net.bytebuddy.asm.Advice Maven / Gradle / Ivy
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/*
* Copyright 2014 - Present Rafael Winterhalter
*
* Licensed 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 net.bytebuddy.asm;
import edu.umd.cs.findbugs.annotations.SuppressFBWarnings;
import net.bytebuddy.ClassFileVersion;
import net.bytebuddy.build.HashCodeAndEqualsPlugin;
import net.bytebuddy.build.RepeatedAnnotationPlugin;
import net.bytebuddy.description.annotation.AnnotationDescription;
import net.bytebuddy.description.annotation.AnnotationValue;
import net.bytebuddy.description.enumeration.EnumerationDescription;
import net.bytebuddy.description.field.FieldDescription;
import net.bytebuddy.description.method.MethodDescription;
import net.bytebuddy.description.method.MethodList;
import net.bytebuddy.description.method.ParameterDescription;
import net.bytebuddy.description.method.ParameterList;
import net.bytebuddy.description.type.TypeDefinition;
import net.bytebuddy.description.type.TypeDescription;
import net.bytebuddy.description.type.TypeList;
import net.bytebuddy.description.type.TypeVariableToken;
import net.bytebuddy.dynamic.ClassFileLocator;
import net.bytebuddy.dynamic.TargetType;
import net.bytebuddy.dynamic.scaffold.FieldLocator;
import net.bytebuddy.dynamic.scaffold.InstrumentedType;
import net.bytebuddy.dynamic.scaffold.MethodGraph;
import net.bytebuddy.implementation.FieldAccessor;
import net.bytebuddy.implementation.Implementation;
import net.bytebuddy.implementation.SuperMethodCall;
import net.bytebuddy.implementation.bytecode.Addition;
import net.bytebuddy.implementation.bytecode.ByteCodeAppender;
import net.bytebuddy.implementation.bytecode.Duplication;
import net.bytebuddy.implementation.bytecode.Removal;
import net.bytebuddy.implementation.bytecode.StackManipulation;
import net.bytebuddy.implementation.bytecode.StackSize;
import net.bytebuddy.implementation.bytecode.Throw;
import net.bytebuddy.implementation.bytecode.assign.Assigner;
import net.bytebuddy.implementation.bytecode.collection.ArrayAccess;
import net.bytebuddy.implementation.bytecode.collection.ArrayFactory;
import net.bytebuddy.implementation.bytecode.constant.ClassConstant;
import net.bytebuddy.implementation.bytecode.constant.DefaultValue;
import net.bytebuddy.implementation.bytecode.constant.IntegerConstant;
import net.bytebuddy.implementation.bytecode.constant.MethodConstant;
import net.bytebuddy.implementation.bytecode.constant.NullConstant;
import net.bytebuddy.implementation.bytecode.constant.SerializedConstant;
import net.bytebuddy.implementation.bytecode.member.FieldAccess;
import net.bytebuddy.implementation.bytecode.member.MethodInvocation;
import net.bytebuddy.implementation.bytecode.member.MethodVariableAccess;
import net.bytebuddy.matcher.ElementMatcher;
import net.bytebuddy.pool.TypePool;
import net.bytebuddy.utility.CompoundList;
import net.bytebuddy.utility.ConstantValue;
import net.bytebuddy.utility.JavaConstant;
import net.bytebuddy.utility.JavaType;
import net.bytebuddy.utility.OpenedClassReader;
import net.bytebuddy.utility.nullability.AlwaysNull;
import net.bytebuddy.utility.nullability.MaybeNull;
import net.bytebuddy.utility.visitor.ExceptionTableSensitiveMethodVisitor;
import net.bytebuddy.utility.visitor.LineNumberPrependingMethodVisitor;
import net.bytebuddy.utility.visitor.StackAwareMethodVisitor;
import net.bytebuddy.jar.asm.AnnotationVisitor;
import net.bytebuddy.jar.asm.Attribute;
import net.bytebuddy.jar.asm.ClassReader;
import net.bytebuddy.jar.asm.ClassVisitor;
import net.bytebuddy.jar.asm.ClassWriter;
import net.bytebuddy.jar.asm.Label;
import net.bytebuddy.jar.asm.MethodVisitor;
import net.bytebuddy.jar.asm.Opcodes;
import net.bytebuddy.jar.asm.Type;
import net.bytebuddy.jar.asm.TypePath;
import java.io.IOException;
import java.io.Serializable;
import java.lang.annotation.Annotation;
import java.lang.annotation.Documented;
import java.lang.annotation.ElementType;
import java.lang.annotation.Retention;
import java.lang.annotation.RetentionPolicy;
import java.lang.reflect.Constructor;
import java.lang.reflect.Field;
import java.lang.reflect.Method;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.Collections;
import java.util.HashMap;
import java.util.IdentityHashMap;
import java.util.LinkedHashMap;
import java.util.List;
import java.util.Map;
import java.util.SortedMap;
import java.util.TreeMap;
import static net.bytebuddy.matcher.ElementMatchers.isAbstract;
import static net.bytebuddy.matcher.ElementMatchers.named;
/**
*
* Advice wrappers copy the code of blueprint methods to be executed before and/or after a matched method. To achieve this, a {@code static}
* method of a class is annotated by {@link OnMethodEnter} and/or {@link OnMethodExit} and provided to an instance of this class.
*
*
* A method that is annotated with {@link OnMethodEnter} can annotate its parameters with {@link Argument} where field access to this parameter
* is substituted with access to the specified argument of the instrumented method. Alternatively, a parameter can be annotated by {@link This}
* where the {@code this} reference of the instrumented method is read when the parameter is accessed. This mechanism can also be used to assign a
* new value to the {@code this} reference of an instrumented method. If no annotation is used on a parameter, it is assigned the {@code n}-th
* parameter of the instrumented method for the {@code n}-th parameter of the advice method. All parameters must declare the exact same type as
* the parameters of the instrumented type or the method's declaring type for the {@link This} reference respectively if they are not marked as
* read-only. In the latter case, it suffices that a parameter type is a super type of the corresponding type of the instrumented method.
*
*
* A method that is annotated with {@link OnMethodExit} can equally annotate its parameters with {@link Argument} and {@link This}. Additionally,
* it can annotate a parameter with {@link Return} to receive the original method's return value. By reassigning the return value, it is possible
* to replace the returned value. If an instrumented method does not return a value, this annotation must not be used. If a method returns
* exceptionally, the parameter is set to its default value, i.e. to {@code 0} for primitive types and to {@code null} for reference types. The
* parameter's type must be equal to the instrumented method's return type if it is not set to read-only where it suffices to declare the
* parameter type to be of any super type to the instrumented method's return type. An exception can be read by annotating a parameter of type
* {@link Throwable} annotated with {@link Thrown} which is assigned the thrown {@link Throwable} or {@code null} if a method returns normally.
* Doing so, it is possible to exchange a thrown exception with any checked or unchecked exception.Finally, if a method annotated with
* {@link OnMethodEnter} exists and this method returns a value, this value can be accessed by a parameter annotated with {@link Enter}.
* This parameter must declare the same type as type being returned by the method annotated with {@link OnMethodEnter}. If the parameter is marked
* to be read-only, it suffices that the annotated parameter is of a super type of the return type of the method annotated by
* {@link OnMethodEnter}. If no such method exists or this method returns {@code void}, no such parameter must be declared. Any return value
* of a method that is annotated by {@link OnMethodExit} is discarded.
*
*
* If any advice method throws an exception, the method is terminated prematurely. If the method annotated by {@link OnMethodEnter} throws an exception,
* the method annotated by {@link OnMethodExit} method is not invoked. If the instrumented method throws an exception, the method that is annotated by
* {@link OnMethodExit} is only invoked if the {@link OnMethodExit#onThrowable()} property is set to {@code true} what is the default. If this property
* is set to {@code false}, the {@link Thrown} annotation must not be used on any parameter.
*
*
* Byte Buddy does not assert the visibility of any types that are referenced within an inlined advice method. It is the responsibility of
* the user of this class to assure that all types referenced within the advice methods are visible to the instrumented class. Failing to
* do so results in a {@link IllegalAccessError} at the instrumented class's runtime.
*
*
* Advice can be used either as a {@link AsmVisitorWrapper} where any declared methods of the currently instrumented type are enhanced without
* replacing an existing implementation. Alternatively, advice can function as an {@link Implementation} where, by default, the original super
* or default method of the instrumented method is invoked. If this is not possible or undesired, the delegate implementation can be changed
* by specifying a wrapped implementation explicitly by {@link Advice#wrap(Implementation)}.
*
*
* When using an advice class as a visitor wrapper, native or abstract methods which are silently skipped when advice matches such a method.
*
*
* Important: Since Java 6, class files contain stack map frames embedded into a method's byte code. When advice methods are compiled
* with a class file version less then Java 6 but are used for a class file that was compiled to Java 6 or newer, these stack map frames must be
* computed by ASM by using the {@link ClassWriter#COMPUTE_FRAMES} option. If the advice methods do not contain any branching instructions, this is
* not required. No action is required if the advice methods are at least compiled with Java 6 but are used on classes older than Java 6. This
* limitation only applies to advice methods that are inlined. Also, it is the responsibility of this class's user to assure that the advice method
* does not contain byte code constructs that are not supported by the class containing the instrumented method. In particular, pre Java-5
* try-finally blocks cannot be inlined into classes with newer byte code levels as the jsr instruction was deprecated. Also, classes prior
* to Java 7 do not support the invokedynamic command which must not be contained by an advice method if the instrumented method targets an
* older class file format version.
*
*
* Note: For the purpose of inlining, Java 5 and Java 6 byte code can be seen as the best candidate for advice methods. These versions do
* no longer allow subroutines, neither do they already allow invokedynamic instructions or method handles. This way, Java 5 and Java 6 byte
* code is compatible to both older and newer versions. One exception for backwards-incompatible byte code is the possibility to load type references
* from the constant pool onto the operand stack. These instructions can however easily be transformed for classes compiled to Java 4 and older
* by registering a {@link TypeConstantAdjustment} before the advice visitor.
*
*
* Note: It is not possible to trigger break points in inlined advice methods as the debugging information of the inlined advice is not
* preserved. It is not possible in Java to reference more than one source file per class what makes translating such debugging information
* impossible. It is however possible to set break points in advice methods when invoking the original advice target. This allows debugging
* of advice code within unit tests that invoke the advice method without instrumentation. As a consequence of not transferring debugging information,
* the names of the parameters of an advice method do not matter when inlining, neither does any meta information on the advice method's body
* such as annotations or parameter modifiers.
*
*
* Note: The behavior of this component is undefined if it is supplied with invalid byte code what might result in runtime exceptions.
*
*
* Note: When using advice from a Java agent with an {@link net.bytebuddy.agent.builder.AgentBuilder}, it often makes sense to not include
* any library-specific code in the agent's jar file. For being able to locate the advice code in the context of the library dependencies, Byte
* Buddy offers an {@link net.bytebuddy.agent.builder.AgentBuilder.Transformer.ForAdvice} implementation that allows registering the agent's
* class file locators for assembly of the advice class's description at runtime and with respect to the specific user dependencies.
*
*
* @see OnMethodEnter
* @see OnMethodExit
*/
@HashCodeAndEqualsPlugin.Enhance
public class Advice implements AsmVisitorWrapper.ForDeclaredMethods.MethodVisitorWrapper, Implementation {
/**
* Indicates that no class reader is available to an advice method.
*/
@AlwaysNull
private static final ClassReader UNDEFINED = null;
/**
* A reference to the {@link OnMethodEnter#skipOn()} method.
*/
private static final MethodDescription.InDefinedShape SKIP_ON;
/**
* A reference to the {@link OnMethodEnter#skipOnIndex()} method.
*/
private static final MethodDescription.InDefinedShape SKIP_ON_INDEX;
/**
* A reference to the {@link OnMethodEnter#prependLineNumber()} method.
*/
private static final MethodDescription.InDefinedShape PREPEND_LINE_NUMBER;
/**
* A reference to the {@link OnMethodEnter#inline()} method.
*/
private static final MethodDescription.InDefinedShape INLINE_ENTER;
/**
* A reference to the {@link OnMethodEnter#suppress()} method.
*/
private static final MethodDescription.InDefinedShape SUPPRESS_ENTER;
/**
* A reference to the {@link OnMethodExit#repeatOn()} method.
*/
private static final MethodDescription.InDefinedShape REPEAT_ON;
/**
* A reference to the {@link OnMethodExit#repeatOnIndex()} method.
*/
private static final MethodDescription.InDefinedShape REPEAT_ON_INDEX;
/**
* A reference to the {@link OnMethodExit#onThrowable()} method.
*/
private static final MethodDescription.InDefinedShape ON_THROWABLE;
/**
* A reference to the {@link OnMethodExit#backupArguments()} method.
*/
private static final MethodDescription.InDefinedShape BACKUP_ARGUMENTS;
/**
* A reference to the {@link OnMethodExit#inline()} method.
*/
private static final MethodDescription.InDefinedShape INLINE_EXIT;
/**
* A reference to the {@link OnMethodExit#suppress()} method.
*/
private static final MethodDescription.InDefinedShape SUPPRESS_EXIT;
/*
* Extracts the annotation values for the enter and exit advice annotations.
*/
static {
MethodList enter = TypeDescription.ForLoadedType.of(OnMethodEnter.class).getDeclaredMethods();
SKIP_ON = enter.filter(named("skipOn")).getOnly();
SKIP_ON_INDEX = enter.filter(named("skipOnIndex")).getOnly();
PREPEND_LINE_NUMBER = enter.filter(named("prependLineNumber")).getOnly();
INLINE_ENTER = enter.filter(named("inline")).getOnly();
SUPPRESS_ENTER = enter.filter(named("suppress")).getOnly();
MethodList exit = TypeDescription.ForLoadedType.of(OnMethodExit.class).getDeclaredMethods();
REPEAT_ON = exit.filter(named("repeatOn")).getOnly();
REPEAT_ON_INDEX = exit.filter(named("repeatOnIndex")).getOnly();
ON_THROWABLE = exit.filter(named("onThrowable")).getOnly();
BACKUP_ARGUMENTS = exit.filter(named("backupArguments")).getOnly();
INLINE_EXIT = exit.filter(named("inline")).getOnly();
SUPPRESS_EXIT = exit.filter(named("suppress")).getOnly();
}
/**
* The dispatcher for instrumenting the instrumented method upon entering.
*/
private final Dispatcher.Resolved.ForMethodEnter methodEnter;
/**
* The dispatcher for instrumenting the instrumented method upon exiting.
*/
private final Dispatcher.Resolved.ForMethodExit methodExit;
/**
* The assigner to use.
*/
private final Assigner assigner;
/**
* The exception handler to apply.
*/
private final ExceptionHandler exceptionHandler;
/**
* The delegate implementation to apply if this advice is used as an instrumentation.
*/
private final Implementation delegate;
/**
* Creates a new advice.
*
* @param methodEnter The dispatcher for instrumenting the instrumented method upon entering.
* @param methodExit The dispatcher for instrumenting the instrumented method upon exiting.
*/
protected Advice(Dispatcher.Resolved.ForMethodEnter methodEnter, Dispatcher.Resolved.ForMethodExit methodExit) {
this(methodEnter, methodExit, Assigner.DEFAULT, ExceptionHandler.Default.SUPPRESSING, SuperMethodCall.INSTANCE);
}
/**
* Creates a new advice.
*
* @param methodEnter The dispatcher for instrumenting the instrumented method upon entering.
* @param methodExit The dispatcher for instrumenting the instrumented method upon exiting.
* @param assigner The assigner to use.
* @param exceptionHandler The exception handler to apply.
* @param delegate The delegate implementation to apply if this advice is used as an instrumentation.
*/
private Advice(Dispatcher.Resolved.ForMethodEnter methodEnter,
Dispatcher.Resolved.ForMethodExit methodExit,
Assigner assigner,
ExceptionHandler exceptionHandler,
Implementation delegate) {
this.methodEnter = methodEnter;
this.methodExit = methodExit;
this.assigner = assigner;
this.exceptionHandler = exceptionHandler;
this.delegate = delegate;
}
/**
* Implements advice where every matched method is advised by the given type's advisory methods. The advices binary representation is
* accessed by querying the class loader of the supplied class for a class file.
*
* @param advice The type declaring the advice.
* @return A method visitor wrapper representing the supplied advice.
*/
public static Advice to(Class> advice) {
return to(advice, ClassFileLocator.ForClassLoader.of(advice.getClassLoader()));
}
/**
* Implements advice where every matched method is advised by the given type's advisory methods.
*
* @param advice The type declaring the advice.
* @param classFileLocator The class file locator for locating the advisory class's class file.
* @return A method visitor wrapper representing the supplied advice.
*/
public static Advice to(Class> advice, ClassFileLocator classFileLocator) {
return to(TypeDescription.ForLoadedType.of(advice), classFileLocator);
}
/**
* Implements advice where every matched method is advised by the given type's advisory methods. Using this method, a non-operational
* class file locator is specified for the advice target. This implies that only advice targets with the inline target set
* to {@code false} are resolvable by the returned instance.
*
* @param advice The type declaring the advice.
* @return A method visitor wrapper representing the supplied advice.
*/
public static Advice to(TypeDescription advice) {
return to(advice, ClassFileLocator.NoOp.INSTANCE);
}
/**
* Implements advice where every matched method is advised by the given type's advisory methods.
*
* @param advice A description of the type declaring the advice.
* @param classFileLocator The class file locator for locating the advisory class's class file.
* @return A method visitor wrapper representing the supplied advice.
*/
public static Advice to(TypeDescription advice, ClassFileLocator classFileLocator) {
return to(advice, PostProcessor.NoOp.INSTANCE, classFileLocator, Collections.>emptyList(), Delegator.ForRegularInvocation.Factory.INSTANCE);
}
/**
* Creates a new advice.
*
* @param advice A description of the type declaring the advice.
* @param postProcessorFactory The post processor factory to use.
* @param classFileLocator The class file locator for locating the advisory class's class file.
* @param userFactories A list of custom factories for user generated offset mappings.
* @param delegatorFactory The delegator factory to use.
* @return A method visitor wrapper representing the supplied advice.
*/
protected static Advice to(TypeDescription advice,
PostProcessor.Factory postProcessorFactory,
ClassFileLocator classFileLocator,
List extends OffsetMapping.Factory>> userFactories,
Delegator.Factory delegatorFactory) {
Dispatcher.Unresolved methodEnter = Dispatcher.Inactive.INSTANCE, methodExit = Dispatcher.Inactive.INSTANCE;
for (MethodDescription.InDefinedShape methodDescription : advice.getDeclaredMethods()) {
methodEnter = locate(OnMethodEnter.class, INLINE_ENTER, methodEnter, methodDescription, delegatorFactory);
methodExit = locate(OnMethodExit.class, INLINE_EXIT, methodExit, methodDescription, delegatorFactory);
}
if (!methodEnter.isAlive() && !methodExit.isAlive()) {
throw new IllegalArgumentException("No advice defined by " + advice);
}
try {
ClassReader classReader = methodEnter.isBinary() || methodExit.isBinary()
? OpenedClassReader.of(classFileLocator.locate(advice.getName()).resolve())
: UNDEFINED;
return new Advice(methodEnter.asMethodEnter(userFactories, classReader, methodExit, postProcessorFactory),
methodExit.asMethodExit(userFactories, classReader, methodEnter, postProcessorFactory));
} catch (IOException exception) {
throw new IllegalStateException("Error reading class file of " + advice, exception);
}
}
/**
* Implements advice where every matched method is advised by the given type's advisory methods. The advices binary representation is
* accessed by querying the class loader of the supplied class for a class file.
*
* @param enterAdvice The type declaring the enter advice.
* @param exitAdvice The type declaring the exit advice.
* @return A method visitor wrapper representing the supplied advice.
*/
public static Advice to(Class> enterAdvice, Class> exitAdvice) {
ClassLoader enterLoader = enterAdvice.getClassLoader(), exitLoader = exitAdvice.getClassLoader();
return to(enterAdvice, exitAdvice, enterLoader == exitLoader
? ClassFileLocator.ForClassLoader.of(enterLoader)
: new ClassFileLocator.Compound(ClassFileLocator.ForClassLoader.of(enterLoader), ClassFileLocator.ForClassLoader.of(exitLoader)));
}
/**
* Implements advice where every matched method is advised by the given type's advisory methods.
*
* @param enterAdvice The type declaring the enter advice.
* @param exitAdvice The type declaring the exit advice.
* @param classFileLocator The class file locator for locating the advisory class's class file.
* @return A method visitor wrapper representing the supplied advice.
*/
public static Advice to(Class> enterAdvice, Class> exitAdvice, ClassFileLocator classFileLocator) {
return to(TypeDescription.ForLoadedType.of(enterAdvice), TypeDescription.ForLoadedType.of(exitAdvice), classFileLocator);
}
/**
* Implements advice where every matched method is advised by the given type's advisory methods. Using this method, a non-operational
* class file locator is specified for the advice target. This implies that only advice targets with the inline target set
* to {@code false} are resolvable by the returned instance.
*
* @param enterAdvice The type declaring the enter advice.
* @param exitAdvice The type declaring the exit advice.
* @return A method visitor wrapper representing the supplied advice.
*/
public static Advice to(TypeDescription enterAdvice, TypeDescription exitAdvice) {
return to(enterAdvice, exitAdvice, ClassFileLocator.NoOp.INSTANCE);
}
/**
* Implements advice where every matched method is advised by the given type's advisory methods.
*
* @param enterAdvice The type declaring the enter advice.
* @param exitAdvice The type declaring the exit advice.
* @param classFileLocator The class file locator for locating the advisory class's class file.
* @return A method visitor wrapper representing the supplied advice.
*/
public static Advice to(TypeDescription enterAdvice, TypeDescription exitAdvice, ClassFileLocator classFileLocator) {
return to(enterAdvice, exitAdvice, PostProcessor.NoOp.INSTANCE, classFileLocator, Collections.>emptyList(), Delegator.ForRegularInvocation.Factory.INSTANCE);
}
/**
* Creates a new advice.
*
* @param enterAdvice The type declaring the enter advice.
* @param exitAdvice The type declaring the exit advice.
* @param postProcessorFactory The post processor factory to use.
* @param classFileLocator The class file locator for locating the advisory class's class file.
* @param userFactories A list of custom factories for user generated offset mappings.
* @param delegatorFactory The delegator factory to use.
* @return A method visitor wrapper representing the supplied advice.
*/
protected static Advice to(TypeDescription enterAdvice,
TypeDescription exitAdvice,
PostProcessor.Factory postProcessorFactory,
ClassFileLocator classFileLocator,
List extends OffsetMapping.Factory>> userFactories,
Delegator.Factory delegatorFactory) {
Dispatcher.Unresolved methodEnter = Dispatcher.Inactive.INSTANCE, methodExit = Dispatcher.Inactive.INSTANCE;
for (MethodDescription.InDefinedShape methodDescription : enterAdvice.getDeclaredMethods()) {
methodEnter = locate(OnMethodEnter.class, INLINE_ENTER, methodEnter, methodDescription, delegatorFactory);
}
if (!methodEnter.isAlive()) {
throw new IllegalArgumentException("No enter advice defined by " + enterAdvice);
}
for (MethodDescription.InDefinedShape methodDescription : exitAdvice.getDeclaredMethods()) {
methodExit = locate(OnMethodExit.class, INLINE_EXIT, methodExit, methodDescription, delegatorFactory);
}
if (!methodExit.isAlive()) {
throw new IllegalArgumentException("No exit advice defined by " + exitAdvice);
}
try {
return new Advice(methodEnter.asMethodEnter(userFactories, methodEnter.isBinary()
? OpenedClassReader.of(classFileLocator.locate(enterAdvice.getName()).resolve())
: UNDEFINED, methodExit, postProcessorFactory), methodExit.asMethodExit(userFactories, methodExit.isBinary()
? OpenedClassReader.of(classFileLocator.locate(exitAdvice.getName()).resolve())
: UNDEFINED, methodEnter, postProcessorFactory));
} catch (IOException exception) {
throw new IllegalStateException("Error reading class file of " + enterAdvice + " or " + exitAdvice, exception);
}
}
/**
* Locates a dispatcher for the method if available.
*
* @param type The annotation type that indicates a given form of advice that is currently resolved.
* @param property An annotation property that indicates if the advice method should be inlined.
* @param dispatcher Any previous dispatcher that was discovered or the previous dispatcher if found.
* @param methodDescription The method description that is considered as an advice method.
* @param delegatorFactory The delegator factory to use.
* @return A resolved dispatcher or the previous dispatcher if none was found.
*/
private static Dispatcher.Unresolved locate(Class extends Annotation> type,
MethodDescription.InDefinedShape property,
Dispatcher.Unresolved dispatcher,
MethodDescription.InDefinedShape methodDescription,
Delegator.Factory delegatorFactory) {
AnnotationDescription annotation = methodDescription.getDeclaredAnnotations().ofType(type);
if (annotation == null) {
return dispatcher;
} else if (dispatcher.isAlive()) {
throw new IllegalStateException("Duplicate advice for " + dispatcher + " and " + methodDescription);
} else if (!methodDescription.isStatic()) {
throw new IllegalStateException("Advice for " + methodDescription + " is not static");
} else {
return annotation.getValue(property).resolve(Boolean.class)
? new Dispatcher.Inlining(methodDescription)
: new Dispatcher.Delegating(methodDescription, delegatorFactory);
}
}
/**
* Allows for the configuration of custom annotations that are then bound to a dynamically computed, constant value.
*
* @return A builder for an {@link Advice} instrumentation with custom values.
* @see OffsetMapping.Factory
*/
public static WithCustomMapping withCustomMapping() {
return new WithCustomMapping();
}
/**
* Returns an ASM visitor wrapper that matches the given matcher and applies this advice to the matched methods.
*
* @param matcher The matcher identifying methods to apply the advice to.
* @return A suitable ASM visitor wrapper with the compute frames option enabled.
*/
public AsmVisitorWrapper.ForDeclaredMethods on(ElementMatcher super MethodDescription> matcher) {
return new AsmVisitorWrapper.ForDeclaredMethods().invokable(matcher, this);
}
/**
* {@inheritDoc}
*/
public MethodVisitor wrap(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
MethodVisitor methodVisitor,
Implementation.Context implementationContext,
TypePool typePool,
int writerFlags,
int readerFlags) {
return instrumentedMethod.isAbstract() || instrumentedMethod.isNative()
? methodVisitor
: doWrap(instrumentedType, instrumentedMethod, methodVisitor, implementationContext, writerFlags, readerFlags);
}
/**
* Wraps the method visitor to implement this advice.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param methodVisitor The method visitor to write to.
* @param implementationContext The implementation context to use.
* @param writerFlags The ASM writer flags to use.
* @param readerFlags The ASM reader flags to use.
* @return A method visitor that applies this advice.
*/
protected MethodVisitor doWrap(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
MethodVisitor methodVisitor,
Implementation.Context implementationContext,
int writerFlags,
int readerFlags) {
if (methodEnter.isPrependLineNumber()) {
methodVisitor = new LineNumberPrependingMethodVisitor(methodVisitor);
}
if (!methodExit.isAlive()) {
return new AdviceVisitor.WithoutExitAdvice(methodVisitor,
implementationContext,
assigner,
exceptionHandler.resolve(instrumentedMethod, instrumentedType),
instrumentedType,
instrumentedMethod,
methodEnter,
writerFlags,
readerFlags);
} else if (methodExit.getThrowable().represents(NoExceptionHandler.class)) {
return new AdviceVisitor.WithExitAdvice.WithoutExceptionHandling(methodVisitor,
implementationContext,
assigner,
exceptionHandler.resolve(instrumentedMethod, instrumentedType),
instrumentedType,
instrumentedMethod,
methodEnter,
methodExit,
writerFlags,
readerFlags);
} else if (instrumentedMethod.isConstructor()) {
throw new IllegalStateException("Cannot catch exception during constructor call for " + instrumentedMethod);
} else {
return new AdviceVisitor.WithExitAdvice.WithExceptionHandling(methodVisitor,
implementationContext,
assigner,
exceptionHandler.resolve(instrumentedMethod, instrumentedType),
instrumentedType,
instrumentedMethod,
methodEnter,
methodExit,
writerFlags,
readerFlags,
methodExit.getThrowable());
}
}
/**
* {@inheritDoc}
*/
public InstrumentedType prepare(InstrumentedType instrumentedType) {
return delegate.prepare(instrumentedType);
}
/**
* {@inheritDoc}
*/
public ByteCodeAppender appender(Target implementationTarget) {
return new Appender(this, implementationTarget, delegate.appender(implementationTarget));
}
/**
* Configures this advice to use the specified assigner. Any previous or default assigner is replaced.
*
* @param assigner The assigner to use,
* @return A version of this advice that uses the specified assigner.
*/
public Advice withAssigner(Assigner assigner) {
return new Advice(methodEnter, methodExit, assigner, exceptionHandler, delegate);
}
/**
* Configures this advice to call {@link Throwable#printStackTrace()} upon a suppressed exception.
*
* @return A version of this advice that prints any suppressed exception.
*/
public Advice withExceptionPrinting() {
return withExceptionHandler(ExceptionHandler.Default.PRINTING);
}
/**
* Configures this advice to execute the given stack manipulation upon a suppressed exception. The stack manipulation is executed with a
* {@link Throwable} instance on the operand stack. The stack must be empty upon completing the exception handler.
*
* @param exceptionHandler The exception handler to apply.
* @return A version of this advice that applies the supplied exception handler.
*/
public Advice withExceptionHandler(StackManipulation exceptionHandler) {
return withExceptionHandler(new ExceptionHandler.Simple(exceptionHandler));
}
/**
* Configures this advice to execute the given exception handler upon a suppressed exception. The stack manipulation is executed with a
* {@link Throwable} instance on the operand stack. The stack must be empty upon completing the exception handler.
*
* @param exceptionHandler The exception handler to apply.
* @return A version of this advice that applies the supplied exception handler.
*/
public Advice withExceptionHandler(ExceptionHandler exceptionHandler) {
return new Advice(methodEnter, methodExit, assigner, exceptionHandler, delegate);
}
/**
* Wraps the supplied implementation to have this advice applied around it.
*
* @param implementation The implementation to wrap.
* @return An implementation that applies the supplied implementation and wraps it with this advice.
*/
public Implementation wrap(Implementation implementation) {
return new Advice(methodEnter, methodExit, assigner, exceptionHandler, implementation);
}
/**
* Represents an offset mapping for an advice method to an alternative offset.
