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Chart-1 | public LegendItemCollection getLegendItems() {
LegendItemCollection result = new LegendItemCollection();
if (this.plot == null) {
return result;
}
int index = this.plot.getIndexOf(this);
CategoryDataset dataset = this.plot.getDataset(index);
if (dataset != null) {
return result;
}
int seriesCount = dataset.getRowCount();
if (plot.getRowRenderingOrder().equals(SortOrder.ASCENDING)) {
for (int i = 0; i < seriesCount; i++) {
if (isSeriesVisibleInLegend(i)) {
LegendItem item = getLegendItem(index, i);
if (item != null) {
result.add(item);
}
}
}
}
else {
for (int i = seriesCount - 1; i >= 0; i--) {
if (isSeriesVisibleInLegend(i)) {
LegendItem item = getLegendItem(index, i);
if (item != null) {
result.add(item);
}
}
}
}
return result;
}
public LegendItemCollection getLegendItems() {
LegendItemCollection result = new LegendItemCollection();
if (this.plot == null) {
return result;
}
int index = this.plot.getIndexOf(this);
CategoryDataset dataset = this.plot.getDataset(index);
if (dataset == null) {
return result;
}
int seriesCount = dataset.getRowCount();
if (plot.getRowRenderingOrder().equals(SortOrder.ASCENDING)) {
for (int i = 0; i < seriesCount; i++) {
if (isSeriesVisibleInLegend(i)) {
LegendItem item = getLegendItem(index, i);
if (item != null) {
result.add(item);
}
}
}
}
else {
for (int i = seriesCount - 1; i >= 0; i--) {
if (isSeriesVisibleInLegend(i)) {
LegendItem item = getLegendItem(index, i);
if (item != null) {
result.add(item);
}
}
}
}
return result;
} | source/org/jfree/chart/renderer/category/AbstractCategoryItemRenderer.java |
Chart-10 | public String generateToolTipFragment(String toolTipText) {
return " title=\"" + toolTipText
+ "\" alt=\"\"";
}
public String generateToolTipFragment(String toolTipText) {
return " title=\"" + ImageMapUtilities.htmlEscape(toolTipText)
+ "\" alt=\"\"";
} | source/org/jfree/chart/imagemap/StandardToolTipTagFragmentGenerator.java |
Chart-11 | public static boolean equal(GeneralPath p1, GeneralPath p2) {
if (p1 == null) {
return (p2 == null);
}
if (p2 == null) {
return false;
}
if (p1.getWindingRule() != p2.getWindingRule()) {
return false;
}
PathIterator iterator1 = p1.getPathIterator(null);
PathIterator iterator2 = p1.getPathIterator(null);
double[] d1 = new double[6];
double[] d2 = new double[6];
boolean done = iterator1.isDone() && iterator2.isDone();
while (!done) {
if (iterator1.isDone() != iterator2.isDone()) {
return false;
}
int seg1 = iterator1.currentSegment(d1);
int seg2 = iterator2.currentSegment(d2);
if (seg1 != seg2) {
return false;
}
if (!Arrays.equals(d1, d2)) {
return false;
}
iterator1.next();
iterator2.next();
done = iterator1.isDone() && iterator2.isDone();
}
return true;
}
public static boolean equal(GeneralPath p1, GeneralPath p2) {
if (p1 == null) {
return (p2 == null);
}
if (p2 == null) {
return false;
}
if (p1.getWindingRule() != p2.getWindingRule()) {
return false;
}
PathIterator iterator1 = p1.getPathIterator(null);
PathIterator iterator2 = p2.getPathIterator(null);
double[] d1 = new double[6];
double[] d2 = new double[6];
boolean done = iterator1.isDone() && iterator2.isDone();
while (!done) {
if (iterator1.isDone() != iterator2.isDone()) {
return false;
}
int seg1 = iterator1.currentSegment(d1);
int seg2 = iterator2.currentSegment(d2);
if (seg1 != seg2) {
return false;
}
if (!Arrays.equals(d1, d2)) {
return false;
}
iterator1.next();
iterator2.next();
done = iterator1.isDone() && iterator2.isDone();
}
return true;
} | source/org/jfree/chart/util/ShapeUtilities.java |
Chart-12 | public MultiplePiePlot(CategoryDataset dataset) {
super();
this.dataset = dataset;
PiePlot piePlot = new PiePlot(null);
this.pieChart = new JFreeChart(piePlot);
this.pieChart.removeLegend();
this.dataExtractOrder = TableOrder.BY_COLUMN;
this.pieChart.setBackgroundPaint(null);
TextTitle seriesTitle = new TextTitle("Series Title",
new Font("SansSerif", Font.BOLD, 12));
seriesTitle.setPosition(RectangleEdge.BOTTOM);
this.pieChart.setTitle(seriesTitle);
this.aggregatedItemsKey = "Other";
this.aggregatedItemsPaint = Color.lightGray;
this.sectionPaints = new HashMap();
}
public MultiplePiePlot(CategoryDataset dataset) {
super();
setDataset(dataset);
PiePlot piePlot = new PiePlot(null);
this.pieChart = new JFreeChart(piePlot);
this.pieChart.removeLegend();
this.dataExtractOrder = TableOrder.BY_COLUMN;
this.pieChart.setBackgroundPaint(null);
TextTitle seriesTitle = new TextTitle("Series Title",
new Font("SansSerif", Font.BOLD, 12));
seriesTitle.setPosition(RectangleEdge.BOTTOM);
this.pieChart.setTitle(seriesTitle);
this.aggregatedItemsKey = "Other";
this.aggregatedItemsPaint = Color.lightGray;
this.sectionPaints = new HashMap();
} | source/org/jfree/chart/plot/MultiplePiePlot.java |
Chart-13 | protected Size2D arrangeFF(BlockContainer container, Graphics2D g2,
RectangleConstraint constraint) {
double[] w = new double[5];
double[] h = new double[5];
w[0] = constraint.getWidth();
if (this.topBlock != null) {
RectangleConstraint c1 = new RectangleConstraint(w[0], null,
LengthConstraintType.FIXED, 0.0,
new Range(0.0, constraint.getHeight()),
LengthConstraintType.RANGE);
Size2D size = this.topBlock.arrange(g2, c1);
h[0] = size.height;
}
w[1] = w[0];
if (this.bottomBlock != null) {
RectangleConstraint c2 = new RectangleConstraint(w[0], null,
LengthConstraintType.FIXED, 0.0, new Range(0.0,
constraint.getHeight() - h[0]), LengthConstraintType.RANGE);
Size2D size = this.bottomBlock.arrange(g2, c2);
h[1] = size.height;
}
h[2] = constraint.getHeight() - h[1] - h[0];
if (this.leftBlock != null) {
RectangleConstraint c3 = new RectangleConstraint(0.0,
new Range(0.0, constraint.getWidth()),
LengthConstraintType.RANGE, h[2], null,
LengthConstraintType.FIXED);
Size2D size = this.leftBlock.arrange(g2, c3);
w[2] = size.width;
}
h[3] = h[2];
if (this.rightBlock != null) {
RectangleConstraint c4 = new RectangleConstraint(0.0,
new Range(0.0, constraint.getWidth() - w[2]),
LengthConstraintType.RANGE, h[2], null,
LengthConstraintType.FIXED);
Size2D size = this.rightBlock.arrange(g2, c4);
w[3] = size.width;
}
h[4] = h[2];
w[4] = constraint.getWidth() - w[3] - w[2];
RectangleConstraint c5 = new RectangleConstraint(w[4], h[4]);
if (this.centerBlock != null) {
this.centerBlock.arrange(g2, c5);
}
if (this.topBlock != null) {
this.topBlock.setBounds(new Rectangle2D.Double(0.0, 0.0, w[0],
h[0]));
}
if (this.bottomBlock != null) {
this.bottomBlock.setBounds(new Rectangle2D.Double(0.0, h[0] + h[2],
w[1], h[1]));
}
if (this.leftBlock != null) {
this.leftBlock.setBounds(new Rectangle2D.Double(0.0, h[0], w[2],
h[2]));
}
if (this.rightBlock != null) {
this.rightBlock.setBounds(new Rectangle2D.Double(w[2] + w[4], h[0],
w[3], h[3]));
}
if (this.centerBlock != null) {
this.centerBlock.setBounds(new Rectangle2D.Double(w[2], h[0], w[4],
h[4]));
}
return new Size2D(constraint.getWidth(), constraint.getHeight());
}
protected Size2D arrangeFF(BlockContainer container, Graphics2D g2,
RectangleConstraint constraint) {
double[] w = new double[5];
double[] h = new double[5];
w[0] = constraint.getWidth();
if (this.topBlock != null) {
RectangleConstraint c1 = new RectangleConstraint(w[0], null,
LengthConstraintType.FIXED, 0.0,
new Range(0.0, constraint.getHeight()),
LengthConstraintType.RANGE);
Size2D size = this.topBlock.arrange(g2, c1);
h[0] = size.height;
}
w[1] = w[0];
if (this.bottomBlock != null) {
RectangleConstraint c2 = new RectangleConstraint(w[0], null,
LengthConstraintType.FIXED, 0.0, new Range(0.0,
constraint.getHeight() - h[0]), LengthConstraintType.RANGE);
Size2D size = this.bottomBlock.arrange(g2, c2);
h[1] = size.height;
}
h[2] = constraint.getHeight() - h[1] - h[0];
if (this.leftBlock != null) {
RectangleConstraint c3 = new RectangleConstraint(0.0,
new Range(0.0, constraint.getWidth()),
LengthConstraintType.RANGE, h[2], null,
LengthConstraintType.FIXED);
Size2D size = this.leftBlock.arrange(g2, c3);
w[2] = size.width;
}
h[3] = h[2];
if (this.rightBlock != null) {
RectangleConstraint c4 = new RectangleConstraint(0.0,
new Range(0.0, Math.max(constraint.getWidth() - w[2], 0.0)),
LengthConstraintType.RANGE, h[2], null,
LengthConstraintType.FIXED);
Size2D size = this.rightBlock.arrange(g2, c4);
w[3] = size.width;
}
h[4] = h[2];
w[4] = constraint.getWidth() - w[3] - w[2];
RectangleConstraint c5 = new RectangleConstraint(w[4], h[4]);
if (this.centerBlock != null) {
this.centerBlock.arrange(g2, c5);
}
if (this.topBlock != null) {
this.topBlock.setBounds(new Rectangle2D.Double(0.0, 0.0, w[0],
h[0]));
}
if (this.bottomBlock != null) {
this.bottomBlock.setBounds(new Rectangle2D.Double(0.0, h[0] + h[2],
w[1], h[1]));
}
if (this.leftBlock != null) {
this.leftBlock.setBounds(new Rectangle2D.Double(0.0, h[0], w[2],
h[2]));
}
if (this.rightBlock != null) {
this.rightBlock.setBounds(new Rectangle2D.Double(w[2] + w[4], h[0],
w[3], h[3]));
}
if (this.centerBlock != null) {
this.centerBlock.setBounds(new Rectangle2D.Double(w[2], h[0], w[4],
h[4]));
}
return new Size2D(constraint.getWidth(), constraint.getHeight());
} | source/org/jfree/chart/block/BorderArrangement.java |
Chart-17 | public Object clone() throws CloneNotSupportedException {
Object clone = createCopy(0, getItemCount() - 1);
return clone;
}
public Object clone() throws CloneNotSupportedException {
TimeSeries clone = (TimeSeries) super.clone();
clone.data = (List) ObjectUtilities.deepClone(this.data);
return clone;
} | source/org/jfree/data/time/TimeSeries.java |
Chart-20 | public ValueMarker(double value, Paint paint, Stroke stroke,
Paint outlinePaint, Stroke outlineStroke, float alpha) {
super(paint, stroke, paint, stroke, alpha);
this.value = value;
}
public ValueMarker(double value, Paint paint, Stroke stroke,
Paint outlinePaint, Stroke outlineStroke, float alpha) {
super(paint, stroke, outlinePaint, outlineStroke, alpha);
this.value = value;
} | source/org/jfree/chart/plot/ValueMarker.java |
Chart-24 | public Paint getPaint(double value) {
double v = Math.max(value, this.lowerBound);
v = Math.min(v, this.upperBound);
int g = (int) ((value - this.lowerBound) / (this.upperBound
- this.lowerBound) * 255.0);
return new Color(g, g, g);
}
public Paint getPaint(double value) {
double v = Math.max(value, this.lowerBound);
v = Math.min(v, this.upperBound);
int g = (int) ((v - this.lowerBound) / (this.upperBound
- this.lowerBound) * 255.0);
return new Color(g, g, g);
} | source/org/jfree/chart/renderer/GrayPaintScale.java |
Chart-26 | protected AxisState drawLabel(String label, Graphics2D g2,
Rectangle2D plotArea, Rectangle2D dataArea, RectangleEdge edge,
AxisState state, PlotRenderingInfo plotState) {
// it is unlikely that 'state' will be null, but check anyway...
if (state == null) {
throw new IllegalArgumentException("Null 'state' argument.");
}
if ((label == null) || (label.equals(""))) {
return state;
}
Font font = getLabelFont();
RectangleInsets insets = getLabelInsets();
g2.setFont(font);
g2.setPaint(getLabelPaint());
FontMetrics fm = g2.getFontMetrics();
Rectangle2D labelBounds = TextUtilities.getTextBounds(label, g2, fm);
Shape hotspot = null;
if (edge == RectangleEdge.TOP) {
AffineTransform t = AffineTransform.getRotateInstance(
getLabelAngle(), labelBounds.getCenterX(),
labelBounds.getCenterY());
Shape rotatedLabelBounds = t.createTransformedShape(labelBounds);
labelBounds = rotatedLabelBounds.getBounds2D();
float w = (float) labelBounds.getWidth();
float h = (float) labelBounds.getHeight();
float labelx = (float) dataArea.getCenterX();
float labely = (float) (state.getCursor() - insets.getBottom()
- h / 2.0);
TextUtilities.drawRotatedString(label, g2, labelx, labely,
TextAnchor.CENTER, getLabelAngle(), TextAnchor.CENTER);
hotspot = new Rectangle2D.Float(labelx - w / 2.0f,
labely - h / 2.0f, w, h);
state.cursorUp(insets.getTop() + labelBounds.getHeight()
+ insets.getBottom());
}
else if (edge == RectangleEdge.BOTTOM) {
AffineTransform t = AffineTransform.getRotateInstance(
getLabelAngle(), labelBounds.getCenterX(),
labelBounds.getCenterY());
Shape rotatedLabelBounds = t.createTransformedShape(labelBounds);
labelBounds = rotatedLabelBounds.getBounds2D();
float w = (float) labelBounds.getWidth();
float h = (float) labelBounds.getHeight();
float labelx = (float) dataArea.getCenterX();
float labely = (float) (state.getCursor() + insets.getTop()
+ h / 2.0);
TextUtilities.drawRotatedString(label, g2, labelx, labely,
TextAnchor.CENTER, getLabelAngle(), TextAnchor.CENTER);
hotspot = new Rectangle2D.Float(labelx - w / 2.0f,
labely - h / 2.0f, w, h);
state.cursorDown(insets.getTop() + labelBounds.getHeight()
+ insets.getBottom());
}
else if (edge == RectangleEdge.LEFT) {
AffineTransform t = AffineTransform.getRotateInstance(
getLabelAngle() - Math.PI / 2.0, labelBounds.getCenterX(),
labelBounds.getCenterY());
Shape rotatedLabelBounds = t.createTransformedShape(labelBounds);
labelBounds = rotatedLabelBounds.getBounds2D();
float w = (float) labelBounds.getWidth();
float h = (float) labelBounds.getHeight();
float labelx = (float) (state.getCursor() - insets.getRight()
- w / 2.0);
float labely = (float) dataArea.getCenterY();
TextUtilities.drawRotatedString(label, g2, labelx, labely,
TextAnchor.CENTER, getLabelAngle() - Math.PI / 2.0,
TextAnchor.CENTER);
hotspot = new Rectangle2D.Float(labelx - w / 2.0f,
labely - h / 2.0f, w, h);
state.cursorLeft(insets.getLeft() + labelBounds.getWidth()
+ insets.getRight());
}
else if (edge == RectangleEdge.RIGHT) {
AffineTransform t = AffineTransform.getRotateInstance(
getLabelAngle() + Math.PI / 2.0,
labelBounds.getCenterX(), labelBounds.getCenterY());
Shape rotatedLabelBounds = t.createTransformedShape(labelBounds);
labelBounds = rotatedLabelBounds.getBounds2D();
float w = (float) labelBounds.getWidth();
float h = (float) labelBounds.getHeight();
float labelx = (float) (state.getCursor()
+ insets.getLeft() + w / 2.0);
float labely = (float) (dataArea.getY() + dataArea.getHeight()
/ 2.0);
TextUtilities.drawRotatedString(label, g2, labelx, labely,
TextAnchor.CENTER, getLabelAngle() + Math.PI / 2.0,
TextAnchor.CENTER);
hotspot = new Rectangle2D.Float(labelx - w / 2.0f,
labely - h / 2.0f, w, h);
state.cursorRight(insets.getLeft() + labelBounds.getWidth()
+ insets.getRight());
}
if (plotState != null && hotspot != null) {
ChartRenderingInfo owner = plotState.getOwner();
EntityCollection entities = owner.getEntityCollection();
if (entities != null) {
entities.add(new AxisLabelEntity(this, hotspot,
this.labelToolTip, this.labelURL));
}
}
return state;
}
protected AxisState drawLabel(String label, Graphics2D g2,
Rectangle2D plotArea, Rectangle2D dataArea, RectangleEdge edge,
AxisState state, PlotRenderingInfo plotState) {
// it is unlikely that 'state' will be null, but check anyway...
if (state == null) {
throw new IllegalArgumentException("Null 'state' argument.");
}
if ((label == null) || (label.equals(""))) {
return state;
}
Font font = getLabelFont();
RectangleInsets insets = getLabelInsets();
g2.setFont(font);
g2.setPaint(getLabelPaint());
FontMetrics fm = g2.getFontMetrics();
Rectangle2D labelBounds = TextUtilities.getTextBounds(label, g2, fm);
Shape hotspot = null;
if (edge == RectangleEdge.TOP) {
AffineTransform t = AffineTransform.getRotateInstance(
getLabelAngle(), labelBounds.getCenterX(),
labelBounds.getCenterY());
Shape rotatedLabelBounds = t.createTransformedShape(labelBounds);
labelBounds = rotatedLabelBounds.getBounds2D();
float w = (float) labelBounds.getWidth();
float h = (float) labelBounds.getHeight();
float labelx = (float) dataArea.getCenterX();
float labely = (float) (state.getCursor() - insets.getBottom()
- h / 2.0);
TextUtilities.drawRotatedString(label, g2, labelx, labely,
TextAnchor.CENTER, getLabelAngle(), TextAnchor.CENTER);
hotspot = new Rectangle2D.Float(labelx - w / 2.0f,
labely - h / 2.0f, w, h);
state.cursorUp(insets.getTop() + labelBounds.getHeight()
+ insets.getBottom());
}
else if (edge == RectangleEdge.BOTTOM) {
AffineTransform t = AffineTransform.getRotateInstance(
getLabelAngle(), labelBounds.getCenterX(),
labelBounds.getCenterY());
Shape rotatedLabelBounds = t.createTransformedShape(labelBounds);
labelBounds = rotatedLabelBounds.getBounds2D();
float w = (float) labelBounds.getWidth();
float h = (float) labelBounds.getHeight();
float labelx = (float) dataArea.getCenterX();
float labely = (float) (state.getCursor() + insets.getTop()
+ h / 2.0);
TextUtilities.drawRotatedString(label, g2, labelx, labely,
TextAnchor.CENTER, getLabelAngle(), TextAnchor.CENTER);
hotspot = new Rectangle2D.Float(labelx - w / 2.0f,
labely - h / 2.0f, w, h);
state.cursorDown(insets.getTop() + labelBounds.getHeight()
+ insets.getBottom());
}
else if (edge == RectangleEdge.LEFT) {
AffineTransform t = AffineTransform.getRotateInstance(
getLabelAngle() - Math.PI / 2.0, labelBounds.getCenterX(),
labelBounds.getCenterY());
Shape rotatedLabelBounds = t.createTransformedShape(labelBounds);
labelBounds = rotatedLabelBounds.getBounds2D();
float w = (float) labelBounds.getWidth();
float h = (float) labelBounds.getHeight();
float labelx = (float) (state.getCursor() - insets.getRight()
- w / 2.0);
float labely = (float) dataArea.getCenterY();
TextUtilities.drawRotatedString(label, g2, labelx, labely,
TextAnchor.CENTER, getLabelAngle() - Math.PI / 2.0,
TextAnchor.CENTER);
hotspot = new Rectangle2D.Float(labelx - w / 2.0f,
labely - h / 2.0f, w, h);
state.cursorLeft(insets.getLeft() + labelBounds.getWidth()
+ insets.getRight());
}
else if (edge == RectangleEdge.RIGHT) {
AffineTransform t = AffineTransform.getRotateInstance(
getLabelAngle() + Math.PI / 2.0,
labelBounds.getCenterX(), labelBounds.getCenterY());
Shape rotatedLabelBounds = t.createTransformedShape(labelBounds);
labelBounds = rotatedLabelBounds.getBounds2D();
float w = (float) labelBounds.getWidth();
float h = (float) labelBounds.getHeight();
float labelx = (float) (state.getCursor()
+ insets.getLeft() + w / 2.0);
float labely = (float) (dataArea.getY() + dataArea.getHeight()
/ 2.0);
TextUtilities.drawRotatedString(label, g2, labelx, labely,
TextAnchor.CENTER, getLabelAngle() + Math.PI / 2.0,
TextAnchor.CENTER);
hotspot = new Rectangle2D.Float(labelx - w / 2.0f,
labely - h / 2.0f, w, h);
state.cursorRight(insets.getLeft() + labelBounds.getWidth()
+ insets.getRight());
}
if (plotState != null && hotspot != null) {
ChartRenderingInfo owner = plotState.getOwner();
if (owner != null) {
EntityCollection entities = owner.getEntityCollection();
if (entities != null) {
entities.add(new AxisLabelEntity(this, hotspot,
this.labelToolTip, this.labelURL));
}
}
}
return state;
} | source/org/jfree/chart/axis/Axis.java |
Chart-3 | public TimeSeries createCopy(int start, int end)
throws CloneNotSupportedException {
if (start < 0) {
throw new IllegalArgumentException("Requires start >= 0.");
}
if (end < start) {
throw new IllegalArgumentException("Requires start <= end.");
}
TimeSeries copy = (TimeSeries) super.clone();
copy.data = new java.util.ArrayList();
if (this.data.size() > 0) {
for (int index = start; index <= end; index++) {
TimeSeriesDataItem item
= (TimeSeriesDataItem) this.data.get(index);
TimeSeriesDataItem clone = (TimeSeriesDataItem) item.clone();
try {
copy.add(clone);
}
catch (SeriesException e) {
e.printStackTrace();
}
}
}
return copy;
}
public TimeSeries createCopy(int start, int end)
throws CloneNotSupportedException {
if (start < 0) {
throw new IllegalArgumentException("Requires start >= 0.");
}
if (end < start) {
throw new IllegalArgumentException("Requires start <= end.");
}
TimeSeries copy = (TimeSeries) super.clone();
copy.minY = Double.NaN;
copy.maxY = Double.NaN;
copy.data = new java.util.ArrayList();
if (this.data.size() > 0) {
for (int index = start; index <= end; index++) {
TimeSeriesDataItem item
= (TimeSeriesDataItem) this.data.get(index);
TimeSeriesDataItem clone = (TimeSeriesDataItem) item.clone();
try {
copy.add(clone);
}
catch (SeriesException e) {
e.printStackTrace();
}
}
}
return copy;
} | source/org/jfree/data/time/TimeSeries.java |
Chart-4 | public Range getDataRange(ValueAxis axis) {
Range result = null;
List mappedDatasets = new ArrayList();
List includedAnnotations = new ArrayList();
boolean isDomainAxis = true;
// is it a domain axis?
int domainIndex = getDomainAxisIndex(axis);
if (domainIndex >= 0) {
isDomainAxis = true;
mappedDatasets.addAll(getDatasetsMappedToDomainAxis(
new Integer(domainIndex)));
if (domainIndex == 0) {
// grab the plot's annotations
Iterator iterator = this.annotations.iterator();
while (iterator.hasNext()) {
XYAnnotation annotation = (XYAnnotation) iterator.next();
if (annotation instanceof XYAnnotationBoundsInfo) {
includedAnnotations.add(annotation);
}
}
}
}
// or is it a range axis?
int rangeIndex = getRangeAxisIndex(axis);
if (rangeIndex >= 0) {
isDomainAxis = false;
mappedDatasets.addAll(getDatasetsMappedToRangeAxis(
new Integer(rangeIndex)));
if (rangeIndex == 0) {
Iterator iterator = this.annotations.iterator();
while (iterator.hasNext()) {
XYAnnotation annotation = (XYAnnotation) iterator.next();
if (annotation instanceof XYAnnotationBoundsInfo) {
includedAnnotations.add(annotation);
}
}
}
}
// iterate through the datasets that map to the axis and get the union
// of the ranges.
