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package java.lang.invoke;

import java.io.Serializable;
import java.util.Arrays;

/**
 * 

Methods to facilitate the creation of simple "function objects" that * implement one or more interfaces by delegation to a provided {@link MethodHandle}, * possibly after type adaptation and partial evaluation of arguments. These * methods are typically used as bootstrap methods for {@code invokedynamic} * call sites, to support the lambda expression and method * reference expression features of the Java Programming Language. * *

Indirect access to the behavior specified by the provided {@code MethodHandle} * proceeds in order through three phases: *

    *
  • Linkage occurs when the methods in this class are invoked. * They take as arguments an interface to be implemented (typically a * functional interface, one with a single abstract method), a * name and signature of a method from that interface to be implemented, a * method handle describing the desired implementation behavior * for that method, and possibly other additional metadata, and produce a * {@link CallSite} whose target can be used to create suitable function * objects. Linkage may involve dynamically loading a new class that * implements the target interface. The {@code CallSite} can be considered a * "factory" for function objects and so these linkage methods are referred * to as "metafactories".
  • * *
  • Capture occurs when the {@code CallSite}'s target is * invoked, typically through an {@code invokedynamic} call site, * producing a function object. This may occur many times for * a single factory {@code CallSite}. Capture may involve allocation of a * new function object, or may return an existing function object. The * behavior {@code MethodHandle} may have additional parameters beyond those * of the specified interface method; these are referred to as captured * parameters, which must be provided as arguments to the * {@code CallSite} target, and which may be early-bound to the behavior * {@code MethodHandle}. The number of captured parameters and their types * are determined during linkage.
  • * *
  • Invocation occurs when an implemented interface method * is invoked on a function object. This may occur many times for a single * function object. The method referenced by the behavior {@code MethodHandle} * is invoked with the captured arguments and any additional arguments * provided on invocation, as if by {@link MethodHandle#invoke(Object...)}.
  • *
* *

It is sometimes useful to restrict the set of inputs or results permitted * at invocation. For example, when the generic interface {@code Predicate} * is parameterized as {@code Predicate}, the input must be a * {@code String}, even though the method to implement allows any {@code Object}. * At linkage time, an additional {@link MethodType} parameter describes the * "instantiated" method type; on invocation, the arguments and eventual result * are checked against this {@code MethodType}. * *

This class provides two forms of linkage methods: a standard version * ({@link #metafactory(MethodHandles.Lookup, String, MethodType, MethodType, MethodHandle, MethodType)}) * using an optimized protocol, and an alternate version * {@link #altMetafactory(MethodHandles.Lookup, String, MethodType, Object...)}). * The alternate version is a generalization of the standard version, providing * additional control over the behavior of the generated function objects via * flags and additional arguments. The alternate version adds the ability to * manage the following attributes of function objects: * *

    *
  • Bridging. It is sometimes useful to implement multiple * variations of the method signature, involving argument or return type * adaptation. This occurs when multiple distinct VM signatures for a method * are logically considered to be the same method by the language. The * flag {@code FLAG_BRIDGES} indicates that a list of additional * {@code MethodType}s will be provided, each of which will be implemented * by the resulting function object. These methods will share the same * name and instantiated type.
  • * *
  • Multiple interfaces. If needed, more than one interface * can be implemented by the function object. (These additional interfaces * are typically marker interfaces with no methods.) The flag {@code FLAG_MARKERS} * indicates that a list of additional interfaces will be provided, each of * which should be implemented by the resulting function object.
  • * *
  • Serializability. The generated function objects do not * generally support serialization. If desired, {@code FLAG_SERIALIZABLE} * can be used to indicate that the function objects should be serializable. * Serializable function objects will use, as their serialized form, * instances of the class {@code SerializedLambda}, which requires additional * assistance from the capturing class (the class described by the * {@link MethodHandles.Lookup} parameter {@code caller}); see * {@link SerializedLambda} for details.
  • *
* *