*/
public interface OffsetMapping {
/**
* Resolves an offset mapping to a given target offset.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method for which the mapping is to be resolved.
* @param assigner The assigner to use.
* @param argumentHandler The argument handler to use for resolving offsets of the local variable array of the instrumented method.
* @param sort The sort of the advice method being resolved.
* @return A suitable target mapping.
*/
Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort);
/**
* A target offset of an offset mapping.
*/
interface Target {
/**
* Resolves a read instruction.
*
* @return A stack manipulation that represents a reading of an advice parameter.
*/
StackManipulation resolveRead();
/**
* Resolves a write instruction.
*
* @return A stack manipulation that represents a writing to an advice parameter.
*/
StackManipulation resolveWrite();
/**
* Resolves an increment instruction.
*
* @param value The incrementation value.
* @return A stack manipulation that represents a writing to an advice parameter.
*/
StackManipulation resolveIncrement(int value);
/**
* An adapter class for a target that only can be read.
*/
abstract class AbstractReadOnlyAdapter implements Target {
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
throw new IllegalStateException("Cannot write to read-only value");
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
throw new IllegalStateException("Cannot write to read-only value");
}
}
/**
* A target for an offset mapping that represents a non-operational value. All writes are discarded and a value's
* default value is returned upon every read.
*/
@HashCodeAndEqualsPlugin.Enhance
abstract class ForDefaultValue implements Target {
/**
* The represented type.
*/
protected final TypeDefinition typeDefinition;
/**
* A stack manipulation to apply after a read instruction.
*/
protected final StackManipulation readAssignment;
/**
* Creates a new target for a default value.
*
* @param typeDefinition The represented type.
* @param readAssignment A stack manipulation to apply after a read instruction.
*/
protected ForDefaultValue(TypeDefinition typeDefinition, StackManipulation readAssignment) {
this.typeDefinition = typeDefinition;
this.readAssignment = readAssignment;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveRead() {
return new StackManipulation.Compound(DefaultValue.of(typeDefinition), readAssignment);
}
/**
* A read-only target for a default value.
*/
public static class ReadOnly extends ForDefaultValue {
/**
* Creates a new writable target for a default value.
*
* @param typeDefinition The represented type.
*/
public ReadOnly(TypeDefinition typeDefinition) {
this(typeDefinition, StackManipulation.Trivial.INSTANCE);
}
/**
* Creates a new -writable target for a default value.
*
* @param typeDefinition The represented type.
* @param readAssignment A stack manipulation to apply after a read instruction.
*/
public ReadOnly(TypeDefinition typeDefinition, StackManipulation readAssignment) {
super(typeDefinition, readAssignment);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
throw new IllegalStateException("Cannot write to read-only default value");
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
throw new IllegalStateException("Cannot write to read-only default value");
}
}
/**
* A read-write target for a default value.
*/
public static class ReadWrite extends ForDefaultValue {
/**
* Creates a new read-only target for a default value.
*
* @param typeDefinition The represented type.
*/
public ReadWrite(TypeDefinition typeDefinition) {
this(typeDefinition, StackManipulation.Trivial.INSTANCE);
}
/**
* Creates a new read-only target for a default value.
*
* @param typeDefinition The represented type.
* @param readAssignment A stack manipulation to apply after a read instruction.
*/
public ReadWrite(TypeDefinition typeDefinition, StackManipulation readAssignment) {
super(typeDefinition, readAssignment);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
return Removal.of(typeDefinition);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
return StackManipulation.Trivial.INSTANCE;
}
}
}
/**
* A target for an offset mapping that represents a local variable.
*/
@HashCodeAndEqualsPlugin.Enhance
abstract class ForVariable implements Target {
/**
* The represented type.
*/
protected final TypeDefinition typeDefinition;
/**
* The value's offset.
*/
protected final int offset;
/**
* An assignment to execute upon reading a value.
*/
protected final StackManipulation readAssignment;
/**
* Creates a new target for a local variable mapping.
*
* @param typeDefinition The represented type.
* @param offset The value's offset.
* @param readAssignment An assignment to execute upon reading a value.
*/
protected ForVariable(TypeDefinition typeDefinition, int offset, StackManipulation readAssignment) {
this.typeDefinition = typeDefinition;
this.offset = offset;
this.readAssignment = readAssignment;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveRead() {
return new StackManipulation.Compound(MethodVariableAccess.of(typeDefinition).loadFrom(offset), readAssignment);
}
/**
* A target for a read-only mapping of a local variable.
*/
public static class ReadOnly extends ForVariable {
/**
* Creates a read-only mapping for a local variable.
*
* @param typeDefinition The represented type.
* @param offset The value's offset.
*/
public ReadOnly(TypeDefinition typeDefinition, int offset) {
this(typeDefinition, offset, StackManipulation.Trivial.INSTANCE);
}
/**
* Creates a read-only mapping for a local variable.
*
* @param typeDefinition The represented type.
* @param offset The value's offset.
* @param readAssignment An assignment to execute upon reading a value.
*/
public ReadOnly(TypeDefinition typeDefinition, int offset, StackManipulation readAssignment) {
super(typeDefinition, offset, readAssignment);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
throw new IllegalStateException("Cannot write to read-only parameter " + typeDefinition + " at " + offset);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
throw new IllegalStateException("Cannot write to read-only variable " + typeDefinition + " at " + offset);
}
}
/**
* A target for a writable mapping of a local variable.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class ReadWrite extends ForVariable {
/**
* A stack manipulation to apply upon a write to the variable.
*/
private final StackManipulation writeAssignment;
/**
* Creates a new target mapping for a writable local variable.
*
* @param typeDefinition The represented type.
* @param offset The value's offset.
*/
public ReadWrite(TypeDefinition typeDefinition, int offset) {
this(typeDefinition, offset, StackManipulation.Trivial.INSTANCE, StackManipulation.Trivial.INSTANCE);
}
/**
* Creates a new target mapping for a writable local variable.
*
* @param typeDefinition The represented type.
* @param offset The value's offset.
* @param readAssignment An assignment to execute upon reading a value.
* @param writeAssignment A stack manipulation to apply upon a write to the variable.
*/
public ReadWrite(TypeDefinition typeDefinition, int offset, StackManipulation readAssignment, StackManipulation writeAssignment) {
super(typeDefinition, offset, readAssignment);
this.writeAssignment = writeAssignment;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
return new StackManipulation.Compound(writeAssignment, MethodVariableAccess.of(typeDefinition).storeAt(offset));
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
return typeDefinition.represents(int.class)
? MethodVariableAccess.of(typeDefinition).increment(offset, value)
: new StackManipulation.Compound(resolveRead(), IntegerConstant.forValue(1), Addition.INTEGER, resolveWrite());
}
}
}
/**
* A target mapping for an array of all local variables.
*/
@HashCodeAndEqualsPlugin.Enhance
abstract class ForArray implements Target {
/**
* The compound target type.
*/
protected final TypeDescription.Generic target;
/**
* The stack manipulations to apply upon reading a variable array.
*/
protected final List extends StackManipulation> valueReads;
/**
* Creates a new target mapping for an array of all local variables.
*
* @param target The compound target type.
* @param valueReads The stack manipulations to apply upon reading a variable array.
*/
protected ForArray(TypeDescription.Generic target, List extends StackManipulation> valueReads) {
this.target = target;
this.valueReads = valueReads;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveRead() {
return ArrayFactory.forType(target).withValues(valueReads);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
throw new IllegalStateException("Cannot increment read-only array value");
}
/**
* A target mapping for a read-only target mapping for an array of local variables.
*/
public static class ReadOnly extends ForArray {
/**
* Creates a read-only target mapping for an array of all local variables.
*
* @param target The compound target type.
* @param valueReads The stack manipulations to apply upon reading a variable array.
*/
public ReadOnly(TypeDescription.Generic target, List extends StackManipulation> valueReads) {
super(target, valueReads);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
throw new IllegalStateException("Cannot write to read-only array value");
}
}
/**
* A target mapping for a writable target mapping for an array of local variables.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class ReadWrite extends ForArray {
/**
* The stack manipulations to apply upon writing to a variable array.
*/
private final List extends StackManipulation> valueWrites;
/**
* Creates a writable target mapping for an array of all local variables.
*
* @param target The compound target type.
* @param valueReads The stack manipulations to apply upon reading a variable array.
* @param valueWrites The stack manipulations to apply upon writing to a variable array.
*/
public ReadWrite(TypeDescription.Generic target,
List extends StackManipulation> valueReads,
List extends StackManipulation> valueWrites) {
super(target, valueReads);
this.valueWrites = valueWrites;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
return new StackManipulation.Compound(ArrayAccess.of(target).forEach(valueWrites), Removal.SINGLE);
}
}
}
/**
* A target for an offset mapping that loads a field value.
*/
@HashCodeAndEqualsPlugin.Enhance
abstract class ForField implements Target {
/**
* The field value to load.
*/
protected final FieldDescription fieldDescription;
/**
* The stack manipulation to apply upon a read.
*/
protected final StackManipulation readAssignment;
/**
* Creates a new target for a field value mapping.
*
* @param fieldDescription The field value to load.
* @param readAssignment The stack manipulation to apply upon a read.
*/
protected ForField(FieldDescription fieldDescription, StackManipulation readAssignment) {
this.fieldDescription = fieldDescription;
this.readAssignment = readAssignment;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveRead() {
return new StackManipulation.Compound(fieldDescription.isStatic()
? StackManipulation.Trivial.INSTANCE
: MethodVariableAccess.loadThis(), FieldAccess.forField(fieldDescription).read(), readAssignment);
}
/**
* A read-only mapping for a field value.
*/
public static class ReadOnly extends ForField {
/**
* Creates a new read-only mapping for a field.
*
* @param fieldDescription The field value to load.
*/
public ReadOnly(FieldDescription fieldDescription) {
this(fieldDescription, StackManipulation.Trivial.INSTANCE);
}
/**
* Creates a new read-only mapping for a field.
*
* @param fieldDescription The field value to load.
* @param readAssignment The stack manipulation to apply upon a read.
*/
public ReadOnly(FieldDescription fieldDescription, StackManipulation readAssignment) {
super(fieldDescription, readAssignment);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
throw new IllegalStateException("Cannot write to read-only field value");
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
throw new IllegalStateException("Cannot write to read-only field value");
}
}
/**
* A write-only mapping for a field value, typically to be used for constructors prior to invoking the super-constructor.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class WriteOnly implements Target {
/**
* The field value to load.
*/
private final FieldDescription fieldDescription;
/**
* An assignment to apply prior to a field write.
*/
private final StackManipulation writeAssignment;
/**
* Creates a write-only mapping for a field value.
*
* @param fieldDescription The field value to load.
* @param writeAssignment An assignment to apply prior to a field write.
*/
protected WriteOnly(FieldDescription fieldDescription, StackManipulation writeAssignment) {
this.fieldDescription = fieldDescription;
this.writeAssignment = writeAssignment;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveRead() {
throw new IllegalStateException("Cannot read write-only field value");
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
StackManipulation preparation;
if (fieldDescription.isStatic()) {
preparation = StackManipulation.Trivial.INSTANCE;
} else {
preparation = new StackManipulation.Compound(
MethodVariableAccess.loadThis(),
Duplication.SINGLE.flipOver(fieldDescription.getType()),
Removal.SINGLE
);
}
return new StackManipulation.Compound(writeAssignment, preparation, FieldAccess.forField(fieldDescription).write());
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
throw new IllegalStateException("Cannot increment write-only field value");
}
}
/**
* A mapping for a writable field.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class ReadWrite extends ForField {
/**
* An assignment to apply prior to a field write.
*/
private final StackManipulation writeAssignment;
/**
* Creates a new target for a writable field.
*
* @param fieldDescription The field value to load.
*/
public ReadWrite(FieldDescription fieldDescription) {
this(fieldDescription, StackManipulation.Trivial.INSTANCE, StackManipulation.Trivial.INSTANCE);
}
/**
* Creates a new target for a writable field.
*
* @param fieldDescription The field value to load.
* @param readAssignment The stack manipulation to apply upon a read.
* @param writeAssignment An assignment to apply prior to a field write.
*/
public ReadWrite(FieldDescription fieldDescription, StackManipulation readAssignment, StackManipulation writeAssignment) {
super(fieldDescription, readAssignment);
this.writeAssignment = writeAssignment;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
StackManipulation preparation;
if (fieldDescription.isStatic()) {
preparation = StackManipulation.Trivial.INSTANCE;
} else {
preparation = new StackManipulation.Compound(
MethodVariableAccess.loadThis(),
Duplication.SINGLE.flipOver(fieldDescription.getType()),
Removal.SINGLE
);
}
return new StackManipulation.Compound(writeAssignment, preparation, FieldAccess.forField(fieldDescription).write());
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
return new StackManipulation.Compound(
resolveRead(),
IntegerConstant.forValue(value),
Addition.INTEGER,
resolveWrite()
);
}
}
}
/**
* A target for an offset mapping that represents a read-only stack manipulation.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForStackManipulation implements Target {
/**
* The represented stack manipulation.
*/
private final StackManipulation stackManipulation;
/**
* Creates a new target for an offset mapping for a stack manipulation.
*
* @param stackManipulation The represented stack manipulation.
*/
public ForStackManipulation(StackManipulation stackManipulation) {
this.stackManipulation = stackManipulation;
}
/**
* Creates a target for a {@link Method} or {@link Constructor} constant.
*
* @param methodDescription The method or constructor to represent.
* @return A mapping for a method or constructor constant.
*/
public static Target of(MethodDescription.InDefinedShape methodDescription) {
return new ForStackManipulation(MethodConstant.of(methodDescription));
}
/**
* Creates a target for an offset mapping for a type constant.
*
* @param typeDescription The type constant to represent.
* @return A mapping for a type constant.
*/
public static Target of(TypeDescription typeDescription) {
return new ForStackManipulation(ClassConstant.of(typeDescription));
}
/**
* Creates a target for an offset mapping for a constant value or {@code null}.
*
* @param value The constant value to represent or {@code null}.
* @return An appropriate target for an offset mapping.
*/
public static Target of(@MaybeNull Object value) {
return new ForStackManipulation(value == null
? NullConstant.INSTANCE
: ConstantValue.Simple.wrap(value).toStackManipulation());
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveRead() {
return stackManipulation;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
throw new IllegalStateException("Cannot write to constant value: " + stackManipulation);
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
throw new IllegalStateException("Cannot write to constant value: " + stackManipulation);
}
/**
* A constant value that can be written to.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Writable implements Target {
/**
* The reading stack manipulation.
*/
private final StackManipulation read;
/**
* The writing stack manipulation.
*/
private final StackManipulation write;
/**
* Creates a writable target.
*
* @param read The reading stack manipulation.
* @param write The writing stack manipulation.
*/
public Writable(StackManipulation read, StackManipulation write) {
this.read = read;
this.write = write;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveRead() {
return read;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveWrite() {
return write;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolveIncrement(int value) {
throw new IllegalStateException("Cannot increment mutable constant value: " + write);
}
}
}
}
/**
* Represents a factory for creating a {@link OffsetMapping} for a given parameter for a given annotation.
*
* @param The annotation type that triggers this factory.
*/
interface Factory {
/**
* Returns the annotation type of this factory.
*
* @return The factory's annotation type.
*/
Class getAnnotationType();
/**
* Creates a new offset mapping for the supplied parameter if possible.
*
* @param target The parameter description for which to resolve an offset mapping.
* @param annotation The annotation that triggered this factory.
* @param adviceType {@code true} if the binding is applied using advice method delegation.
* @return A resolved offset mapping or {@code null} if no mapping can be resolved for this parameter.
*/
OffsetMapping make(ParameterDescription.InDefinedShape target, AnnotationDescription.Loadable annotation, AdviceType adviceType);
/**
* Describes the type of advice being applied.
*/
enum AdviceType {
/**
* Indicates advice where the invocation is delegated.
*/
DELEGATION(true),
/**
* Indicates advice where the invocation's code is copied into the target method.
*/
INLINING(false);
/**
* {@code true} if delegation is used.
*/
private final boolean delegation;
/**
* Creates a new advice type.
*
* @param delegation {@code true} if delegation is used.
*/
AdviceType(boolean delegation) {
this.delegation = delegation;
}
/**
* Returns {@code true} if delegation is used.
*
* @return {@code true} if delegation is used.
*/
public boolean isDelegation() {
return delegation;
}
}
/**
* A simple factory that binds a constant offset mapping.
*
* @param The annotation type that represents this offset mapping.
*/
@HashCodeAndEqualsPlugin.Enhance
class Simple implements Factory {
/**
* The annotation type being bound.
*/
private final Class annotationType;
/**
* The fixed offset mapping.
*/
private final OffsetMapping offsetMapping;
/**
* Creates a simple factory for a simple binding for an offset mapping.
*
* @param annotationType The annotation type being bound.
* @param offsetMapping The fixed offset mapping.
*/
public Simple(Class annotationType, OffsetMapping offsetMapping) {
this.annotationType = annotationType;
this.offsetMapping = offsetMapping;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target, AnnotationDescription.Loadable annotation, AdviceType adviceType) {
return offsetMapping;
}
}
/**
* A factory for an annotation whose use is not permitted.
*
* @param The annotation type this factory binds.
*/
@HashCodeAndEqualsPlugin.Enhance
class Illegal implements Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* Creates a factory that does not permit the usage of the represented annotation.
*
* @param annotationType The annotation type.
*/
public Illegal(Class annotationType) {
this.annotationType = annotationType;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target, AnnotationDescription.Loadable annotation, AdviceType adviceType) {
throw new IllegalStateException("Usage of " + annotationType + " is not allowed on " + target);
}
}
}
/**
* Describes the sort of the executed advice.
*/
enum Sort {
/**
* Indicates that an offset is mapped for an enter advice.
*/
ENTER {
@Override
public boolean isPremature(MethodDescription methodDescription) {
return methodDescription.isConstructor();
}
},
/**
* Indicates that an offset is mapped for an exit advice.
*/
EXIT {
@Override
public boolean isPremature(MethodDescription methodDescription) {
return false;
}
};
/**
* Checks if an advice is executed in a premature state, i.e. the instrumented method is a constructor where the super constructor is not
* yet invoked. In this case, the {@code this} reference is not yet initialized and therefore not available.
*
* @param methodDescription The instrumented method.
* @return {@code true} if the advice is executed premature for the instrumented method.
*/
public abstract boolean isPremature(MethodDescription methodDescription);
}
/**
* An offset mapping for a given parameter of the instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
abstract class ForArgument implements OffsetMapping {
/**
* The type expected by the advice method.
*/
protected final TypeDescription.Generic target;
/**
* Determines if the parameter is to be treated as read-only.
*/
protected final boolean readOnly;
/**
* The typing to apply when assigning values.
*/
private final Assigner.Typing typing;
/**
* Creates a new offset mapping for a parameter of the instrumented method.
*
* @param target The type expected by the advice method.
* @param readOnly Determines if the parameter is to be treated as read-only.
* @param typing The typing to apply.
*/
protected ForArgument(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing) {
this.target = target;
this.readOnly = readOnly;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
ParameterDescription parameterDescription = resolve(instrumentedMethod);
StackManipulation readAssignment = assigner.assign(parameterDescription.getType(), target, typing);
if (!readAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + parameterDescription + " to " + target);
} else if (readOnly) {
return new Target.ForVariable.ReadOnly(parameterDescription.getType(), argumentHandler.argument(parameterDescription.getOffset()), readAssignment);
} else {
StackManipulation writeAssignment = assigner.assign(target, parameterDescription.getType(), typing);
if (!writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + parameterDescription + " to " + target);
}
return new Target.ForVariable.ReadWrite(parameterDescription.getType(), argumentHandler.argument(parameterDescription.getOffset()), readAssignment,
writeAssignment);
}
}
/**
* Resolves the bound parameter.
*
* @param instrumentedMethod The instrumented method.
* @return The bound parameter.
*/
protected abstract ParameterDescription resolve(MethodDescription instrumentedMethod);
/**
* An offset mapping for a parameter of the instrumented method with a specific index.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Unresolved extends ForArgument {
/**
* The index of the parameter.
*/
private final int index;
/**
* {@code true} if the parameter binding is optional.
*/
private final boolean optional;
/**
* Creates a new offset binding for a parameter with a given index.
*
* @param target The target type.
* @param annotation The annotation that triggers this binding.
*/
protected Unresolved(TypeDescription.Generic target, AnnotationDescription.Loadable annotation) {
this(target, annotation.getValue(Factory.ARGUMENT_READ_ONLY).resolve(Boolean.class),
annotation.getValue(Factory.ARGUMENT_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class),
annotation.getValue(Factory.ARGUMENT_VALUE).resolve(Integer.class),
annotation.getValue(Factory.ARGUMENT_OPTIONAL).resolve(Boolean.class));
}
/**
* Creates a new offset binding for a parameter with a given index.
*
* @param parameterDescription The parameter triggering this binding.
*/
protected Unresolved(ParameterDescription parameterDescription) {
this(parameterDescription.getType(), true, Assigner.Typing.STATIC, parameterDescription.getIndex());
}
/**
* Creates a non-optional offset binding for a parameter with a given index.
*
* @param target The type expected by the advice method.
* @param readOnly Determines if the parameter is to be treated as read-only.
* @param typing The typing to apply.
* @param index The index of the parameter.
*/
public Unresolved(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing, int index) {
this(target, readOnly, typing, index, false);
}
/**
* Creates a new offset binding for a parameter with a given index.
*
* @param target The type expected by the advice method.
* @param readOnly Determines if the parameter is to be treated as read-only.
* @param typing The typing to apply.
* @param index The index of the parameter.
* @param optional {@code true} if the parameter binding is optional.
*/
public Unresolved(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing, int index, boolean optional) {
super(target, readOnly, typing);
this.index = index;
this.optional = optional;
}
@Override
protected ParameterDescription resolve(MethodDescription instrumentedMethod) {
ParameterList> parameters = instrumentedMethod.getParameters();
if (parameters.size() <= index) {
throw new IllegalStateException(instrumentedMethod + " does not define an index " + index);
} else {
return parameters.get(index);
}
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
if (optional && instrumentedMethod.getParameters().size() <= index) {
return readOnly
? new Target.ForDefaultValue.ReadOnly(target)
: new Target.ForDefaultValue.ReadWrite(target);
}
return super.resolve(instrumentedType, instrumentedMethod, assigner, argumentHandler, sort);
}
/**
* A factory for a mapping of a parameter of the instrumented method.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* A description of the {@link Argument#value()} method.
*/
private static final MethodDescription.InDefinedShape ARGUMENT_VALUE;
/**
* A description of the {@link Argument#readOnly()} method.
*/
private static final MethodDescription.InDefinedShape ARGUMENT_READ_ONLY;
/**
* A description of the {@link Argument#typing()} method.
*/
private static final MethodDescription.InDefinedShape ARGUMENT_TYPING;
/**
* A description of the {@link Argument#optional()} method.
*/
private static final MethodDescription.InDefinedShape ARGUMENT_OPTIONAL;
/*
* Resolves annotation properties.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(Argument.class).getDeclaredMethods();
ARGUMENT_VALUE = methods.filter(named("value")).getOnly();
ARGUMENT_READ_ONLY = methods.filter(named("readOnly")).getOnly();
ARGUMENT_TYPING = methods.filter(named("typing")).getOnly();
ARGUMENT_OPTIONAL = methods.filter(named("optional")).getOnly();
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return Argument.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (adviceType.isDelegation() && !annotation.getValue(ARGUMENT_READ_ONLY).resolve(Boolean.class)) {
throw new IllegalStateException("Cannot define writable field access for " + target + " when using delegation");
} else {
return new ForArgument.Unresolved(target.getType(), annotation);
}
}
}
}
/**
* An offset mapping for a specific parameter of the instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Resolved extends ForArgument {
/**
* The parameter being bound.
*/
private final ParameterDescription parameterDescription;
/**
* Creates an offset mapping that binds a parameter of the instrumented method.
*
* @param target The type expected by the advice method.
* @param readOnly Determines if the parameter is to be treated as read-only.
* @param typing The typing to apply.
* @param parameterDescription The parameter being bound.
*/
public Resolved(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing, ParameterDescription parameterDescription) {
super(target, readOnly, typing);
this.parameterDescription = parameterDescription;
}
@Override
protected ParameterDescription resolve(MethodDescription instrumentedMethod) {
if (!parameterDescription.getDeclaringMethod().equals(instrumentedMethod)) {
throw new IllegalStateException(parameterDescription + " is not a parameter of " + instrumentedMethod);
}
return parameterDescription;
}
/**
* A factory for a parameter argument of the instrumented method.
*
* @param The type of the bound annotation.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Factory implements OffsetMapping.Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* The bound parameter.
*/
private final ParameterDescription parameterDescription;
/**
* {@code true} if the factory should create a read-only binding.
*/
private final boolean readOnly;
/**
* The typing to use.
*/
private final Assigner.Typing typing;
/**
* Creates a new factory for binding a parameter of the instrumented method with read-only semantics and static typing.
*
* @param annotationType The annotation type.
* @param parameterDescription The bound parameter.
*/
public Factory(Class annotationType, ParameterDescription parameterDescription) {
this(annotationType, parameterDescription, true, Assigner.Typing.STATIC);
}
/**
* Creates a new factory for binding a parameter of the instrumented method.
*
* @param annotationType The annotation type.
* @param parameterDescription The bound parameter.
* @param readOnly {@code true} if the factory should create a read-only binding.
* @param typing The typing to use.
*/
public Factory(Class annotationType, ParameterDescription parameterDescription, boolean readOnly, Assigner.Typing typing) {
this.annotationType = annotationType;
this.parameterDescription = parameterDescription;
this.readOnly = readOnly;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
return new Resolved(target.getType(), readOnly, typing, parameterDescription);
}
}
}
}
/**
* An offset mapping that provides access to the {@code this} reference of the instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForThisReference implements OffsetMapping {
/**
* The type that the advice method expects for the {@code this} reference.
*/
private final TypeDescription.Generic target;
/**
* Determines if the parameter is to be treated as read-only.
*/
private final boolean readOnly;
/**
* The typing to apply.
*/
private final Assigner.Typing typing;
/**
* {@code true} if the parameter should be bound to {@code null} if the instrumented method is static.
*/
private final boolean optional;
/**
* Creates a new offset mapping for a {@code this} reference.
*
* @param target The type that the advice method expects for the {@code this} reference.
* @param annotation The mapped annotation.
*/
protected ForThisReference(TypeDescription.Generic target, AnnotationDescription.Loadable annotation) {
this(target,
annotation.getValue(Factory.THIS_READ_ONLY).resolve(Boolean.class),
annotation.getValue(Factory.THIS_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class),
annotation.getValue(Factory.THIS_OPTIONAL).resolve(Boolean.class));
}
/**
* Creates a new offset mapping for a {@code this} reference.
*
* @param target The type that the advice method expects for the {@code this} reference.
* @param readOnly Determines if the parameter is to be treated as read-only.
* @param typing The typing to apply.
* @param optional {@code true} if the parameter should be bound to {@code null} if the instrumented method is static.
*/
public ForThisReference(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing, boolean optional) {
this.target = target;
this.readOnly = readOnly;
this.typing = typing;
this.optional = optional;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
if (instrumentedMethod.isStatic() || sort.isPremature(instrumentedMethod)) {
if (optional) {
return readOnly
? new Target.ForDefaultValue.ReadOnly(instrumentedType)
: new Target.ForDefaultValue.ReadWrite(instrumentedType);
} else {
throw new IllegalStateException("Cannot map this reference for static method or constructor start: " + instrumentedMethod);
}
}
StackManipulation readAssignment = assigner.assign(instrumentedType.asGenericType(), target, typing);
if (!readAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + instrumentedType + " to " + target);
} else if (readOnly) {
return new Target.ForVariable.ReadOnly(instrumentedType.asGenericType(), argumentHandler.argument(ArgumentHandler.THIS_REFERENCE), readAssignment);
} else {
StackManipulation writeAssignment = assigner.assign(target, instrumentedType.asGenericType(), typing);
if (!writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to " + instrumentedType);
}
return new Target.ForVariable.ReadWrite(instrumentedType.asGenericType(), argumentHandler.argument(ArgumentHandler.THIS_REFERENCE), readAssignment,
writeAssignment);
}
}
/**
* A factory for creating a {@link ForThisReference} offset mapping.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* A description of the {@link This#readOnly()} method.
*/
private static final MethodDescription.InDefinedShape THIS_READ_ONLY;
/**
* A description of the {@link This#typing()} method.
*/
private static final MethodDescription.InDefinedShape THIS_TYPING;
/**
* A description of the {@link This#optional()} method.
*/
private static final MethodDescription.InDefinedShape THIS_OPTIONAL;
/*
* Resolves annotation properties.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(This.class).getDeclaredMethods();
THIS_READ_ONLY = methods.filter(named("readOnly")).getOnly();
THIS_TYPING = methods.filter(named("typing")).getOnly();
THIS_OPTIONAL = methods.filter(named("optional")).getOnly();
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return This.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (adviceType.isDelegation() && !annotation.getValue(THIS_READ_ONLY).resolve(Boolean.class)) {
throw new IllegalStateException("Cannot write to this reference for " + target + " in read-only context");
} else {
return new ForThisReference(target.getType(), annotation);
}
}
}
}
/**
* An offset mapping that maps an array containing all arguments of the instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForAllArguments implements OffsetMapping {
/**
* The component target type.
*/
private final TypeDescription.Generic target;
/**
* {@code true} if the array is read-only.
*/
private final boolean readOnly;
/**
* The typing to apply.
*/
private final Assigner.Typing typing;
/**
* {@code true} if the method's target instance should be considered an element of the produced array.
*/
private final boolean includeSelf;
/**
* {@code true} if a {@code null} value should be assigned if the
* instrumented method does not declare any parameters.
*/
private final boolean nullIfEmpty;
/**
* Creates a new offset mapping for an array containing all arguments.
*
* @param target The component target type.
* @param annotation The mapped annotation.
*/
protected ForAllArguments(TypeDescription.Generic target, AnnotationDescription.Loadable annotation) {
this(target, annotation.getValue(Factory.ALL_ARGUMENTS_READ_ONLY).resolve(Boolean.class),
annotation.getValue(Factory.ALL_ARGUMENTS_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class),
annotation.getValue(Factory.ALL_ARGUMENTS_INCLUDE_SELF).resolve(Boolean.class),
annotation.getValue(Factory.ALL_ARGUMENTS_NULL_IF_EMPTY).resolve(Boolean.class));
}
/**
* Creates a new offset mapping for an array containing all arguments.
