private static TypeDesc TryGetTypeTemplate_Internal(TypeDesc concreteType, CanonicalFormKind kind, out NativeFormatModuleInfo nativeLayoutInfoModule, out uint nativeLayoutInfoToken)
{
nativeLayoutInfoModule = null;
nativeLayoutInfoToken = 0;
var canonForm = concreteType.ConvertToCanonForm(kind);
var hashCode = canonForm.GetHashCode();
foreach (NativeFormatModuleInfo moduleInfo in ModuleList.EnumerateModules())
{
ExternalReferencesTable externalFixupsTable;
NativeHashtable typeTemplatesHashtable = LoadHashtable(moduleInfo, ReflectionMapBlob.TypeTemplateMap, out externalFixupsTable);
if (typeTemplatesHashtable.IsNull)
{
continue;
}
var enumerator = typeTemplatesHashtable.Lookup(hashCode);
NativeParser entryParser;
while (!(entryParser = enumerator.GetNext()).IsNull)
{
RuntimeTypeHandle candidateTemplateTypeHandle = externalFixupsTable.GetRuntimeTypeHandleFromIndex(entryParser.GetUnsigned());
TypeDesc candidateTemplate = concreteType.Context.ResolveRuntimeTypeHandle(candidateTemplateTypeHandle);
if (canonForm == candidateTemplate.ConvertToCanonForm(kind))
{
TypeLoaderLogger.WriteLine("Found template for type " + concreteType.ToString() + ": " + candidateTemplate.ToString());
nativeLayoutInfoToken = entryParser.GetUnsigned();
if (nativeLayoutInfoToken == BadTokenFixupValue)
{
// TODO: once multifile gets fixed up, make this throw a BadImageFormatException
TypeLoaderLogger.WriteLine("ERROR: template not fixed up, skipping");
continue;
}
Debug.Assert(
(kind != CanonicalFormKind.Universal) ||
(kind == CanonicalFormKind.Universal && candidateTemplate == candidateTemplate.ConvertToCanonForm(kind)));
nativeLayoutInfoModule = moduleInfo;
return(candidateTemplate);
}
}
}
TypeLoaderLogger.WriteLine("ERROR: Cannot find a suitable template for type " + concreteType.ToString());
return(null);
}
//
// Returns the template method for a generic method instantation
//
public static InstantiatedMethod TryGetGenericMethodTemplate(InstantiatedMethod concreteMethod, out NativeFormatModuleInfo nativeLayoutInfoModule, out uint nativeLayoutInfoToken)
{
// First, see if there is a specific canonical template
InstantiatedMethod result = TryGetGenericMethodTemplate_Internal(concreteMethod, CanonicalFormKind.Specific, out nativeLayoutInfoModule, out nativeLayoutInfoToken);
// If not found, see if there's a universal canonical template
if (result == null)
{
result = TryGetGenericMethodTemplate_Internal(concreteMethod, CanonicalFormKind.Universal, out nativeLayoutInfoModule, out nativeLayoutInfoToken);
}
return(result);
}
/// <summary>
/// Initialize ExternalReferencesTable using the CommonFixupsTable metadata blob on a given module.
/// </summary>
/// <param name="moduleHandle">Module handle is used to locate the CommonFixupsTable blob</param>
/// <returns>true when the CommonFixupsTable blob was found in the given module, false when not</returns>
public bool InitializeCommonFixupsTable(NativeFormatModuleInfo module)
{
return(Initialize(module, ReflectionMapBlob.CommonFixupsTable));
}
private static InstantiatedMethod TryGetGenericMethodTemplate_Internal(InstantiatedMethod concreteMethod, CanonicalFormKind kind, out NativeFormatModuleInfo nativeLayoutInfoModule, out uint nativeLayoutInfoToken)
{
nativeLayoutInfoModule = null;
nativeLayoutInfoToken = 0;
var canonForm = concreteMethod.GetCanonMethodTarget(kind);
var hashCode = canonForm.GetHashCode();
foreach (NativeFormatModuleInfo moduleInfo in ModuleList.EnumerateModules())
{
NativeReader nativeLayoutReader = TypeLoaderEnvironment.GetNativeLayoutInfoReader(moduleInfo.Handle);
if (nativeLayoutReader == null)
{
continue;
}
NativeHashtable genericMethodTemplatesHashtable = LoadHashtable(moduleInfo, ReflectionMapBlob.GenericMethodsTemplateMap, out _);
if (genericMethodTemplatesHashtable.IsNull)
{
continue;
}
var context = new NativeLayoutInfoLoadContext
{
_typeSystemContext = concreteMethod.Context,
