import static org.opendaylight.mdsal.binding.dom.codec.impl.ByteBuddyUtils.putField;
import com.google.common.base.MoreObjects.ToStringHelper;
-import com.google.common.base.Supplier;
import com.google.common.collect.ImmutableMap;
import com.google.common.collect.Maps;
+import java.lang.invoke.MethodHandles;
+import java.lang.invoke.MethodHandles.Lookup;
+import java.lang.invoke.VarHandle;
import java.lang.reflect.Method;
import java.util.ArrayList;
import java.util.Arrays;
+import java.util.Comparator;
import java.util.List;
+import java.util.Map;
import java.util.Map.Entry;
import java.util.Objects;
import java.util.Optional;
-import java.util.concurrent.atomic.AtomicReferenceFieldUpdater;
import net.bytebuddy.ByteBuddy;
import net.bytebuddy.description.field.FieldDescription;
import net.bytebuddy.description.method.MethodDescription;
import net.bytebuddy.jar.asm.Label;
import net.bytebuddy.jar.asm.MethodVisitor;
import net.bytebuddy.jar.asm.Opcodes;
-import org.eclipse.jdt.annotation.NonNull;
import org.eclipse.jdt.annotation.Nullable;
+import org.opendaylight.mdsal.binding.dom.codec.impl.ClassGeneratorBridge.LocalNameProvider;
+import org.opendaylight.mdsal.binding.dom.codec.impl.ClassGeneratorBridge.NodeContextSupplierProvider;
import org.opendaylight.mdsal.binding.dom.codec.loader.CodecClassLoader;
import org.opendaylight.mdsal.binding.dom.codec.loader.CodecClassLoader.ClassGenerator;
import org.opendaylight.mdsal.binding.dom.codec.loader.CodecClassLoader.GeneratorResult;
*
* <p>
* Code generation here is probably more involved than usual mainly due to the fact we *really* want to express the
- * strong connection between a generated class and BindingCodecContext in terms of a true constant, which boils down to
- * {@code private static final NodeContextSupplier NCS}. Having such constants provides significant boost to JITs
- * ability to optimize code -- especially with inlining and constant propagation.
+ * strong connection between a generated class to the extent possible. In most cases (grouping-generated types) this
+ * involves one level of indirection, which is a safe approach. If we are dealing with a type generated outside of a
+ * grouping statement, though, we are guaranteed instantiation-invariance and hence can hard-wire to a runtime-constant
+ * {@link NodeContextSupplier} -- which provides significant boost to JITs ability to optimize code -- especially with
+ * inlining and constant propagation.
*
* <p>
* The accessor mapping performance is critical due to users typically not taking care of storing the results acquired
* we end up generating a class with the following layout:
* <pre>
* public final class Foo$$$codecImpl extends CodecDataObject implements Foo {
- * private static final AtomicRefereceFieldUpdater<Foo$$$codecImpl, Object> getBar$$$A;
- * private static final NodeContextSupplier getBar$$$C;
+ * private static final VarHandle getBar$$$V;
* private volatile Object getBar;
*
* public Foo$$$codecImpl(NormalizedNodeContainer data) {
* }
*
* public Bar getBar() {
- * return (Bar) codecMember(getBar$$$A, getBar$$$C);
+ * return (Bar) codecMember(getBar$$$V, "bar");
* }
* }
* </pre>
* single place in a maintainable form. The glue code is extremely light (~6 instructions), which is beneficial on both
* sides of invocation:
* - generated method can readily be inlined into the caller
- * - it forms a call site into which codeMember() can be inlined with both AtomicReferenceFieldUpdater and
- * NodeContextSupplier being constant
+ * - it forms a call site into which codeMember() can be inlined with VarHandle being constant
*
* <p>
- * The second point is important here, as it allows the invocation logic around AtomicRefereceFieldUpdater to completely
- * disappear, becoming synonymous with operations of a volatile field. NodeContextSupplier being constant also means
- * it will resolve to one of its two implementations, allowing NodeContextSupplier.get() to be resolved to a constant
- * (pointing to the supplier itself) or to a simple volatile read (which will be non-null after first access).
