//====================================================================
// Implement explicit overload selection using subscript syntax ([]).
//====================================================================
public static IntPtr mp_subscript(IntPtr tp, IntPtr idx)
{
OverloadMapper self = (OverloadMapper)GetManagedObject(tp);
// Note: if the type provides a non-generic method with N args
// and a generic method that takes N params, then we always
// prefer the non-generic version in doing overload selection.
Type[] types = Runtime.PythonArgsToTypeArray(idx);
if (types == null)
{
return Exceptions.RaiseTypeError("type(s) expected");
}
MethodInfo mi = MethodBinder.MatchSignature(self.m.info, types);
if (mi == null)
{
string e = "No match found for signature";
return Exceptions.RaiseTypeError(e);
}
MethodBinding mb = new MethodBinding(self.m, self.target);
mb.info = mi;
Runtime.Incref(mb.pyHandle);
return mb.pyHandle;
}
public static IntPtr mp_subscript(IntPtr tp, IntPtr idx) {
MethodBinding self = (MethodBinding)GetManagedObject(tp);
MethodInfo sig = MethodBinder.MatchByTypeSig(self.m.info, idx);
if (sig == null) {
return Exceptions.RaiseTypeError(
"No match found for signature"
);
}
MethodBinding mb = new MethodBinding(self.m, self.target);
mb.info = sig;
Runtime.Incref(mb.pyHandle);
return mb.pyHandle;
}
//====================================================================
// Implement binding of generic methods using the subscript syntax [].
//====================================================================
public static IntPtr mp_subscript(IntPtr tp, IntPtr idx) {
MethodBinding self = (MethodBinding)GetManagedObject(tp);
Type[] types = Runtime.PythonArgsToTypeArray(idx);
if (types == null) {
return Exceptions.RaiseTypeError("type(s) expected");
}
MethodInfo mi = MethodBinder.MatchParameters(self.m.info, types);
if (mi == null) {
string e = "No match found for given type params";
return Exceptions.RaiseTypeError(e);
}
MethodBinding mb = new MethodBinding(self.m, self.target);
mb.info = mi;
Runtime.Incref(mb.pyHandle);
return mb.pyHandle;
}
/// <summary>
/// Implement binding of generic methods using the subscript syntax [].
/// </summary>
public static IntPtr mp_subscript(IntPtr tp, IntPtr idx)
{
var self = (MethodBinding)GetManagedObject(tp);
Type[] types = Runtime.PythonArgsToTypeArray(idx);
if (types == null)
{
return(Exceptions.RaiseTypeError("type(s) expected"));
}
MethodInfo mi = MethodBinder.MatchParameters(self.m.info, types);
if (mi == null)
{
return(Exceptions.RaiseTypeError("No match found for given type params"));
}
var mb = new MethodBinding(self.m, self.target)
{
info = mi
};
return(mb.pyHandle);
}
//====================================================================
// Descriptor __get__ implementation. Accessing a CLR method returns
// a "bound" method similar to a Python bound method.
//====================================================================
public static IntPtr tp_descr_get(IntPtr ds, IntPtr ob, IntPtr tp) {
MethodObject self = (MethodObject)GetManagedObject(ds);
MethodBinding binding;
// If the method is accessed through its type (rather than via
// an instance) we return an 'unbound' MethodBinding that will
// cached for future accesses through the type.
if (ob == IntPtr.Zero) {
if (self.unbound == null) {
self.unbound = new MethodBinding(self, IntPtr.Zero);
}
binding = self.unbound;
Runtime.Incref(binding.pyHandle);;
return binding.pyHandle;
}
if (Runtime.PyObject_IsInstance(ob, tp) < 1) {
return Exceptions.RaiseTypeError("invalid argument");
}
binding = new MethodBinding(self, ob);
return binding.pyHandle;
}
//====================================================================
// Descriptor __get__ implementation. Accessing a CLR method returns
// a "bound" method similar to a Python bound method.
