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* published by the Free Software Foundation. Oracle designates this
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*
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
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package sun.reflect.generics.visitor;
import java.lang.reflect.Type;
import java.util.List;
import java.util.Iterator;
import sun.reflect.generics.tree.*;
import sun.reflect.generics.factory.*;
Visitor that converts AST to reified types.
/**
* Visitor that converts AST to reified types.
*/
public class Reifier implements TypeTreeVisitor<Type> {
private Type resultType;
private final GenericsFactory factory;
private Reifier(GenericsFactory f){
factory = f;
}
private GenericsFactory getFactory(){ return factory;}
Factory method. The resulting visitor will convert an AST representing generic signatures into corresponding reflective objects, using the provided factory, f
. Params: - f – - a factory that can be used to manufacture reflective
objects returned by this visitor
Returns: A visitor that can be used to reify ASTs representing
generic type information into reflective objects
/**
* Factory method. The resulting visitor will convert an AST
* representing generic signatures into corresponding reflective
* objects, using the provided factory, {@code f}.
* @param f - a factory that can be used to manufacture reflective
* objects returned by this visitor
* @return A visitor that can be used to reify ASTs representing
* generic type information into reflective objects
*/
public static Reifier make(GenericsFactory f){
return new Reifier(f);
}
// Helper method. Visits an array of TypeArgument and produces
// reified Type array.
private Type[] reifyTypeArguments(TypeArgument[] tas) {
Type[] ts = new Type[tas.length];
for (int i = 0; i < tas.length; i++) {
tas[i].accept(this);
ts[i] = resultType;
}
return ts;
}
Accessor for the result of the last visit by this visitor,
Returns: The type computed by this visitor based on its last
visit
/**
* Accessor for the result of the last visit by this visitor,
* @return The type computed by this visitor based on its last
* visit
*/
public Type getResult() { assert resultType != null;return resultType;}
public void visitFormalTypeParameter(FormalTypeParameter ftp){
resultType = getFactory().makeTypeVariable(ftp.getName(),
ftp.getBounds());
}
public void visitClassTypeSignature(ClassTypeSignature ct){
// This method examines the pathname stored in ct, which has the form
// n1.n2...nk<targs>....
// where n1 ... nk-1 might not exist OR
// nk might not exist (but not both). It may be that k equals 1.
// The idea is that nk is the simple class type name that has
// any type parameters associated with it.
// We process this path in two phases.
// First, we scan until we reach nk (if it exists).
// If nk does not exist, this identifies a raw class n1 ... nk-1
// which we can return.
// if nk does exist, we begin the 2nd phase.
// Here nk defines a parameterized type. Every further step nj (j > k)
// down the path must also be represented as a parameterized type,
// whose owner is the representation of the previous step in the path,
// n{j-1}.
// extract iterator on list of simple class type sigs
List<SimpleClassTypeSignature> scts = ct.getPath();
assert(!scts.isEmpty());
Iterator<SimpleClassTypeSignature> iter = scts.iterator();
SimpleClassTypeSignature sc = iter.next();
StringBuilder n = new StringBuilder(sc.getName());
boolean dollar = sc.getDollar();
// phase 1: iterate over simple class types until
// we are either done or we hit one with non-empty type parameters
while (iter.hasNext() && sc.getTypeArguments().length == 0) {
sc = iter.next();
dollar = sc.getDollar();
n.append(dollar?"$":".").append(sc.getName());
}
// Now, either sc is the last element of the list, or
// it has type arguments (or both)
assert(!(iter.hasNext()) || (sc.getTypeArguments().length > 0));
// Create the raw type
Type c = getFactory().makeNamedType(n.toString());
// if there are no type arguments
if (sc.getTypeArguments().length == 0) {
//we have surely reached the end of the path
assert(!iter.hasNext());
resultType = c; // the result is the raw type
} else {
assert(sc.getTypeArguments().length > 0);
// otherwise, we have type arguments, so we create a parameterized
// type, whose declaration is the raw type c, and whose owner is
// the declaring class of c (if any). This latter fact is indicated
// by passing null as the owner.
// First, we reify the type arguments
Type[] pts = reifyTypeArguments(sc.getTypeArguments());
Type owner = getFactory().makeParameterizedType(c, pts, null);
// phase 2: iterate over remaining simple class types
dollar =false;
while (iter.hasNext()) {
sc = iter.next();
dollar = sc.getDollar();
n.append(dollar?"$":".").append(sc.getName()); // build up raw class name
c = getFactory().makeNamedType(n.toString()); // obtain raw class
pts = reifyTypeArguments(sc.getTypeArguments());// reify params
// Create a parameterized type, based on type args, raw type
// and previous owner
owner = getFactory().makeParameterizedType(c, pts, owner);
}
resultType = owner;
}
}
public void visitArrayTypeSignature(ArrayTypeSignature a){
// extract and reify component type
a.getComponentType().accept(this);
Type ct = resultType;
resultType = getFactory().makeArrayType(ct);
}
public void visitTypeVariableSignature(TypeVariableSignature tv){
resultType = getFactory().findTypeVariable(tv.getIdentifier());
}
public void visitWildcard(Wildcard w){
resultType = getFactory().makeWildcard(w.getUpperBounds(),
w.getLowerBounds());
}
public void visitSimpleClassTypeSignature(SimpleClassTypeSignature sct){
resultType = getFactory().makeNamedType(sct.getName());
}
public void visitBottomSignature(BottomSignature b){
}
public void visitByteSignature(ByteSignature b){
resultType = getFactory().makeByte();
}
public void visitBooleanSignature(BooleanSignature b){
resultType = getFactory().makeBool();
}
public void visitShortSignature(ShortSignature s){
resultType = getFactory().makeShort();
}
public void visitCharSignature(CharSignature c){
resultType = getFactory().makeChar();
}
public void visitIntSignature(IntSignature i){
resultType = getFactory().makeInt();
}
public void visitLongSignature(LongSignature l){
resultType = getFactory().makeLong();
}
public void visitFloatSignature(FloatSignature f){
resultType = getFactory().makeFloat();
}
public void visitDoubleSignature(DoubleSignature d){
resultType = getFactory().makeDouble();
}
public void visitVoidDescriptor(VoidDescriptor v){
resultType = getFactory().makeVoid();
}
}