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/*
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance
* with the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing,
* software distributed under the License is distributed on an
* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
* KIND, either express or implied. See the License for the
* specific language governing permissions and limitations
* under the License.
*/
package org.codehaus.groovy.classgen.asm;
import org.codehaus.groovy.ast.ClassHelper;
import org.codehaus.groovy.ast.ClassNode;
import org.codehaus.groovy.ast.ConstructorNode;
import org.codehaus.groovy.ast.FieldNode;
import org.codehaus.groovy.ast.MethodNode;
import org.codehaus.groovy.ast.Parameter;
import org.codehaus.groovy.ast.expr.ArgumentListExpression;
import org.codehaus.groovy.ast.expr.ArrayExpression;
import org.codehaus.groovy.ast.expr.CastExpression;
import org.codehaus.groovy.ast.expr.ClassExpression;
import org.codehaus.groovy.ast.expr.ConstantExpression;
import org.codehaus.groovy.ast.expr.ConstructorCallExpression;
import org.codehaus.groovy.ast.expr.Expression;
import org.codehaus.groovy.ast.expr.MethodCallExpression;
import org.codehaus.groovy.ast.expr.PropertyExpression;
import org.codehaus.groovy.ast.expr.SpreadExpression;
import org.codehaus.groovy.ast.expr.StaticMethodCallExpression;
import org.codehaus.groovy.ast.expr.TupleExpression;
import org.codehaus.groovy.ast.expr.VariableExpression;
import org.codehaus.groovy.ast.tools.WideningCategories;
import org.codehaus.groovy.classgen.AsmClassGenerator;
import org.codehaus.groovy.runtime.ScriptBytecodeAdapter;
import org.codehaus.groovy.runtime.typehandling.DefaultTypeTransformation;
import org.codehaus.groovy.runtime.typehandling.ShortTypeHandling;
import org.codehaus.groovy.syntax.SyntaxException;
import org.objectweb.asm.Label;
import org.objectweb.asm.MethodVisitor;
import java.lang.reflect.Modifier;
import java.util.ArrayList;
import java.util.Iterator;
import java.util.LinkedList;
import java.util.List;
import java.util.Objects;
import java.util.TreeMap;
import static org.apache.groovy.ast.tools.ExpressionUtils.isNullConstant;
import static org.apache.groovy.ast.tools.ExpressionUtils.isSuperExpression;
import static org.apache.groovy.ast.tools.ExpressionUtils.isThisExpression;
import static org.objectweb.asm.Opcodes.AALOAD;
import static org.objectweb.asm.Opcodes.ACONST_NULL;
import static org.objectweb.asm.Opcodes.ALOAD;
import static org.objectweb.asm.Opcodes.ATHROW;
import static org.objectweb.asm.Opcodes.CHECKCAST;
import static org.objectweb.asm.Opcodes.DUP;
import static org.objectweb.asm.Opcodes.DUP2_X1;
import static org.objectweb.asm.Opcodes.DUP_X1;
import static org.objectweb.asm.Opcodes.GOTO;
import static org.objectweb.asm.Opcodes.INVOKEINTERFACE;
import static org.objectweb.asm.Opcodes.INVOKESPECIAL;
import static org.objectweb.asm.Opcodes.INVOKESTATIC;
import static org.objectweb.asm.Opcodes.INVOKEVIRTUAL;
import static org.objectweb.asm.Opcodes.NEW;
import static org.objectweb.asm.Opcodes.POP;
import static org.objectweb.asm.Opcodes.SWAP;
public class InvocationWriter {
// method invocation
public static final MethodCallerMultiAdapter invokeMethodOnCurrent = MethodCallerMultiAdapter.newStatic(ScriptBytecodeAdapter.class, "invokeMethodOnCurrent", true, false);
public static final MethodCallerMultiAdapter invokeMethodOnSuper = MethodCallerMultiAdapter.newStatic(ScriptBytecodeAdapter.class, "invokeMethodOnSuper", true, false);
public static final MethodCallerMultiAdapter invokeMethod = MethodCallerMultiAdapter.newStatic(ScriptBytecodeAdapter.class, "invokeMethod", true, false);
public static final MethodCallerMultiAdapter invokeStaticMethod = MethodCallerMultiAdapter.newStatic(ScriptBytecodeAdapter.class, "invokeStaticMethod", true, true);
public static final MethodCaller invokeClosureMethod = MethodCaller.newStatic(ScriptBytecodeAdapter.class, "invokeClosure");
public static final MethodCaller castToVargsArray = MethodCaller.newStatic(DefaultTypeTransformation.class, "castToVargsArray");
private static final MethodNode CLASS_FOR_NAME_STRING = ClassHelper.CLASS_Type.getDeclaredMethod("forName", new Parameter[]{new Parameter(ClassHelper.STRING_TYPE, "name")});
// type conversions
private static final MethodCaller asTypeMethod = MethodCaller.newStatic(ScriptBytecodeAdapter.class, "asType");
private static final MethodCaller castToTypeMethod = MethodCaller.newStatic(ScriptBytecodeAdapter.class, "castToType");
