Batch of classes necessary to implement invoke dynamic interfaces. Taken from JDK8 build 132
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27 * The {@code java.lang.invoke} package contains dynamic language support provided directly by
28 * the Java core class libraries and virtual machine.
31 * As described in the Java Virtual Machine Specification,
32 * certain types in this package have special relations to dynamic
33 * language support in the virtual machine:
35 * <li>The class {@link java.lang.invoke.MethodHandle MethodHandle} contains
36 * <a href="MethodHandle.html#sigpoly">signature polymorphic methods</a>
37 * which can be linked regardless of their type descriptor.
38 * Normally, method linkage requires exact matching of type descriptors.
41 * <li>The JVM bytecode format supports immediate constants of
42 * the classes {@link java.lang.invoke.MethodHandle MethodHandle} and {@link java.lang.invoke.MethodType MethodType}.
46 * <h1><a name="jvm_mods"></a>Summary of relevant Java Virtual Machine changes</h1>
47 * The following low-level information summarizes relevant parts of the
48 * Java Virtual Machine specification. For full details, please see the
49 * current version of that specification.
51 * Each occurrence of an {@code invokedynamic} instruction is called a <em>dynamic call site</em>.
52 * <h2><a name="indyinsn"></a>{@code invokedynamic} instructions</h2>
53 * A dynamic call site is originally in an unlinked state. In this state, there is
54 * no target method for the call site to invoke.
56 * Before the JVM can execute a dynamic call site (an {@code invokedynamic} instruction),
57 * the call site must first be <em>linked</em>.
58 * Linking is accomplished by calling a <em>bootstrap method</em>
59 * which is given the static information content of the call site,
60 * and which must produce a {@link java.lang.invoke.MethodHandle method handle}
61 * that gives the behavior of the call site.
63 * Each {@code invokedynamic} instruction statically specifies its own
64 * bootstrap method as a constant pool reference.
65 * The constant pool reference also specifies the call site's name and type descriptor,
66 * just like {@code invokevirtual} and the other invoke instructions.
68 * Linking starts with resolving the constant pool entry for the
69 * bootstrap method, and resolving a {@link java.lang.invoke.MethodType MethodType} object for
70 * the type descriptor of the dynamic call site.
71 * This resolution process may trigger class loading.
72 * It may therefore throw an error if a class fails to load.
73 * This error becomes the abnormal termination of the dynamic
74 * call site execution.
75 * Linkage does not trigger class initialization.
77 * The bootstrap method is invoked on at least three values:
79 * <li>a {@code MethodHandles.Lookup}, a lookup object on the <em>caller class</em> in which dynamic call site occurs </li>
80 * <li>a {@code String}, the method name mentioned in the call site </li>
81 * <li>a {@code MethodType}, the resolved type descriptor of the call </li>
82 * <li>optionally, between 1 and 251 additional static arguments taken from the constant pool </li>
84 * Invocation is as if by
85 * {@link java.lang.invoke.MethodHandle#invoke MethodHandle.invoke}.
86 * The returned result must be a {@link java.lang.invoke.CallSite CallSite} (or a subclass).
87 * The type of the call site's target must be exactly equal to the type
88 * derived from the dynamic call site's type descriptor and passed to
89 * the bootstrap method.
90 * The call site then becomes permanently linked to the dynamic call site.
92 * As documented in the JVM specification, all failures arising from
93 * the linkage of a dynamic call site are reported
94 * by a {@link java.lang.BootstrapMethodError BootstrapMethodError},
95 * which is thrown as the abnormal termination of the dynamic call
97 * If this happens, the same error will the thrown for all subsequent
98 * attempts to execute the dynamic call site.
100 * <h2>timing of linkage</h2>
101 * A dynamic call site is linked just before its first execution.
102 * The bootstrap method call implementing the linkage occurs within
103 * a thread that is attempting a first execution.
105 * If there are several such threads, the bootstrap method may be
106 * invoked in several threads concurrently.
107 * Therefore, bootstrap methods which access global application
108 * data must take the usual precautions against race conditions.
109 * In any case, every {@code invokedynamic} instruction is either
110 * unlinked or linked to a unique {@code CallSite} object.
112 * In an application which requires dynamic call sites with individually
113 * mutable behaviors, their bootstrap methods should produce distinct
114 * {@link java.lang.invoke.CallSite CallSite} objects, one for each linkage request.
115 * Alternatively, an application can link a single {@code CallSite} object
116 * to several {@code invokedynamic} instructions, in which case
117 * a change to the target method will become visible at each of
120 * If several threads simultaneously execute a bootstrap method for a single dynamic
121 * call site, the JVM must choose one {@code CallSite} object and install it visibly to
122 * all threads. Any other bootstrap method calls are allowed to complete, but their
123 * results are ignored, and their dynamic call site invocations proceed with the originally
124 * chosen target object.
126 * <p style="font-size:smaller;">
127 * <em>Discussion:</em>
128 * These rules do not enable the JVM to duplicate dynamic call sites,
129 * or to issue “causeless” bootstrap method calls.
130 * Every dynamic call site transitions at most once from unlinked to linked,
131 * just before its first invocation.
132 * There is no way to undo the effect of a completed bootstrap method call.
