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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.
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/* -*- Mode: java; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
*
* 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;
import static org.mozilla.javascript.UniqueTag.DOUBLE_MARK;
import java.io.PrintStream;
import java.io.Serializable;
import java.math.BigInteger;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;
import java.util.Objects;
import org.mozilla.javascript.ScriptRuntime.NoSuchMethodShim;
import org.mozilla.javascript.ast.FunctionNode;
import org.mozilla.javascript.ast.ScriptNode;
import org.mozilla.javascript.debug.DebugFrame;
public final class Interpreter extends Icode implements Evaluator {
// data for parsing
InterpreterData itsData;
static final int EXCEPTION_TRY_START_SLOT = 0;
static final int EXCEPTION_TRY_END_SLOT = 1;
static final int EXCEPTION_HANDLER_SLOT = 2;
static final int EXCEPTION_TYPE_SLOT = 3;
static final int EXCEPTION_LOCAL_SLOT = 4;
static final int EXCEPTION_SCOPE_SLOT = 5;
// SLOT_SIZE: space for try start/end, handler, start, handler type,
// exception local and scope local
static final int EXCEPTION_SLOT_SIZE = 6;
/** Class to hold data corresponding to one interpreted call stack frame. */
private static class CallFrame implements Cloneable, Serializable {
private static final long serialVersionUID = -2843792508994958978L;
// fields marked "final" in a comment are effectively final except when they're modified
// immediately after cloning.
/*final*/ CallFrame parentFrame;
// amount of stack frames before this one on the interpretation stack
/*final*/ int frameIndex;
// If true indicates read-only frame that is a part of continuation
boolean frozen;
final InterpretedFunction fnOrScript;
final InterpreterData idata;
// Stack structure
// stack[0 <= i < localShift]: arguments and local variables
// stack[localShift <= i <= emptyStackTop]: used for local temporaries
// stack[emptyStackTop < i < stack.length]: stack data
// sDbl[i]: if stack[i] is UniqueTag.DOUBLE_MARK, sDbl[i] holds the number value
/*final*/ Object[] stack;
/*final*/ int[] stackAttributes;
/*final*/ double[] sDbl;
final CallFrame varSource; // defaults to this unless continuation frame
final int localShift;
final int emptyStackTop;
final DebugFrame debuggerFrame;
final boolean useActivation;
boolean isContinuationsTopFrame;
final Scriptable thisObj;
// The values that change during interpretation
Object result;
double resultDbl;
int pc;
int pcPrevBranch;
int pcSourceLineStart;
Scriptable scope;
int savedStackTop;
int savedCallOp;
Object throwable;
CallFrame(
Context cx,
Scriptable thisObj,
InterpretedFunction fnOrScript,
CallFrame parentFrame) {
idata = fnOrScript.idata;
debuggerFrame = cx.debugger != null ? cx.debugger.getFrame(cx, idata) : null;
useActivation = debuggerFrame != null || idata.itsNeedsActivation;
emptyStackTop = idata.itsMaxVars + idata.itsMaxLocals - 1;
this.fnOrScript = fnOrScript;
varSource = this;
localShift = idata.itsMaxVars;
this.thisObj = thisObj;
this.parentFrame = parentFrame;
frameIndex = (parentFrame == null) ? 0 : parentFrame.frameIndex + 1;
if (frameIndex > cx.getMaximumInterpreterStackDepth()) {
throw Context.reportRuntimeError("Exceeded maximum stack depth");
}
// Initialize initial values of variables that change during
// interpretation.
result = Undefined.instance;
pcSourceLineStart = idata.firstLinePC;
savedStackTop = emptyStackTop;
}
void initializeArgs(
Context cx,
Scriptable callerScope,
Object[] args,
double[] argsDbl,
int argShift,
int argCount) {
if (useActivation) {
// Copy args to new array to pass to enterActivationFunction
// or debuggerFrame.onEnter
if (argsDbl != null) {
args = getArgsArray(args, argsDbl, argShift, argCount);
}
argShift = 0;
argsDbl = null;
}
if (idata.itsFunctionType != 0) {
scope = fnOrScript.getParentScope();
if (useActivation) {
if (idata.itsFunctionType == FunctionNode.ARROW_FUNCTION) {
scope =
ScriptRuntime.createArrowFunctionActivation(
fnOrScript,
cx,
scope,
args,
idata.isStrict,
idata.argsHasRest);
} else {
scope =
ScriptRuntime.createFunctionActivation(
fnOrScript,
cx,
scope,
args,
idata.isStrict,
idata.argsHasRest);
}
}
} else {
scope = callerScope;
ScriptRuntime.initScript(
fnOrScript, thisObj, cx, scope, fnOrScript.idata.evalScriptFlag);
}
if (idata.itsNestedFunctions != null) {
if (idata.itsFunctionType != 0 && !idata.itsNeedsActivation) Kit.codeBug();
for (int i = 0; i < idata.itsNestedFunctions.length; i++) {
InterpreterData fdata = idata.itsNestedFunctions[i];
if (fdata.itsFunctionType == FunctionNode.FUNCTION_STATEMENT) {
initFunction(cx, scope, fnOrScript, i);
}
}
}
final int maxFrameArray = idata.itsMaxFrameArray;
// TODO: move this check into InterpreterData construction
if (maxFrameArray != emptyStackTop + idata.itsMaxStack + 1) Kit.codeBug();
// Initialize args, vars, locals and stack
stack = new Object[maxFrameArray];
stackAttributes = new int[maxFrameArray];
sDbl = new double[maxFrameArray];
int varCount = idata.getParamAndVarCount();
for (int i = 0; i < varCount; i++) {
if (idata.getParamOrVarConst(i)) stackAttributes[i] = ScriptableObject.CONST;
}
int definedArgs = idata.argCount;
if (definedArgs > argCount) {
definedArgs = argCount;
}
// Fill the frame structure
System.arraycopy(args, argShift, stack, 0, definedArgs);
if (argsDbl != null) {
System.arraycopy(argsDbl, argShift, sDbl, 0, definedArgs);
}
for (int i = definedArgs; i != idata.itsMaxVars; ++i) {
stack[i] = Undefined.instance;
}
if (idata.argsHasRest) {
Object[] vals;
int offset = idata.argCount - 1;
if (argCount >= idata.argCount) {
vals = new Object[argCount - offset];
argShift = argShift + offset;
for (int valsIdx = 0; valsIdx != vals.length; ++argShift, ++valsIdx) {
Object val = args[argShift];
if (val == UniqueTag.DOUBLE_MARK) {
val = ScriptRuntime.wrapNumber(argsDbl[argShift]);
}
vals[valsIdx] = val;
}
} else {
vals = ScriptRuntime.emptyArgs;
}
stack[offset] = cx.newArray(scope, vals);
}
}
CallFrame cloneFrozen() {
if (!frozen) Kit.codeBug();
CallFrame copy;
try {
copy = (CallFrame) clone();
} catch (CloneNotSupportedException ex) {
throw new IllegalStateException();
}
// clone stack but keep varSource to point to values
// from this frame to share variables.
copy.stack = stack.clone();
copy.stackAttributes = stackAttributes.clone();
copy.sDbl = sDbl.clone();
copy.frozen = false;
return copy;
}
@Override
public boolean equals(Object other) {
// Overridden for semantic equality comparison. These objects
// are typically exposed as NativeContinuation.implementation,
// comparing them allows establishing whether the continuations
// are semantically equal.
if (other instanceof CallFrame) {
// If the call is not within a Context with a top call, we force
// one. It is required as some objects within fully initialized
// global scopes (notably, XMLLibImpl) need to have a top scope
// in order to evaluate their attributes.
try (Context cx = Context.enter()) {
if (ScriptRuntime.hasTopCall(cx)) {
return equalsInTopScope(other).booleanValue();
}
final Scriptable top = ScriptableObject.getTopLevelScope(scope);
return ((Boolean)
ScriptRuntime.doTopCall(
(c, scope, thisObj, args) -> equalsInTopScope(other),
cx,
top,
top,
ScriptRuntime.emptyArgs,
isStrictTopFrame()))
.booleanValue();
}
}
return false;
}
@Override
public int hashCode() {
// Overridden for consistency with equals.
// Trying to strike a balance between speed of calculation and
// distribution. Not hashing stack variables as those could have
// unbounded computational cost and limit it to topmost 8 frames.
int depth = 0;
CallFrame f = this;
int h = 0;
do {
h = 31 * (31 * h + f.pc) + f.idata.icodeHashCode();
f = f.parentFrame;
} while (f != null && depth++ < 8);
return h;
}
private Boolean equalsInTopScope(Object other) {
return EqualObjectGraphs.withThreadLocal(eq -> equals(this, (CallFrame) other, eq));
}
private boolean isStrictTopFrame() {
CallFrame f = this;
for (; ; ) {
final CallFrame p = f.parentFrame;
if (p == null) {
return f.idata.isStrict;
}
f = p;
}
}
private static Boolean equals(CallFrame f1, CallFrame f2, EqualObjectGraphs equal) {
// Iterative instead of recursive, as interpreter stack depth can
// be larger than JVM stack depth.
for (; ; ) {
if (f1 == f2) {
return Boolean.TRUE;
} else if (f1 == null || f2 == null) {
return Boolean.FALSE;
} else if (!f1.fieldsEqual(f2, equal)) {
return Boolean.FALSE;
} else {
f1 = f1.parentFrame;
f2 = f2.parentFrame;
}
}
}
private boolean fieldsEqual(CallFrame other, EqualObjectGraphs equal) {
return frameIndex == other.frameIndex
&& pc == other.pc
&& compareIdata(idata, other.idata)
&& equal.equalGraphs(varSource.stack, other.varSource.stack)
&& Arrays.equals(varSource.sDbl, other.varSource.sDbl)
&& equal.equalGraphs(thisObj, other.thisObj)
&& equal.equalGraphs(fnOrScript, other.fnOrScript)
&& equal.equalGraphs(scope, other.scope);
}
}
private static boolean compareIdata(InterpreterData i1, InterpreterData i2) {
return i1 == i2 || Objects.equals(getEncodedSource(i1), getEncodedSource(i2));
}
private static final class ContinuationJump implements Serializable {
private static final long serialVersionUID = 7687739156004308247L;
CallFrame capturedFrame;
CallFrame branchFrame;
Object result;
double resultDbl;
ContinuationJump(NativeContinuation c, CallFrame current) {
this.capturedFrame = (CallFrame) c.getImplementation();
if (this.capturedFrame == null || current == null) {
// Continuation and current execution does not share
// any frames if there is nothing to capture or
// if there is no currently executed frames
this.branchFrame = null;
} else {
// Search for branch frame where parent frame chains starting
// from captured and current meet.
CallFrame chain1 = this.capturedFrame;
CallFrame chain2 = current;
// First work parents of chain1 or chain2 until the same
// frame depth.
int diff = chain1.frameIndex - chain2.frameIndex;
if (diff != 0) {
if (diff < 0) {
// swap to make sure that
// chain1.frameIndex > chain2.frameIndex and diff > 0
chain1 = current;
chain2 = this.capturedFrame;
diff = -diff;
}
do {
chain1 = chain1.parentFrame;
} while (--diff != 0);
if (chain1.frameIndex != chain2.frameIndex) Kit.codeBug();
}
// Now walk parents in parallel until a shared frame is found
// or until the root is reached.
while (chain1 != chain2 && chain1 != null) {
chain1 = chain1.parentFrame;
chain2 = chain2.parentFrame;
}
this.branchFrame = chain1;
if (this.branchFrame != null && !this.branchFrame.frozen) Kit.codeBug();
}
}
}
private static CallFrame captureFrameForGenerator(CallFrame frame) {
frame.frozen = true;
CallFrame result = frame.cloneFrozen();
frame.frozen = false;
// now isolate this frame from its previous context
result.parentFrame = null;
result.frameIndex = 0;
return result;
}
static {
// Checks for byte code consistencies, good compiler can eliminate them
if (Token.LAST_BYTECODE_TOKEN > 127) {
String str = "Violation of Token.LAST_BYTECODE_TOKEN <= 127";
System.err.println(str);
throw new IllegalStateException(str);
}
if (MIN_ICODE < -128) {
String str = "Violation of Interpreter.MIN_ICODE >= -128";
System.err.println(str);
throw new IllegalStateException(str);
}
}
@Override
public Object compile(
CompilerEnvirons compilerEnv,
ScriptNode tree,
String encodedSource,
boolean returnFunction) {
CodeGenerator cgen = new CodeGenerator();
itsData = cgen.compile(compilerEnv, tree, encodedSource, returnFunction);
return itsData;
}
@Override
public Script createScriptObject(Object bytecode, Object staticSecurityDomain) {
if (bytecode != itsData) {
Kit.codeBug();
}
return InterpretedFunction.createScript(itsData, staticSecurityDomain);
}
@Override
public void setEvalScriptFlag(Script script) {
((InterpretedFunction) script).idata.evalScriptFlag = true;
}
@Override
public Function createFunctionObject(
Context cx, Scriptable scope, Object bytecode, Object staticSecurityDomain) {
if (bytecode != itsData) {
Kit.codeBug();
}
return InterpretedFunction.createFunction(cx, scope, itsData, staticSecurityDomain);
}
private static int getShort(byte[] iCode, int pc) {
return (iCode[pc] << 8) | (iCode[pc + 1] & 0xFF);
}
private static int getIndex(byte[] iCode, int pc) {
return ((iCode[pc] & 0xFF) << 8) | (iCode[pc + 1] & 0xFF);
}
private static int getInt(byte[] iCode, int pc) {
return (iCode[pc] << 24)
| ((iCode[pc + 1] & 0xFF) << 16)
| ((iCode[pc + 2] & 0xFF) << 8)
| (iCode[pc + 3] & 0xFF);
}
private static int getExceptionHandler(CallFrame frame, boolean onlyFinally) {
int[] exceptionTable = frame.idata.itsExceptionTable;
if (exceptionTable == null) {
// No exception handlers
return -1;
}
// Icode switch in the interpreter increments PC immediately
// and it is necessary to subtract 1 from the saved PC
// to point it before the start of the next instruction.