_typeArgumentHandles = concreteMethod.OwningType.Instantiation,
_methodArgumentHandles = concreteMethod.Instantiation,
_module = moduleInfo
};
var enumerator = genericMethodTemplatesHashtable.Lookup(hashCode);
NativeParser entryParser;
while (!(entryParser = enumerator.GetNext()).IsNull)
{
var methodSignatureParser = new NativeParser(nativeLayoutReader, entryParser.GetUnsigned());
// Get the unified generic method holder and convert it to its canonical form
var candidateTemplate = (InstantiatedMethod)context.GetMethod(ref methodSignatureParser);
Debug.Assert(candidateTemplate.Instantiation.Length > 0);
if (canonForm == candidateTemplate.GetCanonMethodTarget(kind))
{
TypeLoaderLogger.WriteLine("Found template for generic method " + concreteMethod.ToString() + ": " + candidateTemplate.ToString());
nativeLayoutInfoModule = moduleInfo;
nativeLayoutInfoToken = entryParser.GetUnsigned();
if (nativeLayoutInfoToken == BadTokenFixupValue)
{
// TODO: once multifile gets fixed up, make this throw a BadImageFormatException
TypeLoaderLogger.WriteLine("ERROR: template not fixed up, skipping");
continue;
}
Debug.Assert(
(kind != CanonicalFormKind.Universal) ||
(kind == CanonicalFormKind.Universal && candidateTemplate == candidateTemplate.GetCanonMethodTarget(kind)));
return(candidateTemplate);
}
}
}
TypeLoaderLogger.WriteLine("ERROR: Cannot find a suitable template for generic method " + concreteMethod.ToString());
return(null);
}
/// <summary>
/// Attempt to convert the dispatch cell to a metadata token to a more efficient vtable dispatch or interface/slot dispatch.
/// Failure to convert is not a correctness issue. We also support performing a dispatch based on metadata token alone.
/// </summary>
private static DispatchCellInfo ConvertDispatchCellInfo_Inner(NativeFormatModuleInfo module, DispatchCellInfo cellInfo)
{
Debug.Assert(cellInfo.CellType == DispatchCellType.MetadataToken);
TypeSystemContext context = TypeSystemContextFactory.Create();
MethodDesc targetMethod = context.ResolveMetadataUnit(module).GetMethod(cellInfo.MetadataToken.AsHandle(), null);
Debug.Assert(!targetMethod.HasInstantiation); // At this time we do not support generic virtuals through the dispatch mechanism
Debug.Assert(targetMethod.IsVirtual);
if (targetMethod.OwningType.IsInterface)
{
if (!LazyVTableResolver.TryGetInterfaceSlotNumberFromMethod(targetMethod, out cellInfo.InterfaceSlot))
{
// Unable to resolve interface method. Fail, by not mutating cellInfo
return(cellInfo);
}
if (!targetMethod.OwningType.RetrieveRuntimeTypeHandleIfPossible())
{
new TypeBuilder().BuildType(targetMethod.OwningType);
}
cellInfo.CellType = DispatchCellType.InterfaceAndSlot;
cellInfo.InterfaceType = targetMethod.OwningType.RuntimeTypeHandle.ToIntPtr();
cellInfo.MetadataToken = 0;
}
else
{
// Virtual function case, attempt to resolve to a VTable slot offset.
// If the offset is less than 4096 update the cellInfo
#if DEBUG
// The path of resolving a metadata token at dispatch time is relatively rare in practice.
// Force it to occur in debug builds with much more regularity
if ((s_ConvertDispatchCellInfoCounter % 16) == 0)
{
s_ConvertDispatchCellInfoCounter++;
TypeSystemContextFactory.Recycle(context);
return(cellInfo);
}
s_ConvertDispatchCellInfoCounter++;
#endif
int slotIndexOfMethod = LazyVTableResolver.VirtualMethodToSlotIndex(targetMethod);
int vtableOffset = -1;
if (slotIndexOfMethod >= 0)
{
vtableOffset = LazyVTableResolver.SlotIndexToEETypeVTableOffset(slotIndexOfMethod);
}
if ((vtableOffset < 4096) && (vtableOffset != -1))
{
cellInfo.CellType = DispatchCellType.VTableOffset;
cellInfo.VTableOffset = checked ((uint)vtableOffset);
cellInfo.MetadataToken = 0;
}
// Otherwise, do nothing, and resolve with a metadata dispatch later
}
TypeSystemContextFactory.Recycle(context);
return(cellInfo);
}
/// <summary>
/// Initialize ExternalReferencesTable using the NativeStatics metadata blob on a given module.
