tMD_MethodDef* MetaData_GetMethodDefFromDefRefOrSpec(tMetaData *pMetaData, IDX_TABLE token, tMD_TypeDef **ppClassTypeArgs, tMD_TypeDef **ppMethodTypeArgs) {
void *pTableEntry;
pTableEntry = MetaData_GetTableRow(pMetaData, token);
if (((tMDC_ToMethodDef*)pTableEntry)->pMethodDef != NULL) {
return ((tMDC_ToMethodDef*)pTableEntry)->pMethodDef;
}
switch (TABLE_ID(token)) {
case MD_TABLE_METHODDEF:
((tMDC_ToMethodDef*)pTableEntry)->pMethodDef = (tMD_MethodDef*)pTableEntry;
return (tMD_MethodDef*)pTableEntry;
case MD_TABLE_MEMBERREF:
{
tMD_MemberRef *pMemberRef;
pMemberRef = (tMD_MemberRef*)pTableEntry;
switch (TABLE_ID(pMemberRef->class_))
{
case MD_TABLE_TYPEREF:
case MD_TABLE_TYPESPEC:
{
tMD_TypeDef *pTypeDef;
tMD_MethodDef *pMethodDef;
pTypeDef = MetaData_GetTypeDefFromDefRefOrSpec(pMetaData, pMemberRef->class_, ppClassTypeArgs, ppMethodTypeArgs);
MetaData_Fill_TypeDef(pTypeDef, NULL, NULL);
pMethodDef = FindMethodInType(pTypeDef, pMemberRef->name, pMetaData, pMemberRef->signature, pTypeDef->ppClassTypeArgs, ppMethodTypeArgs);
//pMethodDef->pMethodDef = pMethodDef;
return pMethodDef;
}
default:
Crash("MetaData_GetMethodDefFromMethodDefOrRef(): Cannot handle pMemberRef->class_=0x%08x", pMemberRef->class_);
}
}
case MD_TABLE_METHODSPEC:
{
tMD_MethodSpec *pMethodSpec;
tMD_MethodDef *pMethodDef;
pMethodSpec = (tMD_MethodSpec*)pTableEntry;
pMethodDef = Generics_GetMethodDefFromSpec(pMethodSpec, ppClassTypeArgs, ppMethodTypeArgs);
// Note: Cannot cache the MethodDef from the MethodSpec, as class generic arguments
// may be different.
return pMethodDef;
}
}
Crash("MetaData_GetMethodDefFromMethodDefOrRef(): Cannot handle token: 0x%08x", token);
FAKE_RETURN;
}
tMD_FieldDef* MetaData_GetFieldDefFromDefOrRef(tMetaData *pMetaData, IDX_TABLE token, tMD_TypeDef **ppClassTypeArgs, tMD_TypeDef **ppMethodTypeArgs) {
void *pTableEntry;
pTableEntry = MetaData_GetTableRow(pMetaData, token);
if (((tMDC_ToFieldDef*)pTableEntry)->pFieldDef != NULL) {
return ((tMDC_ToFieldDef*)pTableEntry)->pFieldDef;
}
switch (TABLE_ID(token)) {
case MD_TABLE_FIELDDEF:
((tMDC_ToFieldDef*)pTableEntry)->pFieldDef = (tMD_FieldDef*)pTableEntry;
return (tMD_FieldDef*)pTableEntry;
case MD_TABLE_MEMBERREF:
{
tMD_MemberRef *pMemberRef;
pMemberRef = (tMD_MemberRef*)pTableEntry;
switch (TABLE_ID(pMemberRef->class_))
{
case MD_TABLE_TYPEREF:
case MD_TABLE_TYPESPEC:
{
tMD_TypeDef *pTypeDef;
tMD_FieldDef *pFieldDef;
pTypeDef = MetaData_GetTypeDefFromDefRefOrSpec(pMetaData, pMemberRef->class_, ppClassTypeArgs, ppMethodTypeArgs);
pFieldDef = FindFieldInType(pTypeDef, pMemberRef->name);
if (TABLE_ID(pMemberRef->class_) == MD_TABLE_TYPEREF) {
// Can't do this for TypeSpec because the resulting TypeDef will change
// depending on what the class type arguments are.
