--- a/nashorn/src/jdk.scripting.nashorn/share/classes/module-info.java Thu Jun 08 16:32:57 2017 +0000
+++ b/nashorn/src/jdk.scripting.nashorn/share/classes/module-info.java Thu Jun 08 23:11:15 2017 +0000
@@ -24,74 +24,121 @@
*/
/**
-<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>
+ * Provides the implementation of Nashorn script engine and
+ * the runtime environment for programs written in ECMAScript 5.1.
+ * <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}
-
-@moduleGraph
-@since 9
+ *
+ * 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}
+ *
+ * @provides javax.script.ScriptEngineFactory
+ * @moduleGraph
+ * @since 9
*/
module jdk.scripting.nashorn {
requires java.logging;