Assume the linkage arguments are as follows: *

    *
  • {@code invokedType} (describing the {@code CallSite} signature) has * K parameters of types (D1..Dk) and return type Rd;
  • *
  • {@code samMethodType} (describing the implemented method type) has N * parameters, of types (U1..Un) and return type Ru;
  • *
  • {@code implMethod} (the {@code MethodHandle} providing the * implementation has M parameters, of types (A1..Am) and return type Ra * (if the method describes an instance method, the method type of this * method handle already includes an extra first argument corresponding to * the receiver);
  • *
  • {@code instantiatedMethodType} (allowing restrictions on invocation) * has N parameters, of types (T1..Tn) and return type Rt.
  • *
* *

Then the following linkage invariants must hold: *

    *
  • Rd is an interface
  • *
  • {@code implMethod} is a direct method handle
  • *
  • {@code samMethodType} and {@code instantiatedMethodType} have the same * arity N, and for i=1..N, Ti and Ui are the same type, or Ti and Ui are * both reference types and Ti is a subtype of Ui
  • *
  • Either Rt and Ru are the same type, or both are reference types and * Rt is a subtype of Ru
  • *
  • K + N = M
  • *
  • For i=1..K, Di = Ai
  • *
  • For i=1..N, Ti is adaptable to Aj, where j=i+k
  • *
  • The return type Rt is void, or the return type Ra is not void and is * adaptable to Rt
  • *
* *

Further, at capture time, if {@code implMethod} corresponds to an instance * method, and there are any capture arguments ({@code K > 0}), then the first * capture argument (corresponding to the receiver) must be non-null. * *

A type Q is considered adaptable to S as follows: *

* * * * * * * * * * * * * * * * * * * * * *
QSLink-time checksInvocation-time checks
PrimitivePrimitiveQ can be converted to S via a primitive widening conversionNone
PrimitiveReferenceS is a supertype of the Wrapper(Q)Cast from Wrapper(Q) to S
ReferencePrimitivefor parameter types: Q is a primitive wrapper and Primitive(Q) * can be widened to S *
for return types: If Q is a primitive wrapper, check that * Primitive(Q) can be widened to S
If Q is not a primitive wrapper, cast Q to the base Wrapper(S); * for example Number for numeric types
ReferenceReferencefor parameter types: S is a supertype of Q *
for return types: none
Cast from Q to S
* * @apiNote These linkage methods are designed to support the evaluation * of lambda expressions and method references in the Java * Language. For every lambda expressions or method reference in the source code, * there is a target type which is a functional interface. Evaluating a lambda * expression produces an object of its target type. The recommended mechanism * for evaluating lambda expressions is to desugar the lambda body to a method, * invoke an invokedynamic call site whose static argument list describes the * sole method of the functional interface and the desugared implementation * method, and returns an object (the lambda object) that implements the target * type. (For method references, the implementation method is simply the * referenced method; no desugaring is needed.) * *

The argument list of the implementation method and the argument list of * the interface method(s) may differ in several ways. The implementation * methods may have additional arguments to accommodate arguments captured by * the lambda expression; there may also be differences resulting from permitted * adaptations of arguments, such as casting, boxing, unboxing, and primitive * widening. (Varargs adaptations are not handled by the metafactories; these are * expected to be handled by the caller.) * *

Invokedynamic call sites have two argument lists: a static argument list * and a dynamic argument list. The static argument list is stored in the * constant pool; the dynamic argument is pushed on the operand stack at capture * time. The bootstrap method has access to the entire static argument list * (which in this case, includes information describing the implementation method, * the target interface, and the target interface method(s)), as well as a * method signature describing the number and static types (but not the values) * of the dynamic arguments and the static return type of the invokedynamic site. * * @implNote The implementation method is described with a method handle. In * theory, any method handle could be used. Currently supported are direct method * handles representing invocation of virtual, interface, constructor and static * methods. */ public class LambdaMetafactory { /** Flag for alternate metafactories indicating the lambda object * must be serializable */ public static final int FLAG_SERIALIZABLE = 1 << 0; /** * Flag for alternate metafactories indicating the lambda object implements * other marker interfaces * besides Serializable */ public static final int FLAG_MARKERS = 1 << 1; /** * Flag for alternate metafactories indicating the lambda object requires * additional bridge methods */ public static final int FLAG_BRIDGES = 1 << 2; private static final Class[] EMPTY_CLASS_ARRAY = new Class[0]; private static final MethodType[] EMPTY_MT_ARRAY = new MethodType[0]; /** * Facilitates the creation of simple "function objects" that implement one * or more interfaces by delegation to a provided {@link MethodHandle}, * after appropriate type adaptation and partial evaluation of arguments. * Typically used as a bootstrap method for {@code invokedynamic} * call sites, to support the lambda expression and method * reference expression features of the Java Programming Language. * *

