Java Code Examples for jdk.internal.dynalink.linker.LinkerServices#asType()

private static MethodHandle createConvertingInvocation(final MethodHandle sizedMethod,
        final LinkerServices linkerServices, final MethodType callSiteType) {
    return linkerServices.asType(sizedMethod, callSiteType);
}
 

private GuardedInvocationComponent getPropertySetter(final CallSiteDescriptor callSiteDescriptor,
        final LinkerServices linkerServices, final List<String> operations) throws Exception {
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Must have three arguments: target object, property name, and property value.
            assertParameterCount(callSiteDescriptor, 3);

            // We want setters that conform to "Object(O, V)". Note, we aren't doing "R(O, V)" as it might not be
            // valid for us to convert return values proactively. Also, since we don't know what setters will be
            // invoked, we'll conservatively presume Object return type. The one exception is void return.
            final MethodType origType = callSiteDescriptor.getMethodType();
            final MethodType type = origType.returnType() == void.class ? origType : origType.changeReturnType(Object.class);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke, null|nextComponent.invocation),
            //     get_setter_handle(type, linkerServices))
            // only with a bunch of method signature adjustments. Basically, retrieve method setter
            // MethodHandle; if it is non-null, invoke it, otherwise either return null, or delegate to next
            // component's invocation.

            // Call site type is "ret_type(object_type,property_name_type,property_value_type)", which we'll
            // abbreviate to R(O, N, V) going forward, although we don't really use R here (see above about using
            // Object return type).
            final MethodType setterType = type.dropParameterTypes(1, 2);
            // Bind property setter handle to the expected setter type and linker services. Type is
            // MethodHandle(Object, String, Object)
            final MethodHandle boundGetter = MethodHandles.insertArguments(getPropertySetterHandle, 0,
                    callSiteDescriptor.changeMethodType(setterType), linkerServices);

            // Cast getter to MethodHandle(O, N, V)
            final MethodHandle typedGetter = linkerServices.asType(boundGetter, type.changeReturnType(
                    MethodHandle.class));

            // Handle to invoke the setter R(MethodHandle, O, V)
            final MethodHandle invokeHandle = MethodHandles.exactInvoker(setterType);
            // Handle to invoke the setter, dropping unnecessary fold arguments R(MethodHandle, O, N, V)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandle, 2, type.parameterType(
                    1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, operations);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(MethodHandle)->Object(MethodHandle, O, N, V); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_METHOD_HANDLE, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, MethodHandle.class));
            } else {
                // Object(O, N, V)->Object(MethodHandle, O, N, V); adapts the next component's invocation to drop the
                // extra argument resulting from fold
                fallbackFolded = MethodHandles.dropArguments(nextComponent.getGuardedInvocation().getInvocation(),
                        0, MethodHandle.class);
            }

            // fold(R(MethodHandle, O, N, V), MethodHandle(O, N, V))
            final MethodHandle compositeSetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_METHOD_HANDLE_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeSetter, type);
            }
            return nextComponent.compose(compositeSetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have two arguments: target object and property value
            assertParameterCount(callSiteDescriptor, 2);
            final GuardedInvocation gi = createGuardedDynamicMethodInvocation(callSiteDescriptor, linkerServices,
                    callSiteDescriptor.getNameToken(CallSiteDescriptor.NAME_OPERAND), propertySetters);
            // If we have a property setter with this name, this composite operation will always stop here
            if(gi != null) {
                return new GuardedInvocationComponent(gi, clazz, ValidationType.EXACT_CLASS);
            }
            // If we don't have a property setter with this name, always fall back to the next operation in the
            // composite (if any)
            return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, operations);
        }
        default: {
            // More than two name components; don't know what to do with it.
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertySetter(CallSiteDescriptor callSiteDescriptor,
        LinkerServices linkerServices, List<String> operations) throws Exception {
    final MethodType type = callSiteDescriptor.getMethodType();
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Must have three arguments: target object, property name, and property value.
            assertParameterCount(callSiteDescriptor, 3);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke, null|nextComponent.invocation),
            //     get_setter_handle(type, linkerServices))
            // only with a bunch of method signature adjustments. Basically, retrieve method setter
            // MethodHandle; if it is non-null, invoke it, otherwise either return null, or delegate to next
            // component's invocation.

            // Call site type is "ret_type(object_type,property_name_type,property_value_type)", which we'll
            // abbreviate to R(O, N, V) going forward.
            // We want setters that conform to "R(O, V)"
            final MethodType setterType = type.dropParameterTypes(1, 2);
            // Bind property setter handle to the expected setter type and linker services. Type is
            // MethodHandle(Object, String, Object)
            final MethodHandle boundGetter = MethodHandles.insertArguments(getPropertySetterHandle, 0,
                    CallSiteDescriptorFactory.dropParameterTypes(callSiteDescriptor, 1, 2), linkerServices);

            // Cast getter to MethodHandle(O, N, V)
            final MethodHandle typedGetter = linkerServices.asType(boundGetter, type.changeReturnType(
                    MethodHandle.class));

            // Handle to invoke the setter R(MethodHandle, O, V)
            final MethodHandle invokeHandle = MethodHandles.exactInvoker(setterType);
            // Handle to invoke the setter, dropping unnecessary fold arguments R(MethodHandle, O, N, V)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandle, 2, type.parameterType(
                    1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, operations);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(MethodHandle)->R(MethodHandle, O, N, V); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_METHOD_HANDLE, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, MethodHandle.class));
            } else {
                // R(O, N, V)->R(MethodHandle, O, N, V); adapts the next component's invocation to drop the
                // extra argument resulting from fold
                fallbackFolded = MethodHandles.dropArguments(nextComponent.getGuardedInvocation().getInvocation(),
                        0, MethodHandle.class);
            }