+ * The second point is important here, as it allows the invocation logic around VarHandle to completely disappear,
+ * becoming synonymous with operations on a field. Even though the field itself is declared as volatile, it is only ever
+ * accessed through helper method using VarHandles -- and those helpers are using relaxed field ordering
+ * of {@code getAcquire()}/{@code setRelease()} memory semantics.
*
* <p>
- * The sticky point here is the NodeContextSupplier, as it is a heap object which cannot normally be looked up from the
- * static context in which the static class initializer operates -- so we need perform some sort of a trick here.
+ * Furthermore there are distinct {@code codecMember} methods, each of which supports a different invocation style:
+ * <ul>
+ * <li>with {@code String}, which ends up looking up a {@link ValueNodeCodecContext}</li>
+ * <li>with {@code Class}, which ends up looking up a {@link DataContainerCodecContext}</li>
+ * <li>with {@code NodeContextSupplier}, which performs a direct load</li>
+ * </ul>
+ * The third mode of operation requires that the object being implemented is not defined in a {@code grouping}, because
+ * it welds the object to a particular namespace -- hence it trades namespace mobility for access speed.
*
* <p>
+ * The sticky point here is the NodeContextSupplier, as it is a heap object which cannot normally be looked up from the
+ * static context in which the static class initializer operates -- so we need perform some sort of a trick here.
* Eventhough ByteBuddy provides facilities for bridging references to type fields, those facilities operate on volatile
* fields -- hence they do not quite work for us.
*
* We take a different approach here, which takes advantage of the fact we are in control of both code generation (here)
* and class loading (in {@link CodecClassLoader}). The process is performed in four steps:
* <ul>
- * <li>During code generation, the context fields are pointed towards {@link CodecDataObjectBridge#resolve(String)} and
- * {@link CodecDataObjectBridge#resolveKey(String)} methods, which are public and static, hence perfectly usable
+ * <li>During code generation, the context fields are pointed towards
+ * {@link ClassGeneratorBridge#resolveNodeContextSupplier(String)} and
+ * {@link ClassGeneratorBridge#resolveKey(String)} methods, which are public and static, hence perfectly usable
* in the context of a class initializer.</li>
* <li>During class loading of generated byte code, the original instance of the generator is called to wrap the actual
* class loading operation. At this point the generator installs itself as the current generator for this thread via
- * {@link CodecDataObjectBridge#setup(CodecDataObjectGenerator)} and allows the class to be loaded.
+ * {@link ClassGeneratorBridge#setup(CodecDataObjectGenerator)} and allows the class to be loaded.
* <li>After the class has been loaded, but before the call returns, we will force the class to initialize, at which
- * point the static invocations will be redirect to {@link #resolve(String)} and {@link #resolveKey(String)}
- * methods, thus initializing the fields to the intended constants.</li>
+ * point the static invocations will be redirect to {@link #resolveNodeContextSupplier(String)} and
+ * {@link #resolveKey(String)} methods, thus initializing the fields to the intended constants.</li>
* <li>Before returning from the class loading call, the generator will detach itself via
- * {@link CodecDataObjectBridge#tearDown(CodecDataObjectGenerator)}.</li>
+ * {@link ClassGeneratorBridge#tearDown(CodecDataObjectGenerator)}.</li>
* </ul>
*
* <p>
* This strategy works due to close cooperation with the target ClassLoader, as the entire code generation and loading
* block runs with the class loading lock for this FQCN and the reference is not leaked until the process completes.