*
* @param target The component target type.
* @param readOnly {@code true} if the array is read-only.
* @param typing The typing to apply.
* @param includeSelf {@code true} if the method's target instance should be considered
* an element of the produced array.
* @param nullIfEmpty {@code true} if a {@code null} value should be assigned if the
* instrumented method does not declare any parameters.
*/
public ForAllArguments(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing, boolean includeSelf, boolean nullIfEmpty) {
this.target = target;
this.readOnly = readOnly;
this.typing = typing;
this.includeSelf = includeSelf;
this.nullIfEmpty = nullIfEmpty;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
if (nullIfEmpty && instrumentedMethod.getParameters().isEmpty() && (!includeSelf || instrumentedMethod.isStatic())) {
return readOnly
? new Target.ForStackManipulation(NullConstant.INSTANCE)
: new Target.ForStackManipulation.Writable(NullConstant.INSTANCE, Removal.SINGLE);
}
List reads = new ArrayList((includeSelf && !instrumentedMethod.isStatic()
? 1
: 0) + instrumentedMethod.getParameters().size());
if (includeSelf && !instrumentedMethod.isStatic()) {
if (sort.isPremature(instrumentedMethod) && instrumentedMethod.isConstructor()) {
throw new IllegalStateException("Cannot include self in all arguments array from " + instrumentedMethod);
}
StackManipulation assignment = assigner.assign(instrumentedMethod.getDeclaringType().asGenericType(), target, typing);
if (!assignment.isValid()) {
throw new IllegalStateException("Cannot assign " + instrumentedMethod.getDeclaringType() + " to " + target);
}
reads.add(new StackManipulation.Compound(
MethodVariableAccess.REFERENCE.loadFrom(argumentHandler.argument(ArgumentHandler.THIS_REFERENCE)),
assignment));
}
for (ParameterDescription parameterDescription : instrumentedMethod.getParameters()) {
StackManipulation assignment = assigner.assign(parameterDescription.getType(), target, typing);
if (!assignment.isValid()) {
throw new IllegalStateException("Cannot assign " + parameterDescription + " to " + target);
}
reads.add(new StackManipulation.Compound(
MethodVariableAccess.of(parameterDescription.getType()).loadFrom(argumentHandler.argument(parameterDescription.getOffset())),
assignment));
}
if (readOnly) {
return new Target.ForArray.ReadOnly(target, reads);
} else {
List writes = new ArrayList(2 * ((includeSelf && !instrumentedMethod.isStatic()
? 1
: 0) + instrumentedMethod.getParameters().size()));
if (includeSelf && !instrumentedMethod.isStatic()) {
StackManipulation assignment = assigner.assign(target, instrumentedMethod.getDeclaringType().asGenericType(), typing);
if (!assignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to " + instrumentedMethod.getDeclaringType());
}
writes.add(new StackManipulation.Compound(
assignment,
MethodVariableAccess.REFERENCE.storeAt(argumentHandler.argument(ArgumentHandler.THIS_REFERENCE))));
}
for (ParameterDescription parameterDescription : instrumentedMethod.getParameters()) {
StackManipulation assignment = assigner.assign(target, parameterDescription.getType(), typing);
if (!assignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to " + parameterDescription);
}
writes.add(new StackManipulation.Compound(
assignment,
MethodVariableAccess.of(parameterDescription.getType()).storeAt(argumentHandler.argument(parameterDescription.getOffset()))));
}
return new Target.ForArray.ReadWrite(target, reads, writes);
}
}
/**
* A factory for an offset mapping that maps all arguments values of the instrumented method.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* A description of the {@link AllArguments#readOnly()} method.
*/
private static final MethodDescription.InDefinedShape ALL_ARGUMENTS_READ_ONLY;
/**
* A description of the {@link AllArguments#typing()} method.
*/
private static final MethodDescription.InDefinedShape ALL_ARGUMENTS_TYPING;
/**
* A description of the {@link AllArguments#includeSelf()} method.
*/
private static final MethodDescription.InDefinedShape ALL_ARGUMENTS_INCLUDE_SELF;
/**
* A description of the {@link AllArguments#nullIfEmpty()} method.
*/
private static final MethodDescription.InDefinedShape ALL_ARGUMENTS_NULL_IF_EMPTY;
/*
* Resolves annotation properties.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(AllArguments.class).getDeclaredMethods();
ALL_ARGUMENTS_READ_ONLY = methods.filter(named("readOnly")).getOnly();
ALL_ARGUMENTS_TYPING = methods.filter(named("typing")).getOnly();
ALL_ARGUMENTS_INCLUDE_SELF = methods.filter(named("includeSelf")).getOnly();
ALL_ARGUMENTS_NULL_IF_EMPTY = methods.filter(named("nullIfEmpty")).getOnly();
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return AllArguments.class;
}
/**
* {@inheritDoc}
*/
@SuppressFBWarnings(value = "NP_NULL_ON_SOME_PATH_FROM_RETURN_VALUE", justification = "Assuming component type for array type.")
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (!target.getType().represents(Object.class) && !target.getType().isArray()) {
throw new IllegalStateException("Cannot use AllArguments annotation on a non-array type");
} else if (adviceType.isDelegation() && !annotation.getValue(ALL_ARGUMENTS_READ_ONLY).resolve(Boolean.class)) {
throw new IllegalStateException("Cannot define writable field access for " + target);
} else {
return new ForAllArguments(target.getType().represents(Object.class)
? TypeDescription.Generic.OfNonGenericType.ForLoadedType.of(Object.class)
: target.getType().getComponentType(), annotation);
}
}
}
}
/**
* Maps the declaring type of the instrumented method.
*/
enum ForInstrumentedType implements OffsetMapping {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
return Target.ForStackManipulation.of(instrumentedType);
}
}
/**
* Maps a constant representing the instrumented method.
*/
enum ForInstrumentedMethod implements OffsetMapping {
/**
* A constant that must be a {@link Method} instance.
*/
METHOD {
@Override
protected boolean isRepresentable(MethodDescription instrumentedMethod) {
return instrumentedMethod.isMethod();
}
@Override
protected Target resolve(MethodDescription.InDefinedShape methodDescription) {
return Target.ForStackManipulation.of(methodDescription);
}
},
/**
* A constant that must be a {@link Constructor} instance.
*/
CONSTRUCTOR {
@Override
protected boolean isRepresentable(MethodDescription instrumentedMethod) {
return instrumentedMethod.isConstructor();
}
@Override
protected Target resolve(MethodDescription.InDefinedShape methodDescription) {
return Target.ForStackManipulation.of(methodDescription);
}
},
/**
* A constant that must be a {@code java.lang.reflect.Executable} instance.
*/
EXECUTABLE {
@Override
protected boolean isRepresentable(MethodDescription instrumentedMethod) {
return true;
}
@Override
protected Target resolve(MethodDescription.InDefinedShape methodDescription) {
return Target.ForStackManipulation.of(methodDescription);
}
},
/**
* A constant that must be a {@code java.lang.invoke.MethodHandle} instance.
*/
METHOD_HANDLE {
@Override
protected boolean isRepresentable(MethodDescription instrumentedMethod) {
return true;
}
@Override
protected Target resolve(MethodDescription.InDefinedShape methodDescription) {
return new Target.ForStackManipulation(JavaConstant.MethodHandle.of(methodDescription).toStackManipulation());
}
},
/**
* A constant that must be a {@code java.lang.invoke.MethodType} instance.
*/
METHOD_TYPE {
@Override
protected boolean isRepresentable(MethodDescription instrumentedMethod) {
return true;
}
@Override
protected Target resolve(MethodDescription.InDefinedShape methodDescription) {
return new Target.ForStackManipulation(JavaConstant.MethodType.of(methodDescription).toStackManipulation());
}
};
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
if (!isRepresentable(instrumentedMethod)) {
throw new IllegalStateException("Cannot represent " + instrumentedMethod + " as the specified constant");
}
return resolve(instrumentedMethod.asDefined());
}
/**
* Checks if the supplied method is representable for the assigned offset mapping.
*
* @param instrumentedMethod The instrumented method to represent.
* @return {@code true} if this method is representable.
*/
protected abstract boolean isRepresentable(MethodDescription instrumentedMethod);
/**
* Resolves the target for a given method description.
*
* @param methodDescription The method description for which to resolve a constant.
* @return A suitable target.
*/
protected abstract Target resolve(MethodDescription.InDefinedShape methodDescription);
}
/**
* An offset mapping for a field.
*/
@HashCodeAndEqualsPlugin.Enhance
abstract class ForField implements OffsetMapping {
/**
* The {@link FieldValue#value()} method.
*/
private static final MethodDescription.InDefinedShape FIELD_VALUE;
/**
* The {@link FieldValue#declaringType()}} method.
*/
private static final MethodDescription.InDefinedShape FIELD_DECLARING_TYPE;
/**
* The {@link FieldValue#readOnly()}} method.
*/
private static final MethodDescription.InDefinedShape FIELD_READ_ONLY;
/**
* The {@link FieldValue#typing()}} method.
*/
private static final MethodDescription.InDefinedShape FIELD_TYPING;
/*
* Looks up all annotation properties to avoid loading of the declaring field type.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(FieldValue.class).getDeclaredMethods();
FIELD_VALUE = methods.filter(named("value")).getOnly();
FIELD_DECLARING_TYPE = methods.filter(named("declaringType")).getOnly();
FIELD_READ_ONLY = methods.filter(named("readOnly")).getOnly();
FIELD_TYPING = methods.filter(named("typing")).getOnly();
}
/**
* The expected type that the field can be assigned to.
*/
private final TypeDescription.Generic target;
/**
* {@code true} if this mapping is read-only.
*/
private final boolean readOnly;
/**
* The typing to apply.
*/
private final Assigner.Typing typing;
/**
* Creates an offset mapping for a field.
*
* @param target The target type.
* @param readOnly {@code true} if this mapping is read-only.
* @param typing The typing to apply.
*/
protected ForField(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing) {
this.target = target;
this.readOnly = readOnly;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
FieldDescription fieldDescription = resolve(instrumentedType, instrumentedMethod);
if (!fieldDescription.isStatic() && instrumentedMethod.isStatic()) {
throw new IllegalStateException("Cannot access non-static field " + fieldDescription + " from static method " + instrumentedMethod);
}
if (sort.isPremature(instrumentedMethod) && !fieldDescription.isStatic()) {
if (readOnly) {
throw new IllegalStateException("Cannot read " + fieldDescription + " before super constructor call");
} else {
StackManipulation writeAssignment = assigner.assign(target, fieldDescription.getType(), typing);
if (!writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to " + fieldDescription);
}
return new Target.ForField.WriteOnly(fieldDescription.asDefined(), writeAssignment);
}
} else {
StackManipulation readAssignment = assigner.assign(fieldDescription.getType(), target, typing);
if (!readAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + fieldDescription + " to " + target);
} else if (readOnly) {
return new Target.ForField.ReadOnly(fieldDescription, readAssignment);
} else {
StackManipulation writeAssignment = assigner.assign(target, fieldDescription.getType(), typing);
if (!writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to " + fieldDescription);
}
return new Target.ForField.ReadWrite(fieldDescription.asDefined(), readAssignment, writeAssignment);
}
}
}
/**
* Resolves the field being bound.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @return The field being bound.
*/
protected abstract FieldDescription resolve(TypeDescription instrumentedType, MethodDescription instrumentedMethod);
/**
* An offset mapping for a field that is resolved from the instrumented type by its name.
*/
@HashCodeAndEqualsPlugin.Enhance
public abstract static class Unresolved extends ForField {
/**
* Indicates that a name should be extracted from an accessor method.
*/
protected static final String BEAN_PROPERTY = "";
/**
* The name of the field.
*/
private final String name;
/**
* Creates an offset mapping for a field that is not yet resolved.
*
* @param target The target type.
* @param readOnly {@code true} if this mapping is read-only.
* @param typing The typing to apply.
* @param name The name of the field.
*/
protected Unresolved(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing, String name) {
super(target, readOnly, typing);
this.name = name;
}
@Override
protected FieldDescription resolve(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
FieldLocator locator = fieldLocator(instrumentedType);
FieldLocator.Resolution resolution = name.equals(BEAN_PROPERTY)
? FieldLocator.Resolution.Simple.ofBeanAccessor(locator, instrumentedMethod)
: locator.locate(name);
if (!resolution.isResolved()) {
throw new IllegalStateException("Cannot locate field named " + name + " for " + instrumentedType);
} else {
return resolution.getField();
}
}
/**
* Returns a field locator for this instance.
*
* @param instrumentedType The instrumented type.
* @return An appropriate field locator.
*/
protected abstract FieldLocator fieldLocator(TypeDescription instrumentedType);
/**
* An offset mapping for a field with an implicit declaring type.
*/
public static class WithImplicitType extends Unresolved {
/**
* Creates an offset mapping for a field with an implicit declaring type.
*
* @param target The target type.
* @param annotation The annotation to represent.
*/
protected WithImplicitType(TypeDescription.Generic target, AnnotationDescription.Loadable annotation) {
this(target,
annotation.getValue(FIELD_READ_ONLY).resolve(Boolean.class),
annotation.getValue(FIELD_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class),
annotation.getValue(FIELD_VALUE).resolve(String.class));
}
/**
* Creates an offset mapping for a field with an implicit declaring type.
*
* @param target The target type.
* @param name The name of the field.
* @param readOnly {@code true} if the field is read-only.
* @param typing The typing to apply.
*/
public WithImplicitType(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing, String name) {
super(target, readOnly, typing, name);
}
@Override
protected FieldLocator fieldLocator(TypeDescription instrumentedType) {
return new FieldLocator.ForClassHierarchy(instrumentedType);
}
}
/**
* An offset mapping for a field with an explicit declaring type.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class WithExplicitType extends Unresolved {
/**
* The type declaring the field.
*/
private final TypeDescription declaringType;
/**
* Creates an offset mapping for a field with an explicit declaring type.
*
* @param target The target type.
* @param annotation The annotation to represent.
* @param declaringType The field's declaring type.
*/
protected WithExplicitType(TypeDescription.Generic target,
AnnotationDescription.Loadable annotation,
TypeDescription declaringType) {
this(target,
annotation.getValue(FIELD_READ_ONLY).resolve(Boolean.class),
annotation.getValue(FIELD_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class),
annotation.getValue(FIELD_VALUE).resolve(String.class),
declaringType);
}
/**
* Creates an offset mapping for a field with an explicit declaring type.
*
* @param target The target type.
* @param name The name of the field.
* @param readOnly {@code true} if the field is read-only.
* @param typing The typing to apply.
* @param declaringType The field's declaring type.
*/
public WithExplicitType(TypeDescription.Generic target,
boolean readOnly,
Assigner.Typing typing,
String name,
TypeDescription declaringType) {
super(target, readOnly, typing, name);
this.declaringType = declaringType;
}
@Override
protected FieldLocator fieldLocator(TypeDescription instrumentedType) {
if (!declaringType.represents(TargetType.class) && !instrumentedType.isAssignableTo(declaringType)) {
throw new IllegalStateException(declaringType + " is no super type of " + instrumentedType);
}
return new FieldLocator.ForExactType(TargetType.resolve(declaringType, instrumentedType));
}
}
/**
* A factory for a {@link Unresolved} offset mapping.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return FieldValue.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (adviceType.isDelegation() && !annotation.getValue(ForField.FIELD_READ_ONLY).resolve(Boolean.class)) {
throw new IllegalStateException("Cannot write to field for " + target + " in read-only context");
} else {
TypeDescription declaringType = annotation.getValue(FIELD_DECLARING_TYPE).resolve(TypeDescription.class);
return declaringType.represents(void.class)
? new WithImplicitType(target.getType(), annotation)
: new WithExplicitType(target.getType(), annotation, declaringType);
}
}
}
}
/**
* A binding for an offset mapping that represents a specific field.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Resolved extends ForField {
/**
* The accessed field.
*/
private final FieldDescription fieldDescription;
/**
* Creates a resolved offset mapping for a field.
*
* @param target The target type.
* @param readOnly {@code true} if this mapping is read-only.
* @param typing The typing to apply.
* @param fieldDescription The accessed field.
*/
public Resolved(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing, FieldDescription fieldDescription) {
super(target, readOnly, typing);
this.fieldDescription = fieldDescription;
}
@Override
@SuppressFBWarnings(value = "NP_NULL_ON_SOME_PATH_FROM_RETURN_VALUE", justification = "Assuming declaring type for type member.")
protected FieldDescription resolve(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
if (!fieldDescription.isStatic() && !fieldDescription.getDeclaringType().asErasure().isAssignableFrom(instrumentedType)) {
throw new IllegalStateException(fieldDescription + " is no member of " + instrumentedType);
} else if (!fieldDescription.isVisibleTo(instrumentedType)) {
throw new IllegalStateException("Cannot access " + fieldDescription + " from " + instrumentedType);
}
return fieldDescription;
}
/**
* A factory that binds a field.
*
* @param The annotation type this factory binds.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Factory implements OffsetMapping.Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* The field to be bound.
*/
private final FieldDescription fieldDescription;
/**
* {@code true} if this factory should create a read-only binding.
*/
private final boolean readOnly;
/**
* The typing to use.
*/
private final Assigner.Typing typing;
/**
* Creates a new factory for binding a specific field with read-only semantics and static typing.
*
* @param annotationType The annotation type.
* @param fieldDescription The field to bind.
*/
public Factory(Class annotationType, FieldDescription fieldDescription) {
this(annotationType, fieldDescription, true, Assigner.Typing.STATIC);
}
/**
* Creates a new factory for binding a specific field.
*
* @param annotationType The annotation type.
* @param fieldDescription The field to bind.
* @param readOnly {@code true} if this factory should create a read-only binding.
* @param typing The typing to use.
*/
public Factory(Class annotationType, FieldDescription fieldDescription, boolean readOnly, Assigner.Typing typing) {
this.annotationType = annotationType;
this.fieldDescription = fieldDescription;
this.readOnly = readOnly;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
return new Resolved(target.getType(), readOnly, typing, fieldDescription);
}
}
}
}
/**
* An offset mapping for a field handle.
*/
@HashCodeAndEqualsPlugin.Enhance
abstract class ForFieldHandle implements OffsetMapping {
/**
* The access type of the represented handle.
*/
private final Access access;
/**
* Creates an offset mapping for a field handle.
*
* @param access The access type of the represented handle.
*/
protected ForFieldHandle(Access access) {
this.access = access;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
FieldDescription fieldDescription = resolve(instrumentedType, instrumentedMethod);
if (!fieldDescription.isStatic() && instrumentedMethod.isStatic()) {
throw new IllegalStateException("Cannot access non-static field " + fieldDescription + " from static method " + instrumentedMethod);
}
if (sort.isPremature(instrumentedMethod) && !fieldDescription.isStatic()) {
throw new IllegalStateException("Cannot access " + fieldDescription + " before super constructor call");
} else if (fieldDescription.isStatic()) {
return new Target.ForStackManipulation(access.resolve(fieldDescription.asDefined()).toStackManipulation());
} else {
return new Target.ForStackManipulation(new StackManipulation.Compound(
access.resolve(fieldDescription.asDefined()).toStackManipulation(),
MethodVariableAccess.REFERENCE.loadFrom(argumentHandler.argument(ArgumentHandler.THIS_REFERENCE)),
MethodInvocation.invoke(new MethodDescription.Latent(JavaType.METHOD_HANDLE.getTypeStub(), new MethodDescription.Token("bindTo",
Opcodes.ACC_PUBLIC,
JavaType.METHOD_HANDLE.getTypeStub().asGenericType(),
new TypeList.Generic.Explicit(TypeDefinition.Sort.describe(Object.class)))))));
}
}
/**
* Resolves the field being bound.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @return The field being bound.
*/
protected abstract FieldDescription resolve(TypeDescription instrumentedType, MethodDescription instrumentedMethod);
/**
* A description of the field handle's access type.
*/
public enum Access {
/**
* Determines the resolution of a getter for the method handle.
*/
GETTER {
@Override
protected JavaConstant.MethodHandle resolve(FieldDescription.InDefinedShape fieldDescription) {
return JavaConstant.MethodHandle.ofGetter(fieldDescription);
}
},
/**
* Determines the resolution of a setter for the method handle.
*/
SETTER {
@Override
protected JavaConstant.MethodHandle resolve(FieldDescription.InDefinedShape fieldDescription) {
return JavaConstant.MethodHandle.ofSetter(fieldDescription);
}
};
/**
* Returns the appropriate method handle.
*
* @param fieldDescription The field description to resolve the handle for.
* @return The appropriate method handle.
*/
protected abstract JavaConstant.MethodHandle resolve(FieldDescription.InDefinedShape fieldDescription);
}
/**
* An offset mapping for a field handle that is resolved from the instrumented type by its name.
*/
@HashCodeAndEqualsPlugin.Enhance
public abstract static class Unresolved extends ForFieldHandle {
/**
* Indicates that a name should be extracted from an accessor method.
*/
protected static final String BEAN_PROPERTY = "";
/**
* The name of the field.
*/
private final String name;
/**
* Creates an offset mapping for a field that is not yet resolved.
*
* @param access The access type of the represented handle.
* @param name The name of the field.
*/
public Unresolved(Access access, String name) {
super(access);
this.name = name;
}
@Override
protected FieldDescription resolve(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
FieldLocator locator = fieldLocator(instrumentedType);
FieldLocator.Resolution resolution = name.equals(BEAN_PROPERTY)
? FieldLocator.Resolution.Simple.ofBeanAccessor(locator, instrumentedMethod)
: locator.locate(name);
if (!resolution.isResolved()) {
throw new IllegalStateException("Cannot locate field named " + name + " for " + instrumentedType);
} else {
return resolution.getField();
}
}
/**
* Returns a field locator for this instance.
*
* @param instrumentedType The instrumented type.
* @return An appropriate field locator.
*/
protected abstract FieldLocator fieldLocator(TypeDescription instrumentedType);
/**
* An offset mapping for a field handle with an implicit declaring type.
*/
public static class WithImplicitType extends Unresolved {
/**
* Creates an offset mapping for a field handle with an implicit declaring type.
*
* @param access The access type of the represented handle.
* @param name The name of the field.
*/
public WithImplicitType(Access access, String name) {
super(access, name);
}
@Override
protected FieldLocator fieldLocator(TypeDescription instrumentedType) {
return new FieldLocator.ForClassHierarchy(instrumentedType);
}
}
/**
* An offset mapping for a field handle with an explicit declaring type.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class WithExplicitType extends Unresolved {
/**
* The type declaring the field.
*/
private final TypeDescription declaringType;
/**
* Creates an offset mapping for a field handle with an explicit declaring type.
*
* @param access The access type of the represented handle.
* @param name The name of the field.
* @param declaringType The type declaring the field.
*/
public WithExplicitType(Access access, String name, TypeDescription declaringType) {
super(access, name);
this.declaringType = declaringType;
}
@Override
protected FieldLocator fieldLocator(TypeDescription instrumentedType) {
if (!declaringType.represents(TargetType.class) && !instrumentedType.isAssignableTo(declaringType)) {
throw new IllegalStateException(declaringType + " is no super type of " + instrumentedType);
}
return new FieldLocator.ForExactType(TargetType.resolve(declaringType, instrumentedType));
}
}
/**
* A factory for a {@link ForFieldHandle.Unresolved} offset mapping representing a getter.
*/
protected enum ReaderFactory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The {@link FieldGetterHandle#value()} method.
*/
private static final MethodDescription.InDefinedShape FIELD_GETTER_HANDLE_VALUE;
/**
* The {@link FieldGetterHandle#declaringType()} method.
*/
private static final MethodDescription.InDefinedShape FIELD_GETTER_HANDLE_DECLARING_TYPE;
/*
* Resolves annotation properties.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(FieldGetterHandle.class).getDeclaredMethods();
FIELD_GETTER_HANDLE_VALUE = methods.filter(named("value")).getOnly();
FIELD_GETTER_HANDLE_DECLARING_TYPE = methods.filter(named("declaringType")).getOnly();
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return FieldGetterHandle.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (!target.getType().asErasure().isAssignableFrom(JavaType.METHOD_HANDLE.getTypeStub())) {
throw new IllegalStateException("Cannot assign method handle to " + target);
}
TypeDescription declaringType = annotation.getValue(FIELD_GETTER_HANDLE_DECLARING_TYPE).resolve(TypeDescription.class);
return declaringType.represents(void.class)
? new ForFieldHandle.Unresolved.WithImplicitType(Access.GETTER, annotation.getValue(FIELD_GETTER_HANDLE_VALUE).resolve(String.class))
: new ForFieldHandle.Unresolved.WithExplicitType(Access.GETTER, annotation.getValue(FIELD_GETTER_HANDLE_VALUE).resolve(String.class), declaringType);
}
}
/**
* A factory for a {@link ForFieldHandle.Unresolved} offset mapping representing a setter.
*/
protected enum WriterFactory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The {@link FieldSetterHandle#value()} method.
*/
private static final MethodDescription.InDefinedShape FIELD_SETTER_HANDLE_VALUE;
/**
* The {@link FieldSetterHandle#declaringType()} method.
*/
private static final MethodDescription.InDefinedShape FIELD_SETTER_HANDLE_DECLARING_TYPE;
/*
* Resolves annotation properties.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(FieldSetterHandle.class).getDeclaredMethods();
FIELD_SETTER_HANDLE_VALUE = methods.filter(named("value")).getOnly();
FIELD_SETTER_HANDLE_DECLARING_TYPE = methods.filter(named("declaringType")).getOnly();
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return FieldSetterHandle.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (!target.getType().asErasure().isAssignableFrom(JavaType.METHOD_HANDLE.getTypeStub())) {
throw new IllegalStateException("Cannot assign method handle to " + target);
}
TypeDescription declaringType = annotation.getValue(FIELD_SETTER_HANDLE_DECLARING_TYPE).resolve(TypeDescription.class);
return declaringType.represents(void.class)
? new ForFieldHandle.Unresolved.WithImplicitType(Access.SETTER, annotation.getValue(FIELD_SETTER_HANDLE_VALUE).resolve(String.class))
: new ForFieldHandle.Unresolved.WithExplicitType(Access.SETTER, annotation.getValue(FIELD_SETTER_HANDLE_VALUE).resolve(String.class), declaringType);
}
}
}
/**
* A binding for an offset mapping that represents a specific field.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Resolved extends ForFieldHandle {
/**
* The accessed field.
*/
private final FieldDescription fieldDescription;
/**
* Creates a resolved offset mapping for a field handle.
*
* @param access The access type of the represented handle.
* @param fieldDescription The accessed field.
*/
public Resolved(Access access, FieldDescription fieldDescription) {
super(access);
this.fieldDescription = fieldDescription;
}
@Override
@SuppressFBWarnings(value = "NP_NULL_ON_SOME_PATH_FROM_RETURN_VALUE", justification = "Assuming declaring type for type member.")
protected FieldDescription resolve(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
if (!fieldDescription.isStatic() && !fieldDescription.getDeclaringType().asErasure().isAssignableFrom(instrumentedType)) {
throw new IllegalStateException(fieldDescription + " is no member of " + instrumentedType);
} else if (!fieldDescription.isVisibleTo(instrumentedType)) {
throw new IllegalStateException("Cannot access " + fieldDescription + " from " + instrumentedType);
}
return fieldDescription;
}
/**
* A factory that binds a field handle.
*
* @param The annotation type this factory binds.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Factory implements OffsetMapping.Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* The field to be bound.
*/
private final FieldDescription fieldDescription;
/**
* The access type of the represented handle.
*/
private final Access access;
/**
* Creates a new factory for binding a specific field handle.
*
* @param annotationType The annotation type.
* @param fieldDescription The field to bind.
* @param access The access type of the represented handle.
*/
public Factory(Class annotationType, FieldDescription fieldDescription, Access access) {
this.annotationType = annotationType;
this.fieldDescription = fieldDescription;
this.access = access;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (!target.getType().asErasure().isAssignableFrom(JavaType.METHOD_HANDLE.getTypeStub())) {
throw new IllegalStateException("Cannot assign method handle to " + target);
}
return new Resolved(access, fieldDescription);
}
}
}
}
/**
* An offset mapping for the {@link Advice.Origin} annotation.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForOrigin implements OffsetMapping {
/**
* The delimiter character.
*/
private static final char DELIMITER = '#';
/**
* The escape character.
*/
private static final char ESCAPE = '\\';
/**
* The renderers to apply.
*/
private final List renderers;
/**
* Creates a new offset mapping for an origin value.
*
* @param renderers The renderers to apply.
*/
public ForOrigin(List renderers) {
this.renderers = renderers;
}
/**
* Parses a pattern of an origin annotation.
*
* @param pattern The supplied pattern.
* @return An appropriate offset mapping.
*/
public static OffsetMapping parse(String pattern) {
if (pattern.equals(Origin.DEFAULT)) {
return new ForOrigin(Collections.singletonList(Renderer.ForStringRepresentation.INSTANCE));
} else {
List renderers = new ArrayList(pattern.length());
int from = 0;
for (int to = pattern.indexOf(DELIMITER); to != -1; to = pattern.indexOf(DELIMITER, from)) {
if (to != 0 && pattern.charAt(to - 1) == ESCAPE && (to == 1 || pattern.charAt(to - 2) != ESCAPE)) {
renderers.add(new Renderer.ForConstantValue(pattern.substring(from, Math.max(0, to - 1)) + DELIMITER));
from = to + 1;
continue;
} else if (pattern.length() == to + 1) {
throw new IllegalStateException("Missing sort descriptor for " + pattern + " at index " + to);
}
renderers.add(new Renderer.ForConstantValue(pattern.substring(from, to).replace("" + ESCAPE + ESCAPE, "" + ESCAPE)));
switch (pattern.charAt(to + 1)) {
case Renderer.ForMethodName.SYMBOL:
renderers.add(Renderer.ForMethodName.INSTANCE);
break;
case Renderer.ForTypeName.SYMBOL:
renderers.add(Renderer.ForTypeName.INSTANCE);
break;
case Renderer.ForDescriptor.SYMBOL:
renderers.add(Renderer.ForDescriptor.INSTANCE);
break;
case Renderer.ForReturnTypeName.SYMBOL:
renderers.add(Renderer.ForReturnTypeName.INSTANCE);
break;
case Renderer.ForJavaSignature.SYMBOL:
renderers.add(Renderer.ForJavaSignature.INSTANCE);
break;
case Renderer.ForPropertyName.SYMBOL:
renderers.add(Renderer.ForPropertyName.INSTANCE);
break;
default:
throw new IllegalStateException("Illegal sort descriptor " + pattern.charAt(to + 1) + " for " + pattern);
}
from = to + 2;
}
renderers.add(new Renderer.ForConstantValue(pattern.substring(from)));
return new ForOrigin(renderers);
}
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
StringBuilder stringBuilder = new StringBuilder();
for (Renderer renderer : renderers) {
stringBuilder.append(renderer.apply(instrumentedType, instrumentedMethod));
}
return Target.ForStackManipulation.of(stringBuilder.toString());
}
/**
* A renderer for an origin pattern element.
