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* 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
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package sun.tools.tree;
import sun.tools.java.*;
import sun.tools.asm.Assembler;
import sun.tools.asm.LocalVariable;
import java.io.PrintStream;
import java.util.Hashtable;
/**
* 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 VarDeclarationStatement extends Statement {
LocalMember field;
Expression expr;
/**
* Constructor
*/
public VarDeclarationStatement(long where, Expression expr) {
super(VARDECLARATION, where);
this.expr = expr;
}
public VarDeclarationStatement(long where, LocalMember field, Expression expr) {
super(VARDECLARATION, where);
this.field = field;
this.expr = expr;
}
/**
* Check statement
*/
Vset checkDeclaration(Environment env, Context ctx, Vset vset, int mod, Type t, Hashtable exp) {
if (labels != null) {
env.error(where, "declaration.with.label", labels[0]);
}
if (field != null) {
if (ctx.getLocalClass(field.getName()) != null
&& field.isInnerClass()) {
env.error(where, "local.class.redefined", field.getName());
}
ctx.declare(env, field);
if (field.isInnerClass()) {
ClassDefinition body = field.getInnerClass();
try {
vset = body.checkLocalClass(env, ctx, vset,
null, null, null);
} catch (ClassNotFound ee) {
env.error(where, "class.not.found", ee.name, opNames[op]);
}
return vset;
}
vset.addVar(field.number);
return (expr != null) ? expr.checkValue(env, ctx, vset, exp) : vset;
}
// Argument 'expr' is either an IdentifierExpression for a declaration of
// the form 'type x' or an AssignmentExpression for a declaration of the
// form 'type x = initvalue'. Note that these expressions are treated
// specially in this context, and don't have much connection to their ordinary
// meaning.
Expression e = expr;
if (e.op == ASSIGN) {
expr = ((AssignExpression)e).right;
e = ((AssignExpression)e).left;
} else {
expr = null;
}
boolean declError = t.isType(TC_ERROR);
while (e.op == ARRAYACCESS) {
ArrayAccessExpression array = (ArrayAccessExpression)e;
if (array.index != null) {
env.error(array.index.where, "array.dim.in.type");
declError = true;
}
e = array.right;
t = Type.tArray(t);
}
if (e.op == IDENT) {
Identifier id = ((IdentifierExpression)e).id;
if (ctx.getLocalField(id) != null) {
env.error(where, "local.redefined", id);
}
field = new LocalMember(e.where, ctx.field.getClassDefinition(), mod, t, id);
ctx.declare(env, field);
if (expr != null) {
vset = expr.checkInitializer(env, ctx, vset, t, exp);
expr = convert(env, ctx, t, expr);
field.setValue(expr); // for the sake of non-blank finals
if (field.isConstant()) {
// Keep in mind that isConstant() only means expressions
// that are constant according to the JLS. They might
// not be either constants or evaluable (eg. 1/0).
field.addModifiers(M_INLINEABLE);
}
vset.addVar(field.number);
} else if (declError) {
vset.addVar(field.number);
} else {
vset.addVarUnassigned(field.number);
}
return vset;
}
env.error(e.where, "invalid.decl");
return vset;
}
/**
* Inline
*/
public Statement inline(Environment env, Context ctx) {
if (field.isInnerClass()) {
ClassDefinition body = field.getInnerClass();
body.inlineLocalClass(env);
return null;
}
// Don't generate code for variable if unused and
// optimization is on, whether or not debugging is on
if (env.opt() && !field.isUsed()) {
return new ExpressionStatement(where, expr).inline(env, ctx);
}
ctx.declare(env, field);
if (expr != null) {
expr = expr.inlineValue(env, ctx);
field.setValue(expr); // for the sake of non-blank finals
if (env.opt() && (field.writecount == 0)) {
if (expr.op == IDENT) {
// This code looks like it tests whether a final variable
// is being initialized by an identifier expression.
// Then if the identifier is a local of the same method
// it makes the final variable eligible to be inlined.
// BUT: why isn't the local also checked to make sure
// it is itself final? Unknown.
IdentifierExpression e = (IdentifierExpression)expr;
if (e.field.isLocal() && ((ctx = ctx.getInlineContext()) != null) &&
(((LocalMember)e.field).number < ctx.varNumber)) {
//System.out.println("FINAL IDENT = " + field + " in " + ctx.field);
field.setValue(expr);
field.addModifiers(M_INLINEABLE);
// The two lines below used to elide the declaration
// of inlineable variables, on the theory that there
// wouldn't be any references. But this breaks the
// translation of nested classes, which might refer to
// the variable.
//expr = null;
//return null;
}
}
if (expr.isConstant() || (expr.op == THIS) || (expr.op == SUPER)) {
//System.out.println("FINAL = " + field + " in " + ctx.field);
field.setValue(expr);
field.addModifiers(M_INLINEABLE);
// The two lines below used to elide the declaration
// of inlineable variables, on the theory that there
// wouldn't be any references. But this breaks the
// translation of nested classes, which might refer to
// the variable. Fix for 4073244.
//expr = null;
//return null;
}
}
}
return this;
}
/**
* Create a copy of the statement for method inlining
*/
public Statement copyInline(Context ctx, boolean valNeeded) {
VarDeclarationStatement s = (VarDeclarationStatement)clone();
if (expr != null) {
s.expr = expr.copyInline(ctx);
}
return s;
}
/**
* The cost of inlining this statement
*/
public int costInline(int thresh, Environment env, Context ctx) {
if (field != null && field.isInnerClass()) {
return thresh; // don't copy classes...
}
return (expr != null) ? expr.costInline(thresh, env, ctx) : 0;
}
/**
* Code
*/
public void code(Environment env, Context ctx, Assembler asm) {
if (expr != null && !expr.type.isType(TC_VOID)) {
// The two lines of code directly following this comment used
// to be in the opposite order. They were switched so that
// lines like the following:
//
// int j = (j = 4);
//
// will compile correctly. (Constructions like the above are
// legal. JLS 14.3.2 says that the scope of a local variable
// includes its own initializer.) It is important that we
// declare `field' before we code `expr', because otherwise
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