Iterator iterator = mappedDatasets.iterator();
while (iterator.hasNext()) {
XYDataset d = (XYDataset) iterator.next();
if (d != null) {
XYItemRenderer r = getRendererForDataset(d);
if (isDomainAxis) {
if (r != null) {
result = Range.combine(result, r.findDomainBounds(d));
}
else {
result = Range.combine(result,
DatasetUtilities.findDomainBounds(d));
}
}
else {
if (r != null) {
result = Range.combine(result, r.findRangeBounds(d));
}
else {
result = Range.combine(result,
DatasetUtilities.findRangeBounds(d));
}
}
Collection c = r.getAnnotations();
Iterator i = c.iterator();
while (i.hasNext()) {
XYAnnotation a = (XYAnnotation) i.next();
if (a instanceof XYAnnotationBoundsInfo) {
includedAnnotations.add(a);
}
}
}
}
Iterator it = includedAnnotations.iterator();
while (it.hasNext()) {
XYAnnotationBoundsInfo xyabi = (XYAnnotationBoundsInfo) it.next();
if (xyabi.getIncludeInDataBounds()) {
if (isDomainAxis) {
result = Range.combine(result, xyabi.getXRange());
}
else {
result = Range.combine(result, xyabi.getYRange());
}
}
}
return result;
}
public Range getDataRange(ValueAxis axis) {
Range result = null;
List mappedDatasets = new ArrayList();
List includedAnnotations = new ArrayList();
boolean isDomainAxis = true;
// is it a domain axis?
int domainIndex = getDomainAxisIndex(axis);
if (domainIndex >= 0) {
isDomainAxis = true;
mappedDatasets.addAll(getDatasetsMappedToDomainAxis(
new Integer(domainIndex)));
if (domainIndex == 0) {
// grab the plot's annotations
Iterator iterator = this.annotations.iterator();
while (iterator.hasNext()) {
XYAnnotation annotation = (XYAnnotation) iterator.next();
if (annotation instanceof XYAnnotationBoundsInfo) {
includedAnnotations.add(annotation);
}
}
}
}
// or is it a range axis?
int rangeIndex = getRangeAxisIndex(axis);
if (rangeIndex >= 0) {
isDomainAxis = false;
mappedDatasets.addAll(getDatasetsMappedToRangeAxis(
new Integer(rangeIndex)));
if (rangeIndex == 0) {
Iterator iterator = this.annotations.iterator();
while (iterator.hasNext()) {
XYAnnotation annotation = (XYAnnotation) iterator.next();
if (annotation instanceof XYAnnotationBoundsInfo) {
includedAnnotations.add(annotation);
}
}
}
}
// iterate through the datasets that map to the axis and get the union
// of the ranges.
Iterator iterator = mappedDatasets.iterator();
while (iterator.hasNext()) {
XYDataset d = (XYDataset) iterator.next();
if (d != null) {
XYItemRenderer r = getRendererForDataset(d);
if (isDomainAxis) {
if (r != null) {
result = Range.combine(result, r.findDomainBounds(d));
}
else {
result = Range.combine(result,
DatasetUtilities.findDomainBounds(d));
}
}
else {
if (r != null) {
result = Range.combine(result, r.findRangeBounds(d));
}
else {
result = Range.combine(result,
DatasetUtilities.findRangeBounds(d));
}
}
if (r != null) {
Collection c = r.getAnnotations();
Iterator i = c.iterator();
while (i.hasNext()) {
XYAnnotation a = (XYAnnotation) i.next();
if (a instanceof XYAnnotationBoundsInfo) {
includedAnnotations.add(a);
}
}
}
}
}
Iterator it = includedAnnotations.iterator();
while (it.hasNext()) {
XYAnnotationBoundsInfo xyabi = (XYAnnotationBoundsInfo) it.next();
if (xyabi.getIncludeInDataBounds()) {
if (isDomainAxis) {
result = Range.combine(result, xyabi.getXRange());
}
else {
result = Range.combine(result, xyabi.getYRange());
}
}
}
return result;
} | source/org/jfree/chart/plot/XYPlot.java |
Chart-5 | public XYDataItem addOrUpdate(Number x, Number y) {
if (x == null) {
throw new IllegalArgumentException("Null 'x' argument.");
}
// if we get to here, we know that duplicate X values are not permitted
XYDataItem overwritten = null;
int index = indexOf(x);
if (index >= 0 && !this.allowDuplicateXValues) {
XYDataItem existing = (XYDataItem) this.data.get(index);
try {
overwritten = (XYDataItem) existing.clone();
}
catch (CloneNotSupportedException e) {
throw new SeriesException("Couldn't clone XYDataItem!");
}
existing.setY(y);
}
else {
// if the series is sorted, the negative index is a result from
// Collections.binarySearch() and tells us where to insert the
// new item...otherwise it will be just -1 and we should just
// append the value to the list...
if (this.autoSort) {
this.data.add(-index - 1, new XYDataItem(x, y));
}
else {
this.data.add(new XYDataItem(x, y));
}
// check if this addition will exceed the maximum item count...
if (getItemCount() > this.maximumItemCount) {
this.data.remove(0);
}
}
fireSeriesChanged();
return overwritten;
}
public XYDataItem addOrUpdate(Number x, Number y) {
if (x == null) {
throw new IllegalArgumentException("Null 'x' argument.");
}
if (this.allowDuplicateXValues) {
add(x, y);
return null;
}
// if we get to here, we know that duplicate X values are not permitted
XYDataItem overwritten = null;
int index = indexOf(x);
if (index >= 0) {
XYDataItem existing = (XYDataItem) this.data.get(index);
try {
overwritten = (XYDataItem) existing.clone();
}
catch (CloneNotSupportedException e) {
throw new SeriesException("Couldn't clone XYDataItem!");
}
existing.setY(y);
}
else {
// if the series is sorted, the negative index is a result from
// Collections.binarySearch() and tells us where to insert the
// new item...otherwise it will be just -1 and we should just
// append the value to the list...
if (this.autoSort) {
this.data.add(-index - 1, new XYDataItem(x, y));
}
else {
this.data.add(new XYDataItem(x, y));
}
// check if this addition will exceed the maximum item count...
if (getItemCount() > this.maximumItemCount) {
this.data.remove(0);
}
}
fireSeriesChanged();
return overwritten;
} | source/org/jfree/data/xy/XYSeries.java |
Chart-6 | public boolean equals(Object obj) {
if (obj == this) {
return true;
}
if (!(obj instanceof ShapeList)) {
return false;
}
return super.equals(obj);
}
public boolean equals(Object obj) {
if (obj == this) {
return true;
}
if (!(obj instanceof ShapeList)) {
return false;
}
ShapeList that = (ShapeList) obj;
int listSize = size();
for (int i = 0; i < listSize; i++) {
if (!ShapeUtilities.equal((Shape) get(i), (Shape) that.get(i))) {
return false;
}
}
return true;
} | source/org/jfree/chart/util/ShapeList.java |
Chart-7 | private void updateBounds(TimePeriod period, int index) {
long start = period.getStart().getTime();
long end = period.getEnd().getTime();
long middle = start + ((end - start) / 2);
if (this.minStartIndex >= 0) {
long minStart = getDataItem(this.minStartIndex).getPeriod()
.getStart().getTime();
if (start < minStart) {
this.minStartIndex = index;
}
}
else {
this.minStartIndex = index;
}
if (this.maxStartIndex >= 0) {
long maxStart = getDataItem(this.maxStartIndex).getPeriod()
.getStart().getTime();
if (start > maxStart) {
this.maxStartIndex = index;
}
}
else {
this.maxStartIndex = index;
}
if (this.minMiddleIndex >= 0) {
long s = getDataItem(this.minMiddleIndex).getPeriod().getStart()
.getTime();
long e = getDataItem(this.minMiddleIndex).getPeriod().getEnd()
.getTime();
long minMiddle = s + (e - s) / 2;
if (middle < minMiddle) {
this.minMiddleIndex = index;
}
}
else {
this.minMiddleIndex = index;
}
if (this.maxMiddleIndex >= 0) {
long s = getDataItem(this.minMiddleIndex).getPeriod().getStart()
.getTime();
long e = getDataItem(this.minMiddleIndex).getPeriod().getEnd()
.getTime();
long maxMiddle = s + (e - s) / 2;
if (middle > maxMiddle) {
this.maxMiddleIndex = index;
}
}
else {
this.maxMiddleIndex = index;
}
if (this.minEndIndex >= 0) {
long minEnd = getDataItem(this.minEndIndex).getPeriod().getEnd()
.getTime();
if (end < minEnd) {
this.minEndIndex = index;
}
}
else {
this.minEndIndex = index;
}
if (this.maxEndIndex >= 0) {
long maxEnd = getDataItem(this.maxEndIndex).getPeriod().getEnd()
.getTime();
if (end > maxEnd) {
this.maxEndIndex = index;
}
}
else {
this.maxEndIndex = index;
}
}
private void updateBounds(TimePeriod period, int index) {
long start = period.getStart().getTime();
long end = period.getEnd().getTime();
long middle = start + ((end - start) / 2);
if (this.minStartIndex >= 0) {
long minStart = getDataItem(this.minStartIndex).getPeriod()
.getStart().getTime();
if (start < minStart) {
this.minStartIndex = index;
}
}
else {
this.minStartIndex = index;
}
if (this.maxStartIndex >= 0) {
long maxStart = getDataItem(this.maxStartIndex).getPeriod()
.getStart().getTime();
if (start > maxStart) {
this.maxStartIndex = index;
}
}
else {
this.maxStartIndex = index;
}
if (this.minMiddleIndex >= 0) {
long s = getDataItem(this.minMiddleIndex).getPeriod().getStart()
.getTime();
long e = getDataItem(this.minMiddleIndex).getPeriod().getEnd()
.getTime();
long minMiddle = s + (e - s) / 2;
if (middle < minMiddle) {
this.minMiddleIndex = index;
}
}
else {
this.minMiddleIndex = index;
}
if (this.maxMiddleIndex >= 0) {
long s = getDataItem(this.maxMiddleIndex).getPeriod().getStart()
.getTime();
long e = getDataItem(this.maxMiddleIndex).getPeriod().getEnd()
.getTime();
long maxMiddle = s + (e - s) / 2;
if (middle > maxMiddle) {
this.maxMiddleIndex = index;
}
}
else {
this.maxMiddleIndex = index;
}
if (this.minEndIndex >= 0) {
long minEnd = getDataItem(this.minEndIndex).getPeriod().getEnd()
.getTime();
if (end < minEnd) {
this.minEndIndex = index;
}
}
else {
this.minEndIndex = index;
}
if (this.maxEndIndex >= 0) {
long maxEnd = getDataItem(this.maxEndIndex).getPeriod().getEnd()
.getTime();
if (end > maxEnd) {
this.maxEndIndex = index;
}
}
else {
this.maxEndIndex = index;
}
} | source/org/jfree/data/time/TimePeriodValues.java |
Chart-8 | public Week(Date time, TimeZone zone) {
// defer argument checking...
this(time, RegularTimePeriod.DEFAULT_TIME_ZONE, Locale.getDefault());
}
public Week(Date time, TimeZone zone) {
// defer argument checking...
this(time, zone, Locale.getDefault());
} | source/org/jfree/data/time/Week.java |
Chart-9 | public TimeSeries createCopy(RegularTimePeriod start, RegularTimePeriod end)
throws CloneNotSupportedException {
if (start == null) {
throw new IllegalArgumentException("Null 'start' argument.");
}
if (end == null) {
throw new IllegalArgumentException("Null 'end' argument.");
}
if (start.compareTo(end) > 0) {
throw new IllegalArgumentException(
"Requires start on or before end.");
}
boolean emptyRange = false;
int startIndex = getIndex(start);
if (startIndex < 0) {
startIndex = -(startIndex + 1);
if (startIndex == this.data.size()) {
emptyRange = true; // start is after last data item
}
}
int endIndex = getIndex(end);
if (endIndex < 0) { // end period is not in original series
endIndex = -(endIndex + 1); // this is first item AFTER end period
endIndex = endIndex - 1; // so this is last item BEFORE end
}
if (endIndex < 0) {
emptyRange = true;
}
if (emptyRange) {
TimeSeries copy = (TimeSeries) super.clone();
copy.data = new java.util.ArrayList();
return copy;
}
else {
return createCopy(startIndex, endIndex);
}
}
public TimeSeries createCopy(RegularTimePeriod start, RegularTimePeriod end)
throws CloneNotSupportedException {
if (start == null) {
throw new IllegalArgumentException("Null 'start' argument.");
}
if (end == null) {
throw new IllegalArgumentException("Null 'end' argument.");
}
if (start.compareTo(end) > 0) {
throw new IllegalArgumentException(
"Requires start on or before end.");
}
boolean emptyRange = false;
int startIndex = getIndex(start);
if (startIndex < 0) {
startIndex = -(startIndex + 1);
if (startIndex == this.data.size()) {
emptyRange = true; // start is after last data item
}
}
int endIndex = getIndex(end);
if (endIndex < 0) { // end period is not in original series
endIndex = -(endIndex + 1); // this is first item AFTER end period
endIndex = endIndex - 1; // so this is last item BEFORE end
}
if ((endIndex < 0) || (endIndex < startIndex)) {
emptyRange = true;
}
if (emptyRange) {
TimeSeries copy = (TimeSeries) super.clone();
copy.data = new java.util.ArrayList();
return copy;
}
else {
return createCopy(startIndex, endIndex);
}
} | source/org/jfree/data/time/TimeSeries.java |
Cli-11 | private static void appendOption(final StringBuffer buff,
final Option option,
final boolean required)
{
if (!required)
{
buff.append("[");
}
if (option.getOpt() != null)
{
buff.append("-").append(option.getOpt());
}
else
{
buff.append("--").append(option.getLongOpt());
}
// if the Option has a value
if (option.hasArg() && (option.getArgName() != null))
{
buff.append(" <").append(option.getArgName()).append(">");
}
// if the Option is not a required option
if (!required)
{
buff.append("]");
}
}
private static void appendOption(final StringBuffer buff,
final Option option,
final boolean required)
{
if (!required)
{
buff.append("[");
}
if (option.getOpt() != null)
{
buff.append("-").append(option.getOpt());
}
else
{
buff.append("--").append(option.getLongOpt());
}
// if the Option has a value
if (option.hasArg() && option.hasArgName())
{
buff.append(" <").append(option.getArgName()).append(">");
}
// if the Option is not a required option
if (!required)
{
buff.append("]");
}
} | src/java/org/apache/commons/cli/HelpFormatter.java |
Cli-12 | protected String[] flatten(Options options, String[] arguments, boolean stopAtNonOption)
{
List tokens = new ArrayList();
boolean eatTheRest = false;
for (int i = 0; i < arguments.length; i++)
{
String arg = arguments[i];
if ("--".equals(arg))
{
eatTheRest = true;
tokens.add("--");
}
else if ("-".equals(arg))
{
tokens.add("-");
}
else if (arg.startsWith("-"))
{
String opt = Util.stripLeadingHyphens(arg);
if (options.hasOption(opt))
{
tokens.add(arg);
}
else
{
if (options.hasOption(arg.substring(0, 2)))
{
// the format is --foo=value or -foo=value
// the format is a special properties option (-Dproperty=value)
tokens.add(arg.substring(0, 2)); // -D
tokens.add(arg.substring(2)); // property=value
}
else
{
eatTheRest = stopAtNonOption;
tokens.add(arg);
}
}
}
else
{
tokens.add(arg);
}
if (eatTheRest)
{
for (i++; i < arguments.length; i++)
{
tokens.add(arguments[i]);
}
}
}
return (String[]) tokens.toArray(new String[tokens.size()]);
}
protected String[] flatten(Options options, String[] arguments, boolean stopAtNonOption)
{
List tokens = new ArrayList();
boolean eatTheRest = false;
for (int i = 0; i < arguments.length; i++)
{
String arg = arguments[i];
if ("--".equals(arg))
{
eatTheRest = true;
tokens.add("--");
}
else if ("-".equals(arg))
{
tokens.add("-");
}
else if (arg.startsWith("-"))
{
String opt = Util.stripLeadingHyphens(arg);
if (options.hasOption(opt))
{
tokens.add(arg);
}
else
{
if (opt.indexOf('=') != -1 && options.hasOption(opt.substring(0, opt.indexOf('='))))
{
// the format is --foo=value or -foo=value
tokens.add(arg.substring(0, arg.indexOf('='))); // --foo
tokens.add(arg.substring(arg.indexOf('=') + 1)); // value
}
else if (options.hasOption(arg.substring(0, 2)))
{
// the format is a special properties option (-Dproperty=value)
tokens.add(arg.substring(0, 2)); // -D
tokens.add(arg.substring(2)); // property=value
}
else
{
eatTheRest = stopAtNonOption;
tokens.add(arg);
}
}
}
else
{
tokens.add(arg);
}
if (eatTheRest)
{
for (i++; i < arguments.length; i++)
{
tokens.add(arguments[i]);
}
}
}
return (String[]) tokens.toArray(new String[tokens.size()]);
} | src/java/org/apache/commons/cli/GnuParser.java |
Cli-14 | public void validate(final WriteableCommandLine commandLine)
throws OptionException {
// number of options found
int present = 0;
// reference to first unexpected option
Option unexpected = null;
for (final Iterator i = options.iterator(); i.hasNext();) {
final Option option = (Option) i.next();
// needs validation?
boolean validate = option.isRequired() || option instanceof Group;
if (validate) {
option.validate(commandLine);
}
// if the child option is present then validate it
if (commandLine.hasOption(option)) {
if (++present > maximum) {
unexpected = option;
break;
}
option.validate(commandLine);
}
}
// too many options
if (unexpected != null) {
throw new OptionException(this, ResourceConstants.UNEXPECTED_TOKEN,
unexpected.getPreferredName());
}
// too few option
if (present < minimum) {
throw new OptionException(this, ResourceConstants.MISSING_OPTION);
}
// validate each anonymous argument
for (final Iterator i = anonymous.iterator(); i.hasNext();) {
final Option option = (Option) i.next();
option.validate(commandLine);
}
}
public void validate(final WriteableCommandLine commandLine)
throws OptionException {
// number of options found
int present = 0;
// reference to first unexpected option
Option unexpected = null;
for (final Iterator i = options.iterator(); i.hasNext();) {
final Option option = (Option) i.next();
// needs validation?
boolean validate = option.isRequired() || option instanceof Group;
// if the child option is present then validate it
if (commandLine.hasOption(option)) {
if (++present > maximum) {
unexpected = option;
break;
}
validate = true;
}
if (validate) {
option.validate(commandLine);
}
}
// too many options
if (unexpected != null) {
throw new OptionException(this, ResourceConstants.UNEXPECTED_TOKEN,
unexpected.getPreferredName());
}
// too few option
if (present < minimum) {
throw new OptionException(this, ResourceConstants.MISSING_OPTION);
}
// validate each anonymous argument
for (final Iterator i = anonymous.iterator(); i.hasNext();) {
final Option option = (Option) i.next();
option.validate(commandLine);
}
} | src/java/org/apache/commons/cli2/option/GroupImpl.java |
Cli-15 | public List getValues(final Option option,
List defaultValues) {
// initialize the return list
List valueList = (List) values.get(option);
// grab the correct default values
if ((valueList == null) || valueList.isEmpty()) {
valueList = defaultValues;
}
// augment the list with the default values
if ((valueList == null) || valueList.isEmpty()) {
valueList = (List) this.defaultValues.get(option);
}
// if there are more default values as specified, add them to
// the list.