((tMDC_ToFieldDef*)pTableEntry)->pFieldDef = pFieldDef;
}
return pFieldDef;
}
default:
Crash("MetaData_GetMethodDefFromMethodDefOrRef(): Cannot handle pMemberRef->class_=0x%08x", pMemberRef->class_);
}
}
}
Crash("MetaData_GetFieldDefFromDefOrRef(): Cannot handle token: 0x%08x", token);
FAKE_RETURN;
}
U32 Type_IsValueType(tMD_TypeDef *pTypeDef) {
// If this type is an interface, then return 0
if (TYPE_ISINTERFACE(pTypeDef)) {
return 0;
}
// If this type is Object or ValueType then return an answer
if (strcmp(pTypeDef->nameSpace, "System") == 0) {
if (strcmp(pTypeDef->name, "ValueType") == 0) {
return 1;
}
if (strcmp(pTypeDef->name, "Object") == 0) {
return 0;
}
}
// Return the isValueType determined by parent type
pTypeDef = MetaData_GetTypeDefFromDefRefOrSpec(pTypeDef->pMetaData, pTypeDef->extends, NULL, NULL);
MetaData_Fill_TypeDef(pTypeDef, NULL, NULL);
return pTypeDef->isValueType;
}
tMetaData* MetaData_GetResolutionScopeMetaData(tMetaData *pMetaData, IDX_TABLE resolutionScopeToken, tMD_TypeDef **ppInNestedType) {
switch (TABLE_ID(resolutionScopeToken)) {
case MD_TABLE_ASSEMBLYREF:
{
tMD_AssemblyRef *pAssemblyRef;
pAssemblyRef = (tMD_AssemblyRef*)MetaData_GetTableRow(pMetaData, resolutionScopeToken);
*ppInNestedType = NULL;
return CLIFile_GetMetaDataForAssembly(pAssemblyRef->name);
}
case MD_TABLE_TYPEREF:
{
tMD_TypeDef *pTypeDef;
pTypeDef = MetaData_GetTypeDefFromDefRefOrSpec(pMetaData, resolutionScopeToken, NULL, NULL);
*ppInNestedType = pTypeDef;
return pTypeDef->pMetaData;
}
default:
Crash("MetaData_GetResolutionScopeMetaData(): Cannot resolve token: 0x%08x", resolutionScopeToken);
FAKE_RETURN;
}
}
// Return pointer to the relevant Def structure.
// pObjectType returns:
// 0 - tMD_TypeDef
// 1 - tMD_MethodDef
// 2 - tMD_FieldDef
// (These link up with the JIT_LOADTOKEN_* opcodes)
PTR MetaData_GetTypeMethodField(tMetaData *pMetaData, IDX_TABLE token, U32 *pObjectType, tMD_TypeDef **ppClassTypeArgs, tMD_TypeDef **ppMethodTypeArgs) {
switch (TABLE_ID(token)) {
case MD_TABLE_TYPEDEF:
case MD_TABLE_TYPEREF:
case MD_TABLE_TYPESPEC:
{
tMD_TypeDef *pTypeDef;
pTypeDef = MetaData_GetTypeDefFromDefRefOrSpec(pMetaData, token, ppClassTypeArgs, ppMethodTypeArgs);
MetaData_Fill_TypeDef(pTypeDef, NULL, NULL);
*pObjectType = 0;
return (PTR)pTypeDef;
}
case MD_TABLE_METHODDEF:
method:
{
tMD_MethodDef *pMethodDef;
pMethodDef = MetaData_GetMethodDefFromDefRefOrSpec(pMetaData, token, ppClassTypeArgs, ppMethodTypeArgs);
if (pMethodDef->isFilled == 0) {
tMD_TypeDef *pTypeDef;
pTypeDef = MetaData_GetTypeDefFromMethodDef(pMethodDef);
MetaData_Fill_TypeDef(pTypeDef, NULL, NULL);
}
*pObjectType = 1;
return (PTR)pMethodDef;
}
case MD_TABLE_FIELDDEF:
field:
{
tMD_FieldDef *pFieldDef;
pFieldDef = MetaData_GetFieldDefFromDefOrRef(pMetaData, token, ppClassTypeArgs, ppMethodTypeArgs);
if (pFieldDef->pParentType == NULL) {
tMD_TypeDef *pTypeDef;
pTypeDef = MetaData_GetTypeDefFromFieldDef(pFieldDef);
MetaData_Fill_TypeDef(pTypeDef, NULL, NULL);
}
*pObjectType = 2;
return (PTR)pFieldDef;
}
case MD_TABLE_MEMBERREF:
{
tMD_MemberRef *pMemberRef;
SIG sig;
