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/*
Copyright 2009-2013 Attila Szegedi
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
* Neither the name of the copyright holder nor the names of
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL COPYRIGHT HOLDER
BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
package jdk.dynalink.beans;
import java.lang.invoke.MethodHandle;
import java.lang.invoke.MethodType;
import java.security.AccessControlContext;
import java.security.AccessController;
import java.security.PrivilegedAction;
import java.text.Collator;
import java.util.ArrayList;
import java.util.Collections;
import java.util.IdentityHashMap;
import java.util.Iterator;
import java.util.LinkedList;
import java.util.List;
import java.util.Map;
import java.util.Set;
import jdk.dynalink.CallSiteDescriptor;
import jdk.dynalink.SecureLookupSupplier;
import jdk.dynalink.beans.ApplicableOverloadedMethods.ApplicabilityTest;
import jdk.dynalink.internal.AccessControlContextFactory;
import jdk.dynalink.internal.InternalTypeUtilities;
import jdk.dynalink.linker.LinkerServices;
Represents a group of SingleDynamicMethod
objects that represents all overloads of a particular name (or all constructors) for a particular class. Correctly handles overload resolution, variable arity methods, and caller sensitive methods within the overloads. /**
* Represents a group of {@link SingleDynamicMethod} objects that represents all overloads of a particular name (or all
* constructors) for a particular class. Correctly handles overload resolution, variable arity methods, and caller
* sensitive methods within the overloads.
*/
class OverloadedDynamicMethod extends DynamicMethod {
Holds a list of all methods.
/**
* Holds a list of all methods.
*/
private final LinkedList<SingleDynamicMethod> methods = new LinkedList<>();
Creates a new overloaded dynamic method.
Params: - clazz – the class this method belongs to
- name – the name of the method
/**
* Creates a new overloaded dynamic method.
*
* @param clazz the class this method belongs to
* @param name the name of the method
*/
OverloadedDynamicMethod(final Class<?> clazz, final String name) {
super(getClassAndMethodName(clazz, name));
}
@Override
SingleDynamicMethod getMethodForExactParamTypes(final String paramTypes) {
final LinkedList<SingleDynamicMethod> matchingMethods = new LinkedList<>();
for(final SingleDynamicMethod method: methods) {
final SingleDynamicMethod matchingMethod = method.getMethodForExactParamTypes(paramTypes);
if(matchingMethod != null) {
matchingMethods.add(matchingMethod);
}
}
switch(matchingMethods.size()) {
case 0: {
return null;
}
case 1: {
return matchingMethods.getFirst();
}
default: {
throw new BootstrapMethodError("Can't choose among " + matchingMethods + " for argument types "
+ paramTypes + " for method " + getName());
}
}
}
@Override
MethodHandle getInvocation(final CallSiteDescriptor callSiteDescriptor, final LinkerServices linkerServices) {
final MethodType callSiteType = callSiteDescriptor.getMethodType();
// First, find all methods applicable to the call site by subtyping (JLS 15.12.2.2)
final ApplicableOverloadedMethods subtypingApplicables = getApplicables(callSiteType,
ApplicableOverloadedMethods.APPLICABLE_BY_SUBTYPING);
// Next, find all methods applicable by method invocation conversion to the call site (JLS 15.12.2.3).
final ApplicableOverloadedMethods methodInvocationApplicables = getApplicables(callSiteType,
ApplicableOverloadedMethods.APPLICABLE_BY_METHOD_INVOCATION_CONVERSION);
// Finally, find all methods applicable by variable arity invocation. (JLS 15.12.2.4).
final ApplicableOverloadedMethods variableArityApplicables = getApplicables(callSiteType,
ApplicableOverloadedMethods.APPLICABLE_BY_VARIABLE_ARITY);
// Find the methods that are maximally specific based on the call site signature
List<SingleDynamicMethod> maximallySpecifics = subtypingApplicables.findMaximallySpecificMethods();
if(maximallySpecifics.isEmpty()) {
maximallySpecifics = methodInvocationApplicables.findMaximallySpecificMethods();
if(maximallySpecifics.isEmpty()) {
maximallySpecifics = variableArityApplicables.findMaximallySpecificMethods();
}
}
// Now, get a list of the rest of the methods; those that are *not* applicable to the call site signature based
// on JLS rules. As paradoxical as that might sound, we have to consider these for dynamic invocation, as they
// might match more concrete types passed in invocations. That's why we provisionally call them "invokables".
// This is typical for very generic signatures at call sites. Typical example: call site specifies
// (Object, Object), and we have a method whose parameter types are (String, int). None of the JLS applicability
// rules will trigger, but we must consider the method, as it can be the right match for a concrete invocation.