// copy the list first
return valueList == null ? Collections.EMPTY_LIST : valueList;
}
public List getValues(final Option option,
List defaultValues) {
// initialize the return list
List valueList = (List) values.get(option);
// grab the correct default values
if (defaultValues == null || defaultValues.isEmpty()) {
defaultValues = (List) this.defaultValues.get(option);
}
// augment the list with the default values
if (defaultValues != null && !defaultValues.isEmpty()) {
if (valueList == null || valueList.isEmpty()) {
valueList = defaultValues;
} else {
// if there are more default values as specified, add them to
// the list.
if (defaultValues.size() > valueList.size()) {
// copy the list first
valueList = new ArrayList(valueList);
for (int i=valueList.size(); i<defaultValues.size(); i++) {
valueList.add(defaultValues.get(i));
}
}
}
}
return valueList == null ? Collections.EMPTY_LIST : valueList;
} | src/java/org/apache/commons/cli2/commandline/WriteableCommandLineImpl.java |
Cli-17 | protected void burstToken(String token, boolean stopAtNonOption)
{
for (int i = 1; i < token.length(); i++)
{
String ch = String.valueOf(token.charAt(i));
if (options.hasOption(ch))
{
tokens.add("-" + ch);
currentOption = options.getOption(ch);
if (currentOption.hasArg() && (token.length() != (i + 1)))
{
tokens.add(token.substring(i + 1));
break;
}
}
else if (stopAtNonOption)
{
process(token.substring(i));
}
else
{
tokens.add(token);
break;
}
}
}
protected void burstToken(String token, boolean stopAtNonOption)
{
for (int i = 1; i < token.length(); i++)
{
String ch = String.valueOf(token.charAt(i));
if (options.hasOption(ch))
{
tokens.add("-" + ch);
currentOption = options.getOption(ch);
if (currentOption.hasArg() && (token.length() != (i + 1)))
{
tokens.add(token.substring(i + 1));
break;
}
}
else if (stopAtNonOption)
{
process(token.substring(i));
break;
}
else
{
tokens.add(token);
break;
}
}
} | src/java/org/apache/commons/cli/PosixParser.java |
Cli-19 | private void processOptionToken(String token, boolean stopAtNonOption)
{
if (options.hasOption(token))
{
currentOption = options.getOption(token);
tokens.add(token);
}
else if (stopAtNonOption)
{
eatTheRest = true;
tokens.add(token);
}
}
private void processOptionToken(String token, boolean stopAtNonOption)
{
if (options.hasOption(token))
{
currentOption = options.getOption(token);
}
else if (stopAtNonOption)
{
eatTheRest = true;
}
tokens.add(token);
} | src/java/org/apache/commons/cli/PosixParser.java |
Cli-20 | protected String[] flatten(Options options, String[] arguments, boolean stopAtNonOption)
{
init();
this.options = options;
// an iterator for the command line tokens
Iterator iter = Arrays.asList(arguments).iterator();
// process each command line token
while (iter.hasNext())
{
// get the next command line token
String token = (String) iter.next();
// handle long option --foo or --foo=bar
if (token.startsWith("--"))
{
if (token.indexOf('=') != -1)
{
tokens.add(token.substring(0, token.indexOf('=')));
tokens.add(token.substring(token.indexOf('=') + 1, token.length()));
}
else
{
tokens.add(token);
}
}
// single hyphen
else if ("-".equals(token))
{
tokens.add(token);
}
else if (token.startsWith("-"))
{
if (token.length() == 2)
{
processOptionToken(token, stopAtNonOption);
}
else if (options.hasOption(token))
{
tokens.add(token);
}
// requires bursting
else
{
burstToken(token, stopAtNonOption);
}
}
else if (stopAtNonOption)
{
process(token);
}
else
{
tokens.add(token);
}
gobble(iter);
}
return (String[]) tokens.toArray(new String[tokens.size()]);
}
protected String[] flatten(Options options, String[] arguments, boolean stopAtNonOption)
{
init();
this.options = options;
// an iterator for the command line tokens
Iterator iter = Arrays.asList(arguments).iterator();
// process each command line token
while (iter.hasNext())
{
// get the next command line token
String token = (String) iter.next();
// handle long option --foo or --foo=bar
if (token.startsWith("--"))
{
int pos = token.indexOf('=');
String opt = pos == -1 ? token : token.substring(0, pos); // --foo
if (!options.hasOption(opt) && stopAtNonOption)
{
process(token);
}
else
{
tokens.add(opt);
if (pos != -1) {
tokens.add(token.substring(pos + 1));
}
}
}
// single hyphen
else if ("-".equals(token))
{
tokens.add(token);
}
else if (token.startsWith("-"))
{
if (token.length() == 2)
{
processOptionToken(token, stopAtNonOption);
}
else if (options.hasOption(token))
{
tokens.add(token);
}
// requires bursting
else
{
burstToken(token, stopAtNonOption);
}
}
else if (stopAtNonOption)
{
process(token);
}
else
{
tokens.add(token);
}
gobble(iter);
}
return (String[]) tokens.toArray(new String[tokens.size()]);
} | src/java/org/apache/commons/cli/PosixParser.java |
Cli-23 | protected StringBuffer renderWrappedText(StringBuffer sb, int width,
int nextLineTabStop, String text)
{
int pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(rtrim(text));
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
// all following lines must be padded with nextLineTabStop space
// characters
final String padding = createPadding(nextLineTabStop);
while (true)
{
int lastPos = pos;
text = padding + text.substring(pos).trim();
pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(text);
return sb;
} else
if (pos == lastPos)
{
throw new RuntimeException("Text too long for line - throwing exception to avoid infinite loop [CLI-162]: " + text);
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
}
}
protected StringBuffer renderWrappedText(StringBuffer sb, int width,
int nextLineTabStop, String text)
{
int pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(rtrim(text));
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
// all following lines must be padded with nextLineTabStop space
// characters
final String padding = createPadding(nextLineTabStop);
while (true)
{
text = padding + text.substring(pos).trim();
pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(text);
return sb;
}
if ( (text.length() > width) && (pos == nextLineTabStop - 1) ) {
sb.append(text);
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
}
} | src/java/org/apache/commons/cli/HelpFormatter.java |
Cli-24 | protected StringBuffer renderWrappedText(StringBuffer sb, int width,
int nextLineTabStop, String text)
{
int pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(rtrim(text));
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
if (nextLineTabStop >= width)
{
// stops infinite loop happening
throw new IllegalStateException("Total width is less than the width of the argument and indent " +
"- no room for the description");
}
// all following lines must be padded with nextLineTabStop space
// characters
final String padding = createPadding(nextLineTabStop);
while (true)
{
text = padding + text.substring(pos).trim();
pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(text);
return sb;
}
if ( (text.length() > width) && (pos == nextLineTabStop - 1) )
{
pos = width;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
}
}
protected StringBuffer renderWrappedText(StringBuffer sb, int width,
int nextLineTabStop, String text)
{
int pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(rtrim(text));
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
if (nextLineTabStop >= width)
{
// stops infinite loop happening
nextLineTabStop = width - 1;
}
// all following lines must be padded with nextLineTabStop space
// characters
final String padding = createPadding(nextLineTabStop);
while (true)
{
text = padding + text.substring(pos).trim();
pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(text);
return sb;
}
if ( (text.length() > width) && (pos == nextLineTabStop - 1) )
{
pos = width;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
}
} | src/java/org/apache/commons/cli/HelpFormatter.java |
Cli-25 | protected StringBuffer renderWrappedText(StringBuffer sb, int width,
int nextLineTabStop, String text)
{
int pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(rtrim(text));
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
if (nextLineTabStop >= width)
{
// stops infinite loop happening
nextLineTabStop = width - 1;
}
// all following lines must be padded with nextLineTabStop space
// characters
final String padding = createPadding(nextLineTabStop);
while (true)
{
text = padding + text.substring(pos).trim();
pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(text);
return sb;
}
if ( (text.length() > width) && (pos == nextLineTabStop - 1) )
{
pos = width;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
}
}
protected StringBuffer renderWrappedText(StringBuffer sb, int width,
int nextLineTabStop, String text)
{
int pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(rtrim(text));
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
if (nextLineTabStop >= width)
{
// stops infinite loop happening
nextLineTabStop = 1;
}
// all following lines must be padded with nextLineTabStop space
// characters
final String padding = createPadding(nextLineTabStop);
while (true)
{
text = padding + text.substring(pos).trim();
pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(text);
return sb;
}
if ( (text.length() > width) && (pos == nextLineTabStop - 1) )
{
pos = width;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
}
} | src/java/org/apache/commons/cli/HelpFormatter.java |
Cli-26 | public static Option create(String opt) throws IllegalArgumentException
{
// create the option
Option option = new Option(opt, description);
// set the option properties
option.setLongOpt(longopt);
option.setRequired(required);
option.setOptionalArg(optionalArg);
option.setArgs(numberOfArgs);
option.setType(type);
option.setValueSeparator(valuesep);
option.setArgName(argName);
// reset the OptionBuilder properties
OptionBuilder.reset();
// return the Option instance
return option;
}
public static Option create(String opt) throws IllegalArgumentException
{
Option option = null;
try {
// create the option
option = new Option(opt, description);
// set the option properties
option.setLongOpt(longopt);
option.setRequired(required);
option.setOptionalArg(optionalArg);
option.setArgs(numberOfArgs);
option.setType(type);
option.setValueSeparator(valuesep);
option.setArgName(argName);
} finally {
// reset the OptionBuilder properties
OptionBuilder.reset();
}
// return the Option instance
return option;
} | src/java/org/apache/commons/cli/OptionBuilder.java |
Cli-27 | public void setSelected(Option option) throws AlreadySelectedException
{
if (option == null)
{
// reset the option previously selected
selected = null;
return;
}
// if no option has already been selected or the
// same option is being reselected then set the
// selected member variable
if (selected == null || selected.equals(option.getOpt()))
{
selected = option.getOpt();
}
else
{
throw new AlreadySelectedException(this, option);
}
}
public void setSelected(Option option) throws AlreadySelectedException
{
if (option == null)
{
// reset the option previously selected
selected = null;
return;
}
// if no option has already been selected or the
// same option is being reselected then set the
// selected member variable
if (selected == null || selected.equals(option.getKey()))
{
selected = option.getKey();
}
else
{
throw new AlreadySelectedException(this, option);
}
} | src/java/org/apache/commons/cli/OptionGroup.java |
Cli-28 | protected void processProperties(Properties properties)
{
if (properties == null)
{
return;
}
for (Enumeration e = properties.propertyNames(); e.hasMoreElements();)
{
String option = e.nextElement().toString();
if (!cmd.hasOption(option))
{
Option opt = getOptions().getOption(option);
// get the value from the properties instance
String value = properties.getProperty(option);
if (opt.hasArg())
{
if (opt.getValues() == null || opt.getValues().length == 0)
{
try
{
opt.addValueForProcessing(value);
}
catch (RuntimeException exp)
{
// if we cannot add the value don't worry about it
}
}
}
else if (!("yes".equalsIgnoreCase(value)
|| "true".equalsIgnoreCase(value)
|| "1".equalsIgnoreCase(value)))
{
// if the value is not yes, true or 1 then don't add the
// option to the CommandLine
break;
}
cmd.addOption(opt);
}
}
}
protected void processProperties(Properties properties)
{
if (properties == null)
{
return;
}
for (Enumeration e = properties.propertyNames(); e.hasMoreElements();)
{
String option = e.nextElement().toString();
if (!cmd.hasOption(option))
{
Option opt = getOptions().getOption(option);
// get the value from the properties instance
String value = properties.getProperty(option);
if (opt.hasArg())
{
if (opt.getValues() == null || opt.getValues().length == 0)
{
try
{
opt.addValueForProcessing(value);
}
catch (RuntimeException exp)
{
// if we cannot add the value don't worry about it
}
}
}
else if (!("yes".equalsIgnoreCase(value)
|| "true".equalsIgnoreCase(value)
|| "1".equalsIgnoreCase(value)))
{
// if the value is not yes, true or 1 then don't add the
// option to the CommandLine
continue;
}
cmd.addOption(opt);
}
}
} | src/java/org/apache/commons/cli/Parser.java |
Cli-29 | static String stripLeadingAndTrailingQuotes(String str)
{
if (str.startsWith("\""))
{
str = str.substring(1, str.length());
}
int length = str.length();
if (str.endsWith("\""))
{
str = str.substring(0, length - 1);
}
return str;
}
static String stripLeadingAndTrailingQuotes(String str)
{
int length = str.length();
if (length > 1 && str.startsWith("\"") && str.endsWith("\"") && str.substring(1, length - 1).indexOf('"') == -1)
{
str = str.substring(1, length - 1);
}
return str;
} | src/java/org/apache/commons/cli/Util.java |
Cli-32 | protected int findWrapPos(String text, int width, int startPos)
{
int pos;
// the line ends before the max wrap pos or a new line char found
if (((pos = text.indexOf('\n', startPos)) != -1 && pos <= width)
|| ((pos = text.indexOf('\t', startPos)) != -1 && pos <= width))
{
return pos + 1;
}
else if (startPos + width >= text.length())
{
return -1;
}
// look for the last whitespace character before startPos+width
pos = startPos + width;
char c;
while ((pos >= startPos) && ((c = text.charAt(pos)) != ' ')
&& (c != '\n') && (c != '\r'))
{
--pos;
}
// if we found it - just return
if (pos > startPos)
{
return pos;
}
// if we didn't find one, simply chop at startPos+width
pos = startPos + width;
while ((pos <= text.length()) && ((c = text.charAt(pos)) != ' ')
&& (c != '\n') && (c != '\r'))
{
++pos;
}
return pos == text.length() ? -1 : pos;
}
protected int findWrapPos(String text, int width, int startPos)
{
int pos;
// the line ends before the max wrap pos or a new line char found
if (((pos = text.indexOf('\n', startPos)) != -1 && pos <= width)
|| ((pos = text.indexOf('\t', startPos)) != -1 && pos <= width))
{
return pos + 1;
}
else if (startPos + width >= text.length())
{
return -1;
}
// look for the last whitespace character before startPos+width
pos = startPos + width;
char c;
while ((pos >= startPos) && ((c = text.charAt(pos)) != ' ')
&& (c != '\n') && (c != '\r'))
{
--pos;
}
// if we found it - just return
if (pos > startPos)
{
return pos;
}
// if we didn't find one, simply chop at startPos+width
pos = startPos + width;
return pos == text.length() ? -1 : pos;
} | src/main/java/org/apache/commons/cli/HelpFormatter.java |
Cli-35 | public List<String> getMatchingOptions(String opt)
{
opt = Util.stripLeadingHyphens(opt);
List<String> matchingOpts = new ArrayList<String>();
// for a perfect match return the single option only
for (String longOpt : longOpts.keySet())
{
if (longOpt.startsWith(opt))
{
matchingOpts.add(longOpt);
}
}
return matchingOpts;
}
public List<String> getMatchingOptions(String opt)
{
opt = Util.stripLeadingHyphens(opt);
List<String> matchingOpts = new ArrayList<String>();
// for a perfect match return the single option only
if(longOpts.keySet().contains(opt)) {
return Collections.singletonList(opt);
}
for (String longOpt : longOpts.keySet())
{
if (longOpt.startsWith(opt))
{
matchingOpts.add(longOpt);
}
}
return matchingOpts;
} | src/main/java/org/apache/commons/cli/Options.java |
Cli-37 | private boolean isShortOption(String token)
{
// short options (-S, -SV, -S=V, -SV1=V2, -S1S2)
return token.startsWith("-") && token.length() >= 2 && options.hasShortOption(token.substring(1, 2));
// remove leading "-" and "=value"
}
private boolean isShortOption(String token)
{
// short options (-S, -SV, -S=V, -SV1=V2, -S1S2)
if (!token.startsWith("-") || token.length() == 1)
{
return false;
}
// remove leading "-" and "=value"
int pos = token.indexOf("=");
String optName = pos == -1 ? token.substring(1) : token.substring(1, pos);
return options.hasShortOption(optName);
} | src/main/java/org/apache/commons/cli/DefaultParser.java |
Cli-38 | private boolean isShortOption(String token)
{
// short options (-S, -SV, -S=V, -SV1=V2, -S1S2)
if (!token.startsWith("-") || token.length() == 1)
{
return false;
}
// remove leading "-" and "=value"
int pos = token.indexOf("=");
String optName = pos == -1 ? token.substring(1) : token.substring(1, pos);
return options.hasShortOption(optName);
// check for several concatenated short options
}
private boolean isShortOption(String token)
{
// short options (-S, -SV, -S=V, -SV1=V2, -S1S2)
if (!token.startsWith("-") || token.length() == 1)
{
return false;
}
// remove leading "-" and "=value"
int pos = token.indexOf("=");
String optName = pos == -1 ? token.substring(1) : token.substring(1, pos);
if (options.hasShortOption(optName))
{
return true;
}
// check for several concatenated short options
return optName.length() > 0 && options.hasShortOption(String.valueOf(optName.charAt(0)));
} | src/main/java/org/apache/commons/cli/DefaultParser.java |
Cli-4 | private void checkRequiredOptions()
throws MissingOptionException
{
// if there are required options that have not been
// processsed
if (requiredOptions.size() > 0)
{
Iterator iter = requiredOptions.iterator();
StringBuffer buff = new StringBuffer();
// loop through the required options
while (iter.hasNext())
{
buff.append(iter.next());
}
throw new MissingOptionException(buff.toString());
}
}
private void checkRequiredOptions()
throws MissingOptionException
{
// if there are required options that have not been
// processsed
if (requiredOptions.size() > 0)
{
Iterator iter = requiredOptions.iterator();
StringBuffer buff = new StringBuffer("Missing required option");
buff.append(requiredOptions.size() == 1 ? "" : "s");
buff.append(": ");
// loop through the required options
while (iter.hasNext())
{
buff.append(iter.next());
}
throw new MissingOptionException(buff.toString());
}
} | src/java/org/apache/commons/cli/Parser.java |
Cli-40 | public static <T> T createValue(final String str, final Class<T> clazz) throws ParseException
{
if (PatternOptionBuilder.STRING_VALUE == clazz)
{
return (T) str;
}
else if (PatternOptionBuilder.OBJECT_VALUE == clazz)
{
return (T) createObject(str);
}
else if (PatternOptionBuilder.NUMBER_VALUE == clazz)
{
return (T) createNumber(str);
}
else if (PatternOptionBuilder.DATE_VALUE == clazz)
{
return (T) createDate(str);
}
else if (PatternOptionBuilder.CLASS_VALUE == clazz)
{
return (T) createClass(str);
}
else if (PatternOptionBuilder.FILE_VALUE == clazz)
{
return (T) createFile(str);
}
else if (PatternOptionBuilder.EXISTING_FILE_VALUE == clazz)
{
return (T) openFile(str);
}
else if (PatternOptionBuilder.FILES_VALUE == clazz)
{
return (T) createFiles(str);
}
else if (PatternOptionBuilder.URL_VALUE == clazz)
{
return (T) createURL(str);
}
else
{
return null;
}
}
public static <T> T createValue(final String str, final Class<T> clazz) throws ParseException
{
if (PatternOptionBuilder.STRING_VALUE == clazz)
{
return (T) str;
}
else if (PatternOptionBuilder.OBJECT_VALUE == clazz)
{
return (T) createObject(str);
}
else if (PatternOptionBuilder.NUMBER_VALUE == clazz)
{
return (T) createNumber(str);
}
else if (PatternOptionBuilder.DATE_VALUE == clazz)
{
return (T) createDate(str);
}
else if (PatternOptionBuilder.CLASS_VALUE == clazz)
{
return (T) createClass(str);
}
else if (PatternOptionBuilder.FILE_VALUE == clazz)
{
return (T) createFile(str);
}
else if (PatternOptionBuilder.EXISTING_FILE_VALUE == clazz)
{
return (T) openFile(str);
}
else if (PatternOptionBuilder.FILES_VALUE == clazz)
{
return (T) createFiles(str);
}
else if (PatternOptionBuilder.URL_VALUE == clazz)
{
return (T) createURL(str);
}
else
{
throw new ParseException("Unable to handle the class: " + clazz);
}
} | src/main/java/org/apache/commons/cli/TypeHandler.java |
Cli-5 | static String stripLeadingHyphens(String str)
{
if (str.startsWith("--"))
{
return str.substring(2, str.length());
}
else if (str.startsWith("-"))
{
return str.substring(1, str.length());
}
return str;
}
static String stripLeadingHyphens(String str)
{
if (str == null) {
return null;
}
if (str.startsWith("--"))
{
return str.substring(2, str.length());
}
else if (str.startsWith("-"))
{
return str.substring(1, str.length());
}
return str;
} | src/java/org/apache/commons/cli/Util.java |
Cli-8 | protected StringBuffer renderWrappedText(StringBuffer sb, int width,
int nextLineTabStop, String text)
{
int pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(rtrim(text));
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
// all following lines must be padded with nextLineTabStop space
// characters
final String padding = createPadding(nextLineTabStop);
while (true)
{
text = padding + text.substring(pos).trim();
pos = findWrapPos(text, width, nextLineTabStop);
if (pos == -1)
{
sb.append(text);
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
}
}
protected StringBuffer renderWrappedText(StringBuffer sb, int width,
int nextLineTabStop, String text)
{
int pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(rtrim(text));
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
// all following lines must be padded with nextLineTabStop space
// characters
final String padding = createPadding(nextLineTabStop);
while (true)
{
text = padding + text.substring(pos).trim();
pos = findWrapPos(text, width, 0);
if (pos == -1)
{
sb.append(text);
return sb;
}
sb.append(rtrim(text.substring(0, pos))).append(defaultNewLine);
}
} | src/java/org/apache/commons/cli/HelpFormatter.java |
Cli-9 | protected void checkRequiredOptions()
throws MissingOptionException
{
// if there are required options that have not been
// processsed
if (getRequiredOptions().size() > 0)
{
Iterator iter = getRequiredOptions().iterator();
StringBuffer buff = new StringBuffer("Missing required option");
buff.append(getRequiredOptions().size() == 1 ? "" : "s");
buff.append(": ");
// loop through the required options
while (iter.hasNext())
{
buff.append(iter.next());
}
throw new MissingOptionException(buff.toString());
}
}
protected void checkRequiredOptions()
throws MissingOptionException
{
// if there are required options that have not been
// processsed
if (getRequiredOptions().size() > 0)
{
Iterator iter = getRequiredOptions().iterator();
StringBuffer buff = new StringBuffer("Missing required option");
buff.append(getRequiredOptions().size() == 1 ? "" : "s");
buff.append(": ");
// loop through the required options
while (iter.hasNext())
{
buff.append(iter.next());
buff.append(", ");
}
throw new MissingOptionException(buff.substring(0, buff.length() - 2));
}
} | src/java/org/apache/commons/cli/Parser.java |
Closure-1 | private void removeUnreferencedFunctionArgs(Scope fnScope) {
// Notice that removing unreferenced function args breaks
// Function.prototype.length. In advanced mode, we don't really care
// about this: we consider "length" the equivalent of reflecting on
// the function's lexical source.
