--- a/nashorn/.hgtags Wed Jul 05 22:39:46 2017 +0200
+++ b/nashorn/.hgtags Wed Jul 05 22:39:56 2017 +0200
@@ -384,3 +384,4 @@
0a4bc2f049132ddc20985565bb41b2be8a458dda jdk-9+148
c281306d33d83c92e0d870ace385d5f99678d7e7 jdk-9+149
ace1d994bca775d6545a4c874ae73d1dfc9ec18b jdk-9+150
+2a0437036a64853334e538044eb68d2df70075fa jdk-9+151
--- a/nashorn/README Wed Jul 05 22:39:46 2017 +0200
+++ b/nashorn/README Wed Jul 05 22:39:56 2017 +0200
@@ -24,33 +24,33 @@
You can clone Nashorn Mercurial forest using this command:
- hg fclone http://hg.openjdk.java.net/nashorn/jdk8 nashorn~jdk8
+ hg fclone http://hg.openjdk.java.net/nashorn/jdk9 nashorn~jdk9
To update your copy of the forest (fwith the latest code:
- (cd nashorn~jdk8 ; hg fpull)
+ (cd nashorn~jdk9 ; hg fpull)
Or just the nashorn subdirectory with
- (cd nashorn~jdk8/nashorn ; hg pull -u)
+ (cd nashorn~jdk9/nashorn ; hg pull -u)
To learn about Mercurial in detail, please visit http://hgbook.red-bean.com.
- How to build?
-To build Nashorn, you need to install JDK 8. You may use the Nashorn
+To build Nashorn, you need to install JDK 9. You may use the Nashorn
forest build (recommended) or down load from java.net. You will need to
set JAVA_HOME environmental variable to point to your JDK installation
directory.
- cd nashorn~jdk8/nashorn/make
+ cd nashorn~jdk9/nashorn/make
ant clean; ant
- How to run?
Use the jjs script (see RELESE_README):
- cd nashorn~jdk8/nashorn
+ cd nashorn~jdk9/nashorn
sh bin/jjs <your .js file>
Nashorn supports javax.script API. It is possible to drop nashorn.jar in
@@ -64,7 +64,7 @@
Comprehensive development documentation is found in the Nashorn JavaDoc. You can
build it using:
- cd nashorn~jdk8/nashorn/make
+ cd nashorn~jdk9/nashorn/make
ant javadoc
after which you can view the generated documentation at dist/javadoc/index.html.
@@ -90,7 +90,7 @@
test/script/external/test262 a symbolic link to that directory. After
you've done this, you can run the ECMA-262 tests using:
- cd nashorn~jdk8/nashorn/make
+ cd nashorn~jdk9/nashorn/make
ant test262
Ant target to get/update external test suites:
@@ -101,7 +101,7 @@
These tests take time, so we have a parallelized runner for them that
takes advantage of all processor cores on the computer:
- cd nashorn~jdk8/nashorn/make
+ cd nashorn~jdk9/nashorn/make
ant test262parallel
- How to write your own test?
--- a/nashorn/RELEASE_README Wed Jul 05 22:39:46 2017 +0200
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,20 +0,0 @@
-The Nashorn repo is in the process of being migrated to OpenJDK and as such is
-incomplete in several areas.
-
-- The build system is not fully integrated. When complete, Nashorn will be
-installed in its proper location in the JRE.
-
-- Once integrated, the correct version of the JDK will be wrapped around
-Nashorn. In the meantime, ensure you use JDK8 b68 or later.
-
-- The jjs tool has not been implemented in binary form yet. Use "sh bin/jjs"
-(or bin/jjs.bat on windows) in the interm.
-
-- The Dynalink component is not fully integrated into Nashorn as yet, but will
-be when details are finalized.
-
-- And, finally Nashorn is still in development. To stay up to date, subscribe
-to nashorn-dev@openjdk.java.net at
-
- http://mail.openjdk.java.net/mailman/listinfo/nashorn-dev.
-
--- a/nashorn/make/build.xml Wed Jul 05 22:39:46 2017 +0200
+++ b/nashorn/make/build.xml Wed Jul 05 22:39:56 2017 +0200
@@ -267,7 +267,7 @@
<!-- generate javadoc for Nashorn classes -->
<target name="javadoc" depends="jar">
- <javadoc destdir="${dist.javadoc.dir}" use="yes" overview="${nashorn.module.src.dir}/overview.html"
+ <javadoc destdir="${dist.javadoc.dir}" use="yes"
windowtitle="${nashorn.product.name} ${nashorn.version}"
additionalparam="-quiet" failonerror="true" useexternalfile="true">
<arg value="--module-source-path"/>
@@ -285,7 +285,7 @@
<!-- generate javadoc only for nashorn extension api classes -->
<target name="nashornapi" depends="jar">
<mkdir dir="${dist.nashornapi.javadoc.dir}"/>
- <javadoc destdir="${dist.nashornapi.javadoc.dir}" use="yes" overview="${nashorn.module.src.dir}/overview.html"
+ <javadoc destdir="${dist.nashornapi.javadoc.dir}" use="yes"
extdirs="${nashorn.ext.path}" windowtitle="${nashorn.product.name} ${nashorn.version}"
additionalparam="-quiet" failonerror="true" useexternalfile="true">
<arg value="--module-source-path"/>
--- a/nashorn/src/jdk.dynalink/share/classes/jdk/dynalink/package-info.java Wed Jul 05 22:39:46 2017 +0200
+++ b/nashorn/src/jdk.dynalink/share/classes/jdk/dynalink/package-info.java Wed Jul 05 22:39:56 2017 +0200
@@ -82,197 +82,6 @@
*/
/**
- * <p>
- * Dynalink is a library for dynamic linking of high-level operations on objects.