            // fold(R(MethodHandle, O, N, V), MethodHandle(O, N, V))
            final MethodHandle compositeSetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_METHOD_HANDLE_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeSetter, type);
            }
            return nextComponent.compose(compositeSetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have two arguments: target object and property value
            assertParameterCount(callSiteDescriptor, 2);
            final GuardedInvocation gi = createGuardedDynamicMethodInvocation(callSiteDescriptor, linkerServices,
                    callSiteDescriptor.getNameToken(CallSiteDescriptor.NAME_OPERAND), propertySetters);
            // If we have a property setter with this name, this composite operation will always stop here
            if(gi != null) {
                return new GuardedInvocationComponent(gi, clazz, ValidationType.EXACT_CLASS);
            }
            // If we don't have a property setter with this name, always fall back to the next operation in the
            // composite (if any)
            return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, operations);
        }
        default: {
            // More than two name components; don't know what to do with it.
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertySetter(CallSiteDescriptor callSiteDescriptor,
        LinkerServices linkerServices, List<String> operations) throws Exception {
    final MethodType type = callSiteDescriptor.getMethodType();
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Must have three arguments: target object, property name, and property value.
            assertParameterCount(callSiteDescriptor, 3);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke, null|nextComponent.invocation),
            //     get_setter_handle(type, linkerServices))
            // only with a bunch of method signature adjustments. Basically, retrieve method setter
            // MethodHandle; if it is non-null, invoke it, otherwise either return null, or delegate to next
            // component's invocation.

            // Call site type is "ret_type(object_type,property_name_type,property_value_type)", which we'll
            // abbreviate to R(O, N, V) going forward.
            // We want setters that conform to "R(O, V)"
            final MethodType setterType = type.dropParameterTypes(1, 2);
            // Bind property setter handle to the expected setter type and linker services. Type is
            // MethodHandle(Object, String, Object)
            final MethodHandle boundGetter = MethodHandles.insertArguments(getPropertySetterHandle, 0,
                    CallSiteDescriptorFactory.dropParameterTypes(callSiteDescriptor, 1, 2), linkerServices);

            // Cast getter to MethodHandle(O, N, V)
            final MethodHandle typedGetter = linkerServices.asType(boundGetter, type.changeReturnType(
                    MethodHandle.class));

            // Handle to invoke the setter R(MethodHandle, O, V)
            final MethodHandle invokeHandle = MethodHandles.exactInvoker(setterType);
            // Handle to invoke the setter, dropping unnecessary fold arguments R(MethodHandle, O, N, V)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandle, 2, type.parameterType(
                    1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, operations);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(MethodHandle)->R(MethodHandle, O, N, V); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_METHOD_HANDLE, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, MethodHandle.class));
            } else {
                // R(O, N, V)->R(MethodHandle, O, N, V); adapts the next component's invocation to drop the
                // extra argument resulting from fold
                fallbackFolded = MethodHandles.dropArguments(nextComponent.getGuardedInvocation().getInvocation(),
                        0, MethodHandle.class);
            }

            // fold(R(MethodHandle, O, N, V), MethodHandle(O, N, V))
            final MethodHandle compositeSetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_METHOD_HANDLE_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeSetter, type);
            }
            return nextComponent.compose(compositeSetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have two arguments: target object and property value
            assertParameterCount(callSiteDescriptor, 2);
            final GuardedInvocation gi = createGuardedDynamicMethodInvocation(callSiteDescriptor, linkerServices,
                    callSiteDescriptor.getNameToken(CallSiteDescriptor.NAME_OPERAND), propertySetters);
            // If we have a property setter with this name, this composite operation will always stop here
            if(gi != null) {
                return new GuardedInvocationComponent(gi, clazz, ValidationType.EXACT_CLASS);
            }
            // If we don't have a property setter with this name, always fall back to the next operation in the
            // composite (if any)
            return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, operations);
        }
        default: {
            // More than two name components; don't know what to do with it.
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertyGetter(CallSiteDescriptor callSiteDescriptor,
        LinkerServices linkerServices, List<String> ops) throws Exception {
    final MethodType type = callSiteDescriptor.getMethodType();
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Must have exactly two arguments: receiver and name
            assertParameterCount(callSiteDescriptor, 2);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke(get_handle), null|nextComponent.invocation), get_getter_handle)
            // only with a bunch of method signature adjustments. Basically, retrieve method getter
            // AnnotatedDynamicMethod; if it is non-null, invoke its "handle" field, otherwise either return null,
            // or delegate to next component's invocation.

            final MethodHandle typedGetter = linkerServices.asType(getPropertyGetterHandle, type.changeReturnType(
                    AnnotatedDynamicMethod.class));
            final MethodHandle callSiteBoundMethodGetter = MethodHandles.insertArguments(
                    GET_ANNOTATED_METHOD, 1, callSiteDescriptor.getLookup());
            final MethodHandle callSiteBoundInvoker = MethodHandles.filterArguments(GETTER_INVOKER, 0,
                    callSiteBoundMethodGetter);
            // Object(AnnotatedDynamicMethod, Object)->R(AnnotatedDynamicMethod, T0)
            final MethodHandle invokeHandleTyped = linkerServices.asType(callSiteBoundInvoker,
                    MethodType.methodType(type.returnType(), AnnotatedDynamicMethod.class, type.parameterType(0)));
            // Since it's in the target of a fold, drop the unnecessary second argument
            // R(AnnotatedDynamicMethod, T0)->R(AnnotatedDynamicMethod, T0, T1)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandleTyped, 2,
                    type.parameterType(1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, ops);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(AnnotatedDynamicMethod)->R(AnnotatedDynamicMethod, T0, T1); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_ANNOTATED_METHOD, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, AnnotatedDynamicMethod.class));
            } else {
                // R(T0, T1)->R(AnnotatedDynamicMethod, T0, T1); adapts the next component's invocation to drop the
                // extra argument resulting from fold
                fallbackFolded = MethodHandles.dropArguments(nextComponent.getGuardedInvocation().getInvocation(),
                        0, AnnotatedDynamicMethod.class);
            }

