Exemple #1
0
        public static IntPtr ConvertUnboxingFunctionPointerToUnderlyingNonUnboxingPointer(IntPtr unboxingFunctionPointer, RuntimeTypeHandle declaringType)
        {
            if (FunctionPointerOps.IsGenericMethodPointer(unboxingFunctionPointer))
            {
                // Handle shared generic methods
                unsafe
                {
                    GenericMethodDescriptor *functionPointerDescriptor = FunctionPointerOps.ConvertToGenericDescriptor(unboxingFunctionPointer);
                    IntPtr nonUnboxingTarget = RuntimeAugments.GetCodeTarget(functionPointerDescriptor->MethodFunctionPointer);
                    Debug.Assert(nonUnboxingTarget != functionPointerDescriptor->MethodFunctionPointer);
                    Debug.Assert(nonUnboxingTarget == RuntimeAugments.GetCodeTarget(nonUnboxingTarget));
                    return(FunctionPointerOps.GetGenericMethodFunctionPointer(nonUnboxingTarget, functionPointerDescriptor->InstantiationArgument));
                }
            }

            // GetCodeTarget will look through simple unboxing stubs (ones that consist of adjusting the this pointer and then
            // jumping to the target.
            IntPtr exactTarget = RuntimeAugments.GetCodeTarget(unboxingFunctionPointer);

            if (RuntimeAugments.IsGenericType(declaringType))
            {
                IntPtr fatFunctionPointerTarget;

                // This check looks for unboxing and instantiating stubs generated via the compiler backend
                if (TypeLoaderEnvironment.TryGetTargetOfUnboxingAndInstantiatingStub(exactTarget, out fatFunctionPointerTarget))
                {
                    // If this is an unboxing and instantiating stub, use separate table, find target, and create fat function pointer
                    exactTarget = FunctionPointerOps.GetGenericMethodFunctionPointer(fatFunctionPointerTarget,
                                                                                     declaringType.ToIntPtr());
                }
#if FEATURE_UNIVERSAL_GENERICS
                else
                {
                    IntPtr newExactTarget;
                    // This check looks for unboxing and instantiating stubs generated dynamically as thunks in the calling convention converter
                    if (CallConverterThunk.TryGetNonUnboxingFunctionPointerFromUnboxingAndInstantiatingStub(exactTarget,
                                                                                                            declaringType, out newExactTarget))
                    {
                        // CallingConventionConverter determined non-unboxing stub
                        exactTarget = newExactTarget;
                    }
                    else
                    {
                        // Target method was a method on a generic, but it wasn't a shared generic, and thus none of the above
                        // complex unboxing stub digging logic was necessary. Do nothing, and use exactTarget as discovered
                        // from GetCodeTarget
                    }
                }
#endif
            }

            return(exactTarget);
        }
            private unsafe static IntPtr ResolveCallOnValueType(IntPtr unused, IntPtr callDescIntPtr)
#endif
            {
                GenericConstrainedCallDesc *callDesc = (GenericConstrainedCallDesc *)callDescIntPtr;
                IntPtr targetAsVirtualCall           = RuntimeAugments.GVMLookupForSlot(callDesc->_constraintType, callDesc->_constrainedMethod);
                IntPtr exactTarget = IntPtr.Zero;

                if (FunctionPointerOps.IsGenericMethodPointer(targetAsVirtualCall))
                {
                    GenericMethodDescriptor *genMethodDesc = FunctionPointerOps.ConvertToGenericDescriptor(targetAsVirtualCall);
                    IntPtr actualCodeTarget = RuntimeAugments.GetCodeTarget(genMethodDesc->MethodFunctionPointer);
                    exactTarget = FunctionPointerOps.GetGenericMethodFunctionPointer(actualCodeTarget, genMethodDesc->InstantiationArgument);
                }
                else
                {
                    IntPtr actualCodeTarget = RuntimeAugments.GetCodeTarget(targetAsVirtualCall);
                    IntPtr callConverterThunk;

                    if (CallConverterThunk.TryGetNonUnboxingFunctionPointerFromUnboxingAndInstantiatingStub(actualCodeTarget, callDesc->_constraintType, out callConverterThunk))
                    {
                        actualCodeTarget = callConverterThunk;
                    }

                    exactTarget = actualCodeTarget;
                }

                // Ensure that all threads will have their function pointers completely published before updating callDesc.
                // as the ExactTarget is read from callDesc by binder generated code without a barrier, we need a barrier here
                // to ensure that the new function pointer data is valid on all threads
                Interlocked.MemoryBarrier();

