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*
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*
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* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
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/*
* @test
* @bug 7007432 7006109
* @summary Test generic types well-formedness
* @author mcimadamore
* @library .
* @run main GenericTypeWellFormednessTest
*/
import com.sun.tools.javac.code.BoundKind;
import com.sun.tools.javac.code.Type;
import com.sun.tools.javac.code.Type.*;
import com.sun.tools.javac.code.Symbol;
import com.sun.tools.javac.code.Symbol.*;
import java.lang.reflect.Array;
/**
* Check parameterized type well-formedness. This test executes a number of checks
* in order to establish as to whether an instantiation of a generic type conforms
* to the generic class' declared bounds.
*/
public class GenericTypeWellFormednessTest extends TypeHarness {
static int executedCount = 0;
static int ignoredCount = 0;
InstantiableType[] rows;
Type[] columns;
static class InstantiableType {
protected Type type;
public InstantiableType(Type type) {
this.type = type;
}
Type inst(Type clazz) {
return type;
}
}
enum Result {
/* generic type is well-formed w.r.t. declared bounds */
OK(true),
/* generic type is not well-formed w.r.t. declared bounds */
FAIL(false),
/* generic type is not well-formed w.r.t. declared bounds according to the JLS 3rd,
* but javac allows it (spec for generic type well-formedness is overly restrictive)
* See regression test test/tools/generics/wildcards/T5097548.java
*/
IGNORE(false);
boolean value;
Result(boolean value) {
this.value = value;
}
}
static final Result T = Result.OK;
static final Result F = Result.FAIL;
static final Result I = Result.IGNORE;
/*is a type in 'rows' a valid instantiation for the generic class in 'col' ? */
Result[][] isValidInstantiation = {
//Foo<X>, Foo<X ext Object>, Foo<X ext Number>, Foo<X ext Foo<X>>, Foo<X ext Foo<+X>>, Foo<X ext Foo<-X>>, Foo<X ext Foo<?>>
/*Foo<Object>*/ { T , T , F , F , F , F , F },
/*Foo<Number>*/ { T , T , T , F , F , F , F },
/*Foo<Integer>*/ { T , T , T , F , F , F , F },
/*Foo<Double>*/ { T , T , T , F , F , F , F },
/*Foo<String>*/ { T , T , F , F , F , F , F },
/*Foo<X1>*/ { T , T , F , F , F , F , F },
/*Foo<X2>*/ { T , T , T , F , F , F , F },
/*Foo<X3>*/ { T , T , T , F , F , F , F },
/*Foo<X4>*/ { T , T , T , F , F , F , F },
/*Foo<X5>*/ { T , T , F , F , F , F , F },
/*Foo<X6>*/ { T , T , F , T , T , T , T },
/*Foo<+Object>*/ { T , T , I , I , I , I , I },
/*Foo<+Number>*/ { T , T , T , F , F , F , F },
/*Foo<+Integer>*/{ T , T , T , F , F , F , F },
/*Foo<+Double>*/ { T , T , T , F , F , F , F },
/*Foo<+String>*/ { T , T , F , F , F , F , F },
/*Foo<+X1>*/ { T , T , F , F , F , F , F },
/*Foo<+X2>*/ { T , T , T , F , F , F , F },
/*Foo<+X3>*/ { T , T , T , F , F , F , F },
/*Foo<+X4>*/ { T , T , T , F , F , F , F },
/*Foo<+X5>*/ { T , T , F , F , F , F , F },
/*Foo<+X6>*/ { T , T , F , T , T , I , T },
/*Foo<-Object>*/ { T , T , F , F , F , F , F },
/*Foo<-Number>*/ { T , T , T , F , F , F , F },
/*Foo<-Integer>*/{ T , T , T , F , F , F , F },
/*Foo<-Double>*/ { T , T , T , F , F , F , F },
/*Foo<-String>*/ { T , T , F , F , F , F , F },
/*Foo<-X1>*/ { T , T , I , I , I , I , I },
/*Foo<-X2>*/ { T , T , I , F , F , F , F },
/*Foo<-X3>*/ { T , T , I , F , F , F , F },
/*Foo<-X4>*/ { T , T , I , F , F , F , F },
/*Foo<-X5>*/ { T , T , I , F , F , F , F },
/*Foo<-X6>*/ { T , T , F , T , I , I , T },
/*Foo<?>*/ { T , T , T , T , T , T , T }};
GenericTypeWellFormednessTest() {
InstantiableType[] basicTypes = {
new InstantiableType(predef.objectType),
new InstantiableType(NumberType()),
new InstantiableType(box(predef.intType)),
new InstantiableType(box(predef.doubleType)),
