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com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder Maven / Gradle / Ivy
package com.fitbur.bytebuddy.implementation.bind;
import edu.umd.cs.findbugs.annotations.SuppressFBWarnings;
import com.fitbur.bytebuddy.description.method.MethodDescription;
import com.fitbur.bytebuddy.description.method.MethodList;
import com.fitbur.bytebuddy.description.type.TypeDescription;
import com.fitbur.bytebuddy.implementation.Implementation;
import com.fitbur.bytebuddy.implementation.bind.annotation.BindingPriority;
import com.fitbur.bytebuddy.implementation.bytecode.StackManipulation;
import com.fitbur.bytebuddy.implementation.bytecode.member.MethodInvocation;
import com.fitbur.bytebuddy.jar.asm.MethodVisitor;
import java.util.*;
import static com.fitbur.bytebuddy.matcher.ElementMatchers.isVisibleTo;
/**
* A method delegation binder is responsible for creating a method binding for a source method to a
* target method . Such a binding allows to implement the source method by calling the target method.
*
* Usually, an implementation will attempt to bind a specific source method to a set of target method candidates
* where all legal bindings are considered for binding. To chose a specific candidate, an
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver}
* will be consulted for selecting a best binding.
*/
public interface MethodDelegationBinder {
/**
* Attempts a binding of a source method to a given target method.
*
* @param implementationTarget The target of the current implementation onto which this binding
* is to be applied.
* @param source The method that is to be bound to the {@code target} method.
* @param target The method that is to be invoked as a delegate.
* @return A binding representing this attempt to bind the {@code source} method to the {@code target} method.
*/
MethodBinding bind(Implementation.Target implementationTarget,
MethodDescription source,
MethodDescription target);
/**
* Implementations are used as delegates for invoking a method that was bound
* using a {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder}.
*/
interface MethodInvoker {
/**
* Creates a method invocation for a given method.
*
* @param methodDescription The method to be invoked.
* @return A stack manipulation encapsulating this method invocation.
*/
StackManipulation invoke(MethodDescription methodDescription);
/**
* A simple method invocation that merely uses the most general form of method invocation as provided by
* {@link com.fitbur.bytebuddy.implementation.bytecode.member.MethodInvocation}.
*/
enum Simple implements MethodInvoker {
/**
* The singleton instance.
*/
INSTANCE;
@Override
public StackManipulation invoke(MethodDescription methodDescription) {
return MethodInvocation.invoke(methodDescription);
}
@Override
public String toString() {
return "MethodDelegationBinder.MethodInvoker.Simple." + name();
}
}
/**
* A method invocation that enforces a virtual invocation that is dispatched on a given type.
*/
class Virtual implements MethodInvoker {
/**
* The type on which a method should be invoked virtually.
*/
private final TypeDescription typeDescription;
/**
* Creates an immutable method invoker that dispatches all methods on a given type.
*
* @param typeDescription The type on which the method is invoked by virtual invocation.
*/
public Virtual(TypeDescription typeDescription) {
this.typeDescription = typeDescription;
}
@Override
public StackManipulation invoke(MethodDescription methodDescription) {
return MethodInvocation.invoke(methodDescription).virtual(typeDescription);
}
@Override
public boolean equals(Object other) {
return this == other || !(other == null || getClass() != other.getClass())
&& typeDescription.equals(((Virtual) other).typeDescription);
}
@Override
public int hashCode() {
return typeDescription.hashCode();
}
@Override
public String toString() {
return "MethodDelegationBinder.MethodInvoker.Virtual{typeDescription=" + typeDescription + '}';
}
}
}
/**
* A binding attempt for a single parameter. Implementations of this type are a suggestion of composing a
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.MethodBinding}
* by using a
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.MethodBinding.Builder}.
* However, method bindings can also be composed without this type which is merely a suggestion.
*
* @param The type of the identification token for this parameter binding.