                // Its possible for multiple threads to race to set exact target. Check to see we always set the same value
                if (callDesc->_exactTarget != IntPtr.Zero)
                {
                    Debug.Assert(callDesc->_exactTarget == exactTarget);
                }

                callDesc->_exactTarget = exactTarget;
                return(exactTarget);
            }
Exemple #3
0
 public override IntPtr GetDelegateThunk(Delegate delegateObject, int thunkKind)
 {
     return CallConverterThunk.GetDelegateThunk(delegateObject, thunkKind);
 }
        //
        // Lazily parse the method signature, and construct the call converter data
        //
        private void EnsureCallConversionInfoLoaded()
        {
            if (_signatureParsed)
            {
                return;
            }

            lock (this)
            {
                // Check if race was won by another thread and the signature got parsed
                if (_signatureParsed)
                {
                    return;
                }

                TypeSystemContext context = TypeSystemContextFactory.Create();
                {
                    Instantiation typeInstantiation   = Instantiation.Empty;
                    Instantiation methodInstantiation = Instantiation.Empty;

                    if (_typeArgs != null && _typeArgs.Length > 0)
                    {
                        typeInstantiation = context.ResolveRuntimeTypeHandles(_typeArgs);
                    }
                    if (_methodArgs != null && _methodArgs.Length > 0)
                    {
                        methodInstantiation = context.ResolveRuntimeTypeHandles(_methodArgs);
                    }

                    bool       hasThis;
                    TypeDesc[] parameters;
                    bool[]     paramsByRefForced;
                    if (!TypeLoaderEnvironment.Instance.GetCallingConverterDataFromMethodSignature(context, _methodSignature, typeInstantiation, methodInstantiation, out hasThis, out parameters, out paramsByRefForced))
                    {
                        Debug.Assert(false);
                        Environment.FailFast("Failed to get type handles for parameters in method signature");
                    }
                    Debug.Assert(parameters != null && parameters.Length >= 1);

                    bool[] byRefParameters = new bool[parameters.Length];
                    RuntimeTypeHandle[] parameterHandles = new RuntimeTypeHandle[parameters.Length];

                    for (int j = 0; j < parameters.Length; j++)
                    {
                        ByRefType parameterAsByRefType = parameters[j] as ByRefType;
                        if (parameterAsByRefType != null)
                        {
                            parameterAsByRefType.ParameterType.RetrieveRuntimeTypeHandleIfPossible();
                            parameterHandles[j] = parameterAsByRefType.ParameterType.RuntimeTypeHandle;
                            byRefParameters[j]  = true;
                        }
                        else
                        {
                            parameters[j].RetrieveRuntimeTypeHandleIfPossible();
                            parameterHandles[j] = parameters[j].RuntimeTypeHandle;
                            byRefParameters[j]  = false;
                        }

                        Debug.Assert(!parameterHandles[j].IsNull());
                    }

                    // Build thunk data
                    TypeHandle   thReturnType = new TypeHandle(CallConverterThunk.GetByRefIndicatorAtIndex(0, byRefParameters), parameterHandles[0]);
                    TypeHandle[] thParameters = null;
                    if (parameters.Length > 1)
                    {
                        thParameters = new TypeHandle[parameters.Length - 1];
                        for (int i = 1; i < parameters.Length; i++)
                        {
                            thParameters[i - 1] = new TypeHandle(CallConverterThunk.GetByRefIndicatorAtIndex(i, byRefParameters), parameterHandles[i]);
                        }
                    }

                    _argIteratorData = new ArgIteratorData(hasThis, false, thParameters, thReturnType);

                    // StandardToStandard thunks don't actually need any parameters to change their ABI
                    // so don't force any params to be adjusted
                    if (!StandardToStandardThunk)
                    {
                        _paramsByRefForced = paramsByRefForced;
                    }
                }
                TypeSystemContextFactory.Recycle(context);

