Constraints constraints;
Location loc;
GenericTypeParameterBuilder type;
+ MemberCache member_cache;
public TypeParameter (DeclSpace parent, DeclSpace decl, string name,
Constraints constraints, Attributes attrs, Location loc)
get { return constraints; }
}
- public bool HasConstructorConstraint {
- get { return constraints != null && constraints.HasConstructorConstraint; }
- }
-
public DeclSpace DeclSpace {
get { return decl; }
}
}
MemberCache IMemberContainer.BaseCache {
- get { return null; }
+ get {
+ if (gc == null)
+ return null;
+
+ if (gc.EffectiveBaseClass.BaseType == null)
+ return null;
+
+ return TypeManager.LookupMemberCache (gc.EffectiveBaseClass.BaseType);
+ }
}
bool IMemberContainer.IsInterface {
- get { return true; }
+ get { return false; }
}
MemberList IMemberContainer.GetMembers (MemberTypes mt, BindingFlags bf)
return FindMembers (mt, bf, null, null);
}
- MemberCache IMemberContainer.MemberCache {
- get { return null; }
+ public MemberCache MemberCache {
+ get {
+ if (member_cache != null)
+ return member_cache;
+
+ if (gc == null)
+ return null;
+
+ Type[] ifaces = TypeManager.ExpandInterfaces (gc.InterfaceConstraints);
+ member_cache = new MemberCache (this, gc.EffectiveBaseClass, ifaces);
+
+ return member_cache;
+ }
}
public MemberList FindMembers (MemberTypes mt, BindingFlags bf,
MemberFilter filter, object criteria)
{
- if (constraints == null)
+ if (gc == null)
return MemberList.Empty;
ArrayList members = new ArrayList ();
bool has_class_constr = false;
if (list.Count > 0) {
Type first = (Type) list [0];
- has_class_constr = !first.IsInterface && !first.IsGenericParameter;
+ has_class_constr = !first.IsGenericParameter && !first.IsInterface;
}
if ((list.Count > 0) && has_class_constr) {
this.Location = loc;
}
+ public TypeArguments (Location loc, params Expression[] types)
+ {
+ this.Location = loc;
+ this.args = new ArrayList (types);
+ }
+
public TypeArguments (int dimension, Location loc)
{
this.dimension = dimension;
ok = false;
continue;
}
- if (te is TypeParameterExpr)
- has_type_args = true;
-#if !MS_COMPATIBLE
+ atypes[i] = te.Type;
+ if (te.Type.IsGenericParameter) {
+ if (te is TypeParameterExpr)
+ has_type_args = true;
+ continue;
+ }
+
if (te.Type.IsSealed && te.Type.IsAbstract) {
Report.Error (718, Location, "`{0}': static classes cannot be used as generic arguments",
te.GetSignatureForError ());
return false;
}
-#endif
+
if (te.Type.IsPointer) {
Report.Error (306, Location, "The type `{0}' may not be used " +
"as a type argument", TypeManager.CSharpName (te.Type));
Expression.Error_VoidInvalidInTheContext (Location);
return false;
}
-
- atypes [i] = te.Type;
}
return ok;
}
+
+ public TypeArguments Clone ()
+ {
+ TypeArguments copy = new TypeArguments (Location);
+ foreach (Expression ta in args)
+ copy.args.Add (ta);
+
+ return copy;
+ }
}
public class TypeParameterName : SimpleName
if (TypeManager.IsBuiltinType (atype) || atype.IsValueType)
return true;
- if (HasDefaultConstructor (ec.DeclContainer.TypeBuilder, atype))
+ if (HasDefaultConstructor (atype))
return true;
Report_SymbolRelatedToPreviousError ();
return false;
}
- bool HasDefaultConstructor (Type containerType, Type atype)
+ bool HasDefaultConstructor (Type atype)
{
if (atype.IsAbstract)
return false;
}
TypeParameter tparam = TypeManager.LookupTypeParameter (atype);
- if (tparam != null)
- return tparam.HasConstructorConstraint;
+ if (tparam != null) {
+ if (tparam.GenericConstraints == null)
+ return false;
+ else
+ return tparam.GenericConstraints.HasConstructorConstraint;
+ }
MemberList list = TypeManager.FindMembers (
atype, MemberTypes.Constructor,
Error_ParameterNameCollision (p.Location, type_argument_name, "method parameter");
return false;
}
+
+ // FIXME: This is wrong, since it only looks at the outermost set of variables
if (block != null) {
- LocalInfo li = (LocalInfo)block.Variables[type_argument_name];
+ LocalInfo li = (LocalInfo)block.Variables [type_argument_name];
if (li != null) {
Error_ParameterNameCollision (li.Location, type_argument_name, "local variable");
return false;
static void InitGenericCodeHelpers ()
{
// Activator
- Type [] type_arg = { type_type };
activator_create_instance = GetMethod (
- activator_type, "CreateInstance", type_arg);
+ activator_type, "CreateInstance", Type.EmptyTypes);
}
static Type CoreLookupType (string ns, string name, int arity)
/// Check whether `a' and `b' may become equal generic types.