*/
interface ParameterBinding extends StackManipulation {
/**
* Returns an identification token for this binding.
*
* @return An identification token unique to this binding.
*/
T getIdentificationToken();
/**
* A singleton representation of an illegal binding for a method parameter. An illegal binding usually
* suggests that a source method cannot be bound to a specific target method.
*/
enum Illegal implements ParameterBinding {
/**
* The singleton instance.
*/
INSTANCE;
@Override
public Void getIdentificationToken() {
throw new IllegalStateException();
}
@Override
public boolean isValid() {
return false;
}
@Override
public Size apply(MethodVisitor methodVisitor, Implementation.Context implementationContext) {
throw new IllegalStateException("An illegal parameter binding must not be applied");
}
@Override
public String toString() {
return "MethodDelegationBinder.ParameterBinding.Illegal." + name();
}
}
/**
* An anonymous binding of a target method parameter.
*/
class Anonymous implements ParameterBinding {
/**
* A pseudo-token that is not exposed and therefore anonymous.
*/
private final Object anonymousToken;
/**
* The stack manipulation that represents the loading of the parameter binding onto the stack.
*/
private final StackManipulation delegate;
/**
* Creates a new, anonymous parameter binding.
*
* @param delegate The stack manipulation that is responsible for loading the parameter value for this
* target method parameter onto the stack.
*/
public Anonymous(StackManipulation delegate) {
this.delegate = delegate;
anonymousToken = new Object();
}
@Override
public Object getIdentificationToken() {
return anonymousToken;
}
@Override
public boolean isValid() {
return delegate.isValid();
}
@Override
public Size apply(MethodVisitor methodVisitor, Implementation.Context implementationContext) {
return delegate.apply(methodVisitor, implementationContext);
}
@Override
public boolean equals(Object other) {
return this == other || !(other == null || getClass() != other.getClass())
&& delegate.equals(((Anonymous) other).delegate);
}
@Override
public int hashCode() {
return 31 * delegate.hashCode();
}
@Override
public String toString() {
return "MethodDelegationBinder.ParameterBinding.Anonymous{" +
"anonymousToken=" + anonymousToken +
", delegate=" + delegate +
'}';
}
}
/**
* A uniquely identifiable parameter binding for a target method. Such bindings are usually later processed by
* a {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver}
* in order to resolve binding conflicts between several bindable target methods to the same source method.
*
* @param The type of the identification token.
* @see com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver
*/
class Unique implements ParameterBinding {
/**
* The token that identifies this parameter binding as unique.
*/
private final T identificationToken;
/**
* The stack manipulation that represents the loading of the parameter binding onto the stack.
*/
private final StackManipulation delegate;
/**
* Creates a new unique parameter binding representant.
*
* @param delegate The stack manipulation that loads the argument for this parameter onto the operand stack.
* @param identificationToken The token used for identifying this parameter binding.
*/
public Unique(StackManipulation delegate, T identificationToken) {
this.delegate = delegate;
this.identificationToken = identificationToken;
}
/**
* A factory method for creating a unique binding that infers the tokens type.
*
* @param delegate The stack manipulation delegate.
* @param identificationToken The identification token.
* @param The type of the identification token.
* @return A new instance representing this unique binding.
*/
public static Unique of(StackManipulation delegate, S identificationToken) {
return new Unique(delegate, identificationToken);
}
@Override
public T getIdentificationToken() {
return identificationToken;
}
@Override
public boolean isValid() {
return delegate.isValid();
}
@Override
public Size apply(MethodVisitor methodVisitor, Implementation.Context implementationContext) {
return delegate.apply(methodVisitor, implementationContext);
}
@Override
public boolean equals(Object other) {
if (this == other) return true;
if (other == null || getClass() != other.getClass()) return false;
Unique unique = (Unique) other;
return identificationToken.equals(unique.identificationToken) && delegate.equals(unique.delegate);
}
@Override
public int hashCode() {
int result = identificationToken.hashCode();
result = 31 * result + delegate.hashCode();
return result;
}
@Override
public String toString() {
return "MethodDelegationBinder.ParameterBinding.Unique{" +
"identificationToken=" + identificationToken +
", delegate=" + delegate +
'}';
}
}
}
/**
* A binding attempt created by a
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder}.