- * These operations include "read a property",
- * "write a property", "invoke a function" and so on. Dynalink is primarily
- * useful for implementing programming languages where at least some expressions
- * have dynamic types (that is, types that can not be decided statically), and
- * the operations on dynamic types are expressed as
- * {@link java.lang.invoke.CallSite call sites}. These call sites will be
- * linked to appropriate target {@link java.lang.invoke.MethodHandle method handles}
- * at run time based on actual types of the values the expressions evaluated to.
- * These can change between invocations, necessitating relinking the call site
- * multiple times to accommodate new types; Dynalink handles all that and more.
- * <p>
- * Dynalink supports implementation of programming languages with object models
- * that differ (even radically) from the JVM's class-based model and have their
- * custom type conversions.
- * <p>
- * Dynalink is closely related to, and relies on, the {@link java.lang.invoke}
- * package.
- * <p>
- *
- * While {@link java.lang.invoke} provides a low level API for dynamic linking
- * of {@code invokedynamic} call sites, it does not provide a way to express
- * higher level operations on objects, nor methods that implement them. These
- * operations are the usual ones in object-oriented environments: property
- * access, access of elements of collections, invocation of methods and
- * constructors (potentially with multiple dispatch, e.g. link- and run-time
- * equivalents of Java overloaded method resolution). These are all functions
- * that are normally desired in a language on the JVM. If a language is
- * statically typed and its type system matches that of the JVM, it can
- * accomplish this with use of the usual invocation, field access, etc.
- * instructions (e.g. {@code invokevirtual}, {@code getfield}). However, if the
- * language is dynamic (hence, types of some expressions are not known until
- * evaluated at run time), or its object model or type system don't match
- * closely that of the JVM, then it should use {@code invokedynamic} call sites
- * instead and let Dynalink manage them.
- * <h2>Example</h2>
- * Dynalink is probably best explained by an example showing its use. Let's
- * suppose you have a program in a language where you don't have to declare the
- * type of an object and you want to access a property on it:
- * <pre>
- * var color = obj.color;
- * </pre>
- * If you generated a Java class to represent the above one-line program, its
- * bytecode would look something like this:
- * <pre>
- * aload 2 // load "obj" on stack
- * invokedynamic "GET:PROPERTY:color"(Object)Object // invoke property getter on object of unknown type
- * astore 3 // store the return value into local variable "color"
- * </pre>
- * In order to link the {@code invokedynamic} instruction, we need a bootstrap
- * method. A minimalist bootstrap method with Dynalink could look like this:
- * <pre>
- * import java.lang.invoke.*;
- * import jdk.dynalink.*;
- * import jdk.dynalink.support.*;
- *
- * class MyLanguageRuntime {
- * private static final DynamicLinker dynamicLinker = new DynamicLinkerFactory().createLinker();
- *
- * public static CallSite bootstrap(MethodHandles.Lookup lookup, String name, MethodType type) {
- * return dynamicLinker.link(
- * new SimpleRelinkableCallSite(
- * new CallSiteDescriptor(lookup, parseOperation(name), type)));
- * }
- *
- * private static Operation parseOperation(String name) {
- * ...
- * }
- * }
- * </pre>
- * There are several objects of significance in the above code snippet:
- * <ul>
- * <li>{@link jdk.dynalink.DynamicLinker} is the main object in Dynalink, it
- * coordinates the linking of call sites to method handles that implement the
- * operations named in them. It is configured and created using a
- * {@link jdk.dynalink.DynamicLinkerFactory}.</li>
- * <li>When the bootstrap method is invoked, it needs to create a
- * {@link java.lang.invoke.CallSite} object. In Dynalink, these call sites need
- * to additionally implement the {@link jdk.dynalink.RelinkableCallSite}
- * interface. "Relinkable" here alludes to the fact that if the call site
- * encounters objects of different types at run time, its target will be changed
- * to a method handle that can perform the operation on the newly encountered
- * type. {@link jdk.dynalink.support.SimpleRelinkableCallSite} and
- * {@link jdk.dynalink.support.ChainedCallSite} (not used in the above example)
- * are two implementations already provided by the library.</li>
- * <li>Dynalink uses {@link jdk.dynalink.CallSiteDescriptor} objects to
- * preserve the parameters to the bootstrap method: the lookup and the method type,
- * as it will need them whenever it needs to relink a call site.</li>
- * <li>Dynalink uses {@link jdk.dynalink.Operation} objects to express
- * dynamic operations. It does not prescribe how would you encode the operations
- * in your call site, though. That is why in the above example the
- * {@code parseOperation} function is left empty, and you would be expected to
- * provide the code to parse the string {@code "GET:PROPERTY:color"}
- * in the call site's name into a named property getter operation object as
- * {@code StandardOperation.GET.withNamespace(StandardNamespace.PROPERTY).named("color")}.