            // fold(R(AnnotatedDynamicMethod, T0, T1), AnnotatedDynamicMethod(T0, T1))
            final MethodHandle compositeGetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_ANNOTATED_METHOD_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeGetter, type);
            }
            return nextComponent.compose(compositeGetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have exactly one argument: receiver
            assertParameterCount(callSiteDescriptor, 1);
            // Fixed name
            final AnnotatedDynamicMethod annGetter = propertyGetters.get(callSiteDescriptor.getNameToken(
                    CallSiteDescriptor.NAME_OPERAND));
            if(annGetter == null) {
                // We have no such property, always delegate to the next component operation
                return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, ops);
            }
            final MethodHandle getter = annGetter.getInvocation(callSiteDescriptor, linkerServices);
            // NOTE: since property getters (not field getters!) are no-arg, we don't have to worry about them being
            // overloaded in a subclass. Therefore, we can discover the most abstract superclass that has the
            // method, and use that as the guard with Guards.isInstance() for a more stably linked call site. If
            // we're linking against a field getter, don't make the assumption.
            // NOTE: No delegation to the next component operation if we have a property with this name, even if its
            // value is null.
            final ValidationType validationType = annGetter.validationType;
            // TODO: we aren't using the type that declares the most generic getter here!
            return new GuardedInvocationComponent(linkerServices.asType(getter, type), getGuard(validationType,
                    type), clazz, validationType);
        }
        default: {
            // Can't do anything with more than 3 name components
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertyGetter(final CallSiteDescriptor callSiteDescriptor,
        final LinkerServices linkerServices, final List<String> ops) throws Exception {
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Since we can't know what kind of a getter we'll get back on different invocations, we'll just
            // conservatively presume Object. Note we can't just coerce to a narrower call site type as the linking
            // runtime might not allow coercing at that call site.
            final MethodType type = callSiteDescriptor.getMethodType().changeReturnType(Object.class);
            // Must have exactly two arguments: receiver and name
            assertParameterCount(callSiteDescriptor, 2);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke(get_handle), null|nextComponent.invocation), get_getter_handle)
            // only with a bunch of method signature adjustments. Basically, retrieve method getter
            // AnnotatedDynamicMethod; if it is non-null, invoke its "handle" field, otherwise either return null,
            // or delegate to next component's invocation.

            final MethodHandle typedGetter = linkerServices.asType(getPropertyGetterHandle, type.changeReturnType(
                    AnnotatedDynamicMethod.class));
            final MethodHandle callSiteBoundMethodGetter = MethodHandles.insertArguments(
                    GET_ANNOTATED_METHOD, 1, callSiteDescriptor.getLookup(), linkerServices);
            final MethodHandle callSiteBoundInvoker = MethodHandles.filterArguments(GETTER_INVOKER, 0,
                    callSiteBoundMethodGetter);
            // Object(AnnotatedDynamicMethod, Object)->Object(AnnotatedDynamicMethod, T0)
            final MethodHandle invokeHandleTyped = linkerServices.asType(callSiteBoundInvoker,
                    MethodType.methodType(type.returnType(), AnnotatedDynamicMethod.class, type.parameterType(0)));
            // Since it's in the target of a fold, drop the unnecessary second argument
            // Object(AnnotatedDynamicMethod, T0)->Object(AnnotatedDynamicMethod, T0, T1)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandleTyped, 2,
                    type.parameterType(1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, ops);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(AnnotatedDynamicMethod)->Object(AnnotatedDynamicMethod, T0, T1); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_ANNOTATED_METHOD, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, AnnotatedDynamicMethod.class));
            } else {
                // Object(T0, T1)->Object(AnnotatedDynamicMethod, T0, T1); adapts the next component's invocation to
                // drop the extra argument resulting from fold and to change its return type to Object.
                final MethodHandle nextInvocation = nextComponent.getGuardedInvocation().getInvocation();
                final MethodType nextType = nextInvocation.type();
                fallbackFolded = MethodHandles.dropArguments(nextInvocation.asType(
                        nextType.changeReturnType(Object.class)), 0, AnnotatedDynamicMethod.class);
            }