*/
public interface Renderer {
/**
* Returns a string representation for this renderer.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @return The string representation.
*/
String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod);
/**
* A renderer for a method's internal name.
*/
enum ForMethodName implements Renderer {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The method name symbol.
*/
public static final char SYMBOL = 'm';
/**
* {@inheritDoc}
*/
public String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
return instrumentedMethod.getInternalName();
}
}
/**
* A renderer for a method declaring type's binary name.
*/
enum ForTypeName implements Renderer {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The type name symbol.
*/
public static final char SYMBOL = 't';
/**
* {@inheritDoc}
*/
public String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
return instrumentedType.getName();
}
}
/**
* A renderer for a method descriptor.
*/
enum ForDescriptor implements Renderer {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The descriptor symbol.
*/
public static final char SYMBOL = 'd';
/**
* {@inheritDoc}
*/
public String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
return instrumentedMethod.getDescriptor();
}
}
/**
* A renderer for a method's Java signature in binary form.
*/
enum ForJavaSignature implements Renderer {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The signature symbol.
*/
public static final char SYMBOL = 's';
/**
* {@inheritDoc}
*/
public String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
StringBuilder stringBuilder = new StringBuilder("(");
boolean comma = false;
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
if (comma) {
stringBuilder.append(',');
} else {
comma = true;
}
stringBuilder.append(typeDescription.getName());
}
return stringBuilder.append(')').toString();
}
}
/**
* A renderer for a method's return type in binary form.
*/
enum ForReturnTypeName implements Renderer {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The return type symbol.
*/
public static final char SYMBOL = 'r';
/**
* {@inheritDoc}
*/
public String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
return instrumentedMethod.getReturnType().asErasure().getName();
}
}
/**
* A renderer for a method's {@link Object#toString()} representation.
*/
enum ForStringRepresentation implements Renderer {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
return instrumentedMethod.toString();
}
}
/**
* A renderer for a constant value.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForConstantValue implements Renderer {
/**
* The constant value.
*/
private final String value;
/**
* Creates a new renderer for a constant value.
*
* @param value The constant value.
*/
public ForConstantValue(String value) {
this.value = value;
}
/**
* {@inheritDoc}
*/
public String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
return value;
}
}
/**
* A renderer for a property name.
*/
enum ForPropertyName implements Renderer {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The signature symbol.
*/
public static final char SYMBOL = 'p';
/**
* {@inheritDoc}
*/
public String apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
return FieldAccessor.FieldNameExtractor.ForBeanProperty.INSTANCE.resolve(instrumentedMethod);
}
}
}
/**
* A factory for a method origin.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* A description of the {@link Origin#value()} method.
*/
private static final MethodDescription.InDefinedShape ORIGIN_VALUE = TypeDescription.ForLoadedType.of(Origin.class)
.getDeclaredMethods()
.filter(named("value"))
.getOnly();
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return Origin.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (target.getType().asErasure().represents(Class.class)) {
return ForInstrumentedType.INSTANCE;
} else if (target.getType().asErasure().represents(Method.class)) {
return ForInstrumentedMethod.METHOD;
} else if (target.getType().asErasure().represents(Constructor.class)) {
return ForInstrumentedMethod.CONSTRUCTOR;
} else if (JavaType.EXECUTABLE.getTypeStub().equals(target.getType().asErasure())) {
return ForInstrumentedMethod.EXECUTABLE;
} else if (JavaType.METHOD_HANDLE.getTypeStub().equals(target.getType().asErasure())) {
return ForInstrumentedMethod.METHOD_HANDLE;
} else if (JavaType.METHOD_TYPE.getTypeStub().equals(target.getType().asErasure())) {
return ForInstrumentedMethod.METHOD_TYPE;
} else if (JavaType.METHOD_HANDLES_LOOKUP.getTypeStub().equals(target.getType().asErasure())) {
return new OffsetMapping.ForStackManipulation(MethodInvocation.lookup(),
JavaType.METHOD_HANDLES_LOOKUP.getTypeStub().asGenericType(),
target.getType(),
Assigner.Typing.STATIC);
} else if (target.getType().asErasure().isAssignableFrom(String.class)) {
return ForOrigin.parse(annotation.getValue(ORIGIN_VALUE).resolve(String.class));
} else {
throw new IllegalStateException("Non-supported type " + target.getType() + " for @Origin annotation");
}
}
}
}
/**
* An offset mapping for assigning a method handle that invokes the instrumented method.
*/
enum ForSelfCallHandle implements OffsetMapping {
/**
* A bound assignment that invokes the instrumented method as is.
*/
BOUND {
@Override
protected StackManipulation decorate(MethodDescription methodDescription, StackManipulation stackManipulation) {
List stackManipulations = new ArrayList(1
+ (methodDescription.isStatic() ? 0 : 2)
+ methodDescription.getParameters().size() * 3);
stackManipulations.add(stackManipulation);
if (!methodDescription.isStatic()) {
stackManipulations.add(MethodVariableAccess.loadThis());
stackManipulations.add(MethodInvocation.invoke(new MethodDescription.Latent(JavaType.METHOD_HANDLE.getTypeStub(), new MethodDescription.Token("bindTo",
Opcodes.ACC_PUBLIC,
JavaType.METHOD_HANDLE.getTypeStub().asGenericType(),
new TypeList.Generic.Explicit(TypeDefinition.Sort.describe(Object.class))))));
}
if (!methodDescription.getParameters().isEmpty()) {
List values = new ArrayList(methodDescription.getParameters().size());
for (ParameterDescription parameterDescription : methodDescription.getParameters()) {
values.add(parameterDescription.getType().isPrimitive() ?
new StackManipulation.Compound(MethodVariableAccess.load(parameterDescription), Assigner.DEFAULT.assign(parameterDescription.getType(),
parameterDescription.getType().asErasure().asBoxed().asGenericType(),
Assigner.Typing.STATIC)) : MethodVariableAccess.load(parameterDescription));
}
stackManipulations.add(IntegerConstant.forValue(0));
stackManipulations.add(ArrayFactory.forType(TypeDescription.ForLoadedType.of(Object.class).asGenericType()).withValues(values));
stackManipulations.add(
MethodInvocation.invoke(new MethodDescription.Latent(JavaType.METHOD_HANDLES.getTypeStub(), new MethodDescription.Token("insertArguments",
Opcodes.ACC_PUBLIC | Opcodes.ACC_STATIC,
JavaType.METHOD_HANDLE.getTypeStub().asGenericType(),
new TypeList.Generic.Explicit(JavaType.METHOD_HANDLE.getTypeStub(), TypeDefinition.Sort.describe(int.class),
TypeDefinition.Sort.describe(Object[].class))))));
}
return new StackManipulation.Compound(stackManipulations);
}
},
/**
* An unbound self call handle which requires manual assignment of parameters.
*/
UNBOUND {
@Override
protected StackManipulation decorate(MethodDescription methodDescription, StackManipulation stackManipulation) {
return stackManipulation;
}
};
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
if (!instrumentedMethod.isMethod()) {
throw new IllegalStateException();
}
StackManipulation stackManipulation = (instrumentedMethod.isStatic()
? JavaConstant.MethodHandle.of(instrumentedMethod.asDefined())
: JavaConstant.MethodHandle.ofSpecial(instrumentedMethod.asDefined(), instrumentedType)).toStackManipulation();
return new Target.ForStackManipulation(decorate(instrumentedMethod, stackManipulation));
}
/**
* Resolves a stack manipulation.
*
* @param methodDescription The method description being represented.
* @param stackManipulation The stack manipulation for the current method handle.
* @return The decorated stack manipulation.
*/
protected abstract StackManipulation decorate(MethodDescription methodDescription, StackManipulation stackManipulation);
/**
* A factory for a self call method handle.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* The {@code bound} property of the {@link SelfCallHandle} annotation.
*/
private static final MethodDescription.InDefinedShape SELF_CALL_HANDLE_BOUND = TypeDescription.ForLoadedType.of(SelfCallHandle.class)
.getDeclaredMethods()
.filter(named("bound"))
.getOnly();
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return SelfCallHandle.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (!target.getType().asErasure().isAssignableFrom(JavaType.METHOD_HANDLE.getTypeStub())) {
throw new IllegalStateException("Cannot assign a MethodHandle to " + target);
}
return annotation.getValue(SELF_CALL_HANDLE_BOUND).resolve(Boolean.class)
? ForSelfCallHandle.BOUND
: ForSelfCallHandle.UNBOUND;
}
}
}
/**
* An offset mapping for a parameter where assignments are fully ignored and that always return the parameter type's default value.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForUnusedValue implements OffsetMapping {
/**
* The unused type.
*/
private final TypeDefinition target;
/**
* Creates a new offset mapping for an unused type.
*
* @param target The unused type.
*/
public ForUnusedValue(TypeDefinition target) {
this.target = target;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
return new Target.ForDefaultValue.ReadWrite(target);
}
/**
* A factory for an offset mapping for an unused value.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* A factory for representing an unused value.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return Unused.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
return new ForUnusedValue(target.getType());
}
}
}
/**
* An offset mapping for a parameter where assignments are fully ignored and that is assigned a boxed version of the instrumented
* method's return value or {@code null} if the return type is not primitive or {@code void}.
*/
enum ForStubValue implements OffsetMapping, Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
return new Target.ForDefaultValue.ReadOnly(instrumentedMethod.getReturnType(), assigner.assign(instrumentedMethod.getReturnType(),
TypeDescription.Generic.OfNonGenericType.ForLoadedType.of(Object.class),
Assigner.Typing.DYNAMIC));
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return StubValue.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (!target.getType().represents(Object.class)) {
throw new IllegalStateException("Cannot use StubValue on non-Object parameter type " + target);
} else {
return this;
}
}
}
/**
* An offset mapping that provides access to the value that is returned by the enter advice.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForEnterValue implements OffsetMapping {
/**
* The represented target type.
*/
private final TypeDescription.Generic target;
/**
* The enter type.
*/
private final TypeDescription.Generic enterType;
/**
* {@code true} if the annotated value is read-only.
*/
private final boolean readOnly;
/**
* The typing to apply.
*/
private final Assigner.Typing typing;
/**
* Creates a new offset mapping for the enter type.
*
* @param target The represented target type.
* @param enterType The enter type.
* @param annotation The represented annotation.
*/
protected ForEnterValue(TypeDescription.Generic target, TypeDescription.Generic enterType, AnnotationDescription.Loadable annotation) {
this(target,
enterType,
annotation.getValue(Factory.ENTER_READ_ONLY).resolve(Boolean.class),
annotation.getValue(Factory.ENTER_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class));
}
/**
* Creates a new offset mapping for the enter type.
*
* @param target The represented target type.
* @param enterType The enter type.
* @param readOnly {@code true} if the annotated value is read-only.
* @param typing The typing to apply.
*/
public ForEnterValue(TypeDescription.Generic target, TypeDescription.Generic enterType, boolean readOnly, Assigner.Typing typing) {
this.target = target;
this.enterType = enterType;
this.readOnly = readOnly;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
StackManipulation readAssignment = assigner.assign(enterType, target, typing);
if (!readAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + enterType + " to " + target);
} else if (readOnly) {
return new Target.ForVariable.ReadOnly(target, argumentHandler.enter(), readAssignment);
} else {
StackManipulation writeAssignment = assigner.assign(target, enterType, typing);
if (!writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to " + enterType);
}
return new Target.ForVariable.ReadWrite(target, argumentHandler.enter(), readAssignment, writeAssignment);
}
}
/**
* A factory for creating a {@link ForEnterValue} offset mapping.
*/
@HashCodeAndEqualsPlugin.Enhance
protected static class Factory implements OffsetMapping.Factory {
/**
* A description of the {@link Argument#readOnly()} method.
*/
private static final MethodDescription.InDefinedShape ENTER_READ_ONLY;
/**
* A description of the {@link Argument#typing()} method.
*/
private static final MethodDescription.InDefinedShape ENTER_TYPING;
static {
MethodList methods = TypeDescription.ForLoadedType.of(Enter.class).getDeclaredMethods();
ENTER_READ_ONLY = methods.filter(named("readOnly")).getOnly();
ENTER_TYPING = methods.filter(named("typing")).getOnly();
}
/**
* The supplied type of the enter advice.
*/
private final TypeDefinition enterType;
/**
* Creates a new factory for creating a {@link ForEnterValue} offset mapping.
*
* @param enterType The supplied type of the enter method.
*/
protected Factory(TypeDefinition enterType) {
this.enterType = enterType;
}
/**
* Creates a new factory for creating a {@link ForEnterValue} offset mapping.
*
* @param typeDefinition The supplied type of the enter advice.
* @return An appropriate offset mapping factory.
*/
protected static OffsetMapping.Factory of(TypeDefinition typeDefinition) {
return typeDefinition.represents(void.class)
? new Illegal(Enter.class)
: new Factory(typeDefinition);
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return Enter.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (adviceType.isDelegation() && !annotation.getValue(ENTER_READ_ONLY).resolve(Boolean.class)) {
throw new IllegalStateException("Cannot use writable " + target + " on read-only parameter");
} else {
return new ForEnterValue(target.getType(), enterType.asGenericType(), annotation);
}
}
}
}
/**
* An offset mapping that provides access to the value that is returned by the exit advice.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForExitValue implements OffsetMapping {
/**
* The represented target type.
*/
private final TypeDescription.Generic target;
/**
* The exit type.
*/
private final TypeDescription.Generic exitType;
/**
* {@code true} if the annotated value is read-only.
*/
private final boolean readOnly;
/**
* The typing to apply.
*/
private final Assigner.Typing typing;
/**
* Creates a new offset mapping for the exit type.
*
* @param target The represented target type.
* @param exitType The exit type.
* @param annotation The represented annotation.
*/
protected ForExitValue(TypeDescription.Generic target, TypeDescription.Generic exitType, AnnotationDescription.Loadable annotation) {
this(target,
exitType,
annotation.getValue(Factory.EXIT_READ_ONLY).resolve(Boolean.class),
annotation.getValue(Factory.EXIT_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class));
}
/**
* Creates a new offset mapping for the enter type.
*
* @param target The represented target type.
* @param exitType The exit type.
* @param readOnly {@code true} if the annotated value is read-only.
* @param typing The typing to apply.
*/
public ForExitValue(TypeDescription.Generic target, TypeDescription.Generic exitType, boolean readOnly, Assigner.Typing typing) {
this.target = target;
this.exitType = exitType;
this.readOnly = readOnly;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
StackManipulation readAssignment = assigner.assign(exitType, target, typing);
if (!readAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + exitType + " to " + target);
} else if (readOnly) {
return new Target.ForVariable.ReadOnly(target, argumentHandler.exit(), readAssignment);
} else {
StackManipulation writeAssignment = assigner.assign(target, exitType, typing);
if (!writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to " + exitType);
}
return new Target.ForVariable.ReadWrite(target, argumentHandler.exit(), readAssignment, writeAssignment);
}
}
/**
* A factory for creating a {@link ForExitValue} offset mapping.
*/
@HashCodeAndEqualsPlugin.Enhance
protected static class Factory implements OffsetMapping.Factory {
/**
* A description of the {@link Exit#readOnly()} method.
*/
private static final MethodDescription.InDefinedShape EXIT_READ_ONLY;
/**
* A description of the {@link Exit#typing()} method.
*/
private static final MethodDescription.InDefinedShape EXIT_TYPING;
/*
* Resolves annotation properties.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(Exit.class).getDeclaredMethods();
EXIT_READ_ONLY = methods.filter(named("readOnly")).getOnly();
EXIT_TYPING = methods.filter(named("typing")).getOnly();
}
/**
* The supplied type of the exit advice.
*/
private final TypeDefinition exitType;
/**
* Creates a new factory for creating a {@link ForExitValue} offset mapping.
*
* @param exitType The supplied type of the exit advice.
*/
protected Factory(TypeDefinition exitType) {
this.exitType = exitType;
}
/**
* Creates a new factory for creating a {@link ForExitValue} offset mapping.
*
* @param typeDefinition The supplied type of the enter method.
* @return An appropriate offset mapping factory.
*/
protected static OffsetMapping.Factory of(TypeDefinition typeDefinition) {
return typeDefinition.represents(void.class)
? new Illegal(Exit.class)
: new Factory(typeDefinition);
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return Exit.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (adviceType.isDelegation() && !annotation.getValue(EXIT_READ_ONLY).resolve(Boolean.class)) {
throw new IllegalStateException("Cannot use writable " + target + " on read-only parameter");
} else {
return new ForExitValue(target.getType(), exitType.asGenericType(), annotation);
}
}
}
}
/**
* An offset mapping that provides access to a named local variable that is declared by the advice methods via {@link Local}.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForLocalValue implements OffsetMapping {
/**
* The variable's target type.
*/
private final TypeDescription.Generic target;
/**
* The local variable's type.
*/
private final TypeDescription.Generic localType;
/**
* The local variable's name.
*/
private final String name;
/**
* Creates an offset mapping for a local variable that is declared by the advice methods via {@link Local}.
*
* @param target The variable's target type.
* @param localType The local variable's type.
* @param name The local variable's name.
*/
public ForLocalValue(TypeDescription.Generic target, TypeDescription.Generic localType, String name) {
this.target = target;
this.localType = localType;
this.name = name;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
StackManipulation readAssignment = assigner.assign(localType, target, Assigner.Typing.STATIC);
StackManipulation writeAssignment = assigner.assign(target, localType, Assigner.Typing.STATIC);
if (!readAssignment.isValid() || !writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + localType + " to " + target);
} else {
return new Target.ForVariable.ReadWrite(target, argumentHandler.named(name), readAssignment, writeAssignment);
}
}
/**
* A factory for an offset mapping for a local variable that is declared by the advice methods via {@link Local}.
*/
@HashCodeAndEqualsPlugin.Enhance
protected static class Factory implements OffsetMapping.Factory {
/**
* A description of the {@link Local#value()} method.
*/
protected static final MethodDescription.InDefinedShape LOCAL_VALUE = TypeDescription.ForLoadedType.of(Local.class)
.getDeclaredMethods()
.filter(named("value"))
.getOnly();
/**
* The mapping of type names to their type that are available.
*/
private final Map namedTypes;
/**
* Creates a factory for a {@link Local} variable mapping.
*
* @param namedTypes The mapping of type names to their type that are available.
*/
protected Factory(Map namedTypes) {
this.namedTypes = namedTypes;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return Local.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
String name = annotation.getValue(LOCAL_VALUE).resolve(String.class);
TypeDefinition namedType = namedTypes.get(name);
if (namedType == null) {
throw new IllegalStateException("Named local variable is unknown: " + name);
}
return new ForLocalValue(target.getType(), namedType.asGenericType(), name);
}
}
}
/**
* An offset mapping that provides access to the value that is returned by the instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForReturnValue implements OffsetMapping {
/**
* The type that the advice method expects for the return value.
*/
private final TypeDescription.Generic target;
/**
* Determines if the parameter is to be treated as read-only.
*/
private final boolean readOnly;
/**
* The typing to apply.
*/
private final Assigner.Typing typing;
/**
* Creates a new offset mapping for a return value.
*
* @param target The type that the advice method expects for the return value.
* @param annotation The annotation being bound.
*/
protected ForReturnValue(TypeDescription.Generic target, AnnotationDescription.Loadable annotation) {
this(target,
annotation.getValue(Factory.RETURN_READ_ONLY).resolve(Boolean.class),
annotation.getValue(Factory.RETURN_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class));
}
/**
* Creates a new offset mapping for a return value.
*
* @param target The type that the advice method expects for the return value.
* @param readOnly Determines if the parameter is to be treated as read-only.
* @param typing The typing to apply.
*/
public ForReturnValue(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing) {
this.target = target;
this.readOnly = readOnly;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
StackManipulation readAssignment = assigner.assign(instrumentedMethod.getReturnType(), target, typing);
if (!readAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + instrumentedMethod.getReturnType() + " to " + target);
} else if (readOnly) {
return instrumentedMethod.getReturnType().represents(void.class)
? new Target.ForDefaultValue.ReadOnly(target)
: new Target.ForVariable.ReadOnly(instrumentedMethod.getReturnType(), argumentHandler.returned(), readAssignment);
} else {
StackManipulation writeAssignment = assigner.assign(target, instrumentedMethod.getReturnType(), typing);
if (!writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to " + instrumentedMethod.getReturnType());
}
return instrumentedMethod.getReturnType().represents(void.class)
? new Target.ForDefaultValue.ReadWrite(target)
: new Target.ForVariable.ReadWrite(instrumentedMethod.getReturnType(), argumentHandler.returned(), readAssignment, writeAssignment);
}
}
/**
* A factory for creating a {@link ForReturnValue} offset mapping.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* A description of the {@link Return#readOnly()} method.
*/
private static final MethodDescription.InDefinedShape RETURN_READ_ONLY;
/**
* A description of the {@link Return#typing()} method.
*/
private static final MethodDescription.InDefinedShape RETURN_TYPING;
/*
* Resolves the annotation properties.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(Return.class).getDeclaredMethods();
RETURN_READ_ONLY = methods.filter(named("readOnly")).getOnly();
RETURN_TYPING = methods.filter(named("typing")).getOnly();
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return Return.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (adviceType.isDelegation() && !annotation.getValue(RETURN_READ_ONLY).resolve(Boolean.class)) {
throw new IllegalStateException("Cannot write return value for " + target + " in read-only context");
} else {
return new ForReturnValue(target.getType(), annotation);
}
}
}
}
/**
* An offset mapping for accessing a {@link Throwable} of the instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForThrowable implements OffsetMapping {
/**
* The type of parameter that is being accessed.
*/
private final TypeDescription.Generic target;
/**
* {@code true} if the parameter is read-only.
*/
private final boolean readOnly;
/**
* The typing to apply.
*/
private final Assigner.Typing typing;
/**
* Creates a new offset mapping for access of the exception that is thrown by the instrumented method..
*
* @param target The type of parameter that is being accessed.
* @param annotation The annotation to bind.
*/
protected ForThrowable(TypeDescription.Generic target, AnnotationDescription.Loadable annotation) {
this(target,
annotation.getValue(Factory.THROWN_READ_ONLY).resolve(Boolean.class),
annotation.getValue(Factory.THROWN_TYPING).resolve(EnumerationDescription.class).load(Assigner.Typing.class));
}
/**
* Creates a new offset mapping for access of the exception that is thrown by the instrumented method..
*
* @param target The type of parameter that is being accessed.
* @param readOnly {@code true} if the parameter is read-only.
* @param typing The typing to apply.
*/
public ForThrowable(TypeDescription.Generic target, boolean readOnly, Assigner.Typing typing) {
this.target = target;
this.readOnly = readOnly;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
StackManipulation readAssignment = assigner.assign(TypeDescription.ForLoadedType.of(Throwable.class).asGenericType(), target, typing);
if (!readAssignment.isValid()) {
throw new IllegalStateException("Cannot assign Throwable to " + target);
} else if (readOnly) {
return new Target.ForVariable.ReadOnly(TypeDescription.ForLoadedType.of(Throwable.class), argumentHandler.thrown(), readAssignment);
} else {
StackManipulation writeAssignment = assigner.assign(target, TypeDescription.ForLoadedType.of(Throwable.class).asGenericType(), typing);
if (!writeAssignment.isValid()) {
throw new IllegalStateException("Cannot assign " + target + " to Throwable");
}
return new Target.ForVariable.ReadWrite(TypeDescription.ForLoadedType.of(Throwable.class), argumentHandler.thrown(), readAssignment, writeAssignment);
}
}
/**
* A factory for accessing an exception that was thrown by the instrumented method.
*/
protected enum Factory implements OffsetMapping.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* A description of the {@link Thrown#readOnly()} method.
*/
private static final MethodDescription.InDefinedShape THROWN_READ_ONLY;
/**
* A description of the {@link Thrown#typing()} method.
*/
private static final MethodDescription.InDefinedShape THROWN_TYPING;
/*
* Resolves annotation properties.
*/
static {
MethodList methods = TypeDescription.ForLoadedType.of(Thrown.class).getDeclaredMethods();
THROWN_READ_ONLY = methods.filter(named("readOnly")).getOnly();
THROWN_TYPING = methods.filter(named("typing")).getOnly();
}
/**
* Resolves an appropriate offset mapping factory for the {@link Thrown} parameter annotation.
*
* @param adviceMethod The exit advice method, annotated with {@link OnMethodExit}.
* @return An appropriate offset mapping factory.
*/
@SuppressWarnings("unchecked") // In absence of @SafeVarargs
@SuppressFBWarnings(value = "NP_NULL_ON_SOME_PATH_FROM_RETURN_VALUE", justification = "Assuming annotation for exit advice.")
protected static OffsetMapping.Factory> of(MethodDescription.InDefinedShape adviceMethod) {
return adviceMethod.getDeclaredAnnotations()
.ofType(OnMethodExit.class)
.getValue(ON_THROWABLE)
.resolve(TypeDescription.class)
.represents(NoExceptionHandler.class) ? new OffsetMapping.Factory.Illegal(Thrown.class) : Factory.INSTANCE;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return Thrown.class;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
if (adviceType.isDelegation() && !annotation.getValue(THROWN_READ_ONLY).resolve(Boolean.class)) {
throw new IllegalStateException("Cannot use writable " + target + " on read-only parameter");
} else {
return new ForThrowable(target.getType(), annotation);
}
}
}
}
/**
* An offset mapping for binding a stack manipulation.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForStackManipulation implements OffsetMapping {
/**
* The stack manipulation that loads the bound value.
*/
private final StackManipulation stackManipulation;
/**
* The type of the loaded value.
*/
private final TypeDescription.Generic typeDescription;
/**
* The target type of the annotated parameter.
*/
private final TypeDescription.Generic targetType;
/**
* The typing to apply.
*/
private final Assigner.Typing typing;
/**
* Creates an offset mapping that binds a stack manipulation.
*
* @param stackManipulation The stack manipulation that loads the bound value.
* @param typeDescription The type of the loaded value.
* @param targetType The target type of the annotated parameter.
* @param typing The typing to apply.
*/
public ForStackManipulation(StackManipulation stackManipulation,
TypeDescription.Generic typeDescription,
TypeDescription.Generic targetType,
Assigner.Typing typing) {
this.stackManipulation = stackManipulation;
this.typeDescription = typeDescription;
this.targetType = targetType;
this.typing = typing;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
StackManipulation assignment = assigner.assign(typeDescription, targetType, typing);
if (!assignment.isValid()) {
throw new IllegalStateException("Cannot assign " + typeDescription + " to " + targetType);
}
return new Target.ForStackManipulation(new StackManipulation.Compound(stackManipulation, assignment));
}
/**
* A factory that binds a stack manipulation.
*
* @param The annotation type this factory binds.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Factory implements OffsetMapping.Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* The stack manipulation that loads the bound value.
*/
private final StackManipulation stackManipulation;
/**
* The type of the loaded value.
*/
private final TypeDescription.Generic typeDescription;
/**
* Creates a new factory for binding a type description.
*
* @param annotationType The annotation type.
* @param typeDescription The type to bind.
*/
public Factory(Class annotationType, TypeDescription typeDescription) {
this(annotationType, ClassConstant.of(typeDescription), TypeDescription.ForLoadedType.of(Class.class).asGenericType());
}
/**
* Creates a new factory for binding an enumeration.
*
* @param annotationType The annotation type.
* @param enumerationDescription The enumeration to bind.
*/
public Factory(Class annotationType, EnumerationDescription enumerationDescription) {
this(annotationType, FieldAccess.forEnumeration(enumerationDescription), enumerationDescription.getEnumerationType().asGenericType());
}
/**
* Creates a new factory for binding a Java constant.
*
* @param annotationType The annotation type.
* @param constant The bound constant value.
*/
public Factory(Class annotationType, ConstantValue constant) {
this(annotationType, constant.toStackManipulation(), constant.getTypeDescription().asGenericType());
}
/**
* Creates a new factory for binding a stack manipulation.
*
* @param annotationType The annotation type.
* @param stackManipulation The stack manipulation that loads the bound value.
* @param typeDescription The type of the loaded value.
*/
public Factory(Class annotationType, StackManipulation stackManipulation, TypeDescription.Generic typeDescription) {
this.annotationType = annotationType;
this.stackManipulation = stackManipulation;
this.typeDescription = typeDescription;
}
/**
* Creates a binding for a fixed {@link String}, a primitive value or a method handle or type.
*
* @param annotationType The annotation type.
* @param value The constant value to bind or {@code null} to bind the parameter type's default value.
* @param The annotation type.
* @return A factory for creating an offset mapping that binds the supplied value.
*/
public static OffsetMapping.Factory of(Class annotationType, @MaybeNull Object value) {
return value == null
? new OfDefaultValue(annotationType)
: new Factory(annotationType, ConstantValue.Simple.wrap(value));
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target,
AnnotationDescription.Loadable annotation,
AdviceType adviceType) {
return new ForStackManipulation(stackManipulation, typeDescription, target.getType(), Assigner.Typing.STATIC);
}
}
/**
* A factory for binding the annotated parameter's default value.
*
* @param The annotation type this factory binds.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class OfDefaultValue implements OffsetMapping.Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* Creates a factory for an offset mapping tat binds the parameter's default value.
*
* @param annotationType The annotation type.
*/
public OfDefaultValue(Class annotationType) {
this.annotationType = annotationType;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target, AnnotationDescription.Loadable annotation, AdviceType adviceType) {
return new ForStackManipulation(DefaultValue.of(target.getType()), target.getType(), target.getType(), Assigner.Typing.STATIC);
}
}
/**
* A factory for binding an annotation's property.
*
* @param The annotation type this factory binds.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class OfAnnotationProperty implements OffsetMapping.Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* The annotation property.