*/
interface MethodBinding extends StackManipulation {
/**
* Returns the target method's parameter index for a given parameter binding token.
*
* A binding token can be any object
* that implements valid {@link Object#hashCode()} and {@link Object#equals(Object)} methods in order
* to look up a given binding. This way, two bindings can be evaluated of having performed a similar type of
* binding such that these bindings can be compared and a dominant binding can be identified by an
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver}.
* Furthermore, a binding is implicitly required to insure the uniqueness of such a parameter binding.
*
* @param parameterBindingToken A token which is used to identify a specific unique binding for a given parameter
* of the target method.
* @return The target method's parameter index of this binding or {@code null} if no such argument binding
* was applied for this binding.
*/
Integer getTargetParameterIndex(Object parameterBindingToken);
/**
* Returns the target method of the method binding attempt.
*
* @return The target method to which the
*/
MethodDescription getTarget();
/**
* Representation of an attempt to bind a source method to a target method that is not applicable.
*
* @see com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder
*/
enum Illegal implements MethodBinding {
/**
* The singleton instance.
*/
INSTANCE;
@Override
public Integer getTargetParameterIndex(Object parameterBindingToken) {
throw new IllegalStateException("Method is not bound");
}
@Override
public MethodDescription getTarget() {
throw new IllegalStateException("Method is not bound");
}
@Override
public boolean isValid() {
return false;
}
@Override
public Size apply(MethodVisitor methodVisitor, Implementation.Context implementationContext) {
throw new IllegalStateException("Cannot delegate to an unbound method");
}
@Override
public String toString() {
return "MethodDelegationBinder.MethodBinding.Illegal." + name();
}
}
/**
* A mutable builder that allows to compose a
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.MethodBinding}
* by adding parameter bindings incrementally.
*/
class Builder {
/**
* The method invoker for invoking the actual method that is bound.
*/
private final MethodInvoker methodInvoker;
/**
* The target method that for which a binding is to be constructed by this builder..
*/
private final MethodDescription target;
/**
* The current list of stack manipulations for loading values for each parameter onto the operand stack.
*/
private final List parameterStackManipulations;
/**
* A mapping of identification tokens to the parameter index they were bound for.
*/
private final LinkedHashMap registeredTargetIndices;
/**
* The index of the next parameter that is to be bound.
*/
private int nextParameterIndex;
/**
* Creates a new builder for the binding of a given method.
*
* @param methodInvoker The method invoker that is used to create the method invocation of the {@code target}
* method.
* @param target The target method that is target of the binding.
*/
public Builder(MethodInvoker methodInvoker, MethodDescription target) {
this.methodInvoker = methodInvoker;
this.target = target;
parameterStackManipulations = new ArrayList(target.getParameters().size());
registeredTargetIndices = new LinkedHashMap();
nextParameterIndex = 0;
}
/**
* Appends a stack manipulation for the next parameter of the target method.
*
* @param parameterBinding A binding representing the next subsequent parameter of the method.
* @return {@code false} if the {@code parameterBindingToken} was already bound. A conflicting binding should
* usually abort the attempt of binding a method and this {@code Builder} should be discarded.
*/
public boolean append(ParameterBinding parameterBinding) {
parameterStackManipulations.add(parameterBinding);
return registeredTargetIndices.put(parameterBinding.getIdentificationToken(), nextParameterIndex++) == null;
}
/**
* Creates a binding that represents the bindings collected by this {@code Builder}.
*
* @param terminatingManipulation A stack manipulation that is applied after the method invocation.
* @return A binding representing the parameter bindings collected by this builder.