int pc = frame.pc - 1;
// OPT: use binary search
int best = -1, bestStart = 0, bestEnd = 0;
for (int i = 0; i != exceptionTable.length; i += EXCEPTION_SLOT_SIZE) {
int start = exceptionTable[i + EXCEPTION_TRY_START_SLOT];
int end = exceptionTable[i + EXCEPTION_TRY_END_SLOT];
if (!(start <= pc && pc < end)) {
continue;
}
if (onlyFinally && exceptionTable[i + EXCEPTION_TYPE_SLOT] != 1) {
continue;
}
if (best >= 0) {
// Since handlers always nest and they never have shared end
// although they can share start it is sufficient to compare
// handlers ends
if (bestEnd < end) {
continue;
}
// Check the above assumption
if (bestStart > start) Kit.codeBug(); // should be nested
if (bestEnd == end) Kit.codeBug(); // no ens sharing
}
best = i;
bestStart = start;
bestEnd = end;
}
return best;
}
static void dumpICode(InterpreterData idata) {
if (!Token.printICode) {
return;
}
byte[] iCode = idata.itsICode;
int iCodeLength = iCode.length;
String[] strings = idata.itsStringTable;
BigInteger[] bigInts = idata.itsBigIntTable;
PrintStream out = System.out;
out.println("ICode dump, for " + idata.itsName + ", length = " + iCodeLength);
out.println("MaxStack = " + idata.itsMaxStack);
int indexReg = 0;
for (int pc = 0; pc < iCodeLength; ) {
out.flush();
out.print(" [" + pc + "] ");
int token = iCode[pc];
int icodeLength = bytecodeSpan(token);
String tname = Icode.bytecodeName(token);
int old_pc = pc;
++pc;
switch (token) {
default:
if (icodeLength != 1) Kit.codeBug();
out.println(tname);
break;
case Icode_GOSUB:
case Token.GOTO:
case Token.IFEQ:
case Token.IFNE:
case Icode_IFEQ_POP:
case Icode_LEAVEDQ:
{
int newPC = pc + getShort(iCode, pc) - 1;
out.println(tname + " " + newPC);
pc += 2;
break;
}
case Icode_VAR_INC_DEC:
case Icode_NAME_INC_DEC:
case Icode_PROP_INC_DEC:
case Icode_ELEM_INC_DEC:
case Icode_REF_INC_DEC:
{
int incrDecrType = iCode[pc];
out.println(tname + " " + incrDecrType);
++pc;
break;
}
case Icode_CALLSPECIAL:
{
int callType = iCode[pc] & 0xFF;
boolean isNew = (iCode[pc + 1] != 0);
int line = getIndex(iCode, pc + 2);
out.println(
tname + " " + callType + " " + isNew + " " + indexReg + " " + line);
pc += 4;
break;
}
case Token.CATCH_SCOPE:
{
boolean afterFisrtFlag = (iCode[pc] != 0);
out.println(tname + " " + afterFisrtFlag);
++pc;
}
break;
case Token.REGEXP:
out.println(tname + " " + idata.itsRegExpLiterals[indexReg]);
break;
case Token.OBJECTLIT:
case Icode_SPARE_ARRAYLIT:
out.println(tname + " " + idata.literalIds[indexReg]);
break;
case Icode_CLOSURE_EXPR:
case Icode_CLOSURE_STMT:
out.println(tname + " " + idata.itsNestedFunctions[indexReg]);
break;
case Token.CALL:
case Icode_TAIL_CALL:
case Token.REF_CALL:
case Token.NEW:
out.println(tname + ' ' + indexReg);
break;
case Token.THROW:
case Token.YIELD:
case Icode_YIELD_STAR:
case Icode_GENERATOR:
case Icode_GENERATOR_END:
case Icode_GENERATOR_RETURN:
{
int line = getIndex(iCode, pc);
out.println(tname + " : " + line);
pc += 2;
break;
}
case Icode_SHORTNUMBER:
{
int value = getShort(iCode, pc);
out.println(tname + " " + value);
pc += 2;
break;
}
case Icode_INTNUMBER:
{
int value = getInt(iCode, pc);
out.println(tname + " " + value);
pc += 4;
break;
}
case Token.NUMBER:
{
double value = idata.itsDoubleTable[indexReg];
out.println(tname + " " + value);
break;
}
case Icode_LINE:
{
int line = getIndex(iCode, pc);
out.println(tname + " : " + line);
pc += 2;
break;
}
case Icode_REG_STR1:
{
String str = strings[0xFF & iCode[pc]];
out.println(tname + " \"" + str + '"');
++pc;
break;
}
case Icode_REG_STR2:
{
String str = strings[getIndex(iCode, pc)];
out.println(tname + " \"" + str + '"');
pc += 2;
break;
}
case Icode_REG_STR4:
{
String str = strings[getInt(iCode, pc)];
out.println(tname + " \"" + str + '"');
pc += 4;
break;
}
case Icode_REG_IND_C0:
indexReg = 0;
out.println(tname);
break;
case Icode_REG_IND_C1:
indexReg = 1;
out.println(tname);
break;
case Icode_REG_IND_C2:
indexReg = 2;
out.println(tname);
break;
case Icode_REG_IND_C3:
indexReg = 3;
out.println(tname);
break;
case Icode_REG_IND_C4:
indexReg = 4;
out.println(tname);
break;
case Icode_REG_IND_C5:
indexReg = 5;
out.println(tname);
break;
case Icode_REG_IND1:
{
indexReg = 0xFF & iCode[pc];
out.println(tname + " " + indexReg);
++pc;
break;
}
case Icode_REG_IND2:
{
indexReg = getIndex(iCode, pc);
out.println(tname + " " + indexReg);
pc += 2;
break;
}
case Icode_REG_IND4:
{
indexReg = getInt(iCode, pc);
out.println(tname + " " + indexReg);
pc += 4;
break;
}
case Icode_GETVAR1:
case Icode_SETVAR1:
case Icode_SETCONSTVAR1:
indexReg = iCode[pc];
out.println(tname + " " + indexReg);
++pc;
break;
// TODO: Icode_REG_STR_C0-3 is not dump. I made this the same it.
case Icode_REG_BIGINT_C0:
case Icode_REG_BIGINT_C1:
case Icode_REG_BIGINT_C2:
case Icode_REG_BIGINT_C3:
Kit.codeBug();
break;
case Icode_REG_BIGINT1:
{
BigInteger bigInt = bigInts[0xFF & iCode[pc]];
out.println(tname + " " + bigInt.toString() + 'n');
++pc;
break;
}
case Icode_REG_BIGINT2:
{
BigInteger bigInt = bigInts[getIndex(iCode, pc)];
out.println(tname + " " + bigInt.toString() + 'n');
pc += 2;
break;
}
case Icode_REG_BIGINT4:
{
BigInteger bigInt = bigInts[getInt(iCode, pc)];
out.println(tname + " " + bigInt.toString() + 'n');
pc += 4;
break;
}
}
if (old_pc + icodeLength != pc) Kit.codeBug();
}
int[] table = idata.itsExceptionTable;
if (table != null) {
out.println("Exception handlers: " + table.length / EXCEPTION_SLOT_SIZE);
for (int i = 0; i != table.length; i += EXCEPTION_SLOT_SIZE) {
int tryStart = table[i + EXCEPTION_TRY_START_SLOT];
int tryEnd = table[i + EXCEPTION_TRY_END_SLOT];
int handlerStart = table[i + EXCEPTION_HANDLER_SLOT];
int type = table[i + EXCEPTION_TYPE_SLOT];
int exceptionLocal = table[i + EXCEPTION_LOCAL_SLOT];
out.println(
" tryStart="
+ tryStart
+ " tryEnd="
+ tryEnd
+ " handlerStart="
+ handlerStart
+ " type="
+ (type == 0 ? "catch" : "finally")
+ " exceptionLocal="
+ exceptionLocal);
}
}
out.flush();
}
private static int bytecodeSpan(int bytecode) {
switch (bytecode) {
case Token.THROW:
case Token.YIELD:
case Icode_YIELD_STAR:
case Icode_GENERATOR:
case Icode_GENERATOR_END:
case Icode_GENERATOR_RETURN:
// source line
return 1 + 2;
case Icode_GOSUB:
case Token.GOTO:
case Token.IFEQ:
case Token.IFNE:
case Icode_IFEQ_POP:
case Icode_LEAVEDQ:
// target pc offset
return 1 + 2;
case Icode_CALLSPECIAL:
// call type
// is new
// line number
return 1 + 1 + 1 + 2;
case Token.CATCH_SCOPE:
// scope flag
return 1 + 1;
case Icode_VAR_INC_DEC:
case Icode_NAME_INC_DEC:
case Icode_PROP_INC_DEC:
case Icode_ELEM_INC_DEC:
case Icode_REF_INC_DEC:
// type of ++/--
return 1 + 1;
case Icode_SHORTNUMBER:
// short number
return 1 + 2;
case Icode_INTNUMBER:
// int number
return 1 + 4;
case Icode_REG_IND1:
// ubyte index
return 1 + 1;
case Icode_REG_IND2:
// ushort index
return 1 + 2;
case Icode_REG_IND4:
// int index
return 1 + 4;
case Icode_REG_STR1:
// ubyte string index
return 1 + 1;
case Icode_REG_STR2:
// ushort string index
return 1 + 2;
case Icode_REG_STR4:
// int string index
return 1 + 4;
case Icode_GETVAR1:
case Icode_SETVAR1:
case Icode_SETCONSTVAR1:
// byte var index
return 1 + 1;
case Icode_LINE:
// line number
return 1 + 2;
}
if (!validBytecode(bytecode)) throw Kit.codeBug();
return 1;
}
static int[] getLineNumbers(InterpreterData data) {
UintMap presentLines = new UintMap();
byte[] iCode = data.itsICode;
int iCodeLength = iCode.length;
for (int pc = 0; pc != iCodeLength; ) {
int bytecode = iCode[pc];
int span = bytecodeSpan(bytecode);
if (bytecode == Icode_LINE) {
if (span != 3) Kit.codeBug();
int line = getIndex(iCode, pc + 1);
presentLines.put(line, 0);
}
pc += span;
}
return presentLines.getKeys();
}
@Override
public void captureStackInfo(RhinoException ex) {
Context cx = Context.getCurrentContext();
if (cx == null || cx.lastInterpreterFrame == null) {
// No interpreter invocations
ex.interpreterStackInfo = null;
ex.interpreterLineData = null;
return;
}
// has interpreter frame on the stack
CallFrame[] array;
if (cx.previousInterpreterInvocations == null
|| cx.previousInterpreterInvocations.size() == 0) {
array = new CallFrame[1];
} else {
int previousCount = cx.previousInterpreterInvocations.size();
if (cx.previousInterpreterInvocations.peek() == cx.lastInterpreterFrame) {
// It can happen if exception was generated after
// frame was pushed to cx.previousInterpreterInvocations
// but before assignment to cx.lastInterpreterFrame.
// In this case frames has to be ignored.
--previousCount;
}
array = new CallFrame[previousCount + 1];
cx.previousInterpreterInvocations.toArray(array);
}
array[array.length - 1] = (CallFrame) cx.lastInterpreterFrame;
int interpreterFrameCount = 0;
for (int i = 0; i != array.length; ++i) {
interpreterFrameCount += 1 + array[i].frameIndex;
}
int[] linePC = new int[interpreterFrameCount];
// Fill linePC with pc positions from all interpreter frames.