- * </ul>
- * <p>What can you already do with the above setup? {@code DynamicLinkerFactory}
- * by default creates a {@code DynamicLinker} that can link Java objects with the
- * usual Java semantics. If you have these three simple classes:
- * <pre>
- * public class A {
- * public String color;
- * public A(String color) { this.color = color; }
- * }
- *
- * public class B {
- * private String color;
- * public B(String color) { this.color = color; }
- * public String getColor() { return color; }
- * }
- *
- * public class C {
- * private int color;
- * public C(int color) { this.color = color; }
- * public int getColor() { return color; }
- * }
- * </pre>
- * and you somehow create their instances and pass them to your call site in your
- * programming language:
- * <pre>
- * for each(var obj in [new A("red"), new B("green"), new C(0x0000ff)]) {
- * print(obj.color);
- * }
- * </pre>
- * then on first invocation, Dynalink will link the {@code .color} getter
- * operation to a field getter for {@code A.color}, on second invocation it will
- * relink it to {@code B.getColor()} returning a {@code String}, and finally on
- * third invocation it will relink it to {@code C.getColor()} returning an {@code int}.
- * The {@code SimpleRelinkableCallSite} we used above only remembers the linkage
- * for the last encountered type (it implements what is known as a <i>monomorphic
- * inline cache</i>). Another already provided implementation,
- * {@link jdk.dynalink.support.ChainedCallSite} will remember linkages for
- * several different types (it is a <i>polymorphic inline cache</i>) and is
- * probably a better choice in serious applications.
- * <h2>Dynalink and bytecode creation</h2>
- * {@code CallSite} objects are usually created as part of bootstrapping
- * {@code invokedynamic} instructions in bytecode. Hence, Dynalink is typically
- * used as part of language runtimes that compile programs into Java
- * {@code .class} bytecode format. Dynalink does not address the aspects of
- * either creating bytecode classes or loading them into the JVM. That said,
- * Dynalink can also be used without bytecode compilation (e.g. in language
- * interpreters) by creating {@code CallSite} objects explicitly and associating
- * them with representations of dynamic operations in the interpreted program
- * (e.g. a typical representation would be some node objects in a syntax tree).
- * <h2>Available operations</h2>
- * Dynalink defines several standard operations in its
- * {@link jdk.dynalink.StandardOperation} class. The linker for Java
- * objects can link all of these operations, and you are encouraged to at
- * minimum support and use these operations in your language too. The
- * standard operations {@code GET} and {@code SET} need to be combined with
- * at least one {@link jdk.dynalink.Namespace} to be useful, e.g. to express a
- * property getter, you'd use {@code StandardOperation.GET.withNamespace(StandardNamespace.PROPERTY)}.
- * Dynalink defines three standard namespaces in the {@link jdk.dynalink.StandardNamespace} class.
- * To associate a fixed name with an operation, you can use
- * {@link jdk.dynalink.NamedOperation} as in the previous example:
- * {@code StandardOperation.GET.withNamespace(StandardNamespace.PROPERTY).named("color")}
- * expresses a getter for the property named "color".
- * <h2>Operations on multiple namespaces</h2>
- * Some languages might not have separate namespaces on objects for
- * properties, elements, and methods, and a source language construct might
- * address several of them at once. Dynalink supports specifying multiple
- * {@link jdk.dynalink.Namespace} objects with {@link jdk.dynalink.NamespaceOperation}.
- * <h2>Language-specific linkers</h2>
- * Languages that define their own object model different than the JVM
- * class-based model and/or use their own type conversions will need to create
- * their own language-specific linkers. See the {@link jdk.dynalink.linker}
- * package and specifically the {@link jdk.dynalink.linker.GuardingDynamicLinker}
- * interface to get started.
- * <h2>Dynalink and Java objects</h2>
- * The {@code DynamicLinker} objects created by {@code DynamicLinkerFactory} by
- * default contain an internal instance of
- * {@code BeansLinker}, which is a language-specific linker
- * that implements the usual Java semantics for all of the above operations and
- * can link any Java object that no other language-specific linker has managed
- * to link. This way, all language runtimes have built-in interoperability with
- * ordinary Java objects. See {@link jdk.dynalink.beans.BeansLinker} for details
- * on how it links the various operations.