*/
public MethodBinding build(StackManipulation terminatingManipulation) {
if (target.getParameters().size() != nextParameterIndex) {
throw new IllegalStateException("The number of parameters bound does not equal the target's number of parameters");
}
return new Build(target,
registeredTargetIndices,
methodInvoker.invoke(target),
parameterStackManipulations,
terminatingManipulation);
}
/**
* Returns the current parameter index that will be bound on the next call of
* {@link Builder#append(com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.ParameterBinding)}.
*
* @return The next index to be bound.
*/
public int getNextParameterIndex() {
return nextParameterIndex;
}
@Override
public String toString() {
return "MethodDelegationBinder.MethodBinding.Builder{" +
"methodInvoker=" + methodInvoker +
", target=" + target +
", parameterStackManipulations=" + parameterStackManipulations +
", registeredTargetIndices=" + registeredTargetIndices +
", nextParameterIndex=" + nextParameterIndex +
'}';
}
/**
* A method binding that was created by a
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.MethodBinding.Builder}.
*/
protected static class Build implements MethodBinding {
/**
* The target method this binding represents.
*/
private final MethodDescription target;
/**
* A map of identification tokens to the indices of their binding parameters.
*/
private final Map registeredTargetIndices;
/**
* A stack manipulation that represents the actual method invocation.
*/
private final StackManipulation methodInvocation;
/**
* A list of manipulations that each represent the loading of a parameter value onto the operand stack.
*/
private final List parameterStackManipulations;
/**
* The stack manipulation that is applied after the method invocation.
*/
private final StackManipulation terminatingStackManipulation;
/**
* Creates a new method binding.
*
* @param target The target method this binding represents.
* @param registeredTargetIndices A map of identification tokens to the indices of their binding
* parameters.
* @param methodInvocation A stack manipulation that represents the actual method invocation.
* @param parameterStackManipulations A list of manipulations that each represent the loading of a
* parameter value onto the operand stack.
* @param terminatingStackManipulation The stack manipulation that is applied after the method invocation.
*/
protected Build(MethodDescription target,
Map registeredTargetIndices,
StackManipulation methodInvocation,
List parameterStackManipulations,
StackManipulation terminatingStackManipulation) {
this.target = target;
this.registeredTargetIndices = new HashMap(registeredTargetIndices);
this.methodInvocation = methodInvocation;
this.parameterStackManipulations = new ArrayList(parameterStackManipulations);
this.terminatingStackManipulation = terminatingStackManipulation;
}
@Override
public boolean isValid() {
boolean result = methodInvocation.isValid() && terminatingStackManipulation.isValid();
Iterator assignment = parameterStackManipulations.iterator();
while (result && assignment.hasNext()) {
result = assignment.next().isValid();
}
return result;
}
@Override
public Integer getTargetParameterIndex(Object parameterBindingToken) {
return registeredTargetIndices.get(parameterBindingToken);
}
@Override
public MethodDescription getTarget() {
return target;
}
@Override
public Size apply(MethodVisitor methodVisitor, Implementation.Context implementationContext) {
Size size = new Size(0, 0);
for (StackManipulation stackManipulation : parameterStackManipulations) {
size = size.aggregate(stackManipulation.apply(methodVisitor, implementationContext));
}
size = size.aggregate(methodInvocation.apply(methodVisitor, implementationContext));
return size.aggregate(terminatingStackManipulation.apply(methodVisitor, implementationContext));
}
@Override
public boolean equals(Object other) {
if (this == other) return true;
if (other == null || getClass() != other.getClass()) return false;
Build build = (Build) other;
return methodInvocation.equals(build.methodInvocation)
&& parameterStackManipulations.equals(build.parameterStackManipulations)
&& registeredTargetIndices.equals(build.registeredTargetIndices)
&& terminatingStackManipulation.equals(build.terminatingStackManipulation)
&& target.equals(build.target);
}
@Override
public int hashCode() {
int result = target.hashCode();
result = 31 * result + registeredTargetIndices.hashCode();
result = 31 * result + methodInvocation.hashCode();
result = 31 * result + parameterStackManipulations.hashCode();
result = 31 * result + terminatingStackManipulation.hashCode();
return result;
}
@Override
public String toString() {
return "MethodDelegationBinder.MethodBinding.Builder.Build{" +
"target=" + target +
", registeredTargetIndices=" + registeredTargetIndices +
", methodInvocation=" + methodInvocation +
", parameterStackManipulations=" + parameterStackManipulations +
", terminatingStackManipulation=" + terminatingStackManipulation +
'}';
}
}
}
}
/**
* Implementations of this interface are able to attempt the resolution of two successful bindings of a method
* to two different target methods in order to identify a dominating binding.