/// The algorithm to do that is a little bit complicated.
/// </summary>
- public static bool MayBecomeEqualGenericTypes (Type a, Type b, Type[] class_infered,
- Type[] method_infered)
+ public static bool MayBecomeEqualGenericTypes (Type a, Type b, Type[] class_inferred,
+ Type[] method_inferred)
{
if (a.IsGenericParameter) {
//
//
if (b.IsGenericParameter || !b.IsGenericType) {
int pos = a.GenericParameterPosition;
- Type[] args = a.DeclaringMethod != null ? method_infered : class_infered;
+ Type[] args = a.DeclaringMethod != null ? method_inferred : class_inferred;
if (args [pos] == null) {
args [pos] = b;
return true;
}
if (b.IsGenericParameter)
- return MayBecomeEqualGenericTypes (b, a, class_infered, method_infered);
+ return MayBecomeEqualGenericTypes (b, a, class_inferred, method_inferred);
//
// At this point, neither a nor b are a type parameter.
//
if (a.IsGenericType || b.IsGenericType)
- return MayBecomeEqualGenericInstances (a, b, class_infered, method_infered);
+ return MayBecomeEqualGenericInstances (a, b, class_inferred, method_inferred);
//
// If both of them are arrays.
a = a.GetElementType ();
b = b.GetElementType ();
- return MayBecomeEqualGenericTypes (a, b, class_infered, method_infered);
+ return MayBecomeEqualGenericTypes (a, b, class_inferred, method_inferred);
}
//
// particular instantiation (26.3.1).
//
public static bool MayBecomeEqualGenericInstances (Type a, Type b,
- Type[] class_infered,
- Type[] method_infered)
+ Type[] class_inferred,
+ Type[] method_inferred)
{
if (!a.IsGenericType || !b.IsGenericType)
return false;
return false;
return MayBecomeEqualGenericInstances (
- GetTypeArguments (a), GetTypeArguments (b), class_infered, method_infered);
+ GetTypeArguments (a), GetTypeArguments (b), class_inferred, method_inferred);
}
public static bool MayBecomeEqualGenericInstances (Type[] aargs, Type[] bargs,
- Type[] class_infered,
- Type[] method_infered)
+ Type[] class_inferred,
+ Type[] method_inferred)
{
if (aargs.Length != bargs.Length)
return false;
for (int i = 0; i < aargs.Length; i++) {
- if (!MayBecomeEqualGenericTypes (aargs [i], bargs [i], class_infered, method_infered))
+ if (!MayBecomeEqualGenericTypes (aargs [i], bargs [i], class_inferred, method_inferred))
return false;
}
return true;
}
- //
- // Type inference.
- //
-
- static bool InferType (Type pt, Type at, Type[] infered)
+ static bool UnifyType (Type pt, Type at, Type[] inferred)
{
if (pt.IsGenericParameter) {
if (pt.DeclaringMethod == null)
int pos = pt.GenericParameterPosition;
- if (infered [pos] == null) {
- infered [pos] = at;
- return true;
- }
-
- if (infered [pos] != at)
- return false;
+ if (inferred [pos] == null)
+ inferred [pos] = at;
- return true;
+ return inferred [pos] == at;
}
if (!pt.ContainsGenericParameters) {
if (at.ContainsGenericParameters)
- return InferType (at, pt, infered);
+ return UnifyType (at, pt, inferred);
else
return true;
}
if (at.GetArrayRank () != pt.GetArrayRank ())
return false;
- return InferType (pt.GetElementType (), at.GetElementType (), infered);
+ return UnifyType (pt.GetElementType (), at.GetElementType (), inferred);
}
if (!pt.IsGenericType)
return false;
Type[] args = GetTypeArguments (pt);
- return InferType (args [0], at.GetElementType (), infered);
+ return UnifyType (args [0], at.GetElementType (), inferred);
}
if (pt.IsArray) {
(pt.GetArrayRank () != at.GetArrayRank ()))
return false;
- return InferType (pt.GetElementType (), at.GetElementType (), infered);
+ return UnifyType (pt.GetElementType (), at.GetElementType (), inferred);
}
if (pt.IsByRef && at.IsByRef)
- return InferType (pt.GetElementType (), at.GetElementType (), infered);
+ return UnifyType (pt.GetElementType (), at.GetElementType (), inferred);
ArrayList list = new ArrayList ();
if (at.IsGenericType)
list.Add (at);
list.AddRange (TypeManager.GetInterfaces (at));
- bool found_one = false;
-
foreach (Type type in list) {
if (!type.IsGenericType)
continue;
- Type[] infered_types = new Type [infered.Length];
-