// Start from the most nested frame
int linePCIndex = interpreterFrameCount;
for (int i = array.length; i != 0; ) {
--i;
CallFrame frame = array[i];
while (frame != null) {
--linePCIndex;
linePC[linePCIndex] = frame.pcSourceLineStart;
frame = frame.parentFrame;
}
}
if (linePCIndex != 0) Kit.codeBug();
ex.interpreterStackInfo = array;
ex.interpreterLineData = linePC;
}
@Override
public String getSourcePositionFromStack(Context cx, int[] linep) {
CallFrame frame = (CallFrame) cx.lastInterpreterFrame;
InterpreterData idata = frame.idata;
if (frame.pcSourceLineStart >= 0) {
linep[0] = getIndex(idata.itsICode, frame.pcSourceLineStart);
} else {
linep[0] = 0;
}
return idata.itsSourceFile;
}
@Override
public String getPatchedStack(RhinoException ex, String nativeStackTrace) {
String tag = "org.mozilla.javascript.Interpreter.interpretLoop";
StringBuilder sb = new StringBuilder(nativeStackTrace.length() + 1000);
String lineSeparator = SecurityUtilities.getSystemProperty("line.separator");
CallFrame[] array = (CallFrame[]) ex.interpreterStackInfo;
int[] linePC = ex.interpreterLineData;
int arrayIndex = array.length;
int linePCIndex = linePC.length;
int offset = 0;
while (arrayIndex != 0) {
--arrayIndex;
int pos = nativeStackTrace.indexOf(tag, offset);
if (pos < 0) {
break;
}
// Skip tag length
pos += tag.length();
// Skip until the end of line
for (; pos != nativeStackTrace.length(); ++pos) {
char c = nativeStackTrace.charAt(pos);
if (c == '\n' || c == '\r') {
break;
}
}
sb.append(nativeStackTrace, offset, pos);
offset = pos;
CallFrame frame = array[arrayIndex];
while (frame != null) {
if (linePCIndex == 0) Kit.codeBug();
--linePCIndex;
InterpreterData idata = frame.idata;
sb.append(lineSeparator);
sb.append("\tat script");
if (idata.itsName != null && idata.itsName.length() != 0) {
sb.append('.');
sb.append(idata.itsName);
}
sb.append('(');
sb.append(idata.itsSourceFile);
int pc = linePC[linePCIndex];
if (pc >= 0) {
// Include line info only if available
sb.append(':');
sb.append(getIndex(idata.itsICode, pc));
}
sb.append(')');
frame = frame.parentFrame;
}
}
sb.append(nativeStackTrace.substring(offset));
return sb.toString();
}
@Override
public List getScriptStack(RhinoException ex) {
ScriptStackElement[][] stack = getScriptStackElements(ex);
List list = new ArrayList<>(stack.length);
String lineSeparator = SecurityUtilities.getSystemProperty("line.separator");
for (ScriptStackElement[] group : stack) {
StringBuilder sb = new StringBuilder();
for (ScriptStackElement elem : group) {
elem.renderJavaStyle(sb);
sb.append(lineSeparator);
}
list.add(sb.toString());
}
return list;
}
public ScriptStackElement[][] getScriptStackElements(RhinoException ex) {
if (ex.interpreterStackInfo == null) {
return null;
}
List list = new ArrayList<>();
CallFrame[] array = (CallFrame[]) ex.interpreterStackInfo;
int[] linePC = ex.interpreterLineData;
int arrayIndex = array.length;
int linePCIndex = linePC.length;
while (arrayIndex != 0) {
--arrayIndex;
CallFrame frame = array[arrayIndex];
List group = new ArrayList<>();
while (frame != null) {
if (linePCIndex == 0) Kit.codeBug();
--linePCIndex;
InterpreterData idata = frame.idata;
String fileName = idata.itsSourceFile;
String functionName = null;
int lineNumber = -1;
int pc = linePC[linePCIndex];
if (pc >= 0) {
lineNumber = getIndex(idata.itsICode, pc);
}
if (idata.itsName != null && idata.itsName.length() != 0) {
functionName = idata.itsName;
}
frame = frame.parentFrame;
group.add(new ScriptStackElement(fileName, functionName, lineNumber));
}
list.add(group.toArray(new ScriptStackElement[0]));
}
return list.toArray(new ScriptStackElement[list.size()][]);
}
static String getEncodedSource(InterpreterData idata) {
if (idata.encodedSource == null) {
return null;
}
return idata.encodedSource.substring(idata.encodedSourceStart, idata.encodedSourceEnd);
}
private static void initFunction(
Context cx, Scriptable scope, InterpretedFunction parent, int index) {
InterpretedFunction fn;
fn = InterpretedFunction.createFunction(cx, scope, parent, index);
ScriptRuntime.initFunction(
cx, scope, fn, fn.idata.itsFunctionType, parent.idata.evalScriptFlag);
}
static Object interpret(
InterpretedFunction ifun,
Context cx,
Scriptable scope,
Scriptable thisObj,
Object[] args) {
if (!ScriptRuntime.hasTopCall(cx)) Kit.codeBug();
if (cx.interpreterSecurityDomain != ifun.securityDomain) {
Object savedDomain = cx.interpreterSecurityDomain;
cx.interpreterSecurityDomain = ifun.securityDomain;
try {
return ifun.securityController.callWithDomain(
ifun.securityDomain, cx, ifun, scope, thisObj, args);
} finally {
cx.interpreterSecurityDomain = savedDomain;
}
}
CallFrame frame = initFrame(cx, scope, thisObj, args, null, 0, args.length, ifun, null);
frame.isContinuationsTopFrame = cx.isContinuationsTopCall;
cx.isContinuationsTopCall = false;
return interpretLoop(cx, frame, null);
}
static class GeneratorState {
GeneratorState(int operation, Object value) {
this.operation = operation;
this.value = value;
}
int operation;
Object value;
RuntimeException returnedException;
}
public static Object resumeGenerator(
Context cx, Scriptable scope, int operation, Object savedState, Object value) {
CallFrame frame = (CallFrame) savedState;
GeneratorState generatorState = new GeneratorState(operation, value);
if (operation == NativeGenerator.GENERATOR_CLOSE) {
try {
return interpretLoop(cx, frame, generatorState);
} catch (RuntimeException e) {
// Only propagate exceptions other than closingException
if (e != value) throw e;
}
return Undefined.instance;
}
Object result = interpretLoop(cx, frame, generatorState);
if (generatorState.returnedException != null) throw generatorState.returnedException;
return result;
}
public static Object restartContinuation(
NativeContinuation c, Context cx, Scriptable scope, Object[] args) {
if (!ScriptRuntime.hasTopCall(cx)) {
return ScriptRuntime.doTopCall(c, cx, scope, null, args, cx.isTopLevelStrict);
}
Object arg;
if (args.length == 0) {
arg = Undefined.instance;
} else {
arg = args[0];
}
CallFrame capturedFrame = (CallFrame) c.getImplementation();
if (capturedFrame == null) {
// No frames to restart
return arg;
}
ContinuationJump cjump = new ContinuationJump(c, null);
cjump.result = arg;
return interpretLoop(cx, null, cjump);
}
private static Object interpretLoop(Context cx, CallFrame frame, Object throwable) {
// throwable holds exception object to rethrow or catch
// It is also used for continuation restart in which case
// it holds ContinuationJump
final Object DBL_MRK = DOUBLE_MARK;
final Object undefined = Undefined.instance;
final boolean instructionCounting = (cx.instructionThreshold != 0);
// arbitrary number to add to instructionCount when calling
// other functions
final int INVOCATION_COST = 100;
// arbitrary exception cost for instruction counting
final int EXCEPTION_COST = 100;
String stringReg = null;
BigInteger bigIntReg = null;
int indexReg = -1;
if (cx.lastInterpreterFrame != null) {
// save the top frame from the previous interpretLoop
// invocation on the stack
if (cx.previousInterpreterInvocations == null) {
cx.previousInterpreterInvocations = new ObjArray();
}
cx.previousInterpreterInvocations.push(cx.lastInterpreterFrame);
}
// When restarting continuation throwable is not null and to jump
// to the code that rewind continuation state indexReg should be set
// to -1.
// With the normal call throwable == null and indexReg == -1 allows to
// catch bugs with using indeReg to access array elements before
// initializing indexReg.
GeneratorState generatorState = null;
if (throwable != null) {
if (throwable instanceof GeneratorState) {
generatorState = (GeneratorState) throwable;
// reestablish this call frame
enterFrame(cx, frame, ScriptRuntime.emptyArgs, true);
throwable = null;
} else if (!(throwable instanceof ContinuationJump)) {
// It should be continuation
Kit.codeBug();
}
}
Object interpreterResult = null;
double interpreterResultDbl = 0.0;
StateLoop:
for (; ; ) {
withoutExceptions:
try {
if (throwable != null) {
// Need to return both 'frame' and 'throwable' from
// 'processThrowable', so just added a 'throwable'
// member in 'frame'.
frame = processThrowable(cx, throwable, frame, indexReg, instructionCounting);
throwable = frame.throwable;
frame.throwable = null;
} else {
if (generatorState == null && frame.frozen) Kit.codeBug();
}
// Use local variables for constant values in frame
// for faster access
Object[] stack = frame.stack;
double[] sDbl = frame.sDbl;
Object[] vars = frame.varSource.stack;
double[] varDbls = frame.varSource.sDbl;
int[] varAttributes = frame.varSource.stackAttributes;
byte[] iCode = frame.idata.itsICode;
String[] strings = frame.idata.itsStringTable;
BigInteger[] bigInts = frame.idata.itsBigIntTable;
// Use local for stackTop as well. Since execption handlers
// can only exist at statement level where stack is empty,
// it is necessary to save/restore stackTop only across
// function calls and normal returns.
int stackTop = frame.savedStackTop;
// Store new frame in cx which is used for error reporting etc.
cx.lastInterpreterFrame = frame;
Loop:
for (; ; ) {
// Exception handler assumes that PC is already incremented
// pass the instruction start when it searches the
// exception handler
int op = iCode[frame.pc++];
jumplessRun:
{
// Back indent to ease implementation reading
switch (op) {
case Icode_GENERATOR:
{
if (!frame.frozen) {
// First time encountering this opcode: create new generator
// object and return
frame.pc--; // we want to come back here when we resume
CallFrame generatorFrame = captureFrameForGenerator(frame);
generatorFrame.frozen = true;
if (cx.getLanguageVersion() >= Context.VERSION_ES6) {
frame.result =
new ES6Generator(
frame.scope,
generatorFrame.fnOrScript,
generatorFrame);
} else {
frame.result =
new NativeGenerator(
frame.scope,
generatorFrame.fnOrScript,
generatorFrame);
}
break Loop;
}
// We are now resuming execution. Fall through to YIELD case.
}
// fall through...
case Token.YIELD:
case Icode_YIELD_STAR:
{
if (!frame.frozen) {
return freezeGenerator(
cx,
frame,
stackTop,
generatorState,
op == Icode_YIELD_STAR);
}
Object obj = thawGenerator(frame, stackTop, generatorState, op);
if (obj != Scriptable.NOT_FOUND) {
throwable = obj;
break withoutExceptions;
}
continue Loop;
}
case Icode_GENERATOR_END:
{
// throw StopIteration
frame.frozen = true;
int sourceLine = getIndex(iCode, frame.pc);
generatorState.returnedException =
new JavaScriptException(
NativeIterator.getStopIterationObject(
frame.scope),
frame.idata.itsSourceFile,
sourceLine);
break Loop;
}
case Icode_GENERATOR_RETURN:
{
// throw StopIteration with the value of "return"
frame.frozen = true;
frame.result = stack[stackTop];
frame.resultDbl = sDbl[stackTop];
--stackTop;
NativeIterator.StopIteration si =
new NativeIterator.StopIteration(
(frame.result == DOUBLE_MARK)
? Double.valueOf(frame.resultDbl)
: frame.result);
int sourceLine = getIndex(iCode, frame.pc);
