JDK 11 jdk.rmic.jmod - RMI Compiler Tool

JDK 11 jdk.rmic.jmod is the JMOD file for JDK 11 RMI (Remote Method Invocation) Compiler Tool tool, which can be invoked by the "rmic" command.

JDK 11 RMI Compiler Tool tool compiled class files are stored in \fyicenter\jdk-11.0.1\jmods\jdk.rmic.jmod.

JDK 11 RMI Compiler Tool tool compiled class files are also linked and stored in the \fyicenter\jdk-11.0.1\lib\modules JImage file.

JDK 11 RMI Compiler Tool tool source code files are stored in \fyicenter\jdk-11.0.1\lib\src.zip\jdk.rmic.

You can click and view the content of each source code file in the list below.

✍: FYIcenter

sun/tools/tree/UplevelReference.java

/*
 * Copyright (c) 1997, 2003, Oracle and/or its affiliates. All rights reserved.
 * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms.
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 *
 */

package sun.tools.tree;

import sun.tools.java.*;
import sun.tools.tree.*;
import sun.tools.asm.Assembler;

/**
 * A reference from one scope to another.
 *
 * WARNING: The contents of this source file are not part of any
 * supported API.  Code that depends on them does so at its own risk:
 * they are subject to change or removal without notice.
 *
 */

public
class UplevelReference implements Constants {
    /**
     * The class in which the reference occurs.
     */
    ClassDefinition client;

    /**
     * The field being referenced.
     * It is always a final argument or a final local variable.
     * (An uplevel reference to a field of a class C is fetched
     * through an implicit uplevel reference to C.this, which is
     * an argument.)
     */
    LocalMember target;

    /**
     * The local variable which bears a copy of the target's value,
     * for all methods of the client class.
     * Its name is "this$C" for <code>this.C</code> or
     * "val$x" for other target variables <code>x</code>.
     * <p>
     * This local variable is always a constructor argument,
     * and is therefore usable only in the constructor and in initializers.
     * All other methods use the local field.
     * @see #localField
     */
    LocalMember localArgument;

    /**
     * A private synthetic field of the client class which
     * bears a copy of the target's value.
     * The compiler tries to avoid creating it if possible.
     * The field has the same name and type as the localArgument.
     * @see #localArgument
     */
    MemberDefinition localField;

    /**
     * The next item on the references list of the client.
     */
    UplevelReference next;

    /**
     * constructor
     */
    public UplevelReference(ClassDefinition client, LocalMember target) {
        this.client = client;
        this.target = target;

        // Choose a name and build a variable declaration node.
        Identifier valName;
        if (target.getName().equals(idThis)) {
            ClassDefinition tc = target.getClassDefinition();
            // It should always be true that tc.enclosingClassOf(client).
            // If it were false, the numbering scheme would fail
            // to produce unique names, since we'd be trying
            // to number classes which were not in the sequence
            // of enclosing scopes.  The next paragraph of this
            // code robustly deals with that possibility, however,
            // by detecting name collisions and perturbing the names.
            int depth = 0;
            for (ClassDefinition pd = tc; !pd.isTopLevel(); pd = pd.getOuterClass()) {
                // The inner classes specification states that the name of
                // a private field containing a reference to the outermost
                // enclosing instance is named "this$0".  That outermost
                // enclosing instance is always the innermost toplevel class.
                depth += 1;
            }
            // In this example, T1,T2,T3 are all top-level (static),
            // while I4,I5,I6,I7 are all inner.  Each of the inner classes
            // will have a single up-level "this$N" reference to the next
            // class out.  Only the outermost "this$0" will refer to a
            // top-level class, T3.
            //
            // class T1 {
            //  static class T2 {
            //   static class T3 {
            //    class I4 {
            //     class I5 {
            //      class I6 {
            //       // at this point we have these fields in various places:
            //       // I4 this$0; I5 this$1; I6 this$2;
            //      }
            //     }
            //     class I7 {
            //       // I4 this$0; I7 this$1;
            //     }
            //    }
            //   }
            //  }
            // }
            valName = Identifier.lookup(prefixThis + depth);
        } else {
            valName = Identifier.lookup(prefixVal + target.getName());
        }