private static final MethodCaller castToClassMethod = MethodCaller.newStatic(ShortTypeHandling.class, "castToClass");
private static final MethodCaller castToStringMethod = MethodCaller.newStatic(ShortTypeHandling.class, "castToString");
private static final MethodCaller castToEnumMethod = MethodCaller.newStatic(ShortTypeHandling.class, "castToEnum");
// constructor calls with this() and super()
private static final MethodCaller selectConstructorAndTransformArguments = MethodCaller.newStatic(ScriptBytecodeAdapter.class, "selectConstructorAndTransformArguments");
private final WriterController controller;
public InvocationWriter(final WriterController controller) {
this.controller = controller;
}
public void makeCall(final Expression origin, final Expression receiver, final Expression message, final Expression arguments, final MethodCallerMultiAdapter adapter, boolean safe, final boolean spreadSafe, boolean implicitThis) {
ClassNode sender = controller.getClassNode();
if (isSuperExpression(receiver) || (isThisExpression(receiver) && !implicitThis)) {
while (ClassHelper.isGeneratedFunction(sender)) {
sender = sender.getOuterClass();
}
if (isSuperExpression(receiver)) {
sender = sender.getSuperClass(); // GROOVY-4035
implicitThis = false; // prevent recursion
safe = false; // GROOVY-6045
}
}
makeCall(origin, new ClassExpression(sender), receiver, message, arguments, adapter, safe, spreadSafe, implicitThis);
}
protected boolean writeDirectMethodCall(final MethodNode target, final boolean implicitThis, final Expression receiver, final TupleExpression args) {
if (target == null) return false;
String methodName = target.getName();
CompileStack compileStack = controller.getCompileStack();
OperandStack operandStack = controller.getOperandStack();
ClassNode declaringClass = target.getDeclaringClass();
ClassNode classNode = controller.getClassNode();
MethodVisitor mv = controller.getMethodVisitor();
int opcode = INVOKEVIRTUAL;
if (target.isStatic()) {
opcode = INVOKESTATIC;
} else if (declaringClass.isInterface()) {
opcode = INVOKEINTERFACE;
} else if (target.isPrivate() || isSuperExpression(receiver)) {
opcode = INVOKESPECIAL;
}
// handle receiver
int argumentsToRemove = 0;
if (opcode != INVOKESTATIC) {
if (receiver != null) {
// load receiver if not static invocation
// todo: fix inner class case
if (implicitThis
&& classNode.getOuterClass() != null
&& !classNode.isDerivedFrom(declaringClass)
&& !classNode.implementsInterface(declaringClass)) {
// we are calling an outer class method
compileStack.pushImplicitThis(false);
if (controller.isInGeneratedFunction()) {
new VariableExpression("thisObject").visit(controller.getAcg());
} else {
Expression expr = new PropertyExpression(new ClassExpression(declaringClass), "this");
expr.visit(controller.getAcg());
}
} else {
compileStack.pushImplicitThis(implicitThis);
receiver.visit(controller.getAcg());
}
operandStack.doGroovyCast(declaringClass);
compileStack.popImplicitThis();
argumentsToRemove += 1;
} else {
mv.visitIntInsn(ALOAD,0);
operandStack.push(classNode);
argumentsToRemove += 1;
}
}
int stackSize = operandStack.getStackLength();
String owner = BytecodeHelper.getClassInternalName(declaringClass);
ClassNode receiverType = receiver != null ? controller.getTypeChooser().resolveType(receiver, classNode) : declaringClass;
if (opcode == INVOKEVIRTUAL && ClassHelper.OBJECT_TYPE.equals(declaringClass)) {
// avoid using a narrowed type if the method is defined on object because it can interfere
// with delegate type inference in static compilation mode and trigger a ClassCastException
receiverType = declaringClass;
}
if (opcode == INVOKEVIRTUAL) {
if (!receiverType.equals(declaringClass)
&& !ClassHelper.OBJECT_TYPE.equals(declaringClass)
&& !receiverType.isArray()
&& !receiverType.isInterface()
&& !ClassHelper.isPrimitiveType(receiverType) // e.g int.getClass()
&& receiverType.isDerivedFrom(declaringClass)) {
owner = BytecodeHelper.getClassInternalName(receiverType);
ClassNode top = operandStack.getTopOperand();
if (!receiverType.equals(top)) {
mv.visitTypeInsn(CHECKCAST, owner);
}
} else if (target.isPublic()
&& (!receiverType.equals(declaringClass) && !Modifier.isPublic(declaringClass.getModifiers()))
&& receiverType.isDerivedFrom(declaringClass) && !Objects.equals(receiverType.getPackageName(), classNode.getPackageName())) {
// GROOVY-6962: package private class, public method
owner = BytecodeHelper.getClassInternalName(receiverType);
}
}
loadArguments(args.getExpressions(), target.getParameters());