134 * <h2>types of bootstrap methods</h2>
135 * As long as each bootstrap method can be correctly invoked
136 * by {@code MethodHandle.invoke}, its detailed type is arbitrary.
137 * For example, the first argument could be {@code Object}
138 * instead of {@code MethodHandles.Lookup}, and the return type
139 * could also be {@code Object} instead of {@code CallSite}.
140 * (Note that the types and number of the stacked arguments limit
141 * the legal kinds of bootstrap methods to appropriately typed
142 * static methods and constructors of {@code CallSite} subclasses.)
144 * If a given {@code invokedynamic} instruction specifies no static arguments,
145 * the instruction's bootstrap method will be invoked on three arguments,
146 * conveying the instruction's caller class, name, and method type.
147 * If the {@code invokedynamic} instruction specifies one or more static arguments,
148 * those values will be passed as additional arguments to the method handle.
149 * (Note that because there is a limit of 255 arguments to any method,
150 * at most 251 extra arguments can be supplied, since the bootstrap method
151 * handle itself and its first three arguments must also be stacked.)
152 * The bootstrap method will be invoked as if by either {@code MethodHandle.invoke}
153 * or {@code invokeWithArguments}. (There is no way to tell the difference.)
155 * The normal argument conversion rules for {@code MethodHandle.invoke} apply to all stacked arguments.
156 * For example, if a pushed value is a primitive type, it may be converted to a reference by boxing conversion.
157 * If the bootstrap method is a variable arity method (its modifier bit {@code 0x0080} is set),
158 * then some or all of the arguments specified here may be collected into a trailing array parameter.
159 * (This is not a special rule, but rather a useful consequence of the interaction
160 * between {@code CONSTANT_MethodHandle} constants, the modifier bit for variable arity methods,
161 * and the {@link java.lang.invoke.MethodHandle#asVarargsCollector asVarargsCollector} transformation.)
163 * Given these rules, here are examples of legal bootstrap method declarations,
164 * given various numbers {@code N} of extra arguments.
165 * The first rows (marked {@code *}) will work for any number of extra arguments.
166 * <table border=1 cellpadding=5 summary="Static argument types">
167 * <tr><th>N</th><th>sample bootstrap method</th></tr>
168 * <tr><td>*</td><td><code>CallSite bootstrap(Lookup caller, String name, MethodType type, Object... args)</code></td></tr>
169 * <tr><td>*</td><td><code>CallSite bootstrap(Object... args)</code></td></tr>
170 * <tr><td>*</td><td><code>CallSite bootstrap(Object caller, Object... nameAndTypeWithArgs)</code></td></tr>
171 * <tr><td>0</td><td><code>CallSite bootstrap(Lookup caller, String name, MethodType type)</code></td></tr>
172 * <tr><td>0</td><td><code>CallSite bootstrap(Lookup caller, Object... nameAndType)</code></td></tr>
173 * <tr><td>1</td><td><code>CallSite bootstrap(Lookup caller, String name, MethodType type, Object arg)</code></td></tr>
174 * <tr><td>2</td><td><code>CallSite bootstrap(Lookup caller, String name, MethodType type, Object... args)</code></td></tr>
175 * <tr><td>2</td><td><code>CallSite bootstrap(Lookup caller, String name, MethodType type, String... args)</code></td></tr>
176 * <tr><td>2</td><td><code>CallSite bootstrap(Lookup caller, String name, MethodType type, String x, int y)</code></td></tr>
178 * The last example assumes that the extra arguments are of type
179 * {@code CONSTANT_String} and {@code CONSTANT_Integer}, respectively.
180 * The second-to-last example assumes that all extra arguments are of type
181 * {@code CONSTANT_String}.
182 * The other examples work with all types of extra arguments.
184 * As noted above, the actual method type of the bootstrap method can vary.
185 * For example, the fourth argument could be {@code MethodHandle},
186 * if that is the type of the corresponding constant in
187 * the {@code CONSTANT_InvokeDynamic} entry.
188 * In that case, the {@code MethodHandle.invoke} call will pass the extra method handle
189 * constant as an {@code Object}, but the type matching machinery of {@code MethodHandle.invoke}
190 * will cast the reference back to {@code MethodHandle} before invoking the bootstrap method.
191 * (If a string constant were passed instead, by badly generated code, that cast would then fail,
192 * resulting in a {@code BootstrapMethodError}.)
194 * Note that, as a consequence of the above rules, the bootstrap method may accept a primitive
195 * argument, if it can be represented by a constant pool entry.
196 * However, arguments of type {@code boolean}, {@code byte}, {@code short}, or {@code char}
197 * cannot be created for bootstrap methods, since such constants cannot be directly
198 * represented in the constant pool, and the invocation of the bootstrap method will
199 * not perform the necessary narrowing primitive conversions.
201 * Extra bootstrap method arguments are intended to allow language implementors
202 * to safely and compactly encode metadata.
203 * In principle, the name and extra arguments are redundant,
204 * since each call site could be given its own unique bootstrap method.
205 * Such a practice is likely to produce large class files and constant pools.
207 * @author John Rose, JSR 292 EG
211 package java.lang.invoke;