/// </summary>
/// <param name="moduleHandle">Module handle is used to locate the NativeStatics blob</param>
/// <returns>true when the NativeStatics blob was found in the given module, false when not</returns>
public bool InitializeNativeStatics(NativeFormatModuleInfo module)
{
return(Initialize(module, ReflectionMapBlob.NativeStatics));
}
private bool CompareMethodSigs(NativeParser parser1, NativeFormatModuleInfo moduleHandle1, NativeParser parser2, NativeFormatModuleInfo moduleHandle2)
{
MethodCallingConvention callingConvention1 = (MethodCallingConvention)parser1.GetUnsigned();
MethodCallingConvention callingConvention2 = (MethodCallingConvention)parser2.GetUnsigned();
if (callingConvention1 != callingConvention2)
{
return(false);
}
if ((callingConvention1 & MethodCallingConvention.Generic) == MethodCallingConvention.Generic)
{
if (parser1.GetUnsigned() != parser2.GetUnsigned())
{
return(false);
}
}
uint parameterCount1 = parser1.GetUnsigned();
uint parameterCount2 = parser2.GetUnsigned();
if (parameterCount1 != parameterCount2)
{
return(false);
}
// Compare one extra parameter to account for the return type
for (uint i = 0; i <= parameterCount1; i++)
{
if (!CompareTypeSigs(ref parser1, moduleHandle1, ref parser2, moduleHandle2))
{
return(false);
}
}
return(true);
}
private bool CompareTypeSigs(ref NativeParser parser1, NativeFormatModuleInfo moduleHandle1, ref NativeParser parser2, NativeFormatModuleInfo moduleHandle2)
{
// startOffset lets us backtrack to the TypeSignatureKind for external types since the TypeLoader
// expects to read it in.
uint data1;
uint startOffset1 = parser1.Offset;
var typeSignatureKind1 = parser1.GetTypeSignatureKind(out data1);
// If the parser is at a lookback type, get a new parser for it and recurse.
// Since we haven't read the element type of parser2 yet, we just pass it in unchanged
if (typeSignatureKind1 == TypeSignatureKind.Lookback)
{
NativeParser lookbackParser1 = parser1.GetLookbackParser(data1);
return(CompareTypeSigs(ref lookbackParser1, moduleHandle1, ref parser2, moduleHandle2));
}
uint data2;
uint startOffset2 = parser2.Offset;
var typeSignatureKind2 = parser2.GetTypeSignatureKind(out data2);
// If parser2 is a lookback type, we need to rewind parser1 to its startOffset1
// before recursing.
if (typeSignatureKind2 == TypeSignatureKind.Lookback)
{
NativeParser lookbackParser2 = parser2.GetLookbackParser(data2);
parser1 = new NativeParser(parser1.Reader, startOffset1);
return(CompareTypeSigs(ref parser1, moduleHandle1, ref lookbackParser2, moduleHandle2));
}
if (typeSignatureKind1 != typeSignatureKind2)
{
return(false);
}
switch (typeSignatureKind1)
{
case TypeSignatureKind.Lookback:
{
// Recursion above better have removed all lookbacks
Debug.Assert(false, "Unexpected lookback type");
return(false);
}
case TypeSignatureKind.Modifier:
{
// Ensure the modifier kind (vector, pointer, byref) is the same
if (data1 != data2)
{
return(false);
}
return(CompareTypeSigs(ref parser1, moduleHandle1, ref parser2, moduleHandle2));
}
case TypeSignatureKind.Variable:
{
// variable index is in data
if (data1 != data2)
{
return(false);
}
break;
}
case TypeSignatureKind.MultiDimArray:
{
// rank is in data
if (data1 != data2)
{
return(false);
}
if (!CompareTypeSigs(ref parser1, moduleHandle1, ref parser2, moduleHandle2))
{
return(false);
}
uint boundCount1 = parser1.GetUnsigned();
uint boundCount2 = parser2.GetUnsigned();
if (boundCount1 != boundCount2)
{
return(false);
}
for (uint i = 0; i < boundCount1; i++)
{
if (parser1.GetUnsigned() != parser2.GetUnsigned())
{
return(false);
}
}
uint lowerBoundCount1 = parser1.GetUnsigned();
uint lowerBoundCount2 = parser2.GetUnsigned();
if (lowerBoundCount1 != lowerBoundCount2)
{
return(false);
}
for (uint i = 0; i < lowerBoundCount1; i++)
{
if (parser1.GetUnsigned() != parser2.GetUnsigned())
{
return(false);
}
}
break;
}
case TypeSignatureKind.FunctionPointer:
{
// callingConvention is in data
if (data1 != data2)
{
return(false);
}
uint argCount1 = parser1.GetUnsigned();
uint argCount2 = parser2.GetUnsigned();
if (argCount1 != argCount2)
{
return(false);
}
for (uint i = 0; i < argCount1; i++)
{