@SuppressWarnings({ "unchecked", "rawtypes" })
final List<SingleDynamicMethod> invokables = (List)methods.clone();
invokables.removeAll(subtypingApplicables.getMethods());
invokables.removeAll(methodInvocationApplicables.getMethods());
invokables.removeAll(variableArityApplicables.getMethods());
for(final Iterator<SingleDynamicMethod> it = invokables.iterator(); it.hasNext();) {
final SingleDynamicMethod m = it.next();
if(!isApplicableDynamically(linkerServices, callSiteType, m)) {
it.remove();
}
}
// If no additional methods can apply at invocation time, and there's more than one maximally specific method
// based on call site signature, that is a link-time ambiguity. In a static scenario, javac would report an
// ambiguity error.
if(invokables.isEmpty() && maximallySpecifics.size() > 1) {
throw new BootstrapMethodError("Can't choose among " + maximallySpecifics + " for argument types "
+ callSiteType);
}
// Merge them all.
invokables.addAll(maximallySpecifics);
switch(invokables.size()) {
case 0: {
// No overloads can ever match the call site type
return null;
}
case 1: {
// Very lucky, we ended up with a single candidate method handle based on the call site signature; we
// can link it very simply by delegating to the SingleDynamicMethod.
return invokables.iterator().next().getInvocation(callSiteDescriptor, linkerServices);
}
default: {
// We have more than one candidate. We have no choice but to link to a method that resolves overloads on
// every invocation (alternatively, we could opportunistically link the one method that resolves for the
// current arguments, but we'd need to install a fairly complex guard for that and when it'd fail, we'd
// go back all the way to candidate selection. Note that we're resolving any potential caller sensitive
// methods here to their handles, as the OverloadedMethod instance is specific to a call site, so it
// has an already determined Lookup.
final List<MethodHandle> methodHandles = new ArrayList<>(invokables.size());
for(final SingleDynamicMethod method: invokables) {
methodHandles.add(method.getTarget(callSiteDescriptor));
}
return new OverloadedMethod(methodHandles, this, getCallSiteClassLoader(callSiteDescriptor), callSiteType, linkerServices, callSiteDescriptor).getInvoker();
}
}
}
private static final AccessControlContext GET_CALL_SITE_CLASS_LOADER_CONTEXT =
AccessControlContextFactory.createAccessControlContext(
"getClassLoader", SecureLookupSupplier.GET_LOOKUP_PERMISSION_NAME);
private static ClassLoader getCallSiteClassLoader(final CallSiteDescriptor callSiteDescriptor) {
return AccessController.doPrivileged(new PrivilegedAction<ClassLoader>() {
@Override
public ClassLoader run() {
return callSiteDescriptor.getLookup().lookupClass().getClassLoader();
}
}, GET_CALL_SITE_CLASS_LOADER_CONTEXT);
}
@Override
public boolean contains(final SingleDynamicMethod m) {
for(final SingleDynamicMethod method: methods) {
if(method.contains(m)) {
return true;
}
}
return false;
}
@Override
public boolean isConstructor() {
assert !methods.isEmpty();
return methods.getFirst().isConstructor();
}
@Override
public String toString() {
// First gather the names and sort them. This makes it consistent and easier to read.
final List<String> names = new ArrayList<>(methods.size());
int len = 0;
for (final SingleDynamicMethod m: methods) {
final String name = m.getName();
len += name.length();
names.add(name);
}
// Case insensitive sorting, so e.g. "Object" doesn't come before "boolean".
final Collator collator = Collator.getInstance();
collator.setStrength(Collator.SECONDARY);
Collections.sort(names, collator);
final String className = getClass().getName();
// Class name length + length of signatures + 2 chars/per signature for indentation and newline +
// 3 for brackets and initial newline
final int totalLength = className.length() + len + 2 * names.size() + 3;
final StringBuilder b = new StringBuilder(totalLength);
b.append('[').append(className).append('\n');
for(final String name: names) {
b.append(' ').append(name).append('\n');
}
b.append(']');
assert b.length() == totalLength;
return b.toString();
};
private static boolean isApplicableDynamically(final LinkerServices linkerServices, final MethodType callSiteType,
final SingleDynamicMethod m) {
final MethodType methodType = m.getMethodType();
final boolean varArgs = m.isVarArgs();
final int fixedArgLen = methodType.parameterCount() - (varArgs ? 1 : 0);
final int callSiteArgLen = callSiteType.parameterCount();
// Arity checks
if(varArgs) {
if(callSiteArgLen < fixedArgLen) {
return false;
}
} else if(callSiteArgLen != fixedArgLen) {
return false;
}
// Fixed arguments type checks, starting from 1, as receiver type doesn't participate
for(int i = 1; i < fixedArgLen; ++i) {
if(!isApplicableDynamically(linkerServices, callSiteType.parameterType(i), methodType.parameterType(i))) {
return false;
}
}
if(!varArgs) {
// Not vararg; both arity and types matched.
return true;
}
final Class<?> varArgArrayType = methodType.parameterType(fixedArgLen);
final Class<?> varArgType = varArgArrayType.getComponentType();
if(fixedArgLen == callSiteArgLen - 1) {
// Exactly one vararg; check both array type matching and array component type matching.