pMemberRef = (tMD_MemberRef*)MetaData_GetTableRow(pMetaData, token);
sig = MetaData_GetBlob(pMemberRef->signature, NULL);
if (*(U8*)sig == 0x06) {
// Field
goto field;
} else {
// Method
goto method;
}
}
}
Crash("MetaData_GetTypeMethodField(): Cannot handle token: 0x%08x", token);
FAKE_RETURN;
}
void MetaData_Fill_TypeDef_(tMD_TypeDef *pTypeDef, tMD_TypeDef **ppClassTypeArgs, tMD_TypeDef **ppMethodTypeArgs)
{
IDX_TABLE firstIdx, lastIdx, token;
U32 instanceMemSize, staticMemSize, virtualOfs, i, j;
tMetaData *pMetaData;
tMD_TypeDef *pParent;
pMetaData = pTypeDef->pMetaData;
pTypeDef->isFilled = 1;
pTypeDef->pTypeDef = pTypeDef;
pTypeDef->pParent = MetaData_GetTypeDefFromDefRefOrSpec(pMetaData, pTypeDef->extends, ppClassTypeArgs, ppMethodTypeArgs);
pParent = pTypeDef->pParent;
if (pParent != NULL)
{
MetaData_Fill_TypeDef(pParent, NULL, NULL);
virtualOfs = pParent->numVirtualMethods;
}
else
{
virtualOfs = 0;
}
pTypeDef->isValueType = (U8)Type_IsValueType(pTypeDef);
// If not primed, then work out how many methods & fields there are.
if (!pTypeDef->isPrimed)
{
// Methods
lastIdx = (pTypeDef->isLast)?
MAKE_TABLE_INDEX(MD_TABLE_METHODDEF, pTypeDef->pMetaData->tables.numRows[MD_TABLE_METHODDEF]):
(pTypeDef[1].methodList - 1);
pTypeDef->numMethods = lastIdx - pTypeDef->methodList + 1;
// Fields
lastIdx = (pTypeDef->isLast)?
MAKE_TABLE_INDEX(MD_TABLE_FIELDDEF, pTypeDef->pMetaData->tables.numRows[MD_TABLE_FIELDDEF]):
(pTypeDef[1].fieldList - 1);
pTypeDef->numFields = lastIdx - pTypeDef->fieldList + 1;
}
// Must create the virtual method table BEFORE any other type resolution is done
// Note that this must not do ANY filling of types or methods.
// This is to ensure that the parent object(s) in any type inheritance hierachy are allocated
// their virtual method offset before derived types.
firstIdx = pTypeDef->methodList;
lastIdx = firstIdx + pTypeDef->numMethods - 1;
// This only needs to be done for non-generic types, or for generic types that are not a definition
// I.e. Fully instantiated generic types
if (!pTypeDef->isGenericDefinition)
{
for (token = firstIdx; token <= lastIdx; token++)
{
tMD_MethodDef *pMethodDef;
pMethodDef = MetaData_GetMethodDefFromDefRefOrSpec(pMetaData, token, ppClassTypeArgs, ppMethodTypeArgs);
// This is needed, so array resolution can work correctly and FindVirtualOverriddenMethod() can work.
pMethodDef->pParentType = pTypeDef;
if (METHOD_ISVIRTUAL(pMethodDef))
{
if (METHOD_ISNEWSLOT(pMethodDef) || pTypeDef->pParent == NULL)
{
// Allocate a new vTable slot if method is explicitly marked as NewSlot, or
// this is of type Object.
pMethodDef->vTableOfs = virtualOfs++;
}
else
{
tMD_MethodDef *pVirtualOveriddenMethod;
pVirtualOveriddenMethod = FindVirtualOverriddenMethod(pTypeDef->pParent, pMethodDef);
Assert(pVirtualOveriddenMethod != NULL);
pMethodDef->vTableOfs = pVirtualOveriddenMethod->vTableOfs;
}
}
else
{
// Dummy value - make it obvious it's not valid!
pMethodDef->vTableOfs = 0xffffffff;
}
}
// Create the virtual method table
pTypeDef->numVirtualMethods = virtualOfs;
// Resolve fields, members, interfaces.