- if (!InferGenericInstance (pt, type, infered_types))
+ if (DropGenericTypeArguments (pt) != DropGenericTypeArguments (type))
continue;
- for (int i = 0; i < infered_types.Length; i++) {
- if (infered [i] == null) {
- infered [i] = infered_types [i];
- continue;
- }
-
- if (infered [i] != infered_types [i])
- return false;
- }
-
- found_one = true;
+ if (!UnifyTypes (pt.GetGenericArguments (), type.GetGenericArguments (), inferred))
+ return false;
}
- return found_one;
+ return true;
}
- static bool InferGenericInstance (Type pt, Type at, Type[] infered_types)
+ static bool UnifyTypes (Type[] pts, Type [] ats, Type [] inferred)
{
- Type[] at_args = at.GetGenericArguments ();
- Type[] pt_args = pt.GetGenericArguments ();
-
- if (at_args.Length != pt_args.Length)
- return false;
-
- for (int i = 0; i < at_args.Length; i++) {
- if (!InferType (pt_args [i], at_args [i], infered_types))
- return false;
- }
-
- for (int i = 0; i < infered_types.Length; i++) {
- if (infered_types [i] == null)
+ for (int i = 0; i < ats.Length; i++) {
+ if (!UnifyType (pts [i], ats [i], inferred))
return false;
}
-
return true;
}
return false;
Type[] method_args = method.GetGenericArguments ();
- Type[] infered_types = new Type [method_args.Length];
+ Type[] inferred_types = new Type [method_args.Length];
//
// If we have come this far, the case which
Type pt = pd.ParameterType (i);
Type at = a.Type;
- if (!InferType (pt, at, infered_types))
+ if (!UnifyType (pt, at, inferred_types))
return false;
}
if ((a.Expr is NullLiteral) || (a.Expr is MethodGroupExpr))
continue;
- if (!InferType (element_type, a.Type, infered_types))
+ if (!UnifyType (element_type, a.Type, inferred_types))
return false;
}
- for (int i = 0; i < infered_types.Length; i++)
- if (infered_types [i] == null)
+ for (int i = 0; i < inferred_types.Length; i++)
+ if (inferred_types [i] == null)
return false;
- method = ((MethodInfo)method).MakeGenericMethod (infered_types);
+ method = ((MethodInfo)method).MakeGenericMethod (inferred_types);
return true;
}
static bool InferTypeArguments (Type[] param_types, Type[] arg_types,
- Type[] infered_types)
+ Type[] inferred_types)
{
- if (infered_types == null)
- return false;
-
for (int i = 0; i < arg_types.Length; i++) {
if (arg_types [i] == null)
continue;
- if (!InferType (param_types [i], arg_types [i], infered_types))
+ if (!UnifyType (param_types [i], arg_types [i], inferred_types))
return false;
}
- for (int i = 0; i < infered_types.Length; i++)
- if (infered_types [i] == null)
+ for (int i = 0; i < inferred_types.Length; ++i)
+ if (inferred_types [i] == null)
return false;
return true;
}
+ //
+ // Infers the type of a single LambdaExpression in the invocation call and
+ // stores the infered type in the inferred_types array.
+ //
+ // The index of the arguments that contain lambdas is passed in
+ //
+ // @lambdas. Merely to avoid rescanning the list.
+ //
+ // The method being called:
+ // @method_generic_args: The generic type arguments for the method being called
+ // @method_pd: The ParameterData for the method being called.
+ //
+ // The call site:
+ // @arguments: Arraylist of Argument()s. The arguments being passed.
+ //
+ // Returns:
+ // @inferred_types: the array that is populated with our results.
+ //
+ // true if the code was able to do one inference.
+ //
+ static bool LambdaInfer (EmitContext ec,
+ Type [] method_generic_args,
+ ParameterData method_pd,
+ ArrayList arguments,
+ Type[] inferred_types,
+ ArrayList lambdas)
+ {
+ int last_count = lambdas.Count;
+
+ for (int i = 0; i < last_count; i++){
+ int argn = (int) lambdas [i];
+
+ Argument a = (Argument) arguments [argn];
+
+ LambdaExpression le = a.Expr as LambdaExpression;
+
+ if (le == null)
+ throw new Exception (
+ String.Format ("Internal Compiler error: argument {0} should be a Lambda Expression",
+ argn));
+
+ //
+ // "The corresponding parameter’s type, in the
+ // following called P, is a delegate type with a
+ // return type that involves one or more method type
+ // parameters."