new InstantiableType(predef.stringType) };
InstantiableType[] typeVars = new InstantiableType[basicTypes.length + 1];
for (int i = 0 ; i < basicTypes.length ; i++) {
typeVars[i] = new InstantiableType(fac.TypeVariable(basicTypes[i].type));
}
typeVars[typeVars.length - 1] = new InstantiableType(null) {
Type inst(Type clazz) {
TypeVar tvar = fac.TypeVariable();
tvar.bound = subst(clazz, Mapping(clazz.getTypeArguments().head, tvar));
return tvar;
}
};
InstantiableType[] typeArgs = join(InstantiableType.class, basicTypes, typeVars);
InstantiableType[] invariantTypes = new InstantiableType[typeArgs.length];
for (int i = 0 ; i < typeArgs.length ; i++) {
final InstantiableType type1 = typeArgs[i];
invariantTypes[i] = new InstantiableType(typeArgs[i].type) {
Type inst(Type clazz) {
return subst(clazz, Mapping(clazz.getTypeArguments().head, type1.inst(clazz)));
}
};
}
InstantiableType[] covariantTypes = new InstantiableType[typeArgs.length];
for (int i = 0 ; i < typeArgs.length ; i++) {
final InstantiableType type1 = typeArgs[i];
covariantTypes[i] = new InstantiableType(null) {
Type inst(Type clazz) {
Type t = fac.Wildcard(BoundKind.EXTENDS, type1.inst(clazz));
return subst(clazz, Mapping(clazz.getTypeArguments().head, t));
}
};
}
InstantiableType[] contravariantTypes = new InstantiableType[typeArgs.length];
for (int i = 0 ; i < typeArgs.length ; i++) {
final InstantiableType type1 = typeArgs[i];
contravariantTypes[i] = new InstantiableType(null) {
Type inst(Type clazz) {
Type t = fac.Wildcard(BoundKind.SUPER, type1.inst(clazz));
return subst(clazz, Mapping(clazz.getTypeArguments().head, t));
}
};
}
InstantiableType[] bivariantTypes = {
new InstantiableType(fac.Wildcard(BoundKind.UNBOUND, predef.objectType)) {
Type inst(Type clazz) {
return subst(clazz, Mapping(clazz.getTypeArguments().head, type));
}
}
};
rows = join(InstantiableType.class, invariantTypes, covariantTypes, contravariantTypes, bivariantTypes);
Type tv1 = fac.TypeVariable();
Type decl1 = fac.Class(tv1);
Type tv2 = fac.TypeVariable(predef.objectType);
Type decl2 = fac.Class(tv2);
Type tv3 = fac.TypeVariable(NumberType());
Type decl3 = fac.Class(tv3);
TypeVar tv4 = fac.TypeVariable();
Type decl4 = fac.Class(tv4);
tv4.bound = decl4;
tv4.tsym.name = predef.exceptionType.tsym.name;
TypeVar tv5 = fac.TypeVariable();
Type decl5 = fac.Class(tv5);
tv5.bound = subst(decl5, Mapping(tv5, fac.Wildcard(BoundKind.EXTENDS, tv5)));
TypeVar tv6 = fac.TypeVariable();
Type decl6 = fac.Class(tv6);
tv6.bound = subst(decl6, Mapping(tv6, fac.Wildcard(BoundKind.SUPER, tv6)));
TypeVar tv7 = fac.TypeVariable();
Type decl7 = fac.Class(tv7);
tv7.bound = subst(decl7, Mapping(tv7, fac.Wildcard(BoundKind.UNBOUND, predef.objectType)));
columns = new Type[] {
decl1, decl2, decl3, decl4, decl5, decl6, decl7
};
}
void test() {
for (int i = 0; i < rows.length ; i++) {
for (int j = 0; j < columns.length ; j++) {
Type decl = columns[j];
Type inst = rows[i].inst(decl);
if (isValidInstantiation[i][j] != Result.IGNORE) {
executedCount++;
assertValidGenericType(inst, isValidInstantiation[i][j].value);
} else {
ignoredCount++;
}
}
}
}
Type NumberType() {
Symbol s = box(predef.intType).tsym;
s.complete();
return ((ClassType)s.type).supertype_field;
}
@SuppressWarnings("unchecked")
<T> T[] join(Class<T> type, T[]... args) {
int totalLength = 0;
for (T[] arr : args) {
totalLength += arr.length;
}
T[] new_arr = (T[])Array.newInstance(type, totalLength);
int idx = 0;
for (T[] arr : args) {
System.arraycopy(arr, 0, new_arr, idx, arr.length);
idx += arr.length;
}
return new_arr;
}
public static void main(String[] args) {
new GenericTypeWellFormednessTest().test();
System.out.println("Executed checks : " + executedCount);
System.out.println("Ignored checks : " + ignoredCount);
}
}