*/
@SuppressFBWarnings(value = "IC_SUPERCLASS_USES_SUBCLASS_DURING_INITIALIZATION", justification = "No circularity, initialization is safe")
interface AmbiguityResolver {
/**
* The default ambiguity resolver to use.
*/
AmbiguityResolver DEFAULT = new MethodDelegationBinder.AmbiguityResolver.Chain(BindingPriority.Resolver.INSTANCE,
DeclaringTypeResolver.INSTANCE,
ArgumentTypeResolver.INSTANCE,
MethodNameEqualityResolver.INSTANCE,
ParameterLengthResolver.INSTANCE);
/**
* Attempts to resolve to conflicting bindings.
*
* @param source The source method that was bound to both target methods.
* @param left The first successful binding of the {@code source} method.
* @param right The second successful binding of the {@code source} method.
* @return The resolution state when resolving a conflicting binding where
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver.Resolution#LEFT}
* indicates a successful binding to the {@code left} binding while
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver.Resolution#RIGHT}
* indicates a successful binding to the {@code right} binding.
*/
Resolution resolve(MethodDescription source, MethodBinding left, MethodBinding right);
/**
* A resolution state of an attempt to resolve two conflicting bindings.
*/
enum Resolution {
/**
* Describes a resolution state where no information about dominance could be gathered.
*/
UNKNOWN(true),
/**
* Describes a resolution state where the left method dominates the right method.
*/
LEFT(false),
/**
* Describes a resolution state where the right method dominates the left method.
*/
RIGHT(false),
/**
* Describes a resolution state where both methods have inflicting dominance over each other.
*/
AMBIGUOUS(true);
/**
* {@code true} if this resolution is unresolved.
*/
private final boolean unresolved;
/**
* Creates a new resolution.
*
* @param unresolved {@code true} if this resolution is unresolved.
*/
Resolution(boolean unresolved) {
this.unresolved = unresolved;
}
/**
* Checks if this binding is unresolved.
*
* @return {@code true} if this binding is unresolved.
*/
public boolean isUnresolved() {
return unresolved;
}
/**
* Merges two resolutions in order to determine their compatibility.
*
* @param other The resolution this resolution is to be checked against.
* @return The merged resolution.
*/
public Resolution merge(Resolution other) {
switch (this) {
case UNKNOWN:
return other;
case AMBIGUOUS:
return AMBIGUOUS;
case LEFT:
case RIGHT:
return other == this ? this : AMBIGUOUS;
default:
throw new AssertionError();
}
}
@Override
public String toString() {
return "MethodDelegationBinder.AmbiguityResolver.Resolution." + name();
}
}
/**
* An ambiguity resolver that does not attempt to resolve a conflicting binding.
*/
enum NoOp implements AmbiguityResolver {
/**
* The singleton instance.
*/
INSTANCE;
@Override
public Resolution resolve(MethodDescription source, MethodBinding left, MethodBinding right) {
return Resolution.UNKNOWN;
}
@Override
public String toString() {
return "MethodDelegationBinder.AmbiguityResolver.NoOp." + name();
}
}
/**
* An ambiguity resolver that always resolves in the specified direction.