+ //
+ //
+ if (!TypeManager.IsDelegateType (method_pd.ParameterType (argn)))
+ goto useless_lambda;
+
+ Type p_type = method_pd.ParameterType (argn);
+ MethodGroupExpr method_group = Expression.MemberLookup (
+ ec.ContainerType, p_type, "Invoke", MemberTypes.Method,
+ Expression.AllBindingFlags, Location.Null) as MethodGroupExpr;
+
+ if (method_group == null){
+ // This we report elsewhere as -200, but here we can ignore
+ goto useless_lambda;
+ }
+ MethodInfo p_delegate_method = method_group.Methods [0] as MethodInfo;
+ if (p_delegate_method == null){
+ // This should not happen.
+ goto useless_lambda;
+ }
+
+ Type p_return_type = p_delegate_method.ReturnType;
+ if (!p_return_type.IsGenericParameter)
+ goto useless_lambda;
+
+ //
+ // P and L have the same number of parameters, and
+ // each parameter in P has the same modifiers as the
+ // corresponding parameter in L, or no modifiers if
+ // L has an implicitly typed parameter list.
+ //
+ ParameterData p_delegate_parameters = TypeManager.GetParameterData (p_delegate_method);
+ int p_delegate_parameter_count = p_delegate_parameters.Count;
+ if (p_delegate_parameter_count != le.Parameters.Count)
+ goto useless_lambda;
+
+ if (le.HasExplicitParameters){
+ for (int j = 0; j < p_delegate_parameter_count; j++){
+ if (p_delegate_parameters.ParameterModifier (j) !=
+ le.Parameters.ParameterModifier (j))
+ goto useless_lambda;
+ }
+ } else {
+ for (int j = 0; j < p_delegate_parameter_count; j++)
+ if (le.Parameters.ParameterModifier (j) != Parameter.Modifier.NONE)
+ goto useless_lambda;
+ }
+
+ //
+ // TODO: P’s parameter types involve no method type
+ // parameters or involve only method type parameters
+ // for which a consistent set of inferences have
+ // already been made.
+ //
+ //Console.WriteLine ("Method: {0}", p_delegate_method);
+ //for (int j = 0; j < p_delegate_parameter_count; j++){
+ //Console.WriteLine ("PType [{2}, {0}] = {1}", j, p_delegate_parameters.ParameterType (j), argn);
+ //}
+
+ //
+ // At this point we know that P has method type parameters
+ // that involve only type parameters that have a consistent
+ // set of inferences made.
+ //
+ if (le.HasExplicitParameters){
+ //
+ // TODO: If L has an explicitly typed parameter
+ // list, when inferred types are substituted for
+ // method type parameters in P, each parameter in P
+ // has the same type as the corresponding parameter
+ // in L.
+ //
+ } else {
+ //
+ // TODO: If L has an implicitly typed parameter
+ // list, when inferred types are substituted for
+ // method type parameters in P and the resulting
+ // parameter types are given to the parameters of L,
+ // the body of L is a valid expression or statement
+ // block.
+
+ Type [] types = new Type [p_delegate_parameter_count];
+
+ //bool failure = false;
+ for (int j = 0; j < p_delegate_parameter_count; j++){
+ Type p_pt = p_delegate_parameters.ParameterType (j);
+
+ if (!p_pt.IsGenericParameter){
+ types [j] = p_pt;
+ continue;
+ }
+
+ //bool found = false;
+ for (int k = 0; k < method_generic_args.Length; k++){
+ if (method_generic_args [k] == p_pt){
+ types [j] = inferred_types [k];
+ break;
+ }
+ }
+ //
+ // If we could not infer just yet, continue
+ //
+ if (types [j] == null)
+ goto do_continue;
+ }
+
+ //
+ // If it results in a valid expression or statement block
+ //
+ Type lambda_inferred_type = le.TryBuild (ec, types);
+
+ if (lambda_inferred_type != null){
+ //
+ // Success, set the proper inferred_type value to the new type.