String desc = BytecodeHelper.getMethodDescriptor(target.getReturnType(), target.getParameters());
mv.visitMethodInsn(opcode, owner, methodName, desc, declaringClass.isInterface());
ClassNode ret = target.getReturnType().redirect();
if (ret == ClassHelper.VOID_TYPE) {
ret = ClassHelper.OBJECT_TYPE;
mv.visitInsn(ACONST_NULL);
}
argumentsToRemove += (operandStack.getStackLength()-stackSize);
controller.getOperandStack().remove(argumentsToRemove);
controller.getOperandStack().push(ret);
return true;
}
private boolean lastIsArray(final List argumentList, final int pos) {
Expression last = argumentList.get(pos);
ClassNode type = controller.getTypeChooser().resolveType(last, controller.getClassNode());
return type.isArray();
}
// load arguments
protected void loadArguments(final List argumentList, final Parameter[] para) {
if (para.length == 0) return;
ClassNode lastParaType = para[para.length - 1].getOriginType();
AsmClassGenerator acg = controller.getAcg();
OperandStack operandStack = controller.getOperandStack();
if (lastParaType.isArray() && (argumentList.size() > para.length
|| argumentList.size() == para.length - 1 || !lastIsArray(argumentList, para.length - 1))) {
int stackLen = operandStack.getStackLength() + argumentList.size();
MethodVisitor mv = controller.getMethodVisitor();
controller.setMethodVisitor(mv);
// varg call
// first parameters as usual
for (int i = 0, n = para.length - 1; i < n; i += 1) {
argumentList.get(i).visit(acg);
operandStack.doGroovyCast(para[i].getType());
}
// last parameters wrapped in an array
List lastParams = new LinkedList<>();
for (int i = para.length - 1, n = argumentList.size(); i < n; i += 1) {
lastParams.add(argumentList.get(i));
}
ArrayExpression array = new ArrayExpression(
lastParaType.getComponentType(),
lastParams
);
array.visit(acg);
// adjust stack length
while (operandStack.getStackLength() < stackLen) {
operandStack.push(ClassHelper.OBJECT_TYPE);
}
if (argumentList.size() == para.length - 1) {
operandStack.remove(1);
}
} else {
for (int i = 0, n = argumentList.size(); i < n; i += 1) {
argumentList.get(i).visit(acg);
operandStack.doGroovyCast(para[i].getType());
}
}
}
protected boolean makeDirectCall(Expression origin, Expression receiver, Expression message, Expression arguments, MethodCallerMultiAdapter adapter, boolean implicitThis, boolean containsSpreadExpression) {
if (makeClassForNameCall(origin, receiver, message, arguments)) return true;
// optimization path
boolean fittingAdapter = adapter == invokeMethodOnCurrent || adapter == invokeStaticMethod;
if (fittingAdapter && controller.optimizeForInt && controller.isFastPath()) {
String methodName = getMethodName(message);
if (methodName != null) {
TupleExpression args;
if (arguments instanceof TupleExpression) {
args = (TupleExpression) arguments;
} else {
args = new TupleExpression(receiver);
}
OptimizingStatementWriter.StatementMeta meta = null;
if (origin != null) meta = origin.getNodeMetaData(OptimizingStatementWriter.StatementMeta.class);
MethodNode mn = null;
if (meta != null) mn = meta.target;
if (writeDirectMethodCall(mn, true, null, args)) return true;
}
}
if (containsSpreadExpression) return false;
if (origin instanceof MethodCallExpression) {
MethodCallExpression mce = (MethodCallExpression) origin;
MethodNode target = mce.getMethodTarget();
return writeDirectMethodCall(target, implicitThis, receiver, makeArgumentList(arguments));
}
return false;
}
protected boolean makeCachedCall(Expression origin, ClassExpression sender, Expression receiver, Expression message, Expression arguments, MethodCallerMultiAdapter adapter, boolean safe, boolean spreadSafe, boolean implicitThis, boolean containsSpreadExpression) {
// prepare call site
if ((adapter == invokeMethod || adapter == invokeMethodOnCurrent || adapter == invokeStaticMethod) && !spreadSafe) {
String methodName = getMethodName(message);
if (methodName != null) {
controller.getCallSiteWriter().makeCallSite(receiver, methodName, arguments, safe, implicitThis, adapter == invokeMethodOnCurrent, adapter == invokeStaticMethod);
return true;
}
}
return false;
}
protected void makeUncachedCall(Expression origin, ClassExpression sender, Expression receiver, Expression message, Expression arguments, MethodCallerMultiAdapter adapter, boolean safe, boolean spreadSafe, boolean implicitThis, boolean containsSpreadExpression) {
OperandStack operandStack = controller.getOperandStack();
CompileStack compileStack = controller.getCompileStack();
AsmClassGenerator acg = controller.getAcg();