        // Make reasonably certain that valName is unique to this client.
        // (This check can be fooled by malicious naming of explicit
        // constructor arguments, or of inherited fields.)
        Identifier base = valName;
        int tick = 0;
        while (true) {
            boolean failed = (client.getFirstMatch(valName) != null);
            for (UplevelReference r = client.getReferences();
                    r != null; r = r.next) {
                if (r.target.getName().equals(valName)) {
                    failed = true;
                }
            }
            if (!failed) {
                break;
            }
            // try another name
            valName = Identifier.lookup(base + "$" + (++tick));
        }

        // Build the constructor argument.
        // Like "this", it wil be shared equally by all constructors of client.
        localArgument = new LocalMember(target.getWhere(),
                                       client,
                                       M_FINAL | M_SYNTHETIC,
                                       target.getType(),
                                       valName);
    }

    /**
     * Insert self into a list of references.
     * Maintain "isEarlierThan" as an invariant of the list.
     * This is important (a) to maximize stability of signatures,
     * and (b) to allow uplevel "this" parameters to come at the
     * front of every argument list they appear in.
     */
    public UplevelReference insertInto(UplevelReference references) {
        if (references == null || isEarlierThan(references)) {
            next = references;
            return this;
        } else {
            UplevelReference prev = references;
            while (!(prev.next == null || isEarlierThan(prev.next))) {
                prev = prev.next;
            }
            next = prev.next;
            prev.next = this;
            return references;
        }
    }

    /**
     * Tells if self precedes the other in the canonical ordering.
     */
    public final boolean isEarlierThan(UplevelReference other) {
        // Outer fields always come first.
        if (isClientOuterField()) {
            return true;
        } else if (other.isClientOuterField()) {
            return false;
        }

        // Now it doesn't matter what the order is; use string comparison.
        LocalMember target2 = other.target;
        Identifier name = target.getName();
        Identifier name2 = target2.getName();
        int cmp = name.toString().compareTo(name2.toString());
        if (cmp != 0) {
            return cmp < 0;
        }
        Identifier cname = target.getClassDefinition().getName();
        Identifier cname2 = target2.getClassDefinition().getName();
        int ccmp = cname.toString().compareTo(cname2.toString());
        return ccmp < 0;
    }

    /**
     * the target of this reference
     */
    public final LocalMember getTarget() {
        return target;
    }

    /**
     * the local argument for this reference
     */
    public final LocalMember getLocalArgument() {
        return localArgument;
    }

    /**
     * the field allocated in the client for this reference
     */
    public final MemberDefinition getLocalField() {
        return localField;
    }

    /**
     * Get the local field, creating one if necessary.
     * The client class must not be frozen.
     */
    public final MemberDefinition getLocalField(Environment env) {
        if (localField == null) {
            makeLocalField(env);
        }
        return localField;
    }

    /**
     * the client class
     */
    public final ClassDefinition getClient() {
        return client;
    }

    /**
     * the next reference in the client's list
     */
    public final UplevelReference getNext() {
        return next;
    }

    /**
     * Tell if this uplevel reference is the up-level "this" pointer
     * of an inner class.  Such references are treated differently
     * than others, because they affect constructor calls across
     * compilation units.
     */
    public boolean isClientOuterField() {
        MemberDefinition outerf = client.findOuterMember();
        return (outerf != null) && (localField == outerf);
    }

    /**
     * Tell if my local argument is directly available in this context.
     * If not, the uplevel reference will have to be via a class field.
     * <p>
     * This must be called in a context which is local
     * to the client of the uplevel reference.
     */
    public boolean localArgumentAvailable(Environment env, Context ctx) {
        MemberDefinition reff = ctx.field;
        if (reff.getClassDefinition() != client) {
            throw new CompilerError("localArgumentAvailable");
        }
        return (   reff.isConstructor()
                || reff.isVariable()
                || reff.isInitializer() );
    }