+ // return true
+ //
+ for (int k = 0; k < method_generic_args.Length; k++){
+ if (method_generic_args [k] == p_return_type){
+ inferred_types [k] = lambda_inferred_type;
+
+ lambdas.RemoveAt (i);
+ return true;
+ }
+ }
+ }
+ }
+
+ useless_lambda:
+ lambdas.RemoveAt (i);
+
+ do_continue:
+ ;
+ }
+
+#if false
+ Console.WriteLine ("Inferred types");
+ foreach (Type it in inferred_types){
+ Console.WriteLine (" IT: {0}", it);
+ if (it == null)
+ return false;
+ }
+#endif
+
+ // No inference was made in any of the elements.
+ return false;
+ }
+
/// <summary>
/// Type inference. Try to infer the type arguments from `method',
/// which is invoked with the arguments `arguments'. This is used
/// when resolving an Invocation or a DelegateInvocation and the user
/// did not explicitly specify type arguments.
/// </summary>
- public static bool InferTypeArguments (ArrayList arguments,
+ public static bool InferTypeArguments (EmitContext ec,
+ ArrayList arguments,
ref MethodBase method)
{
if (!TypeManager.IsGenericMethod (method))
if (arg_count != pd.Count)
return false;
- Type[] method_args = method.GetGenericArguments ();
+ Type[] method_generic_args = method.GetGenericArguments ();
bool is_open = false;
- for (int i = 0; i < method_args.Length; i++) {
- if (method_args [i].IsGenericParameter) {
+
+ for (int i = 0; i < method_generic_args.Length; i++) {
+ if (method_generic_args [i].IsGenericParameter) {
is_open = true;
break;
}
if (!is_open)
return !TypeManager.IsGenericMethodDefinition (method);
- Type[] infered_types = new Type [method_args.Length];
+ Type[] inferred_types = new Type [method_generic_args.Length];
Type[] param_types = new Type [pd.Count];
Type[] arg_types = new Type [pd.Count];
-
+ ArrayList lambdas = null;
+
for (int i = 0; i < arg_count; i++) {
param_types [i] = pd.ParameterType (i);
Argument a = (Argument) arguments [i];
- if ((a.Expr is NullLiteral) || (a.Expr is MethodGroupExpr) ||
- (a.Expr is AnonymousMethodExpression))
+ if (a.Expr is NullLiteral || a.Expr is MethodGroupExpr)
+ continue;
+
+ if (a.Expr is LambdaExpression){
+ if (lambdas == null)
+ lambdas = new ArrayList ();
+ lambdas.Add (i);
+ }
+ else if (a.Expr is AnonymousMethodExpression) {
+ if (RootContext.Version != LanguageVersion.LINQ)
+ continue;
+
+ Type dtype = param_types[i];
+ if (!TypeManager.IsDelegateType (dtype))
+ continue;
+
+ AnonymousMethodExpression am = (AnonymousMethodExpression)a.Expr;
+ Expression e = am.InferTypeArguments (ec, dtype);
+ if (e == null)
+ return false;
+
+ arg_types[i] = e.Type;
continue;
+ }
arg_types [i] = a.Type;
}
- if (!InferTypeArguments (param_types, arg_types, infered_types))
- return false;
+ if (!InferTypeArguments (param_types, arg_types, inferred_types)){
+ //Console.WriteLine ("InferTypeArgument found {0} lambdas ", lambdas);
+ if (lambdas == null)
+ return false;
+
+ //
+ // While the lambda expressions lead to a valid inference
+ //
+ int lambda_count;
+ do {
+ lambda_count = lambdas.Count;
+ if (!LambdaInfer (ec, method_generic_args, pd, arguments, inferred_types, lambdas))
+ return false;
+ } while (lambdas.Count != 0 && lambdas.Count != lambda_count);
+ }
+
+ method = ((MethodInfo)method).MakeGenericMethod (inferred_types);
+
+#if MS_COMPATIBLE
+ // MS implementation throws NotSupportedException for GetParameters
+ // on unbaked generic method
+ ParameterData p = TypeManager.GetParameterData (method);
+ p.InflateTypes (param_types, inferred_types);
+#endif
- method = ((MethodInfo)method).MakeGenericMethod (infered_types);
return true;
}
return false;
Type[] method_args = method.GetGenericArguments ();
- Type[] infered_types = new Type [method_args.Length];
+ Type[] inferred_types = new Type [method_args.Length];
Type[] param_types = new Type [pd.Count];
Type[] arg_types = new Type [pd.Count];
arg_types [i] = apd.ParameterType (i);
}
- if (!InferTypeArguments (param_types, arg_types, infered_types))
+ if (!InferTypeArguments (param_types, arg_types, inferred_types))
return false;
- method = ((MethodInfo)method).MakeGenericMethod (infered_types);
+ method = ((MethodInfo)method).MakeGenericMethod (inferred_types);
return true;
}
}