// ensure VariableArguments are read, not stored
compileStack.pushLHS(false);
// sender only for call sites
if (adapter == AsmClassGenerator.setProperty) {
ConstantExpression.NULL.visit(acg);
} else {
sender.visit(acg);
}
String methodName = getMethodName(message);
if (adapter == invokeMethodOnSuper && methodName != null) {
controller.getSuperMethodNames().add(methodName);
}
// receiver
compileStack.pushImplicitThis(implicitThis);
receiver.visit(acg);
operandStack.box();
compileStack.popImplicitThis();
int operandsToRemove = 2;
// message
if (message != null) {
message.visit(acg);
operandStack.box();
operandsToRemove += 1;
}
// arguments
int numberOfArguments = containsSpreadExpression ? -1 : AsmClassGenerator.argumentSize(arguments);
if (numberOfArguments > MethodCallerMultiAdapter.MAX_ARGS || containsSpreadExpression) {
ArgumentListExpression ae = makeArgumentList(arguments);
if (containsSpreadExpression) {
acg.despreadList(ae.getExpressions(), true);
} else {
ae.visit(acg);
}
} else if (numberOfArguments > 0) {
operandsToRemove += numberOfArguments;
TupleExpression te = (TupleExpression) arguments;
for (int i = 0; i < numberOfArguments; i += 1) {
Expression argument = te.getExpression(i);
argument.visit(acg);
operandStack.box();
if (argument instanceof CastExpression) acg.loadWrapper(argument);
}
}
if (adapter == null) adapter = invokeMethod;
adapter.call(controller.getMethodVisitor(), numberOfArguments, safe, spreadSafe);
compileStack.popLHS();
operandStack.replace(ClassHelper.OBJECT_TYPE, operandsToRemove);
}
protected void makeCall(Expression origin, ClassExpression sender, Expression receiver, Expression message, Expression arguments, MethodCallerMultiAdapter adapter, boolean safe, boolean spreadSafe, boolean implicitThis) {
// direct method call paths
boolean containsSpreadExpression = AsmClassGenerator.containsSpreadExpression(arguments);
if (makeDirectCall(origin, receiver, message, arguments, adapter, implicitThis, containsSpreadExpression)) return;
// normal path
if (makeCachedCall(origin, sender, receiver, message, arguments, adapter, safe, spreadSafe, implicitThis, containsSpreadExpression)) return;
// path through ScriptBytecodeAdapter
makeUncachedCall(origin, sender, receiver, message, arguments, adapter, safe, spreadSafe, implicitThis, containsSpreadExpression);
}
/**
* if Class.forName(x) is recognized, make a direct method call
*/
protected boolean makeClassForNameCall(final Expression origin, final Expression receiver, final Expression message, final Expression arguments) {
if (!(receiver instanceof ClassExpression)) return false;
ClassExpression ce = (ClassExpression) receiver;
if (!ClassHelper.CLASS_Type.equals(ce.getType())) return false;
String msg = getMethodName(message);
if (!"forName".equals(msg)) return false;
ArgumentListExpression ae = makeArgumentList(arguments);
if (ae.getExpressions().size() != 1) return false;
return writeDirectMethodCall(CLASS_FOR_NAME_STRING, false, receiver, ae);
}
public static ArgumentListExpression makeArgumentList(final Expression arguments) {
ArgumentListExpression ae;
if (arguments instanceof ArgumentListExpression) {
ae = (ArgumentListExpression) arguments;
} else if (arguments instanceof TupleExpression) {
TupleExpression te = (TupleExpression) arguments;
ae = new ArgumentListExpression(te.getExpressions());
} else {
ae = new ArgumentListExpression();
ae.addExpression(arguments);
}
return ae;
}
protected String getMethodName(final Expression message) {
String methodName = null;
if (message instanceof CastExpression) {
CastExpression msg = (CastExpression) message;
if (msg.getType() == ClassHelper.STRING_TYPE) {
final Expression methodExpr = msg.getExpression();
if (methodExpr instanceof ConstantExpression) {
methodName = methodExpr.getText();
}
}
}
if (methodName == null && message instanceof ConstantExpression) {
ConstantExpression constantExpression = (ConstantExpression) message;
methodName = constantExpression.getText();
}
return methodName;
}
public void writeInvokeMethod(MethodCallExpression call) {
if (isClosureCall(call)) {
// let's invoke the closure method
invokeClosure(call.getArguments(), call.getMethodAsString());
} else {
if (isFunctionInterfaceCall(call)) {
call = transformToRealMethodCall(call);
}
MethodCallerMultiAdapter adapter = invokeMethod;
Expression objectExpression = call.getObjectExpression();
if (isSuperExpression(objectExpression)) {
adapter = invokeMethodOnSuper;
} else if (isThisExpression(objectExpression)) {