    /**
     * Process an uplevel reference.
     * The only decision to make at this point is whether
     * to build a "localField" instance variable, which
     * is done (lazily) when localArgumentAvailable() proves false.
     */
    public void noteReference(Environment env, Context ctx) {
        if (localField == null && !localArgumentAvailable(env, ctx)) {
            // We need an instance variable unless client is a constructor.
            makeLocalField(env);
        }
    }

    private void makeLocalField(Environment env) {
        // Cannot alter decisions like this one at a late date.
        client.referencesMustNotBeFrozen();
        int mod = M_PRIVATE | M_FINAL | M_SYNTHETIC;
        localField = env.makeMemberDefinition(env,
                                             localArgument.getWhere(),
                                             client, null,
                                             mod,
                                             localArgument.getType(),
                                             localArgument.getName(),
                                             null, null, null);
    }

    /**
     * Assuming noteReference() is all taken care of,
     * build an uplevel reference.
     * <p>
     * This must be called in a context which is local
     * to the client of the uplevel reference.
     */
    public Expression makeLocalReference(Environment env, Context ctx) {
        if (ctx.field.getClassDefinition() != client) {
            throw new CompilerError("makeLocalReference");
        }
        if (localArgumentAvailable(env, ctx)) {
            return new IdentifierExpression(0, localArgument);
        } else {
            return makeFieldReference(env, ctx);
        }
    }

    /**
     * As with makeLocalReference(), build a locally-usable reference.
     * Ignore the availability of local arguments; always use a class field.
     */
    public Expression makeFieldReference(Environment env, Context ctx) {
        Expression e = ctx.findOuterLink(env, 0, localField);
        return new FieldExpression(0, e, localField);
    }

    /**
     * During the inline phase, call this on a list of references
     * for which the code phase will later emit arguments.
     * It will make sure that any "double-uplevel" values
     * needed by the callee are also present at the call site.
     * <p>
     * If any reference is a "ClientOuterField", it is skipped
     * by this method (and by willCodeArguments).  This is because
     */
    public void willCodeArguments(Environment env, Context ctx) {
        if (!isClientOuterField()) {
            ctx.noteReference(env, target);
        }

        if (next != null) {
            next.willCodeArguments(env, ctx);
        }
    }

    /**
     * Code is being generated for a call to a constructor of
     * the client class.  Push an argument for the constructor.
     */
    public void codeArguments(Environment env, Context ctx, Assembler asm,
                              long where, MemberDefinition conField) {
        if (!isClientOuterField()) {
            Expression e = ctx.makeReference(env, target);
            e.codeValue(env, ctx, asm);
        }

        if (next != null) {
            next.codeArguments(env, ctx, asm, where, conField);
        }
    }

    /**
     * Code is being generated for a constructor of the client class.
     * Emit code which initializes the instance.
     */
    public void codeInitialization(Environment env, Context ctx, Assembler asm,
                                   long where, MemberDefinition conField) {
        // If the reference is a clientOuterField, then the initialization
        // code is generated in MethodExpression.makeVarInits().
        // (Fix for bug 4075063.)
        if (localField != null && !isClientOuterField()) {
            Expression e = ctx.makeReference(env, target);
            Expression f = makeFieldReference(env, ctx);
            e = new AssignExpression(e.getWhere(), f, e);
            e.type = localField.getType();
            e.code(env, ctx, asm);
        }

        if (next != null) {
            next.codeInitialization(env, ctx, asm, where, conField);
        }
    }

    public String toString() {
        return "[" + localArgument + " in " + client + "]";
    }
}

sun/tools/tree/UplevelReference.java

 

Or download all of them as a single archive file:

File name: jdk.rmic-11.0.1-src.zip
File size: 418901 bytes
Release date: 2018-11-04
Download 

 

JDK 11 jdk.scripting.nashorn.jmod - Scripting Nashorn Module

JDK 11 jdk.pack.jmod - Pack Module

Download and Use JDK 11

⇑⇑ FAQ for JDK (Java Development Kit)

2020-04-25, 44817👍, 0💬