generatorState.returnedException =
new JavaScriptException(
si, frame.idata.itsSourceFile, sourceLine);
break Loop;
}
case Token.THROW:
{
Object value = stack[stackTop];
if (value == DBL_MRK)
value = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
int sourceLine = getIndex(iCode, frame.pc);
throwable =
new JavaScriptException(
value, frame.idata.itsSourceFile, sourceLine);
break withoutExceptions;
}
case Token.RETHROW:
{
indexReg += frame.localShift;
throwable = stack[indexReg];
break withoutExceptions;
}
case Token.GE:
case Token.LE:
case Token.GT:
case Token.LT:
{
stackTop = doCompare(frame, op, stack, sDbl, stackTop);
continue Loop;
}
case Token.IN:
case Token.INSTANCEOF:
{
stackTop = doInOrInstanceof(cx, op, stack, sDbl, stackTop);
continue Loop;
}
case Token.EQ:
case Token.NE:
{
--stackTop;
boolean valBln = doEquals(stack, sDbl, stackTop);
valBln ^= (op == Token.NE);
stack[stackTop] = ScriptRuntime.wrapBoolean(valBln);
continue Loop;
}
case Token.SHEQ:
case Token.SHNE:
{
--stackTop;
boolean valBln = doShallowEquals(stack, sDbl, stackTop);
valBln ^= (op == Token.SHNE);
stack[stackTop] = ScriptRuntime.wrapBoolean(valBln);
continue Loop;
}
case Token.IFNE:
if (stack_boolean(frame, stackTop--)) {
frame.pc += 2;
continue Loop;
}
break jumplessRun;
case Token.IFEQ:
if (!stack_boolean(frame, stackTop--)) {
frame.pc += 2;
continue Loop;
}
break jumplessRun;
case Icode_IFEQ_POP:
if (!stack_boolean(frame, stackTop--)) {
frame.pc += 2;
continue Loop;
}
stack[stackTop--] = null;
break jumplessRun;
case Token.GOTO:
break jumplessRun;
case Icode_GOSUB:
++stackTop;
stack[stackTop] = DBL_MRK;
sDbl[stackTop] = frame.pc + 2;
break jumplessRun;
case Icode_STARTSUB:
if (stackTop == frame.emptyStackTop + 1) {
// Call from Icode_GOSUB: store return PC address in the local
indexReg += frame.localShift;
stack[indexReg] = stack[stackTop];
sDbl[indexReg] = sDbl[stackTop];
--stackTop;
} else {
// Call from exception handler: exception object is already
// stored
// in the local
if (stackTop != frame.emptyStackTop) Kit.codeBug();
}
continue Loop;
case Icode_RETSUB:
{
// indexReg: local to store return address
if (instructionCounting) {
addInstructionCount(cx, frame, 0);
}
indexReg += frame.localShift;
Object value = stack[indexReg];
if (value != DBL_MRK) {
// Invocation from exception handler, restore object to
// rethrow
throwable = value;
break withoutExceptions;
}
// Normal return from GOSUB
frame.pc = (int) sDbl[indexReg];
if (instructionCounting) {
frame.pcPrevBranch = frame.pc;
}
continue Loop;
}
case Icode_POP:
stack[stackTop] = null;
stackTop--;
continue Loop;
case Icode_POP_RESULT:
frame.result = stack[stackTop];
frame.resultDbl = sDbl[stackTop];
stack[stackTop] = null;
--stackTop;
continue Loop;
case Icode_DUP:
stack[stackTop + 1] = stack[stackTop];
sDbl[stackTop + 1] = sDbl[stackTop];
stackTop++;
continue Loop;
case Icode_DUP2:
stack[stackTop + 1] = stack[stackTop - 1];
sDbl[stackTop + 1] = sDbl[stackTop - 1];
stack[stackTop + 2] = stack[stackTop];
sDbl[stackTop + 2] = sDbl[stackTop];
stackTop += 2;
continue Loop;
case Icode_SWAP:
{
Object o = stack[stackTop];
stack[stackTop] = stack[stackTop - 1];
stack[stackTop - 1] = o;
double d = sDbl[stackTop];
sDbl[stackTop] = sDbl[stackTop - 1];
sDbl[stackTop - 1] = d;
continue Loop;
}
case Token.RETURN:
frame.result = stack[stackTop];
frame.resultDbl = sDbl[stackTop];
--stackTop;
break Loop;
case Token.RETURN_RESULT:
break Loop;
case Icode_RETUNDEF:
frame.result = undefined;
break Loop;
case Token.BITNOT:
{
stackTop = doBitNOT(frame, stack, sDbl, stackTop);
continue Loop;
}
case Token.BITAND:
case Token.BITOR:
case Token.BITXOR:
case Token.LSH:
case Token.RSH:
{
stackTop = doBitOp(frame, op, stack, sDbl, stackTop);
continue Loop;
}
case Token.URSH:
{
double lDbl = stack_double(frame, stackTop - 1);
int rIntValue = stack_int32(frame, stackTop) & 0x1F;
stack[--stackTop] = DBL_MRK;
sDbl[stackTop] = ScriptRuntime.toUint32(lDbl) >>> rIntValue;
continue Loop;
}
case Token.POS:
{
double rDbl = stack_double(frame, stackTop);
stack[stackTop] = DBL_MRK;
sDbl[stackTop] = rDbl;
continue Loop;
}
case Token.NEG:
{
Number rNum = stack_numeric(frame, stackTop);
Number rNegNum = ScriptRuntime.negate(rNum);
if (rNegNum instanceof BigInteger) {
stack[stackTop] = rNegNum;
} else {
stack[stackTop] = DBL_MRK;
sDbl[stackTop] = rNegNum.doubleValue();
}
continue Loop;
}
case Token.ADD:
--stackTop;
doAdd(stack, sDbl, stackTop, cx);
continue Loop;
case Token.SUB:
case Token.MUL:
case Token.DIV:
case Token.MOD:
case Token.EXP:
{
stackTop = doArithmetic(frame, op, stack, sDbl, stackTop);
continue Loop;
}
case Token.NOT:
stack[stackTop] =
ScriptRuntime.wrapBoolean(!stack_boolean(frame, stackTop));
continue Loop;
case Token.BINDNAME:
stack[++stackTop] = ScriptRuntime.bind(cx, frame.scope, stringReg);
continue Loop;
case Token.STRICT_SETNAME:
case Token.SETNAME:
{
Object rhs = stack[stackTop];
if (rhs == DBL_MRK)
rhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Scriptable lhs = (Scriptable) stack[stackTop];
stack[stackTop] =
op == Token.SETNAME
? ScriptRuntime.setName(
lhs, rhs, cx, frame.scope, stringReg)
: ScriptRuntime.strictSetName(
lhs, rhs, cx, frame.scope, stringReg);
continue Loop;
}
case Icode_SETCONST:
{
Object rhs = stack[stackTop];
if (rhs == DBL_MRK)
rhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Scriptable lhs = (Scriptable) stack[stackTop];
stack[stackTop] =
ScriptRuntime.setConst(lhs, rhs, cx, stringReg);
continue Loop;
}
case Token.DELPROP:
case Icode_DELNAME:
{
stackTop = doDelName(cx, frame, op, stack, sDbl, stackTop);
continue Loop;
}
case Token.GETPROPNOWARN:
{
Object lhs = stack[stackTop];
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] =
ScriptRuntime.getObjectPropNoWarn(
lhs, stringReg, cx, frame.scope);
continue Loop;
}
case Token.GETPROP:
{
Object lhs = stack[stackTop];
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] =
ScriptRuntime.getObjectProp(
lhs, stringReg, cx, frame.scope);
continue Loop;
}
case Token.SETPROP:
{
Object rhs = stack[stackTop];
if (rhs == DBL_MRK)
rhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Object lhs = stack[stackTop];
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] =
ScriptRuntime.setObjectProp(
lhs, stringReg, rhs, cx, frame.scope);
continue Loop;
}
case Icode_PROP_INC_DEC:
{
Object lhs = stack[stackTop];
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] =
ScriptRuntime.propIncrDecr(
lhs,
stringReg,
cx,
frame.scope,
iCode[frame.pc]);
++frame.pc;
continue Loop;
}
case Token.GETELEM:
{
stackTop = doGetElem(cx, frame, stack, sDbl, stackTop);
continue Loop;
}
case Token.SETELEM:
{
stackTop = doSetElem(cx, frame, stack, sDbl, stackTop);
continue Loop;
}
case Icode_ELEM_INC_DEC:
{
stackTop =
doElemIncDec(cx, frame, iCode, stack, sDbl, stackTop);
continue Loop;
}
case Token.GET_REF:
{
Ref ref = (Ref) stack[stackTop];
stack[stackTop] = ScriptRuntime.refGet(ref, cx);
continue Loop;
}
case Token.SET_REF:
{
Object value = stack[stackTop];
if (value == DBL_MRK)
value = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Ref ref = (Ref) stack[stackTop];
stack[stackTop] =
ScriptRuntime.refSet(ref, value, cx, frame.scope);
continue Loop;
}
case Token.DEL_REF:
{
Ref ref = (Ref) stack[stackTop];
stack[stackTop] = ScriptRuntime.refDel(ref, cx);
continue Loop;
}
case Icode_REF_INC_DEC:
{
Ref ref = (Ref) stack[stackTop];
stack[stackTop] =
ScriptRuntime.refIncrDecr(
ref, cx, frame.scope, iCode[frame.pc]);
++frame.pc;
continue Loop;
}
case Token.LOCAL_LOAD:
++stackTop;
indexReg += frame.localShift;
stack[stackTop] = stack[indexReg];
sDbl[stackTop] = sDbl[indexReg];
continue Loop;
case Icode_LOCAL_CLEAR:
indexReg += frame.localShift;
stack[indexReg] = null;
continue Loop;
case Icode_NAME_AND_THIS:
// stringReg: name
++stackTop;
stack[stackTop] =
ScriptRuntime.getNameFunctionAndThis(
stringReg, cx, frame.scope);
++stackTop;
stack[stackTop] = ScriptRuntime.lastStoredScriptable(cx);
continue Loop;
case Icode_PROP_AND_THIS:
{
Object obj = stack[stackTop];
if (obj == DBL_MRK)
obj = ScriptRuntime.wrapNumber(sDbl[stackTop]);
// stringReg: property
stack[stackTop] =
ScriptRuntime.getPropFunctionAndThis(
obj, stringReg, cx, frame.scope);
++stackTop;
stack[stackTop] = ScriptRuntime.lastStoredScriptable(cx);
continue Loop;
}
case Icode_ELEM_AND_THIS:
{
Object obj = stack[stackTop - 1];
if (obj == DBL_MRK)
obj = ScriptRuntime.wrapNumber(sDbl[stackTop - 1]);
Object id = stack[stackTop];
if (id == DBL_MRK)
id = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop - 1] =
ScriptRuntime.getElemFunctionAndThis(
obj, id, cx, frame.scope);
stack[stackTop] = ScriptRuntime.lastStoredScriptable(cx);
continue Loop;
}
case Icode_VALUE_AND_THIS:
{
Object value = stack[stackTop];
if (value == DBL_MRK)
value = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] =
ScriptRuntime.getValueFunctionAndThis(value, cx);
++stackTop;
stack[stackTop] = ScriptRuntime.lastStoredScriptable(cx);
continue Loop;
}
case Icode_CALLSPECIAL:
{
if (instructionCounting) {
cx.instructionCount += INVOCATION_COST;
}
stackTop =
doCallSpecial(
cx, frame, stack, sDbl, stackTop, iCode,
indexReg);
continue Loop;
}
case Token.CALL:
case Icode_TAIL_CALL:
case Token.REF_CALL:
{
if (instructionCounting) {
cx.instructionCount += INVOCATION_COST;
}
// stack change: function thisObj arg0 .. argN -> result
// indexReg: number of arguments
stackTop -= 1 + indexReg;
// CALL generation ensures that fun and funThisObj
// are already Scriptable and Callable objects respectively
Callable fun = (Callable) stack[stackTop];
Scriptable funThisObj = (Scriptable) stack[stackTop + 1];
if (op == Token.REF_CALL) {
Object[] outArgs =
getArgsArray(stack, sDbl, stackTop + 2, indexReg);
stack[stackTop] =
ScriptRuntime.callRef(
fun, funThisObj,
outArgs, cx);
continue Loop;
}
Scriptable calleeScope = frame.scope;
if (frame.useActivation) {
calleeScope =
ScriptableObject.getTopLevelScope(frame.scope);
}
if (fun instanceof InterpretedFunction) {
InterpretedFunction ifun = (InterpretedFunction) fun;
if (frame.fnOrScript.securityDomain
== ifun.securityDomain) {
CallFrame callParentFrame = frame;
if (op == Icode_TAIL_CALL) {
// In principle tail call can re-use the current
// frame and its stack arrays but it is hard to
// do properly. Any exceptions that can legally
// happen during frame re-initialization including
// StackOverflowException during innocent looking
// System.arraycopy may leave the current frame
// data corrupted leading to undefined behaviour
// in the catch code bellow that unwinds JS stack
// on exceptions. Then there is issue about frame
// release
// end exceptions there.
// To avoid frame allocation a released frame
// can be cached for re-use which would also benefit
// non-tail calls but it is not clear that this
// caching
// would gain in performance due to potentially
// bad interaction with GC.
callParentFrame = frame.parentFrame;
// Release the current frame. See Bug #344501 to see
// why
// it is being done here.