*/
-final class CodecDataObjectGenerator<T extends CodecDataObject<?>> implements ClassGenerator<T> {
+abstract class CodecDataObjectGenerator<T extends CodecDataObject<?>> implements ClassGenerator<T> {
+ // Not reusable definition: we can inline NodeContextSuppliers without a problem
+ // FIXME: 6.0.0: wire this implementation, which requires that BindingRuntimeTypes provides information about types
+ // being genenerated from within a grouping
+ private static final class Fixed<T extends CodecDataObject<?>> extends CodecDataObjectGenerator<T>
+ implements NodeContextSupplierProvider<T> {
+ private final ImmutableMap<Method, NodeContextSupplier> properties;
+
+ Fixed(final Builder<?> template, final ImmutableMap<Method, NodeContextSupplier> properties,
+ final @Nullable Method keyMethod) {
+ super(template, keyMethod);
+ this.properties = requireNonNull(properties);
+ }
+
+ @Override
+ Builder<T> generateGetters(final Builder<T> builder) {
+ Builder<T> tmp = builder;
+ for (Method method : properties.keySet()) {
+ LOG.trace("Generating for fixed method {}", method);
+ final String methodName = method.getName();
+ final TypeDescription retType = TypeDescription.ForLoadedType.of(method.getReturnType());
+ tmp = tmp.defineMethod(methodName, retType, PUB_FINAL).intercept(
+ new SupplierGetterMethodImplementation(methodName, retType));
+ }
+ return tmp;
+ }
+
+ @Override
+ ArrayList<Method> getterMethods() {
+ return new ArrayList<>(properties.keySet());
+ }
+
+ @Override
+ public NodeContextSupplier resolveNodeContextSupplier(final String methodName) {
+ final Optional<Entry<Method, NodeContextSupplier>> found = properties.entrySet().stream()
+ .filter(entry -> methodName.equals(entry.getKey().getName())).findAny();
+ verify(found.isPresent(), "Failed to find property for %s in %s", methodName, this);
+ return verifyNotNull(found.get().getValue());
+ }
+ }
+
+ // Reusable definition: we have to rely on context lookups
+ private static final class Reusable<T extends CodecDataObject<?>> extends CodecDataObjectGenerator<T>
+ implements LocalNameProvider<T> {
+ private final ImmutableMap<Method, ValueNodeCodecContext> simpleProperties;
+ private final Map<Method, Class<?>> daoProperties;
+
+ Reusable(final Builder<?> template, final ImmutableMap<Method, ValueNodeCodecContext> simpleProperties,
+ final Map<Method, Class<?>> daoProperties, final @Nullable Method keyMethod) {
+ super(template, keyMethod);
+ this.simpleProperties = requireNonNull(simpleProperties);
+ this.daoProperties = requireNonNull(daoProperties);
+ }
+
+ @Override
+ Builder<T> generateGetters(final Builder<T> builder) {
+ Builder<T> tmp = builder;
+ for (Method method : simpleProperties.keySet()) {
+ LOG.trace("Generating for simple method {}", method);
+ final String methodName = method.getName();
+ final TypeDescription retType = TypeDescription.ForLoadedType.of(method.getReturnType());
+ tmp = tmp.defineMethod(methodName, retType, PUB_FINAL).intercept(
+ new SimpleGetterMethodImplementation(methodName, retType));
+ }
+ for (Entry<Method, Class<?>> entry : daoProperties.entrySet()) {
+ final Method method = entry.getKey();
+ LOG.trace("Generating for structured method {}", method);
+ final String methodName = method.getName();
+ final TypeDescription retType = TypeDescription.ForLoadedType.of(method.getReturnType());
+ tmp = tmp.defineMethod(methodName, retType, PUB_FINAL).intercept(
+ new StructuredGetterMethodImplementation(methodName, retType, entry.getValue()));