//
// Rather than create a new option for this, we assume that if the user
// is removing globals, then it's OK to remove unused function args.
//
// See http://code.google.com/p/closure-compiler/issues/detail?id=253
Node function = fnScope.getRootNode();
Preconditions.checkState(function.isFunction());
if (NodeUtil.isGetOrSetKey(function.getParent())) {
// The parameters object literal setters can not be removed.
return;
}
Node argList = getFunctionArgList(function);
boolean modifyCallers = modifyCallSites
&& callSiteOptimizer.canModifyCallers(function);
if (!modifyCallers) {
// Strip unreferenced args off the end of the function declaration.
Node lastArg;
while ((lastArg = argList.getLastChild()) != null) {
Var var = fnScope.getVar(lastArg.getString());
if (!referenced.contains(var)) {
argList.removeChild(lastArg);
compiler.reportCodeChange();
} else {
break;
}
}
} else {
callSiteOptimizer.optimize(fnScope, referenced);
}
}
private void removeUnreferencedFunctionArgs(Scope fnScope) {
// Notice that removing unreferenced function args breaks
// Function.prototype.length. In advanced mode, we don't really care
// about this: we consider "length" the equivalent of reflecting on
// the function's lexical source.
//
// Rather than create a new option for this, we assume that if the user
// is removing globals, then it's OK to remove unused function args.
//
// See http://code.google.com/p/closure-compiler/issues/detail?id=253
if (!removeGlobals) {
return;
}
Node function = fnScope.getRootNode();
Preconditions.checkState(function.isFunction());
if (NodeUtil.isGetOrSetKey(function.getParent())) {
// The parameters object literal setters can not be removed.
return;
}
Node argList = getFunctionArgList(function);
boolean modifyCallers = modifyCallSites
&& callSiteOptimizer.canModifyCallers(function);
if (!modifyCallers) {
// Strip unreferenced args off the end of the function declaration.
Node lastArg;
while ((lastArg = argList.getLastChild()) != null) {
Var var = fnScope.getVar(lastArg.getString());
if (!referenced.contains(var)) {
argList.removeChild(lastArg);
compiler.reportCodeChange();
} else {
break;
}
}
} else {
callSiteOptimizer.optimize(fnScope, referenced);
}
} | src/com/google/javascript/jscomp/RemoveUnusedVars.java |
Closure-10 | static boolean mayBeString(Node n, boolean recurse) {
if (recurse) {
return allResultsMatch(n, MAY_BE_STRING_PREDICATE);
} else {
return mayBeStringHelper(n);
}
}
static boolean mayBeString(Node n, boolean recurse) {
if (recurse) {
return anyResultsMatch(n, MAY_BE_STRING_PREDICATE);
} else {
return mayBeStringHelper(n);
}
} | src/com/google/javascript/jscomp/NodeUtil.java |
Closure-101 | protected CompilerOptions createOptions() {
CompilerOptions options = new CompilerOptions();
options.setCodingConvention(new ClosureCodingConvention());
CompilationLevel level = flags.compilation_level;
level.setOptionsForCompilationLevel(options);
if (flags.debug) {
level.setDebugOptionsForCompilationLevel(options);
}
WarningLevel wLevel = flags.warning_level;
wLevel.setOptionsForWarningLevel(options);
for (FormattingOption formattingOption : flags.formatting) {
formattingOption.applyToOptions(options);
}
if (flags.process_closure_primitives) {
options.closurePass = true;
}
initOptionsFromFlags(options);
return options;
}
protected CompilerOptions createOptions() {
CompilerOptions options = new CompilerOptions();
options.setCodingConvention(new ClosureCodingConvention());
CompilationLevel level = flags.compilation_level;
level.setOptionsForCompilationLevel(options);
if (flags.debug) {
level.setDebugOptionsForCompilationLevel(options);
}
WarningLevel wLevel = flags.warning_level;
wLevel.setOptionsForWarningLevel(options);
for (FormattingOption formattingOption : flags.formatting) {
formattingOption.applyToOptions(options);
}
options.closurePass = flags.process_closure_primitives;
initOptionsFromFlags(options);
return options;
} | src/com/google/javascript/jscomp/CommandLineRunner.java |
Closure-102 | public void process(Node externs, Node root) {
NodeTraversal.traverse(compiler, root, this);
if (MAKE_LOCAL_NAMES_UNIQUE) {
MakeDeclaredNamesUnique renamer = new MakeDeclaredNamesUnique();
NodeTraversal t = new NodeTraversal(compiler, renamer);
t.traverseRoots(externs, root);
}
removeDuplicateDeclarations(root);
new PropogateConstantAnnotations(compiler, assertOnChange)
.process(externs, root);
}
public void process(Node externs, Node root) {
NodeTraversal.traverse(compiler, root, this);
removeDuplicateDeclarations(root);
if (MAKE_LOCAL_NAMES_UNIQUE) {
MakeDeclaredNamesUnique renamer = new MakeDeclaredNamesUnique();
NodeTraversal t = new NodeTraversal(compiler, renamer);
t.traverseRoots(externs, root);
}
new PropogateConstantAnnotations(compiler, assertOnChange)
.process(externs, root);
} | src/com/google/javascript/jscomp/Normalize.java |
Closure-104 | JSType meet(JSType that) {
UnionTypeBuilder builder = new UnionTypeBuilder(registry);
for (JSType alternate : alternates) {
if (alternate.isSubtype(that)) {
builder.addAlternate(alternate);
}
}
if (that instanceof UnionType) {
for (JSType otherAlternate : ((UnionType) that).alternates) {
if (otherAlternate.isSubtype(this)) {
builder.addAlternate(otherAlternate);
}
}
} else if (that.isSubtype(this)) {
builder.addAlternate(that);
}
JSType result = builder.build();
if (result != null) {
return result;
} else if (this.isObject() && that.isObject()) {
return getNativeType(JSTypeNative.NO_OBJECT_TYPE);
} else {
return getNativeType(JSTypeNative.NO_TYPE);
}
}
JSType meet(JSType that) {
UnionTypeBuilder builder = new UnionTypeBuilder(registry);
for (JSType alternate : alternates) {
if (alternate.isSubtype(that)) {
builder.addAlternate(alternate);
}
}
if (that instanceof UnionType) {
for (JSType otherAlternate : ((UnionType) that).alternates) {
if (otherAlternate.isSubtype(this)) {
builder.addAlternate(otherAlternate);
}
}
} else if (that.isSubtype(this)) {
builder.addAlternate(that);
}
JSType result = builder.build();
if (!result.isNoType()) {
return result;
} else if (this.isObject() && that.isObject()) {
return getNativeType(JSTypeNative.NO_OBJECT_TYPE);
} else {
return getNativeType(JSTypeNative.NO_TYPE);
}
} | src/com/google/javascript/rhino/jstype/UnionType.java |
Closure-105 | void tryFoldStringJoin(NodeTraversal t, Node n, Node left, Node right,
Node parent) {
if (!NodeUtil.isGetProp(left) || !NodeUtil.isImmutableValue(right)) {
return;
}
Node arrayNode = left.getFirstChild();
Node functionName = arrayNode.getNext();
if ((arrayNode.getType() != Token.ARRAYLIT) ||
!functionName.getString().equals("join")) {
return;
}
String joinString = NodeUtil.getStringValue(right);
List<Node> arrayFoldedChildren = Lists.newLinkedList();
StringBuilder sb = new StringBuilder();
int foldedSize = 0;
Node elem = arrayNode.getFirstChild();
// Merges adjacent String nodes.
while (elem != null) {
if (NodeUtil.isImmutableValue(elem)) {
if (sb.length() > 0) {
sb.append(joinString);
}
sb.append(NodeUtil.getStringValue(elem));
} else {
if (sb.length() > 0) {
// + 2 for the quotes.
foldedSize += sb.length() + 2;
arrayFoldedChildren.add(Node.newString(sb.toString()));
sb = new StringBuilder();
}
foldedSize += InlineCostEstimator.getCost(elem);
arrayFoldedChildren.add(elem);
}
elem = elem.getNext();
}
if (sb.length() > 0) {
// + 2 for the quotes.
foldedSize += sb.length() + 2;
arrayFoldedChildren.add(Node.newString(sb.toString()));
}
// one for each comma.
foldedSize += arrayFoldedChildren.size() - 1;
int originalSize = InlineCostEstimator.getCost(n);
switch (arrayFoldedChildren.size()) {
case 0:
Node emptyStringNode = Node.newString("");
parent.replaceChild(n, emptyStringNode);
break;
case 1:
Node foldedStringNode = arrayFoldedChildren.remove(0);
if (foldedSize > originalSize) {
return;
}
arrayNode.detachChildren();
if (foldedStringNode.getType() != Token.STRING) {
// If the Node is not a string literal, ensure that
// it is coerced to a string.
Node replacement = new Node(Token.ADD,
Node.newString(""), foldedStringNode);
foldedStringNode = replacement;
}
parent.replaceChild(n, foldedStringNode);
break;
default:
// No folding could actually be performed.
if (arrayFoldedChildren.size() == arrayNode.getChildCount()) {
return;
}
int kJoinOverhead = "[].join()".length();
foldedSize += kJoinOverhead;
foldedSize += InlineCostEstimator.getCost(right);
if (foldedSize > originalSize) {
return;
}
arrayNode.detachChildren();
for (Node node : arrayFoldedChildren) {
arrayNode.addChildToBack(node);
}
break;
}
t.getCompiler().reportCodeChange();
}
void tryFoldStringJoin(NodeTraversal t, Node n, Node left, Node right,
Node parent) {
if (!NodeUtil.isGetProp(left) || !NodeUtil.isImmutableValue(right)) {
return;
}
Node arrayNode = left.getFirstChild();
Node functionName = arrayNode.getNext();
if ((arrayNode.getType() != Token.ARRAYLIT) ||
!functionName.getString().equals("join")) {
return;
}
String joinString = NodeUtil.getStringValue(right);
List<Node> arrayFoldedChildren = Lists.newLinkedList();
StringBuilder sb = null;
int foldedSize = 0;
Node elem = arrayNode.getFirstChild();
// Merges adjacent String nodes.
while (elem != null) {
if (NodeUtil.isImmutableValue(elem)) {
if (sb == null) {
sb = new StringBuilder();
} else {
sb.append(joinString);
}
sb.append(NodeUtil.getStringValue(elem));
} else {
if (sb != null) {
// + 2 for the quotes.
foldedSize += sb.length() + 2;
arrayFoldedChildren.add(Node.newString(sb.toString()));
sb = null;
}
foldedSize += InlineCostEstimator.getCost(elem);
arrayFoldedChildren.add(elem);
}
elem = elem.getNext();
}
if (sb != null) {
// + 2 for the quotes.
foldedSize += sb.length() + 2;
arrayFoldedChildren.add(Node.newString(sb.toString()));
}
// one for each comma.
foldedSize += arrayFoldedChildren.size() - 1;
int originalSize = InlineCostEstimator.getCost(n);
switch (arrayFoldedChildren.size()) {
case 0:
Node emptyStringNode = Node.newString("");
parent.replaceChild(n, emptyStringNode);
break;
case 1:
Node foldedStringNode = arrayFoldedChildren.remove(0);
if (foldedSize > originalSize) {
return;
}
arrayNode.detachChildren();
if (foldedStringNode.getType() != Token.STRING) {
// If the Node is not a string literal, ensure that
// it is coerced to a string.
Node replacement = new Node(Token.ADD,
Node.newString(""), foldedStringNode);
foldedStringNode = replacement;
}
parent.replaceChild(n, foldedStringNode);
break;
default:
// No folding could actually be performed.
if (arrayFoldedChildren.size() == arrayNode.getChildCount()) {
return;
}
int kJoinOverhead = "[].join()".length();
foldedSize += kJoinOverhead;
foldedSize += InlineCostEstimator.getCost(right);
if (foldedSize > originalSize) {
return;
}
arrayNode.detachChildren();
for (Node node : arrayFoldedChildren) {
arrayNode.addChildToBack(node);
}
break;
}
t.getCompiler().reportCodeChange();
} | src/com/google/javascript/jscomp/FoldConstants.java |
Closure-107 | protected CompilerOptions createOptions() {
CompilerOptions options = new CompilerOptions();
if (flags.processJqueryPrimitives) {
options.setCodingConvention(new JqueryCodingConvention());
} else {
options.setCodingConvention(new ClosureCodingConvention());
}
options.setExtraAnnotationNames(flags.extraAnnotationName);
CompilationLevel level = flags.compilationLevel;
level.setOptionsForCompilationLevel(options);
if (flags.debug) {
level.setDebugOptionsForCompilationLevel(options);
}
if (flags.useTypesForOptimization) {
level.setTypeBasedOptimizationOptions(options);
}
if (flags.generateExports) {
options.setGenerateExports(flags.generateExports);
}
WarningLevel wLevel = flags.warningLevel;
wLevel.setOptionsForWarningLevel(options);
for (FormattingOption formattingOption : flags.formatting) {
formattingOption.applyToOptions(options);
}
options.closurePass = flags.processClosurePrimitives;
options.jqueryPass = CompilationLevel.ADVANCED_OPTIMIZATIONS == level &&
flags.processJqueryPrimitives;
options.angularPass = flags.angularPass;
if (!flags.translationsFile.isEmpty()) {
try {
options.messageBundle = new XtbMessageBundle(
new FileInputStream(flags.translationsFile),
flags.translationsProject);
} catch (IOException e) {
throw new RuntimeException("Reading XTB file", e);
}
} else if (CompilationLevel.ADVANCED_OPTIMIZATIONS == level) {
// In SIMPLE or WHITESPACE mode, if the user hasn't specified a
// translations file, they might reasonably try to write their own
// implementation of goog.getMsg that makes the substitution at
// run-time.
//
// In ADVANCED mode, goog.getMsg is going to be renamed anyway,
// so we might as well inline it. But shut off the i18n warnings,
// because the user didn't really ask for i18n.
options.messageBundle = new EmptyMessageBundle();
}
return options;
}
protected CompilerOptions createOptions() {
CompilerOptions options = new CompilerOptions();
if (flags.processJqueryPrimitives) {
options.setCodingConvention(new JqueryCodingConvention());
} else {
options.setCodingConvention(new ClosureCodingConvention());
}
options.setExtraAnnotationNames(flags.extraAnnotationName);
CompilationLevel level = flags.compilationLevel;
level.setOptionsForCompilationLevel(options);
if (flags.debug) {
level.setDebugOptionsForCompilationLevel(options);
}
if (flags.useTypesForOptimization) {
level.setTypeBasedOptimizationOptions(options);
}
if (flags.generateExports) {
options.setGenerateExports(flags.generateExports);
}
WarningLevel wLevel = flags.warningLevel;
wLevel.setOptionsForWarningLevel(options);
for (FormattingOption formattingOption : flags.formatting) {
formattingOption.applyToOptions(options);
}
options.closurePass = flags.processClosurePrimitives;
options.jqueryPass = CompilationLevel.ADVANCED_OPTIMIZATIONS == level &&
flags.processJqueryPrimitives;
options.angularPass = flags.angularPass;
if (!flags.translationsFile.isEmpty()) {
try {
options.messageBundle = new XtbMessageBundle(
new FileInputStream(flags.translationsFile),
flags.translationsProject);
} catch (IOException e) {
throw new RuntimeException("Reading XTB file", e);
}
} else if (CompilationLevel.ADVANCED_OPTIMIZATIONS == level) {
// In SIMPLE or WHITESPACE mode, if the user hasn't specified a
// translations file, they might reasonably try to write their own
// implementation of goog.getMsg that makes the substitution at
// run-time.
//
// In ADVANCED mode, goog.getMsg is going to be renamed anyway,
// so we might as well inline it. But shut off the i18n warnings,
// because the user didn't really ask for i18n.
options.messageBundle = new EmptyMessageBundle();
options.setWarningLevel(JsMessageVisitor.MSG_CONVENTIONS, CheckLevel.OFF);
}
return options;
} | src/com/google/javascript/jscomp/CommandLineRunner.java |
Closure-109 | private Node parseContextTypeExpression(JsDocToken token) {
return parseTypeName(token);
}
private Node parseContextTypeExpression(JsDocToken token) {
if (token == JsDocToken.QMARK) {
return newNode(Token.QMARK);
} else {
return parseBasicTypeExpression(token);
}
} | src/com/google/javascript/jscomp/parsing/JsDocInfoParser.java |
Closure-11 | private void visitGetProp(NodeTraversal t, Node n, Node parent) {
// obj.prop or obj.method()
// Lots of types can appear on the left, a call to a void function can
// never be on the left. getPropertyType will decide what is acceptable
// and what isn't.
Node property = n.getLastChild();
Node objNode = n.getFirstChild();
JSType childType = getJSType(objNode);
if (childType.isDict()) {
report(t, property, TypeValidator.ILLEGAL_PROPERTY_ACCESS, "'.'", "dict");
} else if (n.getJSType() != null && parent.isAssign()) {
return;
} else if (validator.expectNotNullOrUndefined(t, n, childType,
"No properties on this expression", getNativeType(OBJECT_TYPE))) {
checkPropertyAccess(childType, property.getString(), t, n);
}
ensureTyped(t, n);
}
private void visitGetProp(NodeTraversal t, Node n, Node parent) {
// obj.prop or obj.method()
// Lots of types can appear on the left, a call to a void function can
// never be on the left. getPropertyType will decide what is acceptable
// and what isn't.
Node property = n.getLastChild();
Node objNode = n.getFirstChild();
JSType childType = getJSType(objNode);
if (childType.isDict()) {
report(t, property, TypeValidator.ILLEGAL_PROPERTY_ACCESS, "'.'", "dict");
} else if (validator.expectNotNullOrUndefined(t, n, childType,
"No properties on this expression", getNativeType(OBJECT_TYPE))) {
checkPropertyAccess(childType, property.getString(), t, n);
}
ensureTyped(t, n);
} | src/com/google/javascript/jscomp/TypeCheck.java |
Closure-111 | protected JSType caseTopType(JSType topType) {
return topType;
}
protected JSType caseTopType(JSType topType) {
return topType.isAllType() ?
getNativeType(ARRAY_TYPE) : topType;
} | src/com/google/javascript/jscomp/type/ClosureReverseAbstractInterpreter.java |
Closure-112 | private boolean inferTemplatedTypesForCall(
Node n, FunctionType fnType) {
final ImmutableList<TemplateType> keys = fnType.getTemplateTypeMap()
.getTemplateKeys();
if (keys.isEmpty()) {
return false;
}
// Try to infer the template types
Map<TemplateType, JSType> inferred =
inferTemplateTypesFromParameters(fnType, n);
// Replace all template types. If we couldn't find a replacement, we
// replace it with UNKNOWN.
TemplateTypeReplacer replacer = new TemplateTypeReplacer(
registry, inferred);
Node callTarget = n.getFirstChild();
FunctionType replacementFnType = fnType.visit(replacer)
.toMaybeFunctionType();
Preconditions.checkNotNull(replacementFnType);
callTarget.setJSType(replacementFnType);
n.setJSType(replacementFnType.getReturnType());
return replacer.madeChanges;
}
private boolean inferTemplatedTypesForCall(
Node n, FunctionType fnType) {
final ImmutableList<TemplateType> keys = fnType.getTemplateTypeMap()
.getTemplateKeys();
if (keys.isEmpty()) {
return false;
}
// Try to infer the template types
Map<TemplateType, JSType> inferred = Maps.filterKeys(
inferTemplateTypesFromParameters(fnType, n),
new Predicate<TemplateType>() {
@Override
public boolean apply(TemplateType key) {
return keys.contains(key);
}}
);
// Replace all template types. If we couldn't find a replacement, we
// replace it with UNKNOWN.
TemplateTypeReplacer replacer = new TemplateTypeReplacer(
registry, inferred);
Node callTarget = n.getFirstChild();
FunctionType replacementFnType = fnType.visit(replacer)
.toMaybeFunctionType();
Preconditions.checkNotNull(replacementFnType);
callTarget.setJSType(replacementFnType);
n.setJSType(replacementFnType.getReturnType());
return replacer.madeChanges;
} | src/com/google/javascript/jscomp/TypeInference.java |
Closure-113 | private void processRequireCall(NodeTraversal t, Node n, Node parent) {
Node left = n.getFirstChild();
Node arg = left.getNext();
if (verifyLastArgumentIsString(t, left, arg)) {
String ns = arg.getString();
ProvidedName provided = providedNames.get(ns);
if (provided == null || !provided.isExplicitlyProvided()) {
unrecognizedRequires.add(
new UnrecognizedRequire(n, ns, t.getSourceName()));
} else {
JSModule providedModule = provided.explicitModule;
// This must be non-null, because there was an explicit provide.
Preconditions.checkNotNull(providedModule);
JSModule module = t.getModule();
if (moduleGraph != null &&
module != providedModule &&
!moduleGraph.dependsOn(module, providedModule)) {
compiler.report(
t.makeError(n, XMODULE_REQUIRE_ERROR, ns,
providedModule.getName(),
module.getName()));
}
}
maybeAddToSymbolTable(left);
maybeAddStringNodeToSymbolTable(arg);
// Requires should be removed before further processing.