adapter = invokeMethodOnCurrent;
}
if (isStaticInvocation(call)) {
adapter = invokeStaticMethod;
}
Expression messageName = new CastExpression(ClassHelper.STRING_TYPE, call.getMethod());
makeCall(call, objectExpression, messageName, call.getArguments(), adapter, call.isSafe(), call.isSpreadSafe(), call.isImplicitThis());
}
}
private static boolean isFunctionInterfaceCall(final MethodCallExpression call) {
if ("call".equals(call.getMethodAsString())) {
Expression objectExpression = call.getObjectExpression();
if (!isThisExpression(objectExpression)) {
return ClassHelper.isFunctionalInterface(objectExpression.getType());
}
}
return false;
}
private static MethodCallExpression transformToRealMethodCall(MethodCallExpression call) {
ClassNode type = call.getObjectExpression().getType();
MethodNode methodNode = ClassHelper.findSAM(type);
call = (MethodCallExpression) call.transformExpression(expression -> {
if (!(expression instanceof ConstantExpression)) {
return expression;
}
return new ConstantExpression(methodNode.getName());
});
call.setMethodTarget(methodNode);
return call;
}
private boolean isClosureCall(final MethodCallExpression call) {
// are we a local variable?
// it should not be an explicitly "this" qualified method call
// and the current class should have a possible method
ClassNode classNode = controller.getClassNode();
String methodName = call.getMethodAsString();
if (methodName == null) return false;
if (!call.isImplicitThis()) return false;
if (!isThisExpression(call.getObjectExpression())) return false;
FieldNode field = classNode.getDeclaredField(methodName);
if (field == null) return false;
if (isStaticInvocation(call) && !field.isStatic()) return false;
Expression arguments = call.getArguments();
return !classNode.hasPossibleMethod(methodName, arguments);
}
private void invokeClosure(final Expression arguments, final String methodName) {
AsmClassGenerator acg = controller.getAcg();
acg.visitVariableExpression(new VariableExpression(methodName));
controller.getOperandStack().box();
if (arguments instanceof TupleExpression) {
arguments.visit(acg);
} else {
new TupleExpression(arguments).visit(acg);
}
invokeClosureMethod.call(controller.getMethodVisitor());
controller.getOperandStack().replace(ClassHelper.OBJECT_TYPE);
}
private boolean isStaticInvocation(final MethodCallExpression call) {
if (!isThisExpression(call.getObjectExpression())) return false;
if (controller.isStaticMethod()) return true;
return controller.isStaticContext() && !call.isImplicitThis();
}
public void writeInvokeStaticMethod(final StaticMethodCallExpression call) {
Expression receiver = new ClassExpression(call.getOwnerType());
Expression messageName = new ConstantExpression(call.getMethod());
makeCall(call, receiver, messageName, call.getArguments(), InvocationWriter.invokeStaticMethod, false, false, false);
}
private boolean writeDirectConstructorCall(final ConstructorCallExpression call) {
if (!controller.isFastPath()) return false;
OptimizingStatementWriter.StatementMeta meta = call.getNodeMetaData(OptimizingStatementWriter.StatementMeta.class);
ConstructorNode cn = null;
if (meta != null) cn = (ConstructorNode) meta.target;
if (cn == null) return false;
String ownerDescriptor = prepareConstructorCall(cn);
TupleExpression args = makeArgumentList(call.getArguments());
loadArguments(args.getExpressions(), cn.getParameters());
finnishConstructorCall(cn, ownerDescriptor, args.getExpressions().size());
return true;
}
protected String prepareConstructorCall(final ConstructorNode cn) {
String owner = BytecodeHelper.getClassInternalName(cn.getDeclaringClass());
MethodVisitor mv = controller.getMethodVisitor();
mv.visitTypeInsn(NEW, owner);
mv.visitInsn(DUP);
return owner;
}
protected void finnishConstructorCall(final ConstructorNode cn, final String ownerDescriptor, final int argsToRemove) {
String desc = BytecodeHelper.getMethodDescriptor(ClassHelper.VOID_TYPE, cn.getParameters());
MethodVisitor mv = controller.getMethodVisitor();
mv.visitMethodInsn(INVOKESPECIAL, ownerDescriptor, "", desc, false);
controller.getOperandStack().remove(argsToRemove);
controller.getOperandStack().push(cn.getDeclaringClass());
}
protected void writeNormalConstructorCall(final ConstructorCallExpression call) {
Expression arguments = call.getArguments();
if (arguments instanceof TupleExpression) {
TupleExpression tupleExpression = (TupleExpression) arguments;
int size = tupleExpression.getExpressions().size();
if (size == 0) {
arguments = MethodCallExpression.NO_ARGUMENTS;
}
}