if (!CompareTypeSigs(ref parser1, moduleHandle1, ref parser2, moduleHandle2))
{
return(false);
}
}
break;
}
case TypeSignatureKind.Instantiation:
{
// Type parameter count is in data
if (data1 != data2)
{
return(false);
}
if (!CompareTypeSigs(ref parser1, moduleHandle1, ref parser2, moduleHandle2))
{
return(false);
}
for (uint i = 0; i < data1; i++)
{
if (!CompareTypeSigs(ref parser1, moduleHandle1, ref parser2, moduleHandle2))
{
return(false);
}
}
break;
}
case TypeSignatureKind.External:
{
RuntimeTypeHandle typeHandle1 = GetExternalTypeHandle(moduleHandle1, data1);
RuntimeTypeHandle typeHandle2 = GetExternalTypeHandle(moduleHandle2, data2);
if (!typeHandle1.Equals(typeHandle2))
{
return(false);
}
break;
}
default:
return(false);
}
return(true);
}
private bool FindMatchingInterfaceSlot(NativeFormatModuleInfo module, NativeReader nativeLayoutReader, ref NativeParser entryParser, ref ExternalReferencesTable extRefs, ref RuntimeTypeHandle declaringType, ref MethodNameAndSignature methodNameAndSignature, RuntimeTypeHandle openTargetTypeHandle, RuntimeTypeHandle[] targetTypeInstantiation, bool variantDispatch)
{
uint numTargetImplementations = entryParser.GetUnsigned();
for (uint j = 0; j < numTargetImplementations; j++)
{
uint nameAndSigToken = extRefs.GetExternalNativeLayoutOffset(entryParser.GetUnsigned());
MethodNameAndSignature targetMethodNameAndSignature = GetMethodNameAndSignatureFromNativeReader(nativeLayoutReader, module.Handle, nameAndSigToken);
RuntimeTypeHandle targetTypeHandle = extRefs.GetRuntimeTypeHandleFromIndex(entryParser.GetUnsigned());
#if REFLECTION_EXECUTION_TRACE
ReflectionExecutionLogger.WriteLine(" Searching for GVM implementation on targe type = " + GetTypeNameDebug(targetTypeHandle));
#endif
uint numIfaceImpls = entryParser.GetUnsigned();
for (uint k = 0; k < numIfaceImpls; k++)
{
RuntimeTypeHandle implementingTypeHandle = extRefs.GetRuntimeTypeHandleFromIndex(entryParser.GetUnsigned());
uint numIfaceSigs = entryParser.GetUnsigned();
if (!openTargetTypeHandle.Equals(implementingTypeHandle))
{
// Skip over signatures data
for (uint l = 0; l < numIfaceSigs; l++)
{
entryParser.GetUnsigned();
}
continue;
}
for (uint l = 0; l < numIfaceSigs; l++)
{
RuntimeTypeHandle currentIfaceTypeHandle = default(RuntimeTypeHandle);
NativeParser ifaceSigParser = new NativeParser(nativeLayoutReader, extRefs.GetExternalNativeLayoutOffset(entryParser.GetUnsigned()));
if (TypeLoaderEnvironment.Instance.GetTypeFromSignatureAndContext(ref ifaceSigParser, module.Handle, targetTypeInstantiation, null, out currentIfaceTypeHandle))
{
Debug.Assert(!currentIfaceTypeHandle.IsNull());
if ((!variantDispatch && declaringType.Equals(currentIfaceTypeHandle)) ||
(variantDispatch && RuntimeAugments.IsAssignableFrom(declaringType, currentIfaceTypeHandle)))
{
#if REFLECTION_EXECUTION_TRACE
ReflectionExecutionLogger.WriteLine(" " + (declaringType.Equals(currentIfaceTypeHandle) ? "Exact" : "Variant-compatible") + " match found on this target type!");
#endif
// We found the GVM slot target for the input interface GVM call, so let's update the interface GVM slot and return success to the caller
declaringType = targetTypeHandle;
methodNameAndSignature = targetMethodNameAndSignature;
return(true);
}
}
}
}
}
return(false);
}
/// <summary>
/// IF THESE SEMANTICS EVER CHANGE UPDATE THE LOGIC WHICH DEFINES THIS BEHAVIOR IN
/// THE DYNAMIC TYPE LOADER AS WELL AS THE COMPILER.
/// (There is a version of this in UniversalGenericParameterLayout.cs that must be kept in sync with this.)
///
/// Parameter's are considered to have type layout dependent on their generic instantiation
/// if the type of the parameter in its signature is a type variable, or if the type is a generic
/// structure which meets 2 characteristics:
/// 1. Structure size/layout is affected by the size/layout of one or more of its generic parameters
/// 2. One or more of the generic parameters is a type variable, or a generic structure which also recursively
/// would satisfy constraint 2. (Note, that in the recursion case, whether or not the structure is affected
/// by the size/layout of its generic parameters is not investigated.)
///
/// Examples parameter types, and behavior.