// Some clients run closure pass multiple times, first with
// the checks for broken requires turned off. In these cases, we
// allow broken requires to be preserved by the first run to
// let them be caught in the subsequent run.
if (provided != null) {
parent.detachFromParent();
compiler.reportCodeChange();
}
}
}
private void processRequireCall(NodeTraversal t, Node n, Node parent) {
Node left = n.getFirstChild();
Node arg = left.getNext();
if (verifyLastArgumentIsString(t, left, arg)) {
String ns = arg.getString();
ProvidedName provided = providedNames.get(ns);
if (provided == null || !provided.isExplicitlyProvided()) {
unrecognizedRequires.add(
new UnrecognizedRequire(n, ns, t.getSourceName()));
} else {
JSModule providedModule = provided.explicitModule;
// This must be non-null, because there was an explicit provide.
Preconditions.checkNotNull(providedModule);
JSModule module = t.getModule();
if (moduleGraph != null &&
module != providedModule &&
!moduleGraph.dependsOn(module, providedModule)) {
compiler.report(
t.makeError(n, XMODULE_REQUIRE_ERROR, ns,
providedModule.getName(),
module.getName()));
}
}
maybeAddToSymbolTable(left);
maybeAddStringNodeToSymbolTable(arg);
// Requires should be removed before further processing.
// Some clients run closure pass multiple times, first with
// the checks for broken requires turned off. In these cases, we
// allow broken requires to be preserved by the first run to
// let them be caught in the subsequent run.
if (provided != null || requiresLevel.isOn()) {
parent.detachFromParent();
compiler.reportCodeChange();
}
}
} | src/com/google/javascript/jscomp/ProcessClosurePrimitives.java |
Closure-114 | private void recordAssignment(NodeTraversal t, Node n, Node recordNode) {
Node nameNode = n.getFirstChild();
Node parent = n.getParent();
NameInformation ns = createNameInformation(t, nameNode);
if (ns != null) {
if (parent.isFor() && !NodeUtil.isForIn(parent)) {
// Patch for assignments that appear in the init,
// condition or iteration part of a FOR loop. Without
// this change, all 3 of those parts try to claim the for
// loop as their dependency scope. The last assignment in
// those three fields wins, which can result in incorrect
// reference edges between referenced and assigned variables.
//
// TODO(user) revisit the dependency scope calculation
// logic.
if (parent.getFirstChild().getNext() != n) {
recordDepScope(recordNode, ns);
} else {
recordDepScope(nameNode, ns);
}
} else {
// The rhs of the assignment is the caller, so it's used by the
// context. Don't associate it w/ the lhs.
// FYI: this fixes only the specific case where the assignment is the
// caller expression, but it could be nested deeper in the caller and
// we would still get a bug.
// See testAssignWithCall2 for an example of this.
recordDepScope(recordNode, ns);
}
}
}
private void recordAssignment(NodeTraversal t, Node n, Node recordNode) {
Node nameNode = n.getFirstChild();
Node parent = n.getParent();
NameInformation ns = createNameInformation(t, nameNode);
if (ns != null) {
if (parent.isFor() && !NodeUtil.isForIn(parent)) {
// Patch for assignments that appear in the init,
// condition or iteration part of a FOR loop. Without
// this change, all 3 of those parts try to claim the for
// loop as their dependency scope. The last assignment in
// those three fields wins, which can result in incorrect
// reference edges between referenced and assigned variables.
//
// TODO(user) revisit the dependency scope calculation
// logic.
if (parent.getFirstChild().getNext() != n) {
recordDepScope(recordNode, ns);
} else {
recordDepScope(nameNode, ns);
}
} else if (!(parent.isCall() && parent.getFirstChild() == n)) {
// The rhs of the assignment is the caller, so it's used by the
// context. Don't associate it w/ the lhs.
// FYI: this fixes only the specific case where the assignment is the
// caller expression, but it could be nested deeper in the caller and
// we would still get a bug.
// See testAssignWithCall2 for an example of this.
recordDepScope(recordNode, ns);
}
}
} | src/com/google/javascript/jscomp/NameAnalyzer.java |
Closure-115 | private CanInlineResult canInlineReferenceDirectly(
Node callNode, Node fnNode) {
if (!isDirectCallNodeReplacementPossible(fnNode)) {
return CanInlineResult.NO;
}
Node block = fnNode.getLastChild();
boolean hasSideEffects = false;
if (block.hasChildren()) {
Preconditions.checkState(block.hasOneChild());
Node stmt = block.getFirstChild();
if (stmt.isReturn()) {
hasSideEffects = NodeUtil.mayHaveSideEffects(stmt.getFirstChild(), compiler);
}
}
// CALL NODE: [ NAME, ARG1, ARG2, ... ]
Node cArg = callNode.getFirstChild().getNext();
// Functions called via 'call' and 'apply' have a this-object as
// the first parameter, but this is not part of the called function's
// parameter list.
if (!callNode.getFirstChild().isName()) {
if (NodeUtil.isFunctionObjectCall(callNode)) {
// TODO(johnlenz): Support replace this with a value.
if (cArg == null || !cArg.isThis()) {
return CanInlineResult.NO;
}
cArg = cArg.getNext();
} else {
// ".apply" call should be filtered before this.
Preconditions.checkState(!NodeUtil.isFunctionObjectApply(callNode));
}
}
// FUNCTION NODE -> LP NODE: [ ARG1, ARG2, ... ]
Node fnParam = NodeUtil.getFunctionParameters(fnNode).getFirstChild();
while (cArg != null || fnParam != null) {
// For each named parameter check if a mutable argument use more than one.
if (fnParam != null) {
if (cArg != null) {
if (hasSideEffects && NodeUtil.canBeSideEffected(cArg)) {
return CanInlineResult.NO;
}
// Check for arguments that are evaluated more than once.
// Note: Unlike block inlining, there it is not possible that a
// parameter reference will be in a loop.
if (NodeUtil.mayEffectMutableState(cArg, compiler)
&& NodeUtil.getNameReferenceCount(
block, fnParam.getString()) > 1) {
return CanInlineResult.NO;
}
}
// Move to the next name.
fnParam = fnParam.getNext();
}
// For every call argument check for side-effects, even if there
// isn't a named parameter to match.
if (cArg != null) {
if (NodeUtil.mayHaveSideEffects(cArg, compiler)) {
return CanInlineResult.NO;
}
cArg = cArg.getNext();
}
}
return CanInlineResult.YES;
}
private CanInlineResult canInlineReferenceDirectly(
Node callNode, Node fnNode) {
if (!isDirectCallNodeReplacementPossible(fnNode)) {
return CanInlineResult.NO;
}
Node block = fnNode.getLastChild();
// CALL NODE: [ NAME, ARG1, ARG2, ... ]
Node cArg = callNode.getFirstChild().getNext();
// Functions called via 'call' and 'apply' have a this-object as
// the first parameter, but this is not part of the called function's
// parameter list.
if (!callNode.getFirstChild().isName()) {
if (NodeUtil.isFunctionObjectCall(callNode)) {
// TODO(johnlenz): Support replace this with a value.
if (cArg == null || !cArg.isThis()) {
return CanInlineResult.NO;
}
cArg = cArg.getNext();
} else {
// ".apply" call should be filtered before this.
Preconditions.checkState(!NodeUtil.isFunctionObjectApply(callNode));
}
}
// FUNCTION NODE -> LP NODE: [ ARG1, ARG2, ... ]
Node fnParam = NodeUtil.getFunctionParameters(fnNode).getFirstChild();
while (cArg != null || fnParam != null) {
// For each named parameter check if a mutable argument use more than one.
if (fnParam != null) {
if (cArg != null) {
// Check for arguments that are evaluated more than once.
// Note: Unlike block inlining, there it is not possible that a
// parameter reference will be in a loop.
if (NodeUtil.mayEffectMutableState(cArg, compiler)
&& NodeUtil.getNameReferenceCount(
block, fnParam.getString()) > 1) {
return CanInlineResult.NO;
}
}
// Move to the next name.
fnParam = fnParam.getNext();
}
// For every call argument check for side-effects, even if there
// isn't a named parameter to match.
if (cArg != null) {
if (NodeUtil.mayHaveSideEffects(cArg, compiler)) {
return CanInlineResult.NO;
}
cArg = cArg.getNext();
}
}
return CanInlineResult.YES;
} | src/com/google/javascript/jscomp/FunctionInjector.java |
Closure-116 | private CanInlineResult canInlineReferenceDirectly(
Node callNode, Node fnNode) {
if (!isDirectCallNodeReplacementPossible(fnNode)) {
return CanInlineResult.NO;
}
Node block = fnNode.getLastChild();
// CALL NODE: [ NAME, ARG1, ARG2, ... ]
Node cArg = callNode.getFirstChild().getNext();
// Functions called via 'call' and 'apply' have a this-object as
// the first parameter, but this is not part of the called function's
// parameter list.
if (!callNode.getFirstChild().isName()) {
if (NodeUtil.isFunctionObjectCall(callNode)) {
// TODO(johnlenz): Support replace this with a value.
if (cArg == null || !cArg.isThis()) {
return CanInlineResult.NO;
}
cArg = cArg.getNext();
} else {
// ".apply" call should be filtered before this.
Preconditions.checkState(!NodeUtil.isFunctionObjectApply(callNode));
}
}
// FUNCTION NODE -> LP NODE: [ ARG1, ARG2, ... ]
Node fnParam = NodeUtil.getFunctionParameters(fnNode).getFirstChild();
while (cArg != null || fnParam != null) {
// For each named parameter check if a mutable argument use more than one.
if (fnParam != null) {
if (cArg != null) {
// Check for arguments that are evaluated more than once.
// Note: Unlike block inlining, there it is not possible that a
// parameter reference will be in a loop.
if (NodeUtil.mayEffectMutableState(cArg, compiler)
&& NodeUtil.getNameReferenceCount(
block, fnParam.getString()) > 1) {
return CanInlineResult.NO;
}
}
// Move to the next name.
fnParam = fnParam.getNext();
}
// For every call argument check for side-effects, even if there
// isn't a named parameter to match.
if (cArg != null) {
if (NodeUtil.mayHaveSideEffects(cArg, compiler)) {
return CanInlineResult.NO;
}
cArg = cArg.getNext();
}
}
return CanInlineResult.YES;
}
private CanInlineResult canInlineReferenceDirectly(
Node callNode, Node fnNode) {
if (!isDirectCallNodeReplacementPossible(fnNode)) {
return CanInlineResult.NO;
}
Node block = fnNode.getLastChild();
boolean hasSideEffects = false; // empty function case
if (block.hasChildren()) {
Preconditions.checkState(block.hasOneChild());
Node stmt = block.getFirstChild();
if (stmt.isReturn()) {
hasSideEffects = NodeUtil.mayHaveSideEffects(
stmt.getFirstChild(), compiler);
}
}
// CALL NODE: [ NAME, ARG1, ARG2, ... ]
Node cArg = callNode.getFirstChild().getNext();
// Functions called via 'call' and 'apply' have a this-object as
// the first parameter, but this is not part of the called function's
// parameter list.
if (!callNode.getFirstChild().isName()) {
if (NodeUtil.isFunctionObjectCall(callNode)) {
// TODO(johnlenz): Support replace this with a value.
if (cArg == null || !cArg.isThis()) {
return CanInlineResult.NO;
}
cArg = cArg.getNext();
} else {
// ".apply" call should be filtered before this.
Preconditions.checkState(!NodeUtil.isFunctionObjectApply(callNode));
}
}
// FUNCTION NODE -> LP NODE: [ ARG1, ARG2, ... ]
Node fnParam = NodeUtil.getFunctionParameters(fnNode).getFirstChild();
while (cArg != null || fnParam != null) {
// For each named parameter check if a mutable argument use more than one.
if (fnParam != null) {
if (cArg != null) {
if (hasSideEffects && NodeUtil.canBeSideEffected(cArg)) {
return CanInlineResult.NO;
}
// Check for arguments that are evaluated more than once.
// Note: Unlike block inlining, there it is not possible that a
// parameter reference will be in a loop.
if (NodeUtil.mayEffectMutableState(cArg, compiler)
&& NodeUtil.getNameReferenceCount(
block, fnParam.getString()) > 1) {
return CanInlineResult.NO;
}
}
// Move to the next name.
fnParam = fnParam.getNext();
}
// For every call argument check for side-effects, even if there
// isn't a named parameter to match.
if (cArg != null) {
if (NodeUtil.mayHaveSideEffects(cArg, compiler)) {
return CanInlineResult.NO;
}
cArg = cArg.getNext();
}
}
return CanInlineResult.YES;
} | src/com/google/javascript/jscomp/FunctionInjector.java |
Closure-117 | String getReadableJSTypeName(Node n, boolean dereference) {
// The best type name is the actual type name.
// If we're analyzing a GETPROP, the property may be inherited by the
// prototype chain. So climb the prototype chain and find out where
// the property was originally defined.
if (n.isGetProp()) {
ObjectType objectType = getJSType(n.getFirstChild()).dereference();
if (objectType != null) {
String propName = n.getLastChild().getString();
if (objectType.getConstructor() != null &&
objectType.getConstructor().isInterface()) {
objectType = FunctionType.getTopDefiningInterface(
objectType, propName);
} else {
// classes
while (objectType != null && !objectType.hasOwnProperty(propName)) {
objectType = objectType.getImplicitPrototype();
}
}
// Don't show complex function names or anonymous types.
// Instead, try to get a human-readable type name.
if (objectType != null &&
(objectType.getConstructor() != null ||
objectType.isFunctionPrototypeType())) {
return objectType.toString() + "." + propName;
}
}
}
JSType type = getJSType(n);
if (dereference) {
ObjectType dereferenced = type.dereference();
if (dereferenced != null) {
type = dereferenced;
}
}
if (type.isFunctionPrototypeType() ||
(type.toObjectType() != null &&
type.toObjectType().getConstructor() != null)) {
return type.toString();
}
String qualifiedName = n.getQualifiedName();
if (qualifiedName != null) {
return qualifiedName;
} else if (type.isFunctionType()) {
// Don't show complex function names.
return "function";
} else {
return type.toString();
}
}
String getReadableJSTypeName(Node n, boolean dereference) {
JSType type = getJSType(n);
if (dereference) {
ObjectType dereferenced = type.dereference();
if (dereferenced != null) {
type = dereferenced;
}
}
// The best type name is the actual type name.
if (type.isFunctionPrototypeType() ||
(type.toObjectType() != null &&
type.toObjectType().getConstructor() != null)) {
return type.toString();
}
// If we're analyzing a GETPROP, the property may be inherited by the
// prototype chain. So climb the prototype chain and find out where
// the property was originally defined.
if (n.isGetProp()) {
ObjectType objectType = getJSType(n.getFirstChild()).dereference();
if (objectType != null) {
String propName = n.getLastChild().getString();
if (objectType.getConstructor() != null &&
objectType.getConstructor().isInterface()) {
objectType = FunctionType.getTopDefiningInterface(
objectType, propName);
} else {
// classes
while (objectType != null && !objectType.hasOwnProperty(propName)) {
objectType = objectType.getImplicitPrototype();
}
}
// Don't show complex function names or anonymous types.
// Instead, try to get a human-readable type name.
if (objectType != null &&
(objectType.getConstructor() != null ||
objectType.isFunctionPrototypeType())) {
return objectType.toString() + "." + propName;
}
}
}
String qualifiedName = n.getQualifiedName();
if (qualifiedName != null) {
return qualifiedName;
} else if (type.isFunctionType()) {
// Don't show complex function names.
return "function";
} else {
return type.toString();
}
} | src/com/google/javascript/jscomp/TypeValidator.java |
Closure-118 | private void handleObjectLit(NodeTraversal t, Node n) {
for (Node child = n.getFirstChild();
child != null;
child = child.getNext()) {
// Maybe STRING, GET, SET
// We should never see a mix of numbers and strings.
String name = child.getString();
T type = typeSystem.getType(getScope(), n, name);
Property prop = getProperty(name);
if (!prop.scheduleRenaming(child,
processProperty(t, prop, type, null))) {
// TODO(user): It doesn't look like the user can do much in this
// case right now.
if (propertiesToErrorFor.containsKey(name)) {
compiler.report(JSError.make(
t.getSourceName(), child, propertiesToErrorFor.get(name),
Warnings.INVALIDATION, name,
(type == null ? "null" : type.toString()), n.toString(), ""));
}
}
}
}
private void handleObjectLit(NodeTraversal t, Node n) {
for (Node child = n.getFirstChild();
child != null;
child = child.getNext()) {
// Maybe STRING, GET, SET
if (child.isQuotedString()) {
continue;
}
// We should never see a mix of numbers and strings.
String name = child.getString();
T type = typeSystem.getType(getScope(), n, name);
Property prop = getProperty(name);
if (!prop.scheduleRenaming(child,
processProperty(t, prop, type, null))) {
// TODO(user): It doesn't look like the user can do much in this
// case right now.
if (propertiesToErrorFor.containsKey(name)) {
compiler.report(JSError.make(
t.getSourceName(), child, propertiesToErrorFor.get(name),
Warnings.INVALIDATION, name,
(type == null ? "null" : type.toString()), n.toString(), ""));
}
}
}
} | src/com/google/javascript/jscomp/DisambiguateProperties.java |
Closure-119 | public void collect(JSModule module, Scope scope, Node n) {
Node parent = n.getParent();
String name;
boolean isSet = false;
Name.Type type = Name.Type.OTHER;
boolean isPropAssign = false;
switch (n.getType()) {
case Token.GETTER_DEF:
case Token.SETTER_DEF:
case Token.STRING_KEY:
// This may be a key in an object literal declaration.
name = null;
if (parent != null && parent.isObjectLit()) {
name = getNameForObjLitKey(n);
}
if (name == null) {
return;
}
isSet = true;
switch (n.getType()) {
case Token.STRING_KEY:
type = getValueType(n.getFirstChild());
break;
case Token.GETTER_DEF:
type = Name.Type.GET;
break;
case Token.SETTER_DEF:
type = Name.Type.SET;
break;
default:
throw new IllegalStateException("unexpected:" + n);
}
break;
case Token.NAME:
// This may be a variable get or set.
if (parent != null) {
switch (parent.getType()) {
case Token.VAR:
isSet = true;
Node rvalue = n.getFirstChild();
type = rvalue == null ? Name.Type.OTHER : getValueType(rvalue);
break;
case Token.ASSIGN:
if (parent.getFirstChild() == n) {
isSet = true;
type = getValueType(n.getNext());
}
break;
case Token.GETPROP:
return;
case Token.FUNCTION:
Node gramps = parent.getParent();
if (gramps == null || NodeUtil.isFunctionExpression(parent)) {
return;
}
isSet = true;
type = Name.Type.FUNCTION;
break;
case Token.INC:
case Token.DEC:
isSet = true;
type = Name.Type.OTHER;
break;
default:
if (NodeUtil.isAssignmentOp(parent) &&
parent.getFirstChild() == n) {
isSet = true;
type = Name.Type.OTHER;
}
}
}
name = n.getString();
break;
case Token.GETPROP:
// This may be a namespaced name get or set.
if (parent != null) {
switch (parent.getType()) {
case Token.ASSIGN:
if (parent.getFirstChild() == n) {
isSet = true;
type = getValueType(n.getNext());
isPropAssign = true;
}
break;
case Token.INC:
case Token.DEC:
isSet = true;
type = Name.Type.OTHER;
break;
case Token.GETPROP:
return;
default:
if (NodeUtil.isAssignmentOp(parent) &&
parent.getFirstChild() == n) {
isSet = true;
type = Name.Type.OTHER;
}
}
}
name = n.getQualifiedName();
if (name == null) {
return;
}
break;
default:
return;
}
// We are only interested in global names.
if (!isGlobalNameReference(name, scope)) {
return;
}
if (isSet) {
if (isGlobalScope(scope)) {
handleSetFromGlobal(module, scope, n, parent, name, isPropAssign, type);
} else {
handleSetFromLocal(module, scope, n, parent, name);
}
} else {
handleGet(module, scope, n, parent, name);
}
}
public void collect(JSModule module, Scope scope, Node n) {
Node parent = n.getParent();
String name;
boolean isSet = false;
Name.Type type = Name.Type.OTHER;
boolean isPropAssign = false;
switch (n.getType()) {
case Token.GETTER_DEF:
case Token.SETTER_DEF:
case Token.STRING_KEY:
// This may be a key in an object literal declaration.
name = null;
if (parent != null && parent.isObjectLit()) {
name = getNameForObjLitKey(n);
}
if (name == null) {
return;
}
isSet = true;
switch (n.getType()) {
case Token.STRING_KEY:
type = getValueType(n.getFirstChild());
break;
case Token.GETTER_DEF:
type = Name.Type.GET;
break;
case Token.SETTER_DEF:
type = Name.Type.SET;
break;
default:
throw new IllegalStateException("unexpected:" + n);
}
break;
case Token.NAME:
// This may be a variable get or set.
if (parent != null) {
switch (parent.getType()) {
case Token.VAR:
isSet = true;
Node rvalue = n.getFirstChild();
type = rvalue == null ? Name.Type.OTHER : getValueType(rvalue);
break;
case Token.ASSIGN:
if (parent.getFirstChild() == n) {
isSet = true;
type = getValueType(n.getNext());
}
break;
case Token.GETPROP:
return;
case Token.FUNCTION:
Node gramps = parent.getParent();
if (gramps == null || NodeUtil.isFunctionExpression(parent)) {
return;
}
isSet = true;
type = Name.Type.FUNCTION;
break;
case Token.CATCH:
case Token.INC:
case Token.DEC:
isSet = true;
type = Name.Type.OTHER;
break;
default:
if (NodeUtil.isAssignmentOp(parent) &&
parent.getFirstChild() == n) {
isSet = true;
type = Name.Type.OTHER;
}
}
}
name = n.getString();
break;
case Token.GETPROP:
// This may be a namespaced name get or set.
if (parent != null) {
switch (parent.getType()) {
case Token.ASSIGN:
if (parent.getFirstChild() == n) {
isSet = true;
type = getValueType(n.getNext());
isPropAssign = true;
}
break;
case Token.INC:
case Token.DEC:
isSet = true;
type = Name.Type.OTHER;
break;
case Token.GETPROP:
return;
default:
if (NodeUtil.isAssignmentOp(parent) &&
parent.getFirstChild() == n) {
isSet = true;
type = Name.Type.OTHER;
}
}
}
name = n.getQualifiedName();
if (name == null) {
return;
}
break;
default:
return;
}
// We are only interested in global names.
if (!isGlobalNameReference(name, scope)) {
return;
}
if (isSet) {
if (isGlobalScope(scope)) {
handleSetFromGlobal(module, scope, n, parent, name, isPropAssign, type);
} else {
handleSetFromLocal(module, scope, n, parent, name);
}
} else {
handleGet(module, scope, n, parent, name);
}
} | src/com/google/javascript/jscomp/GlobalNamespace.java |
Closure-12 | private boolean hasExceptionHandler(Node cfgNode) {
return false;
}
private boolean hasExceptionHandler(Node cfgNode) {
List<DiGraphEdge<Node, Branch>> branchEdges = getCfg().getOutEdges(cfgNode);
for (DiGraphEdge<Node, Branch> edge : branchEdges) {
if (edge.getValue() == Branch.ON_EX) {
return true;
}
}
return false;
} | src/com/google/javascript/jscomp/MaybeReachingVariableUse.java |
Closure-120 | boolean isAssignedOnceInLifetime() {
Reference ref = getOneAndOnlyAssignment();
if (ref == null) {
return false;
}
// Make sure this assignment is not in a loop.
for (BasicBlock block = ref.getBasicBlock();
block != null; block = block.getParent()) {
if (block.isFunction) {
break;
} else if (block.isLoop) {
return false;
}
}
return true;
}
boolean isAssignedOnceInLifetime() {
Reference ref = getOneAndOnlyAssignment();
if (ref == null) {
return false;
}
// Make sure this assignment is not in a loop.
for (BasicBlock block = ref.getBasicBlock();
block != null; block = block.getParent()) {
if (block.isFunction) {
if (ref.getSymbol().getScope() != ref.scope) {
return false;
}
break;
} else if (block.isLoop) {
return false;
}
}
return true;
} | src/com/google/javascript/jscomp/ReferenceCollectingCallback.java |
Closure-121 | private void inlineNonConstants(
Var v, ReferenceCollection referenceInfo,
boolean maybeModifiedArguments) {
int refCount = referenceInfo.references.size();
Reference declaration = referenceInfo.references.get(0);
Reference init = referenceInfo.getInitializingReference();
int firstRefAfterInit = (declaration == init) ? 2 : 3;
if (refCount > 1 &&
isImmutableAndWellDefinedVariable(v, referenceInfo)) {
// if the variable is referenced more than once, we can only
// inline it if it's immutable and never defined before referenced.