            // fold(Object(AnnotatedDynamicMethod, T0, T1), AnnotatedDynamicMethod(T0, T1))
            final MethodHandle compositeGetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_ANNOTATED_METHOD_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeGetter, type);
            }
            return nextComponent.compose(compositeGetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have exactly one argument: receiver
            assertParameterCount(callSiteDescriptor, 1);
            // Fixed name
            final AnnotatedDynamicMethod annGetter = propertyGetters.get(callSiteDescriptor.getNameToken(
                    CallSiteDescriptor.NAME_OPERAND));
            if(annGetter == null) {
                // We have no such property, always delegate to the next component operation
                return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, ops);
            }
            final MethodHandle getter = annGetter.getInvocation(callSiteDescriptor, linkerServices);
            // NOTE: since property getters (not field getters!) are no-arg, we don't have to worry about them being
            // overloaded in a subclass. Therefore, we can discover the most abstract superclass that has the
            // method, and use that as the guard with Guards.isInstance() for a more stably linked call site. If
            // we're linking against a field getter, don't make the assumption.
            // NOTE: No delegation to the next component operation if we have a property with this name, even if its
            // value is null.
            final ValidationType validationType = annGetter.validationType;
            // TODO: we aren't using the type that declares the most generic getter here!
            return new GuardedInvocationComponent(getter, getGuard(validationType,
                    callSiteDescriptor.getMethodType()), clazz, validationType);
        }
        default: {
            // Can't do anything with more than 3 name components
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertyGetter(final CallSiteDescriptor callSiteDescriptor,
        final LinkerServices linkerServices, final List<String> ops) throws Exception {
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Since we can't know what kind of a getter we'll get back on different invocations, we'll just
            // conservatively presume Object. Note we can't just coerce to a narrower call site type as the linking
            // runtime might not allow coercing at that call site.
            final MethodType type = callSiteDescriptor.getMethodType().changeReturnType(Object.class);
            // Must have exactly two arguments: receiver and name
            assertParameterCount(callSiteDescriptor, 2);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke(get_handle), null|nextComponent.invocation), get_getter_handle)
            // only with a bunch of method signature adjustments. Basically, retrieve method getter
            // AnnotatedDynamicMethod; if it is non-null, invoke its "handle" field, otherwise either return null,
            // or delegate to next component's invocation.

            final MethodHandle typedGetter = linkerServices.asType(getPropertyGetterHandle, type.changeReturnType(
                    AnnotatedDynamicMethod.class));
            final MethodHandle callSiteBoundMethodGetter = MethodHandles.insertArguments(
                    GET_ANNOTATED_METHOD, 1, callSiteDescriptor.getLookup(), linkerServices);
            final MethodHandle callSiteBoundInvoker = MethodHandles.filterArguments(GETTER_INVOKER, 0,
                    callSiteBoundMethodGetter);
            // Object(AnnotatedDynamicMethod, Object)->Object(AnnotatedDynamicMethod, T0)
            final MethodHandle invokeHandleTyped = linkerServices.asType(callSiteBoundInvoker,
                    MethodType.methodType(type.returnType(), AnnotatedDynamicMethod.class, type.parameterType(0)));
            // Since it's in the target of a fold, drop the unnecessary second argument
            // Object(AnnotatedDynamicMethod, T0)->Object(AnnotatedDynamicMethod, T0, T1)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandleTyped, 2,
                    type.parameterType(1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, ops);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(AnnotatedDynamicMethod)->Object(AnnotatedDynamicMethod, T0, T1); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_ANNOTATED_METHOD, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, AnnotatedDynamicMethod.class));
            } else {
                // Object(T0, T1)->Object(AnnotatedDynamicMethod, T0, T1); adapts the next component's invocation to
                // drop the extra argument resulting from fold and to change its return type to Object.
                final MethodHandle nextInvocation = nextComponent.getGuardedInvocation().getInvocation();
                final MethodType nextType = nextInvocation.type();
                fallbackFolded = MethodHandles.dropArguments(nextInvocation.asType(
                        nextType.changeReturnType(Object.class)), 0, AnnotatedDynamicMethod.class);
            }

            // fold(Object(AnnotatedDynamicMethod, T0, T1), AnnotatedDynamicMethod(T0, T1))
            final MethodHandle compositeGetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_ANNOTATED_METHOD_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeGetter, type);
            }
            return nextComponent.compose(compositeGetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have exactly one argument: receiver
            assertParameterCount(callSiteDescriptor, 1);
            // Fixed name
            final AnnotatedDynamicMethod annGetter = propertyGetters.get(callSiteDescriptor.getNameToken(
                    CallSiteDescriptor.NAME_OPERAND));
            if(annGetter == null) {
                // We have no such property, always delegate to the next component operation
                return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, ops);
            }
            final MethodHandle getter = annGetter.getInvocation(callSiteDescriptor, linkerServices);
            // NOTE: since property getters (not field getters!) are no-arg, we don't have to worry about them being
            // overloaded in a subclass. Therefore, we can discover the most abstract superclass that has the
            // method, and use that as the guard with Guards.isInstance() for a more stably linked call site. If
            // we're linking against a field getter, don't make the assumption.
            // NOTE: No delegation to the next component operation if we have a property with this name, even if its
            // value is null.
            final ValidationType validationType = annGetter.validationType;
            // TODO: we aren't using the type that declares the most generic getter here!
            return new GuardedInvocationComponent(getter, getGuard(validationType,
                    callSiteDescriptor.getMethodType()), clazz, validationType);
        }
        default: {
            // Can't do anything with more than 3 name components
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertyGetter(final CallSiteDescriptor callSiteDescriptor,
        final LinkerServices linkerServices, final List<String> ops) throws Exception {
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Since we can't know what kind of a getter we'll get back on different invocations, we'll just
            // conservatively presume Object. Note we can't just coerce to a narrower call site type as the linking
            // runtime might not allow coercing at that call site.
            final MethodType type = callSiteDescriptor.getMethodType().changeReturnType(Object.class);
            // Must have exactly two arguments: receiver and name
            assertParameterCount(callSiteDescriptor, 2);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke(get_handle), null|nextComponent.invocation), get_getter_handle)
            // only with a bunch of method signature adjustments. Basically, retrieve method getter
            // AnnotatedDynamicMethod; if it is non-null, invoke its "handle" field, otherwise either return null,
            // or delegate to next component's invocation.