//====================================================================
public static IntPtr tp_descr_get(IntPtr ds, IntPtr ob, IntPtr tp)
{
MethodObject self = (MethodObject)GetManagedObject(ds);
MethodBinding binding;
// If the method is accessed through its type (rather than via
// an instance) we return an 'unbound' MethodBinding that will
// cached for future accesses through the type.
if (ob == IntPtr.Zero)
{
if (self.unbound == null)
{
self.unbound = new MethodBinding(self, IntPtr.Zero, tp);
}
binding = self.unbound;
Runtime.XIncref(binding.pyHandle);
;
return binding.pyHandle;
}
if (Runtime.PyObject_IsInstance(ob, tp) < 1)
{
return Exceptions.RaiseTypeError("invalid argument");
}
// If the object this descriptor is being called with is a subclass of the type
// this descriptor was defined on then it will be because the base class method
// is being called via super(Derived, self).method(...).
// In which case create a MethodBinding bound to the base class.
CLRObject obj = GetManagedObject(ob) as CLRObject;
if (obj != null
&& obj.inst.GetType() != self.type
&& obj.inst is IPythonDerivedType
&& self.type.IsAssignableFrom(obj.inst.GetType()))
{
ClassBase basecls = ClassManager.GetClass(self.type);
binding = new MethodBinding(self, ob, basecls.pyHandle);
return binding.pyHandle;
}
binding = new MethodBinding(self, ob, tp);
return binding.pyHandle;
}
//====================================================================
// MethodBinding __call__ implementation.
//====================================================================
public static IntPtr tp_call(IntPtr ob, IntPtr args, IntPtr kw)
{
MethodBinding self = (MethodBinding)GetManagedObject(ob);
// This works around a situation where the wrong generic method is picked,
// for example this method in the tests: string Overloaded<T>(int arg1, int arg2, string arg3)
if (self.info != null)
{
if (self.info.IsGenericMethod)
{
int len = Runtime.PyTuple_Size(args);
Type[] sigTp = Runtime.PythonArgsToTypeArray(args, true);
if (sigTp != null)
{
Type[] genericTp = self.info.GetGenericArguments();
MethodInfo betterMatch = MethodBinder.MatchSignatureAndParameters(self.m.info, genericTp, sigTp);
if (betterMatch != null)
{
self.info = betterMatch;
}
}
}
}
// This supports calling a method 'unbound', passing the instance
// as the first argument. Note that this is not supported if any
// of the overloads are static since we can't know if the intent
// was to call the static method or the unbound instance method.
List <IntPtr> disposeList = new List <IntPtr>();
try
{
IntPtr target = self.target;
if ((target == IntPtr.Zero) && (!self.m.IsStatic()))
{
int len = Runtime.PyTuple_Size(args);
if (len < 1)
{
Exceptions.SetError(Exceptions.TypeError, "not enough arguments");
return(IntPtr.Zero);
}
target = Runtime.PyTuple_GetItem(args, 0);
Runtime.Incref(target);
disposeList.Add(target);
args = Runtime.PyTuple_GetSlice(args, 1, len);
disposeList.Add(args);
}
// if the class is a IPythonDerivedClass and target is not the same as self.targetType
// (eg if calling the base class method) then call the original base class method instead
// of the target method.
IntPtr superType = IntPtr.Zero;
if (Runtime.PyObject_TYPE(target) != self.targetType)
{
CLRObject inst = CLRObject.GetManagedObject(target) as CLRObject;
if (inst != null && (inst.inst as IPythonDerivedType) != null)
{
ClassBase baseType = GetManagedObject(self.targetType) as ClassBase;
if (baseType != null)
{
string baseMethodName = "_" + baseType.type.Name + "__" + self.m.name;
IntPtr baseMethod = Runtime.PyObject_GetAttrString(target, baseMethodName);
if (baseMethod != IntPtr.Zero)
{
MethodBinding baseSelf = GetManagedObject(baseMethod) as MethodBinding;
if (baseSelf != null)
{
self = baseSelf;
}
Runtime.Decref(baseMethod);
}
else
{
Runtime.PyErr_Clear();
}
}
}
}
return(self.m.Invoke(target, args, kw, self.info));
}
finally
{
foreach (IntPtr ptr in disposeList)
{
Runtime.Decref(ptr);
}
}
}