This is the standard, streamlined metafactory; additional flexibility * is provided by {@link #altMetafactory(MethodHandles.Lookup, String, MethodType, Object...)}. * A general description of the behavior of this method is provided * {@link LambdaMetafactory above}. * *

When the target of the {@code CallSite} returned from this method is * invoked, the resulting function objects are instances of a class which * implements the interface named by the return type of {@code invokedType}, * declares a method with the name given by {@code invokedName} and the * signature given by {@code samMethodType}. It may also override additional * methods from {@code Object}. * * @param caller Represents a lookup context with the accessibility * privileges of the caller. When used with {@code invokedynamic}, * this is stacked automatically by the VM. * @param invokedName The name of the method to implement. When used with * {@code invokedynamic}, this is provided by the * {@code NameAndType} of the {@code InvokeDynamic} * structure and is stacked automatically by the VM. * @param invokedType The expected signature of the {@code CallSite}. The * parameter types represent the types of capture variables; * the return type is the interface to implement. When * used with {@code invokedynamic}, this is provided by * the {@code NameAndType} of the {@code InvokeDynamic} * structure and is stacked automatically by the VM. * In the event that the implementation method is an * instance method and this signature has any parameters, * the first parameter in the invocation signature must * correspond to the receiver. * @param samMethodType Signature and return type of method to be implemented * by the function object. * @param implMethod A direct method handle describing the implementation * method which should be called (with suitable adaptation * of argument types, return types, and with captured * arguments prepended to the invocation arguments) at * invocation time. * @param instantiatedMethodType The signature and return type that should * be enforced dynamically at invocation time. * This may be the same as {@code samMethodType}, * or may be a specialization of it. * @return a CallSite whose target can be used to perform capture, generating * instances of the interface named by {@code invokedType} * @throws LambdaConversionException If any of the linkage invariants * described {@link LambdaMetafactory above} * are violated */ public static CallSite metafactory(MethodHandles.Lookup caller, String invokedName, MethodType invokedType, MethodType samMethodType, MethodHandle implMethod, MethodType instantiatedMethodType) { throw new IllegalStateException(); } /** * Facilitates the creation of simple "function objects" that implement one * or more interfaces by delegation to a provided {@link MethodHandle}, * after appropriate type adaptation and partial evaluation of arguments. * Typically used as a bootstrap method for {@code invokedynamic} * call sites, to support the lambda expression and method * reference expression features of the Java Programming Language. * *

This is the general, more flexible metafactory; a streamlined version * is provided by {@link #altMetafactory(MethodHandles.Lookup, String, MethodType, Object...)}. * A general description of the behavior of this method is provided * {@link LambdaMetafactory above}. * *

The argument list for this method includes three fixed parameters, * corresponding to the parameters automatically stacked by the VM for the * bootstrap method in an {@code invokedynamic} invocation, and an {@code Object[]} * parameter that contains additional parameters. The declared argument * list for this method is: * *

{@code
     *  CallSite altMetafactory(MethodHandles.Lookup caller,
     *                          String invokedName,
     *                          MethodType invokedType,
     *                          Object... args)
     * }
* *

but it behaves as if the argument list is as follows: * *

{@code
     *  CallSite altMetafactory(MethodHandles.Lookup caller,
     *                          String invokedName,
     *                          MethodType invokedType,
     *                          MethodType samMethodType,
     *                          MethodHandle implMethod,
     *                          MethodType instantiatedMethodType,
     *                          int flags,
     *                          int markerInterfaceCount,  // IF flags has MARKERS set
     *                          Class... markerInterfaces, // IF flags has MARKERS set
     *                          int bridgeCount,           // IF flags has BRIDGES set
     *                          MethodType... bridges      // IF flags has BRIDGES set
     *                          )
     * }
* *