// Only needs to be done if it's not a generic definition type
// It it's not a value-type and the stack-size is not preset, then set it up now.
// It needs to be done here as non-static fields in non-value types can point to the containing type
if (pTypeDef->stackSize == 0 && !pTypeDef->isValueType)
{
pTypeDef->stackType = EVALSTACK_O;
pTypeDef->stackSize = sizeof(void*);
}
// Resolve all fields - instance ONLY at this point,
// because static fields in value-types can be of the containing type, and the size is not yet known.
firstIdx = pTypeDef->fieldList;
lastIdx = firstIdx + pTypeDef->numFields - 1;
staticMemSize = 0;
if (pTypeDef->numFields > 0)
{
pTypeDef->ppFields = mallocForever(pTypeDef->numFields * sizeof(tMD_FieldDef*));
}
instanceMemSize = (pTypeDef->pParent == NULL)?0:pTypeDef->pParent->instanceMemSize;
for (token = firstIdx, i=0; token <= lastIdx; token++, i++)
{
tMD_FieldDef *pFieldDef;
pFieldDef = MetaData_GetFieldDefFromDefOrRef(pMetaData, token, ppClassTypeArgs, ppMethodTypeArgs);
if (!FIELD_ISSTATIC(pFieldDef))
{
// Only handle non-static fields at the moment
if (pTypeDef->pGenericDefinition != NULL)
{
// If this is a generic instantiation type, then all field defs need to be copied,
// as there will be lots of different instantiations.
tMD_FieldDef *pFieldCopy = TMALLOCFOREVER(tMD_FieldDef);
memcpy(pFieldCopy, pFieldDef, sizeof(tMD_FieldDef));
pFieldDef = pFieldCopy;
}
if (FIELD_ISLITERAL(pFieldDef) || FIELD_HASFIELDRVA(pFieldDef))
{
// If it's a literal, then analyse the field, but don't include it in any memory allocation
// If is has an RVA, then analyse the field, but don't include it in any memory allocation
MetaData_Fill_FieldDef(pTypeDef, pFieldDef, 0, ppClassTypeArgs);
}
else
{
MetaData_Fill_FieldDef(pTypeDef, pFieldDef, instanceMemSize, ppClassTypeArgs);
instanceMemSize += pFieldDef->memSize;
}
pTypeDef->ppFields[i] = pFieldDef;
}
}
if (pTypeDef->instanceMemSize == 0)
{
pTypeDef->instanceMemSize = instanceMemSize;
}
// Sort out stack type and size.
// Note that this may already be set, as some basic types have this preset;
// or if it's not a value-type it'll already be set
if (pTypeDef->stackSize == 0)
{
// if it gets here then it must be a value type
pTypeDef->stackType = EVALSTACK_VALUETYPE;
pTypeDef->stackSize = pTypeDef->instanceMemSize;
}
// Sort out array element size. Note that some basic types will have this preset.
if (pTypeDef->arrayElementSize == 0)
{
pTypeDef->arrayElementSize = pTypeDef->stackSize;
}
// Handle static fields
for (token = firstIdx, i=0; token <= lastIdx; token++, i++)
{
tMD_FieldDef *pFieldDef;
pFieldDef = MetaData_GetFieldDefFromDefOrRef(pMetaData, token, ppClassTypeArgs, ppMethodTypeArgs);
if (FIELD_ISSTATIC(pFieldDef))
{
// Only handle static fields here
if (pTypeDef->pGenericDefinition != NULL)
{
// If this is a generic instantiation type, then all field defs need to be copied,
// as there will be lots of different instantiations.