exitFrame(cx, frame, null);
}
CallFrame calleeFrame =
initFrame(
cx,
calleeScope,
funThisObj,
stack,
sDbl,
stackTop + 2,
indexReg,
ifun,
callParentFrame);
if (op != Icode_TAIL_CALL) {
frame.savedStackTop = stackTop;
frame.savedCallOp = op;
}
frame = calleeFrame;
continue StateLoop;
}
}
if (fun instanceof NativeContinuation) {
// Jump to the captured continuation
ContinuationJump cjump;
cjump =
new ContinuationJump(
(NativeContinuation) fun, frame);
// continuation result is the first argument if any
// of continuation call
if (indexReg == 0) {
cjump.result = undefined;
} else {
cjump.result = stack[stackTop + 2];
cjump.resultDbl = sDbl[stackTop + 2];
}
// Start the real unwind job
throwable = cjump;
break withoutExceptions;
}
if (fun instanceof IdFunctionObject) {
IdFunctionObject ifun = (IdFunctionObject) fun;
if (NativeContinuation.isContinuationConstructor(ifun)) {
frame.stack[stackTop] =
captureContinuation(
cx, frame.parentFrame, false);
continue Loop;
}
// Bug 405654 -- make best effort to keep Function.apply and
// Function.call within this interpreter loop invocation
if (BaseFunction.isApplyOrCall(ifun)) {
Callable applyCallable =
ScriptRuntime.getCallable(funThisObj);
if (applyCallable instanceof InterpretedFunction) {
InterpretedFunction iApplyCallable =
(InterpretedFunction) applyCallable;
if (frame.fnOrScript.securityDomain
== iApplyCallable.securityDomain) {
frame =
initFrameForApplyOrCall(
cx,
frame,
indexReg,
stack,
sDbl,
stackTop,
op,
calleeScope,
ifun,
iApplyCallable);
continue StateLoop;
}
}
}
}
// Bug 447697 -- make best effort to keep __noSuchMethod__
// within this
// interpreter loop invocation
if (fun instanceof NoSuchMethodShim) {
// get the shim and the actual method
NoSuchMethodShim noSuchMethodShim = (NoSuchMethodShim) fun;
Callable noSuchMethodMethod =
noSuchMethodShim.noSuchMethodMethod;
// if the method is in fact an InterpretedFunction
if (noSuchMethodMethod instanceof InterpretedFunction) {
InterpretedFunction ifun =
(InterpretedFunction) noSuchMethodMethod;
if (frame.fnOrScript.securityDomain
== ifun.securityDomain) {
frame =
initFrameForNoSuchMethod(
cx,
frame,
indexReg,
stack,
sDbl,
stackTop,
op,
funThisObj,
calleeScope,
noSuchMethodShim,
ifun);
continue StateLoop;
}
}
}
cx.lastInterpreterFrame = frame;
frame.savedCallOp = op;
frame.savedStackTop = stackTop;
stack[stackTop] =
fun.call(
cx,
calleeScope,
funThisObj,
getArgsArray(
stack, sDbl, stackTop + 2, indexReg));
continue Loop;
}
case Token.NEW:
{
if (instructionCounting) {
cx.instructionCount += INVOCATION_COST;
}
// stack change: function arg0 .. argN -> newResult
// indexReg: number of arguments
stackTop -= indexReg;
Object lhs = stack[stackTop];
if (lhs instanceof InterpretedFunction) {
InterpretedFunction f = (InterpretedFunction) lhs;
if (frame.fnOrScript.securityDomain == f.securityDomain) {
Scriptable newInstance =
f.createObject(cx, frame.scope);
CallFrame calleeFrame =
initFrame(
cx,
frame.scope,
newInstance,
stack,
sDbl,
stackTop + 1,
indexReg,
f,
frame);
stack[stackTop] = newInstance;
frame.savedStackTop = stackTop;
frame.savedCallOp = op;
frame = calleeFrame;
continue StateLoop;
}
}
if (!(lhs instanceof Function)) {
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
throw ScriptRuntime.notFunctionError(lhs);
}
Function fun = (Function) lhs;
if (fun instanceof IdFunctionObject) {
IdFunctionObject ifun = (IdFunctionObject) fun;
if (NativeContinuation.isContinuationConstructor(ifun)) {
frame.stack[stackTop] =
captureContinuation(
cx, frame.parentFrame, false);
continue Loop;
}
}
Object[] outArgs =
getArgsArray(stack, sDbl, stackTop + 1, indexReg);
stack[stackTop] = fun.construct(cx, frame.scope, outArgs);
continue Loop;
}
case Token.TYPEOF:
{
Object lhs = stack[stackTop];
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] = ScriptRuntime.typeof(lhs);
continue Loop;
}
case Icode_TYPEOFNAME:
stack[++stackTop] =
ScriptRuntime.typeofName(frame.scope, stringReg);
continue Loop;
case Token.STRING:
stack[++stackTop] = stringReg;
continue Loop;
case Icode_SHORTNUMBER:
++stackTop;
stack[stackTop] = DBL_MRK;
sDbl[stackTop] = getShort(iCode, frame.pc);
frame.pc += 2;
continue Loop;
case Icode_INTNUMBER:
++stackTop;
stack[stackTop] = DBL_MRK;
sDbl[stackTop] = getInt(iCode, frame.pc);
frame.pc += 4;
continue Loop;
case Token.NUMBER:
++stackTop;
stack[stackTop] = DBL_MRK;
sDbl[stackTop] = frame.idata.itsDoubleTable[indexReg];
continue Loop;
case Token.BIGINT:
stack[++stackTop] = bigIntReg;
continue Loop;
case Token.NAME:
stack[++stackTop] = ScriptRuntime.name(cx, frame.scope, stringReg);
continue Loop;
case Icode_NAME_INC_DEC:
stack[++stackTop] =
ScriptRuntime.nameIncrDecr(
frame.scope, stringReg, cx, iCode[frame.pc]);
++frame.pc;
continue Loop;
case Icode_SETCONSTVAR1:
indexReg = iCode[frame.pc++];
// fallthrough
case Token.SETCONSTVAR:
stackTop =
doSetConstVar(
frame,
stack,
sDbl,
stackTop,
vars,
varDbls,
varAttributes,
indexReg);
continue Loop;
case Icode_SETVAR1:
indexReg = iCode[frame.pc++];
// fallthrough
case Token.SETVAR:
stackTop =
doSetVar(
frame,
stack,
sDbl,
stackTop,
vars,
varDbls,
varAttributes,
indexReg);
continue Loop;
case Icode_GETVAR1:
indexReg = iCode[frame.pc++];
// fallthrough
case Token.GETVAR:
stackTop =
doGetVar(
frame, stack, sDbl, stackTop, vars, varDbls,
indexReg);
continue Loop;
case Icode_VAR_INC_DEC:
{
stackTop =
doVarIncDec(
cx,
frame,
stack,
sDbl,
stackTop,
vars,
varDbls,
varAttributes,
indexReg);
continue Loop;
}
case Icode_ZERO:
++stackTop;
stack[stackTop] = DBL_MRK;
sDbl[stackTop] = 0;
continue Loop;
case Icode_ONE:
++stackTop;
stack[stackTop] = DBL_MRK;
sDbl[stackTop] = 1;
continue Loop;
case Token.NULL:
stack[++stackTop] = null;
continue Loop;
case Token.THIS:
stack[++stackTop] = frame.thisObj;
continue Loop;
case Token.THISFN:
stack[++stackTop] = frame.fnOrScript;
continue Loop;
case Token.FALSE:
stack[++stackTop] = Boolean.FALSE;
continue Loop;
case Token.TRUE:
stack[++stackTop] = Boolean.TRUE;
continue Loop;
case Icode_UNDEF:
stack[++stackTop] = undefined;
continue Loop;
case Token.ENTERWITH:
{
Object lhs = stack[stackTop];
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
frame.scope = ScriptRuntime.enterWith(lhs, cx, frame.scope);
continue Loop;
}
case Token.LEAVEWITH:
frame.scope = ScriptRuntime.leaveWith(frame.scope);
continue Loop;
case Token.CATCH_SCOPE:
{
// stack top: exception object
// stringReg: name of exception variable
// indexReg: local for exception scope
--stackTop;
indexReg += frame.localShift;
boolean afterFirstScope = (frame.idata.itsICode[frame.pc] != 0);
Throwable caughtException = (Throwable) stack[stackTop + 1];
Scriptable lastCatchScope;
if (!afterFirstScope) {
lastCatchScope = null;
} else {
lastCatchScope = (Scriptable) stack[indexReg];
}
stack[indexReg] =
ScriptRuntime.newCatchScope(
caughtException,
lastCatchScope,
stringReg,
cx,
frame.scope);
++frame.pc;
continue Loop;
}
case Token.ENUM_INIT_KEYS:
case Token.ENUM_INIT_VALUES:
case Token.ENUM_INIT_ARRAY:
case Token.ENUM_INIT_VALUES_IN_ORDER:
{
Object lhs = stack[stackTop];
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
indexReg += frame.localShift;
int enumType =
op == Token.ENUM_INIT_KEYS
? ScriptRuntime.ENUMERATE_KEYS
: op == Token.ENUM_INIT_VALUES
? ScriptRuntime.ENUMERATE_VALUES
: op == Token.ENUM_INIT_VALUES_IN_ORDER
? ScriptRuntime
.ENUMERATE_VALUES_IN_ORDER
: ScriptRuntime.ENUMERATE_ARRAY;
stack[indexReg] =
ScriptRuntime.enumInit(lhs, cx, frame.scope, enumType);
continue Loop;
}
case Token.ENUM_NEXT:
case Token.ENUM_ID:
{
indexReg += frame.localShift;
Object val = stack[indexReg];
++stackTop;
stack[stackTop] =
(op == Token.ENUM_NEXT)
? ScriptRuntime.enumNext(val, cx)
: ScriptRuntime.enumId(val, cx);
continue Loop;
}
case Token.REF_SPECIAL:
{
// stringReg: name of special property
Object obj = stack[stackTop];
if (obj == DBL_MRK)
obj = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] =
ScriptRuntime.specialRef(
obj, stringReg, cx, frame.scope);
continue Loop;
}
case Token.REF_MEMBER:
{
// indexReg: flags
stackTop = doRefMember(cx, stack, sDbl, stackTop, indexReg);
continue Loop;
}
case Token.REF_NS_MEMBER:
{
// indexReg: flags
stackTop = doRefNsMember(cx, stack, sDbl, stackTop, indexReg);
continue Loop;
}
case Token.REF_NAME:
{
// indexReg: flags
Object name = stack[stackTop];
if (name == DBL_MRK)
name = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] =
ScriptRuntime.nameRef(name, cx, frame.scope, indexReg);
continue Loop;
}
case Token.REF_NS_NAME:
{
// indexReg: flags
stackTop =
doRefNsName(cx, frame, stack, sDbl, stackTop, indexReg);
continue Loop;
}
case Icode_SCOPE_LOAD:
indexReg += frame.localShift;
frame.scope = (Scriptable) stack[indexReg];
continue Loop;
case Icode_SCOPE_SAVE:
indexReg += frame.localShift;
stack[indexReg] = frame.scope;
continue Loop;
case Icode_CLOSURE_EXPR:
InterpretedFunction fn =
InterpretedFunction.createFunction(
cx, frame.scope, frame.fnOrScript, indexReg);
if (fn.idata.itsFunctionType == FunctionNode.ARROW_FUNCTION) {
stack[++stackTop] =
new ArrowFunction(cx, frame.scope, fn, frame.thisObj);
} else {
stack[++stackTop] = fn;
}
continue Loop;
case Icode_CLOSURE_STMT:
initFunction(cx, frame.scope, frame.fnOrScript, indexReg);
continue Loop;
case Token.REGEXP:
Object re = frame.idata.itsRegExpLiterals[indexReg];
stack[++stackTop] = ScriptRuntime.wrapRegExp(cx, frame.scope, re);
continue Loop;
case Icode_TEMPLATE_LITERAL_CALLSITE:
Object[] templateLiterals = frame.idata.itsTemplateLiterals;
stack[++stackTop] =
ScriptRuntime.getTemplateLiteralCallSite(
cx, frame.scope, templateLiterals, indexReg);
continue Loop;
case Icode_LITERAL_NEW:
// indexReg: number of values in the literal
++stackTop;
stack[stackTop] = new int[indexReg];
++stackTop;
stack[stackTop] = new Object[indexReg];
sDbl[stackTop] = 0;
continue Loop;
case Icode_LITERAL_SET:
{
Object value = stack[stackTop];
if (value == DBL_MRK)
value = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
int i = (int) sDbl[stackTop];
((Object[]) stack[stackTop])[i] = value;
sDbl[stackTop] = i + 1;
continue Loop;
}
case Icode_LITERAL_GETTER:
{
Object value = stack[stackTop];
--stackTop;
int i = (int) sDbl[stackTop];
((Object[]) stack[stackTop])[i] = value;
((int[]) stack[stackTop - 1])[i] = -1;
sDbl[stackTop] = i + 1;
continue Loop;
}
case Icode_LITERAL_SETTER:
{
Object value = stack[stackTop];
--stackTop;
int i = (int) sDbl[stackTop];
((Object[]) stack[stackTop])[i] = value;
((int[]) stack[stackTop - 1])[i] = 1;
sDbl[stackTop] = i + 1;
continue Loop;
}
case Token.ARRAYLIT:
case Icode_SPARE_ARRAYLIT:
case Token.OBJECTLIT:
{
Object[] data = (Object[]) stack[stackTop];
--stackTop;
int[] getterSetters = (int[]) stack[stackTop];
Object val;
if (op == Token.OBJECTLIT) {
Object[] ids = (Object[]) frame.idata.literalIds[indexReg];
val =
ScriptRuntime.newObjectLiteral(
ids, data, getterSetters, cx, frame.scope);
} else {
int[] skipIndexces = null;
if (op == Icode_SPARE_ARRAYLIT) {
skipIndexces = (int[]) frame.idata.literalIds[indexReg];
}
val =
ScriptRuntime.newArrayLiteral(
data, skipIndexces, cx, frame.scope);
}
stack[stackTop] = val;
continue Loop;
}
case Icode_ENTERDQ:
{
Object lhs = stack[stackTop];
if (lhs == DBL_MRK)
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
frame.scope = ScriptRuntime.enterDotQuery(lhs, frame.scope);
continue Loop;
}
case Icode_LEAVEDQ:
{
boolean valBln = stack_boolean(frame, stackTop);
Object x = ScriptRuntime.updateDotQuery(valBln, frame.scope);
if (x != null) {
stack[stackTop] = x;
frame.scope = ScriptRuntime.leaveDotQuery(frame.scope);
frame.pc += 2;
continue Loop;
}
// reset stack and PC to code after ENTERDQ
--stackTop;
break jumplessRun;
}
case Token.DEFAULTNAMESPACE:
{
Object value = stack[stackTop];
if (value == DBL_MRK)
value = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] = ScriptRuntime.setDefaultNamespace(value, cx);
continue Loop;
}
case Token.ESCXMLATTR:
{
Object value = stack[stackTop];
if (value != DBL_MRK) {
stack[stackTop] =
ScriptRuntime.escapeAttributeValue(value, cx);
}
continue Loop;
}
case Token.ESCXMLTEXT:
{
Object value = stack[stackTop];
if (value != DBL_MRK) {
stack[stackTop] = ScriptRuntime.escapeTextValue(value, cx);
}
continue Loop;
}
case Icode_DEBUGGER:
if (frame.debuggerFrame != null) {
frame.debuggerFrame.onDebuggerStatement(cx);
}
continue Loop;
case Icode_LINE:
frame.pcSourceLineStart = frame.pc;
if (frame.debuggerFrame != null) {
int line = getIndex(iCode, frame.pc);
frame.debuggerFrame.onLineChange(cx, line);
}
frame.pc += 2;
continue Loop;
case Icode_REG_IND_C0:
indexReg = 0;
continue Loop;
case Icode_REG_IND_C1:
indexReg = 1;
continue Loop;
case Icode_REG_IND_C2:
indexReg = 2;
continue Loop;
case Icode_REG_IND_C3:
indexReg = 3;
continue Loop;
case Icode_REG_IND_C4:
indexReg = 4;
continue Loop;
case Icode_REG_IND_C5:
indexReg = 5;
continue Loop;
case Icode_REG_IND1:
indexReg = 0xFF & iCode[frame.pc];
++frame.pc;
continue Loop;
case Icode_REG_IND2:
indexReg = getIndex(iCode, frame.pc);
frame.pc += 2;
continue Loop;
case Icode_REG_IND4:
indexReg = getInt(iCode, frame.pc);
frame.pc += 4;
continue Loop;
case Icode_REG_STR_C0:
stringReg = strings[0];
continue Loop;
case Icode_REG_STR_C1:
stringReg = strings[1];
continue Loop;
case Icode_REG_STR_C2:
stringReg = strings[2];
continue Loop;
case Icode_REG_STR_C3:
stringReg = strings[3];
continue Loop;
case Icode_REG_STR1:
stringReg = strings[0xFF & iCode[frame.pc]];
++frame.pc;
continue Loop;
case Icode_REG_STR2:
stringReg = strings[getIndex(iCode, frame.pc)];
frame.pc += 2;
continue Loop;
case Icode_REG_STR4:
stringReg = strings[getInt(iCode, frame.pc)];
frame.pc += 4;
continue Loop;
case Icode_REG_BIGINT_C0:
bigIntReg = bigInts[0];
continue Loop;
case Icode_REG_BIGINT_C1:
bigIntReg = bigInts[1];
continue Loop;
case Icode_REG_BIGINT_C2:
bigIntReg = bigInts[2];
continue Loop;
case Icode_REG_BIGINT_C3:
bigIntReg = bigInts[3];
continue Loop;
case Icode_REG_BIGINT1:
bigIntReg = bigInts[0xFF & iCode[frame.pc]];
++frame.pc;
continue Loop;
case Icode_REG_BIGINT2:
bigIntReg = bigInts[getIndex(iCode, frame.pc)];
frame.pc += 2;
continue Loop;
case Icode_REG_BIGINT4:
bigIntReg = bigInts[getInt(iCode, frame.pc)];
frame.pc += 4;
continue Loop;
default:
dumpICode(frame.idata);
throw new RuntimeException(
"Unknown icode : " + op + " @ pc : " + (frame.pc - 1));
} // end of interpreter switch
} // end of jumplessRun label block
// This should be reachable only for jump implementation
// when pc points to encoded target offset
if (instructionCounting) {
addInstructionCount(cx, frame, 2);
}
int offset = getShort(iCode, frame.pc);
if (offset != 0) {
// -1 accounts for pc pointing to jump opcode + 1
frame.pc += offset - 1;
} else {
frame.pc = frame.idata.longJumps.getExistingInt(frame.pc);
}
if (instructionCounting) {
frame.pcPrevBranch = frame.pc;
}
continue Loop;
} // end of Loop: for
exitFrame(cx, frame, null);
interpreterResult = frame.result;
interpreterResultDbl = frame.resultDbl;
if (frame.parentFrame != null) {
frame = frame.parentFrame;
if (frame.frozen) {
frame = frame.cloneFrozen();
}
setCallResult(frame, interpreterResult, interpreterResultDbl);
interpreterResult = null; // Help GC
continue StateLoop;
}
break StateLoop;
} // end of interpreter withoutExceptions: try
catch (Throwable ex) {
if (throwable != null) {
// This is serious bug and it is better to track it ASAP
ex.printStackTrace(System.err);
throw new IllegalStateException();
}
throwable = ex;
}
// This should be reachable only after above catch or from
// finally when it needs to propagate exception or from
// explicit throw
if (throwable == null) Kit.codeBug();
// Exception type
final int EX_CATCH_STATE = 2; // Can execute JS catch
final int EX_FINALLY_STATE = 1; // Can execute JS finally
final int EX_NO_JS_STATE = 0; // Terminate JS execution
int exState;
ContinuationJump cjump = null;
if (generatorState != null
&& generatorState.operation == NativeGenerator.GENERATOR_CLOSE
&& throwable == generatorState.value) {
exState = EX_FINALLY_STATE;
} else if (throwable instanceof JavaScriptException) {
exState = EX_CATCH_STATE;
} else if (throwable instanceof EcmaError) {
// an offical ECMA error object,
exState = EX_CATCH_STATE;
} else if (throwable instanceof EvaluatorException) {
exState = EX_CATCH_STATE;
} else if (throwable instanceof ContinuationPending) {
exState = EX_NO_JS_STATE;
} else if (throwable instanceof RuntimeException) {
exState =
cx.hasFeature(Context.FEATURE_ENHANCED_JAVA_ACCESS)
? EX_CATCH_STATE
: EX_FINALLY_STATE;
} else if (throwable instanceof Error) {
exState =
cx.hasFeature(Context.FEATURE_ENHANCED_JAVA_ACCESS)
? EX_CATCH_STATE
: EX_NO_JS_STATE;
} else if (throwable instanceof ContinuationJump) {
// It must be ContinuationJump
exState = EX_FINALLY_STATE;
cjump = (ContinuationJump) throwable;
} else {
exState =
cx.hasFeature(Context.FEATURE_ENHANCED_JAVA_ACCESS)
? EX_CATCH_STATE
: EX_FINALLY_STATE;
}
if (instructionCounting) {
try {
addInstructionCount(cx, frame, EXCEPTION_COST);
} catch (RuntimeException ex) {
throwable = ex;
exState = EX_FINALLY_STATE;
} catch (Error ex) {
// Error from instruction counting
// => unconditionally terminate JS
throwable = ex;
cjump = null;
exState = EX_NO_JS_STATE;
}
}
if (frame.debuggerFrame != null && throwable instanceof RuntimeException) {
// Call debugger only for RuntimeException
RuntimeException rex = (RuntimeException) throwable;
try {
frame.debuggerFrame.onExceptionThrown(cx, rex);
} catch (Throwable ex) {
// Any exception from debugger
// => unconditionally terminate JS
throwable = ex;
cjump = null;
exState = EX_NO_JS_STATE;
}
}
for (; ; ) {
if (exState != EX_NO_JS_STATE) {
boolean onlyFinally = (exState != EX_CATCH_STATE);
indexReg = getExceptionHandler(frame, onlyFinally);
if (indexReg >= 0) {
// We caught an exception, restart the loop
// with exception pending the processing at the loop
// start
continue StateLoop;
}
}
// No allowed exception handlers in this frame, unwind
// to parent and try to look there
exitFrame(cx, frame, throwable);
frame = frame.parentFrame;
if (frame == null) {
break;
}
if (cjump != null && cjump.branchFrame == frame) {
// Continuation branch point was hit,
// restart the state loop to reenter continuation
indexReg = -1;
continue StateLoop;
}
}
// No more frames, rethrow the exception or deal with continuation
if (cjump != null) {
if (cjump.branchFrame != null) {
// The above loop should locate the top frame
Kit.codeBug();
}
if (cjump.capturedFrame != null) {
// Restarting detached continuation
indexReg = -1;
continue StateLoop;
}
// Return continuation result to the caller
interpreterResult = cjump.result;
interpreterResultDbl = cjump.resultDbl;
throwable = null;
}
break StateLoop;
} // end of StateLoop: for(;;)
// Do cleanups/restorations before the final return or throw
if (cx.previousInterpreterInvocations != null
&& cx.previousInterpreterInvocations.size() != 0) {
cx.lastInterpreterFrame = cx.previousInterpreterInvocations.pop();
} else {
// It was the last interpreter frame on the stack
cx.lastInterpreterFrame = null;
// Force GC of the value cx.previousInterpreterInvocations
cx.previousInterpreterInvocations = null;
}
if (throwable != null) {
if (throwable instanceof RuntimeException) {
throw (RuntimeException) throwable;
}
// Must be instance of Error or code bug
throw (Error) throwable;
}
return (interpreterResult != DBL_MRK)
? interpreterResult
: ScriptRuntime.wrapNumber(interpreterResultDbl);
}
private static int doInOrInstanceof(
Context cx, int op, Object[] stack, double[] sDbl, int stackTop) {
Object rhs = stack[stackTop];
if (rhs == DOUBLE_MARK) rhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Object lhs = stack[stackTop];
if (lhs == DOUBLE_MARK) lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
boolean valBln;
if (op == Token.IN) {
valBln = ScriptRuntime.in(lhs, rhs, cx);
} else {
valBln = ScriptRuntime.instanceOf(lhs, rhs, cx);
}
stack[stackTop] = ScriptRuntime.wrapBoolean(valBln);
return stackTop;
}
private static int doCompare(
CallFrame frame, int op, Object[] stack, double[] sDbl, int stackTop) {
--stackTop;
Object rhs = stack[stackTop + 1];
Object lhs = stack[stackTop];
boolean valBln;
object_compare:
{
number_compare:
{
Number rNum, lNum;
if (rhs == DOUBLE_MARK) {
rNum = sDbl[stackTop + 1];
lNum = stack_numeric(frame, stackTop);
} else if (lhs == DOUBLE_MARK) {
rNum = ScriptRuntime.toNumeric(rhs);
lNum = sDbl[stackTop];
} else {
break number_compare;
}
valBln = ScriptRuntime.compare(lNum, rNum, op);
break object_compare;
}
valBln = ScriptRuntime.compare(lhs, rhs, op);
}
stack[stackTop] = ScriptRuntime.wrapBoolean(valBln);
return stackTop;
}
private static int doBitOp(
CallFrame frame, int op, Object[] stack, double[] sDbl, int stackTop) {
Number lValue = stack_numeric(frame, stackTop - 1);
Number rValue = stack_numeric(frame, stackTop);
stackTop--;
Number result = null;
switch (op) {
case Token.BITAND:
result = ScriptRuntime.bitwiseAND(lValue, rValue);
break;
case Token.BITOR:
result = ScriptRuntime.bitwiseOR(lValue, rValue);
break;
case Token.BITXOR:
result = ScriptRuntime.bitwiseXOR(lValue, rValue);
break;
case Token.LSH:
result = ScriptRuntime.leftShift(lValue, rValue);
break;
case Token.RSH:
result = ScriptRuntime.signedRightShift(lValue, rValue);
break;
}
if (result instanceof BigInteger) {
stack[stackTop] = result;
} else {
stack[stackTop] = DOUBLE_MARK;
sDbl[stackTop] = result.doubleValue();
}
return stackTop;
}
private static int doBitNOT(CallFrame frame, Object[] stack, double[] sDbl, int stackTop) {
Number value = stack_numeric(frame, stackTop);
Number result = ScriptRuntime.bitwiseNOT(value);
if (result instanceof BigInteger) {
stack[stackTop] = result;
} else {
stack[stackTop] = DOUBLE_MARK;
sDbl[stackTop] = result.doubleValue();
}
return stackTop;
}
private static int doDelName(
Context cx, CallFrame frame, int op, Object[] stack, double[] sDbl, int stackTop) {
Object rhs = stack[stackTop];
if (rhs == DOUBLE_MARK) rhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Object lhs = stack[stackTop];
if (lhs == DOUBLE_MARK) lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] = ScriptRuntime.delete(lhs, rhs, cx, frame.scope, op == Icode_DELNAME);
return stackTop;
}
private static int doGetElem(
Context cx, CallFrame frame, Object[] stack, double[] sDbl, int stackTop) {
--stackTop;
Object lhs = stack[stackTop];
if (lhs == DOUBLE_MARK) {
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
}
Object value;
Object id = stack[stackTop + 1];
if (id != DOUBLE_MARK) {
value = ScriptRuntime.getObjectElem(lhs, id, cx, frame.scope);
} else {
double d = sDbl[stackTop + 1];
value = ScriptRuntime.getObjectIndex(lhs, d, cx, frame.scope);
}
stack[stackTop] = value;
return stackTop;
}
private static int doSetElem(
Context cx, CallFrame frame, Object[] stack, double[] sDbl, int stackTop) {
stackTop -= 2;
Object rhs = stack[stackTop + 2];
if (rhs == DOUBLE_MARK) {
rhs = ScriptRuntime.wrapNumber(sDbl[stackTop + 2]);
}
Object lhs = stack[stackTop];
if (lhs == DOUBLE_MARK) {
lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
}
Object value;
Object id = stack[stackTop + 1];
if (id != DOUBLE_MARK) {
value = ScriptRuntime.setObjectElem(lhs, id, rhs, cx, frame.scope);
} else {
double d = sDbl[stackTop + 1];
value = ScriptRuntime.setObjectIndex(lhs, d, rhs, cx, frame.scope);
}
stack[stackTop] = value;
return stackTop;
}
private static int doElemIncDec(
Context cx,
CallFrame frame,
byte[] iCode,
Object[] stack,
double[] sDbl,
int stackTop) {
Object rhs = stack[stackTop];
if (rhs == DOUBLE_MARK) rhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Object lhs = stack[stackTop];
if (lhs == DOUBLE_MARK) lhs = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] = ScriptRuntime.elemIncrDecr(lhs, rhs, cx, frame.scope, iCode[frame.pc]);
++frame.pc;
return stackTop;
}
private static int doCallSpecial(
Context cx,
CallFrame frame,
Object[] stack,
double[] sDbl,
int stackTop,
byte[] iCode,
int indexReg) {
int callType = iCode[frame.pc] & 0xFF;
boolean isNew = (iCode[frame.pc + 1] != 0);
int sourceLine = getIndex(iCode, frame.pc + 2);