Arguments that appear in the argument list for * {@link #metafactory(MethodHandles.Lookup, String, MethodType, MethodType, MethodHandle, MethodType)} * have the same specification as in that method. The additional arguments * are interpreted as follows: *

    *
  • {@code flags} indicates additional options; this is a bitwise * OR of desired flags. Defined flags are {@link #FLAG_BRIDGES}, * {@link #FLAG_MARKERS}, and {@link #FLAG_SERIALIZABLE}.
  • *
  • {@code markerInterfaceCount} is the number of additional interfaces * the function object should implement, and is present if and only if the * {@code FLAG_MARKERS} flag is set.
  • *
  • {@code markerInterfaces} is a variable-length list of additional * interfaces to implement, whose length equals {@code markerInterfaceCount}, * and is present if and only if the {@code FLAG_MARKERS} flag is set.
  • *
  • {@code bridgeCount} is the number of additional method signatures * the function object should implement, and is present if and only if * the {@code FLAG_BRIDGES} flag is set.
  • *
  • {@code bridges} is a variable-length list of additional * methods signatures to implement, whose length equals {@code bridgeCount}, * and is present if and only if the {@code FLAG_BRIDGES} flag is set.
  • *
* *

Each class named by {@code markerInterfaces} is subject to the same * restrictions as {@code Rd}, the return type of {@code invokedType}, * as described {@link LambdaMetafactory above}. Each {@code MethodType} * named by {@code bridges} is subject to the same restrictions as * {@code samMethodType}, as described {@link LambdaMetafactory above}. * *

When FLAG_SERIALIZABLE is set in {@code flags}, the function objects * will implement {@code Serializable}, and will have a {@code writeReplace} * method that returns an appropriate {@link SerializedLambda}. The * {@code caller} class must have an appropriate {@code $deserializeLambda$} * method, as described in {@link SerializedLambda}. * *

When the target of the {@code CallSite} returned from this method is * invoked, the resulting function objects are instances of a class with * the following properties: *

    *
  • The class implements the interface named by the return type * of {@code invokedType} and any interfaces named by {@code markerInterfaces}
  • *
  • The class declares methods with the name given by {@code invokedName}, * and the signature given by {@code samMethodType} and additional signatures * given by {@code bridges}
  • *
  • The class may override methods from {@code Object}, and may * implement methods related to serialization.
  • *
* * @param caller Represents a lookup context with the accessibility * privileges of the caller. When used with {@code invokedynamic}, * this is stacked automatically by the VM. * @param invokedName The name of the method to implement. When used with * {@code invokedynamic}, this is provided by the * {@code NameAndType} of the {@code InvokeDynamic} * structure and is stacked automatically by the VM. * @param invokedType The expected signature of the {@code CallSite}. The * parameter types represent the types of capture variables; * the return type is the interface to implement. When * used with {@code invokedynamic}, this is provided by * the {@code NameAndType} of the {@code InvokeDynamic} * structure and is stacked automatically by the VM. * In the event that the implementation method is an * instance method and this signature has any parameters, * the first parameter in the invocation signature must * correspond to the receiver. * @param args An {@code Object[]} array containing the required * arguments {@code samMethodType}, {@code implMethod}, * {@code instantiatedMethodType}, {@code flags}, and any * optional arguments, as described * {@link #altMetafactory(MethodHandles.Lookup, String, MethodType, Object...)} above} * @return a CallSite whose target can be used to perform capture, generating * instances of the interface named by {@code invokedType} * @throws LambdaConversionException If any of the linkage invariants * described {@link LambdaMetafactory above} * are violated */ public static CallSite altMetafactory(MethodHandles.Lookup caller, String invokedName, MethodType invokedType, Object... args) { throw new IllegalStateException(); } }




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