tMD_FieldDef *pFieldCopy = TMALLOCFOREVER(tMD_FieldDef);
memcpy(pFieldCopy, pFieldDef, sizeof(tMD_FieldDef));
pFieldDef = pFieldCopy;
}
if (FIELD_ISLITERAL(pFieldDef) || FIELD_HASFIELDRVA(pFieldDef))
{
// If it's a literal, then analyse the field, but don't include it in any memory allocation
// If is has an RVA, then analyse the field, but don't include it in any memory allocation
MetaData_Fill_FieldDef(pTypeDef, pFieldDef, 0, ppClassTypeArgs);
}
else
{
MetaData_Fill_FieldDef(pTypeDef, pFieldDef, staticMemSize, ppClassTypeArgs);
staticMemSize += pFieldDef->memSize;
}
pTypeDef->ppFields[i] = pFieldDef;
}
}
if (staticMemSize > 0) {
pTypeDef->pStaticFields = mallocForever(staticMemSize);
memset(pTypeDef->pStaticFields, 0, staticMemSize);
// Set the field addresses (->pMemory) of all static fields
for (i = 0; i<pTypeDef->numFields; i++) {
tMD_FieldDef *pFieldDef;
pFieldDef = pTypeDef->ppFields[i];
if (FIELD_ISSTATIC(pFieldDef) && pFieldDef->pMemory == NULL) {
// Only set it if it isn't already set. It will be already set if this field has an RVA
pFieldDef->pMemory = pTypeDef->pStaticFields + pFieldDef->memOffset;
}
}
pTypeDef->staticFieldSize = staticMemSize;
}
// Resolve all members
firstIdx = pTypeDef->methodList;
lastIdx = firstIdx + pTypeDef->numMethods - 1;
pTypeDef->ppMethods = mallocForever(pTypeDef->numMethods * sizeof(tMD_MethodDef*));
pTypeDef->pVTable = mallocForever(pTypeDef->numVirtualMethods * sizeof(tMD_MethodDef*));
// Copy initial vTable from parent
if (pTypeDef->pParent != NULL) {
memcpy(pTypeDef->pVTable, pTypeDef->pParent->pVTable, pTypeDef->pParent->numVirtualMethods * sizeof(tMD_MethodDef*));
}
for (token = firstIdx, i = 0; token <= lastIdx; token++, i++) {
tMD_MethodDef *pMethodDef;
pMethodDef = MetaData_GetMethodDefFromDefRefOrSpec(pMetaData, token, ppClassTypeArgs, ppMethodTypeArgs);
if (pTypeDef->pGenericDefinition != NULL) {
// If this is a generic instantiation type, then all method defs need to be copied,
// as there will be lots of different instantiations.
tMD_MethodDef *pMethodCopy = TMALLOCFOREVER(tMD_MethodDef);
memcpy(pMethodCopy, pMethodDef, sizeof(tMD_MethodDef));
pMethodDef = pMethodCopy;
}
if (METHOD_ISSTATIC(pMethodDef) && strcmp(pMethodDef->name, ".cctor") == 0) {
// This is a static constructor
pTypeDef->pStaticConstructor = pMethodDef;
}
if (!METHOD_ISSTATIC(pMethodDef) && pTypeDef->pParent != NULL &&
strcmp(pMethodDef->name, "Finalize") == 0) {
// This is a Finalizer method, but not for Object.
// Delibrately miss out Object's Finalizer because it's empty and will cause every object
// of any type to have a Finalizer which will be terrible for performance.
pTypeDef->pFinalizer = pMethodDef;
}
if (METHOD_ISVIRTUAL(pMethodDef)) {
// This is a virtual method, so enter it in the vTable
pTypeDef->pVTable[pMethodDef->vTableOfs] = pMethodDef;
}
pTypeDef->ppMethods[i] = pMethodDef;
}
// Find inherited Finalizer, if this type doesn't have an explicit Finalizer, and if there is one
if (pTypeDef->pFinalizer == NULL) {
tMD_TypeDef *pInheritedType = pTypeDef->pParent;
while (pInheritedType != NULL) {
if (pInheritedType->pFinalizer != NULL) {
pTypeDef->pFinalizer = pInheritedType->pFinalizer;
break;
}
pInheritedType = pInheritedType->pParent;
}
}
// Fill all method definitions for this type
for (i=0; i<pTypeDef->numMethods; i++) {
MetaData_Fill_MethodDef(pTypeDef, pTypeDef->ppMethods[i], ppClassTypeArgs, ppMethodTypeArgs);
}
// Map all interface method calls. This only needs to be done for Classes, not Interfaces
// And is not done for generic definitions.