Expression receiver = new ClassExpression(call.getType());
controller.getCallSiteWriter().makeCallSite(receiver, CallSiteWriter.CONSTRUCTOR, arguments, false, false, false, false);
}
public void writeInvokeConstructor(final ConstructorCallExpression call) {
if (writeDirectConstructorCall(call)) return;
if (writeAICCall(call)) return;
writeNormalConstructorCall(call);
}
protected boolean writeAICCall(final ConstructorCallExpression call) {
if (!call.isUsingAnonymousInnerClass()) return false;
ConstructorNode cn = call.getType().getDeclaredConstructors().get(0);
OperandStack os = controller.getOperandStack();
String ownerDescriptor = prepareConstructorCall(cn);
List args = makeArgumentList(call.getArguments()).getExpressions();
Parameter[] params = cn.getParameters();
// if a this appears as parameter here, then it should be
// not static, unless we are in a static method. But since
// ACG#visitVariableExpression does the opposite for this case, we
// push here an explicit this. This should not have any negative effect
// sine visiting a method call or property with implicit this will push
// a new value for this again.
controller.getCompileStack().pushImplicitThis(true);
for (int i = 0, n = params.length; i < n; i += 1) {
Parameter p = params[i];
Expression arg = args.get(i);
if (arg instanceof VariableExpression) {
VariableExpression var = (VariableExpression) arg;
loadVariableWithReference(var);
} else {
arg.visit(controller.getAcg());
}
os.doGroovyCast(p.getType());
}
controller.getCompileStack().popImplicitThis();
finnishConstructorCall(cn, ownerDescriptor, args.size());
return true;
}
private void loadVariableWithReference(final VariableExpression var) {
if (!var.isUseReferenceDirectly()) {
var.visit(controller.getAcg());
} else {
ClosureWriter.loadReference(var.getName(), controller);
}
}
public final void makeSingleArgumentCall(final Expression receiver, final String message, final Expression arguments) {
makeSingleArgumentCall(receiver, message, arguments, false);
}
public void makeSingleArgumentCall(final Expression receiver, final String message, final Expression arguments, final boolean safe) {
controller.getCallSiteWriter().makeSingleArgumentCall(receiver, message, arguments, safe);
}
public void writeSpecialConstructorCall(final ConstructorCallExpression call) {
controller.getCompileStack().pushInSpecialConstructorCall();
visitSpecialConstructorCall(call);
controller.getCompileStack().pop();
}
private void visitSpecialConstructorCall(final ConstructorCallExpression call) {
if (controller.getClosureWriter().addGeneratedClosureConstructorCall(call)) return;
ClassNode callNode = controller.getClassNode();
if (call.isSuperCall()) callNode = callNode.getSuperClass();
List constructors = sortConstructors(call, callNode);
if (!makeDirectConstructorCall(constructors, call, callNode)) {
makeMOPBasedConstructorCall(constructors, call, callNode);
}
}
private static List sortConstructors(final ConstructorCallExpression call, final ClassNode callNode) {
// sort in a new list to prevent side effects
List constructors = new ArrayList<>(callNode.getDeclaredConstructors());
constructors.sort((c0, c1) -> {
String descriptor0 = BytecodeHelper.getMethodDescriptor(ClassHelper.VOID_TYPE, c0.getParameters());
String descriptor1 = BytecodeHelper.getMethodDescriptor(ClassHelper.VOID_TYPE, c1.getParameters());
return descriptor0.compareTo(descriptor1);
});
return constructors;
}
private boolean makeDirectConstructorCall(final List constructors, final ConstructorCallExpression call, final ClassNode callNode) {
if (!controller.isConstructor()) return false;
Expression arguments = call.getArguments();
List argumentList;
if (arguments instanceof TupleExpression) {
argumentList = ((TupleExpression) arguments).getExpressions();
} else {
argumentList = new ArrayList<>();
argumentList.add(arguments);
}
for (Expression expression : argumentList) {
if (expression instanceof SpreadExpression) return false;
}
ConstructorNode cn = getMatchingConstructor(constructors, argumentList);
if (cn == null) return false;
MethodVisitor mv = controller.getMethodVisitor();
OperandStack operandStack = controller.getOperandStack();
Parameter[] params = cn.getParameters();
mv.visitVarInsn(ALOAD, 0);
for (int i = 0, n = params.length; i < n; i += 1) {
Expression expression = argumentList.get(i);
expression.visit(controller.getAcg());
if (!isNullConstant(expression)) {
operandStack.doGroovyCast(params[i].getType());
}
operandStack.remove(1);
}