            final MethodHandle typedGetter = linkerServices.asType(getPropertyGetterHandle, type.changeReturnType(
                    AnnotatedDynamicMethod.class));
            final MethodHandle callSiteBoundMethodGetter = MethodHandles.insertArguments(
                    GET_ANNOTATED_METHOD, 1, callSiteDescriptor.getLookup(), linkerServices);
            final MethodHandle callSiteBoundInvoker = MethodHandles.filterArguments(GETTER_INVOKER, 0,
                    callSiteBoundMethodGetter);
            // Object(AnnotatedDynamicMethod, Object)->Object(AnnotatedDynamicMethod, T0)
            final MethodHandle invokeHandleTyped = linkerServices.asType(callSiteBoundInvoker,
                    MethodType.methodType(type.returnType(), AnnotatedDynamicMethod.class, type.parameterType(0)));
            // Since it's in the target of a fold, drop the unnecessary second argument
            // Object(AnnotatedDynamicMethod, T0)->Object(AnnotatedDynamicMethod, T0, T1)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandleTyped, 2,
                    type.parameterType(1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, ops);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(AnnotatedDynamicMethod)->Object(AnnotatedDynamicMethod, T0, T1); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_ANNOTATED_METHOD, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, AnnotatedDynamicMethod.class));
            } else {
                // Object(T0, T1)->Object(AnnotatedDynamicMethod, T0, T1); adapts the next component's invocation to
                // drop the extra argument resulting from fold and to change its return type to Object.
                final MethodHandle nextInvocation = nextComponent.getGuardedInvocation().getInvocation();
                final MethodType nextType = nextInvocation.type();
                fallbackFolded = MethodHandles.dropArguments(nextInvocation.asType(
                        nextType.changeReturnType(Object.class)), 0, AnnotatedDynamicMethod.class);
            }

            // fold(Object(AnnotatedDynamicMethod, T0, T1), AnnotatedDynamicMethod(T0, T1))
            final MethodHandle compositeGetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_ANNOTATED_METHOD_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeGetter, type);
            }
            return nextComponent.compose(compositeGetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have exactly one argument: receiver
            assertParameterCount(callSiteDescriptor, 1);
            // Fixed name
            final AnnotatedDynamicMethod annGetter = propertyGetters.get(callSiteDescriptor.getNameToken(
                    CallSiteDescriptor.NAME_OPERAND));
            if(annGetter == null) {
                // We have no such property, always delegate to the next component operation
                return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, ops);
            }
            final MethodHandle getter = annGetter.getInvocation(callSiteDescriptor, linkerServices);
            // NOTE: since property getters (not field getters!) are no-arg, we don't have to worry about them being
            // overloaded in a subclass. Therefore, we can discover the most abstract superclass that has the
            // method, and use that as the guard with Guards.isInstance() for a more stably linked call site. If
            // we're linking against a field getter, don't make the assumption.
            // NOTE: No delegation to the next component operation if we have a property with this name, even if its
            // value is null.
            final ValidationType validationType = annGetter.validationType;
            // TODO: we aren't using the type that declares the most generic getter here!
            return new GuardedInvocationComponent(getter, getGuard(validationType,
                    callSiteDescriptor.getMethodType()), clazz, validationType);
        }
        default: {
            // Can't do anything with more than 3 name components
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertySetter(final CallSiteDescriptor callSiteDescriptor,
        final LinkerServices linkerServices, final List<String> operations) throws Exception {
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Must have three arguments: target object, property name, and property value.
            assertParameterCount(callSiteDescriptor, 3);

            // We want setters that conform to "Object(O, V)". Note, we aren't doing "R(O, V)" as it might not be
            // valid for us to convert return values proactively. Also, since we don't know what setters will be
            // invoked, we'll conservatively presume Object return type. The one exception is void return.
            final MethodType origType = callSiteDescriptor.getMethodType();
            final MethodType type = origType.returnType() == void.class ? origType : origType.changeReturnType(Object.class);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke, null|nextComponent.invocation),
            //     get_setter_handle(type, linkerServices))
            // only with a bunch of method signature adjustments. Basically, retrieve method setter
            // MethodHandle; if it is non-null, invoke it, otherwise either return null, or delegate to next
            // component's invocation.

            // Call site type is "ret_type(object_type,property_name_type,property_value_type)", which we'll
            // abbreviate to R(O, N, V) going forward, although we don't really use R here (see above about using
            // Object return type).
            final MethodType setterType = type.dropParameterTypes(1, 2);
            // Bind property setter handle to the expected setter type and linker services. Type is
            // MethodHandle(Object, String, Object)
            final MethodHandle boundGetter = MethodHandles.insertArguments(getPropertySetterHandle, 0,
                    callSiteDescriptor.changeMethodType(setterType), linkerServices);

            // Cast getter to MethodHandle(O, N, V)
            final MethodHandle typedGetter = linkerServices.asType(boundGetter, type.changeReturnType(
                    MethodHandle.class));

            // Handle to invoke the setter R(MethodHandle, O, V)
            final MethodHandle invokeHandle = MethodHandles.exactInvoker(setterType);
            // Handle to invoke the setter, dropping unnecessary fold arguments R(MethodHandle, O, N, V)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandle, 2, type.parameterType(
                    1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, operations);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(MethodHandle)->Object(MethodHandle, O, N, V); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_METHOD_HANDLE, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, MethodHandle.class));
            } else {
                // Object(O, N, V)->Object(MethodHandle, O, N, V); adapts the next component's invocation to drop the
                // extra argument resulting from fold
                fallbackFolded = MethodHandles.dropArguments(nextComponent.getGuardedInvocation().getInvocation(),
                        0, MethodHandle.class);
            }