// indexReg: number of arguments
if (isNew) {
// stack change: function arg0 .. argN -> newResult
stackTop -= indexReg;
Object function = stack[stackTop];
if (function == DOUBLE_MARK) function = ScriptRuntime.wrapNumber(sDbl[stackTop]);
Object[] outArgs = getArgsArray(stack, sDbl, stackTop + 1, indexReg);
stack[stackTop] =
ScriptRuntime.newSpecial(cx, function, outArgs, frame.scope, callType);
} else {
// stack change: function thisObj arg0 .. argN -> result
stackTop -= 1 + indexReg;
// Call code generation ensure that stack here
// is ... Callable Scriptable
Scriptable functionThis = (Scriptable) stack[stackTop + 1];
Callable function = (Callable) stack[stackTop];
Object[] outArgs = getArgsArray(stack, sDbl, stackTop + 2, indexReg);
stack[stackTop] =
ScriptRuntime.callSpecial(
cx,
function,
functionThis,
outArgs,
frame.scope,
frame.thisObj,
callType,
frame.idata.itsSourceFile,
sourceLine);
}
frame.pc += 4;
return stackTop;
}
private static int doSetConstVar(
CallFrame frame,
Object[] stack,
double[] sDbl,
int stackTop,
Object[] vars,
double[] varDbls,
int[] varAttributes,
int indexReg) {
if (!frame.useActivation) {
if ((varAttributes[indexReg] & ScriptableObject.READONLY) == 0) {
throw Context.reportRuntimeErrorById(
"msg.var.redecl", frame.idata.argNames[indexReg]);
}
if ((varAttributes[indexReg] & ScriptableObject.UNINITIALIZED_CONST) != 0) {
vars[indexReg] = stack[stackTop];
varAttributes[indexReg] &= ~ScriptableObject.UNINITIALIZED_CONST;
varDbls[indexReg] = sDbl[stackTop];
}
} else {
Object val = stack[stackTop];
if (val == DOUBLE_MARK) val = ScriptRuntime.wrapNumber(sDbl[stackTop]);
String stringReg = frame.idata.argNames[indexReg];
if (frame.scope instanceof ConstProperties) {
ConstProperties cp = (ConstProperties) frame.scope;
cp.putConst(stringReg, frame.scope, val);
} else throw Kit.codeBug();
}
return stackTop;
}
private static int doSetVar(
CallFrame frame,
Object[] stack,
double[] sDbl,
int stackTop,
Object[] vars,
double[] varDbls,
int[] varAttributes,
int indexReg) {
if (!frame.useActivation) {
if ((varAttributes[indexReg] & ScriptableObject.READONLY) == 0) {
vars[indexReg] = stack[stackTop];
varDbls[indexReg] = sDbl[stackTop];
}
} else {
Object val = stack[stackTop];
if (val == DOUBLE_MARK) val = ScriptRuntime.wrapNumber(sDbl[stackTop]);
String stringReg = frame.idata.argNames[indexReg];
frame.scope.put(stringReg, frame.scope, val);
}
return stackTop;
}
private static int doGetVar(
CallFrame frame,
Object[] stack,
double[] sDbl,
int stackTop,
Object[] vars,
double[] varDbls,
int indexReg) {
++stackTop;
if (!frame.useActivation) {
stack[stackTop] = vars[indexReg];
sDbl[stackTop] = varDbls[indexReg];
} else {
String stringReg = frame.idata.argNames[indexReg];
stack[stackTop] = frame.scope.get(stringReg, frame.scope);
}
return stackTop;
}
private static int doVarIncDec(
Context cx,
CallFrame frame,
Object[] stack,
double[] sDbl,
int stackTop,
Object[] vars,
double[] varDbls,
int[] varAttributes,
int indexReg) {
// indexReg : varindex
++stackTop;
int incrDecrMask = frame.idata.itsICode[frame.pc];
if (!frame.useActivation) {
Object varValue = vars[indexReg];
double d = 0.0;
BigInteger bi = null;
if (varValue == DOUBLE_MARK) {
d = varDbls[indexReg];
} else {
Number num = ScriptRuntime.toNumeric(varValue);
if (num instanceof BigInteger) {
bi = (BigInteger) num;
} else {
d = num.doubleValue();
}
}
if (bi == null) {
// double
double d2 = ((incrDecrMask & Node.DECR_FLAG) == 0) ? d + 1.0 : d - 1.0;
boolean post = ((incrDecrMask & Node.POST_FLAG) != 0);
if ((varAttributes[indexReg] & ScriptableObject.READONLY) == 0) {
if (varValue != DOUBLE_MARK) {
vars[indexReg] = DOUBLE_MARK;
}
varDbls[indexReg] = d2;
stack[stackTop] = DOUBLE_MARK;
sDbl[stackTop] = post ? d : d2;
} else {
if (post && varValue != DOUBLE_MARK) {
stack[stackTop] = varValue;
} else {
stack[stackTop] = DOUBLE_MARK;
sDbl[stackTop] = post ? d : d2;
}
}
} else {
// BigInt
BigInteger result;
if ((incrDecrMask & Node.DECR_FLAG) == 0) {
result = bi.add(BigInteger.ONE);
} else {
result = bi.subtract(BigInteger.ONE);
}
boolean post = ((incrDecrMask & Node.POST_FLAG) != 0);
if ((varAttributes[indexReg] & ScriptableObject.READONLY) == 0) {
vars[indexReg] = result;
stack[stackTop] = post ? bi : result;
} else {
if (post && varValue != DOUBLE_MARK) {
stack[stackTop] = varValue;
} else {
stack[stackTop] = post ? bi : result;
}
}
}
} else {
String varName = frame.idata.argNames[indexReg];
stack[stackTop] = ScriptRuntime.nameIncrDecr(frame.scope, varName, cx, incrDecrMask);
}
++frame.pc;
return stackTop;
}
private static int doRefMember(
Context cx, Object[] stack, double[] sDbl, int stackTop, int flags) {
Object elem = stack[stackTop];
if (elem == DOUBLE_MARK) elem = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Object obj = stack[stackTop];
if (obj == DOUBLE_MARK) obj = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] = ScriptRuntime.memberRef(obj, elem, cx, flags);
return stackTop;
}
private static int doRefNsMember(
Context cx, Object[] stack, double[] sDbl, int stackTop, int flags) {
Object elem = stack[stackTop];
if (elem == DOUBLE_MARK) elem = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Object ns = stack[stackTop];
if (ns == DOUBLE_MARK) ns = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Object obj = stack[stackTop];
if (obj == DOUBLE_MARK) obj = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] = ScriptRuntime.memberRef(obj, ns, elem, cx, flags);
return stackTop;
}
private static int doRefNsName(
Context cx, CallFrame frame, Object[] stack, double[] sDbl, int stackTop, int flags) {
Object name = stack[stackTop];
if (name == DOUBLE_MARK) name = ScriptRuntime.wrapNumber(sDbl[stackTop]);
--stackTop;
Object ns = stack[stackTop];
if (ns == DOUBLE_MARK) ns = ScriptRuntime.wrapNumber(sDbl[stackTop]);
stack[stackTop] = ScriptRuntime.nameRef(ns, name, cx, frame.scope, flags);
return stackTop;
}
/** Call __noSuchMethod__. */
private static CallFrame initFrameForNoSuchMethod(
Context cx,
CallFrame frame,
int indexReg,
Object[] stack,
double[] sDbl,
int stackTop,
int op,
Scriptable funThisObj,
Scriptable calleeScope,
NoSuchMethodShim noSuchMethodShim,
InterpretedFunction ifun) {
// create an args array from the stack
Object[] argsArray = null;
// exactly like getArgsArray except that the first argument
// is the method name from the shim
int shift = stackTop + 2;
Object[] elements = new Object[indexReg];
for (int i = 0; i < indexReg; ++i, ++shift) {
Object val = stack[shift];
if (val == DOUBLE_MARK) {
val = ScriptRuntime.wrapNumber(sDbl[shift]);
}
elements[i] = val;
}
argsArray = new Object[2];
argsArray[0] = noSuchMethodShim.methodName;
argsArray[1] = cx.newArray(calleeScope, elements);
// exactly the same as if it's a regular InterpretedFunction
CallFrame callParentFrame = frame;
if (op == Icode_TAIL_CALL) {
callParentFrame = frame.parentFrame;
exitFrame(cx, frame, null);
}
// init the frame with the underlying method with the
// adjusted args array and shim's function
CallFrame calleeFrame =
initFrame(
cx, calleeScope, funThisObj, argsArray, null, 0, 2, ifun, callParentFrame);
if (op != Icode_TAIL_CALL) {
frame.savedStackTop = stackTop;
frame.savedCallOp = op;
}
return calleeFrame;
}
private static boolean doEquals(Object[] stack, double[] sDbl, int stackTop) {
Object rhs = stack[stackTop + 1];
Object lhs = stack[stackTop];
if (rhs == DOUBLE_MARK) {
if (lhs == DOUBLE_MARK) {
return (sDbl[stackTop] == sDbl[stackTop + 1]);
}
return ScriptRuntime.eqNumber(sDbl[stackTop + 1], lhs);
}
if (lhs == DOUBLE_MARK) {
return ScriptRuntime.eqNumber(sDbl[stackTop], rhs);
}
return ScriptRuntime.eq(lhs, rhs);
}
private static boolean doShallowEquals(Object[] stack, double[] sDbl, int stackTop) {
Object rhs = stack[stackTop + 1];
Object lhs = stack[stackTop];
final Object DBL_MRK = DOUBLE_MARK;
double rdbl, ldbl;
if (rhs == DBL_MRK) {
rdbl = sDbl[stackTop + 1];
if (lhs == DBL_MRK) {
ldbl = sDbl[stackTop];
} else if (lhs instanceof Number && !(lhs instanceof BigInteger)) {
ldbl = ((Number) lhs).doubleValue();
} else {
return false;
}
} else if (lhs == DBL_MRK) {
ldbl = sDbl[stackTop];
if (rhs instanceof Number && !(rhs instanceof BigInteger)) {
rdbl = ((Number) rhs).doubleValue();
} else {
return false;
}
} else {
return ScriptRuntime.shallowEq(lhs, rhs);
}
return (ldbl == rdbl);
}
private static CallFrame processThrowable(
Context cx,
Object throwable,
CallFrame frame,
int indexReg,
boolean instructionCounting) {
// Recovering from exception, indexReg contains
// the index of handler
if (indexReg >= 0) {
// Normal exception handler, transfer
// control appropriately
if (frame.frozen) {
// XXX Deal with exceptios!!!
frame = frame.cloneFrozen();
}
int[] table = frame.idata.itsExceptionTable;
frame.pc = table[indexReg + EXCEPTION_HANDLER_SLOT];
if (instructionCounting) {
frame.pcPrevBranch = frame.pc;
}
frame.savedStackTop = frame.emptyStackTop;
int scopeLocal = frame.localShift + table[indexReg + EXCEPTION_SCOPE_SLOT];
int exLocal = frame.localShift + table[indexReg + EXCEPTION_LOCAL_SLOT];
frame.scope = (Scriptable) frame.stack[scopeLocal];
frame.stack[exLocal] = throwable;
throwable = null;
} else {
// Continuation restoration
ContinuationJump cjump = (ContinuationJump) throwable;
// Clear throwable to indicate that exceptions are OK
throwable = null;
if (cjump.branchFrame != frame) Kit.codeBug();
// Check that we have at least one frozen frame
// in the case of detached continuation restoration:
// unwind code ensure that
if (cjump.capturedFrame == null) Kit.codeBug();
// Need to rewind branchFrame, capturedFrame
// and all frames in between
int rewindCount = cjump.capturedFrame.frameIndex + 1;
if (cjump.branchFrame != null) {
rewindCount -= cjump.branchFrame.frameIndex;
}
int enterCount = 0;
CallFrame[] enterFrames = null;
CallFrame x = cjump.capturedFrame;
for (int i = 0; i != rewindCount; ++i) {
if (!x.frozen) Kit.codeBug();
if (x.useActivation) {
if (enterFrames == null) {
// Allocate enough space to store the rest
// of rewind frames in case all of them
// would require to enter
enterFrames = new CallFrame[rewindCount - i];
}
enterFrames[enterCount] = x;
++enterCount;
}
x = x.parentFrame;
}
while (enterCount != 0) {
// execute enter: walk enterFrames in the reverse
// order since they were stored starting from
// the capturedFrame, not branchFrame
--enterCount;
x = enterFrames[enterCount];
enterFrame(cx, x, ScriptRuntime.emptyArgs, true);
}
// Continuation jump is almost done: capturedFrame
// points to the call to the function that captured
// continuation, so clone capturedFrame and
// emulate return that function with the suplied result
frame = cjump.capturedFrame.cloneFrozen();
setCallResult(frame, cjump.result, cjump.resultDbl);
// restart the execution
}
frame.throwable = throwable;
return frame;
}
private static Object freezeGenerator(
Context cx,
CallFrame frame,
int stackTop,
GeneratorState generatorState,
boolean yieldStar) {
if (generatorState.operation == NativeGenerator.GENERATOR_CLOSE) {
// Error: no yields when generator is closing
throw ScriptRuntime.typeErrorById("msg.yield.closing");
}
// return to our caller (which should be a method of NativeGenerator)
frame.frozen = true;
frame.result = frame.stack[stackTop];
frame.resultDbl = frame.sDbl[stackTop];
frame.savedStackTop = stackTop;
frame.pc--; // we want to come back here when we resume
ScriptRuntime.exitActivationFunction(cx);
final Object result =
(frame.result != DOUBLE_MARK)
? frame.result
: ScriptRuntime.wrapNumber(frame.resultDbl);
if (yieldStar) {
return new ES6Generator.YieldStarResult(result);
}
return result;
}
private static Object thawGenerator(
CallFrame frame, int stackTop, GeneratorState generatorState, int op) {
// we are resuming execution
frame.frozen = false;
int sourceLine = getIndex(frame.idata.itsICode, frame.pc);
frame.pc += 2; // skip line number data
if (generatorState.operation == NativeGenerator.GENERATOR_THROW) {
// processing a call to .throw(exception): must
// act as if exception was thrown from resumption point.