if (!TYPE_ISINTERFACE(pTypeDef)) {
firstIdx = 0;
if (pTypeDef->pParent != NULL) {
j = pTypeDef->numInterfaces = pTypeDef->pParent->numInterfaces;
} else {
j = 0;
}
// TODO: Better to do this once during file load (the bit in this for loop)
for (i=1; i<=pMetaData->tables.numRows[MD_TABLE_INTERFACEIMPL]; i++) {
tMD_InterfaceImpl *pInterfaceImpl;
pInterfaceImpl = (tMD_InterfaceImpl*)MetaData_GetTableRow(pMetaData, MAKE_TABLE_INDEX(MD_TABLE_INTERFACEIMPL, i));
if (pInterfaceImpl->class_ == pTypeDef->tableIndex) {
// count how many interfaces are implemented
pTypeDef->numInterfaces++;
if (firstIdx == 0) {
firstIdx = MAKE_TABLE_INDEX(MD_TABLE_INTERFACEIMPL, i);
}
lastIdx = MAKE_TABLE_INDEX(MD_TABLE_INTERFACEIMPL, i);
}
}
if (pTypeDef->numInterfaces > 0 && !pTypeDef->isGenericDefinition) {
U32 mapNum;
pTypeDef->pInterfaceMaps = (tInterfaceMap*)mallocForever(pTypeDef->numInterfaces * sizeof(tInterfaceMap));
// Copy interface maps from parent type
if (j > 0) {
memcpy(pTypeDef->pInterfaceMaps, pTypeDef->pParent->pInterfaceMaps, j * sizeof(tInterfaceMap));
}
mapNum = j;
if (firstIdx > 0) {
for (token=firstIdx; token<=lastIdx; token++, mapNum++) {
tMD_InterfaceImpl *pInterfaceImpl;
pInterfaceImpl = (tMD_InterfaceImpl*)MetaData_GetTableRow(pMetaData, token);
if (pInterfaceImpl->class_ == pTypeDef->tableIndex) {
tMD_TypeDef *pInterface;
tInterfaceMap *pMap;
// Get the interface that this type implements
pInterface = MetaData_GetTypeDefFromDefRefOrSpec(pMetaData, pInterfaceImpl->interface_, ppClassTypeArgs, ppMethodTypeArgs);
MetaData_Fill_TypeDef(pInterface, NULL, NULL);
pMap = &pTypeDef->pInterfaceMaps[mapNum];
pMap->pInterface = pInterface;
pMap->pVTableLookup = (U32*)mallocForever(pInterface->numVirtualMethods * sizeof(U32));
pMap->ppMethodVLookup = NULL;
// Discover interface mapping for each interface method
for (i=0; i<pInterface->numVirtualMethods; i++) {
tMD_MethodDef *pInterfaceMethod, *pOverriddenMethod;
pInterfaceMethod = pInterface->pVTable[i];
pOverriddenMethod = FindVirtualOverriddenMethod(pTypeDef, pInterfaceMethod);
Assert(pOverriddenMethod != NULL);
pMap->pVTableLookup[i] = pOverriddenMethod->vTableOfs;
}
} else {
Crash("Problem with interface class");
}
}
}
}
}
// If this is an enum type, then pretend its stack type is its underlying type
if (pTypeDef->pParent == types[TYPE_SYSTEM_ENUM]) {
pTypeDef->stackType = EVALSTACK_INT32;
}
}
// If this is a nested type, then find the namespace of it
if (pTypeDef->pNestedIn != NULL) {
tMD_TypeDef *pRootTypeDef = pTypeDef->pNestedIn;
while (pRootTypeDef->pNestedIn != NULL) {
pRootTypeDef = pRootTypeDef->pNestedIn;
}
pTypeDef->nameSpace = pRootTypeDef->nameSpace;
}
log_f(2, "Type: %s.%s\n", pTypeDef->nameSpace, pTypeDef->name);
}
// Get the TypeDef from the type signature
// Also get the size of a field from the signature