///
/// T = true
/// List[T] = false
/// StructNotDependentOnArgsForSize[T] = false
/// GenStructDependencyOnArgsForSize[T] = true
/// StructNotDependentOnArgsForSize[GenStructDependencyOnArgsForSize[T]] = true
/// StructNotDependentOnArgsForSize[GenStructDependencyOnArgsForSize[List[T]]]] = false
///
/// Example non-parameter type behavior
/// T = true
/// List[T] = false
/// StructNotDependentOnArgsForSize[T] = *true*
/// GenStructDependencyOnArgsForSize[T] = true
/// StructNotDependentOnArgsForSize[GenStructDependencyOnArgsForSize[T]] = true
/// StructNotDependentOnArgsForSize[GenStructDependencyOnArgsForSize[List[T]]]] = false
/// </summary>
private bool TypeSignatureHasVarsNeedingCallingConventionConverter(ref NativeParser parser, NativeFormatModuleInfo moduleHandle, TypeSystemContext context, HasVarsInvestigationLevel investigationLevel)
{
uint data;
var kind = parser.GetTypeSignatureKind(out data);
switch (kind)
{
case TypeSignatureKind.External: return(false);
case TypeSignatureKind.Variable: return(true);
case TypeSignatureKind.Lookback:
{
var lookbackParser = parser.GetLookbackParser(data);
return(TypeSignatureHasVarsNeedingCallingConventionConverter(ref lookbackParser, moduleHandle, context, investigationLevel));
}
case TypeSignatureKind.Instantiation:
{
RuntimeTypeHandle genericTypeDef;
if (!TryGetTypeFromSimpleTypeSignature(ref parser, moduleHandle, out genericTypeDef))
{
Debug.Assert(false);
return(true); // Returning true will prevent further reading from the native parser
}
if (!RuntimeAugments.IsValueType(genericTypeDef))
{
// Reference types are treated like pointers. No calling convention conversion needed. Just consume the rest of the signature.
for (uint i = 0; i < data; i++)
{
TypeSignatureHasVarsNeedingCallingConventionConverter(ref parser, moduleHandle, context, HasVarsInvestigationLevel.Ignore);
}
return(false);
}
else
{
bool result = false;
for (uint i = 0; i < data; i++)
{
result = TypeSignatureHasVarsNeedingCallingConventionConverter(ref parser, moduleHandle, context, HasVarsInvestigationLevel.NotParameter) || result;
}
if ((result == true) && (investigationLevel == HasVarsInvestigationLevel.Parameter))
{
if (!TryComputeHasInstantiationDeterminedSize(genericTypeDef, context, out result))
{
Environment.FailFast("Unable to setup calling convention converter correctly");
}
return(result);
}
return(result);
}
}
case TypeSignatureKind.Modifier:
{
// Arrays, pointers and byref types signatures are treated as pointers, not requiring calling convention conversion.
// Just consume the parameter type from the stream and return false;
TypeSignatureHasVarsNeedingCallingConventionConverter(ref parser, moduleHandle, context, HasVarsInvestigationLevel.Ignore);
return(false);
}
case TypeSignatureKind.MultiDimArray:
{
// No need for a calling convention converter for this case. Just consume the signature from the stream.
TypeSignatureHasVarsNeedingCallingConventionConverter(ref parser, moduleHandle, context, HasVarsInvestigationLevel.Ignore);
uint boundCount = parser.GetUnsigned();
for (uint i = 0; i < boundCount; i++)
{
parser.GetUnsigned();
}
uint lowerBoundCount = parser.GetUnsigned();
for (uint i = 0; i < lowerBoundCount; i++)
{
parser.GetUnsigned();
}
}
return(false);
case TypeSignatureKind.FunctionPointer:
{
// No need for a calling convention converter for this case. Just consume the signature from the stream.
uint argCount = parser.GetUnsigned();
for (uint i = 0; i < argCount; i++)
{
TypeSignatureHasVarsNeedingCallingConventionConverter(ref parser, moduleHandle, context, HasVarsInvestigationLevel.Ignore);
}
}
return(false);
default:
parser.ThrowBadImageFormatException();
return(true);
}
}
/// <summary>
/// Get the virtual slot index of a given virtual method. (This is only valid for non-interface virtuals)
/// </summary>
/// <param name="virtualMethod">virtual method to get slot index of</param>
/// <returns>slot index, or -1</returns>
public static int VirtualMethodToSlotIndex(MethodDesc virtualMethod)
{
Debug.Assert(virtualMethod.IsVirtual);
Debug.Assert(!virtualMethod.OwningType.IsInterface);
MethodDesc definingMethod = virtualMethod;
// If not newslot, make sure we've got the defining method here
if (!definingMethod.IsNewSlot)
{
definingMethod = MetadataVirtualMethodAlgorithm.FindSlotDefiningMethodForVirtualMethod(definingMethod);
}
TypeDesc definingType = definingMethod.OwningType;
// Two possible cases for determining slot index that will work
// 1. The definingType is a R2R type with full metadata. Compute the MethodDesc, by scanning the list of virtuals present in metadata. Its possible to not get a slot index. In that case return -1
// 2. The definingType is pregenerated, but we can go from metadata to slot index via the runtime mapping tables.