- * <h2>Cross-language interoperability</h2>
- * A {@code DynamicLinkerFactory} can be configured with a
- * {@link jdk.dynalink.DynamicLinkerFactory#setClassLoader(ClassLoader) class
- * loader}. It will try to instantiate all
- * {@link jdk.dynalink.linker.GuardingDynamicLinkerExporter} classes visible to
- * that class loader and compose the linkers they provide into the
- * {@code DynamicLinker} it creates. This allows for interoperability between
- * languages: if you have two language runtimes A and B deployed in your JVM and
- * they export their linkers through the above mechanism, language runtime A
- * will have a language-specific linker instance from B and vice versa inside
- * their {@code DynamicLinker} objects. This means that if an object from
- * language runtime B gets passed to code from language runtime A, the linker
- * from B will get a chance to link the call site in A when it encounters the
- * object from B.
+ * Contains interfaces and classes that are used to link an {@code invokedynamic} call site.
*/
package jdk.dynalink;
--- a/nashorn/src/jdk.dynalink/share/classes/module-info.java Wed Jul 05 22:39:46 2017 +0200
+++ b/nashorn/src/jdk.dynalink/share/classes/module-info.java Wed Jul 05 22:39:56 2017 +0200
@@ -24,7 +24,198 @@
*/
/**
- * Dynalink
+ * <p>
+ * Dynalink is a library for dynamic linking of high-level operations on objects.
+ * These operations include "read a property",
+ * "write a property", "invoke a function" and so on. Dynalink is primarily
+ * useful for implementing programming languages where at least some expressions
+ * have dynamic types (that is, types that can not be decided statically), and
+ * the operations on dynamic types are expressed as
+ * {@link java.lang.invoke.CallSite call sites}. These call sites will be
+ * linked to appropriate target {@link java.lang.invoke.MethodHandle method handles}
+ * at run time based on actual types of the values the expressions evaluated to.
+ * These can change between invocations, necessitating relinking the call site
+ * multiple times to accommodate new types; Dynalink handles all that and more.
+ * <p>
+ * Dynalink supports implementation of programming languages with object models
+ * that differ (even radically) from the JVM's class-based model and have their
+ * custom type conversions.
+ * <p>
+ * Dynalink is closely related to, and relies on, the {@link java.lang.invoke}
+ * package.
+ * <p>
+ *
+ * While {@link java.lang.invoke} provides a low level API for dynamic linking
+ * of {@code invokedynamic} call sites, it does not provide a way to express
+ * higher level operations on objects, nor methods that implement them. These
+ * operations are the usual ones in object-oriented environments: property
+ * access, access of elements of collections, invocation of methods and
+ * constructors (potentially with multiple dispatch, e.g. link- and run-time
+ * equivalents of Java overloaded method resolution). These are all functions
+ * that are normally desired in a language on the JVM. If a language is
+ * statically typed and its type system matches that of the JVM, it can
+ * accomplish this with use of the usual invocation, field access, etc.
+ * instructions (e.g. {@code invokevirtual}, {@code getfield}). However, if the
+ * language is dynamic (hence, types of some expressions are not known until
+ * evaluated at run time), or its object model or type system don't match
+ * closely that of the JVM, then it should use {@code invokedynamic} call sites
+ * instead and let Dynalink manage them.
+ * <h2>Example</h2>
+ * Dynalink is probably best explained by an example showing its use. Let's
+ * suppose you have a program in a language where you don't have to declare the
+ * type of an object and you want to access a property on it:
+ * <pre>
+ * var color = obj.color;
+ * </pre>
+ * If you generated a Java class to represent the above one-line program, its
+ * bytecode would look something like this:
+ * <pre>
+ * aload 2 // load "obj" on stack
+ * invokedynamic "GET:PROPERTY:color"(Object)Object // invoke property getter on object of unknown type
+ * astore 3 // store the return value into local variable "color"
+ * </pre>
+ * In order to link the {@code invokedynamic} instruction, we need a bootstrap
+ * method. A minimalist bootstrap method with Dynalink could look like this:
+ * <pre>
+ * import java.lang.invoke.*;
+ * import jdk.dynalink.*;
+ * import jdk.dynalink.support.*;
+ *
+ * class MyLanguageRuntime {
+ * private static final DynamicLinker dynamicLinker = new DynamicLinkerFactory().createLinker();
+ *
+ * public static CallSite bootstrap(MethodHandles.Lookup lookup, String name, MethodType type) {
+ * return dynamicLinker.link(
+ * new SimpleRelinkableCallSite(
+ * new CallSiteDescriptor(lookup, parseOperation(name), type)));
+ * }
+ *
+ * private static Operation parseOperation(String name) {
+ * ...