                _signatureParsed = true;
            }
        }
            private unsafe static IntPtr ResolveCallOnValueType(IntPtr unused, IntPtr callDescIntPtr)
#endif
            {
                NonGenericConstrainedCallDesc *callDesc = (NonGenericConstrainedCallDesc *)callDescIntPtr;
                IntPtr exactTarget        = IntPtr.Zero;
                IntPtr targetOnTypeVtable = RuntimeAugments.ResolveDispatchOnType(callDesc->_constraintType, callDesc->_constrainedMethodType, callDesc->_constrainedMethodSlot);
                bool   decodeUnboxing     = true;

                if (!RuntimeAugments.IsInterface(callDesc->_constrainedMethodType))
                {
                    // Non-interface constrained call on a valuetype to a method that isn't GetHashCode/Equals/ToString?!?!
                    if (callDesc->_constrainedMethodSlot > s_MaxObjectVTableSlot)
                    {
                        throw new NotSupportedException();
                    }

                    RuntimeTypeHandle baseTypeHandle;
                    bool gotBaseType = RuntimeAugments.TryGetBaseType(callDesc->_constraintType, out baseTypeHandle);
                    Debug.Assert(gotBaseType);
                    if (targetOnTypeVtable == RuntimeAugments.ResolveDispatchOnType(baseTypeHandle, callDesc->_constrainedMethodType, callDesc->_constrainedMethodSlot))
                    {
                        // In this case, the valuetype does not override the base types implementation of ToString(), GetHashCode(), or Equals(object)
                        decodeUnboxing = false;
                    }
                }

                if (decodeUnboxing)
                {
                    exactTarget = RuntimeAugments.GetCodeTarget(targetOnTypeVtable);
                    if (RuntimeAugments.IsGenericType(callDesc->_constraintType))
                    {
                        IntPtr fatFunctionPointerTarget;
                        if (TypeLoaderEnvironment.TryGetTargetOfUnboxingAndInstantiatingStub(exactTarget, out fatFunctionPointerTarget))
                        {
                            // If this is an unboxing and instantiating stub, use seperate table, find target, and create fat function pointer
                            exactTarget = FunctionPointerOps.GetGenericMethodFunctionPointer(fatFunctionPointerTarget,
                                                                                             callDesc->_constraintType.ToIntPtr());
                        }
                        else
                        {
                            IntPtr newExactTarget;
                            if (CallConverterThunk.TryGetNonUnboxingFunctionPointerFromUnboxingAndInstantiatingStub(exactTarget,
                                                                                                                    callDesc->_constraintType, out newExactTarget))
                            {
                                // CallingConventionConverter determined non-unboxing stub
                                exactTarget = newExactTarget;
                            }
                            else
                            {
                                // Target method was a method on a generic, but it wasn't a shared generic, and thus none of the above
                                // complex unboxing stub digging logic was necessary. Do nothing, and use exactTarget as discovered
                                // from GetCodeTarget
                            }
                        }
                    }
                }
                else
                {
                    // Create a fat function pointer, where the instantiation argument is ConstraintType, and the target is BoxAndToString, BoxAndGetHashCode, or BoxAndEquals
                    IntPtr realTarget;

                    switch (callDesc->_constrainedMethodSlot)
                    {
                    case s_ToStringSlot:
                        realTarget = s_boxAndToStringFuncPtr;
                        break;

                    case s_GetHashCodeSlot:
                        realTarget = s_boxAndGetHashCodeFuncPtr;
                        break;

                    case s_EqualsSlot:
                        realTarget = s_boxAndEqualsFuncPtr;
                        break;

                    default:
                        throw new NotSupportedException();
                    }

                    exactTarget = FunctionPointerOps.GetGenericMethodFunctionPointer(realTarget, callDesc->_constraintType.ToIntPtr());
                }

                // Ensure that all threads will have their function pointers completely published before updating callDesc.
                // as the ExactTarget is read from callDesc by binder generated code without a barrier, we need a barrier here
                // to ensure that the new function pointer data is valid on all threads
                Interlocked.MemoryBarrier();

                // Its possible for multiple threads to race to set exact target. Check to see we always set the same value
                if (callDesc->_exactTarget != IntPtr.Zero)
                {
                    Debug.Assert(callDesc->_exactTarget == exactTarget);
                }

                callDesc->_exactTarget = exactTarget;
                return(exactTarget);
            }
Exemple #6
0
        // This method computes the method pointer and dictionary pointer for a GVM.
        // Inputs:
        //      - targetTypeHanlde: target type on which the GVM is implemented
        //      - nameAndSignature: name and signature of the GVM method
        //      - genericMethodArgumentHandles: GVM instantiation arguments
        // Outputs:
        //      - methodPointer: pointer to the GVM's implementation
        //      - dictionaryPointer: (if applicable) pointer to the dictionary to be used with the GVM call
        public bool TryGetGenericVirtualMethodPointer(RuntimeTypeHandle targetTypeHandle, MethodNameAndSignature nameAndSignature, RuntimeTypeHandle[] genericMethodArgumentHandles, out IntPtr methodPointer, out IntPtr dictionaryPointer)
        {
            methodPointer = dictionaryPointer = IntPtr.Zero;

