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Rhino is an open-source implementation of JavaScript written entirely in Java. It is typically
embedded into Java applications to provide scripting to end users.
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
package org.mozilla.javascript.optimizer;
import org.mozilla.javascript.Node;
import org.mozilla.javascript.ObjArray;
import org.mozilla.javascript.Token;
import org.mozilla.javascript.ast.ScriptNode;
class Optimizer {
static final int NoType = 0;
static final int NumberType = 1;
static final int AnyType = 3;
// It is assumed that (NumberType | AnyType) == AnyType
void optimize(ScriptNode scriptOrFn) {
// run on one function at a time for now
int functionCount = scriptOrFn.getFunctionCount();
for (int i = 0; i != functionCount; ++i) {
OptFunctionNode f = OptFunctionNode.get(scriptOrFn, i);
optimizeFunction(f);
}
}
private void optimizeFunction(OptFunctionNode theFunction) {
if (theFunction.fnode.requiresActivation()) return;
inDirectCallFunction = theFunction.isTargetOfDirectCall();
this.theFunction = theFunction;
ObjArray statementsArray = new ObjArray();
buildStatementList_r(theFunction.fnode, statementsArray);
Node[] theStatementNodes = new Node[statementsArray.size()];
statementsArray.toArray(theStatementNodes);
Block.runFlowAnalyzes(theFunction, theStatementNodes);
if (!theFunction.fnode.requiresActivation()) {
/*
* Now that we know which local vars are in fact always
* Numbers, we re-write the tree to take advantage of
* that. Any arithmetic or assignment op involving just
* Number typed vars is marked so that the codegen will
* generate non-object code.
*/
parameterUsedInNumberContext = false;
for (Node theStatementNode : theStatementNodes) {
rewriteForNumberVariables(theStatementNode, NumberType);
}
theFunction.setParameterNumberContext(parameterUsedInNumberContext);
}
}
/*
Each directCall parameter is passed as a pair of values - an object
and a double. The value passed depends on the type of value available at
the call site. If a double is available, the object in java/lang/Void.TYPE
is passed as the object value, and if an object value is available, then
0.0 is passed as the double value.
The receiving routine always tests the object value before proceeding.
If the parameter is being accessed in a 'Number Context' then the code
sequence is :
if ("parameter_objectValue" == java/lang/Void.TYPE)
...fine..., use the parameter_doubleValue
else
toNumber(parameter_objectValue)
and if the parameter is being referenced in an Object context, the code is
if ("parameter_objectValue" == java/lang/Void.TYPE)
Double.valueOf(parameter_doubleValue)
else
...fine..., use the parameter_objectValue
If the receiving code never uses the doubleValue, it is converted on
entry to a Double instead.
*/
/*
We're referencing a node in a Number context (i.e. we'd prefer it
was a double value). If the node is a parameter in a directCall
function, mark it as being referenced in this context.