+ * }
+ * }
+ * </pre>
+ * There are several objects of significance in the above code snippet:
+ * <ul>
+ * <li>{@link jdk.dynalink.DynamicLinker} is the main object in Dynalink, it
+ * coordinates the linking of call sites to method handles that implement the
+ * operations named in them. It is configured and created using a
+ * {@link jdk.dynalink.DynamicLinkerFactory}.</li>
+ * <li>When the bootstrap method is invoked, it needs to create a
+ * {@link java.lang.invoke.CallSite} object. In Dynalink, these call sites need
+ * to additionally implement the {@link jdk.dynalink.RelinkableCallSite}
+ * interface. "Relinkable" here alludes to the fact that if the call site
+ * encounters objects of different types at run time, its target will be changed
+ * to a method handle that can perform the operation on the newly encountered
+ * type. {@link jdk.dynalink.support.SimpleRelinkableCallSite} and
+ * {@link jdk.dynalink.support.ChainedCallSite} (not used in the above example)
+ * are two implementations already provided by the library.</li>
+ * <li>Dynalink uses {@link jdk.dynalink.CallSiteDescriptor} objects to
+ * preserve the parameters to the bootstrap method: the lookup and the method type,
+ * as it will need them whenever it needs to relink a call site.</li>
+ * <li>Dynalink uses {@link jdk.dynalink.Operation} objects to express
+ * dynamic operations. It does not prescribe how would you encode the operations
+ * in your call site, though. That is why in the above example the
+ * {@code parseOperation} function is left empty, and you would be expected to
+ * provide the code to parse the string {@code "GET:PROPERTY:color"}
+ * in the call site's name into a named property getter operation object as
+ * {@code StandardOperation.GET.withNamespace(StandardNamespace.PROPERTY).named("color")}.
+ * </ul>
+ * <p>What can you already do with the above setup? {@code DynamicLinkerFactory}
+ * by default creates a {@code DynamicLinker} that can link Java objects with the
+ * usual Java semantics. If you have these three simple classes:
+ * <pre>
+ * public class A {
+ * public String color;
+ * public A(String color) { this.color = color; }
+ * }
+ *
+ * public class B {
+ * private String color;
+ * public B(String color) { this.color = color; }
+ * public String getColor() { return color; }
+ * }
+ *
+ * public class C {
+ * private int color;
+ * public C(int color) { this.color = color; }
+ * public int getColor() { return color; }
+ * }
+ * </pre>
+ * and you somehow create their instances and pass them to your call site in your
+ * programming language:
+ * <pre>
+ * for each(var obj in [new A("red"), new B("green"), new C(0x0000ff)]) {
+ * print(obj.color);
+ * }
+ * </pre>
+ * then on first invocation, Dynalink will link the {@code .color} getter
+ * operation to a field getter for {@code A.color}, on second invocation it will
+ * relink it to {@code B.getColor()} returning a {@code String}, and finally on
+ * third invocation it will relink it to {@code C.getColor()} returning an {@code int}.
+ * The {@code SimpleRelinkableCallSite} we used above only remembers the linkage
+ * for the last encountered type (it implements what is known as a <i>monomorphic
+ * inline cache</i>). Another already provided implementation,
+ * {@link jdk.dynalink.support.ChainedCallSite} will remember linkages for
+ * several different types (it is a <i>polymorphic inline cache</i>) and is
+ * probably a better choice in serious applications.
+ * <h2>Dynalink and bytecode creation</h2>
+ * {@code CallSite} objects are usually created as part of bootstrapping
+ * {@code invokedynamic} instructions in bytecode. Hence, Dynalink is typically
+ * used as part of language runtimes that compile programs into Java
+ * {@code .class} bytecode format. Dynalink does not address the aspects of
+ * either creating bytecode classes or loading them into the JVM. That said,
+ * Dynalink can also be used without bytecode compilation (e.g. in language
+ * interpreters) by creating {@code CallSite} objects explicitly and associating
+ * them with representations of dynamic operations in the interpreted program
+ * (e.g. a typical representation would be some node objects in a syntax tree).
+ * <h2>Available operations</h2>
+ * Dynalink defines several standard operations in its
+ * {@link jdk.dynalink.StandardOperation} class. The linker for Java
+ * objects can link all of these operations, and you are encouraged to at
+ * minimum support and use these operations in your language too. The
+ * standard operations {@code GET} and {@code SET} need to be combined with
+ * at least one {@link jdk.dynalink.Namespace} to be useful, e.g. to express a
+ * property getter, you'd use {@code StandardOperation.GET.withNamespace(StandardNamespace.PROPERTY)}.
+ * Dynalink defines three standard namespaces in the {@link jdk.dynalink.StandardNamespace} class.
+ * To associate a fixed name with an operation, you can use
+ * {@link jdk.dynalink.NamedOperation} as in the previous example:
+ * {@code StandardOperation.GET.withNamespace(StandardNamespace.PROPERTY).named("color")}
+ * expresses a getter for the property named "color".