            // fold(R(MethodHandle, O, N, V), MethodHandle(O, N, V))
            final MethodHandle compositeSetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_METHOD_HANDLE_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeSetter, type);
            }
            return nextComponent.compose(compositeSetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have two arguments: target object and property value
            assertParameterCount(callSiteDescriptor, 2);
            final GuardedInvocation gi = createGuardedDynamicMethodInvocation(callSiteDescriptor, linkerServices,
                    callSiteDescriptor.getNameToken(CallSiteDescriptor.NAME_OPERAND), propertySetters);
            // If we have a property setter with this name, this composite operation will always stop here
            if(gi != null) {
                return new GuardedInvocationComponent(gi, clazz, ValidationType.EXACT_CLASS);
            }
            // If we don't have a property setter with this name, always fall back to the next operation in the
            // composite (if any)
            return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, operations);
        }
        default: {
            // More than two name components; don't know what to do with it.
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertyGetter(final CallSiteDescriptor callSiteDescriptor,
        final LinkerServices linkerServices, final List<String> ops) throws Exception {
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Since we can't know what kind of a getter we'll get back on different invocations, we'll just
            // conservatively presume Object. Note we can't just coerce to a narrower call site type as the linking
            // runtime might not allow coercing at that call site.
            final MethodType type = callSiteDescriptor.getMethodType().changeReturnType(Object.class);
            // Must have exactly two arguments: receiver and name
            assertParameterCount(callSiteDescriptor, 2);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke(get_handle), null|nextComponent.invocation), get_getter_handle)
            // only with a bunch of method signature adjustments. Basically, retrieve method getter
            // AnnotatedDynamicMethod; if it is non-null, invoke its "handle" field, otherwise either return null,
            // or delegate to next component's invocation.

            final MethodHandle typedGetter = linkerServices.asType(getPropertyGetterHandle, type.changeReturnType(
                    AnnotatedDynamicMethod.class));
            final MethodHandle callSiteBoundMethodGetter = MethodHandles.insertArguments(
                    GET_ANNOTATED_METHOD, 1, callSiteDescriptor.getLookup(), linkerServices);
            final MethodHandle callSiteBoundInvoker = MethodHandles.filterArguments(GETTER_INVOKER, 0,
                    callSiteBoundMethodGetter);
            // Object(AnnotatedDynamicMethod, Object)->Object(AnnotatedDynamicMethod, T0)
            final MethodHandle invokeHandleTyped = linkerServices.asType(callSiteBoundInvoker,
                    MethodType.methodType(type.returnType(), AnnotatedDynamicMethod.class, type.parameterType(0)));
            // Since it's in the target of a fold, drop the unnecessary second argument
            // Object(AnnotatedDynamicMethod, T0)->Object(AnnotatedDynamicMethod, T0, T1)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandleTyped, 2,
                    type.parameterType(1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, ops);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(AnnotatedDynamicMethod)->Object(AnnotatedDynamicMethod, T0, T1); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_ANNOTATED_METHOD, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, AnnotatedDynamicMethod.class));
            } else {
                // Object(T0, T1)->Object(AnnotatedDynamicMethod, T0, T1); adapts the next component's invocation to
                // drop the extra argument resulting from fold and to change its return type to Object.
                final MethodHandle nextInvocation = nextComponent.getGuardedInvocation().getInvocation();
                final MethodType nextType = nextInvocation.type();
                fallbackFolded = MethodHandles.dropArguments(nextInvocation.asType(
                        nextType.changeReturnType(Object.class)), 0, AnnotatedDynamicMethod.class);
            }

            // fold(Object(AnnotatedDynamicMethod, T0, T1), AnnotatedDynamicMethod(T0, T1))
            final MethodHandle compositeGetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_ANNOTATED_METHOD_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeGetter, type);
            }
            return nextComponent.compose(compositeGetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have exactly one argument: receiver
            assertParameterCount(callSiteDescriptor, 1);
            // Fixed name
            final AnnotatedDynamicMethod annGetter = propertyGetters.get(callSiteDescriptor.getNameToken(
                    CallSiteDescriptor.NAME_OPERAND));
            if(annGetter == null) {
                // We have no such property, always delegate to the next component operation
                return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, ops);
            }
            final MethodHandle getter = annGetter.getInvocation(callSiteDescriptor, linkerServices);
            // NOTE: since property getters (not field getters!) are no-arg, we don't have to worry about them being
            // overloaded in a subclass. Therefore, we can discover the most abstract superclass that has the
            // method, and use that as the guard with Guards.isInstance() for a more stably linked call site. If
            // we're linking against a field getter, don't make the assumption.
            // NOTE: No delegation to the next component operation if we have a property with this name, even if its
            // value is null.
            final ValidationType validationType = annGetter.validationType;
            // TODO: we aren't using the type that declares the most generic getter here!
            return new GuardedInvocationComponent(getter, getGuard(validationType,
                    callSiteDescriptor.getMethodType()), clazz, validationType);
        }
        default: {
            // Can't do anything with more than 3 name components
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertySetter(final CallSiteDescriptor callSiteDescriptor,
        final LinkerServices linkerServices, final List<String> operations) throws Exception {
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Must have three arguments: target object, property name, and property value.
            assertParameterCount(callSiteDescriptor, 3);

            // We want setters that conform to "Object(O, V)". Note, we aren't doing "R(O, V)" as it might not be
            // valid for us to convert return values proactively. Also, since we don't know what setters will be
            // invoked, we'll conservatively presume Object return type. The one exception is void return.
            final MethodType origType = callSiteDescriptor.getMethodType();
            final MethodType type = origType.returnType() == void.class ? origType : origType.changeReturnType(Object.class);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke, null|nextComponent.invocation),
            //     get_setter_handle(type, linkerServices))
            // only with a bunch of method signature adjustments. Basically, retrieve method setter
            // MethodHandle; if it is non-null, invoke it, otherwise either return null, or delegate to next
            // component's invocation.