String descriptor = BytecodeHelper.getMethodDescriptor(ClassHelper.VOID_TYPE, params);
mv.visitMethodInsn(INVOKESPECIAL, BytecodeHelper.getClassInternalName(callNode), "", descriptor, false);
return true;
}
private void makeMOPBasedConstructorCall(final List constructors, final ConstructorCallExpression call, final ClassNode callNode) {
MethodVisitor mv = controller.getMethodVisitor();
OperandStack operandStack = controller.getOperandStack();
call.getArguments().visit(controller.getAcg());
// keep Object[] on stack
mv.visitInsn(DUP);
// to select the constructor we need also the number of
// available constructors and the class we want to make
// the call on
BytecodeHelper.pushConstant(mv, -1);
controller.getAcg().visitClassExpression(new ClassExpression(callNode));
operandStack.remove(1);
// removes one Object[] leaves the int containing the
// call flags and the constructor number
selectConstructorAndTransformArguments.call(mv);
//load "this"
if (controller.isConstructor()) {
mv.visitVarInsn(ALOAD, 0);
} else {
mv.visitTypeInsn(NEW, BytecodeHelper.getClassInternalName(callNode));
}
mv.visitInsn(SWAP);
TreeMap sortedConstructors = new TreeMap<>();
for (ConstructorNode constructor : constructors) {
String typeDescriptor = BytecodeHelper.getMethodDescriptor(ClassHelper.VOID_TYPE, constructor.getParameters());
int hash = BytecodeHelper.hashCode(typeDescriptor);
ConstructorNode sameHashNode = sortedConstructors.put(hash, constructor);
if (sameHashNode != null) {
controller.getSourceUnit().addError(new SyntaxException(
"Unable to compile class "+controller.getClassNode().getName() + " due to hash collision in constructors", call.getLineNumber(), call.getColumnNumber()));
}
}
Label[] targets = new Label[constructors.size()];
int[] indices = new int[constructors.size()];
Iterator hashIt = sortedConstructors.keySet().iterator();
Iterator constructorIt = sortedConstructors.values().iterator();
for (int i = 0, n = targets.length; i < n; i += 1) {
targets[i] = new Label();
indices[i] = hashIt.next();
}
// create switch targets
Label defaultLabel = new Label();
Label afterSwitch = new Label();
mv.visitLookupSwitchInsn(defaultLabel, indices, targets);
for (Label target : targets) {
mv.visitLabel(target);
// to keep the stack height, we need to leave
// one Object[] on the stack as last element. At the
// same time, we need the Object[] on top of the stack
// to extract the parameters.
if (controller.isConstructor()) {
// in this case we need one "this", so a SWAP will exchange
// "this" and Object[], a DUP_X1 will then copy the Object[]
/// to the last place in the stack:
// Object[],this -SWAP-> this,Object[]
// this,Object[] -DUP_X1-> Object[],this,Object[]
mv.visitInsn(SWAP);
mv.visitInsn(DUP_X1);
} else {
// in this case we need two "this" in between and the Object[]
// at the bottom of the stack as well as on top for our invokeSpecial
// So we do DUP_X1, DUP2_X1, POP
// Object[],this -DUP_X1-> this,Object[],this
// this,Object[],this -DUP2_X1-> Object[],this,this,Object[],this
// Object[],this,this,Object[],this -POP-> Object[],this,this,Object[]
mv.visitInsn(DUP_X1);
mv.visitInsn(DUP2_X1);
mv.visitInsn(POP);
}
ConstructorNode cn = constructorIt.next();
String descriptor = BytecodeHelper.getMethodDescriptor(ClassHelper.VOID_TYPE, cn.getParameters());
// unwrap the Object[] and make transformations if needed
// that means, to duplicate the Object[], make a cast with possible
// unboxing and then swap it with the Object[] for each parameter
// vargs need special attention and transformation though
Parameter[] parameters = cn.getParameters();
int lengthWithoutVargs = parameters.length;
if (parameters.length > 0 && parameters[parameters.length - 1].getType().isArray()) {
lengthWithoutVargs -= 1;
}
for (int p = 0; p < lengthWithoutVargs; p += 1) {
loadAndCastElement(operandStack, mv, parameters, p);
}
if (parameters.length > lengthWithoutVargs) {
ClassNode type = parameters[lengthWithoutVargs].getType();
BytecodeHelper.pushConstant(mv, lengthWithoutVargs);
controller.getAcg().visitClassExpression(new ClassExpression(type));
operandStack.remove(1);
castToVargsArray.call(mv);
BytecodeHelper.doCast(mv, type);
} else {
// at the end we remove the Object[]
// the vargs case simply the last swap so no pop is needed
mv.visitInsn(POP);
}
// make the constructor call
mv.visitMethodInsn(INVOKESPECIAL, BytecodeHelper.getClassInternalName(callNode), "", descriptor, false);
mv.visitJumpInsn(GOTO, afterSwitch);
}
mv.visitLabel(defaultLabel);
// this part should never be reached!