Node value;
if (init != null) {
value = init.getAssignedValue();
} else {
// Create a new node for variable that is never initialized.
Node srcLocation = declaration.getNode();
value = NodeUtil.newUndefinedNode(srcLocation);
}
Preconditions.checkNotNull(value);
inlineWellDefinedVariable(v, value, referenceInfo.references);
staleVars.add(v);
} else if (refCount == firstRefAfterInit) {
// The variable likely only read once, try some more
// complex inlining heuristics.
Reference reference = referenceInfo.references.get(
firstRefAfterInit - 1);
if (canInline(declaration, init, reference)) {
inline(v, declaration, init, reference);
staleVars.add(v);
}
} else if (declaration != init && refCount == 2) {
if (isValidDeclaration(declaration) && isValidInitialization(init)) {
// The only reference is the initialization, remove the assignment and
// the variable declaration.
Node value = init.getAssignedValue();
Preconditions.checkNotNull(value);
inlineWellDefinedVariable(v, value, referenceInfo.references);
staleVars.add(v);
}
}
// If this variable was not inlined normally, check if we can
// inline an alias of it. (If the variable was inlined, then the
// reference data is out of sync. We're better off just waiting for
// the next pass.)
if (!maybeModifiedArguments &&
!staleVars.contains(v) &&
referenceInfo.isWellDefined() &&
referenceInfo.isAssignedOnceInLifetime()) {
// Inlining the variable based solely on well-defined and assigned
// once is *NOT* correct. We relax the correctness requirement if
// the variable is declared constant.
List<Reference> refs = referenceInfo.references;
for (int i = 1 /* start from a read */; i < refs.size(); i++) {
Node nameNode = refs.get(i).getNode();
if (aliasCandidates.containsKey(nameNode)) {
AliasCandidate candidate = aliasCandidates.get(nameNode);
if (!staleVars.contains(candidate.alias) &&
!isVarInlineForbidden(candidate.alias)) {
Reference aliasInit;
aliasInit = candidate.refInfo.getInitializingReference();
Node value = aliasInit.getAssignedValue();
Preconditions.checkNotNull(value);
inlineWellDefinedVariable(candidate.alias,
value,
candidate.refInfo.references);
staleVars.add(candidate.alias);
}
}
}
}
}
private void inlineNonConstants(
Var v, ReferenceCollection referenceInfo,
boolean maybeModifiedArguments) {
int refCount = referenceInfo.references.size();
Reference declaration = referenceInfo.references.get(0);
Reference init = referenceInfo.getInitializingReference();
int firstRefAfterInit = (declaration == init) ? 2 : 3;
if (refCount > 1 &&
isImmutableAndWellDefinedVariable(v, referenceInfo)) {
// if the variable is referenced more than once, we can only
// inline it if it's immutable and never defined before referenced.
Node value;
if (init != null) {
value = init.getAssignedValue();
} else {
// Create a new node for variable that is never initialized.
Node srcLocation = declaration.getNode();
value = NodeUtil.newUndefinedNode(srcLocation);
}
Preconditions.checkNotNull(value);
inlineWellDefinedVariable(v, value, referenceInfo.references);
staleVars.add(v);
} else if (refCount == firstRefAfterInit) {
// The variable likely only read once, try some more
// complex inlining heuristics.
Reference reference = referenceInfo.references.get(
firstRefAfterInit - 1);
if (canInline(declaration, init, reference)) {
inline(v, declaration, init, reference);
staleVars.add(v);
}
} else if (declaration != init && refCount == 2) {
if (isValidDeclaration(declaration) && isValidInitialization(init)) {
// The only reference is the initialization, remove the assignment and
// the variable declaration.
Node value = init.getAssignedValue();
Preconditions.checkNotNull(value);
inlineWellDefinedVariable(v, value, referenceInfo.references);
staleVars.add(v);
}
}
// If this variable was not inlined normally, check if we can
// inline an alias of it. (If the variable was inlined, then the
// reference data is out of sync. We're better off just waiting for
// the next pass.)
if (!maybeModifiedArguments &&
!staleVars.contains(v) &&
referenceInfo.isWellDefined() &&
referenceInfo.isAssignedOnceInLifetime() &&
// Inlining the variable based solely on well-defined and assigned
// once is *NOT* correct. We relax the correctness requirement if
// the variable is declared constant.
(isInlineableDeclaredConstant(v, referenceInfo) ||
referenceInfo.isOnlyAssignmentSameScopeAsDeclaration())) {
List<Reference> refs = referenceInfo.references;
for (int i = 1 /* start from a read */; i < refs.size(); i++) {
Node nameNode = refs.get(i).getNode();
if (aliasCandidates.containsKey(nameNode)) {
AliasCandidate candidate = aliasCandidates.get(nameNode);
if (!staleVars.contains(candidate.alias) &&
!isVarInlineForbidden(candidate.alias)) {
Reference aliasInit;
aliasInit = candidate.refInfo.getInitializingReference();
Node value = aliasInit.getAssignedValue();
Preconditions.checkNotNull(value);
inlineWellDefinedVariable(candidate.alias,
value,
candidate.refInfo.references);
staleVars.add(candidate.alias);
}
}
}
}
} | src/com/google/javascript/jscomp/InlineVariables.java |
Closure-122 | private void handleBlockComment(Comment comment) {
if (comment.getValue().indexOf("/* @") != -1 || comment.getValue().indexOf("\n * @") != -1) {
errorReporter.warning(
SUSPICIOUS_COMMENT_WARNING,
sourceName,
comment.getLineno(), "", 0);
}
}
private void handleBlockComment(Comment comment) {
Pattern p = Pattern.compile("(/|(\n[ \t]*))\\*[ \t]*@[a-zA-Z]");
if (p.matcher(comment.getValue()).find()) {
errorReporter.warning(
SUSPICIOUS_COMMENT_WARNING,
sourceName,
comment.getLineno(), "", 0);
}
} | src/com/google/javascript/jscomp/parsing/IRFactory.java |
Closure-123 | void add(Node n, Context context) {
if (!cc.continueProcessing()) {
return;
}
int type = n.getType();
String opstr = NodeUtil.opToStr(type);
int childCount = n.getChildCount();
Node first = n.getFirstChild();
Node last = n.getLastChild();
// Handle all binary operators
if (opstr != null && first != last) {
Preconditions.checkState(
childCount == 2,
"Bad binary operator \"%s\": expected 2 arguments but got %s",
opstr, childCount);
int p = NodeUtil.precedence(type);
// For right-hand-side of operations, only pass context if it's
// the IN_FOR_INIT_CLAUSE one.
Context rhsContext = getContextForNoInOperator(context);
// Handle associativity.
// e.g. if the parse tree is a * (b * c),
// we can simply generate a * b * c.
if (last.getType() == type &&
NodeUtil.isAssociative(type)) {
addExpr(first, p, context);
cc.addOp(opstr, true);
addExpr(last, p, rhsContext);
} else if (NodeUtil.isAssignmentOp(n) && NodeUtil.isAssignmentOp(last)) {
// Assignments are the only right-associative binary operators
addExpr(first, p, context);
cc.addOp(opstr, true);
addExpr(last, p, rhsContext);
} else {
unrollBinaryOperator(n, type, opstr, context, rhsContext, p, p + 1);
}
return;
}
cc.startSourceMapping(n);
switch (type) {
case Token.TRY: {
Preconditions.checkState(first.getNext().isBlock() &&
!first.getNext().hasMoreThanOneChild());
Preconditions.checkState(childCount >= 2 && childCount <= 3);
add("try");
add(first, Context.PRESERVE_BLOCK);
// second child contains the catch block, or nothing if there
// isn't a catch block
Node catchblock = first.getNext().getFirstChild();
if (catchblock != null) {
add(catchblock);
}
if (childCount == 3) {
add("finally");
add(last, Context.PRESERVE_BLOCK);
}
break;
}
case Token.CATCH:
Preconditions.checkState(childCount == 2);
add("catch(");
add(first);
add(")");
add(last, Context.PRESERVE_BLOCK);
break;
case Token.THROW:
Preconditions.checkState(childCount == 1);
add("throw");
add(first);
// Must have a ';' after a throw statement, otherwise safari can't
// parse this.
cc.endStatement(true);
break;
case Token.RETURN:
add("return");
if (childCount == 1) {
add(first);
} else {
Preconditions.checkState(childCount == 0);
}
cc.endStatement();
break;
case Token.VAR:
if (first != null) {
add("var ");
addList(first, false, getContextForNoInOperator(context));
}
break;
case Token.LABEL_NAME:
Preconditions.checkState(!n.getString().isEmpty());
addIdentifier(n.getString());
break;
case Token.NAME:
if (first == null || first.isEmpty()) {
addIdentifier(n.getString());
} else {
Preconditions.checkState(childCount == 1);
addIdentifier(n.getString());
cc.addOp("=", true);
if (first.isComma()) {
addExpr(first, NodeUtil.precedence(Token.ASSIGN), Context.OTHER);
} else {
// Add expression, consider nearby code at lowest level of
// precedence.
addExpr(first, 0, getContextForNoInOperator(context));
}
}
break;
case Token.ARRAYLIT:
add("[");
addArrayList(first);
add("]");
break;
case Token.PARAM_LIST:
add("(");
addList(first);
add(")");
break;
case Token.COMMA:
Preconditions.checkState(childCount == 2);
unrollBinaryOperator(n, Token.COMMA, ",", context,
getContextForNoInOperator(context), 0, 0);
break;
case Token.NUMBER:
Preconditions.checkState(childCount == 0);
cc.addNumber(n.getDouble());
break;
case Token.TYPEOF:
case Token.VOID:
case Token.NOT:
case Token.BITNOT:
case Token.POS: {
// All of these unary operators are right-associative
Preconditions.checkState(childCount == 1);
cc.addOp(NodeUtil.opToStrNoFail(type), false);
addExpr(first, NodeUtil.precedence(type), Context.OTHER);
break;
}
case Token.NEG: {
Preconditions.checkState(childCount == 1);
// It's important to our sanity checker that the code
// we print produces the same AST as the code we parse back.
// NEG is a weird case because Rhino parses "- -2" as "2".
if (n.getFirstChild().isNumber()) {
cc.addNumber(-n.getFirstChild().getDouble());
} else {
cc.addOp(NodeUtil.opToStrNoFail(type), false);
addExpr(first, NodeUtil.precedence(type), Context.OTHER);
}
break;
}
case Token.HOOK: {
Preconditions.checkState(childCount == 3);
int p = NodeUtil.precedence(type);
Context rhsContext = Context.OTHER;
addExpr(first, p + 1, context);
cc.addOp("?", true);
addExpr(first.getNext(), 1, rhsContext);
cc.addOp(":", true);
addExpr(last, 1, rhsContext);
break;
}
case Token.REGEXP:
if (!first.isString() ||
!last.isString()) {
throw new Error("Expected children to be strings");
}
String regexp = regexpEscape(first.getString(), outputCharsetEncoder);
// I only use one .add because whitespace matters
if (childCount == 2) {
add(regexp + last.getString());
} else {
Preconditions.checkState(childCount == 1);
add(regexp);
}
break;
case Token.FUNCTION:
if (n.getClass() != Node.class) {
throw new Error("Unexpected Node subclass.");
}
Preconditions.checkState(childCount == 3);
boolean funcNeedsParens = (context == Context.START_OF_EXPR);
if (funcNeedsParens) {
add("(");
}
add("function");
add(first);
add(first.getNext());
add(last, Context.PRESERVE_BLOCK);
cc.endFunction(context == Context.STATEMENT);
if (funcNeedsParens) {
add(")");
}
break;
case Token.GETTER_DEF:
case Token.SETTER_DEF:
Preconditions.checkState(n.getParent().isObjectLit());
Preconditions.checkState(childCount == 1);
Preconditions.checkState(first.isFunction());
// Get methods are unnamed
Preconditions.checkState(first.getFirstChild().getString().isEmpty());
if (type == Token.GETTER_DEF) {
// Get methods have no parameters.
Preconditions.checkState(!first.getChildAtIndex(1).hasChildren());
add("get ");
} else {
// Set methods have one parameter.
Preconditions.checkState(first.getChildAtIndex(1).hasOneChild());
add("set ");
}
// The name is on the GET or SET node.
String name = n.getString();
Node fn = first;
Node parameters = fn.getChildAtIndex(1);
Node body = fn.getLastChild();
// Add the property name.
if (!n.isQuotedString() &&
TokenStream.isJSIdentifier(name) &&
// do not encode literally any non-literal characters that were
// Unicode escaped.
NodeUtil.isLatin(name)) {
add(name);
} else {
// Determine if the string is a simple number.
double d = getSimpleNumber(name);
if (!Double.isNaN(d)) {
cc.addNumber(d);
} else {
addJsString(n);
}
}
add(parameters);
add(body, Context.PRESERVE_BLOCK);
break;
case Token.SCRIPT:
case Token.BLOCK: {
if (n.getClass() != Node.class) {
throw new Error("Unexpected Node subclass.");
}
boolean preserveBlock = context == Context.PRESERVE_BLOCK;
if (preserveBlock) {
cc.beginBlock();
}
boolean preferLineBreaks =
type == Token.SCRIPT ||
(type == Token.BLOCK &&
!preserveBlock &&
n.getParent() != null &&
n.getParent().isScript());
for (Node c = first; c != null; c = c.getNext()) {
add(c, Context.STATEMENT);
// VAR doesn't include ';' since it gets used in expressions
if (c.isVar()) {
cc.endStatement();
}
if (c.isFunction()) {
cc.maybeLineBreak();
}
// Prefer to break lines in between top-level statements
// because top-level statements are more homogeneous.
if (preferLineBreaks) {
cc.notePreferredLineBreak();
}
}
if (preserveBlock) {
cc.endBlock(cc.breakAfterBlockFor(n, context == Context.STATEMENT));
}
break;
}
case Token.FOR:
if (childCount == 4) {
add("for(");
if (first.isVar()) {
add(first, Context.IN_FOR_INIT_CLAUSE);
} else {
addExpr(first, 0, Context.IN_FOR_INIT_CLAUSE);
}
add(";");
add(first.getNext());
add(";");
add(first.getNext().getNext());
add(")");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
} else {
Preconditions.checkState(childCount == 3);
add("for(");
add(first);
add("in");
add(first.getNext());
add(")");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
}
break;
case Token.DO:
Preconditions.checkState(childCount == 2);
add("do");
addNonEmptyStatement(first, Context.OTHER, false);
add("while(");
add(last);
add(")");
cc.endStatement();
break;
case Token.WHILE:
Preconditions.checkState(childCount == 2);
add("while(");
add(first);
add(")");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
break;
case Token.EMPTY:
Preconditions.checkState(childCount == 0);
break;
case Token.GETPROP: {
Preconditions.checkState(
childCount == 2,
"Bad GETPROP: expected 2 children, but got %s", childCount);
Preconditions.checkState(
last.isString(),
"Bad GETPROP: RHS should be STRING");
boolean needsParens = (first.isNumber());
if (needsParens) {
add("(");
}
addExpr(first, NodeUtil.precedence(type), context);
if (needsParens) {
add(")");
}
if (this.languageMode == LanguageMode.ECMASCRIPT3
&& TokenStream.isKeyword(last.getString())) {
// Check for ECMASCRIPT3 keywords.
add("[");
add(last);
add("]");
} else {
add(".");
addIdentifier(last.getString());
}
break;
}
case Token.GETELEM:
Preconditions.checkState(
childCount == 2,
"Bad GETELEM: expected 2 children but got %s", childCount);
addExpr(first, NodeUtil.precedence(type), context);
add("[");
add(first.getNext());
add("]");
break;
case Token.WITH:
Preconditions.checkState(childCount == 2);
add("with(");
add(first);
add(")");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
break;
case Token.INC:
case Token.DEC: {
Preconditions.checkState(childCount == 1);
String o = type == Token.INC ? "++" : "--";
int postProp = n.getIntProp(Node.INCRDECR_PROP);
// A non-zero post-prop value indicates a post inc/dec, default of zero
// is a pre-inc/dec.
if (postProp != 0) {
addExpr(first, NodeUtil.precedence(type), context);
cc.addOp(o, false);
} else {
cc.addOp(o, false);
add(first);
}
break;
}
case Token.CALL:
// We have two special cases here:
// 1) If the left hand side of the call is a direct reference to eval,
// then it must have a DIRECT_EVAL annotation. If it does not, then
// that means it was originally an indirect call to eval, and that
// indirectness must be preserved.
// 2) If the left hand side of the call is a property reference,
// then the call must not a FREE_CALL annotation. If it does, then
// that means it was originally an call without an explicit this and
// that must be preserved.
if (isIndirectEval(first)
|| n.getBooleanProp(Node.FREE_CALL) && NodeUtil.isGet(first)) {
add("(0,");
addExpr(first, NodeUtil.precedence(Token.COMMA), Context.OTHER);
add(")");
} else {
addExpr(first, NodeUtil.precedence(type), context);
}
add("(");
addList(first.getNext());
add(")");
break;
case Token.IF:
boolean hasElse = childCount == 3;
boolean ambiguousElseClause =
context == Context.BEFORE_DANGLING_ELSE && !hasElse;
if (ambiguousElseClause) {
cc.beginBlock();
}
add("if(");
add(first);
add(")");
if (hasElse) {
addNonEmptyStatement(
first.getNext(), Context.BEFORE_DANGLING_ELSE, false);
add("else");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
} else {
addNonEmptyStatement(first.getNext(), Context.OTHER, false);
Preconditions.checkState(childCount == 2);
}
if (ambiguousElseClause) {
cc.endBlock();
}
break;
case Token.NULL:
Preconditions.checkState(childCount == 0);
cc.addConstant("null");
break;
case Token.THIS:
Preconditions.checkState(childCount == 0);
add("this");
break;
case Token.FALSE:
Preconditions.checkState(childCount == 0);
cc.addConstant("false");
break;
case Token.TRUE:
Preconditions.checkState(childCount == 0);
cc.addConstant("true");
break;
case Token.CONTINUE:
Preconditions.checkState(childCount <= 1);
add("continue");
if (childCount == 1) {
if (!first.isLabelName()) {
throw new Error("Unexpected token type. Should be LABEL_NAME.");
}
add(" ");
add(first);
}
cc.endStatement();
break;
case Token.DEBUGGER:
Preconditions.checkState(childCount == 0);
add("debugger");
cc.endStatement();
break;
case Token.BREAK:
Preconditions.checkState(childCount <= 1);
add("break");
if (childCount == 1) {
if (!first.isLabelName()) {
throw new Error("Unexpected token type. Should be LABEL_NAME.");
}
add(" ");
add(first);
}
cc.endStatement();
break;
case Token.EXPR_RESULT:
Preconditions.checkState(childCount == 1);
add(first, Context.START_OF_EXPR);
cc.endStatement();
break;
case Token.NEW:
add("new ");
int precedence = NodeUtil.precedence(type);
// If the first child contains a CALL, then claim higher precedence
// to force parentheses. Otherwise, when parsed, NEW will bind to the
// first viable parentheses (don't traverse into functions).
if (NodeUtil.containsType(
first, Token.CALL, NodeUtil.MATCH_NOT_FUNCTION)) {
precedence = NodeUtil.precedence(first.getType()) + 1;
}
addExpr(first, precedence, Context.OTHER);
// '()' is optional when no arguments are present
Node next = first.getNext();
if (next != null) {
add("(");
addList(next);
add(")");
}
break;
case Token.STRING_KEY:
Preconditions.checkState(
childCount == 1, "Object lit key must have 1 child");
addJsString(n);
break;
case Token.STRING:
Preconditions.checkState(
childCount == 0, "A string may not have children");
addJsString(n);
break;
case Token.DELPROP:
Preconditions.checkState(childCount == 1);
add("delete ");
add(first);
break;
case Token.OBJECTLIT: {
boolean needsParens = (context == Context.START_OF_EXPR);
if (needsParens) {
add("(");
}
add("{");
for (Node c = first; c != null; c = c.getNext()) {
if (c != first) {
cc.listSeparator();
}
if (c.isGetterDef() || c.isSetterDef()) {
add(c);
} else {
Preconditions.checkState(c.isStringKey());
String key = c.getString();
// Object literal property names don't have to be quoted if they
// are not JavaScript keywords
if (!c.isQuotedString()
&& !(languageMode == LanguageMode.ECMASCRIPT3
&& TokenStream.isKeyword(key))
&& TokenStream.isJSIdentifier(key)
// do not encode literally any non-literal characters that
// were Unicode escaped.