+ * <h2>Operations on multiple namespaces</h2>
+ * Some languages might not have separate namespaces on objects for
+ * properties, elements, and methods, and a source language construct might
+ * address several of them at once. Dynalink supports specifying multiple
+ * {@link jdk.dynalink.Namespace} objects with {@link jdk.dynalink.NamespaceOperation}.
+ * <h2>Language-specific linkers</h2>
+ * Languages that define their own object model different than the JVM
+ * class-based model and/or use their own type conversions will need to create
+ * their own language-specific linkers. See the {@link jdk.dynalink.linker}
+ * package and specifically the {@link jdk.dynalink.linker.GuardingDynamicLinker}
+ * interface to get started.
+ * <h2>Dynalink and Java objects</h2>
+ * The {@code DynamicLinker} objects created by {@code DynamicLinkerFactory} by
+ * default contain an internal instance of
+ * {@code BeansLinker}, which is a language-specific linker
+ * that implements the usual Java semantics for all of the above operations and
+ * can link any Java object that no other language-specific linker has managed
+ * to link. This way, all language runtimes have built-in interoperability with
+ * ordinary Java objects. See {@link jdk.dynalink.beans.BeansLinker} for details
+ * on how it links the various operations.
+ * <h2>Cross-language interoperability</h2>
+ * A {@code DynamicLinkerFactory} can be configured with a
+ * {@link jdk.dynalink.DynamicLinkerFactory#setClassLoader(ClassLoader) class
+ * loader}. It will try to instantiate all
+ * {@link jdk.dynalink.linker.GuardingDynamicLinkerExporter} classes visible to
+ * that class loader and compose the linkers they provide into the
+ * {@code DynamicLinker} it creates. This allows for interoperability between
+ * languages: if you have two language runtimes A and B deployed in your JVM and
+ * they export their linkers through the above mechanism, language runtime A
+ * will have a language-specific linker instance from B and vice versa inside
+ * their {@code DynamicLinker} objects. This means that if an object from
+ * language runtime B gets passed to code from language runtime A, the linker
+ * from B will get a chance to link the call site in A when it encounters the
+ * object from B.
*/
module jdk.dynalink {
requires java.logging;
--- a/nashorn/src/jdk.scripting.nashorn/share/classes/module-info.java Wed Jul 05 22:39:46 2017 +0200
+++ b/nashorn/src/jdk.scripting.nashorn/share/classes/module-info.java Wed Jul 05 22:39:56 2017 +0200
@@ -24,7 +24,71 @@
*/
/**
- * Nashorn
+<p>
+Nashorn is a runtime environment for programs written in ECMAScript 5.1.
+</p>
+<h1>Usage</h1>
+The recommended way to use Nashorn is through the <a href="http://jcp.org/en/jsr/detail?id=223" target="_top">JSR-223
+"Scripting for the Java Platform"</a> APIs found in the {@link javax.script} package. Usually, you'll obtain a
+{@link javax.script.ScriptEngine} instance for Nashorn using:
+<pre>
+import javax.script.*;
+...
+ScriptEngine nashornEngine = new ScriptEngineManager().getEngineByName("nashorn");
+</pre>
+and then use it just as you would any other JSR-223 script engine. See
+<a href="jdk/nashorn/api/scripting/package-summary.html">{@code jdk.nashorn.api.scripting}</a> package
+for details.
+<h1>Compatibility</h1>
+Nashorn is 100% compliant with the <a href="http://www.ecma-international.org/publications/standards/Ecma-262.htm"
+target="_top">ECMA-262 Standard, Edition 5.1</a>. It requires a Java Virtual Machine that implements the
+<a href="http://jcp.org/en/jsr/detail?id=292" target="_top">JSR-292 "Supporting Dynamically Typed Languages on the Java
+Platform"</a> specification (often referred to as "invokedynamic"), as well as the already mentioned JSR-223.
+<h1>Interoperability with the Java platform</h1>
+In addition to being a 100% ECMAScript 5.1 runtime, Nashorn provides features for interoperability of the ECMAScript
+programs with the Java platform. In general, any Java object put into the script engine's context will be visible from
+the script. In terms of the standard, such Java objects are not considered "native objects", but rather "host objects",
+as defined in section 4.3.8. This distinction allows certain semantical differences in handling them compared to native
+objects. For most purposes, Java objects behave just as native objects do: you can invoke their methods, get and set
+their properties. In most cases, though, you can't add arbitrary properties to them, nor can you remove existing
+properties.
+<h2>Java collection handling</h2>
+Native Java arrays and {@link java.util.List}s support indexed access to their elements through the property accessors,
+and {@link java.util.Map}s support both property and element access through both dot and square-bracket property
+accessors, with the difference being that dot operator gives precedence to object properties (its fields and properties
+defined as {@code getXxx} and {@code setXxx} methods) while the square bracket operator gives precedence to map
+elements. Native Java arrays expose the {@code length} property.