+ }
+
+ return tmp;
+ }
+
+ @Override
+ ArrayList<Method> getterMethods() {
+ final ArrayList<Method> ret = new ArrayList<>(simpleProperties.size() + daoProperties.size());
+ ret.addAll(simpleProperties.keySet());
+ ret.addAll(daoProperties.keySet());
+ return ret;
+ }
+
+ @Override
+ public String resolveLocalName(final String methodName) {
+ final Optional<Entry<Method, ValueNodeCodecContext>> found = simpleProperties.entrySet().stream()
+ .filter(entry -> methodName.equals(entry.getKey().getName())).findAny();
+ verify(found.isPresent(), "Failed to find property for %s in %s", methodName, this);
+ return found.get().getValue().getSchema().getQName().getLocalName();
+ }
+ }
+
private static final Logger LOG = LoggerFactory.getLogger(CodecDataObjectGenerator.class);
private static final Generic BB_BOOLEAN = TypeDefinition.Sort.describe(boolean.class);
private static final Generic BB_DATAOBJECT = TypeDefinition.Sort.describe(DataObject.class);
private static final Generic BB_HELPER = TypeDefinition.Sort.describe(ToStringHelper.class);
private static final Generic BB_INT = TypeDefinition.Sort.describe(int.class);
- private static final Generic BB_IIC = TypeDefinition.Sort.describe(IdentifiableItemCodec.class);
- private static final Generic BB_NCS = TypeDefinition.Sort.describe(NodeContextSupplier.class);
-
- private static final StackManipulation BRIDGE_RESOLVE = invokeMethod(CodecDataObjectBridge.class,
- "resolve", String.class);
- private static final StackManipulation BRIDGE_RESOLVE_KEY = invokeMethod(CodecDataObjectBridge.class,
- "resolveKey", String.class);
- private static final StackManipulation CODEC_MEMBER = invokeMethod(CodecDataObject.class,
- "codecMember", AtomicReferenceFieldUpdater.class, NodeContextSupplier.class);
- private static final StackManipulation CODEC_MEMBER_KEY = invokeMethod(CodecDataObject.class,
- "codecMember", AtomicReferenceFieldUpdater.class, IdentifiableItemCodec.class);
+ private static final Comparator<Method> METHOD_BY_ALPHABET = Comparator.comparing(Method::getName);
private static final StackManipulation ARRAYS_EQUALS = invokeMethod(Arrays.class, "equals",
byte[].class, byte[].class);
ACDO = bb.subclass(AugmentableCodecDataObject.class).visit(ByteBuddyUtils.computeFrames());
}
- private final ImmutableMap<Method, NodeContextSupplier> properties;
- private final Entry<Method, IdentifiableItemCodec> keyMethod;
private final Builder<?> template;
+ private final Method keyMethod;
- private CodecDataObjectGenerator(final Builder<?> template,
- final ImmutableMap<Method, NodeContextSupplier> properties,
- final @Nullable Entry<Method, IdentifiableItemCodec> keyMethod) {
+ CodecDataObjectGenerator(final Builder<?> template, final @Nullable Method keyMethod) {
this.template = requireNonNull(template);
- this.properties = requireNonNull(properties);
this.keyMethod = keyMethod;
}
static <D extends DataObject, T extends CodecDataObject<T>> Class<T> generate(final CodecClassLoader loader,
- final Class<D> bindingInterface, final ImmutableMap<Method, NodeContextSupplier> properties,
- final Entry<Method, IdentifiableItemCodec> keyMethod) {
+ final Class<D> bindingInterface, final ImmutableMap<Method, ValueNodeCodecContext> simpleProperties,
+ final Map<Method, Class<?>> daoProperties, final Method keyMethod) {
return loader.generateClass(bindingInterface, "codecImpl",
- new CodecDataObjectGenerator<>(CDO, properties, keyMethod));
+ new Reusable<>(CDO, simpleProperties, daoProperties, keyMethod));