if (!IsPregeneratedOrTemplateTypeLoaded(definingType))
{
// Case 1
MetadataType definingMetadataType = (MetadataType)definingType;
int baseTypeSlotCount = 0;
if (definingMetadataType.BaseType != null)
{
unsafe
{
if (definingMetadataType.BaseType.RetrieveRuntimeTypeHandleIfPossible())
{
baseTypeSlotCount = definingMetadataType.BaseType.GetRuntimeTypeHandle().ToEETypePtr()->NumVtableSlots;
}
else
{
baseTypeSlotCount = definingMetadataType.BaseType.GetOrCreateTypeBuilderState().NumVTableSlots;
}
}
}
int currentSlot = baseTypeSlotCount;
if (definingMetadataType.ConvertToCanonForm(CanonicalFormKind.Specific).IsCanonicalSubtype(CanonicalFormKind.Specific))
{
// Deal with the space reserved for the canonical dictionary
currentSlot++;
}
foreach (MethodDesc method in definingMetadataType.GetMethods())
{
if (!MethodDefinesVTableSlot(method))
{
continue;
}
if (method == definingMethod)
{
return(currentSlot);
}
else
{
currentSlot++;
}
}
// No slot index defined.
return(-1);
}
else
{
// Case 2, pregenerated type
TypeSystem.NativeFormat.NativeFormatMethod definingMethodOpenType = (TypeSystem.NativeFormat.NativeFormatMethod)definingMethod.GetTypicalMethodDefinition();
MethodSignatureComparer methodSignatureComparer = new MethodSignatureComparer(
definingMethodOpenType.MetadataReader, definingMethodOpenType.Handle);
if (!definingType.RetrieveRuntimeTypeHandleIfPossible())
{
new TypeBuilder().BuildType(definingType);
}
TypeSystem.NativeFormat.NativeFormatType definingNativeFormatType = (TypeSystem.NativeFormat.NativeFormatType)definingType.GetTypeDefinition();
NativeFormatModuleInfo moduleToLookIn = definingNativeFormatType.MetadataUnit.RuntimeModuleInfo;
TypeLoaderEnvironment.VirtualResolveDataResult virtualSlotInfo;
if (!TypeLoaderEnvironment.TryGetVirtualResolveData(moduleToLookIn, definingType.RuntimeTypeHandle, Array.Empty <RuntimeTypeHandle>(), ref methodSignatureComparer, out virtualSlotInfo))
{
return(-1);
}
Debug.Assert(!virtualSlotInfo.IsGVM);
return(virtualSlotInfo.SlotIndex);
}
}
private bool FindMatchingInterfaceSlot(NativeFormatModuleInfo module, NativeReader nativeLayoutReader, ref NativeParser entryParser, ref ExternalReferencesTable extRefs, ref RuntimeTypeHandle declaringType, ref MethodNameAndSignature methodNameAndSignature, RuntimeTypeHandle instanceTypeHandle, RuntimeTypeHandle openTargetTypeHandle, RuntimeTypeHandle[] targetTypeInstantiation, bool variantDispatch, bool defaultMethods)
{
uint numTargetImplementations = entryParser.GetUnsigned();
#if GVM_RESOLUTION_TRACE
Debug.WriteLine(" :: Declaring type = " + GetTypeNameDebug(declaringType));
Debug.WriteLine(" :: Target type = " + GetTypeNameDebug(openTargetTypeHandle));
#endif
for (uint j = 0; j < numTargetImplementations; j++)
{
uint nameAndSigToken = entryParser.GetUnsigned();
MethodNameAndSignature targetMethodNameAndSignature = null;
RuntimeTypeHandle targetTypeHandle = default;
bool isDefaultInterfaceMethodImplementation;
if (nameAndSigToken != SpecialGVMInterfaceEntry.Diamond && nameAndSigToken != SpecialGVMInterfaceEntry.Reabstraction)
{
targetMethodNameAndSignature = GetMethodNameAndSignatureFromNativeReader(nativeLayoutReader, module.Handle, nameAndSigToken);
targetTypeHandle = extRefs.GetRuntimeTypeHandleFromIndex(entryParser.GetUnsigned());
isDefaultInterfaceMethodImplementation = RuntimeAugments.IsInterface(targetTypeHandle);
#if GVM_RESOLUTION_TRACE
Debug.WriteLine(" Searching for GVM implementation on targe type = " + GetTypeNameDebug(targetTypeHandle));
#endif
}
else
{
isDefaultInterfaceMethodImplementation = true;
}
uint numIfaceImpls = entryParser.GetUnsigned();
for (uint k = 0; k < numIfaceImpls; k++)
{
RuntimeTypeHandle implementingTypeHandle = extRefs.GetRuntimeTypeHandleFromIndex(entryParser.GetUnsigned());
#if GVM_RESOLUTION_TRACE
Debug.WriteLine(" -> Current implementing type = " + GetTypeNameDebug(implementingTypeHandle));