mv.visitTypeInsn(NEW, "java/lang/IllegalArgumentException");
mv.visitInsn(DUP);
mv.visitLdcInsn("This class has been compiled with a super class which is binary incompatible with the current super class found on classpath. You should recompile this class with the new version.");
mv.visitMethodInsn(INVOKESPECIAL, "java/lang/IllegalArgumentException", "", "(Ljava/lang/String;)V", false);
mv.visitInsn(ATHROW);
mv.visitLabel(afterSwitch);
// For a special constructor call inside a constructor we don't need
// any result object on the stack, for outside the constructor we do.
// to keep the stack height for the able we kept one object as dummy
// result on the stack, which we can remove now if inside a constructor.
if (!controller.isConstructor()) {
// in case we are not in a constructor we have an additional
// object on the stack, the result of our constructor call
// which we want to keep, so we swap with the dummy object and
// do normal removal of it. In the end, the call result will be
// on the stack then
mv.visitInsn(SWAP);
operandStack.push(callNode); // for call result
}
mv.visitInsn(POP);
}
private static void loadAndCastElement(final OperandStack operandStack, final MethodVisitor mv, final Parameter[] parameters, final int p) {
operandStack.push(ClassHelper.OBJECT_TYPE);
mv.visitInsn(DUP);
BytecodeHelper.pushConstant(mv, p);
mv.visitInsn(AALOAD);
operandStack.push(ClassHelper.OBJECT_TYPE);
ClassNode type = parameters[p].getType();
operandStack.doGroovyCast(type);
operandStack.swap();
operandStack.remove(2);
}
// we match only on the number of arguments, not anything else
private static ConstructorNode getMatchingConstructor(final List constructors, final List argumentList) {
ConstructorNode lastMatch = null;
for (ConstructorNode cn : constructors) {
Parameter[] params = cn.getParameters();
// if number of parameters does not match we have no match
if (argumentList.size() != params.length) continue;
if (lastMatch == null) {
lastMatch = cn;
} else {
// we already had a match so we don't make a direct call at all
return null;
}
}
return lastMatch;
}
/**
* Converts sourceType to a non primitive by using Groovy casting.
* sourceType might be a primitive
* This might be done using SBA#castToType
*/
public void castToNonPrimitiveIfNecessary(final ClassNode sourceType, final ClassNode targetType) {
OperandStack os = controller.getOperandStack();
ClassNode boxedType = os.box();
if (WideningCategories.implementsInterfaceOrSubclassOf(boxedType, targetType)) return;
MethodVisitor mv = controller.getMethodVisitor();
if (ClassHelper.CLASS_Type.equals(targetType)) {
castToClassMethod.call(mv);
} else if (ClassHelper.STRING_TYPE.equals(targetType)) {
castToStringMethod.call(mv);
} else if (targetType.isDerivedFrom(ClassHelper.Enum_Type)) {
(new ClassExpression(targetType)).visit(controller.getAcg());
os.remove(1);
castToEnumMethod.call(mv);
BytecodeHelper.doCast(mv, targetType);
} else {
(new ClassExpression(targetType)).visit(controller.getAcg());
os.remove(1);
castToTypeMethod.call(mv);
}
}
public void castNonPrimitiveToBool(final ClassNode last) {
MethodVisitor mv = controller.getMethodVisitor();
BytecodeHelper.unbox(mv, ClassHelper.boolean_TYPE);
}
public void coerce(final ClassNode from, final ClassNode target) {
if (from.isDerivedFrom(target)) return;
MethodVisitor mv = controller.getMethodVisitor();
OperandStack os = controller.getOperandStack();
os.box();
(new ClassExpression(target)).visit(controller.getAcg());
os.remove(1);
asTypeMethod.call(mv);
BytecodeHelper.doCast(mv,target);
os.replace(target);
}
}
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