));
}
}
}
// create the new managed type subclassing the base managed type
var baseClass = ManagedType.GetManagedObject(py_base_type) as ClassBase;
if (null == baseClass)
{
return(Exceptions.RaiseTypeError("invalid base class, expected CLR class type"));
}
try
{
Type subType = ClassDerivedObject.CreateDerivedType(name,
baseClass.type.Value,
py_dict,
(string)namespaceStr,
(string)assembly);
// create the new ManagedType and python type
ClassBase subClass = ClassManager.GetClass(subType);
IntPtr py_type = GetTypeHandle(subClass, subType);
// by default the class dict will have all the C# methods in it, but as this is a
// derived class we want the python overrides in there instead if they exist.
var cls_dict = new BorrowedReference(Marshal.ReadIntPtr(py_type, TypeOffset.tp_dict));
ThrowIfIsNotZero(Runtime.PyDict_Update(cls_dict, new BorrowedReference(py_dict)));
Runtime.XIncref(py_type);
// Update the __classcell__ if it exists
BorrowedReference cell = Runtime.PyDict_GetItemString(cls_dict, "__classcell__");
if (!cell.IsNull)
{
ThrowIfIsNotZero(Runtime.PyCell_Set(cell, py_type));
ThrowIfIsNotZero(Runtime.PyDict_DelItemString(cls_dict, "__classcell__"));
}
return(py_type);
}
catch (Exception e)
{
return(Exceptions.RaiseTypeError(e.Message));
}
}