#endif
uint numIfaceSigs = entryParser.GetUnsigned();
if (!openTargetTypeHandle.Equals(implementingTypeHandle) ||
defaultMethods != isDefaultInterfaceMethodImplementation)
{
// Skip over signatures data
for (uint l = 0; l < numIfaceSigs; l++)
{
entryParser.GetUnsigned();
}
continue;
}
for (uint l = 0; l < numIfaceSigs; l++)
{
RuntimeTypeHandle currentIfaceTypeHandle = default(RuntimeTypeHandle);
NativeParser ifaceSigParser = new NativeParser(nativeLayoutReader, entryParser.GetUnsigned());
if (TypeLoaderEnvironment.Instance.GetTypeFromSignatureAndContext(ref ifaceSigParser, module.Handle, targetTypeInstantiation, null, out currentIfaceTypeHandle))
{
#if GVM_RESOLUTION_TRACE
Debug.WriteLine(" -> Current interface on type = " + GetTypeNameDebug(currentIfaceTypeHandle));
#endif
Debug.Assert(!currentIfaceTypeHandle.IsNull());
if ((!variantDispatch && declaringType.Equals(currentIfaceTypeHandle)) ||
(variantDispatch && RuntimeAugments.IsAssignableFrom(declaringType, currentIfaceTypeHandle)))
{
#if GVM_RESOLUTION_TRACE
Debug.WriteLine(" " + (declaringType.Equals(currentIfaceTypeHandle) ? "Exact" : "Variant-compatible") + " match found on this target type!");
#endif
if (targetMethodNameAndSignature == null)
{
if (nameAndSigToken == SpecialGVMInterfaceEntry.Diamond)
{
throw new AmbiguousImplementationException();
}
else
{
Debug.Assert(nameAndSigToken == SpecialGVMInterfaceEntry.Reabstraction);
throw new EntryPointNotFoundException();
}
}
// We found the GVM slot target for the input interface GVM call, so let's update the interface GVM slot and return success to the caller
if (!RuntimeAugments.IsInterface(targetTypeHandle) || !RuntimeAugments.IsGenericTypeDefinition(targetTypeHandle))
{
// Not a default interface method or default interface method on a non-generic type.
// We have a usable type handle.
declaringType = targetTypeHandle;
}
else if (RuntimeAugments.IsGenericType(currentIfaceTypeHandle) && RuntimeAugments.GetGenericDefinition(currentIfaceTypeHandle).Equals(targetTypeHandle))
{
// Default interface method implemented on the same type that declared the slot.
// Use the instantiation as-is from what we found.
declaringType = currentIfaceTypeHandle;
}
else
{
declaringType = default;
// Default interface method implemented on a different generic interface.
// We need to find a usable instantiation. There should be only one match because we
// would be dealing with a diamond otherwise.
int numInstanceInterfaces = RuntimeAugments.GetInterfaceCount(instanceTypeHandle);
for (int instIntfIndex = 0; instIntfIndex < numInstanceInterfaces; instIntfIndex++)
{
RuntimeTypeHandle instIntf = RuntimeAugments.GetInterface(instanceTypeHandle, instIntfIndex);
if (RuntimeAugments.IsGenericType(instIntf) &&
RuntimeAugments.GetGenericDefinition(instIntf).Equals(targetTypeHandle))
{
// Got a potential interface. Check if the implementing interface is in the interface
// list. We don't want IsAssignableFrom because we need an exact match.
int numIntInterfaces = RuntimeAugments.GetInterfaceCount(instIntf);
for (int intIntfIndex = 0; intIntfIndex < numIntInterfaces; intIntfIndex++)
{
if (RuntimeAugments.GetInterface(instIntf, intIntfIndex).Equals(currentIfaceTypeHandle))
{
Debug.Assert(declaringType.IsNull());
declaringType = instIntf;
#if !DEBUG
break;
#endif
}
}
#if !DEBUG
if (!declaringType.IsNull())
{
break;
}
#endif
}
}
Debug.Assert(!declaringType.IsNull());
}
methodNameAndSignature = targetMethodNameAndSignature;
return(true);
}
}
}
}
}
return(false);
}
//
// Returns the native layout info reader
//
internal unsafe NativeReader GetNativeLayoutInfoReader(NativeFormatModuleInfo module)
{
return GetNativeLayoutInfoReader(module.Handle);
}
/// <summary>
/// Register all modules which were added (Registered) to the runtime and are not already registered with the TypeLoader.