final Class<?> callSiteArgType = callSiteType.parameterType(fixedArgLen);
return isApplicableDynamically(linkerServices, callSiteArgType, varArgArrayType)
|| isApplicableDynamically(linkerServices, callSiteArgType, varArgType);
}
// Either zero, or more than one vararg; check if all actual vararg types match the vararg array component type.
for(int i = fixedArgLen; i < callSiteArgLen; ++i) {
if(!isApplicableDynamically(linkerServices, callSiteType.parameterType(i), varArgType)) {
return false;
}
}
return true;
}
private static boolean isApplicableDynamically(final LinkerServices linkerServices, final Class<?> callSiteType,
final Class<?> methodType) {
return isPotentiallyConvertible(callSiteType, methodType)
|| linkerServices.canConvert(callSiteType, methodType);
}
private ApplicableOverloadedMethods getApplicables(final MethodType callSiteType, final ApplicabilityTest test) {
return new ApplicableOverloadedMethods(methods, callSiteType, test);
}
Add a method to this overloaded method's set.
Params: - method – a method to add
/**
* Add a method to this overloaded method's set.
*
* @param method a method to add
*/
public void addMethod(final SingleDynamicMethod method) {
assert constructorFlagConsistent(method);
methods.add(method);
}
private boolean constructorFlagConsistent(final SingleDynamicMethod method) {
return methods.isEmpty()? true : (methods.getFirst().isConstructor() == method.isConstructor());
}
Determines whether one type can be potentially converted to another type at runtime. Allows a conversion between
any subtype and supertype in either direction, and also allows a conversion between any two primitive types, as
well as between any primitive type and any reference type that can hold a boxed primitive.
Params: - callSiteType – the parameter type at the call site
- methodType – the parameter type in the method declaration
Returns: true if callSiteType is potentially convertible to the methodType.
/**
* Determines whether one type can be potentially converted to another type at runtime. Allows a conversion between
* any subtype and supertype in either direction, and also allows a conversion between any two primitive types, as
* well as between any primitive type and any reference type that can hold a boxed primitive.
*
* @param callSiteType the parameter type at the call site
* @param methodType the parameter type in the method declaration
* @return true if callSiteType is potentially convertible to the methodType.
*/
private static boolean isPotentiallyConvertible(final Class<?> callSiteType, final Class<?> methodType) {
// Widening or narrowing reference conversion
if(InternalTypeUtilities.areAssignable(callSiteType, methodType)) {
return true;
}
if(callSiteType.isPrimitive()) {
// Allow any conversion among primitives, as well as from any
// primitive to any type that can receive a boxed primitive.
// TODO: narrow this a bit, i.e. allow, say, boolean to Character?
// MethodHandles.convertArguments() allows it, so we might need to
// too.
return methodType.isPrimitive() || isAssignableFromBoxedPrimitive(methodType);
}
if(methodType.isPrimitive()) {
// Allow conversion from any reference type that can contain a
// boxed primitive to any primitive.
// TODO: narrow this a bit too?
return isAssignableFromBoxedPrimitive(callSiteType);
}
return false;
}
private static final Set<Class<?>> PRIMITIVE_WRAPPER_TYPES = createPrimitiveWrapperTypes();
private static Set<Class<?>> createPrimitiveWrapperTypes() {
final Map<Class<?>, Class<?>> classes = new IdentityHashMap<>();
addClassHierarchy(classes, Boolean.class);
addClassHierarchy(classes, Byte.class);
addClassHierarchy(classes, Character.class);
addClassHierarchy(classes, Short.class);
addClassHierarchy(classes, Integer.class);
addClassHierarchy(classes, Long.class);
addClassHierarchy(classes, Float.class);
addClassHierarchy(classes, Double.class);
return classes.keySet();
}
private static void addClassHierarchy(final Map<Class<?>, Class<?>> map, final Class<?> clazz) {
if(clazz == null) {
return;
}
map.put(clazz, clazz);
addClassHierarchy(map, clazz.getSuperclass());
for(final Class<?> itf: clazz.getInterfaces()) {
addClassHierarchy(map, itf);
}
}
Returns true if the class can be assigned from any boxed primitive.
Params: - clazz – the class
Returns: true if the class can be assigned from any boxed primitive. Basically, it is true if the class is any
primitive wrapper class, or a superclass or superinterface of any primitive wrapper class.
/**
* Returns true if the class can be assigned from any boxed primitive.
*
* @param clazz the class
* @return true if the class can be assigned from any boxed primitive. Basically, it is true if the class is any
* primitive wrapper class, or a superclass or superinterface of any primitive wrapper class.
*/
private static boolean isAssignableFromBoxedPrimitive(final Class<?> clazz) {
return PRIMITIVE_WRAPPER_TYPES.contains(clazz);
}
}