}
static <D extends DataObject, T extends CodecDataObject<T>> Class<T> generateAugmentable(
final CodecClassLoader loader, final Class<D> bindingInterface,
- final ImmutableMap<Method, NodeContextSupplier> properties,
- final Entry<Method, IdentifiableItemCodec> keyMethod) {
+ final ImmutableMap<Method, ValueNodeCodecContext> simpleProperties,
+ final Map<Method, Class<?>> daoProperties, final Method keyMethod) {
return loader.generateClass(bindingInterface, "codecImpl",
- new CodecDataObjectGenerator<>(ACDO, properties, keyMethod));
+ new Reusable<>(ACDO, simpleProperties, daoProperties, keyMethod));
}
@Override
- public GeneratorResult<T> generateClass(final CodecClassLoader loeader, final String fqcn,
+ public final GeneratorResult<T> generateClass(final CodecClassLoader loeader, final String fqcn,
final Class<?> bindingInterface) {
LOG.trace("Generating class {}", fqcn);
@SuppressWarnings("unchecked")
Builder<T> builder = (Builder<T>) template.name(fqcn).implement(bindingInterface);
- for (Method method : properties.keySet()) {
- LOG.trace("Generating for method {}", method);
- final String methodName = method.getName();
- final TypeDescription retType = TypeDescription.ForLoadedType.of(method.getReturnType());
- builder = builder.defineMethod(methodName, retType, PUB_FINAL)
- .intercept(new MethodImplementation(BB_NCS, BRIDGE_RESOLVE, CODEC_MEMBER, methodName, retType));
- }
+ builder = generateGetters(builder);
if (keyMethod != null) {
LOG.trace("Generating for key {}", keyMethod);
- final Method method = keyMethod.getKey();
- final String methodName = method.getName();
- final TypeDescription retType = TypeDescription.ForLoadedType.of(method.getReturnType());
- builder = builder.defineMethod(methodName, retType, PUB_FINAL)
- .intercept(new MethodImplementation(BB_IIC, BRIDGE_RESOLVE_KEY, CODEC_MEMBER_KEY, methodName,
- retType));
+ final String methodName = keyMethod.getName();
+ final TypeDescription retType = TypeDescription.ForLoadedType.of(keyMethod.getReturnType());
+ builder = builder.defineMethod(methodName, retType, PUB_FINAL).intercept(
+ new KeyMethodImplementation(methodName, retType));
}
// Index all property methods, turning them into "getFoo()" invocations, retaining order. We will be using
// those invocations in each of the three methods. Note that we do not glue the invocations to 'this', as we
// will be invoking them on 'other' in codecEquals()
- final ImmutableMap<StackManipulation, Method> methods = Maps.uniqueIndex(properties.keySet(),
+ final ArrayList<Method> properties = getterMethods();
+ // Make sure properties are alpha-sorted
+ properties.sort(METHOD_BY_ALPHABET);
+ final ImmutableMap<StackManipulation, Method> methods = Maps.uniqueIndex(properties,
ByteBuddyUtils::invokeMethod);
// Final bits:
.make());
}
- @Override
- public Class<T> customizeLoading(final @NonNull Supplier<Class<T>> loader) {
- final CodecDataObjectGenerator<?> prev = CodecDataObjectBridge.setup(this);
- try {
- final Class<T> result = loader.get();
-
- /*
- * This a bit of magic to support NodeContextSupplier constants. These constants need to be resolved while
- * we have the information needed to find them -- that information is being held in this instance and we
- * leak it to a thread-local variable held by CodecDataObjectBridge.
- *
- * By default the JVM will defer class initialization to first use, which unfortunately is too late for
- * us, and hence we need to force class to initialize.