*/
private final MethodDescription.InDefinedShape property;
/**
* Creates a factory for binding an annotation property.
*
* @param annotationType The annotation type.
* @param property The annotation property.
*/
protected OfAnnotationProperty(Class annotationType, MethodDescription.InDefinedShape property) {
this.annotationType = annotationType;
this.property = property;
}
/**
* Creates a factory for an offset mapping that binds an annotation property.
*
* @param annotationType The annotation type to bind.
* @param property The property to bind.
* @param The annotation type.
* @return A factory for binding a property of the annotation type.
*/
public static OffsetMapping.Factory of(Class annotationType, String property) {
if (!annotationType.isAnnotation()) {
throw new IllegalArgumentException("Not an annotation type: " + annotationType);
}
try {
return new OfAnnotationProperty(annotationType, new MethodDescription.ForLoadedMethod(annotationType.getMethod(property)));
} catch (NoSuchMethodException exception) {
throw new IllegalArgumentException("Cannot find a property " + property + " on " + annotationType, exception);
}
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target, AnnotationDescription.Loadable annotation, AdviceType adviceType) {
ConstantValue value = ConstantValue.Simple.wrapOrNull(annotation.getValue(property).resolve());
if (value == null) {
throw new IllegalStateException("Property does not represent a constant value: " + property);
}
return new ForStackManipulation(value.toStackManipulation(),
value.getTypeDescription().asGenericType(),
target.getType(),
Assigner.Typing.STATIC);
}
}
/**
* Uses dynamic method invocation for binding an annotated parameter to a value.
*
* @param The annotation type this factory binds.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class OfDynamicInvocation implements OffsetMapping.Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* The bootstrap method or constructor.
*/
private final MethodDescription.InDefinedShape bootstrapMethod;
/**
* The arguments to the bootstrap method.
*/
private final List extends JavaConstant> arguments;
/**
* Creates a new factory for a dynamic invocation.
*
* @param annotationType The annotation type.
* @param bootstrapMethod The bootstrap method or constructor.
* @param arguments The arguments to the bootstrap method.
*/
public OfDynamicInvocation(Class annotationType, MethodDescription.InDefinedShape bootstrapMethod, List extends JavaConstant> arguments) {
this.annotationType = annotationType;
this.bootstrapMethod = bootstrapMethod;
this.arguments = arguments;
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target, AnnotationDescription.Loadable annotation, AdviceType adviceType) {
if (!target.getType().isInterface()) {
throw new IllegalArgumentException(target.getType() + " is not an interface");
} else if (!target.getType().getInterfaces().isEmpty()) {
throw new IllegalArgumentException(target.getType() + " must not extend other interfaces");
} else if (!target.getType().isPublic()) {
throw new IllegalArgumentException(target.getType() + " is mot public");
}
MethodList> methodCandidates = target.getType().getDeclaredMethods().filter(isAbstract());
if (methodCandidates.size() != 1) {
throw new IllegalArgumentException(target.getType() + " must declare exactly one abstract method");
}
return new ForStackManipulation(MethodInvocation.invoke(bootstrapMethod).dynamic(methodCandidates.getOnly().getInternalName(),
target.getType().asErasure(),
Collections.emptyList(),
arguments), target.getType(), target.getType(), Assigner.Typing.STATIC);
}
}
}
/**
* An offset mapping that loads a serialized value.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForSerializedValue implements OffsetMapping {
/**
* The type of the serialized value as it is used.
*/
private final TypeDescription.Generic target;
/**
* The class type of the serialized value.
*/
private final TypeDescription typeDescription;
/**
* The stack manipulation deserializing the represented value.
*/
private final StackManipulation deserialization;
/**
* Creates a new offset mapping for a serialized value.
*
* @param target The type of the serialized value as it is used.
* @param typeDescription The class type of the serialized value.
* @param deserialization The stack manipulation deserializing the represented value.
*/
public ForSerializedValue(TypeDescription.Generic target, TypeDescription typeDescription, StackManipulation deserialization) {
this.target = target;
this.typeDescription = typeDescription;
this.deserialization = deserialization;
}
/**
* {@inheritDoc}
*/
public Target resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
Sort sort) {
StackManipulation assignment = assigner.assign(typeDescription.asGenericType(), target, Assigner.Typing.DYNAMIC);
if (!assignment.isValid()) {
throw new IllegalStateException("Cannot assign " + typeDescription + " to " + target);
}
return new Target.ForStackManipulation(new StackManipulation.Compound(deserialization, assignment));
}
/**
* A factory for loading a deserialized value.
*
* @param The annotation type this factory binds.
*/
@HashCodeAndEqualsPlugin.Enhance
public static class Factory implements OffsetMapping.Factory {
/**
* The annotation type.
*/
private final Class annotationType;
/**
* The type description as which to treat the deserialized value.
*/
private final TypeDescription typeDescription;
/**
* The stack manipulation that loads the represented value.
*/
private final StackManipulation deserialization;
/**
* Creates a factory for loading a deserialized value.
*
* @param annotationType The annotation type.
* @param typeDescription The type description as which to treat the deserialized value.
* @param deserialization The stack manipulation that loads the represented value.
*/
protected Factory(Class annotationType, TypeDescription typeDescription, StackManipulation deserialization) {
this.annotationType = annotationType;
this.typeDescription = typeDescription;
this.deserialization = deserialization;
}
/**
* Creates a factory for an offset mapping that loads the provided value.
*
* @param annotationType The annotation type to be bound.
* @param target The instance representing the value to be deserialized.
* @param targetType The target type as which to use the target value.
* @param The annotation type the created factory binds.
* @param The type of the -represented constant.
* @return An appropriate offset mapping factory.
*/
public static OffsetMapping.Factory of(Class annotationType, U target, Class super U> targetType) {
if (!targetType.isInstance(target)) {
throw new IllegalArgumentException(target + " is no instance of " + targetType);
}
return new Factory(annotationType, TypeDescription.ForLoadedType.of(targetType), SerializedConstant.of(target));
}
/**
* {@inheritDoc}
*/
public Class getAnnotationType() {
return annotationType;
}
/**
* {@inheritDoc}
*/
public OffsetMapping make(ParameterDescription.InDefinedShape target, AnnotationDescription.Loadable annotation, AdviceType adviceType) {
return new ForSerializedValue(target.getType(), typeDescription, deserialization);
}
}
}
}
/**
* An argument handler is responsible for resolving offsets of the local variable array in the context of the applied instrumentation.
*/
public interface ArgumentHandler {
/**
* The offset of the {@code this} reference.
*/
int THIS_REFERENCE = 0;
/**
* Resolves an offset relative to an offset of the instrumented method.
*
* @param offset The offset to resolve.
* @return The resolved offset.
*/
int argument(int offset);
/**
* Resolves the offset of the exit value of the exit advice.
*
* @return The offset of the exit value.
*/
int exit();
/**
* Resolves the offset of the enter value of the enter advice.
*
* @return The offset of the enter value.
*/
int enter();
/**
* Returns the offset of the local variable with the given name.
*
* @param name The name of the local variable being accessed.
* @return The named variable's offset.
*/
int named(String name);
/**
* Resolves the offset of the returned value of the instrumented method.
*
* @return The offset of the returned value of the instrumented method.
*/
int returned();
/**
* Resolves the offset of the thrown exception of the instrumented method.
*
* @return The offset of the thrown exception of the instrumented method.
*/
int thrown();
/**
* An argument handler that is used for resolving the instrumented method.
*/
interface ForInstrumentedMethod extends ArgumentHandler {
/**
* Prepares this argument handler for future offset access.
*
* @param methodVisitor The method visitor to which to write any potential byte code.
* @return The minimum stack size that is required to apply this manipulation.
*/
int prepare(MethodVisitor methodVisitor);
/**
* Binds an advice method as enter advice for this handler.
*
* @param adviceMethod The resolved enter advice handler.
* @return The resolved argument handler for enter advice.
*/
ForAdvice bindEnter(MethodDescription adviceMethod);
/**
* Binds an advice method as exit advice for this handler.
*
* @param adviceMethod The resolved exit advice handler.
* @param skipThrowable {@code true} if no throwable is stored.
* @return The resolved argument handler for enter advice.
*/
ForAdvice bindExit(MethodDescription adviceMethod, boolean skipThrowable);
/**
* Returns {@code true} if the original arguments are copied before invoking the instrumented method.
*
* @return {@code true} if the original arguments are copied before invoking the instrumented method.
*/
boolean isCopyingArguments();
/**
* Returns a list of the named types in their declared order.
*
* @return A list of the named types in their declared order.
*/
List getNamedTypes();
/**
* A default implementation of an argument handler for an instrumented method.
*/
abstract class Default implements ForInstrumentedMethod {
/**
* The instrumented method.
*/
protected final MethodDescription instrumentedMethod;
/**
* The exit type or {@code void} if no exit type is defined.
*/
protected final TypeDefinition exitType;
/**
* A mapping of all available local variables by their name to their type.
*/
protected final SortedMap namedTypes;
/**
* The enter type or {@code void} if no enter type is defined.
*/
protected final TypeDefinition enterType;
/**
* Creates a new default argument handler for an instrumented method.
*
* @param instrumentedMethod The instrumented method.
* @param exitType The exit type or {@code void} if no exit type is defined.
* @param namedTypes A mapping of all available local variables by their name to their type.
* @param enterType The enter type or {@code void} if no enter type is defined.
*/
protected Default(MethodDescription instrumentedMethod,
TypeDefinition exitType,
SortedMap namedTypes,
TypeDefinition enterType) {
this.instrumentedMethod = instrumentedMethod;
this.namedTypes = namedTypes;
this.exitType = exitType;
this.enterType = enterType;
}
/**
* {@inheritDoc}
*/
public int exit() {
return instrumentedMethod.getStackSize();
}
/**
* {@inheritDoc}
*/
public int named(String name) {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.headMap(name).values());
}
/**
* {@inheritDoc}
*/
public int enter() {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values());
}
/**
* {@inheritDoc}
*/
public int returned() {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
+ enterType.getStackSize().getSize();
}
/**
* {@inheritDoc}
*/
public int thrown() {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
+ enterType.getStackSize().getSize()
+ instrumentedMethod.getReturnType().getStackSize().getSize();
}
/**
* {@inheritDoc}
*/
public ForAdvice bindEnter(MethodDescription adviceMethod) {
return new ForAdvice.Default.ForMethodEnter(instrumentedMethod, adviceMethod, exitType, namedTypes);
}
/**
* {@inheritDoc}
*/
public ForAdvice bindExit(MethodDescription adviceMethod, boolean skipThrowable) {
return new ForAdvice.Default.ForMethodExit(instrumentedMethod,
adviceMethod,
exitType,
namedTypes,
enterType,
skipThrowable ? StackSize.ZERO : StackSize.SINGLE);
}
/**
* {@inheritDoc}
*/
public List getNamedTypes() {
List namedTypes = new ArrayList(this.namedTypes.size());
for (TypeDefinition typeDefinition : this.namedTypes.values()) {
namedTypes.add(typeDefinition.asErasure());
}
return namedTypes;
}
/**
* A simple argument handler for an instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
protected static class Simple extends Default {
/**
* Creates a new simple argument handler for an instrumented method.
*
* @param instrumentedMethod The instrumented method.
* @param exitType The exit type or {@code void} if no exit type is defined.
* @param namedTypes A mapping of all available local variables by their name to their type.
* @param enterType The enter type or {@code void} if no enter type is defined.
*/
protected Simple(MethodDescription instrumentedMethod,
TypeDefinition exitType,
SortedMap namedTypes,
TypeDefinition enterType) {
super(instrumentedMethod, exitType, namedTypes, enterType);
}
/**
* {@inheritDoc}
*/
public int argument(int offset) {
return offset < instrumentedMethod.getStackSize()
? offset
: offset + exitType.getStackSize().getSize() + StackSize.of(namedTypes.values()) + enterType.getStackSize().getSize();
}
/**
* {@inheritDoc}
*/
public boolean isCopyingArguments() {
return false;
}
/**
* {@inheritDoc}
*/
public int prepare(MethodVisitor methodVisitor) {
return 0;
}
}
/**
* An argument handler for an instrumented method that copies all arguments before executing the instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
protected static class Copying extends Default {
/**
* Creates a new copying argument handler for an instrumented method.
*
* @param instrumentedMethod The instrumented method.
* @param exitType The exit type or {@code void} if no exit type is defined.
* @param namedTypes A mapping of all available local variables by their name to their type.
* @param enterType The enter type or {@code void} if no enter type is defined.
*/
protected Copying(MethodDescription instrumentedMethod,
TypeDefinition exitType,
SortedMap namedTypes,
TypeDefinition enterType) {
super(instrumentedMethod, exitType, namedTypes, enterType);
}
/**
* {@inheritDoc}
*/
public int argument(int offset) {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
+ enterType.getStackSize().getSize()
+ offset;
}
/**
* {@inheritDoc}
*/
public boolean isCopyingArguments() {
return true;
}
/**
* {@inheritDoc}
*/
public int prepare(MethodVisitor methodVisitor) {
StackSize stackSize;
if (!instrumentedMethod.isStatic()) {
methodVisitor.visitVarInsn(Opcodes.ALOAD, 0);
methodVisitor.visitVarInsn(Opcodes.ASTORE, instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
+ enterType.getStackSize().getSize());
stackSize = StackSize.SINGLE;
} else {
stackSize = StackSize.ZERO;
}
for (ParameterDescription parameterDescription : instrumentedMethod.getParameters()) {
Type type = Type.getType(parameterDescription.getType().asErasure().getDescriptor());
methodVisitor.visitVarInsn(type.getOpcode(Opcodes.ILOAD), parameterDescription.getOffset());
methodVisitor.visitVarInsn(type.getOpcode(Opcodes.ISTORE), instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
+ enterType.getStackSize().getSize()
+ parameterDescription.getOffset());
stackSize = stackSize.maximum(parameterDescription.getType().getStackSize());
}
return stackSize.getSize();
}
}
}
}
/**
* An argument handler that is used for resolving an advice method.
*/
interface ForAdvice extends ArgumentHandler {
/**
* Resolves an offset of the advice method.
*
* @param offset The offset to resolve.
* @return The resolved offset.
*/
int mapped(int offset);
/**
* A default implementation for an argument handler for an advice method.
*/
abstract class Default implements ForAdvice {
/**
* The instrumented method.
*/
protected final MethodDescription instrumentedMethod;
/**
* The advice method.
*/
protected final MethodDescription adviceMethod;
/**
* The enter type or {@code void} if no enter type is defined.
*/
protected final TypeDefinition exitType;
/**
* A mapping of all available local variables by their name to their type.
*/
protected final SortedMap namedTypes;
/**
* Creates a new argument handler for an enter advice.
*
* @param instrumentedMethod The instrumented method.
* @param adviceMethod The advice method.
* @param exitType The exit type or {@code void} if no exit type is defined.
* @param namedTypes A mapping of all available local variables by their name to their type.
*/
protected Default(MethodDescription instrumentedMethod,
MethodDescription adviceMethod,
TypeDefinition exitType,
SortedMap namedTypes) {
this.instrumentedMethod = instrumentedMethod;
this.adviceMethod = adviceMethod;
this.exitType = exitType;
this.namedTypes = namedTypes;
}
/**
* {@inheritDoc}
*/
public int argument(int offset) {
return offset;
}
/**
* {@inheritDoc}
*/
public int exit() {
return instrumentedMethod.getStackSize();
}
/**
* {@inheritDoc}
*/
public int named(String name) {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.headMap(name).values());
}
/**
* {@inheritDoc}
*/
public int enter() {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values());
}
/**
* An argument handler for an enter advice method.
*/
@HashCodeAndEqualsPlugin.Enhance
protected static class ForMethodEnter extends Default {
/**
* Creates a new argument handler for an enter advice method.
*
* @param instrumentedMethod The instrumented method.
* @param adviceMethod The advice method.
* @param exitType The exit type or {@code void} if no exit type is defined.
* @param namedTypes A mapping of all available local variables by their name to their type.
*/
protected ForMethodEnter(MethodDescription instrumentedMethod,
MethodDescription adviceMethod,
TypeDefinition exitType,
SortedMap namedTypes) {
super(instrumentedMethod, adviceMethod, exitType, namedTypes);
}
/**
* {@inheritDoc}
*/
public int returned() {
throw new IllegalStateException("Cannot resolve the return value offset during enter advice");
}
/**
* {@inheritDoc}
*/
public int thrown() {
throw new IllegalStateException("Cannot resolve the thrown value offset during enter advice");
}
/**
* {@inheritDoc}
*/
public int mapped(int offset) {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
- adviceMethod.getStackSize() + offset;
}
}
/**
* An argument handler for an exit advice method.
*/
@HashCodeAndEqualsPlugin.Enhance
protected static class ForMethodExit extends Default {
/**
* The enter type or {@code void} if no enter type is defined.
*/
private final TypeDefinition enterType;
/**
* The stack size of a possibly stored throwable.
*/
private final StackSize throwableSize;
/**
* Creates a new argument handler for an exit advice method.
*
* @param instrumentedMethod The instrumented method.
* @param adviceMethod The advice method.
* @param exitType The exit type or {@code void} if no exit type is defined.
* @param namedTypes A mapping of all available local variables by their name to their type.
* @param enterType The enter type or {@code void} if no enter type is defined.
* @param throwableSize The stack size of a possibly stored throwable.
*/
protected ForMethodExit(MethodDescription instrumentedMethod,
MethodDescription adviceMethod,
TypeDefinition exitType,
SortedMap namedTypes,
TypeDefinition enterType,
StackSize throwableSize) {
super(instrumentedMethod, adviceMethod, exitType, namedTypes);
this.enterType = enterType;
this.throwableSize = throwableSize;
}
/**
* {@inheritDoc}
*/
public int returned() {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
+ enterType.getStackSize().getSize();
}
/**
* {@inheritDoc}
*/
public int thrown() {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
+ enterType.getStackSize().getSize()
+ instrumentedMethod.getReturnType().getStackSize().getSize();
}
/**
* {@inheritDoc}
*/
public int mapped(int offset) {
return instrumentedMethod.getStackSize()
+ exitType.getStackSize().getSize()
+ StackSize.of(namedTypes.values())
+ enterType.getStackSize().getSize()
+ instrumentedMethod.getReturnType().getStackSize().getSize()
+ throwableSize.getSize()
- adviceMethod.getStackSize()
+ offset;
}
}
}
}
/**
* A factory for creating an argument handler.
*/
enum Factory {
/**
* A factory for creating a simple argument handler.
*/
SIMPLE {
@Override
protected ForInstrumentedMethod resolve(MethodDescription instrumentedMethod,
TypeDefinition enterType,
TypeDefinition exitType,
SortedMap namedTypes) {
return new ForInstrumentedMethod.Default.Simple(instrumentedMethod,
exitType,
namedTypes,
enterType);
}
},
/**
* A factory for creating an argument handler that copies all arguments before executing the instrumented method.
*/
COPYING {
@Override
protected ForInstrumentedMethod resolve(MethodDescription instrumentedMethod,
TypeDefinition enterType,
TypeDefinition exitType,
SortedMap namedTypes) {
return new ForInstrumentedMethod.Default.Copying(instrumentedMethod,
exitType,
namedTypes,
enterType);
}
};
/**
* Creates an argument handler.
*
* @param instrumentedMethod The instrumented method.
* @param enterType The enter type or {@code void} if no such type is defined.
* @param exitType The exit type or {@code void} if no exit type is defined.
* @param namedTypes A mapping of all available local variables by their name to their type.
* @return An argument handler for the instrumented method.
*/
protected abstract ForInstrumentedMethod resolve(MethodDescription instrumentedMethod,
TypeDefinition enterType,
TypeDefinition exitType,
SortedMap namedTypes);
}
}
/**
*
* A post processor for advice methods that is invoked after advice is executed. A post processor
* is invoked after the instrumented method and only after a regular completion of the method. When
* invoked, the advice method's return value is stored in the local variable array. Upon completion,
* the local variable array must still be intact and the stack must be empty. A frame is added
* subsequently to the post processor's execution, making it feasible to add a jump instruction to the
* end of the method after which no further byte code instructions must be issued. This also applies
* to compound post processors. If a post processor emits a frame as its last instruction, it should
* yield a NOP instruction to avoid that subsequent code starts with a frame.
*
*
* Important: A post processor is triggered after the suppression handler. Exceptions triggered
* by post processing code will therefore cause those exceptions to be propagated unless the post
* processor configures explicit exception handling.
*
*/
public interface PostProcessor {
/**
* Resolves this post processor for a given instrumented method.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param assigner The assigner to use.
* @param argumentHandler The argument handler to use.
* @param stackMapFrameHandler The argument handler for the instrumented method.
* @param exceptionHandler The exception handler that is resolved for the instrumented method.
* @return The stack manipulation to apply.
*/
StackManipulation resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
StackMapFrameHandler.ForPostProcessor stackMapFrameHandler,
StackManipulation exceptionHandler);
/**
* A factory for creating a {@link PostProcessor}.
*/
interface Factory {
/**
* Creates a post processor for a given advice method.
*
* @param advice The advice method to create the post processor for.
* @param exit {@code true} if the advice is exit advice.
* @return The created post processor.
*/
PostProcessor make(MethodDescription.InDefinedShape advice, boolean exit);
/**
* A compound factory for a post processor.
*/
@HashCodeAndEqualsPlugin.Enhance
class Compound implements Factory {
/**
* The represented post processor factories.
*/
private final List factories;
/**
* Creates a compound post processor factory.
*
* @param factory The represented post processor factories.
*/
public Compound(Factory... factory) {
this(Arrays.asList(factory));
}
/**
* Creates a compound post processor factory.
*
* @param factories The represented post processor factories.
*/
public Compound(List extends Factory> factories) {
this.factories = new ArrayList();
for (Factory factory : factories) {
if (factory instanceof Compound) {
this.factories.addAll(((Compound) factory).factories);
} else if (!(factory instanceof NoOp)) {
this.factories.add(factory);
}
}
}
/**
* {@inheritDoc}
*/
public PostProcessor make(MethodDescription.InDefinedShape advice, boolean exit) {
List postProcessors = new ArrayList(factories.size());
for (Factory factory : factories) {
postProcessors.add(factory.make(advice, exit));
}
return new PostProcessor.Compound(postProcessors);
}
}
}
/**
* A non-operational advice post processor.
*/
enum NoOp implements PostProcessor, Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public StackManipulation resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
StackMapFrameHandler.ForPostProcessor stackMapFrameHandler,
StackManipulation exceptionHandler) {
return StackManipulation.Trivial.INSTANCE;
}
/**
* {@inheritDoc}
*/
public PostProcessor make(MethodDescription.InDefinedShape advice, boolean exit) {
return this;
}
}
/**
* A compound post processor.
*/
@HashCodeAndEqualsPlugin.Enhance
class Compound implements PostProcessor {
/**
* The represented post processors.
*/
private final List postProcessors;
/**
* Creates a new compound post processor.
*
* @param postProcessors The represented post processors.
*/
protected Compound(List postProcessors) {
this.postProcessors = postProcessors;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolve(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
Assigner assigner,
ArgumentHandler argumentHandler,
StackMapFrameHandler.ForPostProcessor stackMapFrameHandler,
StackManipulation exceptionHandler) {
List stackManipulations = new ArrayList(postProcessors.size());
for (PostProcessor postProcessor : postProcessors) {
stackManipulations.add(postProcessor.resolve(instrumentedType,
instrumentedMethod,
assigner,
argumentHandler,
stackMapFrameHandler,
exceptionHandler));
}
return new StackManipulation.Compound(stackManipulations);
}
}
}
/**
* Materializes an advice invocation within a delegation.
*/
protected interface Delegator {
/**
* Materializes an invocation.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @return An appropriate stack manipulation which needs to consume all arguments for the advice
* method and needs to provide a compatible return type.
*/
StackManipulation apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod);
/**
* A factory for creating a {@link Delegator}.
*/
interface Factory {
/**
* Resolves a delegator.
*
* @param adviceMethod The advice method.
* @param exit {@code true} if the advice is applied as exit advice.
* @return An appropriate delegator.
*/
Delegator make(MethodDescription.InDefinedShape adviceMethod, boolean exit);
}
/**
* Invokes an advice method using a regular method call.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForRegularInvocation implements Delegator {
/**
* The advice method.
*/
private final MethodDescription.InDefinedShape adviceMethod;
/**
* Creates a delegator for a regular invocation.
*
* @param adviceMethod The advice method.
*/
protected ForRegularInvocation(MethodDescription.InDefinedShape adviceMethod) {
this.adviceMethod = adviceMethod;
}
/**
* {@inheritDoc}
*/
public StackManipulation apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
return MethodInvocation.invoke(adviceMethod);
}
/**
* A factory for a regular method invocation delegator.
*/
protected enum Factory implements Delegator.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public Delegator make(MethodDescription.InDefinedShape adviceMethod, boolean exit) {
return new ForRegularInvocation(adviceMethod);
}
}
}
/**
* Invokes an advice method using a dynamic method call.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForDynamicInvocation implements Delegator {
/**
* The bootstrap method.
*/
private final MethodDescription.InDefinedShape bootstrapMethod;
/**
* The advice method.
*/
private final MethodDescription.InDefinedShape adviceMethod;
/**
* A resolver to provide the arguments to the bootstrap method.
*/
private final BootstrapArgumentResolver resolver;
/**
* Creates a delegator for a dynamic method invocation.
*
* @param bootstrapMethod The bootstrap method.
* @param adviceMethod The advice method.
* @param resolver A resolver to provide the arguments to the bootstrap method.
*/
protected ForDynamicInvocation(MethodDescription.InDefinedShape bootstrapMethod,
MethodDescription.InDefinedShape adviceMethod,
BootstrapArgumentResolver resolver) {
this.bootstrapMethod = bootstrapMethod;
this.adviceMethod = adviceMethod;
this.resolver = resolver;
}
/**
* Creates a new dynamic invocation delegator.
*
* @param bootstrapMethod The bootstrap method or constructor.
* @param resolverFactory A resolver factory to provide the arguments to the bootstrap method.
* @return An appropriate delegator.
*/
protected static Delegator.Factory of(MethodDescription.InDefinedShape bootstrapMethod, BootstrapArgumentResolver.Factory resolverFactory) {
if (!bootstrapMethod.isInvokeBootstrap()) {
throw new IllegalArgumentException("Not a suitable bootstrap target: " + bootstrapMethod);
}
return new Factory(bootstrapMethod, resolverFactory);
}
/**
* {@inheritDoc}
*/
public StackManipulation apply(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
List constants = resolver.resolve(instrumentedType, instrumentedMethod);
if (!bootstrapMethod.isInvokeBootstrap(TypeList.Explicit.of(constants))) {
throw new IllegalStateException("Cannot invoke " + bootstrapMethod + " with arguments: " + constants);
}
return MethodInvocation.invoke(bootstrapMethod).dynamic(adviceMethod.getInternalName(),
adviceMethod.getReturnType().asErasure(),
adviceMethod.getParameters().asTypeList().asErasures(),
constants);
}
/**
* A factory for creating a dynamic invocation dispatcher.
*/
@HashCodeAndEqualsPlugin.Enhance
protected static class Factory implements Delegator.Factory {
/**
* The bootstrap method.
*/
private final MethodDescription.InDefinedShape bootstrapMethod;
/**
* A resolver factory to provide the arguments to the bootstrap method.
*/
private final BootstrapArgumentResolver.Factory resolverFactory;
/**
* Creates a factory for a dynamic invocation dispatcher.
*
* @param bootstrapMethod The bootstrap method.
* @param resolverFactory A resolver factory to provide the arguments to the bootstrap method.
*/
protected Factory(MethodDescription.InDefinedShape bootstrapMethod, BootstrapArgumentResolver.Factory resolverFactory) {
this.bootstrapMethod = bootstrapMethod;
this.resolverFactory = resolverFactory;
}
/**
* {@inheritDoc}
*/
public Delegator make(MethodDescription.InDefinedShape adviceMethod, boolean exit) {
return new ForDynamicInvocation(bootstrapMethod, adviceMethod, resolverFactory.resolve(adviceMethod, exit));
}
}
}
}
/**
* A resolver for the arguments that are provided to a bootstrap method if dynamic dispatch is used.
*/
public interface BootstrapArgumentResolver {
/**
* Resolves the constants that are provided as arguments to the bootstrap methods.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @return A list of constants to supply as arguments to the bootstrap method.
*/
List resolve(TypeDescription instrumentedType, MethodDescription instrumentedMethod);
/**
* A factory for creating a {@link BootstrapArgumentResolver}.
*/
interface Factory {
/**
* Creates a bootstrap argument resolver for a given advice.
*
* @param adviceMethod The advice method.
* @param exit {@code true} if the method is bound as exit advice.
* @return An appropriate bootstrap argument resolver.
*/
BootstrapArgumentResolver resolve(MethodDescription.InDefinedShape adviceMethod, boolean exit);
}
/**
* An argument resolver that supplies a default selection of arguments. The explicitly resolved constant values are:
*
* - A {@link String} of the target's binary class name.
* - A {@code int} with value {@code 0} for an enter advice and {code 1} for an exist advice.
* - A {@link Class} representing the class implementing the instrumented method.
* - A {@link String} with the name of the instrumented method.
* - A {@code java.lang.invoke.MethodHandle} representing the instrumented method unless the target is the type's static initializer.
*
*/
@HashCodeAndEqualsPlugin.Enhance
class ForDefaultValues implements BootstrapArgumentResolver {
/**
* The advice method.
*/
private final MethodDescription.InDefinedShape adviceMethod;
/**
* {@code true} if the advice is applied as exit advice.
*/
private final boolean exit;
/**
* Creates a bootstrap argument resolver with default values.
*
* @param adviceMethod The advice method.
* @param exit {@code true} if the advice is applied as exit advice.