&& NodeUtil.isLatin(key)) {
add(key);
} else {
// Determine if the string is a simple number.
double d = getSimpleNumber(key);
if (!Double.isNaN(d)) {
cc.addNumber(d);
} else {
addExpr(c, 1, Context.OTHER);
}
}
add(":");
addExpr(c.getFirstChild(), 1, Context.OTHER);
}
}
add("}");
if (needsParens) {
add(")");
}
break;
}
case Token.SWITCH:
add("switch(");
add(first);
add(")");
cc.beginBlock();
addAllSiblings(first.getNext());
cc.endBlock(context == Context.STATEMENT);
break;
case Token.CASE:
Preconditions.checkState(childCount == 2);
add("case ");
add(first);
addCaseBody(last);
break;
case Token.DEFAULT_CASE:
Preconditions.checkState(childCount == 1);
add("default");
addCaseBody(first);
break;
case Token.LABEL:
Preconditions.checkState(childCount == 2);
if (!first.isLabelName()) {
throw new Error("Unexpected token type. Should be LABEL_NAME.");
}
add(first);
add(":");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), true);
break;
case Token.CAST:
add("(");
add(first);
add(")");
break;
default:
throw new Error("Unknown type " + type + "\n" + n.toStringTree());
}
cc.endSourceMapping(n);
}
void add(Node n, Context context) {
if (!cc.continueProcessing()) {
return;
}
int type = n.getType();
String opstr = NodeUtil.opToStr(type);
int childCount = n.getChildCount();
Node first = n.getFirstChild();
Node last = n.getLastChild();
// Handle all binary operators
if (opstr != null && first != last) {
Preconditions.checkState(
childCount == 2,
"Bad binary operator \"%s\": expected 2 arguments but got %s",
opstr, childCount);
int p = NodeUtil.precedence(type);
// For right-hand-side of operations, only pass context if it's
// the IN_FOR_INIT_CLAUSE one.
Context rhsContext = getContextForNoInOperator(context);
// Handle associativity.
// e.g. if the parse tree is a * (b * c),
// we can simply generate a * b * c.
if (last.getType() == type &&
NodeUtil.isAssociative(type)) {
addExpr(first, p, context);
cc.addOp(opstr, true);
addExpr(last, p, rhsContext);
} else if (NodeUtil.isAssignmentOp(n) && NodeUtil.isAssignmentOp(last)) {
// Assignments are the only right-associative binary operators
addExpr(first, p, context);
cc.addOp(opstr, true);
addExpr(last, p, rhsContext);
} else {
unrollBinaryOperator(n, type, opstr, context, rhsContext, p, p + 1);
}
return;
}
cc.startSourceMapping(n);
switch (type) {
case Token.TRY: {
Preconditions.checkState(first.getNext().isBlock() &&
!first.getNext().hasMoreThanOneChild());
Preconditions.checkState(childCount >= 2 && childCount <= 3);
add("try");
add(first, Context.PRESERVE_BLOCK);
// second child contains the catch block, or nothing if there
// isn't a catch block
Node catchblock = first.getNext().getFirstChild();
if (catchblock != null) {
add(catchblock);
}
if (childCount == 3) {
add("finally");
add(last, Context.PRESERVE_BLOCK);
}
break;
}
case Token.CATCH:
Preconditions.checkState(childCount == 2);
add("catch(");
add(first);
add(")");
add(last, Context.PRESERVE_BLOCK);
break;
case Token.THROW:
Preconditions.checkState(childCount == 1);
add("throw");
add(first);
// Must have a ';' after a throw statement, otherwise safari can't
// parse this.
cc.endStatement(true);
break;
case Token.RETURN:
add("return");
if (childCount == 1) {
add(first);
} else {
Preconditions.checkState(childCount == 0);
}
cc.endStatement();
break;
case Token.VAR:
if (first != null) {
add("var ");
addList(first, false, getContextForNoInOperator(context));
}
break;
case Token.LABEL_NAME:
Preconditions.checkState(!n.getString().isEmpty());
addIdentifier(n.getString());
break;
case Token.NAME:
if (first == null || first.isEmpty()) {
addIdentifier(n.getString());
} else {
Preconditions.checkState(childCount == 1);
addIdentifier(n.getString());
cc.addOp("=", true);
if (first.isComma()) {
addExpr(first, NodeUtil.precedence(Token.ASSIGN), Context.OTHER);
} else {
// Add expression, consider nearby code at lowest level of
// precedence.
addExpr(first, 0, getContextForNoInOperator(context));
}
}
break;
case Token.ARRAYLIT:
add("[");
addArrayList(first);
add("]");
break;
case Token.PARAM_LIST:
add("(");
addList(first);
add(")");
break;
case Token.COMMA:
Preconditions.checkState(childCount == 2);
unrollBinaryOperator(n, Token.COMMA, ",", context,
getContextForNoInOperator(context), 0, 0);
break;
case Token.NUMBER:
Preconditions.checkState(childCount == 0);
cc.addNumber(n.getDouble());
break;
case Token.TYPEOF:
case Token.VOID:
case Token.NOT:
case Token.BITNOT:
case Token.POS: {
// All of these unary operators are right-associative
Preconditions.checkState(childCount == 1);
cc.addOp(NodeUtil.opToStrNoFail(type), false);
addExpr(first, NodeUtil.precedence(type), Context.OTHER);
break;
}
case Token.NEG: {
Preconditions.checkState(childCount == 1);
// It's important to our sanity checker that the code
// we print produces the same AST as the code we parse back.
// NEG is a weird case because Rhino parses "- -2" as "2".
if (n.getFirstChild().isNumber()) {
cc.addNumber(-n.getFirstChild().getDouble());
} else {
cc.addOp(NodeUtil.opToStrNoFail(type), false);
addExpr(first, NodeUtil.precedence(type), Context.OTHER);
}
break;
}
case Token.HOOK: {
Preconditions.checkState(childCount == 3);
int p = NodeUtil.precedence(type);
Context rhsContext = getContextForNoInOperator(context);
addExpr(first, p + 1, context);
cc.addOp("?", true);
addExpr(first.getNext(), 1, rhsContext);
cc.addOp(":", true);
addExpr(last, 1, rhsContext);
break;
}
case Token.REGEXP:
if (!first.isString() ||
!last.isString()) {
throw new Error("Expected children to be strings");
}
String regexp = regexpEscape(first.getString(), outputCharsetEncoder);
// I only use one .add because whitespace matters
if (childCount == 2) {
add(regexp + last.getString());
} else {
Preconditions.checkState(childCount == 1);
add(regexp);
}
break;
case Token.FUNCTION:
if (n.getClass() != Node.class) {
throw new Error("Unexpected Node subclass.");
}
Preconditions.checkState(childCount == 3);
boolean funcNeedsParens = (context == Context.START_OF_EXPR);
if (funcNeedsParens) {
add("(");
}
add("function");
add(first);
add(first.getNext());
add(last, Context.PRESERVE_BLOCK);
cc.endFunction(context == Context.STATEMENT);
if (funcNeedsParens) {
add(")");
}
break;
case Token.GETTER_DEF:
case Token.SETTER_DEF:
Preconditions.checkState(n.getParent().isObjectLit());
Preconditions.checkState(childCount == 1);
Preconditions.checkState(first.isFunction());
// Get methods are unnamed
Preconditions.checkState(first.getFirstChild().getString().isEmpty());
if (type == Token.GETTER_DEF) {
// Get methods have no parameters.
Preconditions.checkState(!first.getChildAtIndex(1).hasChildren());
add("get ");
} else {
// Set methods have one parameter.
Preconditions.checkState(first.getChildAtIndex(1).hasOneChild());
add("set ");
}
// The name is on the GET or SET node.
String name = n.getString();
Node fn = first;
Node parameters = fn.getChildAtIndex(1);
Node body = fn.getLastChild();
// Add the property name.
if (!n.isQuotedString() &&
TokenStream.isJSIdentifier(name) &&
// do not encode literally any non-literal characters that were
// Unicode escaped.
NodeUtil.isLatin(name)) {
add(name);
} else {
// Determine if the string is a simple number.
double d = getSimpleNumber(name);
if (!Double.isNaN(d)) {
cc.addNumber(d);
} else {
addJsString(n);
}
}
add(parameters);
add(body, Context.PRESERVE_BLOCK);
break;
case Token.SCRIPT:
case Token.BLOCK: {
if (n.getClass() != Node.class) {
throw new Error("Unexpected Node subclass.");
}
boolean preserveBlock = context == Context.PRESERVE_BLOCK;
if (preserveBlock) {
cc.beginBlock();
}
boolean preferLineBreaks =
type == Token.SCRIPT ||
(type == Token.BLOCK &&
!preserveBlock &&
n.getParent() != null &&
n.getParent().isScript());
for (Node c = first; c != null; c = c.getNext()) {
add(c, Context.STATEMENT);
// VAR doesn't include ';' since it gets used in expressions
if (c.isVar()) {
cc.endStatement();
}
if (c.isFunction()) {
cc.maybeLineBreak();
}
// Prefer to break lines in between top-level statements
// because top-level statements are more homogeneous.
if (preferLineBreaks) {
cc.notePreferredLineBreak();
}
}
if (preserveBlock) {
cc.endBlock(cc.breakAfterBlockFor(n, context == Context.STATEMENT));
}
break;
}
case Token.FOR:
if (childCount == 4) {
add("for(");
if (first.isVar()) {
add(first, Context.IN_FOR_INIT_CLAUSE);
} else {
addExpr(first, 0, Context.IN_FOR_INIT_CLAUSE);
}
add(";");
add(first.getNext());
add(";");
add(first.getNext().getNext());
add(")");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
} else {
Preconditions.checkState(childCount == 3);
add("for(");
add(first);
add("in");
add(first.getNext());
add(")");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
}
break;
case Token.DO:
Preconditions.checkState(childCount == 2);
add("do");
addNonEmptyStatement(first, Context.OTHER, false);
add("while(");
add(last);
add(")");
cc.endStatement();
break;
case Token.WHILE:
Preconditions.checkState(childCount == 2);
add("while(");
add(first);
add(")");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
break;
case Token.EMPTY:
Preconditions.checkState(childCount == 0);
break;
case Token.GETPROP: {
Preconditions.checkState(
childCount == 2,
"Bad GETPROP: expected 2 children, but got %s", childCount);
Preconditions.checkState(
last.isString(),
"Bad GETPROP: RHS should be STRING");
boolean needsParens = (first.isNumber());
if (needsParens) {
add("(");
}
addExpr(first, NodeUtil.precedence(type), context);
if (needsParens) {
add(")");
}
if (this.languageMode == LanguageMode.ECMASCRIPT3
&& TokenStream.isKeyword(last.getString())) {
// Check for ECMASCRIPT3 keywords.
add("[");
add(last);
add("]");
} else {
add(".");
addIdentifier(last.getString());
}
break;
}
case Token.GETELEM:
Preconditions.checkState(
childCount == 2,
"Bad GETELEM: expected 2 children but got %s", childCount);
addExpr(first, NodeUtil.precedence(type), context);
add("[");
add(first.getNext());
add("]");
break;
case Token.WITH:
Preconditions.checkState(childCount == 2);
add("with(");
add(first);
add(")");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
break;
case Token.INC:
case Token.DEC: {
Preconditions.checkState(childCount == 1);
String o = type == Token.INC ? "++" : "--";
int postProp = n.getIntProp(Node.INCRDECR_PROP);
// A non-zero post-prop value indicates a post inc/dec, default of zero
// is a pre-inc/dec.
if (postProp != 0) {
addExpr(first, NodeUtil.precedence(type), context);
cc.addOp(o, false);
} else {
cc.addOp(o, false);
add(first);
}
break;
}
case Token.CALL:
// We have two special cases here:
// 1) If the left hand side of the call is a direct reference to eval,
// then it must have a DIRECT_EVAL annotation. If it does not, then
// that means it was originally an indirect call to eval, and that
// indirectness must be preserved.
// 2) If the left hand side of the call is a property reference,
// then the call must not a FREE_CALL annotation. If it does, then
// that means it was originally an call without an explicit this and
// that must be preserved.
if (isIndirectEval(first)
|| n.getBooleanProp(Node.FREE_CALL) && NodeUtil.isGet(first)) {
add("(0,");
addExpr(first, NodeUtil.precedence(Token.COMMA), Context.OTHER);
add(")");
} else {
addExpr(first, NodeUtil.precedence(type), context);
}
add("(");
addList(first.getNext());
add(")");
break;
case Token.IF:
boolean hasElse = childCount == 3;
boolean ambiguousElseClause =
context == Context.BEFORE_DANGLING_ELSE && !hasElse;
if (ambiguousElseClause) {
cc.beginBlock();
}
add("if(");
add(first);
add(")");
if (hasElse) {
addNonEmptyStatement(
first.getNext(), Context.BEFORE_DANGLING_ELSE, false);
add("else");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), false);
} else {
addNonEmptyStatement(first.getNext(), Context.OTHER, false);
Preconditions.checkState(childCount == 2);
}
if (ambiguousElseClause) {
cc.endBlock();
}
break;
case Token.NULL:
Preconditions.checkState(childCount == 0);
cc.addConstant("null");
break;
case Token.THIS:
Preconditions.checkState(childCount == 0);
add("this");
break;
case Token.FALSE:
Preconditions.checkState(childCount == 0);
cc.addConstant("false");
break;
case Token.TRUE:
Preconditions.checkState(childCount == 0);
cc.addConstant("true");
break;
case Token.CONTINUE:
Preconditions.checkState(childCount <= 1);
add("continue");
if (childCount == 1) {
if (!first.isLabelName()) {
throw new Error("Unexpected token type. Should be LABEL_NAME.");
}
add(" ");
add(first);
}
cc.endStatement();
break;
case Token.DEBUGGER:
Preconditions.checkState(childCount == 0);
add("debugger");
cc.endStatement();
break;
case Token.BREAK:
Preconditions.checkState(childCount <= 1);
add("break");
if (childCount == 1) {
if (!first.isLabelName()) {
throw new Error("Unexpected token type. Should be LABEL_NAME.");
}
add(" ");
add(first);
}
cc.endStatement();
break;
case Token.EXPR_RESULT:
Preconditions.checkState(childCount == 1);
add(first, Context.START_OF_EXPR);
cc.endStatement();
break;
case Token.NEW:
add("new ");
int precedence = NodeUtil.precedence(type);
// If the first child contains a CALL, then claim higher precedence
// to force parentheses. Otherwise, when parsed, NEW will bind to the
// first viable parentheses (don't traverse into functions).
if (NodeUtil.containsType(
first, Token.CALL, NodeUtil.MATCH_NOT_FUNCTION)) {
precedence = NodeUtil.precedence(first.getType()) + 1;
}
addExpr(first, precedence, Context.OTHER);
// '()' is optional when no arguments are present
Node next = first.getNext();
if (next != null) {
add("(");
addList(next);
add(")");
}
break;
case Token.STRING_KEY:
Preconditions.checkState(
childCount == 1, "Object lit key must have 1 child");
addJsString(n);
break;
case Token.STRING:
Preconditions.checkState(
childCount == 0, "A string may not have children");
addJsString(n);
break;
case Token.DELPROP:
Preconditions.checkState(childCount == 1);
add("delete ");
add(first);
break;
case Token.OBJECTLIT: {
boolean needsParens = (context == Context.START_OF_EXPR);
if (needsParens) {
add("(");
}
add("{");
for (Node c = first; c != null; c = c.getNext()) {
if (c != first) {
cc.listSeparator();
}
if (c.isGetterDef() || c.isSetterDef()) {
add(c);
} else {
Preconditions.checkState(c.isStringKey());
String key = c.getString();
// Object literal property names don't have to be quoted if they
// are not JavaScript keywords
if (!c.isQuotedString()
&& !(languageMode == LanguageMode.ECMASCRIPT3
&& TokenStream.isKeyword(key))
&& TokenStream.isJSIdentifier(key)
// do not encode literally any non-literal characters that
// were Unicode escaped.
&& NodeUtil.isLatin(key)) {
add(key);
} else {
// Determine if the string is a simple number.
double d = getSimpleNumber(key);
if (!Double.isNaN(d)) {
cc.addNumber(d);
} else {
addExpr(c, 1, Context.OTHER);
}
}
add(":");
addExpr(c.getFirstChild(), 1, Context.OTHER);
}
}
add("}");
if (needsParens) {
add(")");
}
break;
}
case Token.SWITCH:
add("switch(");
add(first);
add(")");
cc.beginBlock();
addAllSiblings(first.getNext());
cc.endBlock(context == Context.STATEMENT);
break;
case Token.CASE:
Preconditions.checkState(childCount == 2);
add("case ");
add(first);
addCaseBody(last);
break;
case Token.DEFAULT_CASE:
Preconditions.checkState(childCount == 1);
add("default");
addCaseBody(first);
break;
case Token.LABEL:
Preconditions.checkState(childCount == 2);
if (!first.isLabelName()) {
throw new Error("Unexpected token type. Should be LABEL_NAME.");
}
add(first);
add(":");
addNonEmptyStatement(
last, getContextForNonEmptyExpression(context), true);
break;
case Token.CAST:
add("(");
add(first);
add(")");
break;
default:
throw new Error("Unknown type " + type + "\n" + n.toStringTree());
}
cc.endSourceMapping(n);
} | src/com/google/javascript/jscomp/CodeGenerator.java |
Closure-124 | private boolean isSafeReplacement(Node node, Node replacement) {
// No checks are needed for simple names.
if (node.isName()) {
return true;
}
Preconditions.checkArgument(node.isGetProp());
node = node.getFirstChild();
if (node.isName()
&& isNameAssignedTo(node.getString(), replacement)) {
return false;
}
return true;
}
private boolean isSafeReplacement(Node node, Node replacement) {
// No checks are needed for simple names.
if (node.isName()) {
return true;
}
Preconditions.checkArgument(node.isGetProp());
while (node.isGetProp()) {
node = node.getFirstChild();
}
if (node.isName()
&& isNameAssignedTo(node.getString(), replacement)) {
return false;
}
return true;
} | src/com/google/javascript/jscomp/ExploitAssigns.java |
Closure-125 | private void visitNew(NodeTraversal t, Node n) {
Node constructor = n.getFirstChild();
JSType type = getJSType(constructor).restrictByNotNullOrUndefined();
if (type.isConstructor() || type.isEmptyType() || type.isUnknownType()) {
FunctionType fnType = type.toMaybeFunctionType();
if (fnType != null) {
visitParameterList(t, n, fnType);
ensureTyped(t, n, fnType.getInstanceType());
} else {
ensureTyped(t, n);
}
} else {
report(t, n, NOT_A_CONSTRUCTOR);
ensureTyped(t, n);
}
}
private void visitNew(NodeTraversal t, Node n) {
Node constructor = n.getFirstChild();
JSType type = getJSType(constructor).restrictByNotNullOrUndefined();
if (type.isConstructor() || type.isEmptyType() || type.isUnknownType()) {
FunctionType fnType = type.toMaybeFunctionType();
if (fnType != null && fnType.hasInstanceType()) {
visitParameterList(t, n, fnType);
ensureTyped(t, n, fnType.getInstanceType());
} else {
ensureTyped(t, n);
}
} else {
report(t, n, NOT_A_CONSTRUCTOR);
ensureTyped(t, n);
}
} | src/com/google/javascript/jscomp/TypeCheck.java |
Closure-126 | void tryMinimizeExits(Node n, int exitType, String labelName) {
// Just an 'exit'.
if (matchingExitNode(n, exitType, labelName)) {
NodeUtil.removeChild(n.getParent(), n);
compiler.reportCodeChange();
return;
}
// Just an 'if'.
if (n.isIf()) {
Node ifBlock = n.getFirstChild().getNext();
tryMinimizeExits(ifBlock, exitType, labelName);
Node elseBlock = ifBlock.getNext();
if (elseBlock != null) {
tryMinimizeExits(elseBlock, exitType, labelName);
}
return;
}
// Just a 'try/catch/finally'.
if (n.isTry()) {
Node tryBlock = n.getFirstChild();
tryMinimizeExits(tryBlock, exitType, labelName);
Node allCatchNodes = NodeUtil.getCatchBlock(n);
if (NodeUtil.hasCatchHandler(allCatchNodes)) {
Preconditions.checkState(allCatchNodes.hasOneChild());
Node catchNode = allCatchNodes.getFirstChild();
Node catchCodeBlock = catchNode.getLastChild();
tryMinimizeExits(catchCodeBlock, exitType, labelName);
}
/* Don't try to minimize the exits of finally blocks, as this
* can cause problems if it changes the completion type of the finally
* block. See ECMA 262 Sections 8.9 & 12.14
*/
if (NodeUtil.hasFinally(n)) {
Node finallyBlock = n.getLastChild();
tryMinimizeExits(finallyBlock, exitType, labelName);
}
}
// Just a 'label'.
if (n.isLabel()) {
Node labelBlock = n.getLastChild();
tryMinimizeExits(labelBlock, exitType, labelName);
}
// TODO(johnlenz): The last case of SWITCH statement?
// The rest assumes a block with at least one child, bail on anything else.
if (!n.isBlock() || n.getLastChild() == null) {
return;
}
// Multiple if-exits can be converted in a single pass.