// This is needed to avoid recursive sizing of types like System.Boolean,
// that has a field of type System.Boolean
tMD_TypeDef* Type_GetTypeFromSig(tMetaData *pMetaData, SIG *pSig, tMD_TypeDef **ppClassTypeArgs, tMD_TypeDef **ppMethodTypeArgs) {
U32 entry;
entry = MetaData_DecodeSigEntry(pSig);
switch (entry) {
case ELEMENT_TYPE_VOID:
return NULL;
case ELEMENT_TYPE_BOOLEAN:
return types[TYPE_SYSTEM_BOOLEAN];
case ELEMENT_TYPE_CHAR:
return types[TYPE_SYSTEM_CHAR];
case ELEMENT_TYPE_I1:
return types[TYPE_SYSTEM_SBYTE];
case ELEMENT_TYPE_U1:
return types[TYPE_SYSTEM_BYTE];
case ELEMENT_TYPE_I2:
return types[TYPE_SYSTEM_INT16];
case ELEMENT_TYPE_U2:
return types[TYPE_SYSTEM_UINT16];
case ELEMENT_TYPE_I4:
return types[TYPE_SYSTEM_INT32];
case ELEMENT_TYPE_I8:
return types[TYPE_SYSTEM_INT64];
case ELEMENT_TYPE_U8:
return types[TYPE_SYSTEM_UINT64];
case ELEMENT_TYPE_U4:
return types[TYPE_SYSTEM_UINT32];
case ELEMENT_TYPE_R4:
return types[TYPE_SYSTEM_SINGLE];
case ELEMENT_TYPE_R8:
return types[TYPE_SYSTEM_DOUBLE];
case ELEMENT_TYPE_STRING:
return types[TYPE_SYSTEM_STRING];
case ELEMENT_TYPE_PTR:
return types[TYPE_SYSTEM_UINTPTR];
case ELEMENT_TYPE_BYREF:
{
tMD_TypeDef *pByRefType;
// type of the by-ref parameter, don't care
pByRefType = Type_GetTypeFromSig(pMetaData, pSig, ppClassTypeArgs, ppMethodTypeArgs);
}
// fall-through
case ELEMENT_TYPE_INTPTR:
return types[TYPE_SYSTEM_INTPTR];
case ELEMENT_TYPE_VALUETYPE:
case ELEMENT_TYPE_CLASS:
entry = MetaData_DecodeSigEntryToken(pSig);
return MetaData_GetTypeDefFromDefRefOrSpec(pMetaData, entry, ppClassTypeArgs, ppMethodTypeArgs);
case ELEMENT_TYPE_VAR:
entry = MetaData_DecodeSigEntry(pSig); // This is the argument number
if (ppClassTypeArgs == NULL) {
// Return null here as we don't yet know what the type really is.
// The generic instantiation code figures this out later.
return NULL;
} else {
return ppClassTypeArgs[entry];
}
case ELEMENT_TYPE_GENERICINST:
{
tMD_TypeDef *pType;
pType = Generics_GetGenericTypeFromSig(pMetaData, pSig, ppClassTypeArgs, ppMethodTypeArgs);
return pType;
}
//case ELEMENT_TYPE_INTPTR:
// return types[TYPE_SYSTEM_INTPTR];
case ELEMENT_TYPE_UINTPTR:
return types[TYPE_SYSTEM_UINTPTR];
case ELEMENT_TYPE_OBJECT:
return types[TYPE_SYSTEM_OBJECT];
case ELEMENT_TYPE_SZARRAY:
{
tMD_TypeDef *pElementType;
pElementType = Type_GetTypeFromSig(pMetaData, pSig, ppClassTypeArgs, ppMethodTypeArgs);
return Type_GetArrayTypeDef(pElementType, ppClassTypeArgs, ppMethodTypeArgs);
}
case ELEMENT_TYPE_MVAR:
entry = MetaData_DecodeSigEntry(pSig); // This is the argument number
if (ppMethodTypeArgs == NULL) {
// Can't do anything sensible, as we don't have any type args
return NULL;
} else {
return ppMethodTypeArgs[entry];
}
default:
Crash("Type_GetTypeFromSig(): Cannot handle signature element type: 0x%02x", entry);
FAKE_RETURN;
}
}