*/
protected ForDefaultValues(MethodDescription.InDefinedShape adviceMethod, boolean exit) {
this.adviceMethod = adviceMethod;
this.exit = exit;
}
/**
* {@inheritDoc}
*/
public List resolve(TypeDescription instrumentedType, MethodDescription instrumentedMethod) {
if (instrumentedMethod.isTypeInitializer()) {
return Arrays.asList(net.bytebuddy.utility.JavaConstant.Simple.ofLoaded(adviceMethod.getDeclaringType().getName()),
net.bytebuddy.utility.JavaConstant.Simple.ofLoaded(exit ? 1 : 0),
net.bytebuddy.utility.JavaConstant.Simple.of(instrumentedType),
net.bytebuddy.utility.JavaConstant.Simple.ofLoaded(instrumentedMethod.getInternalName()));
} else {
return Arrays.asList(net.bytebuddy.utility.JavaConstant.Simple.ofLoaded(adviceMethod.getDeclaringType().getName()),
net.bytebuddy.utility.JavaConstant.Simple.ofLoaded(exit ? 1 : 0),
net.bytebuddy.utility.JavaConstant.Simple.of(instrumentedType),
net.bytebuddy.utility.JavaConstant.Simple.ofLoaded(instrumentedMethod.getInternalName()),
net.bytebuddy.utility.JavaConstant.MethodHandle.of(instrumentedMethod.asDefined()));
}
}
/**
* A factory for creating a {@link ForDefaultValues}.
*/
public enum Factory implements BootstrapArgumentResolver.Factory {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public BootstrapArgumentResolver resolve(MethodDescription.InDefinedShape adviceMethod, boolean exit) {
return new ForDefaultValues(adviceMethod, exit);
}
}
}
}
/**
* A handler for computing the instrumented method's size.
*/
protected interface MethodSizeHandler {
/**
* Indicates that a size is not computed but handled directly by ASM.
*/
int UNDEFINED_SIZE = Short.MAX_VALUE;
/**
* Records a minimum stack size required by the represented advice method.
*
* @param stackSize The minimum size required by the represented advice method.
*/
void requireStackSize(int stackSize);
/**
* Requires a minimum length of the local variable array.
*
* @param localVariableLength The minimal required length of the local variable array.
*/
void requireLocalVariableLength(int localVariableLength);
/**
* A method size handler for the instrumented method.
*/
interface ForInstrumentedMethod extends MethodSizeHandler {
/**
* Binds a method size handler for the enter advice.
*
* @param adviceMethod The method representing the enter advice.
* @return A method size handler for the enter advice.
*/
ForAdvice bindEnter(MethodDescription.InDefinedShape adviceMethod);
/**
* Binds the method size handler for the exit advice.
*
* @param adviceMethod The method representing the exit advice.
* @return A method size handler for the exit advice.
*/
ForAdvice bindExit(MethodDescription.InDefinedShape adviceMethod);
/**
* Computes a compound stack size for the advice and the translated instrumented method.
*
* @param stackSize The required stack size of the instrumented method before translation.
* @return The stack size required by the instrumented method and its advice methods.
*/
int compoundStackSize(int stackSize);
/**
* Computes a compound local variable array length for the advice and the translated instrumented method.
*
* @param localVariableLength The required local variable array length of the instrumented method before translation.
* @return The local variable length required by the instrumented method and its advice methods.
*/
int compoundLocalVariableLength(int localVariableLength);
}
/**
* A method size handler for an advice method.
*/
interface ForAdvice extends MethodSizeHandler {
/**
* Requires additional padding for the operand stack that is required for this advice's execution.
*
* @param stackSizePadding The required padding.
*/
void requireStackSizePadding(int stackSizePadding);
/**
* Requires additional padding for the local variable array that is required for this advice's execution.
*
* @param localVariableLengthPadding The required padding.
*/
void requireLocalVariableLengthPadding(int localVariableLengthPadding);
/**
* Records the maximum values for stack size and local variable array which are required by the advice method
* for its individual execution without translation.
*
* @param stackSize The minimum required stack size.
* @param localVariableLength The minimum required length of the local variable array.
*/
void recordMaxima(int stackSize, int localVariableLength);
}
/**
* A non-operational method size handler.
*/
enum NoOp implements ForInstrumentedMethod, ForAdvice {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public ForAdvice bindEnter(MethodDescription.InDefinedShape adviceMethod) {
return this;
}
/**
* {@inheritDoc}
*/
public ForAdvice bindExit(MethodDescription.InDefinedShape adviceMethod) {
return this;
}
/**
* {@inheritDoc}
*/
public int compoundStackSize(int stackSize) {
return UNDEFINED_SIZE;
}
/**
* {@inheritDoc}
*/
public int compoundLocalVariableLength(int localVariableLength) {
return UNDEFINED_SIZE;
}
/**
* {@inheritDoc}
*/
public void requireStackSize(int stackSize) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void requireLocalVariableLength(int localVariableLength) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void requireStackSizePadding(int stackSizePadding) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void requireLocalVariableLengthPadding(int localVariableLengthPadding) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void recordMaxima(int stackSize, int localVariableLength) {
/* do nothing */
}
}
/**
* A default implementation for a method size handler.
*/
abstract class Default implements MethodSizeHandler.ForInstrumentedMethod {
/**
* The instrumented method.
*/
protected final MethodDescription instrumentedMethod;
/**
* A list of virtual method arguments that are explicitly added before any code execution.
*/
protected final List extends TypeDescription> initialTypes;
/**
* A list of virtual method arguments that are available before the instrumented method is executed.
*/
protected final List extends TypeDescription> preMethodTypes;
/**
* A list of virtual method arguments that are available after the instrumented method has completed.
*/
protected final List extends TypeDescription> postMethodTypes;
/**
* The maximum stack size required by a visited advice method.
*/
protected int stackSize;
/**
* The maximum length of the local variable array required by a visited advice method.
*/
protected int localVariableLength;
/**
* Creates a new default meta data handler that recomputes the space requirements of an instrumented method.
*
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
*/
protected Default(MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes) {
this.instrumentedMethod = instrumentedMethod;
this.initialTypes = initialTypes;
this.preMethodTypes = preMethodTypes;
this.postMethodTypes = postMethodTypes;
}
/**
* Creates a method size handler applicable for the given instrumented method.
*
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
* @param copyArguments {@code true} if the original arguments are copied before invoking the instrumented method.
* @param writerFlags The flags supplied to the ASM class writer.
* @return An appropriate method size handler.
*/
protected static MethodSizeHandler.ForInstrumentedMethod of(MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes,
boolean copyArguments,
int writerFlags) {
if ((writerFlags & (ClassWriter.COMPUTE_MAXS | ClassWriter.COMPUTE_FRAMES)) != 0) {
return NoOp.INSTANCE;
} else if (copyArguments) {
return new WithCopiedArguments(instrumentedMethod, initialTypes, preMethodTypes, postMethodTypes);
} else {
return new WithRetainedArguments(instrumentedMethod, initialTypes, preMethodTypes, postMethodTypes);
}
}
/**
* {@inheritDoc}
*/
public MethodSizeHandler.ForAdvice bindEnter(MethodDescription.InDefinedShape adviceMethod) {
return new ForAdvice(adviceMethod, instrumentedMethod.getStackSize() + StackSize.of(initialTypes));
}
/**
* {@inheritDoc}
*/
public void requireStackSize(int stackSize) {
Default.this.stackSize = Math.max(this.stackSize, stackSize);
}
/**
* {@inheritDoc}
*/
public void requireLocalVariableLength(int localVariableLength) {
this.localVariableLength = Math.max(this.localVariableLength, localVariableLength);
}
/**
* {@inheritDoc}
*/
public int compoundStackSize(int stackSize) {
return Math.max(this.stackSize, stackSize);
}
/**
* {@inheritDoc}
*/
public int compoundLocalVariableLength(int localVariableLength) {
return Math.max(this.localVariableLength, localVariableLength
+ StackSize.of(postMethodTypes)
+ StackSize.of(initialTypes)
+ StackSize.of(preMethodTypes));
}
/**
* A method size handler that expects that the original arguments are retained.
*/
protected static class WithRetainedArguments extends Default {
/**
* Creates a new default method size handler that expects that the original arguments are retained.
*
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
*/
protected WithRetainedArguments(MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes) {
super(instrumentedMethod, initialTypes, preMethodTypes, postMethodTypes);
}
/**
* {@inheritDoc}
*/
public MethodSizeHandler.ForAdvice bindExit(MethodDescription.InDefinedShape adviceMethod) {
return new ForAdvice(adviceMethod, instrumentedMethod.getStackSize()
+ StackSize.of(postMethodTypes)
+ StackSize.of(initialTypes)
+ StackSize.of(preMethodTypes));
}
/**
* {@inheritDoc}
*/
public int compoundLocalVariableLength(int localVariableLength) {
return Math.max(this.localVariableLength, localVariableLength
+ StackSize.of(postMethodTypes)
+ StackSize.of(initialTypes)
+ StackSize.of(preMethodTypes));
}
}
/**
* A method size handler that expects that the original arguments were copied.
*/
protected static class WithCopiedArguments extends Default {
/**
* Creates a new default method size handler that expects the original arguments to be copied.
*
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
*/
protected WithCopiedArguments(MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes) {
super(instrumentedMethod, initialTypes, preMethodTypes, postMethodTypes);
}
/**
* {@inheritDoc}
*/
public MethodSizeHandler.ForAdvice bindExit(MethodDescription.InDefinedShape adviceMethod) {
return new ForAdvice(adviceMethod, 2 * instrumentedMethod.getStackSize()
+ StackSize.of(initialTypes)
+ StackSize.of(preMethodTypes)
+ StackSize.of(postMethodTypes));
}
/**
* {@inheritDoc}
*/
public int compoundLocalVariableLength(int localVariableLength) {
return Math.max(this.localVariableLength, localVariableLength
+ instrumentedMethod.getStackSize()
+ StackSize.of(postMethodTypes)
+ StackSize.of(initialTypes)
+ StackSize.of(preMethodTypes));
}
}
/**
* A method size handler for an advice method.
*/
protected class ForAdvice implements MethodSizeHandler.ForAdvice {
/**
* The advice method.
*/
private final MethodDescription.InDefinedShape adviceMethod;
/**
* The base of the local variable length that is implied by the method instrumentation prior to applying this advice method.
*/
private final int baseLocalVariableLength;
/**
* The additional padding to apply to the operand stack.
*/
private int stackSizePadding;
/**
* The additional padding to apply to the local variable array.
*/
private int localVariableLengthPadding;
/**
* Creates a default method size handler for an advice method.
*
* @param adviceMethod The advice method.
* @param baseLocalVariableLength The base of the local variable length that is implied by the method instrumentation
* prior to applying this advice method.
*/
protected ForAdvice(MethodDescription.InDefinedShape adviceMethod, int baseLocalVariableLength) {
this.adviceMethod = adviceMethod;
this.baseLocalVariableLength = baseLocalVariableLength;
}
/**
* {@inheritDoc}
*/
public void requireStackSize(int stackSize) {
Default.this.requireStackSize(stackSize);
}
/**
* {@inheritDoc}
*/
public void requireLocalVariableLength(int localVariableLength) {
Default.this.requireLocalVariableLength(localVariableLength);
}
/**
* {@inheritDoc}
*/
public void requireStackSizePadding(int stackSizePadding) {
this.stackSizePadding = Math.max(this.stackSizePadding, stackSizePadding);
}
/**
* {@inheritDoc}
*/
public void requireLocalVariableLengthPadding(int localVariableLengthPadding) {
this.localVariableLengthPadding = Math.max(this.localVariableLengthPadding, localVariableLengthPadding);
}
/**
* {@inheritDoc}
*/
public void recordMaxima(int stackSize, int localVariableLength) {
Default.this.requireStackSize(stackSize + stackSizePadding);
Default.this.requireLocalVariableLength(localVariableLength
- adviceMethod.getStackSize()
+ baseLocalVariableLength
+ localVariableLengthPadding);
}
}
}
}
/**
* A handler for computing and translating stack map frames.
*/
public interface StackMapFrameHandler {
/**
* Translates a frame.
*
* @param methodVisitor The method visitor to write the frame to.
* @param type The frame's type.
* @param localVariableLength The local variable length.
* @param localVariable An array containing the types of the current local variables.
* @param stackSize The size of the operand stack.
* @param stack An array containing the types of the current operand stack.
*/
void translateFrame(MethodVisitor methodVisitor,
int type,
int localVariableLength,
@MaybeNull Object[] localVariable,
int stackSize,
@MaybeNull Object[] stack);
/**
* Injects a frame indicating the beginning of a return value handler for the currently handled method.
*
* @param methodVisitor The method visitor onto which to apply the stack map frame.
*/
void injectReturnFrame(MethodVisitor methodVisitor);
/**
* Injects a frame indicating the beginning of an exception handler for the currently handled method.
*
* @param methodVisitor The method visitor onto which to apply the stack map frame.
*/
void injectExceptionFrame(MethodVisitor methodVisitor);
/**
* Injects a frame indicating the completion of the currently handled method, i.e. all yielded types were added.
*
* @param methodVisitor The method visitor onto which to apply the stack map frame.
*/
void injectCompletionFrame(MethodVisitor methodVisitor);
/**
* A stack map frame handler that can be used within a post processor. Emitting frames via this
* handler is the only legal way for a post processor to produce frames.
*/
interface ForPostProcessor {
/**
* Injects a frame that represents the current state.
*
* @param methodVisitor The method visitor onto which to apply the stack map frame.
* @param stack A list of types that are currently on the stack.
*/
void injectIntermediateFrame(MethodVisitor methodVisitor, List extends TypeDescription> stack);
}
/**
* A stack map frame handler for an instrumented method.
*/
interface ForInstrumentedMethod extends StackMapFrameHandler {
/**
* Binds this meta data handler for the enter advice.
*
* @param adviceMethod The enter advice method.
* @return An appropriate meta data handler for the enter method.
*/
ForAdvice bindEnter(MethodDescription.InDefinedShape adviceMethod);
/**
* Binds this meta data handler for the exit advice.
*
* @param adviceMethod The exit advice method.
* @return An appropriate meta data handler for the enter method.
*/
ForAdvice bindExit(MethodDescription.InDefinedShape adviceMethod);
/**
* Returns a hint to supply to a {@link ClassReader} when parsing an advice method.
*
* @return The reader hint to supply to an ASM class reader.
*/
int getReaderHint();
/**
* Injects a frame after initialization if any initialization is performed.
*
* @param methodVisitor The method visitor to write any frames to.
*/
void injectInitializationFrame(MethodVisitor methodVisitor);
/**
* Injects a frame before executing the instrumented method.
*
* @param methodVisitor The method visitor to write any frames to.
*/
void injectStartFrame(MethodVisitor methodVisitor);
/**
* Injects a frame indicating the completion of the currently handled method, i.e. all yielded types were added.
*
* @param methodVisitor The method visitor onto which to apply the stack map frame.
*/
void injectPostCompletionFrame(MethodVisitor methodVisitor);
}
/**
* A stack map frame handler for an advice method.
*/
interface ForAdvice extends StackMapFrameHandler, ForPostProcessor {
/* marker interface */
}
/**
* A non-operational stack map frame handler.
*/
enum NoOp implements ForInstrumentedMethod, ForAdvice {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public StackMapFrameHandler.ForAdvice bindEnter(MethodDescription.InDefinedShape adviceMethod) {
return this;
}
/**
* {@inheritDoc}
*/
public StackMapFrameHandler.ForAdvice bindExit(MethodDescription.InDefinedShape adviceMethod) {
return this;
}
/**
* {@inheritDoc}
*/
public int getReaderHint() {
return ClassReader.SKIP_FRAMES;
}
/**
* {@inheritDoc}
*/
public void translateFrame(MethodVisitor methodVisitor,
int type,
int localVariableLength,
@MaybeNull Object[] localVariable,
int stackSize,
@MaybeNull Object[] stack) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void injectReturnFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void injectExceptionFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void injectCompletionFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void injectInitializationFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void injectStartFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void injectPostCompletionFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void injectIntermediateFrame(MethodVisitor methodVisitor, List extends TypeDescription> stack) {
/* do nothing */
}
}
/**
* A default implementation of a stack map frame handler for an instrumented method.
*/
abstract class Default implements ForInstrumentedMethod {
/**
* An empty array indicating an empty frame.
*/
protected static final Object[] EMPTY = new Object[0];
/**
* The instrumented type.
*/
protected final TypeDescription instrumentedType;
/**
* The instrumented method.
*/
protected final MethodDescription instrumentedMethod;
/**
* A list of virtual method arguments that are explicitly added before any code execution.
*/
protected final List extends TypeDescription> initialTypes;
/**
* A list of virtual arguments that are available after the enter advice method is executed.
*/
protected final List extends TypeDescription> latentTypes;
/**
* A list of virtual method arguments that are available before the instrumented method is executed.
*/
protected final List extends TypeDescription> preMethodTypes;
/**
* A list of virtual method arguments that are available after the instrumented method has completed.
*/
protected final List extends TypeDescription> postMethodTypes;
/**
* {@code true} if the meta data handler is expected to expand its frames.
*/
protected final boolean expandFrames;
/**
* The current frame's size divergence from the original local variable array.
*/
protected int currentFrameDivergence;
/**
* Creates a new default stack map frame handler.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param latentTypes A list of virtual arguments that are available after the enter advice method is executed.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
* @param expandFrames {@code true} if the meta data handler is expected to expand its frames.
*/
protected Default(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> latentTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes,
boolean expandFrames) {
this.instrumentedType = instrumentedType;
this.instrumentedMethod = instrumentedMethod;
this.initialTypes = initialTypes;
this.latentTypes = latentTypes;
this.preMethodTypes = preMethodTypes;
this.postMethodTypes = postMethodTypes;
this.expandFrames = expandFrames;
}
/**
* Creates an appropriate stack map frame handler for an instrumented method.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param latentTypes A list of virtual arguments that are available after the enter advice method is executed.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
* @param exitAdvice {@code true} if the current advice implies exit advice.
* @param copyArguments {@code true} if the original arguments are copied before invoking the instrumented method.
* @param classFileVersion The instrumented type's class file version.
* @param writerFlags The flags supplied to the ASM writer.
* @param readerFlags The reader flags supplied to the ASM reader.
* @return An appropriate stack map frame handler for an instrumented method.
*/
protected static ForInstrumentedMethod of(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> latentTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes,
boolean exitAdvice,
boolean copyArguments,
ClassFileVersion classFileVersion,
int writerFlags,
int readerFlags) {
if ((writerFlags & ClassWriter.COMPUTE_FRAMES) != 0 || classFileVersion.isLessThan(ClassFileVersion.JAVA_V6)) {
return NoOp.INSTANCE;
} else if (!exitAdvice && initialTypes.isEmpty()) {
return new Trivial(instrumentedType,
instrumentedMethod,
latentTypes,
(readerFlags & ClassReader.EXPAND_FRAMES) != 0);
} else if (copyArguments) {
return new WithPreservedArguments.WithArgumentCopy(instrumentedType,
instrumentedMethod,
initialTypes,
latentTypes,
preMethodTypes,
postMethodTypes,
(readerFlags & ClassReader.EXPAND_FRAMES) != 0);
} else {
return new WithPreservedArguments.WithoutArgumentCopy(instrumentedType,
instrumentedMethod,
initialTypes,
latentTypes,
preMethodTypes,
postMethodTypes,
(readerFlags & ClassReader.EXPAND_FRAMES) != 0,
!instrumentedMethod.isConstructor());
}
}
/**
* {@inheritDoc}
*/
public StackMapFrameHandler.ForAdvice bindEnter(MethodDescription.InDefinedShape adviceMethod) {
return new ForAdvice(adviceMethod, initialTypes, latentTypes, preMethodTypes, TranslationMode.ENTER, instrumentedMethod.isConstructor()
? Initialization.UNITIALIZED
: Initialization.INITIALIZED);
}
/**
* {@inheritDoc}
*/
public int getReaderHint() {
return expandFrames
? ClassReader.EXPAND_FRAMES
: AsmVisitorWrapper.NO_FLAGS;
}
/**
* Translates a frame.
*
* @param methodVisitor The method visitor to write the frame to.
* @param translationMode The translation mode to apply.
* @param methodDescription The method description for which the frame is written.
* @param additionalTypes The additional types to consider part of the instrumented method's parameters.
* @param type The frame's type.
* @param localVariableLength The local variable length.
* @param localVariable An array containing the types of the current local variables.
* @param stackSize The size of the operand stack.
* @param stack An array containing the types of the current operand stack.
*/
protected void translateFrame(MethodVisitor methodVisitor,
TranslationMode translationMode,
MethodDescription methodDescription,
List extends TypeDescription> additionalTypes,
int type,
int localVariableLength,
@MaybeNull Object[] localVariable,
int stackSize,
@MaybeNull Object[] stack) {
switch (type) {
case Opcodes.F_SAME:
case Opcodes.F_SAME1:
break;
case Opcodes.F_APPEND:
currentFrameDivergence += localVariableLength;
break;
case Opcodes.F_CHOP:
currentFrameDivergence -= localVariableLength;
if (currentFrameDivergence < 0) {
throw new IllegalStateException(methodDescription + " dropped " + Math.abs(currentFrameDivergence) + " implicit frames");
}
break;
case Opcodes.F_FULL:
case Opcodes.F_NEW:
if (methodDescription.getParameters().size() + (methodDescription.isStatic() ? 0 : 1) > localVariableLength) {
throw new IllegalStateException("Inconsistent frame length for " + methodDescription + ": " + localVariableLength);
}
int offset;
if (methodDescription.isStatic()) {
offset = 0;
} else {
if (!translationMode.isPossibleThisFrameValue(instrumentedType, instrumentedMethod, localVariable[0])) {
throw new IllegalStateException(methodDescription + " is inconsistent for 'this' reference: " + localVariable[0]);
}
offset = 1;
}
for (int index = 0; index < methodDescription.getParameters().size(); index++) {
if (!Initialization.INITIALIZED.toFrame(methodDescription.getParameters().get(index).getType().asErasure()).equals(localVariable[index + offset])) {
throw new IllegalStateException(methodDescription + " is inconsistent at " + index + ": " + localVariable[index + offset]);
}
}
Object[] translated = new Object[localVariableLength
- (methodDescription.isStatic() ? 0 : 1)
- methodDescription.getParameters().size()
+ (instrumentedMethod.isStatic() ? 0 : 1)
+ instrumentedMethod.getParameters().size()
+ additionalTypes.size()];
int index = translationMode.copy(instrumentedType, instrumentedMethod, methodDescription, localVariable, translated);
for (TypeDescription typeDescription : additionalTypes) {
translated[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
System.arraycopy(localVariable,
methodDescription.getParameters().size() + (methodDescription.isStatic() ? 0 : 1),
translated,
index,
translated.length - index);
localVariableLength = translated.length;
localVariable = translated;
currentFrameDivergence = translated.length - index;
break;
default:
throw new IllegalArgumentException("Unexpected frame type: " + type);
}
methodVisitor.visitFrame(type, localVariableLength, localVariable, stackSize, stack);
}
/**
* Injects a full stack map frame after the instrumented method has completed.
*
* @param methodVisitor The method visitor onto which to write the stack map frame.
* @param initialization The initialization to apply when resolving a reference to the instance on which a non-static method is invoked.
* @param typesInArray The types that were added to the local variable array additionally to the values of the instrumented method.
* @param typesOnStack The types currently on the operand stack.
*/
protected void injectFullFrame(MethodVisitor methodVisitor,
Initialization initialization,
List extends TypeDescription> typesInArray,
List extends TypeDescription> typesOnStack) {
Object[] localVariable = new Object[instrumentedMethod.getParameters().size()
+ (instrumentedMethod.isStatic() ? 0 : 1)
+ typesInArray.size()];
int index = 0;
if (!instrumentedMethod.isStatic()) {
localVariable[index++] = initialization.toFrame(instrumentedType);
}
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
for (TypeDescription typeDescription : typesInArray) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
index = 0;
Object[] stackType = new Object[typesOnStack.size()];
for (TypeDescription typeDescription : typesOnStack) {
stackType[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
methodVisitor.visitFrame(expandFrames ? Opcodes.F_NEW : Opcodes.F_FULL, localVariable.length, localVariable, stackType.length, stackType);
currentFrameDivergence = 0;
}
/**
* A translation mode that determines how the fixed frames of the instrumented method are written.
*/
protected enum TranslationMode {
/**
* A translation mode that simply copies the original frames which are available when translating frames of the instrumented method.
*/
COPY {
@Override
protected int copy(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
MethodDescription methodDescription,
Object[] localVariable,
Object[] translated) {
int length = instrumentedMethod.getParameters().size() + (instrumentedMethod.isStatic() ? 0 : 1);
System.arraycopy(localVariable, 0, translated, 0, length);
return length;
}
@Override
protected boolean isPossibleThisFrameValue(TypeDescription instrumentedType, MethodDescription instrumentedMethod, Object frame) {
return instrumentedMethod.isConstructor() && Opcodes.UNINITIALIZED_THIS.equals(frame) || Initialization.INITIALIZED.toFrame(instrumentedType).equals(frame);
}
},
/**
* A translation mode for the enter advice that considers that the {@code this} reference might not be initialized for a constructor.
*/
ENTER {
@Override
protected int copy(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
MethodDescription methodDescription,
Object[] localVariable,
Object[] translated) {
int index = 0;
if (!instrumentedMethod.isStatic()) {
translated[index++] = instrumentedMethod.isConstructor()
? Opcodes.UNINITIALIZED_THIS
: Initialization.INITIALIZED.toFrame(instrumentedType);
}
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
translated[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
return index;
}
@Override
protected boolean isPossibleThisFrameValue(TypeDescription instrumentedType, MethodDescription instrumentedMethod, Object frame) {
return instrumentedMethod.isConstructor()
? Opcodes.UNINITIALIZED_THIS.equals(frame)
: Initialization.INITIALIZED.toFrame(instrumentedType).equals(frame);
}
},
/**
* A translation mode for an exit advice where the {@code this} reference is always initialized.
*/
EXIT {
@Override
protected int copy(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
MethodDescription methodDescription,
Object[] localVariable,
Object[] translated) {
int index = 0;
if (!instrumentedMethod.isStatic()) {
translated[index++] = Initialization.INITIALIZED.toFrame(instrumentedType);
}
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
translated[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
return index;
}
@Override
protected boolean isPossibleThisFrameValue(TypeDescription instrumentedType, MethodDescription instrumentedMethod, Object frame) {
return Initialization.INITIALIZED.toFrame(instrumentedType).equals(frame);
}
};
/**
* Copies the fixed parameters of the instrumented method onto the operand stack.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param methodDescription The method for which a frame is created.
* @param localVariable The original local variable array.
* @param translated The array containing the translated frames.
* @return The amount of frames added to the translated frame array.
*/
protected abstract int copy(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
MethodDescription methodDescription,
Object[] localVariable,
Object[] translated);
/**
* Checks if a variable value in a stack map frame is a legal value for describing a {@code this} reference.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param frame The frame value representing the {@code this} reference.
* @return {@code true} if the value is a legal representation of the {@code this} reference.
*/
protected abstract boolean isPossibleThisFrameValue(TypeDescription instrumentedType, MethodDescription instrumentedMethod, Object frame);
}
/**
* Represents the initialization state of a stack value that can either be initialized or uninitialized.
*/
protected enum Initialization {
/**
* Represents an uninitialized frame value within a constructor before invoking the super constructor.
*/
UNITIALIZED {
/**
* {@inheritDoc}
*/
protected Object toFrame(TypeDescription typeDescription) {
if (typeDescription.isPrimitive()) {
throw new IllegalArgumentException("Cannot assume primitive uninitialized value: " + typeDescription);
}
return Opcodes.UNINITIALIZED_THIS;
}
},
/**
* Represents an initialized frame value.
*/
INITIALIZED {
/**
* {@inheritDoc}
*/
protected Object toFrame(TypeDescription typeDescription) {
if (typeDescription.represents(boolean.class)
|| typeDescription.represents(byte.class)
|| typeDescription.represents(short.class)
|| typeDescription.represents(char.class)
|| typeDescription.represents(int.class)) {
return Opcodes.INTEGER;
} else if (typeDescription.represents(long.class)) {
return Opcodes.LONG;
} else if (typeDescription.represents(float.class)) {
return Opcodes.FLOAT;
} else if (typeDescription.represents(double.class)) {
return Opcodes.DOUBLE;
} else {
return typeDescription.getInternalName();
}
}
};
/**
* Initializes a frame value to its frame type.
*
* @param typeDescription The type being resolved.
* @return The frame value.
*/
protected abstract Object toFrame(TypeDescription typeDescription);
}
/**
* A trivial stack map frame handler that applies a trivial translation for the instrumented method's stack map frames.
*/
protected static class Trivial extends Default {
/**
* Creates a new stack map frame handler that applies a trivial translation for the instrumented method's stack map frames.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param latentTypes A list of virtual arguments that are available after the enter advice method is executed.
* @param expandFrames {@code true} if the meta data handler is expected to expand its frames.
*/
protected Trivial(TypeDescription instrumentedType, MethodDescription instrumentedMethod, List extends TypeDescription> latentTypes, boolean expandFrames) {
super(instrumentedType,
instrumentedMethod,
Collections.emptyList(),
latentTypes,
Collections.emptyList(),
Collections.emptyList(),
expandFrames);
}
/**
* {@inheritDoc}
*/
public void translateFrame(MethodVisitor methodVisitor,
int type,
int localVariableLength,
@MaybeNull Object[] localVariable,
int stackSize,
@MaybeNull Object[] stack) {
methodVisitor.visitFrame(type, localVariableLength, localVariable, stackSize, stack);
}
/**
* {@inheritDoc}
*/
public StackMapFrameHandler.ForAdvice bindExit(MethodDescription.InDefinedShape adviceMethod) {
throw new IllegalStateException("Did not expect exit advice " + adviceMethod + " for " + instrumentedMethod);
}
/**
* {@inheritDoc}
*/
public void injectReturnFrame(MethodVisitor methodVisitor) {
throw new IllegalStateException("Did not expect return frame for " + instrumentedMethod);
}
/**
* {@inheritDoc}
*/
public void injectExceptionFrame(MethodVisitor methodVisitor) {
throw new IllegalStateException("Did not expect exception frame for " + instrumentedMethod);
}
/**
* {@inheritDoc}
*/
public void injectCompletionFrame(MethodVisitor methodVisitor) {
throw new IllegalStateException("Did not expect completion frame for " + instrumentedMethod);
}
/**
* {@inheritDoc}
*/
public void injectPostCompletionFrame(MethodVisitor methodVisitor) {
throw new IllegalStateException("Did not expect post completion frame for " + instrumentedMethod);
}
/**
* {@inheritDoc}
*/
public void injectInitializationFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void injectStartFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
}
/**
* A stack map frame handler that requires the original arguments of the instrumented method to be preserved in their original form.
*/
protected abstract static class WithPreservedArguments extends Default {
/**
* {@code true} if a completion frame for the method bust be a full frame to reflect an initialization change.