*/
private void markDCPNumberContext(Node n) {
if (inDirectCallFunction && n.getType() == Token.GETVAR) {
int varIndex = theFunction.getVarIndex(n);
if (theFunction.isParameter(varIndex)) {
parameterUsedInNumberContext = true;
}
}
}
private boolean convertParameter(Node n) {
if (inDirectCallFunction && n.getType() == Token.GETVAR) {
int varIndex = theFunction.getVarIndex(n);
if (theFunction.isParameter(varIndex)) {
n.removeProp(Node.ISNUMBER_PROP);
return true;
}
}
return false;
}
private int rewriteForNumberVariables(Node n, int desired) {
switch (n.getType()) {
case Token.EXPR_VOID:
{
Node child = n.getFirstChild();
int type = rewriteForNumberVariables(child, NumberType);
if (type == NumberType) n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
return NoType;
}
case Token.NUMBER:
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
return NumberType;
case Token.GETVAR:
{
int varIndex = theFunction.getVarIndex(n);
if (inDirectCallFunction
&& theFunction.isParameter(varIndex)
&& desired == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
return NumberType;
} else if (theFunction.isNumberVar(varIndex)) {
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
return NumberType;
}
return NoType;
}
case Token.INC:
case Token.DEC:
{
Node child = n.getFirstChild();
int type = rewriteForNumberVariables(child, NumberType);
if (child.getType() == Token.GETVAR) {
if (type == NumberType && !convertParameter(child)) {
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
markDCPNumberContext(child);
return NumberType;
}
return NoType;
} else if (child.getType() == Token.GETELEM
|| child.getType() == Token.GETPROP) {
return type;
}
return NoType;
}
case Token.SETVAR:
case Token.SETCONSTVAR:
{
Node lChild = n.getFirstChild();
Node rChild = lChild.getNext();
int rType = rewriteForNumberVariables(rChild, NumberType);
int varIndex = theFunction.getVarIndex(n);
if (inDirectCallFunction && theFunction.isParameter(varIndex)) {
if (rType == NumberType) {
if (!convertParameter(rChild)) {
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
return NumberType;
}
markDCPNumberContext(rChild);
return NoType;
}
return rType;
} else if (theFunction.isNumberVar(varIndex)) {
if (rType != NumberType) {
n.removeChild(rChild);
n.addChildToBack(new Node(Token.TO_DOUBLE, rChild));
}
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
markDCPNumberContext(rChild);
return NumberType;
} else {
if (rType == NumberType) {
if (!convertParameter(rChild)) {
n.removeChild(rChild);
n.addChildToBack(new Node(Token.TO_OBJECT, rChild));
}
}
return NoType;
}
}
case Token.LE:
case Token.LT:
case Token.GE:
case Token.GT:
{
Node lChild = n.getFirstChild();
Node rChild = lChild.getNext();
int lType = rewriteForNumberVariables(lChild, NumberType);
int rType = rewriteForNumberVariables(rChild, NumberType);
markDCPNumberContext(lChild);
markDCPNumberContext(rChild);
if (convertParameter(lChild)) {
if (convertParameter(rChild)) {
return NoType;
} else if (rType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.RIGHT);
}
} else if (convertParameter(rChild)) {
if (lType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.LEFT);
}
} else {
if (lType == NumberType) {
if (rType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
} else {
n.putIntProp(Node.ISNUMBER_PROP, Node.LEFT);
}
} else {
if (rType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.RIGHT);
}
}
}
// we actually build a boolean value
return NoType;
}
case Token.ADD:
{
Node lChild = n.getFirstChild();
Node rChild = lChild.getNext();
int lType = rewriteForNumberVariables(lChild, NumberType);
int rType = rewriteForNumberVariables(rChild, NumberType);
if (convertParameter(lChild)) {
if (convertParameter(rChild)) {
return NoType;
}
if (rType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.RIGHT);
}
} else {
if (convertParameter(rChild)) {
if (lType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.LEFT);
}
} else {
if (lType == NumberType) {
if (rType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
return NumberType;
}
n.putIntProp(Node.ISNUMBER_PROP, Node.LEFT);
} else {
if (rType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.RIGHT);
}
}
}
}
return NoType;
}
case Token.BITXOR:
case Token.BITOR:
case Token.BITAND:
case Token.RSH:
case Token.LSH:
case Token.SUB:
case Token.MUL:
case Token.DIV:
case Token.MOD:
case Token.EXP:
{