/// </summary>
/// <param name="moduleType">Type to assign to all new modules.</param>
public void RegisterNewModules(ModuleType moduleType)
{
// prevent multiple threads from registering modules concurrently
using (LockHolder.Hold(_moduleRegistrationLock))
{
// Fetch modules that have already been registered with the runtime
int loadedModuleCount = RuntimeAugments.GetLoadedModules(null);
TypeManagerHandle[] loadedModuleHandles = new TypeManagerHandle[loadedModuleCount];
int loadedModuleCountUpdated = RuntimeAugments.GetLoadedModules(loadedModuleHandles);
Debug.Assert(loadedModuleCount == loadedModuleCountUpdated);
LowLevelList <TypeManagerHandle> newModuleHandles = new LowLevelList <TypeManagerHandle>(loadedModuleHandles.Length);
foreach (TypeManagerHandle moduleHandle in loadedModuleHandles)
{
// Skip already registered modules.
int oldModuleIndex;
if (_loadedModuleMap.HandleToModuleIndex.TryGetValue(moduleHandle, out oldModuleIndex))
{
continue;
}
newModuleHandles.Add(moduleHandle);
}
// Copy existing modules to new dictionary
int oldModuleCount = _loadedModuleMap.Modules.Length;
ModuleInfo[] updatedModules = new ModuleInfo[oldModuleCount + newModuleHandles.Count];
if (oldModuleCount > 0)
{
Array.Copy(_loadedModuleMap.Modules, 0, updatedModules, 0, oldModuleCount);
}
for (int newModuleIndex = 0; newModuleIndex < newModuleHandles.Count; newModuleIndex++)
{
ModuleInfo newModuleInfo;
unsafe
{
byte *pBlob;
uint cbBlob;
if (RuntimeAugments.FindBlob(newModuleHandles[newModuleIndex], (int)ReflectionMapBlob.EmbeddedMetadata, new IntPtr(&pBlob), new IntPtr(&cbBlob)))
{
newModuleInfo = new NativeFormatModuleInfo(newModuleHandles[newModuleIndex], moduleType, (IntPtr)pBlob, (int)cbBlob);
}
else
{
newModuleInfo = new ModuleInfo(newModuleHandles[newModuleIndex], moduleType);
}
}
updatedModules[oldModuleCount + newModuleIndex] = newModuleInfo;
if (_moduleRegistrationCallbacks != null)
{
_moduleRegistrationCallbacks(newModuleInfo);
}
}
// Atomically update the module map
_loadedModuleMap = new ModuleMap(updatedModules);
}
}
internal bool GetCallingConverterDataFromMethodSignature_NativeLayout_Common(
TypeSystemContext context,
RuntimeSignature methodSig,
Instantiation typeInstantiation,
Instantiation methodInstantiation,
out bool hasThis,
out TypeDesc[] parameters,
out bool[] parametersWithGenericDependentLayout,
NativeReader nativeReader,
ulong[] debuggerPreparedExternalReferences)
{
bool isNotDebuggerCall = debuggerPreparedExternalReferences == null;
hasThis = false;
parameters = null;
NativeLayoutInfoLoadContext nativeLayoutContext = new NativeLayoutInfoLoadContext();
nativeLayoutContext._module = isNotDebuggerCall ? (NativeFormatModuleInfo)methodSig.GetModuleInfo() : null;
nativeLayoutContext._typeSystemContext = context;
nativeLayoutContext._typeArgumentHandles = typeInstantiation;
nativeLayoutContext._methodArgumentHandles = methodInstantiation;
nativeLayoutContext._debuggerPreparedExternalReferences = debuggerPreparedExternalReferences;
NativeFormatModuleInfo module = null;
NativeReader reader = null;
if (isNotDebuggerCall)
{
reader = GetNativeLayoutInfoReader(methodSig);
module = ModuleList.Instance.GetModuleInfoByHandle(new TypeManagerHandle(methodSig.ModuleHandle));
}
else
{
reader = nativeReader;
}
NativeParser parser = new NativeParser(reader, methodSig.NativeLayoutOffset);
MethodCallingConvention callingConvention = (MethodCallingConvention)parser.GetUnsigned();
hasThis = !callingConvention.HasFlag(MethodCallingConvention.Static);
uint numGenArgs = callingConvention.HasFlag(MethodCallingConvention.Generic) ? parser.GetUnsigned() : 0;
uint parameterCount = parser.GetUnsigned();
parameters = new TypeDesc[parameterCount + 1];
parametersWithGenericDependentLayout = new bool[parameterCount + 1];
// One extra parameter to account for the return type
for (uint i = 0; i <= parameterCount; i++)
{
// NativeParser is a struct, so it can be copied.
NativeParser parserCopy = parser;
// Parse the signature twice. The first time to find out the exact type of the signature
// The second time to identify if the parameter loaded via the signature should be forced to be
// passed byref as part of the universal generic calling convention.
parameters[i] = GetConstructedTypeFromParserAndNativeLayoutContext(ref parser, nativeLayoutContext);
parametersWithGenericDependentLayout[i] = TypeSignatureHasVarsNeedingCallingConventionConverter(ref parserCopy, module, context, HasVarsInvestigationLevel.Parameter);
if (parameters[i] == null)
{
return(false);
}
}
return(true);
}