*/
enum Directional implements AmbiguityResolver {
/**
* A resolver that always resolves to
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver.Resolution#LEFT}.
*/
LEFT(true),
/**
* A resolver that always resolves to
* {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver.Resolution#RIGHT}.
*/
RIGHT(false);
/**
* {@code true} if this instance should resolve to the left side.
*/
private final boolean left;
/**
* Creates a new directional resolver.
* @param left {@code true} if this instance should resolve to the left side.
*/
Directional(boolean left) {
this.left = left;
}
@Override
public Resolution resolve(MethodDescription source, MethodBinding left, MethodBinding right) {
return this.left
? Resolution.LEFT
: Resolution.RIGHT;
}
@Override
public String toString() {
return "MethodDelegationBinder.AmbiguityResolver.Directional." + name();
}
}
/**
* A chain of {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver}s
* that are applied in the given order until two bindings can be resolved.
*/
class Chain implements AmbiguityResolver {
/**
* A list of ambiguity resolvers that are applied by this chain in their order of application.
*/
private final List ambiguityResolvers;
/**
* Creates an immutable chain of ambiguity resolvers.
*
* @param ambiguityResolver The ambiguity resolvers to chain in the order of their application.
*/
public Chain(AmbiguityResolver... ambiguityResolver) {
this(Arrays.asList(ambiguityResolver));
}
/**
* Creates an immutable chain of ambiguity resolvers.
*
* @param ambiguityResolvers The ambiguity resolvers to chain in the order of their application.
*/
public Chain(List ambiguityResolvers) {
this.ambiguityResolvers = ambiguityResolvers;
}
@Override
public Resolution resolve(MethodDescription source, MethodBinding left, MethodBinding right) {
Resolution resolution = Resolution.UNKNOWN;
Iterator iterator = ambiguityResolvers.iterator();
while (resolution.isUnresolved() && iterator.hasNext()) {
resolution = iterator.next().resolve(source, left, right);
}
return resolution;
}
@Override
public boolean equals(Object other) {
return this == other || !(other == null || getClass() != other.getClass())
&& ambiguityResolvers.equals(((Chain) other).ambiguityResolvers);
}
@Override
public int hashCode() {
return ambiguityResolvers.hashCode();
}
@Override
public String toString() {
return "MethodDelegationBinder.AmbiguityResolver.Chain{ambiguityResolvers=" + ambiguityResolvers + '}';
}
}
}
/**
* A helper class that allows to identify a best binding for a given type and source method chosing from a list of given
* target methods by using a given {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder}
* and an {@link com.fitbur.bytebuddy.implementation.bind.MethodDelegationBinder.AmbiguityResolver}.
*
* The {@code Processor} will:
*
* Try to bind the {@code source} method using the {@code MethodDelegationBinder}.
* Find a best method among the successful bindings using the {@code AmbiguityResolver}.
*
*/
class Processor {
/**
* Represents the index of the only value of two elements in a list.
*/
private static final int ONLY = 0;
/**
* Represents the index of the left value of two elements in a list.
*/
private static final int LEFT = 0;
/**
* Represents the index of the right value of two elements in a list.
*/
private static final int RIGHT = 1;
/**
* This processor's method delegation binder.
*/
private final MethodDelegationBinder methodDelegationBinder;
/**
* The processor's ambiguity resolver.
*/
private final AmbiguityResolver ambiguityResolver;
/**
* Creates a new processor for a method delegation binder.
*
* @param methodDelegationBinder This processor's method delegation binder.
* @param ambiguityResolver The processor's ambiguity resolver.
*/
public Processor(MethodDelegationBinder methodDelegationBinder, AmbiguityResolver ambiguityResolver) {
this.methodDelegationBinder = methodDelegationBinder;
this.ambiguityResolver = ambiguityResolver;
}
/**
* @param implementationTarget The implementation target for binding the {@code source} method to.