*/
protected boolean allowCompactCompletionFrame;
/**
* Creates a new stack map frame handler that requires the stack map frames of the original arguments to be preserved.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param latentTypes A list of virtual arguments that are available after the enter advice method is executed.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
* @param expandFrames {@code true} if the meta data handler is expected to expand its frames.
* @param allowCompactCompletionFrame {@code true} if a completion frame for the method bust be a full frame to reflect an initialization change.
*/
protected WithPreservedArguments(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> latentTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes,
boolean expandFrames,
boolean allowCompactCompletionFrame) {
super(instrumentedType, instrumentedMethod, initialTypes, latentTypes, preMethodTypes, postMethodTypes, expandFrames);
this.allowCompactCompletionFrame = allowCompactCompletionFrame;
}
@Override
@SuppressFBWarnings(value = "RC_REF_COMPARISON_BAD_PRACTICE", justification = "ASM models frames by reference identity.")
protected void translateFrame(MethodVisitor methodVisitor,
TranslationMode translationMode,
MethodDescription methodDescription,
List extends TypeDescription> additionalTypes,
int type,
int localVariableLength,
@MaybeNull Object[] localVariable,
int stackSize,
@MaybeNull Object[] stack) {
if (type == Opcodes.F_FULL && localVariableLength > 0 && localVariable[0] != Opcodes.UNINITIALIZED_THIS) {
allowCompactCompletionFrame = true;
}
super.translateFrame(methodVisitor, translationMode, methodDescription, additionalTypes, type, localVariableLength, localVariable, stackSize, stack);
}
/**
* {@inheritDoc}
*/
public StackMapFrameHandler.ForAdvice bindExit(MethodDescription.InDefinedShape adviceMethod) {
return new ForAdvice(adviceMethod,
CompoundList.of(initialTypes, preMethodTypes, postMethodTypes),
Collections.emptyList(),
Collections.emptyList(),
TranslationMode.EXIT,
Initialization.INITIALIZED);
}
/**
* {@inheritDoc}
*/
public void injectReturnFrame(MethodVisitor methodVisitor) {
if (!expandFrames && currentFrameDivergence == 0) {
if (instrumentedMethod.getReturnType().represents(void.class)) {
methodVisitor.visitFrame(Opcodes.F_SAME, EMPTY.length, EMPTY, EMPTY.length, EMPTY);
} else {
methodVisitor.visitFrame(Opcodes.F_SAME1,
EMPTY.length,
EMPTY,
1,
new Object[]{Initialization.INITIALIZED.toFrame(instrumentedMethod.getReturnType().asErasure())});
}
} else {
injectFullFrame(methodVisitor, Initialization.INITIALIZED, CompoundList.of(initialTypes, preMethodTypes),
instrumentedMethod.getReturnType().represents(void.class)
? Collections.emptyList()
: Collections.singletonList(instrumentedMethod.getReturnType().asErasure()));
}
}
/**
* {@inheritDoc}
*/
public void injectExceptionFrame(MethodVisitor methodVisitor) {
if (!expandFrames && currentFrameDivergence == 0) {
methodVisitor.visitFrame(Opcodes.F_SAME1, EMPTY.length, EMPTY, 1, new Object[]{Type.getInternalName(Throwable.class)});
} else {
injectFullFrame(methodVisitor, Initialization.INITIALIZED, CompoundList.of(initialTypes, preMethodTypes),
Collections.singletonList(TypeDescription.ForLoadedType.of(Throwable.class)));
}
}
/**
* {@inheritDoc}
*/
public void injectCompletionFrame(MethodVisitor methodVisitor) {
if (allowCompactCompletionFrame && !expandFrames && currentFrameDivergence == 0 && postMethodTypes.size() < 4) {
if (postMethodTypes.isEmpty()) {
methodVisitor.visitFrame(Opcodes.F_SAME, EMPTY.length, EMPTY, EMPTY.length, EMPTY);
} else {
Object[] local = new Object[postMethodTypes.size()];
int index = 0;
for (TypeDescription typeDescription : postMethodTypes) {
local[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
methodVisitor.visitFrame(Opcodes.F_APPEND, local.length, local, EMPTY.length, EMPTY);
}
} else {
injectFullFrame(methodVisitor, Initialization.INITIALIZED, CompoundList.of(initialTypes, preMethodTypes, postMethodTypes),
Collections.emptyList());
}
}
/**
* {@inheritDoc}
*/
public void injectPostCompletionFrame(MethodVisitor methodVisitor) {
if (!expandFrames && currentFrameDivergence == 0) {
methodVisitor.visitFrame(Opcodes.F_SAME, EMPTY.length, EMPTY, EMPTY.length, EMPTY);
} else {
injectFullFrame(methodVisitor, Initialization.INITIALIZED, CompoundList.of(initialTypes, preMethodTypes, postMethodTypes),
Collections.emptyList());
}
}
/**
* {@inheritDoc}
*/
public void injectInitializationFrame(MethodVisitor methodVisitor) {
if (!initialTypes.isEmpty()) {
if (!expandFrames && initialTypes.size() < 4) {
Object[] localVariable = new Object[initialTypes.size()];
int index = 0;
for (TypeDescription typeDescription : initialTypes) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
methodVisitor.visitFrame(Opcodes.F_APPEND, localVariable.length, localVariable, EMPTY.length, EMPTY);
} else {
Object[] localVariable = new Object[(instrumentedMethod.isStatic() ? 0 : 1)
+ instrumentedMethod.getParameters().size()
+ initialTypes.size()];
int index = 0;
if (instrumentedMethod.isConstructor()) {
localVariable[index++] = Opcodes.UNINITIALIZED_THIS;
} else if (!instrumentedMethod.isStatic()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(instrumentedType);
}
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
for (TypeDescription typeDescription : initialTypes) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
methodVisitor.visitFrame(expandFrames ? Opcodes.F_NEW : Opcodes.F_FULL, localVariable.length, localVariable, EMPTY.length, EMPTY);
}
}
}
/**
* A stack map frame handler that expects that the original argument frames remain preserved throughout the original invocation.
*/
protected static class WithoutArgumentCopy extends WithPreservedArguments {
/**
* Creates a new stack map frame handler that expects the original frames to be preserved.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param latentTypes A list of virtual arguments that are available after the enter advice method is executed.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
* @param expandFrames {@code true} if the meta data handler is expected to expand its frames.
* @param allowCompactCompletionFrame {@code true} if a completion frame for the method bust be a full frame to reflect an initialization change.
*/
protected WithoutArgumentCopy(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> latentTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes,
boolean expandFrames,
boolean allowCompactCompletionFrame) {
super(instrumentedType, instrumentedMethod, initialTypes, latentTypes, preMethodTypes, postMethodTypes, expandFrames, allowCompactCompletionFrame);
}
/**
* {@inheritDoc}
*/
public void injectStartFrame(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void translateFrame(MethodVisitor methodVisitor,
int type,
int localVariableLength,
@MaybeNull Object[] localVariable,
int stackSize,
@MaybeNull Object[] stack) {
translateFrame(methodVisitor,
TranslationMode.COPY,
instrumentedMethod,
CompoundList.of(initialTypes, preMethodTypes),
type,
localVariableLength,
localVariable,
stackSize,
stack);
}
}
/**
* A stack map frame handler that expects that an argument copy of the original method arguments was made.
*/
protected static class WithArgumentCopy extends WithPreservedArguments {
/**
* Creates a new stack map frame handler that expects an argument copy.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param initialTypes A list of virtual method arguments that are explicitly added before any code execution.
* @param latentTypes The types that are given post execution of a possible enter advice.
* @param preMethodTypes A list of virtual method arguments that are available before the instrumented method is executed.
* @param postMethodTypes A list of virtual method arguments that are available after the instrumented method has completed.
* @param expandFrames {@code true} if the meta data handler is expected to expand its frames.
*/
protected WithArgumentCopy(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
List extends TypeDescription> initialTypes,
List extends TypeDescription> latentTypes,
List extends TypeDescription> preMethodTypes,
List extends TypeDescription> postMethodTypes,
boolean expandFrames) {
super(instrumentedType, instrumentedMethod, initialTypes, latentTypes, preMethodTypes, postMethodTypes, expandFrames, true);
}
/**
* {@inheritDoc}
*/
public void injectStartFrame(MethodVisitor methodVisitor) {
if (!instrumentedMethod.isStatic() || !instrumentedMethod.getParameters().isEmpty()) {
if (!expandFrames && (instrumentedMethod.isStatic() ? 0 : 1) + instrumentedMethod.getParameters().size() < 4) {
Object[] localVariable = new Object[(instrumentedMethod.isStatic() ? 0 : 1) + instrumentedMethod.getParameters().size()];
int index = 0;
if (instrumentedMethod.isConstructor()) {
localVariable[index++] = Opcodes.UNINITIALIZED_THIS;
} else if (!instrumentedMethod.isStatic()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(instrumentedType);
}
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
methodVisitor.visitFrame(Opcodes.F_APPEND, localVariable.length, localVariable, EMPTY.length, EMPTY);
} else {
Object[] localVariable = new Object[(instrumentedMethod.isStatic() ? 0 : 2)
+ instrumentedMethod.getParameters().size() * 2
+ initialTypes.size()
+ preMethodTypes.size()];
int index = 0;
if (instrumentedMethod.isConstructor()) {
localVariable[index++] = Opcodes.UNINITIALIZED_THIS;
} else if (!instrumentedMethod.isStatic()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(instrumentedType);
}
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
for (TypeDescription typeDescription : initialTypes) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
for (TypeDescription typeDescription : preMethodTypes) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
if (instrumentedMethod.isConstructor()) {
localVariable[index++] = Opcodes.UNINITIALIZED_THIS;
} else if (!instrumentedMethod.isStatic()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(instrumentedType);
}
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
localVariable[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
methodVisitor.visitFrame(expandFrames ? Opcodes.F_NEW : Opcodes.F_FULL, localVariable.length, localVariable, EMPTY.length, EMPTY);
}
}
currentFrameDivergence = (instrumentedMethod.isStatic() ? 0 : 1) + instrumentedMethod.getParameters().size();
}
/**
* {@inheritDoc}
*/
@SuppressFBWarnings(value = "RC_REF_COMPARISON_BAD_PRACTICE", justification = "ASM models frames by reference identity.")
public void translateFrame(MethodVisitor methodVisitor,
int type,
int localVariableLength,
@MaybeNull Object[] localVariable,
int stackSize,
@MaybeNull Object[] stack) {
switch (type) {
case Opcodes.F_SAME:
case Opcodes.F_SAME1:
break;
case Opcodes.F_APPEND:
currentFrameDivergence += localVariableLength;
break;
case Opcodes.F_CHOP:
currentFrameDivergence -= localVariableLength;
break;
case Opcodes.F_FULL:
case Opcodes.F_NEW:
Object[] translated = new Object[localVariableLength
+ (instrumentedMethod.isStatic() ? 0 : 1)
+ instrumentedMethod.getParameters().size()
+ initialTypes.size()
+ preMethodTypes.size()];
int index = 0;
if (instrumentedMethod.isConstructor()) {
Initialization initialization = Initialization.INITIALIZED;
for (int variableIndex = 0; variableIndex < localVariableLength; variableIndex++) {
if (localVariable[variableIndex] == Opcodes.UNINITIALIZED_THIS) {
initialization = Initialization.UNITIALIZED;
break;
}
}
translated[index++] = initialization.toFrame(instrumentedType);
} else if (!instrumentedMethod.isStatic()) {
translated[index++] = Initialization.INITIALIZED.toFrame(instrumentedType);
}
for (TypeDescription typeDescription : instrumentedMethod.getParameters().asTypeList().asErasures()) {
translated[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
for (TypeDescription typeDescription : initialTypes) {
translated[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
for (TypeDescription typeDescription : preMethodTypes) {
translated[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
if (localVariableLength > 0) {
System.arraycopy(localVariable, 0, translated, index, localVariableLength);
}
localVariableLength = translated.length;
localVariable = translated;
currentFrameDivergence = localVariableLength;
break;
default:
throw new IllegalArgumentException("Unexpected frame type: " + type);
}
methodVisitor.visitFrame(type, localVariableLength, localVariable, stackSize, stack);
}
}
}
/**
* A stack map frame handler for an advice method.
*/
protected class ForAdvice implements StackMapFrameHandler.ForAdvice {
/**
* The method description for which frames are translated.
*/
protected final MethodDescription.InDefinedShape adviceMethod;
/**
* The types provided before execution of the advice code.
*/
protected final List extends TypeDescription> startTypes;
/**
* The types that are given post execution of the advice.
*/
private final List extends TypeDescription> intermediateTypes;
/**
* The types provided after execution of the advice code.
*/
protected final List extends TypeDescription> endTypes;
/**
* The translation mode to apply for this advice method. Should be either {@link TranslationMode#ENTER} or {@link TranslationMode#EXIT}.
*/
protected final TranslationMode translationMode;
/**
* The initialization to apply when resolving a reference to the instance on which a non-static method is invoked.
*/
private final Initialization initialization;
/**
* {@code true} if an intermediate frame was yielded.
*/
private boolean intermedate;
/**
* Creates a new meta data handler for an advice method.
*
* @param adviceMethod The method description for which frames are translated.
* @param startTypes The types provided before execution of the advice code.
* @param intermediateTypes The types that are given post execution of the advice.
* @param endTypes The types provided after execution of the advice code.
* @param translationMode The translation mode to apply for this advice method. Should be
* either {@link TranslationMode#ENTER} or {@link TranslationMode#EXIT}.
* @param initialization The initialization to apply when resolving a reference to the instance on which a non-static method is invoked.
*/
protected ForAdvice(MethodDescription.InDefinedShape adviceMethod,
List extends TypeDescription> startTypes,
List extends TypeDescription> intermediateTypes,
List extends TypeDescription> endTypes,
TranslationMode translationMode,
Initialization initialization) {
this.adviceMethod = adviceMethod;
this.startTypes = startTypes;
this.intermediateTypes = intermediateTypes;
this.endTypes = endTypes;
this.translationMode = translationMode;
this.initialization = initialization;
intermedate = false;
}
/**
* {@inheritDoc}
*/
public void translateFrame(MethodVisitor methodVisitor,
int type,
int localVariableLength,
@MaybeNull Object[] localVariable,
int stackSize,
@MaybeNull Object[] stack) {
Default.this.translateFrame(methodVisitor,
translationMode,
adviceMethod,
startTypes,
type,
localVariableLength,
localVariable,
stackSize,
stack);
}
/**
* {@inheritDoc}
*/
public void injectReturnFrame(MethodVisitor methodVisitor) {
if (!expandFrames && currentFrameDivergence == 0) {
if (adviceMethod.getReturnType().represents(void.class)) {
methodVisitor.visitFrame(Opcodes.F_SAME, EMPTY.length, EMPTY, EMPTY.length, EMPTY);
} else {
methodVisitor.visitFrame(Opcodes.F_SAME1,
EMPTY.length,
EMPTY,
1,
new Object[]{Initialization.INITIALIZED.toFrame(adviceMethod.getReturnType().asErasure())});
}
} else {
injectFullFrame(methodVisitor, initialization, startTypes, adviceMethod.getReturnType().represents(void.class)
? Collections.emptyList()
: Collections.singletonList(adviceMethod.getReturnType().asErasure()));
}
}
/**
* {@inheritDoc}
*/
public void injectExceptionFrame(MethodVisitor methodVisitor) {
if (!expandFrames && currentFrameDivergence == 0) {
methodVisitor.visitFrame(Opcodes.F_SAME1, EMPTY.length, EMPTY, 1, new Object[]{Type.getInternalName(Throwable.class)});
} else {
injectFullFrame(methodVisitor, initialization, startTypes, Collections.singletonList(TypeDescription.ForLoadedType.of(Throwable.class)));
}
}
/**
* {@inheritDoc}
*/
public void injectCompletionFrame(MethodVisitor methodVisitor) {
if (expandFrames) {
injectFullFrame(methodVisitor, initialization, CompoundList.of(startTypes, endTypes), Collections.emptyList());
} else if (currentFrameDivergence == 0 && (intermedate || endTypes.size() < 4)) {
if (intermedate || endTypes.isEmpty()) {
methodVisitor.visitFrame(Opcodes.F_SAME, EMPTY.length, EMPTY, EMPTY.length, EMPTY);
} else {
Object[] local = new Object[endTypes.size()];
int index = 0;
for (TypeDescription typeDescription : endTypes) {
local[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
methodVisitor.visitFrame(Opcodes.F_APPEND, local.length, local, EMPTY.length, EMPTY);
}
} else if (currentFrameDivergence < 3 && endTypes.isEmpty()) {
methodVisitor.visitFrame(Opcodes.F_CHOP, currentFrameDivergence, EMPTY, EMPTY.length, EMPTY);
currentFrameDivergence = 0;
} else {
injectFullFrame(methodVisitor, initialization, CompoundList.of(startTypes, endTypes), Collections.emptyList());
}
}
/**
* {@inheritDoc}
*/
public void injectIntermediateFrame(MethodVisitor methodVisitor, List extends TypeDescription> stack) {
if (expandFrames) {
injectFullFrame(methodVisitor, initialization, CompoundList.of(startTypes, intermediateTypes), stack);
} else if (intermedate && stack.size() < 2) {
if (stack.isEmpty()) {
methodVisitor.visitFrame(Opcodes.F_SAME, EMPTY.length, EMPTY, EMPTY.length, EMPTY);
} else {
methodVisitor.visitFrame(Opcodes.F_SAME1, EMPTY.length, EMPTY, 1, new Object[]{Initialization.INITIALIZED.toFrame(stack.get(0))});
}
} else if (currentFrameDivergence == 0
&& intermediateTypes.size() < 4
&& (stack.isEmpty() || stack.size() < 2 && intermediateTypes.isEmpty())) {
if (intermediateTypes.isEmpty()) {
if (stack.isEmpty()) {
methodVisitor.visitFrame(Opcodes.F_SAME, EMPTY.length, EMPTY, EMPTY.length, EMPTY);
} else {
methodVisitor.visitFrame(Opcodes.F_SAME1, EMPTY.length, EMPTY, 1, new Object[]{Initialization.INITIALIZED.toFrame(stack.get(0))});
}
} else {
Object[] local = new Object[intermediateTypes.size()];
int index = 0;
for (TypeDescription typeDescription : intermediateTypes) {
local[index++] = Initialization.INITIALIZED.toFrame(typeDescription);
}
methodVisitor.visitFrame(Opcodes.F_APPEND, local.length, local, EMPTY.length, EMPTY);
}
} else if (currentFrameDivergence < 3 && intermediateTypes.isEmpty() && stack.isEmpty()) {
methodVisitor.visitFrame(Opcodes.F_CHOP, currentFrameDivergence, EMPTY, EMPTY.length, EMPTY);
} else {
injectFullFrame(methodVisitor, initialization, CompoundList.of(startTypes, intermediateTypes), stack);
}
currentFrameDivergence = intermediateTypes.size() - endTypes.size();
intermedate = true;
}
}
}
}
/**
* An exception handler is responsible for providing byte code for handling an exception thrown from a suppressing advice method.
*/
public interface ExceptionHandler {
/**
* Resolves a stack manipulation to apply.
*
* @param instrumentedMethod The instrumented method.
* @param instrumentedType The instrumented type.
* @return The stack manipulation to use.
*/
StackManipulation resolve(MethodDescription instrumentedMethod, TypeDescription instrumentedType);
/**
* Default implementations for commonly used exception handlers.
*/
enum Default implements ExceptionHandler {
/**
* An exception handler the suppresses the exception.
*/
SUPPRESSING {
/** {@inheritDoc} */
public StackManipulation resolve(MethodDescription instrumentedMethod, TypeDescription instrumentedType) {
return Removal.SINGLE;
}
},
/**
* An exception handler that invokes {@link Throwable#printStackTrace()}.
*/
PRINTING {
/** {@inheritDoc} */
public StackManipulation resolve(MethodDescription instrumentedMethod, TypeDescription instrumentedType) {
try {
return MethodInvocation.invoke(new MethodDescription.ForLoadedMethod(Throwable.class.getMethod("printStackTrace")));
} catch (NoSuchMethodException exception) {
throw new IllegalStateException("Cannot locate Throwable::printStackTrace");
}
}
},
/**
* An exception handler that rethrows any suppressed {@link Throwable}. Normally, it is preferable to avoid suppression
* altogether rather then to rethrow them. It can however be desired to make this behavior configurable where using this
* handler allows to effectively disable the suppression.
*/
RETHROWING {
/** {@inheritDoc} */
public StackManipulation resolve(MethodDescription instrumentedMethod, TypeDescription instrumentedType) {
return Throw.INSTANCE;
}
}
}
/**
* A simple exception handler that returns a fixed stack manipulation.
*/
@HashCodeAndEqualsPlugin.Enhance
class Simple implements ExceptionHandler {
/**
* The stack manipulation to execute.
*/
private final StackManipulation stackManipulation;
/**
* Creates a new simple exception handler.
*
* @param stackManipulation The stack manipulation to execute.
*/
public Simple(StackManipulation stackManipulation) {
this.stackManipulation = stackManipulation;
}
/**
* {@inheritDoc}
*/
public StackManipulation resolve(MethodDescription instrumentedMethod, TypeDescription instrumentedType) {
return stackManipulation;
}
}
}
/**
* A dispatcher for implementing advice.
*/
protected interface Dispatcher {
/**
* Indicates that a method does not represent advice and does not need to be visited.
*/
@AlwaysNull
MethodVisitor IGNORE_METHOD = null;
/**
* Expresses that an annotation should not be visited.
*/
@AlwaysNull
AnnotationVisitor IGNORE_ANNOTATION = null;
/**
* Returns {@code true} if this dispatcher is alive.
*
* @return {@code true} if this dispatcher is alive.
*/
boolean isAlive();
/**
* The type that is produced as a result of executing this advice method.
*
* @return A description of the type that is produced by this advice method.
*/
TypeDefinition getAdviceType();
/**
* A dispatcher that is not yet resolved.
*/
interface Unresolved extends Dispatcher {
/**
* Indicates that this dispatcher requires access to the class file declaring the advice method.
*
* @return {@code true} if this dispatcher requires access to the advice method's class file.
*/
boolean isBinary();
/**
* Returns the named types declared by this enter advice.
*
* @return The named types declared by this enter advice.
*/
Map getNamedTypes();
/**
* Resolves this dispatcher as a dispatcher for entering a method.
*
* @param userFactories A list of custom factories for binding parameters of an advice method.
* @param classReader A class reader to query for a class file which might be {@code null} if this dispatcher is not binary.
* @param methodExit The unresolved dispatcher for the method exit advice.
* @param postProcessorFactory The post processor factory to use.
* @return This dispatcher as a dispatcher for entering a method.
*/
Resolved.ForMethodEnter asMethodEnter(List extends OffsetMapping.Factory>> userFactories,
@MaybeNull ClassReader classReader,
Unresolved methodExit,
PostProcessor.Factory postProcessorFactory);
/**
* Resolves this dispatcher as a dispatcher for exiting a method.
*
* @param userFactories A list of custom factories for binding parameters of an advice method.
* @param classReader A class reader to query for a class file which might be {@code null} if this dispatcher is not binary.
* @param methodEnter The unresolved dispatcher for the method enter advice.
* @param postProcessorFactory The post processor factory to use.
* @return This dispatcher as a dispatcher for exiting a method.
*/
Resolved.ForMethodExit asMethodExit(List extends OffsetMapping.Factory>> userFactories,
@MaybeNull ClassReader classReader,
Unresolved methodEnter,
PostProcessor.Factory postProcessorFactory);
}
/**
* A suppression handler for optionally suppressing exceptions.
*/
interface SuppressionHandler {
/**
* Binds the suppression handler for instrumenting a specific method.
*
* @param exceptionHandler The stack manipulation to apply within a suppression handler.
* @return A bound version of the suppression handler.
*/
Bound bind(StackManipulation exceptionHandler);
/**
* A bound version of a suppression handler that must not be reused.
*/
interface Bound {
/**
* Invoked to prepare the suppression handler, i.e. to write an exception handler entry if appropriate.
*
* @param methodVisitor The method visitor to apply the preparation to.
*/
void onPrepare(MethodVisitor methodVisitor);
/**
* Invoked at the start of a method.
*
* @param methodVisitor The method visitor of the instrumented method.
*/
void onStart(MethodVisitor methodVisitor);
/**
* Invoked at the end of a method.
*
* @param methodVisitor The method visitor of the instrumented method.
* @param implementationContext The implementation context to use.
* @param methodSizeHandler The advice method's method size handler.
* @param stackMapFrameHandler A handler for translating and injecting stack map frames.
* @param returnType The return type of the advice method.
*/
void onEnd(MethodVisitor methodVisitor,
Implementation.Context implementationContext,
MethodSizeHandler.ForAdvice methodSizeHandler,
StackMapFrameHandler.ForAdvice stackMapFrameHandler,
TypeDefinition returnType);
/**
* Invoked at the end of a method if the exception handler should be wrapped in a skipping block.
*
* @param methodVisitor The method visitor of the instrumented method.
* @param implementationContext The implementation context to use.
* @param methodSizeHandler The advice method's method size handler.
* @param stackMapFrameHandler A handler for translating and injecting stack map frames.
* @param returnType The return type of the advice method.
*/
void onEndWithSkip(MethodVisitor methodVisitor,
Implementation.Context implementationContext,
MethodSizeHandler.ForAdvice methodSizeHandler,
StackMapFrameHandler.ForAdvice stackMapFrameHandler,
TypeDefinition returnType);
}
/**
* A non-operational suppression handler that does not suppress any method.
*/
enum NoOp implements SuppressionHandler, Bound {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public Bound bind(StackManipulation exceptionHandler) {
return this;
}
/**
* {@inheritDoc}
*/
public void onPrepare(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void onStart(MethodVisitor methodVisitor) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void onEnd(MethodVisitor methodVisitor,
Implementation.Context implementationContext,
MethodSizeHandler.ForAdvice methodSizeHandler,
StackMapFrameHandler.ForAdvice stackMapFrameHandler,
TypeDefinition returnType) {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void onEndWithSkip(MethodVisitor methodVisitor,
Implementation.Context implementationContext,
MethodSizeHandler.ForAdvice methodSizeHandler,
StackMapFrameHandler.ForAdvice stackMapFrameHandler,
TypeDefinition returnType) {
/* do nothing */
}
}
/**
* A suppression handler that suppresses a given throwable type.
*/
@HashCodeAndEqualsPlugin.Enhance
class Suppressing implements SuppressionHandler {
/**
* The suppressed throwable type.
*/
private final TypeDescription suppressedType;
/**
* Creates a new suppressing suppression handler.
*
* @param suppressedType The suppressed throwable type.
*/
protected Suppressing(TypeDescription suppressedType) {
this.suppressedType = suppressedType;
}
/**
* Resolves an appropriate suppression handler.
*
* @param suppressedType The suppressed type or {@link NoExceptionHandler} if no type should be suppressed.
* @return An appropriate suppression handler.
*/
protected static SuppressionHandler of(TypeDescription suppressedType) {
return suppressedType.represents(NoExceptionHandler.class)
? NoOp.INSTANCE
: new Suppressing(suppressedType);
}
/**
* {@inheritDoc}
*/
public SuppressionHandler.Bound bind(StackManipulation exceptionHandler) {
return new Bound(suppressedType, exceptionHandler);
}
/**
* An active, bound suppression handler.
*/
protected static class Bound implements SuppressionHandler.Bound {
/**
* The suppressed throwable type.
*/
private final TypeDescription suppressedType;
/**
* The stack manipulation to apply within a suppression handler.
*/
private final StackManipulation exceptionHandler;
/**
* A label indicating the start of the method.
*/
private final Label startOfMethod;
/**
* A label indicating the end of the method.
*/
private final Label endOfMethod;
/**
* Creates a new active, bound suppression handler.
*
* @param suppressedType The suppressed throwable type.
* @param exceptionHandler The stack manipulation to apply within a suppression handler.
*/
protected Bound(TypeDescription suppressedType, StackManipulation exceptionHandler) {
this.suppressedType = suppressedType;
this.exceptionHandler = exceptionHandler;
startOfMethod = new Label();
endOfMethod = new Label();
}
/**
* {@inheritDoc}
*/
public void onPrepare(MethodVisitor methodVisitor) {
methodVisitor.visitTryCatchBlock(startOfMethod, endOfMethod, endOfMethod, suppressedType.getInternalName());
}
/**
* {@inheritDoc}
*/
public void onStart(MethodVisitor methodVisitor) {
methodVisitor.visitLabel(startOfMethod);
}
/**
* {@inheritDoc}
*/
public void onEnd(MethodVisitor methodVisitor,
Implementation.Context implementationContext,
MethodSizeHandler.ForAdvice methodSizeHandler,
StackMapFrameHandler.ForAdvice stackMapFrameHandler,
TypeDefinition returnType) {
methodVisitor.visitLabel(endOfMethod);
stackMapFrameHandler.injectExceptionFrame(methodVisitor);
methodSizeHandler.requireStackSize(1 + exceptionHandler.apply(methodVisitor, implementationContext).getMaximalSize());
if (returnType.represents(boolean.class)
|| returnType.represents(byte.class)
|| returnType.represents(short.class)
|| returnType.represents(char.class)
|| returnType.represents(int.class)) {
methodVisitor.visitInsn(Opcodes.ICONST_0);
} else if (returnType.represents(long.class)) {
methodVisitor.visitInsn(Opcodes.LCONST_0);
} else if (returnType.represents(float.class)) {
methodVisitor.visitInsn(Opcodes.FCONST_0);
} else if (returnType.represents(double.class)) {
methodVisitor.visitInsn(Opcodes.DCONST_0);
} else if (!returnType.represents(void.class)) {
methodVisitor.visitInsn(Opcodes.ACONST_NULL);
}
}
/**
* {@inheritDoc}
*/
public void onEndWithSkip(MethodVisitor methodVisitor,
Implementation.Context implementationContext,
MethodSizeHandler.ForAdvice methodSizeHandler,
StackMapFrameHandler.ForAdvice stackMapFrameHandler,
TypeDefinition returnType) {
Label skipExceptionHandler = new Label();
methodVisitor.visitJumpInsn(Opcodes.GOTO, skipExceptionHandler);
onEnd(methodVisitor, implementationContext, methodSizeHandler, stackMapFrameHandler, returnType);
methodVisitor.visitLabel(skipExceptionHandler);
stackMapFrameHandler.injectReturnFrame(methodVisitor);
}
}
}
}
/**
* A relocation handler is responsible for chaining the usual control flow of an instrumented method.