return new JavaScriptException(
generatorState.value, frame.idata.itsSourceFile, sourceLine);
}
if (generatorState.operation == NativeGenerator.GENERATOR_CLOSE) {
return generatorState.value;
}
if (generatorState.operation != NativeGenerator.GENERATOR_SEND) throw Kit.codeBug();
if ((op == Token.YIELD) || (op == Icode_YIELD_STAR)) {
frame.stack[stackTop] = generatorState.value;
}
return Scriptable.NOT_FOUND;
}
private static CallFrame initFrameForApplyOrCall(
Context cx,
CallFrame frame,
int indexReg,
Object[] stack,
double[] sDbl,
int stackTop,
int op,
Scriptable calleeScope,
IdFunctionObject ifun,
InterpretedFunction iApplyCallable) {
Scriptable applyThis;
if (indexReg != 0) {
Object obj = stack[stackTop + 2];
if (obj == DOUBLE_MARK) obj = ScriptRuntime.wrapNumber(sDbl[stackTop + 2]);
applyThis = ScriptRuntime.toObjectOrNull(cx, obj, frame.scope);
} else {
applyThis = null;
}
if (applyThis == null) {
// This covers the case of args[0] == (null|undefined) as well.
applyThis = ScriptRuntime.getTopCallScope(cx);
}
if (op == Icode_TAIL_CALL) {
exitFrame(cx, frame, null);
frame = frame.parentFrame;
} else {
frame.savedStackTop = stackTop;
frame.savedCallOp = op;
}
final CallFrame calleeFrame;
if (BaseFunction.isApply(ifun)) {
Object[] callArgs =
indexReg < 2
? ScriptRuntime.emptyArgs
: ScriptRuntime.getApplyArguments(cx, stack[stackTop + 3]);
calleeFrame =
initFrame(
cx,
calleeScope,
applyThis,
callArgs,
null,
0,
callArgs.length,
iApplyCallable,
frame);
} else {
// Shift args left
for (int i = 1; i < indexReg; ++i) {
stack[stackTop + 1 + i] = stack[stackTop + 2 + i];
sDbl[stackTop + 1 + i] = sDbl[stackTop + 2 + i];
}
int argCount = indexReg < 2 ? 0 : indexReg - 1;
calleeFrame =
initFrame(
cx,
calleeScope,
applyThis,
stack,
sDbl,
stackTop + 2,
argCount,
iApplyCallable,
frame);
}
return calleeFrame;
}
private static CallFrame initFrame(
Context cx,
Scriptable callerScope,
Scriptable thisObj,
Object[] args,
double[] argsDbl,
int argShift,
int argCount,
InterpretedFunction fnOrScript,
CallFrame parentFrame) {
CallFrame frame = new CallFrame(cx, thisObj, fnOrScript, parentFrame);
frame.initializeArgs(cx, callerScope, args, argsDbl, argShift, argCount);
enterFrame(cx, frame, args, false);
return frame;
}
private static void enterFrame(
Context cx, CallFrame frame, Object[] args, boolean continuationRestart) {
boolean usesActivation = frame.idata.itsNeedsActivation;
boolean isDebugged = frame.debuggerFrame != null;
if (usesActivation || isDebugged) {
Scriptable scope = frame.scope;
if (scope == null) {
Kit.codeBug();
} else if (continuationRestart) {
// Walk the parent chain of frame.scope until a NativeCall is
// found. Normally, frame.scope is a NativeCall when called
// from initFrame() for a debugged or activatable function.
// However, when called from interpretLoop() as part of
// restarting a continuation, it can also be a NativeWith if
// the continuation was captured within a "with" or "catch"
// block ("catch" implicitly uses NativeWith to create a scope
// to expose the exception variable).
for (; ; ) {
if (scope instanceof NativeWith) {
scope = scope.getParentScope();
if (scope == null
|| (frame.parentFrame != null
&& frame.parentFrame.scope == scope)) {
// If we get here, we didn't find a NativeCall in
// the call chain before reaching parent frame's
// scope. This should not be possible.
Kit.codeBug();
break; // Never reached, but keeps the static analyzer
// happy about "scope" not being null 5 lines above.
}
} else {
break;
}
}
}
if (isDebugged) {
frame.debuggerFrame.onEnter(cx, scope, frame.thisObj, args);
}
// Enter activation only when itsNeedsActivation true,
// since debugger should not interfere with activation
// chaining
if (usesActivation) {
ScriptRuntime.enterActivationFunction(cx, scope);
}
}
}
private static void exitFrame(Context cx, CallFrame frame, Object throwable) {
if (frame.idata.itsNeedsActivation) {
ScriptRuntime.exitActivationFunction(cx);
}
if (frame.debuggerFrame != null) {
try {
if (throwable instanceof Throwable) {
frame.debuggerFrame.onExit(cx, true, throwable);
} else {
Object result;
ContinuationJump cjump = (ContinuationJump) throwable;
if (cjump == null) {
result = frame.result;
} else {
result = cjump.result;
}
if (result == DOUBLE_MARK) {
double resultDbl;
if (cjump == null) {
resultDbl = frame.resultDbl;
} else {
resultDbl = cjump.resultDbl;
}
result = ScriptRuntime.wrapNumber(resultDbl);
}
frame.debuggerFrame.onExit(cx, false, result);
}
} catch (Throwable ex) {
System.err.println("RHINO USAGE WARNING: onExit terminated with exception");
ex.printStackTrace(System.err);
}
}
}
private static void setCallResult(CallFrame frame, Object callResult, double callResultDbl) {
if (frame.savedCallOp == Token.CALL) {
frame.stack[frame.savedStackTop] = callResult;
frame.sDbl[frame.savedStackTop] = callResultDbl;
} else if (frame.savedCallOp == Token.NEW) {
// If construct returns scriptable,
// then it replaces on stack top saved original instance
// of the object.
if (callResult instanceof Scriptable) {
frame.stack[frame.savedStackTop] = callResult;
}
} else {
Kit.codeBug();
}
frame.savedCallOp = 0;
}
public static NativeContinuation captureContinuation(Context cx) {
if (cx.lastInterpreterFrame == null || !(cx.lastInterpreterFrame instanceof CallFrame)) {
throw new IllegalStateException("Interpreter frames not found");
}
return captureContinuation(cx, (CallFrame) cx.lastInterpreterFrame, true);
}
private static NativeContinuation captureContinuation(
Context cx, CallFrame frame, boolean requireContinuationsTopFrame) {
NativeContinuation c = new NativeContinuation();
ScriptRuntime.setObjectProtoAndParent(c, ScriptRuntime.getTopCallScope(cx));
// Make sure that all frames are frozen
CallFrame x = frame;
CallFrame outermost = frame;
while (x != null && !x.frozen) {
x.frozen = true;
// Allow to GC unused stack space
for (int i = x.savedStackTop + 1; i != x.stack.length; ++i) {
// Allow to GC unused stack space
x.stack[i] = null;
x.stackAttributes[i] = ScriptableObject.EMPTY;
}
if (x.savedCallOp == Token.CALL) {
// the call will always overwrite the stack top with the result
x.stack[x.savedStackTop] = null;
} else {
if (x.savedCallOp != Token.NEW) Kit.codeBug();
// the new operator uses stack top to store the constructed
// object so it shall not be cleared: see comments in
// setCallResult
}
outermost = x;
x = x.parentFrame;
}
if (requireContinuationsTopFrame) {
while (outermost.parentFrame != null) outermost = outermost.parentFrame;
if (!outermost.isContinuationsTopFrame) {
throw new IllegalStateException(
"Cannot capture continuation "
+ "from JavaScript code not called directly by "
+ "executeScriptWithContinuations or "
+ "callFunctionWithContinuations");
}
}
c.initImplementation(frame);
return c;
}
private static int stack_int32(CallFrame frame, int i) {
Object x = frame.stack[i];
if (x == UniqueTag.DOUBLE_MARK) {
return ScriptRuntime.toInt32(frame.sDbl[i]);
}
return ScriptRuntime.toInt32(x);
}
private static double stack_double(CallFrame frame, int i) {
Object x = frame.stack[i];
if (x != UniqueTag.DOUBLE_MARK) {
return ScriptRuntime.toNumber(x);
}
return frame.sDbl[i];
}
private static Number stack_numeric(CallFrame frame, int i) {
Object x = frame.stack[i];
if (x != UniqueTag.DOUBLE_MARK) {
return ScriptRuntime.toNumeric(x);
}
return frame.sDbl[i];
}
private static boolean stack_boolean(CallFrame frame, int i) {
Object x = frame.stack[i];
if (Boolean.TRUE.equals(x)) {
return true;
} else if (Boolean.FALSE.equals(x)) {
return false;
} else if (x == UniqueTag.DOUBLE_MARK) {
double d = frame.sDbl[i];
return !Double.isNaN(d) && d != 0.0;
} else if (x == null || x == Undefined.instance) {
return false;
} else if (x instanceof BigInteger) {
return !x.equals(BigInteger.ZERO);
} else if (x instanceof Number) {
double d = ((Number) x).doubleValue();
return (!Double.isNaN(d) && d != 0.0);
} else {
return ScriptRuntime.toBoolean(x);
}
}
private static void doAdd(Object[] stack, double[] sDbl, int stackTop, Context cx) {
Object rhs = stack[stackTop + 1];
Object lhs = stack[stackTop];
double d;
boolean leftRightOrder;
if (rhs == DOUBLE_MARK) {
d = sDbl[stackTop + 1];
if (lhs == DOUBLE_MARK) {
sDbl[stackTop] += d;
return;
}
leftRightOrder = true;
// fallthrough to object + number code
} else if (lhs == DOUBLE_MARK) {
d = sDbl[stackTop];
lhs = rhs;
leftRightOrder = false;
// fallthrough to object + number code
} else {
if (lhs instanceof Scriptable || rhs instanceof Scriptable) {
stack[stackTop] = ScriptRuntime.add(lhs, rhs, cx);
// the next two else if branches are a bit more tricky
// to reduce method calls
} else if (lhs instanceof CharSequence) {
if (rhs instanceof CharSequence) {
stack[stackTop] = new ConsString((CharSequence) lhs, (CharSequence) rhs);
} else {
stack[stackTop] =
new ConsString((CharSequence) lhs, ScriptRuntime.toCharSequence(rhs));
}
} else if (rhs instanceof CharSequence) {
stack[stackTop] =
new ConsString(ScriptRuntime.toCharSequence(lhs), (CharSequence) rhs);
} else {
Number lNum = (lhs instanceof Number) ? (Number) lhs : ScriptRuntime.toNumeric(lhs);
Number rNum = (rhs instanceof Number) ? (Number) rhs : ScriptRuntime.toNumeric(rhs);
if (lNum instanceof BigInteger && rNum instanceof BigInteger) {
stack[stackTop] = ((BigInteger) lNum).add((BigInteger) rNum);
} else if (lNum instanceof BigInteger || rNum instanceof BigInteger) {
throw ScriptRuntime.typeErrorById("msg.cant.convert.to.number", "BigInt");
} else {
stack[stackTop] = DOUBLE_MARK;
sDbl[stackTop] = lNum.doubleValue() + rNum.doubleValue();
}
}
return;
}
// handle object(lhs) + number(d) code
if (lhs instanceof Scriptable) {
rhs = ScriptRuntime.wrapNumber(d);
if (!leftRightOrder) {
Object tmp = lhs;
lhs = rhs;
rhs = tmp;
}
stack[stackTop] = ScriptRuntime.add(lhs, rhs, cx);
} else if (lhs instanceof CharSequence) {
CharSequence rstr = ScriptRuntime.numberToString(d, 10);
if (leftRightOrder) {
stack[stackTop] = new ConsString((CharSequence) lhs, rstr);
} else {
stack[stackTop] = new ConsString(rstr, (CharSequence) lhs);
}
} else {
Number lNum = (lhs instanceof Number) ? (Number) lhs : ScriptRuntime.toNumeric(lhs);
if (lNum instanceof BigInteger) {
throw ScriptRuntime.typeErrorById("msg.cant.convert.to.number", "BigInt");
} else {
stack[stackTop] = DOUBLE_MARK;
sDbl[stackTop] = lNum.doubleValue() + d;
}
}
}
private static int doArithmetic(
CallFrame frame, int op, Object[] stack, double[] sDbl, int stackTop) {
Number lNum = stack_numeric(frame, stackTop - 1);
Number rNum = stack_numeric(frame, stackTop);
--stackTop;
Number result = null;
switch (op) {
case Token.SUB:
result = ScriptRuntime.subtract(lNum, rNum);
break;
case Token.MUL:
result = ScriptRuntime.multiply(lNum, rNum);
break;
case Token.DIV:
result = ScriptRuntime.divide(lNum, rNum);
break;
case Token.MOD:
result = ScriptRuntime.remainder(lNum, rNum);
break;
case Token.EXP:
result = ScriptRuntime.exponentiate(lNum, rNum);
break;
}
if (result instanceof BigInteger) {
stack[stackTop] = result;
} else {
stack[stackTop] = DOUBLE_MARK;
sDbl[stackTop] = result.doubleValue();
}
return stackTop;
}
private static Object[] getArgsArray(Object[] stack, double[] sDbl, int shift, int count) {
if (count == 0) {
return ScriptRuntime.emptyArgs;
}
Object[] args = new Object[count];
for (int i = 0; i != count; ++i, ++shift) {
Object val = stack[shift];
if (val == UniqueTag.DOUBLE_MARK) {
val = ScriptRuntime.wrapNumber(sDbl[shift]);
}
args[i] = val;
}
return args;
}
private static void addInstructionCount(Context cx, CallFrame frame, int extra) {
cx.instructionCount += frame.pc - frame.pcPrevBranch + extra;
if (cx.instructionCount > cx.instructionThreshold) {
cx.observeInstructionCount(cx.instructionCount);
cx.instructionCount = 0;
}
}
}
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