* @param source The source method that is to be bound.
* @param targetCandidates All possible targets for the delegation binding that are to be considered.
* @return The best binding that was identified. If no such binding can be identified, an exception is thrown.
*/
public MethodBinding process(Implementation.Target implementationTarget, MethodDescription source, MethodList targetCandidates) {
List possibleDelegations = bind(implementationTarget, source, targetCandidates);
if (possibleDelegations.isEmpty()) {
throw new IllegalArgumentException("None of " + targetCandidates + " allows for delegation from " + source);
}
return resolve(source, possibleDelegations);
}
/**
* Creates a list of method bindings for any legal target method.
*
* @param implementationTarget The implementation target for binding the {@code source} method to.
* @param source The method that is to be bound to any {@code targets} method.
* @param targetCandidates All possible targets for the delegation binding that are to be considered.
* @return A list of valid method bindings representing a subset of the given target methods.
*/
private List bind(Implementation.Target implementationTarget, MethodDescription source, MethodList targetCandidates) {
List possibleDelegations = new ArrayList();
for (MethodDescription targetCandidate : targetCandidates.filter(isVisibleTo(implementationTarget.getInstrumentedType()))) {
MethodBinding methodBinding = methodDelegationBinder.bind(implementationTarget, source, targetCandidate);
if (methodBinding.isValid()) {
possibleDelegations.add(methodBinding);
}
}
return possibleDelegations;
}
/**
* Resolves the most specific target method of a list of legal method bindings.
*
* @param source The source method that is to be bound.
* @param targets A list of possible binding targets.
* @return The most specific method binding that was located from the given list of candidate targets.
*/
private MethodBinding resolve(MethodDescription source, List targets) {
switch (targets.size()) {
case 1:
return targets.get(ONLY);
case 2: {
MethodBinding left = targets.get(LEFT);
MethodBinding right = targets.get(RIGHT);
switch (ambiguityResolver.resolve(source, left, right)) {
case LEFT:
return left;
case RIGHT:
return right;
case AMBIGUOUS:
case UNKNOWN:
throw new IllegalArgumentException("Cannot resolve ambiguous delegation of " + source + " to " + left + " or " + right);
default:
throw new AssertionError();
}
}
default: /* case 3+: */ {
MethodBinding left = targets.get(LEFT);
MethodBinding right = targets.get(RIGHT);
switch (ambiguityResolver.resolve(source, left, right)) {
case LEFT:
targets.remove(RIGHT);
return resolve(source, targets);
case RIGHT:
targets.remove(LEFT);
return resolve(source, targets);
case AMBIGUOUS:
case UNKNOWN:
targets.remove(RIGHT); // Remove right element first due to index alteration!
targets.remove(LEFT);
MethodBinding subResult = resolve(source, targets);
switch (ambiguityResolver.resolve(source, left, subResult).merge(ambiguityResolver.resolve(source, right, subResult))) {
case RIGHT:
return subResult;
case LEFT:
case AMBIGUOUS:
case UNKNOWN:
throw new IllegalArgumentException("Cannot resolve ambiguous delegation of " + source + " to " + left + " or " + right);
default:
throw new AssertionError();
}
default:
throw new AssertionError();
}
}
}
}
@Override
public boolean equals(Object other) {
return this == other || !(other == null || getClass() != other.getClass())
&& ambiguityResolver.equals(((Processor) other).ambiguityResolver)
&& methodDelegationBinder.equals(((Processor) other).methodDelegationBinder);
}
@Override
public int hashCode() {
return 31 * methodDelegationBinder.hashCode() + ambiguityResolver.hashCode();
}
@Override
public String toString() {
return "MethodDelegationBinder.Processor{"
+ "methodDelegationBinder=" + methodDelegationBinder
+ ", ambiguityResolver=" + ambiguityResolver + '}';
}
}
}