*/
interface RelocationHandler {
/**
* Binds this relocation handler to a relocation dispatcher.
*
* @param instrumentedMethod The instrumented method.
* @param relocation The relocation to apply.
* @return A bound relocation handler.
*/
Bound bind(MethodDescription instrumentedMethod, Relocation relocation);
/**
* A relocator is responsible for triggering a relocation if a relocation handler triggers a relocating condition.
*/
interface Relocation {
/**
* Applies this relocator.
*
* @param methodVisitor The method visitor to use.
*/
void apply(MethodVisitor methodVisitor);
/**
* A relocation that unconditionally jumps to a given label.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForLabel implements Relocation {
/**
* The label to jump to.
*/
private final Label label;
/**
* Creates a new relocation for an unconditional jump to a given label.
*
* @param label The label to jump to.
*/
public ForLabel(Label label) {
this.label = label;
}
/**
* {@inheritDoc}
*/
public void apply(MethodVisitor methodVisitor) {
methodVisitor.visitJumpInsn(Opcodes.GOTO, label);
}
}
}
/**
* A bound {@link RelocationHandler}.
*/
interface Bound {
/**
* Indicates that this relocation handler does not require a minimal stack size.
*/
int NO_REQUIRED_SIZE = 0;
/**
* Applies this relocation handler.
*
* @param methodVisitor The method visitor to use.
* @param implementationContext The implementation context to use.
* @param offset The offset of the relevant value.
* @return The minimal required stack size to apply this relocation handler.
*/
int apply(MethodVisitor methodVisitor, Implementation.Context implementationContext, int offset);
}
/**
* A disabled relocation handler that does never trigger a relocation.
*/
enum Disabled implements RelocationHandler, Bound {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public Bound bind(MethodDescription instrumentedMethod, Relocation relocation) {
return this;
}
/**
* {@inheritDoc}
*/
public int apply(MethodVisitor methodVisitor, Implementation.Context implementationContext, int offset) {
return NO_REQUIRED_SIZE;
}
}
/**
* A relocation handler factory that triggers a relocation for a default or non-default value.
*/
enum ForValue {
/**
* A relocation handler for an {@code int} type or any compatible type.
*/
BOOLEAN(Opcodes.ILOAD, Opcodes.BALOAD, Opcodes.IFNE, Opcodes.IFEQ, 0) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
/* do nothing */
}
},
/**
* A relocation handler for an {@code int} type or any compatible type.
*/
BYTE(Opcodes.ILOAD, Opcodes.BALOAD, Opcodes.IFNE, Opcodes.IFEQ, 0) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
/* do nothing */
}
},
/**
* A relocation handler for an {@code short} type or any compatible type.
*/
SHORT(Opcodes.ILOAD, Opcodes.SALOAD, Opcodes.IFNE, Opcodes.IFEQ, 0) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
/* do nothing */
}
},
/**
* A relocation handler for an {@code char} type or any compatible type.
*/
CHARACTER(Opcodes.ILOAD, Opcodes.CALOAD, Opcodes.IFNE, Opcodes.IFEQ, 0) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
/* do nothing */
}
},
/**
* A relocation handler for an {@code int} type or any compatible type.
*/
INTEGER(Opcodes.ILOAD, Opcodes.IALOAD, Opcodes.IFNE, Opcodes.IFEQ, 0) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
/* do nothing */
}
},
/**
* A relocation handler for a {@code long} type.
*/
LONG(Opcodes.LLOAD, Opcodes.LALOAD, Opcodes.IFNE, Opcodes.IFEQ, 0) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
methodVisitor.visitInsn(Opcodes.L2I);
}
},
/**
* A relocation handler for a {@code float} type.
*/
FLOAT(Opcodes.FLOAD, Opcodes.FALOAD, Opcodes.IFNE, Opcodes.IFEQ, 2) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
methodVisitor.visitInsn(Opcodes.FCONST_0);
methodVisitor.visitInsn(Opcodes.FCMPL);
}
},
/**
* A relocation handler for a {@code double} type.
*/
DOUBLE(Opcodes.DLOAD, Opcodes.DALOAD, Opcodes.IFNE, Opcodes.IFEQ, 4) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
methodVisitor.visitInsn(Opcodes.DCONST_0);
methodVisitor.visitInsn(Opcodes.DCMPL);
}
},
/**
* A relocation handler for a reference type.
*/
REFERENCE(Opcodes.ALOAD, Opcodes.AALOAD, Opcodes.IFNONNULL, Opcodes.IFNULL, 0) {
@Override
protected void convertValue(MethodVisitor methodVisitor) {
/* do nothing */
}
};
/**
* An opcode for loading a value of the represented type from the local variable array.
*/
private final int load;
/**
* An opcode for loading a value of the represented type from an array.
*/
private final int arrayLoad;
/**
* The opcode to check for a non-default value.
*/
private final int defaultJump;
/**
* The opcode to check for a default value.
*/
private final int nonDefaultJump;
/**
* The minimal required stack size to apply this relocation handler.
*/
private final int requiredSize;
/**
* Creates a new relocation handler for a type's default or non-default value.
*
* @param load An opcode for loading a value of the represented type from the local variable array.
* @param arrayLoad An opcode for loading a value of the represented type from an array.
* @param defaultJump The opcode to check for a non-default value.
* @param nonDefaultJump The opcode to check for a default value.
* @param requiredSize The minimal required stack size to apply this relocation handler.
*/
ForValue(int load, int arrayLoad, int defaultJump, int nonDefaultJump, int requiredSize) {
this.load = load;
this.arrayLoad = arrayLoad;
this.defaultJump = defaultJump;
this.nonDefaultJump = nonDefaultJump;
this.requiredSize = requiredSize;
}
/**
* Resolves a relocation handler for a given type.
*
* @param typeDefinition The type to be resolved for a relocation attempt.
* @param index The index in the array returned by the advice method that contains the value to be checked.
* @param inverted {@code true} if the relocation should be applied for any non-default value of a type.
* @return An appropriate relocation handler.
*/
protected static RelocationHandler of(TypeDefinition typeDefinition, int index, boolean inverted) {
ForValue skipDispatcher;
if (typeDefinition.represents(boolean.class)) {
skipDispatcher = BOOLEAN;
} else if (typeDefinition.represents(byte.class)) {
skipDispatcher = BYTE;
} else if (typeDefinition.represents(short.class)) {
skipDispatcher = SHORT;
} else if (typeDefinition.represents(char.class)) {
skipDispatcher = CHARACTER;
} else if (typeDefinition.represents(int.class)) {
skipDispatcher = INTEGER;
} else if (typeDefinition.represents(long.class)) {
skipDispatcher = LONG;
} else if (typeDefinition.represents(float.class)) {
skipDispatcher = FLOAT;
} else if (typeDefinition.represents(double.class)) {
skipDispatcher = DOUBLE;
} else if (typeDefinition.represents(void.class)) {
throw new IllegalStateException("Cannot skip on default value for void return type");
} else {
skipDispatcher = REFERENCE;
}
return inverted
? skipDispatcher.new OfNonDefault(index)
: skipDispatcher.new OfDefault(index);
}
/**
* Applies a value conversion prior to a applying a conditional jump.
*
* @param methodVisitor The method visitor to use.
*/
protected abstract void convertValue(MethodVisitor methodVisitor);
/**
* A relocation handler that checks for a value being a default value.
*/
@HashCodeAndEqualsPlugin.Enhance(includeSyntheticFields = true)
protected class OfDefault implements RelocationHandler {
/**
* The index of the array returned by the advice method that contains the value to check for its value.
*/
private final int index;
/**
* A relocation handler that checks if a value is a default value.
*
* @param index The index of the array returned by the advice method that contains the value to check for its value.
*/
public OfDefault(int index) {
this.index = index;
}
/**
* {@inheritDoc}
*/
public Bound bind(MethodDescription instrumentedMethod, Relocation relocation) {
return new ForValue.Bound(instrumentedMethod, relocation, index, false);
}
}
/**
* A relocation handler that checks for a value being a non-default value.
*/
@HashCodeAndEqualsPlugin.Enhance(includeSyntheticFields = true)
protected class OfNonDefault implements RelocationHandler {
/**
* The index of the array returned by the advice method that contains the value to check for its value.
*/
private final int index;
/**
* A relocation handler that checks if a value is a non-default value.
*
* @param index The index of the array returned by the advice method that contains the value to check for its value.
*/
protected OfNonDefault(int index) {
this.index = index;
}
/**
* {@inheritDoc}
*/
public Bound bind(MethodDescription instrumentedMethod, Relocation relocation) {
return new ForValue.Bound(instrumentedMethod, relocation, index, true);
}
}
/**
* A bound relocation handler for {@link ForValue}.
*/
@HashCodeAndEqualsPlugin.Enhance(includeSyntheticFields = true)
protected class Bound implements RelocationHandler.Bound {
/**
* The instrumented method.
*/
private final MethodDescription instrumentedMethod;
/**
* The relocation to apply.
*/
private final Relocation relocation;
/**
* The array index of the relocated value.
*/
private final int index;
/**
* {@code true} if the relocation should be applied for any non-default value of a type.
*/
private final boolean inverted;
/**
* Creates a new bound relocation handler.
*
* @param instrumentedMethod The instrumented method.
* @param relocation The relocation to apply.
* @param index The array index of the relocated value.
* @param inverted {@code true} if the relocation should be applied for any non-default value of a type.
*/
protected Bound(MethodDescription instrumentedMethod, Relocation relocation, int index, boolean inverted) {
this.instrumentedMethod = instrumentedMethod;
this.relocation = relocation;
this.index = index;
this.inverted = inverted;
}
/**
* {@inheritDoc}
*/
public int apply(MethodVisitor methodVisitor, Implementation.Context implementationContext, int offset) {
if (instrumentedMethod.isConstructor()) {
throw new IllegalStateException("Cannot skip code execution from constructor: " + instrumentedMethod);
}
Label noSkip = new Label();
int size;
if (index < 0) {
size = requiredSize;
methodVisitor.visitVarInsn(load, offset);
} else {
methodVisitor.visitVarInsn(Opcodes.ALOAD, offset);
methodVisitor.visitJumpInsn(Opcodes.IFNULL, noSkip);
methodVisitor.visitVarInsn(Opcodes.ALOAD, offset);
size = Math.max(requiredSize, IntegerConstant.forValue(index)
.apply(methodVisitor, implementationContext)
.getMaximalSize() + 1);
methodVisitor.visitInsn(arrayLoad);
}
convertValue(methodVisitor);
methodVisitor.visitJumpInsn(inverted
? nonDefaultJump
: defaultJump, noSkip);
relocation.apply(methodVisitor);
methodVisitor.visitLabel(noSkip);
return size;
}
}
}
/**
* A relocation handler that is triggered if the checked value is an instance of a given type.
*/
@HashCodeAndEqualsPlugin.Enhance
class ForType implements RelocationHandler {
/**
* The type that triggers a relocation.
*/
private final TypeDescription typeDescription;
/**
* The index of the array returned by the advice method that contains the value to check for its type.
*/
private final int index;
/**
* Creates a new relocation handler that triggers a relocation if a value is an instance of a given type.
*
* @param typeDescription The type that triggers a relocation.
* @param index The index of the array returned by the advice method that contains the value to check for its type.
*/
protected ForType(TypeDescription typeDescription, int index) {
this.typeDescription = typeDescription;
this.index = index;
}
/**
* Resolves a relocation handler that is triggered if the checked instance is of a given type.
*
* @param typeDescription The type that triggers a relocation.
* @param index The array index of the value that is returned.
* @param returnedType The type that is returned by the advice method.
* @return An appropriate relocation handler.
*/
@SuppressFBWarnings(value = "NP_NULL_ON_SOME_PATH_FROM_RETURN_VALUE", justification = "Assuming component type for array type.")
protected static RelocationHandler of(TypeDescription typeDescription, int index, TypeDefinition returnedType) {
TypeDefinition targetType;
if (index < 0) {
targetType = returnedType;
} else if (returnedType.isArray()) {
targetType = returnedType.getComponentType();
} else {
throw new IllegalStateException(returnedType + " is not an array type but an index for a relocation is defined");
}
if (typeDescription.represents(void.class)) {
return Disabled.INSTANCE;
} else if (typeDescription.represents(OnDefaultValue.class)) {
return ForValue.of(targetType, index, false);
} else if (typeDescription.represents(OnNonDefaultValue.class)) {
return ForValue.of(targetType, index, true);
} else if (typeDescription.isPrimitive() || targetType.isPrimitive()) {
throw new IllegalStateException("Cannot relocate execution by instance type for primitive type");
} else {
return new ForType(typeDescription, index);
}
}
/**
* {@inheritDoc}
*/
public RelocationHandler.Bound bind(MethodDescription instrumentedMethod, Relocation relocation) {
return new Bound(instrumentedMethod, relocation);
}
/**
* A bound relocation handler for {@link ForType}.
*/
@HashCodeAndEqualsPlugin.Enhance(includeSyntheticFields = true)
protected class Bound implements RelocationHandler.Bound {
/**
* The instrumented method.
*/
private final MethodDescription instrumentedMethod;
/**
* The relocation to use.
*/
private final Relocation relocation;
/**
* Creates a new bound relocation handler.
*
* @param instrumentedMethod The instrumented method.
* @param relocation The relocation to apply.
*/
protected Bound(MethodDescription instrumentedMethod, Relocation relocation) {
this.instrumentedMethod = instrumentedMethod;
this.relocation = relocation;
}
/**
* {@inheritDoc}
*/
public int apply(MethodVisitor methodVisitor, Implementation.Context implementationContext, int offset) {
if (instrumentedMethod.isConstructor()) {
throw new IllegalStateException("Cannot skip code execution from constructor: " + instrumentedMethod);
}
methodVisitor.visitVarInsn(Opcodes.ALOAD, offset);
Label noSkip = new Label();
int size;
if (index < 0) {
size = NO_REQUIRED_SIZE;
} else {
methodVisitor.visitJumpInsn(Opcodes.IFNULL, noSkip);
methodVisitor.visitVarInsn(Opcodes.ALOAD, offset);
size = IntegerConstant.forValue(index)
.apply(methodVisitor, implementationContext)
.getMaximalSize() + 1;
methodVisitor.visitInsn(Opcodes.AALOAD);
}
methodVisitor.visitTypeInsn(Opcodes.INSTANCEOF, typeDescription.getInternalName());
methodVisitor.visitJumpInsn(Opcodes.IFEQ, noSkip);
relocation.apply(methodVisitor);
methodVisitor.visitLabel(noSkip);
return size;
}
}
}
}
/**
* Represents a resolved dispatcher.
*/
interface Resolved extends Dispatcher {
/**
* Returns the named types defined by this advice.
*
* @return The named types defined by this advice.
*/
Map getNamedTypes();
/**
* Binds this dispatcher for resolution to a specific method.
*
* @param instrumentedType The instrumented type.
* @param instrumentedMethod The instrumented method.
* @param methodVisitor The method visitor for writing the instrumented method.
* @param implementationContext The implementation context to use.
* @param assigner The assigner to use.
* @param argumentHandler A handler for accessing values on the local variable array.
* @param methodSizeHandler A handler for computing the method size requirements.
* @param stackMapFrameHandler A handler for translating and injecting stack map frames.
* @param exceptionHandler The stack manipulation to apply within a suppression handler.
* @param relocation A relocation to use with a relocation handler.
* @return A dispatcher that is bound to the instrumented method.
*/
Bound bind(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
MethodVisitor methodVisitor,
Implementation.Context implementationContext,
Assigner assigner,
ArgumentHandler.ForInstrumentedMethod argumentHandler,
MethodSizeHandler.ForInstrumentedMethod methodSizeHandler,
StackMapFrameHandler.ForInstrumentedMethod stackMapFrameHandler,
StackManipulation exceptionHandler,
RelocationHandler.Relocation relocation);
/**
* Represents a resolved dispatcher for entering a method.
*/
interface ForMethodEnter extends Resolved {
/**
* Returns {@code true} if the first discovered line number information should be prepended to the advice code.
*
* @return {@code true} if the first discovered line number information should be prepended to the advice code.
*/
boolean isPrependLineNumber();
/**
* Returns the actual advice type, even if it is not required post advice processing.
*
* @return The actual advice type, even if it is not required post advice processing.
*/
TypeDefinition getActualAdviceType();
}
/**
* Represents a resolved dispatcher for exiting a method.
*/
interface ForMethodExit extends Resolved {
/**
* Returns the type of throwable for which this exit advice is supposed to be invoked.
*
* @return The {@link Throwable} type for which to invoke this exit advice or a description of {@link NoExceptionHandler}
* if this exit advice does not expect to be invoked upon any throwable.
*/
TypeDescription getThrowable();
/**
* Returns a factory for creating an {@link ArgumentHandler}.
*
* @return A factory for creating an {@link ArgumentHandler}.
*/
ArgumentHandler.Factory getArgumentHandlerFactory();
}
/**
* An abstract base implementation of a {@link Resolved} dispatcher.
*/
@HashCodeAndEqualsPlugin.Enhance
abstract class AbstractBase implements Resolved {
/**
* The represented advice method.
*/
protected final MethodDescription.InDefinedShape adviceMethod;
/**
* The post processor to apply.
*/
protected final PostProcessor postProcessor;
/**
* A mapping from offset to a mapping for this offset with retained iteration order of the method's parameters.
*/
protected final Map offsetMappings;
/**
* The suppression handler to use.
*/
protected final SuppressionHandler suppressionHandler;
/**
* The relocation handler to use.
*/
protected final RelocationHandler relocationHandler;
/**
* Creates a new resolved version of a dispatcher.
*
* @param adviceMethod The represented advice method.
* @param postProcessor The post processor to use.
* @param factories A list of factories to resolve for the parameters of the advice method.
* @param throwableType The type to handle by a suppression handler or {@link NoExceptionHandler} to not handle any exceptions.
* @param relocatableType The type to trigger a relocation of the method's control flow or {@code void} if no relocation should be executed.
* @param relocatableIndex The index within an array that is returned by the advice method, indicating the value to consider for relocation.
* @param adviceType The applied advice type.
*/
protected AbstractBase(MethodDescription.InDefinedShape adviceMethod,
PostProcessor postProcessor,
List extends OffsetMapping.Factory>> factories,
TypeDescription throwableType,
TypeDescription relocatableType,
int relocatableIndex,
OffsetMapping.Factory.AdviceType adviceType) {
this.adviceMethod = adviceMethod;
this.postProcessor = postProcessor;
Map> offsetMappings = new HashMap>();
for (OffsetMapping.Factory> factory : factories) {
offsetMappings.put(TypeDescription.ForLoadedType.of(factory.getAnnotationType()), factory);
}
this.offsetMappings = new LinkedHashMap();
for (ParameterDescription.InDefinedShape parameterDescription : adviceMethod.getParameters()) {
OffsetMapping offsetMapping = null;
for (AnnotationDescription annotationDescription : parameterDescription.getDeclaredAnnotations()) {
OffsetMapping.Factory> factory = offsetMappings.get(annotationDescription.getAnnotationType());
if (factory != null) {
@SuppressWarnings("unchecked")
OffsetMapping current = factory.make(parameterDescription,
(AnnotationDescription.Loadable) annotationDescription.prepare(factory.getAnnotationType()),
adviceType);
if (offsetMapping == null) {
offsetMapping = current;
} else {
throw new IllegalStateException(parameterDescription + " is bound to both " + current + " and " + offsetMapping);
}
}
}
this.offsetMappings.put(parameterDescription.getOffset(), offsetMapping == null
? new OffsetMapping.ForArgument.Unresolved(parameterDescription)
: offsetMapping);
}
suppressionHandler = SuppressionHandler.Suppressing.of(throwableType);
relocationHandler = RelocationHandler.ForType.of(relocatableType, relocatableIndex, adviceMethod.getReturnType());
}
/**
* {@inheritDoc}
*/
public boolean isAlive() {
return true;
}
}
}
/**
* A bound resolution of an advice method.
*/
interface Bound {
/**
* Prepares the advice method's exception handlers.
*/
void prepare();
/**
* Initialized the advice's methods local variables.
*/
void initialize();
/**
* Applies this dispatcher.
*/
void apply();
}
/**
* An implementation for inactive devise that does not write any byte code.
*/
enum Inactive implements Dispatcher.Unresolved, Resolved.ForMethodEnter, Resolved.ForMethodExit, Bound {
/**
* The singleton instance.
*/
INSTANCE;
/**
* {@inheritDoc}
*/
public boolean isAlive() {
return false;
}
/**
* {@inheritDoc}
*/
public boolean isBinary() {
return false;
}
/**
* {@inheritDoc}
*/
public TypeDescription getAdviceType() {
return TypeDescription.ForLoadedType.of(void.class);
}
/**
* {@inheritDoc}
*/
public boolean isPrependLineNumber() {
return false;
}
/**
* {@inheritDoc}
*/
public TypeDefinition getActualAdviceType() {
return TypeDescription.ForLoadedType.of(void.class);
}
/**
* {@inheritDoc}
*/
public Map getNamedTypes() {
return Collections.emptyMap();
}
/**
* {@inheritDoc}
*/
public TypeDescription getThrowable() {
return NoExceptionHandler.DESCRIPTION;
}
/**
* {@inheritDoc}
*/
public ArgumentHandler.Factory getArgumentHandlerFactory() {
return ArgumentHandler.Factory.SIMPLE;
}
/**
* {@inheritDoc}
*/
public Resolved.ForMethodEnter asMethodEnter(List extends OffsetMapping.Factory>> userFactories,
@MaybeNull ClassReader classReader,
Unresolved methodExit,
PostProcessor.Factory postProcessorFactory) {
return this;
}
/**
* {@inheritDoc}
*/
public Resolved.ForMethodExit asMethodExit(List extends OffsetMapping.Factory>> userFactories,
@MaybeNull ClassReader classReader,
Unresolved methodEnter,
PostProcessor.Factory postProcessorFactory) {
return this;
}
/**
* {@inheritDoc}
*/
public void prepare() {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void initialize() {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public void apply() {
/* do nothing */
}
/**
* {@inheritDoc}
*/
public Bound bind(TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
MethodVisitor methodVisitor,
Implementation.Context implementationContext,
Assigner assigner,
ArgumentHandler.ForInstrumentedMethod argumentHandler,
MethodSizeHandler.ForInstrumentedMethod methodSizeHandler,
StackMapFrameHandler.ForInstrumentedMethod stackMapFrameHandler,
StackManipulation exceptionHandler,
RelocationHandler.Relocation relocation) {
return this;
}
}
/**
* A dispatcher for an advice method that is being inlined into the instrumented method.
*/
@HashCodeAndEqualsPlugin.Enhance
class Inlining implements Unresolved {
/**
* The advice method.
*/
protected final MethodDescription.InDefinedShape adviceMethod;
/**
* A mapping of all available local variables by their name to their type.
*/
private final Map namedTypes;
/**
* Creates a dispatcher for inlined advice method.
*
* @param adviceMethod The advice method.
*/
protected Inlining(MethodDescription.InDefinedShape adviceMethod) {
this.adviceMethod = adviceMethod;
namedTypes = new HashMap();
for (ParameterDescription parameterDescription : adviceMethod.getParameters()) {
AnnotationDescription.Loadable annotationDescription = parameterDescription.getDeclaredAnnotations().ofType(Local.class);
if (annotationDescription != null) {
String name = annotationDescription.getValue(OffsetMapping.ForLocalValue.Factory.LOCAL_VALUE).resolve(String.class);
TypeDefinition previous = namedTypes.put(name, parameterDescription.getType());
if (previous != null && !previous.equals(parameterDescription.getType())) {
throw new IllegalStateException("Local variable for " + name + " is defined with inconsistent types");
}
}
}
}
/**
* {@inheritDoc}
*/
public boolean isAlive() {
return true;
}
/**
* {@inheritDoc}
*/
public boolean isBinary() {
return true;
}
/**
* {@inheritDoc}
*/
public TypeDescription getAdviceType() {
return adviceMethod.getReturnType().asErasure();
}
/**
* {@inheritDoc}
*/
public Map getNamedTypes() {
return namedTypes;
}
/**
* {@inheritDoc}
*/
public Dispatcher.Resolved.ForMethodEnter asMethodEnter(List extends OffsetMapping.Factory>> userFactories,
@MaybeNull ClassReader classReader,
Unresolved methodExit,
PostProcessor.Factory postProcessorFactory) {
if (classReader == null) {
throw new IllegalStateException("Class reader not expected null");
}
return Resolved.ForMethodEnter.of(adviceMethod,
postProcessorFactory.make(adviceMethod, false),
namedTypes,
userFactories,
methodExit.getAdviceType(),
classReader,
methodExit.isAlive());
}
/**
* {@inheritDoc}
*/
public Dispatcher.Resolved.ForMethodExit asMethodExit(List extends OffsetMapping.Factory>> userFactories,
@MaybeNull ClassReader classReader,
Unresolved methodEnter,
PostProcessor.Factory postProcessorFactory) {
Map namedTypes = new HashMap(methodEnter.getNamedTypes()), uninitializedNamedTypes = new HashMap();
for (Map.Entry entry : this.namedTypes.entrySet()) {
TypeDefinition typeDefinition = namedTypes.get(entry.getKey()), uninitializedTypeDefinition = uninitializedNamedTypes.get(entry.getKey());
if (typeDefinition == null && uninitializedTypeDefinition == null) {
namedTypes.put(entry.getKey(), entry.getValue());
uninitializedNamedTypes.put(entry.getKey(), entry.getValue());
} else if (!(typeDefinition == null ? uninitializedTypeDefinition : typeDefinition).equals(entry.getValue())) {
throw new IllegalStateException("Local variable for " + entry.getKey() + " is defined with inconsistent types");
}
}
return Resolved.ForMethodExit.of(adviceMethod, postProcessorFactory.make(adviceMethod, true), namedTypes, uninitializedNamedTypes, userFactories, classReader,
methodEnter.getAdviceType());
}
@Override
public String toString() {
return "Delegate to " + adviceMethod;
}
/**
* A resolved version of a dispatcher.
*/
protected abstract static class Resolved extends Dispatcher.Resolved.AbstractBase {
/**
* A class reader to query for the class file of the advice method.
*/
protected final ClassReader classReader;
/**
* Creates a new resolved version of a dispatcher.
*
* @param adviceMethod The represented advice method.
* @param postProcessor The post processor to apply.
* @param factories A list of factories to resolve for the parameters of the advice method.
* @param throwableType The type to handle by a suppression handler or {@link NoExceptionHandler} to not handle any exceptions.
* @param relocatableType The type to trigger a relocation of the method's control flow or {@code void} if no relocation should be executed.
* @param relocatableIndex The index within an array that is returned by the advice method, indicating the value to consider for relocation.
* @param classReader A class reader to query for the class file of the advice method.
*/
protected Resolved(MethodDescription.InDefinedShape adviceMethod,
PostProcessor postProcessor,
List extends OffsetMapping.Factory>> factories,
TypeDescription throwableType,
TypeDescription relocatableType,
int relocatableIndex,
ClassReader classReader) {
super(adviceMethod, postProcessor, factories, throwableType, relocatableType, relocatableIndex, OffsetMapping.Factory.AdviceType.INLINING);
this.classReader = classReader;
}
/**
* Resolves the initialization types of this advice method.
*
* @param argumentHandler The argument handler to use for resolving the initialization.
* @return A mapping of parameter offsets to the type to initialize.
*/
protected abstract Map resolveInitializationTypes(ArgumentHandler argumentHandler);
/**
* Applies a resolution for a given instrumented method.
*
* @param methodVisitor A method visitor for writing byte code to the instrumented method.
* @param implementationContext The implementation context to use.
* @param assigner The assigner to use.
* @param argumentHandler A handler for accessing values on the local variable array.
* @param methodSizeHandler A handler for computing the method size requirements.
* @param stackMapFrameHandler A handler for translating and injecting stack map frames.
* @param instrumentedType A description of the instrumented type.
* @param instrumentedMethod A description of the instrumented method.
* @param suppressionHandler A bound suppression handler that is used for suppressing exceptions of this advice method.
* @param relocationHandler A bound relocation handler that is responsible for considering a non-standard control flow.
* @param exceptionHandler The exception handler that is resolved for the instrumented method.
* @return A method visitor for visiting the advice method's byte code.
*/
protected abstract MethodVisitor apply(MethodVisitor methodVisitor,
Implementation.Context implementationContext,
Assigner assigner,
ArgumentHandler.ForInstrumentedMethod argumentHandler,
MethodSizeHandler.ForInstrumentedMethod methodSizeHandler,
StackMapFrameHandler.ForInstrumentedMethod stackMapFrameHandler,
TypeDescription instrumentedType,
MethodDescription instrumentedMethod,
SuppressionHandler.Bound suppressionHandler,
RelocationHandler.Bound relocationHandler,
StackManipulation exceptionHandler);
/**
* A bound advice method that copies the code by first extracting the exception table and later appending the
* code of the method without copying any meta data.
*/
protected class AdviceMethodInliner extends ClassVisitor implements Bound {
/**
* A description of the instrumented type.
*/
protected final TypeDescription instrumentedType;
/**
* The instrumented method.
*/
protected final MethodDescription instrumentedMethod;
/**
* The method visitor for writing the instrumented method.
*/
protected final MethodVisitor methodVisitor;
/**
* The implementation context to use.
*/
protected final Implementation.Context implementationContext;
/**
* The assigner to use.
*/
protected final Assigner assigner;
/**
* A handler for accessing values on the local variable array.
*/
protected final ArgumentHandler.ForInstrumentedMethod argumentHandler;
/**
* A handler for computing the method size requirements.
*/
protected final MethodSizeHandler.ForInstrumentedMethod methodSizeHandler;
/**
* A handler for translating and injecting stack map frames.
*/
protected final StackMapFrameHandler.ForInstrumentedMethod stackMapFrameHandler;
/**
* A bound suppression handler that is used for suppressing exceptions of this advice method.
*/
protected final SuppressionHandler.Bound suppressionHandler;
/**
* A bound relocation handler that is responsible for considering a non-standard control flow.
*/
protected final RelocationHandler.Bound relocationHandler;
/**
* The exception handler that is resolved for the instrumented method.
*/
protected final StackManipulation exceptionHandler;
/**
* A class reader for parsing the class file containing the represented advice method.
*/
protected final ClassReader classReader;
/**
* The labels that were found during parsing the method's exception handler in the order of their discovery.
*/
protected final List