+<h2>ECMAScript primitive types</h2>
+ECMAScript primitive types for number, string, and boolean are represented with {@link java.lang.Number},
+{@link java.lang.CharSequence}, and {@link java.lang.Boolean} objects. While the most often used number type is
+{@link java.lang.Double} and the most often used string type is {@link java.lang.String}, don't rely on it as various
+internal optimizations cause other subclasses of {@code Number} and internal implementations of {@code CharSequence} to
+be used.
+<h2>Type conversions</h2>
+When a method on a Java object is invoked, the arguments are converted to the formal parameter types of the Java method
+using all allowed ECMAScript conversions. This can be surprising, as in general, conversions from string to number will
+succeed according to Standard's section 9.3 "ToNumber" and so on; string to boolean, number to boolean, Object to
+number, Object to string all work. Note that if the Java method's declared parameter type is {@code java.lang.Object},
+Nashorn objects are passed without any conversion whatsoever; specifically if the JavaScript value being passed is of
+primitive string type, you can only rely on it being a {@code java.lang.CharSequence}, and if the value is a number, you
+can only rely on it being a {@code java.lang.Number}. If the Java method declared parameter type is more specific (e.g.
+{@code java.lang.String} or {@code java.lang.Double}), then Nashorn will of course ensure the required type is passed.
+<h2>SAM types</h2>
+As a special extension when invoking Java methods, ECMAScript function objects can be passed in place of an argument
+whose Java type is so-called "single abstract method" or "SAM" type. While this name usually covers single-method
+interfaces, Nashorn is a bit more versatile, and it recognizes a type as a SAM type if all its abstract methods are
+overloads of the same name, and it is either an interface, or it is an abstract class with
+a no-arg constructor. The type itself must be public, while the constructor and the methods can be either public or
+protected. If there are multiple abstract overloads of the same name, the single function will serve as the shared
+implementation for all of them, <em>and additionally it will also override any non-abstract methods of the same name</em>.
+This is done to be consistent with the fact that ECMAScript does not have the concept of overloaded methods.
+<h2>The {@code Java} object</h2>
+Nashorn exposes a non-standard global object named {@code Java} that is the primary API entry point into Java
+platform-specific functionality. You can use it to create instances of Java classes, convert from Java arrays to native
+arrays and back, and so on.
+<h2>Other non-standard built-in objects</h2>
+In addition to {@code Java}, Nashorn also exposes some other non-standard built-in objects:
+{@code JSAdapter}, {@code JavaImporter}, {@code Packages}
*/
module jdk.scripting.nashorn {
requires java.logging;
@@ -47,4 +111,3 @@
provides jdk.dynalink.linker.GuardingDynamicLinkerExporter
with jdk.nashorn.api.linker.NashornLinkerExporter;
}
-
--- a/nashorn/src/jdk.scripting.nashorn/share/classes/overview.html Wed Jul 05 22:39:46 2017 +0200
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,113 +0,0 @@
-<!--
- Copyright (c) 2010, 2013, Oracle and/or its affiliates. All rights reserved.
- DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
-
- This code is free software; you can redistribute it and/or modify it
- under the terms of the GNU General Public License version 2 only, as
- published by the Free Software Foundation. Oracle designates this
- particular file as subject to the "Classpath" exception as provided
- by Oracle in the LICENSE file that accompanied this code.
-
- This code is distributed in the hope that it will be useful, but WITHOUT
- ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
- FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
- version 2 for more details (a copy is included in the LICENSE file that
- accompanied this code).
-
- You should have received a copy of the GNU General Public License version
- 2 along with this work; if not, write to the Free Software Foundation,
- Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
-
- Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
- or visit www.oracle.com if you need additional information or have any
- questions.
--->
-<body>
-<p>
-Nashorn is a runtime environment for programs written in ECMAScript 5.1.
-</p>
-<h1>Usage</h1>
-<p>
-The recommended way to use Nashorn is through the <a href="http://jcp.org/en/jsr/detail?id=223" target="_top">JSR-223
-"Scripting for the Java Platform"</a> APIs found in the {@link javax.script} package. Usually, you'll obtain a
-{@link javax.script.ScriptEngine} instance for Nashorn using:
-<pre>
-import javax.script.*;
-...
-ScriptEngine nashornEngine = new ScriptEngineManager().getEngineByName("nashorn");
-</pre>
-and then use it just as you would any other JSR-223 script engine. See
-<a href="jdk/nashorn/api/scripting/package-summary.html">{@code jdk.nashorn.api.scripting}</a> package
-for details.
-<p>
-<h1>Compatibility</h1>
-Nashorn is 100% compliant with the <a href="http://www.ecma-international.org/publications/standards/Ecma-262.htm"
-target="_top">ECMA-262 Standard, Edition 5.1</a>. It requires a Java Virtual Machine that implements the
-<a href="http://jcp.org/en/jsr/detail?id=292" target="_top">JSR-292 "Supporting Dynamically Typed Languages on the Java
-Platform"</a> specification (often referred to as "invokedynamic"), as well as the already mentioned JSR-223.