- */
- try {
- Class.forName(result.getName(), true, result.getClassLoader());
- } catch (ClassNotFoundException e) {
- throw new LinkageError("Failed to find newly-defined " + result, e);
- }
+ abstract Builder<T> generateGetters(Builder<T> builder);
- return result;
- } finally {
- CodecDataObjectBridge.tearDown(prev);
- }
- }
-
- @NonNull NodeContextSupplier resolve(final @NonNull String methodName) {
- final Optional<Entry<Method, NodeContextSupplier>> found = properties.entrySet().stream()
- .filter(entry -> methodName.equals(entry.getKey().getName())).findAny();
- verify(found.isPresent(), "Failed to find property for %s in %s", methodName, this);
- return verifyNotNull(found.get().getValue());
- }
-
- @NonNull IdentifiableItemCodec resolveKey(final @NonNull String methodName) {
- return verifyNotNull(verifyNotNull(keyMethod, "No key method attached for %s in %s", methodName, this)
- .getValue());
- }
+ abstract ArrayList<Method> getterMethods();
private static Implementation codecEquals(final ImmutableMap<StackManipulation, Method> properties) {
// Label for 'return false;'
return new Implementation.Simple(manipulations.toArray(new StackManipulation[0]));
}
- private static final class MethodImplementation implements Implementation {
- private static final Generic BB_ARFU = TypeDefinition.Sort.describe(AtomicReferenceFieldUpdater.class);
+ private abstract static class AbstractMethodImplementation implements Implementation {
+ private static final Generic BB_HANDLE = TypeDefinition.Sort.describe(VarHandle.class);
private static final Generic BB_OBJECT = TypeDefinition.Sort.describe(Object.class);
private static final StackManipulation OBJECT_CLASS = ClassConstant.of(TypeDescription.OBJECT);
- private static final StackManipulation ARFU_NEWUPDATER = invokeMethod(AtomicReferenceFieldUpdater.class,
- "newUpdater", Class.class, Class.class, String.class);
+ private static final StackManipulation LOOKUP = invokeMethod(MethodHandles.class, "lookup");
+ private static final StackManipulation FIND_VAR_HANDLE = invokeMethod(Lookup.class,
+ "findVarHandle", Class.class, String.class, Class.class);
- private static final int PRIV_CONST = Opcodes.ACC_PRIVATE | Opcodes.ACC_STATIC | Opcodes.ACC_FINAL
+ static final int PRIV_CONST = Opcodes.ACC_PRIVATE | Opcodes.ACC_STATIC | Opcodes.ACC_FINAL
| Opcodes.ACC_SYNTHETIC;
private static final int PRIV_VOLATILE = Opcodes.ACC_PRIVATE | Opcodes.ACC_VOLATILE | Opcodes.ACC_SYNTHETIC;
- private final Generic contextType;
- private final StackManipulation resolveMethod;
- private final StackManipulation codecMember;
- private final TypeDescription retType;
-
+ final TypeDescription retType;
// getFoo
- private final String methodName;
- // getFoo$$$A
- private final String arfuName;
- // getFoo$$$C
- private final String contextName;
+ final String methodName;
+ // getFoo$$$V
+ final String handleName;
- MethodImplementation(final Generic contextType, final StackManipulation resolveMethod,
- final StackManipulation codecMember, final String methodName, final TypeDescription retType) {
- this.contextType = requireNonNull(contextType);