            // Call site type is "ret_type(object_type,property_name_type,property_value_type)", which we'll
            // abbreviate to R(O, N, V) going forward, although we don't really use R here (see above about using
            // Object return type).
            final MethodType setterType = type.dropParameterTypes(1, 2);
            // Bind property setter handle to the expected setter type and linker services. Type is
            // MethodHandle(Object, String, Object)
            final MethodHandle boundGetter = MethodHandles.insertArguments(getPropertySetterHandle, 0,
                    callSiteDescriptor.changeMethodType(setterType), linkerServices);

            // Cast getter to MethodHandle(O, N, V)
            final MethodHandle typedGetter = linkerServices.asType(boundGetter, type.changeReturnType(
                    MethodHandle.class));

            // Handle to invoke the setter R(MethodHandle, O, V)
            final MethodHandle invokeHandle = MethodHandles.exactInvoker(setterType);
            // Handle to invoke the setter, dropping unnecessary fold arguments R(MethodHandle, O, N, V)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandle, 2, type.parameterType(
                    1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, operations);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(MethodHandle)->Object(MethodHandle, O, N, V); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_METHOD_HANDLE, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, MethodHandle.class));
            } else {
                // Object(O, N, V)->Object(MethodHandle, O, N, V); adapts the next component's invocation to drop the
                // extra argument resulting from fold
                fallbackFolded = MethodHandles.dropArguments(nextComponent.getGuardedInvocation().getInvocation(),
                        0, MethodHandle.class);
            }

            // fold(R(MethodHandle, O, N, V), MethodHandle(O, N, V))
            final MethodHandle compositeSetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_METHOD_HANDLE_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeSetter, type);
            }
            return nextComponent.compose(compositeSetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have two arguments: target object and property value
            assertParameterCount(callSiteDescriptor, 2);
            final GuardedInvocation gi = createGuardedDynamicMethodInvocation(callSiteDescriptor, linkerServices,
                    callSiteDescriptor.getNameToken(CallSiteDescriptor.NAME_OPERAND), propertySetters);
            // If we have a property setter with this name, this composite operation will always stop here
            if(gi != null) {
                return new GuardedInvocationComponent(gi, clazz, ValidationType.EXACT_CLASS);
            }
            // If we don't have a property setter with this name, always fall back to the next operation in the
            // composite (if any)
            return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, operations);
        }
        default: {
            // More than two name components; don't know what to do with it.
            return null;
        }
    }
}
 

private GuardedInvocationComponent getPropertySetter(CallSiteDescriptor callSiteDescriptor,
        LinkerServices linkerServices, List<String> operations) throws Exception {
    final MethodType type = callSiteDescriptor.getMethodType();
    switch(callSiteDescriptor.getNameTokenCount()) {
        case 2: {
            // Must have three arguments: target object, property name, and property value.
            assertParameterCount(callSiteDescriptor, 3);

            // What's below is basically:
            //   foldArguments(guardWithTest(isNotNull, invoke, null|nextComponent.invocation),
            //     get_setter_handle(type, linkerServices))
            // only with a bunch of method signature adjustments. Basically, retrieve method setter
            // MethodHandle; if it is non-null, invoke it, otherwise either return null, or delegate to next
            // component's invocation.

            // Call site type is "ret_type(object_type,property_name_type,property_value_type)", which we'll
            // abbreviate to R(O, N, V) going forward.
            // We want setters that conform to "R(O, V)"
            final MethodType setterType = type.dropParameterTypes(1, 2);
            // Bind property setter handle to the expected setter type and linker services. Type is
            // MethodHandle(Object, String, Object)
            final MethodHandle boundGetter = MethodHandles.insertArguments(getPropertySetterHandle, 0,
                    CallSiteDescriptorFactory.dropParameterTypes(callSiteDescriptor, 1, 2), linkerServices);

            // Cast getter to MethodHandle(O, N, V)
            final MethodHandle typedGetter = linkerServices.asType(boundGetter, type.changeReturnType(
                    MethodHandle.class));

            // Handle to invoke the setter R(MethodHandle, O, V)
            final MethodHandle invokeHandle = MethodHandles.exactInvoker(setterType);
            // Handle to invoke the setter, dropping unnecessary fold arguments R(MethodHandle, O, N, V)
            final MethodHandle invokeHandleFolded = MethodHandles.dropArguments(invokeHandle, 2, type.parameterType(
                    1));
            final GuardedInvocationComponent nextComponent = getGuardedInvocationComponent(callSiteDescriptor,
                    linkerServices, operations);

            final MethodHandle fallbackFolded;
            if(nextComponent == null) {
                // Object(MethodHandle)->R(MethodHandle, O, N, V); returns constant null
                fallbackFolded = MethodHandles.dropArguments(CONSTANT_NULL_DROP_METHOD_HANDLE, 1,
                        type.parameterList()).asType(type.insertParameterTypes(0, MethodHandle.class));
            } else {
                // R(O, N, V)->R(MethodHandle, O, N, V); adapts the next component's invocation to drop the
                // extra argument resulting from fold
                fallbackFolded = MethodHandles.dropArguments(nextComponent.getGuardedInvocation().getInvocation(),
                        0, MethodHandle.class);
            }