            TypeSystemContext context = TypeSystemContextFactory.Create();

            DefType            targetType          = (DefType)context.ResolveRuntimeTypeHandle(targetTypeHandle);
            Instantiation      methodInstantiation = context.ResolveRuntimeTypeHandles(genericMethodArgumentHandles);
            InstantiatedMethod method = (InstantiatedMethod)context.ResolveGenericMethodInstantiation(false, targetType, nameAndSignature, methodInstantiation, IntPtr.Zero, false);

            if (!method.CanShareNormalGenericCode())
            {
                // First see if we can find an exact method implementation for the GVM (avoid using USG implementations if we can,
                // because USG code is much slower).
                if (TryLookupExactMethodPointerForComponents(targetTypeHandle, nameAndSignature, genericMethodArgumentHandles, out methodPointer))
                {
                    Debug.Assert(methodPointer != IntPtr.Zero);
                    TypeSystemContextFactory.Recycle(context);
                    return(true);
                }
            }

            // If we cannot find an exact method entry point, look for an equivalent template and compute the generic dictinoary
            TemplateLocator    templateLocator  = new TemplateLocator();
            NativeLayoutInfo   nativeLayoutInfo = new NativeLayoutInfo();
            InstantiatedMethod templateMethod   = templateLocator.TryGetGenericMethodTemplate(method, out nativeLayoutInfo.Module, out nativeLayoutInfo.Token);

            if (templateMethod == null)
            {
                return(false);
            }

            methodPointer = templateMethod.IsCanonicalMethod(CanonicalFormKind.Universal) ?
                            templateMethod.UsgFunctionPointer :
                            templateMethod.FunctionPointer;

            if (!TryLookupGenericMethodDictionaryForComponents(targetTypeHandle, nameAndSignature, genericMethodArgumentHandles, out dictionaryPointer))
            {
                using (LockHolder.Hold(_typeLoaderLock))
                {
                    // Now that we hold the lock, we may find that existing types can now find
                    // their associated RuntimeTypeHandle. Flush the type builder states as a way
                    // to force the reresolution of RuntimeTypeHandles which couldn't be found before.
                    context.FlushTypeBuilderStates();

                    if (!TypeBuilder.TryBuildGenericMethod(method, out dictionaryPointer))
                    {
                        return(false);
                    }
                }
            }

            Debug.Assert(methodPointer != IntPtr.Zero && dictionaryPointer != IntPtr.Zero);

            if (templateMethod.IsCanonicalMethod(CanonicalFormKind.Universal))
            {
                // Check if we need to wrap the method pointer into a calling convention converter thunk
                if (!TypeLoaderEnvironment.Instance.MethodSignatureHasVarsNeedingCallingConventionConverter(context, nameAndSignature.Signature))
                {
                    TypeSystemContextFactory.Recycle(context);
                    return(true);
                }

                RuntimeTypeHandle[] typeArgs = Array.Empty <RuntimeTypeHandle>();

                if (RuntimeAugments.IsGenericType(targetTypeHandle))
                {
                    RuntimeAugments.GetGenericInstantiation(targetTypeHandle, out typeArgs);
                }

                // Create a CallingConventionConverter to call the method correctly
                IntPtr thunkPtr = CallConverterThunk.MakeThunk(
                    CallConverterThunk.ThunkKind.StandardToGenericInstantiating,
                    methodPointer,
                    nameAndSignature.Signature,
                    dictionaryPointer,
                    typeArgs,
                    genericMethodArgumentHandles);

                Debug.Assert(thunkPtr != IntPtr.Zero);

                methodPointer = thunkPtr;
                // Set dictionaryPointer to null so we don't make a fat function pointer around the whole thing.
                dictionaryPointer = IntPtr.Zero;

                // TODO! add a new call converter thunk that will pass the instantiating arg through and use a fat function pointer.
                // should allow us to make fewer thunks.
            }

            TypeSystemContextFactory.Recycle(context);
            return(true);
        }