- this.resolveMethod = requireNonNull(resolveMethod);
- this.codecMember = requireNonNull(codecMember);
+ AbstractMethodImplementation(final String methodName, final TypeDescription retType) {
this.methodName = requireNonNull(methodName);
this.retType = requireNonNull(retType);
- this.arfuName = methodName + "$$$A";
- this.contextName = methodName + "$$$C";
+ this.handleName = methodName + "$$$V";
}
@Override
public InstrumentedType prepare(final InstrumentedType instrumentedType) {
final InstrumentedType tmp = instrumentedType
- // private static final AtomicReferenceFieldUpdater<This, Object> getFoo$$$A;
- .withField(new FieldDescription.Token(arfuName, PRIV_CONST, BB_ARFU))
- // private static final <CONTEXT_TYPE> getFoo$$$C;
- .withField(new FieldDescription.Token(contextName, PRIV_CONST, contextType))
+ // private static final VarHandle getFoo$$$V;
+ .withField(new FieldDescription.Token(handleName, PRIV_CONST, BB_HANDLE))
// private volatile Object getFoo;
.withField(new FieldDescription.Token(methodName, PRIV_VOLATILE, BB_OBJECT));
- // "getFoo"
- final TextConstant methodNameText = new TextConstant(methodName);
-
- return tmp
- .withInitializer(new ByteCodeAppender.Simple(
- // getFoo$$$A = AtomicReferenceFieldUpdater.newUpdater(This.class, Object.class, "getFoo");
- ClassConstant.of(tmp),
- OBJECT_CLASS,
- methodNameText,
- ARFU_NEWUPDATER,
- putField(tmp, arfuName),
- // getFoo$$$C = CodecDataObjectBridge.<RESOLVE_METHOD>("getFoo");
- methodNameText,
- resolveMethod,
- putField(tmp, contextName)));
+ return tmp.withInitializer(new ByteCodeAppender.Simple(
+ // TODO: acquiring lookup is expensive, we should share it across all initialization
+ // getFoo$$$V = MethodHandles.lookup().findVarHandle(This.class, "getFoo", Object.class);
+ LOOKUP,
+ ClassConstant.of(tmp),
+ new TextConstant(methodName),
+ OBJECT_CLASS,
+ FIND_VAR_HANDLE,
+ putField(tmp, handleName)));
+ }
+ }
+
+ private static final class KeyMethodImplementation extends AbstractMethodImplementation {
+ private static final StackManipulation CODEC_KEY = invokeMethod(CodecDataObject.class,
+ "codecKey", VarHandle.class);
+
+ KeyMethodImplementation(final String methodName, final TypeDescription retType) {
+ super(methodName, retType);
+ }
+
+ @Override
+ public ByteCodeAppender appender(final Target implementationTarget) {
+ final TypeDescription instrumentedType = implementationTarget.getInstrumentedType();
+ return new ByteCodeAppender.Simple(
+ // return (FooType) codecKey(getFoo$$$V);
+ THIS,
+ getField(instrumentedType, handleName),
+ CODEC_KEY,
+ TypeCasting.to(retType),
+ MethodReturn.REFERENCE);
+ }
+ }
+
+ /*
+ * A simple leaf method, which looks up child by a String constant. This is slightly more complicated because we
+ * want to make sure we are using the same String instance as the one stored in associated DataObjectCodecContext,
+ * so that during lookup we perform an identity check instead of comparing content -- speeding things up as well
+ * as minimizing footprint. Since that string is not guaranteed to be interned in the String Pool, we cannot rely
+ * on the constant pool entry to resolve to the same object.