-<h1>Interoperability with the Java platform</h1>
-<p>
-In addition to being a 100% ECMAScript 5.1 runtime, Nashorn provides features for interoperability of the ECMAScript
-programs with the Java platform. In general, any Java object put into the script engine's context will be visible from
-the script. In terms of the standard, such Java objects are not considered "native objects", but rather "host objects",
-as defined in section 4.3.8. This distinction allows certain semantical differences in handling them compared to native
-objects. For most purposes, Java objects behave just as native objects do: you can invoke their methods, get and set
-their properties. In most cases, though, you can't add arbitrary properties to them, nor can you remove existing
-properties.
-<p>
-<h2>Java collection handling</h2>
-<p>
-Native Java arrays and {@link java.util.List}s support indexed access to their elements through the property accessors,
-and {@link java.util.Map}s support both property and element access through both dot and square-bracket property
-accessors, with the difference being that dot operator gives precedence to object properties (its fields and properties
-defined as {@code getXxx} and {@code setXxx} methods) while the square bracket operator gives precedence to map
-elements. Native Java arrays expose the {@code length} property.
-<p>
-<h2>ECMAScript primitive types</h2>
-<p>
-ECMAScript primitive types for number, string, and boolean are represented with {@link java.lang.Number},
-{@link java.lang.CharSequence}, and {@link java.lang.Boolean} objects. While the most often used number type is
-{@link java.lang.Double} and the most often used string type is {@link java.lang.String}, don't rely on it as various
-internal optimizations cause other subclasses of {@code Number} and internal implementations of {@code CharSequence} to
-be used.
-<p>
-<h2>Type conversions</h2>
-<p>
-When a method on a Java object is invoked, the arguments are converted to the formal parameter types of the Java method
-using all allowed ECMAScript conversions. This can be surprising, as in general, conversions from string to number will
-succeed according to Standard's section 9.3 "ToNumber" and so on; string to boolean, number to boolean, Object to
-number, Object to string all work. Note that if the Java method's declared parameter type is {@code java.lang.Object},
-Nashorn objects are passed without any conversion whatsoever; specifically if the JavaScript value being passed is of
-primitive string type, you can only rely on it being a {@code java.lang.CharSequence}, and if the value is a number, you
-can only rely on it being a {@code java.lang.Number}. If the Java method declared parameter type is more specific (e.g.
-{@code java.lang.String} or {@code java.lang.Double}), then Nashorn will of course ensure the required type is passed.
-<p>
-<h2>SAM types</h2>
-<p>
-As a special extension when invoking Java methods, ECMAScript function objects can be passed in place of an argument
-whose Java type is so-called "single abstract method" or "SAM" type. While this name usually covers single-method
-interfaces, Nashorn is a bit more versatile, and it recognizes a type as a SAM type if all its abstract methods are
-overloads of the same name, and it is either an interface, or it is an abstract class with
-a no-arg constructor. The type itself must be public, while the constructor and the methods can be either public or
-protected. If there are multiple abstract overloads of the same name, the single function will serve as the shared
-implementation for all of them, <em>and additionally it will also override any non-abstract methods of the same name</em>.
-This is done to be consistent with the fact that ECMAScript does not have the concept of overloaded methods.
-<p>
-<h2>The {@code Java} object</h2>
-Nashorn exposes a non-standard global object named {@code Java} that is the primary API entry point into Java
-platform-specific functionality. You can use it to create instances of Java classes, convert from Java arrays to native
-arrays and back, and so on. The methods on the objects are directly implemented by public static methods on the class
-<a href="jdk/nashorn/internal/objects/NativeJava.html">{@code NativeJava}</a>, see that class for details on what
-functionality is available.
-<h2>Representations of Java types</h2>
-The method <a href="jdk/nashorn/internal/objects/NativeJava.html#type(java.lang.Object,%20java.lang.Object)">
-{@code Java.type(typeName)}</a> takes a name of a type, and returns an object representing a Java type. You can
-use that object to both create new instances of Java classes, as well as to access static fields and methods on them.
-The type object is distinct from the {@code java.lang.Class} object, which represents the reflective run-time type
-identity and doesn't carry i.e. static members. Again, see the link for {@code NativeJava} above for details.
-<h2>Other non-standard built-in objects</h2>
-In addition to {@code Java}, Nashorn also exposes some other non-standard built-in objects:
-<a href="jdk/nashorn/internal/objects/NativeJSAdapter.html">{@code JSAdapter}</a>,
-<a href="jdk/nashorn/internal/objects/NativeJavaImporter.html">{@code JavaImporter}</a>,
-<a href="jdk/nashorn/internal/runtime/NativeJavaPackage.html">{@code Packages}.</a>
-</body>