            // fold(R(MethodHandle, O, N, V), MethodHandle(O, N, V))
            final MethodHandle compositeSetter = MethodHandles.foldArguments(MethodHandles.guardWithTest(
                        IS_METHOD_HANDLE_NOT_NULL, invokeHandleFolded, fallbackFolded), typedGetter);
            if(nextComponent == null) {
                return getClassGuardedInvocationComponent(compositeSetter, type);
            }
            return nextComponent.compose(compositeSetter, getClassGuard(type), clazz, ValidationType.EXACT_CLASS);
        }
        case 3: {
            // Must have two arguments: target object and property value
            assertParameterCount(callSiteDescriptor, 2);
            final GuardedInvocation gi = createGuardedDynamicMethodInvocation(callSiteDescriptor, linkerServices,
                    callSiteDescriptor.getNameToken(CallSiteDescriptor.NAME_OPERAND), propertySetters);
            // If we have a property setter with this name, this composite operation will always stop here
            if(gi != null) {
                return new GuardedInvocationComponent(gi, clazz, ValidationType.EXACT_CLASS);
            }
            // If we don't have a property setter with this name, always fall back to the next operation in the
            // composite (if any)
            return getGuardedInvocationComponent(callSiteDescriptor, linkerServices, operations);
        }
        default: {
            // More than two name components; don't know what to do with it.
            return null;
        }
    }
}
 

/**
 * Takes a guard-test method handle, and adapts it to the requested type, returning a boolean. Applies the passed
 * {@link LinkerServices} object's {@link LinkerServices#asType(MethodHandle, MethodType)}.
 * @param linkerServices the linker services to use for type conversions
 * @param test the test method handle
 * @param type the type to adapt the method handle to
 * @return the adapted method handle
 */
public static MethodHandle asType(final LinkerServices linkerServices, final MethodHandle test, final MethodType type) {
    return linkerServices.asType(test, getTestType(test, type));
}
 

/**
 * Takes a guard-test method handle, and adapts it to the requested type, returning a boolean. Applies the passed
 * {@link LinkerServices} object's {@link LinkerServices#asType(MethodHandle, MethodType)}.
 * @param linkerServices the linker services to use for type conversions
 * @param test the test method handle
 * @param type the type to adapt the method handle to
 * @return the adapted method handle
 */
public static MethodHandle asType(final LinkerServices linkerServices, final MethodHandle test, final MethodType type) {
    return linkerServices.asType(test, getTestType(test, type));
}
 

/**
 * Takes a guard-test method handle, and adapts it to the requested type, returning a boolean. Applies the passed
 * {@link LinkerServices} object's {@link LinkerServices#asType(MethodHandle, MethodType)}.
 * @param linkerServices the linker services to use for type conversions
 * @param test the test method handle
 * @param type the type to adapt the method handle to
 * @return the adapted method handle
 */
public static MethodHandle asType(final LinkerServices linkerServices, final MethodHandle test, final MethodType type) {
    return linkerServices.asType(test, getTestType(test, type));
}
 

/**
 * Takes a guard-test method handle, and adapts it to the requested type, returning a boolean. Applies the passed
 * {@link LinkerServices} object's {@link LinkerServices#asType(MethodHandle, MethodType)}.
 * @param linkerServices the linker services to use for type conversions
 * @param test the test method handle
 * @param type the type to adapt the method handle to
 * @return the adapted method handle
 */
public static MethodHandle asType(LinkerServices linkerServices, MethodHandle test, MethodType type) {
    return linkerServices.asType(test, getTestType(test, type));
}
 

/**
 * Takes a guard-test method handle, and adapts it to the requested type, returning a boolean. Applies the passed
 * {@link LinkerServices} object's {@link LinkerServices#asType(MethodHandle, MethodType)}.
 * @param linkerServices the linker services to use for type conversions
 * @param test the test method handle
 * @param type the type to adapt the method handle to
 * @return the adapted method handle
 */
public static MethodHandle asType(final LinkerServices linkerServices, final MethodHandle test, final MethodType type) {
    return linkerServices.asType(test, getTestType(test, type));
}
 

/**
 * Takes a guard-test method handle, and adapts it to the requested type, returning a boolean. Applies the passed
 * {@link LinkerServices} object's {@link LinkerServices#asType(MethodHandle, MethodType)}.
 * @param linkerServices the linker services to use for type conversions
 * @param test the test method handle
 * @param type the type to adapt the method handle to
 * @return the adapted method handle
 */
public static MethodHandle asType(final LinkerServices linkerServices, final MethodHandle test, final MethodType type) {
    return linkerServices.asType(test, getTestType(test, type));
}
 

/**
 * Takes a guard-test method handle, and adapts it to the requested type, returning a boolean. Applies the passed
 * {@link LinkerServices} object's {@link LinkerServices#asType(MethodHandle, MethodType)}.
 * @param linkerServices the linker services to use for type conversions
 * @param test the test method handle
 * @param type the type to adapt the method handle to
 * @return the adapted method handle
 */
public static MethodHandle asType(final LinkerServices linkerServices, final MethodHandle test, final MethodType type) {
    return linkerServices.asType(test, getTestType(test, type));
}
 

/**
 * Takes a guard-test method handle, and adapts it to the requested type, returning a boolean. Applies the passed
 * {@link LinkerServices} object's {@link LinkerServices#asType(MethodHandle, MethodType)}.
 * @param linkerServices the linker services to use for type conversions
 * @param test the test method handle
 * @param type the type to adapt the method handle to
 * @return the adapted method handle
 */
public static MethodHandle asType(LinkerServices linkerServices, MethodHandle test, MethodType type) {
    return linkerServices.asType(test, getTestType(test, type));
}