+ */
+ private static final class SimpleGetterMethodImplementation extends AbstractMethodImplementation {
+ private static final StackManipulation CODEC_MEMBER = invokeMethod(CodecDataObject.class,
+ "codecMember", VarHandle.class, String.class);
+ private static final StackManipulation BRIDGE_RESOLVE = invokeMethod(ClassGeneratorBridge.class,
+ "resolveLocalName", String.class);
+ private static final Generic BB_STRING = TypeDefinition.Sort.describe(String.class);
+
+ // getFoo$$$S
+ private final String stringName;
+
+ SimpleGetterMethodImplementation(final String methodName, final TypeDescription retType) {
+ super(methodName, retType);
+ this.stringName = methodName + "$$$S";
+ }
+
+ @Override
+ public InstrumentedType prepare(final InstrumentedType instrumentedType) {
+ final InstrumentedType tmp = super.prepare(instrumentedType)
+ // private static final String getFoo$$$S;
+ .withField(new FieldDescription.Token(stringName, PRIV_CONST, BB_STRING));
+
+ return tmp.withInitializer(new ByteCodeAppender.Simple(
+ // getFoo$$$S = CodecDataObjectBridge.resolveString("getFoo");
+ new TextConstant(methodName),
+ BRIDGE_RESOLVE,
+ putField(tmp, stringName)));
+ }
+
+ @Override
+ public ByteCodeAppender appender(final Target implementationTarget) {
+ final TypeDescription instrumentedType = implementationTarget.getInstrumentedType();
+ return new ByteCodeAppender.Simple(
+ // return (FooType) codecMember(getFoo$$$V, getFoo$$$S);
+ THIS,
+ getField(instrumentedType, handleName),
+ getField(instrumentedType, stringName),
+ CODEC_MEMBER,
+ TypeCasting.to(retType),
+ MethodReturn.REFERENCE);
+ }
+ }
+
+ private static final class StructuredGetterMethodImplementation extends AbstractMethodImplementation {
+ private static final StackManipulation CODEC_MEMBER = invokeMethod(CodecDataObject.class,
+ "codecMember", VarHandle.class, Class.class);
+
+ private final Class<?> bindingClass;
+
+ StructuredGetterMethodImplementation(final String methodName, final TypeDescription retType,
+ final Class<?> bindingClass) {
+ super(methodName, retType);
+ this.bindingClass = requireNonNull(bindingClass);
+ }
+
+ @Override
+ public ByteCodeAppender appender(final Target implementationTarget) {
+ final TypeDescription instrumentedType = implementationTarget.getInstrumentedType();
+ return new ByteCodeAppender.Simple(
+ // return (FooType) codecMember(getFoo$$$V, FooType.class);
+ THIS,
+ getField(instrumentedType, handleName),
+ ClassConstant.of(TypeDefinition.Sort.describe(bindingClass).asErasure()),
+ CODEC_MEMBER,
+ TypeCasting.to(retType),
+ MethodReturn.REFERENCE);
+ }
+ }
+
+ private static final class SupplierGetterMethodImplementation extends AbstractMethodImplementation {
+ private static final StackManipulation CODEC_MEMBER = invokeMethod(CodecDataObject.class,
+ "codecMember", VarHandle.class, NodeContextSupplier.class);
+ private static final StackManipulation BRIDGE_RESOLVE = invokeMethod(ClassGeneratorBridge.class,
+ "resolveNodeContextSupplier", String.class);
+ private static final Generic BB_NCS = TypeDefinition.Sort.describe(NodeContextSupplier.class);
+
+ // getFoo$$$C
+ private final String contextName;
+
+ SupplierGetterMethodImplementation(final String methodName, final TypeDescription retType) {
+ super(methodName, retType);
+ contextName = methodName + "$$$C";
+ }
+
+ @Override
+ public InstrumentedType prepare(final InstrumentedType instrumentedType) {
+ final InstrumentedType tmp = super.prepare(instrumentedType)
+ // private static final NodeContextSupplier getFoo$$$C;
+ .withField(new FieldDescription.Token(contextName, PRIV_CONST, BB_NCS));
+
+ return tmp.withInitializer(new ByteCodeAppender.Simple(
+ // getFoo$$$C = CodecDataObjectBridge.resolve("getFoo");
+ new TextConstant(methodName),
+ BRIDGE_RESOLVE,
+ putField(tmp, contextName)));
}
@Override
public ByteCodeAppender appender(final Target implementationTarget) {
final TypeDescription instrumentedType = implementationTarget.getInstrumentedType();
return new ByteCodeAppender.Simple(
- // return (FooType) codecMember(getFoo$$$A, getFoo$$$C);
+ // return (FooType) codecMember(getFoo$$$V, getFoo$$$C);
THIS,
- getField(instrumentedType, arfuName),
+ getField(instrumentedType, handleName),
getField(instrumentedType, contextName),
- codecMember,
+ CODEC_MEMBER,
TypeCasting.to(retType),
MethodReturn.REFERENCE);
}