Node lChild = n.getFirstChild();
Node rChild = lChild.getNext();
int lType = rewriteForNumberVariables(lChild, NumberType);
int rType = rewriteForNumberVariables(rChild, NumberType);
markDCPNumberContext(lChild);
markDCPNumberContext(rChild);
if (lType == NumberType) {
if (rType == NumberType) {
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
return NumberType;
}
if (!convertParameter(rChild)) {
n.removeChild(rChild);
n.addChildToBack(new Node(Token.TO_DOUBLE, rChild));
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
}
return NumberType;
}
if (rType == NumberType) {
if (!convertParameter(lChild)) {
n.removeChild(lChild);
n.addChildToFront(new Node(Token.TO_DOUBLE, lChild));
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
}
return NumberType;
}
// Numeric Type (Number or BigInt)
return AnyType;
}
case Token.BITNOT:
case Token.POS:
case Token.NEG:
{
Node child = n.getFirstChild();
int type = rewriteForNumberVariables(child, NumberType);
if (type == NumberType && !convertParameter(child)) {
n.putIntProp(Node.ISNUMBER_PROP, Node.BOTH);
markDCPNumberContext(child);
return NumberType;
}
return NoType;
}
case Token.SETELEM:
case Token.SETELEM_OP:
{
Node arrayBase = n.getFirstChild();
Node arrayIndex = arrayBase.getNext();
Node rValue = arrayIndex.getNext();
int baseType = rewriteForNumberVariables(arrayBase, NumberType);
if (baseType == NumberType) {
if (!convertParameter(arrayBase)) {
n.removeChild(arrayBase);
n.addChildToFront(new Node(Token.TO_OBJECT, arrayBase));
}
}
int indexType = rewriteForNumberVariables(arrayIndex, NumberType);
if (indexType == NumberType) {
if (!convertParameter(arrayIndex)) {
// setting the ISNUMBER_PROP signals the codegen
// to use the OptRuntime.setObjectIndex that takes
// a double index
n.putIntProp(Node.ISNUMBER_PROP, Node.LEFT);
}
}
int rValueType = rewriteForNumberVariables(rValue, NumberType);
if (rValueType == NumberType) {
if (!convertParameter(rValue)) {
n.removeChild(rValue);
n.addChildToBack(new Node(Token.TO_OBJECT, rValue));
}
}
return NoType;
}
case Token.GETELEM:
{
Node arrayBase = n.getFirstChild();
Node arrayIndex = arrayBase.getNext();
int baseType = rewriteForNumberVariables(arrayBase, NumberType);
if (baseType == NumberType) {
if (!convertParameter(arrayBase)) {
n.removeChild(arrayBase);
n.addChildToFront(new Node(Token.TO_OBJECT, arrayBase));
}
}
int indexType = rewriteForNumberVariables(arrayIndex, NumberType);
if (indexType == NumberType) {
if (!convertParameter(arrayIndex)) {
// setting the ISNUMBER_PROP signals the codegen
// to use the OptRuntime.getObjectIndex that takes
// a double index
n.putIntProp(Node.ISNUMBER_PROP, Node.RIGHT);
}
}
return NoType;
}
case Token.CALL:
{
Node child = n.getFirstChild(); // the function node
// must be an object
rewriteAsObjectChildren(child, child.getFirstChild());
child = child.getNext(); // the first arg
OptFunctionNode target = (OptFunctionNode) n.getProp(Node.DIRECTCALL_PROP);
if (target != null) {
/*
we leave each child as a Number if it can be. The codegen will
handle moving the pairs of parameters.
*/
while (child != null) {
int type = rewriteForNumberVariables(child, NumberType);
if (type == NumberType) {
markDCPNumberContext(child);
}
child = child.getNext();
}
} else {
rewriteAsObjectChildren(n, child);
}
return NoType;
}
default:
{
rewriteAsObjectChildren(n, n.getFirstChild());
return NoType;
}
}
}
private void rewriteAsObjectChildren(Node n, Node child) {
// Force optimized children to be objects
while (child != null) {
Node nextChild = child.getNext();
int type = rewriteForNumberVariables(child, NoType);
if (type == NumberType) {
if (!convertParameter(child)) {
n.removeChild(child);
Node nuChild = new Node(Token.TO_OBJECT, child);
if (nextChild == null) n.addChildToBack(nuChild);
else n.addChildBefore(nuChild, nextChild);
}
}
child = nextChild;
}
}
private static void buildStatementList_r(Node node, ObjArray statements) {
int type = node.getType();
if (type == Token.BLOCK
|| type == Token.LOCAL_BLOCK
|| type == Token.LOOP
|| type == Token.FUNCTION) {
Node child = node.getFirstChild();
while (child != null) {
buildStatementList_r(child, statements);
child = child.getNext();
}
} else {
statements.add(node);
}
}
private boolean inDirectCallFunction;
OptFunctionNode theFunction;
private boolean parameterUsedInNumberContext;
}
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