// Convert "if (blah) break; if (blah2) break; other_stmt;" to
// become "if (blah); else { if (blah2); else { other_stmt; } }"
// which will get converted to "if (!blah && !blah2) { other_stmt; }".
for (Node c : n.children()) {
// An 'if' block to process below.
if (c.isIf()) {
Node ifTree = c;
Node trueBlock, falseBlock;
// First, the true condition block.
trueBlock = ifTree.getFirstChild().getNext();
falseBlock = trueBlock.getNext();
tryMinimizeIfBlockExits(trueBlock, falseBlock,
ifTree, exitType, labelName);
// Now the else block.
// The if blocks may have changed, get them again.
trueBlock = ifTree.getFirstChild().getNext();
falseBlock = trueBlock.getNext();
if (falseBlock != null) {
tryMinimizeIfBlockExits(falseBlock, trueBlock,
ifTree, exitType, labelName);
}
}
if (c == n.getLastChild()) {
break;
}
}
// Now try to minimize the exits of the last child, if it is removed
// look at what has become the last child.
for (Node c = n.getLastChild(); c != null; c = n.getLastChild()) {
tryMinimizeExits(c, exitType, labelName);
// If the node is still the last child, we are done.
if (c == n.getLastChild()) {
break;
}
}
}
void tryMinimizeExits(Node n, int exitType, String labelName) {
// Just an 'exit'.
if (matchingExitNode(n, exitType, labelName)) {
NodeUtil.removeChild(n.getParent(), n);
compiler.reportCodeChange();
return;
}
// Just an 'if'.
if (n.isIf()) {
Node ifBlock = n.getFirstChild().getNext();
tryMinimizeExits(ifBlock, exitType, labelName);
Node elseBlock = ifBlock.getNext();
if (elseBlock != null) {
tryMinimizeExits(elseBlock, exitType, labelName);
}
return;
}
// Just a 'try/catch/finally'.
if (n.isTry()) {
Node tryBlock = n.getFirstChild();
tryMinimizeExits(tryBlock, exitType, labelName);
Node allCatchNodes = NodeUtil.getCatchBlock(n);
if (NodeUtil.hasCatchHandler(allCatchNodes)) {
Preconditions.checkState(allCatchNodes.hasOneChild());
Node catchNode = allCatchNodes.getFirstChild();
Node catchCodeBlock = catchNode.getLastChild();
tryMinimizeExits(catchCodeBlock, exitType, labelName);
}
/* Don't try to minimize the exits of finally blocks, as this
* can cause problems if it changes the completion type of the finally
* block. See ECMA 262 Sections 8.9 & 12.14
*/
}
// Just a 'label'.
if (n.isLabel()) {
Node labelBlock = n.getLastChild();
tryMinimizeExits(labelBlock, exitType, labelName);
}
// TODO(johnlenz): The last case of SWITCH statement?
// The rest assumes a block with at least one child, bail on anything else.
if (!n.isBlock() || n.getLastChild() == null) {
return;
}
// Multiple if-exits can be converted in a single pass.
// Convert "if (blah) break; if (blah2) break; other_stmt;" to
// become "if (blah); else { if (blah2); else { other_stmt; } }"
// which will get converted to "if (!blah && !blah2) { other_stmt; }".
for (Node c : n.children()) {
// An 'if' block to process below.
if (c.isIf()) {
Node ifTree = c;
Node trueBlock, falseBlock;
// First, the true condition block.
trueBlock = ifTree.getFirstChild().getNext();
falseBlock = trueBlock.getNext();
tryMinimizeIfBlockExits(trueBlock, falseBlock,
ifTree, exitType, labelName);
// Now the else block.
// The if blocks may have changed, get them again.
trueBlock = ifTree.getFirstChild().getNext();
falseBlock = trueBlock.getNext();
if (falseBlock != null) {
tryMinimizeIfBlockExits(falseBlock, trueBlock,
ifTree, exitType, labelName);
}
}
if (c == n.getLastChild()) {
break;
}
}
// Now try to minimize the exits of the last child, if it is removed
// look at what has become the last child.
for (Node c = n.getLastChild(); c != null; c = n.getLastChild()) {
tryMinimizeExits(c, exitType, labelName);
// If the node is still the last child, we are done.
if (c == n.getLastChild()) {
break;
}
}
} | src/com/google/javascript/jscomp/MinimizeExitPoints.java |
Closure-128 | static boolean isSimpleNumber(String s) {
int len = s.length();
for (int index = 0; index < len; index++) {
char c = s.charAt(index);
if (c < '0' || c > '9') {
return false;
}
}
return len > 0 && s.charAt(0) != '0';
}
static boolean isSimpleNumber(String s) {
int len = s.length();
if (len == 0) {
return false;
}
for (int index = 0; index < len; index++) {
char c = s.charAt(index);
if (c < '0' || c > '9') {
return false;
}
}
return len == 1 || s.charAt(0) != '0';
} | src/com/google/javascript/jscomp/CodeGenerator.java |
Closure-129 | private void annotateCalls(Node n) {
Preconditions.checkState(n.isCall());
// Keep track of of the "this" context of a call. A call without an
// explicit "this" is a free call.
Node first = n.getFirstChild();
// ignore cast nodes.
if (!NodeUtil.isGet(first)) {
n.putBooleanProp(Node.FREE_CALL, true);
}
// Keep track of the context in which eval is called. It is important
// to distinguish between "(0, eval)()" and "eval()".
if (first.isName() &&
"eval".equals(first.getString())) {
first.putBooleanProp(Node.DIRECT_EVAL, true);
}
}
private void annotateCalls(Node n) {
Preconditions.checkState(n.isCall());
// Keep track of of the "this" context of a call. A call without an
// explicit "this" is a free call.
Node first = n.getFirstChild();
// ignore cast nodes.
while (first.isCast()) {
first = first.getFirstChild();
}
if (!NodeUtil.isGet(first)) {
n.putBooleanProp(Node.FREE_CALL, true);
}
// Keep track of the context in which eval is called. It is important
// to distinguish between "(0, eval)()" and "eval()".
if (first.isName() &&
"eval".equals(first.getString())) {
first.putBooleanProp(Node.DIRECT_EVAL, true);
}
} | src/com/google/javascript/jscomp/PrepareAst.java |
Closure-13 | private void traverse(Node node) {
// The goal here is to avoid retraversing
// the entire AST to catch newly created opportunities.
// So we track whether a "unit of code" has changed,
// and revisit immediately.
if (!shouldVisit(node)) {
return;
}
int visits = 0;
do {
Node c = node.getFirstChild();
while(c != null) {
traverse(c);
Node next = c.getNext();
c = next;
}
visit(node);
visits++;
Preconditions.checkState(visits < 10000, "too many interations");
} while (shouldRetraverse(node));
exitNode(node);
}
private void traverse(Node node) {
// The goal here is to avoid retraversing
// the entire AST to catch newly created opportunities.
// So we track whether a "unit of code" has changed,
// and revisit immediately.
if (!shouldVisit(node)) {
return;
}
int visits = 0;
do {
Node c = node.getFirstChild();
while(c != null) {
Node next = c.getNext();
traverse(c);
c = next;
}
visit(node);
visits++;
Preconditions.checkState(visits < 10000, "too many interations");
} while (shouldRetraverse(node));
exitNode(node);
} | src/com/google/javascript/jscomp/PeepholeOptimizationsPass.java |
Closure-130 | private void inlineAliases(GlobalNamespace namespace) {
// Invariant: All the names in the worklist meet condition (a).
Deque<Name> workList = new ArrayDeque<Name>(namespace.getNameForest());
while (!workList.isEmpty()) {
Name name = workList.pop();
// Don't attempt to inline a getter or setter property as a variable.
if (name.type == Name.Type.GET || name.type == Name.Type.SET) {
continue;
}
if (name.globalSets == 1 && name.localSets == 0 &&
name.aliasingGets > 0) {
// {@code name} meets condition (b). Find all of its local aliases
// and try to inline them.
List<Ref> refs = Lists.newArrayList(name.getRefs());
for (Ref ref : refs) {
if (ref.type == Type.ALIASING_GET && ref.scope.isLocal()) {
// {@code name} meets condition (c). Try to inline it.
if (inlineAliasIfPossible(ref, namespace)) {
name.removeRef(ref);
}
}
}
}
// Check if {@code name} has any aliases left after the
// local-alias-inlining above.
if ((name.type == Name.Type.OBJECTLIT ||
name.type == Name.Type.FUNCTION) &&
name.aliasingGets == 0 && name.props != null) {
// All of {@code name}'s children meet condition (a), so they can be
// added to the worklist.
workList.addAll(name.props);
}
}
}
private void inlineAliases(GlobalNamespace namespace) {
// Invariant: All the names in the worklist meet condition (a).
Deque<Name> workList = new ArrayDeque<Name>(namespace.getNameForest());
while (!workList.isEmpty()) {
Name name = workList.pop();
// Don't attempt to inline a getter or setter property as a variable.
if (name.type == Name.Type.GET || name.type == Name.Type.SET) {
continue;
}
if (!name.inExterns && name.globalSets == 1 && name.localSets == 0 &&
name.aliasingGets > 0) {
// {@code name} meets condition (b). Find all of its local aliases
// and try to inline them.
List<Ref> refs = Lists.newArrayList(name.getRefs());
for (Ref ref : refs) {
if (ref.type == Type.ALIASING_GET && ref.scope.isLocal()) {
// {@code name} meets condition (c). Try to inline it.
if (inlineAliasIfPossible(ref, namespace)) {
name.removeRef(ref);
}
}
}
}
// Check if {@code name} has any aliases left after the
// local-alias-inlining above.
if ((name.type == Name.Type.OBJECTLIT ||
name.type == Name.Type.FUNCTION) &&
name.aliasingGets == 0 && name.props != null) {
// All of {@code name}'s children meet condition (a), so they can be
// added to the worklist.
workList.addAll(name.props);
}
}
} | src/com/google/javascript/jscomp/CollapseProperties.java |
Closure-131 | public static boolean isJSIdentifier(String s) {
int length = s.length();
if (length == 0 ||
!Character.isJavaIdentifierStart(s.charAt(0))) {
return false;
}
for (int i = 1; i < length; i++) {
if (
!Character.isJavaIdentifierPart(s.charAt(i))) {
return false;
}
}
return true;
}
public static boolean isJSIdentifier(String s) {
int length = s.length();
if (length == 0 ||
Character.isIdentifierIgnorable(s.charAt(0)) ||
!Character.isJavaIdentifierStart(s.charAt(0))) {
return false;
}
for (int i = 1; i < length; i++) {
if (Character.isIdentifierIgnorable(s.charAt(i)) ||
!Character.isJavaIdentifierPart(s.charAt(i))) {
return false;
}
}
return true;
} | src/com/google/javascript/rhino/TokenStream.java |
Closure-132 | private Node tryMinimizeIf(Node n) {
Node parent = n.getParent();
Node cond = n.getFirstChild();
/* If the condition is a literal, we'll let other
* optimizations try to remove useless code.
*/
if (NodeUtil.isLiteralValue(cond, true)) {
return n;
}
Node thenBranch = cond.getNext();
Node elseBranch = thenBranch.getNext();
if (elseBranch == null) {
if (isFoldableExpressBlock(thenBranch)) {
Node expr = getBlockExpression(thenBranch);
if (!late && isPropertyAssignmentInExpression(expr)) {
// Keep opportunities for CollapseProperties such as
// a.longIdentifier || a.longIdentifier = ... -> var a = ...;
// until CollapseProperties has been run.
return n;
}
if (cond.isNot()) {
// if(!x)bar(); -> x||bar();
if (isLowerPrecedenceInExpression(cond, OR_PRECEDENCE) &&
isLowerPrecedenceInExpression(expr.getFirstChild(),
OR_PRECEDENCE)) {
// It's not okay to add two sets of parentheses.
return n;
}
Node or = IR.or(
cond.removeFirstChild(),
expr.removeFirstChild()).srcref(n);
Node newExpr = NodeUtil.newExpr(or);
parent.replaceChild(n, newExpr);
reportCodeChange();
return newExpr;
}
// if(x)foo(); -> x&&foo();
if (isLowerPrecedenceInExpression(cond, AND_PRECEDENCE) &&
isLowerPrecedenceInExpression(expr.getFirstChild(),
AND_PRECEDENCE)) {
// One additional set of parentheses is worth the change even if
// there is no immediate code size win. However, two extra pair of
// {}, we would have to think twice. (unless we know for sure the
// we can further optimize its parent.
return n;
}
n.removeChild(cond);
Node and = IR.and(cond, expr.removeFirstChild()).srcref(n);
Node newExpr = NodeUtil.newExpr(and);
parent.replaceChild(n, newExpr);
reportCodeChange();
return newExpr;
} else {
// Try to combine two IF-ELSE
if (NodeUtil.isStatementBlock(thenBranch) &&
thenBranch.hasOneChild()) {
Node innerIf = thenBranch.getFirstChild();
if (innerIf.isIf()) {
Node innerCond = innerIf.getFirstChild();
Node innerThenBranch = innerCond.getNext();
Node innerElseBranch = innerThenBranch.getNext();
if (innerElseBranch == null &&
!(isLowerPrecedenceInExpression(cond, AND_PRECEDENCE) &&
isLowerPrecedenceInExpression(innerCond, AND_PRECEDENCE))) {
n.detachChildren();
n.addChildToBack(
IR.and(
cond,
innerCond.detachFromParent())
.srcref(cond));
n.addChildrenToBack(innerThenBranch.detachFromParent());
reportCodeChange();
// Not worth trying to fold the current IF-ELSE into && because
// the inner IF-ELSE wasn't able to be folded into && anyways.
return n;
}
}
}
}
return n;
}
/* TODO(dcc) This modifies the siblings of n, which is undesirable for a
* peephole optimization. This should probably get moved to another pass.
*/
tryRemoveRepeatedStatements(n);
// if(!x)foo();else bar(); -> if(x)bar();else foo();
// An additional set of curly braces isn't worth it.
if (cond.isNot() && !consumesDanglingElse(elseBranch)) {
n.replaceChild(cond, cond.removeFirstChild());
n.removeChild(thenBranch);
n.addChildToBack(thenBranch);
reportCodeChange();
return n;
}
// if(x)return 1;else return 2; -> return x?1:2;
if (isReturnExpressBlock(thenBranch) && isReturnExpressBlock(elseBranch)) {
Node thenExpr = getBlockReturnExpression(thenBranch);
Node elseExpr = getBlockReturnExpression(elseBranch);
n.removeChild(cond);
thenExpr.detachFromParent();
elseExpr.detachFromParent();
// note - we ignore any cases with "return;", technically this
// can be converted to "return undefined;" or some variant, but
// that does not help code size.
Node returnNode = IR.returnNode(
IR.hook(cond, thenExpr, elseExpr)
.srcref(n));
parent.replaceChild(n, returnNode);
reportCodeChange();
return returnNode;
}
boolean thenBranchIsExpressionBlock = isFoldableExpressBlock(thenBranch);
boolean elseBranchIsExpressionBlock = isFoldableExpressBlock(elseBranch);
if (thenBranchIsExpressionBlock && elseBranchIsExpressionBlock) {
Node thenOp = getBlockExpression(thenBranch).getFirstChild();
Node elseOp = getBlockExpression(elseBranch).getFirstChild();
if (thenOp.getType() == elseOp.getType()) {
// if(x)a=1;else a=2; -> a=x?1:2;
if (NodeUtil.isAssignmentOp(thenOp)) {
Node lhs = thenOp.getFirstChild();
if (areNodesEqualForInlining(lhs, elseOp.getFirstChild()) &&
// if LHS has side effects, don't proceed [since the optimization
// evaluates LHS before cond]
// NOTE - there are some circumstances where we can
// proceed even if there are side effects...
!mayEffectMutableState(lhs)) {
n.removeChild(cond);
Node assignName = thenOp.removeFirstChild();
Node thenExpr = thenOp.removeFirstChild();
Node elseExpr = elseOp.getLastChild();
elseOp.removeChild(elseExpr);
Node hookNode = IR.hook(cond, thenExpr, elseExpr).srcref(n);
Node assign = new Node(thenOp.getType(), assignName, hookNode)
.srcref(thenOp);
Node expr = NodeUtil.newExpr(assign);
parent.replaceChild(n, expr);
reportCodeChange();
return expr;
}
}
}
// if(x)foo();else bar(); -> x?foo():bar()
n.removeChild(cond);
thenOp.detachFromParent();
elseOp.detachFromParent();
Node expr = IR.exprResult(
IR.hook(cond, thenOp, elseOp).srcref(n));
parent.replaceChild(n, expr);
reportCodeChange();
return expr;
}
boolean thenBranchIsVar = isVarBlock(thenBranch);
boolean elseBranchIsVar = isVarBlock(elseBranch);
// if(x)var y=1;else y=2 -> var y=x?1:2
if (thenBranchIsVar && elseBranchIsExpressionBlock &&
getBlockExpression(elseBranch).getFirstChild().isAssign()) {
Node var = getBlockVar(thenBranch);
Node elseAssign = getBlockExpression(elseBranch).getFirstChild();
Node name1 = var.getFirstChild();
Node maybeName2 = elseAssign.getFirstChild();
if (name1.hasChildren()
&& maybeName2.isName()
&& name1.getString().equals(maybeName2.getString())) {
Node thenExpr = name1.removeChildren();
Node elseExpr = elseAssign.getLastChild().detachFromParent();
cond.detachFromParent();
Node hookNode = IR.hook(cond, thenExpr, elseExpr)
.srcref(n);
var.detachFromParent();
name1.addChildrenToBack(hookNode);
parent.replaceChild(n, var);
reportCodeChange();
return var;
}
// if(x)y=1;else var y=2 -> var y=x?1:2
} else if (elseBranchIsVar && thenBranchIsExpressionBlock &&
getBlockExpression(thenBranch).getFirstChild().isAssign()) {
Node var = getBlockVar(elseBranch);
Node thenAssign = getBlockExpression(thenBranch).getFirstChild();
Node maybeName1 = thenAssign.getFirstChild();
Node name2 = var.getFirstChild();
if (name2.hasChildren()
&& maybeName1.isName()
&& maybeName1.getString().equals(name2.getString())) {
Node thenExpr = thenAssign.getLastChild().detachFromParent();
Node elseExpr = name2.removeChildren();
cond.detachFromParent();
Node hookNode = IR.hook(cond, thenExpr, elseExpr)
.srcref(n);
var.detachFromParent();
name2.addChildrenToBack(hookNode);
parent.replaceChild(n, var);
reportCodeChange();
return var;
}
}
return n;
}
private Node tryMinimizeIf(Node n) {
Node parent = n.getParent();
Node cond = n.getFirstChild();
/* If the condition is a literal, we'll let other
* optimizations try to remove useless code.
*/
if (NodeUtil.isLiteralValue(cond, true)) {
return n;
}
Node thenBranch = cond.getNext();
Node elseBranch = thenBranch.getNext();
if (elseBranch == null) {
if (isFoldableExpressBlock(thenBranch)) {
Node expr = getBlockExpression(thenBranch);
if (!late && isPropertyAssignmentInExpression(expr)) {
// Keep opportunities for CollapseProperties such as
// a.longIdentifier || a.longIdentifier = ... -> var a = ...;
// until CollapseProperties has been run.
return n;
}
if (cond.isNot()) {
// if(!x)bar(); -> x||bar();
if (isLowerPrecedenceInExpression(cond, OR_PRECEDENCE) &&
isLowerPrecedenceInExpression(expr.getFirstChild(),
OR_PRECEDENCE)) {
// It's not okay to add two sets of parentheses.
return n;
}
Node or = IR.or(
cond.removeFirstChild(),
expr.removeFirstChild()).srcref(n);
Node newExpr = NodeUtil.newExpr(or);
parent.replaceChild(n, newExpr);
reportCodeChange();
return newExpr;
}
// if(x)foo(); -> x&&foo();
if (isLowerPrecedenceInExpression(cond, AND_PRECEDENCE) &&
isLowerPrecedenceInExpression(expr.getFirstChild(),
AND_PRECEDENCE)) {
// One additional set of parentheses is worth the change even if
// there is no immediate code size win. However, two extra pair of
// {}, we would have to think twice. (unless we know for sure the
// we can further optimize its parent.
return n;
}
n.removeChild(cond);
Node and = IR.and(cond, expr.removeFirstChild()).srcref(n);
Node newExpr = NodeUtil.newExpr(and);
parent.replaceChild(n, newExpr);
reportCodeChange();
return newExpr;
} else {
// Try to combine two IF-ELSE
if (NodeUtil.isStatementBlock(thenBranch) &&
thenBranch.hasOneChild()) {
Node innerIf = thenBranch.getFirstChild();
if (innerIf.isIf()) {
Node innerCond = innerIf.getFirstChild();
Node innerThenBranch = innerCond.getNext();
Node innerElseBranch = innerThenBranch.getNext();
if (innerElseBranch == null &&
!(isLowerPrecedenceInExpression(cond, AND_PRECEDENCE) &&
isLowerPrecedenceInExpression(innerCond, AND_PRECEDENCE))) {
n.detachChildren();
n.addChildToBack(
IR.and(
cond,
innerCond.detachFromParent())
.srcref(cond));
n.addChildrenToBack(innerThenBranch.detachFromParent());
reportCodeChange();
// Not worth trying to fold the current IF-ELSE into && because
// the inner IF-ELSE wasn't able to be folded into && anyways.
return n;
}
}
}
}
return n;
}
/* TODO(dcc) This modifies the siblings of n, which is undesirable for a
* peephole optimization. This should probably get moved to another pass.
*/
tryRemoveRepeatedStatements(n);
// if(!x)foo();else bar(); -> if(x)bar();else foo();
// An additional set of curly braces isn't worth it.
if (cond.isNot() && !consumesDanglingElse(elseBranch)) {
n.replaceChild(cond, cond.removeFirstChild());
n.removeChild(thenBranch);
n.addChildToBack(thenBranch);
reportCodeChange();
return n;
}
// if(x)return 1;else return 2; -> return x?1:2;
if (isReturnExpressBlock(thenBranch) && isReturnExpressBlock(elseBranch)) {
Node thenExpr = getBlockReturnExpression(thenBranch);
Node elseExpr = getBlockReturnExpression(elseBranch);
n.removeChild(cond);
thenExpr.detachFromParent();
elseExpr.detachFromParent();
// note - we ignore any cases with "return;", technically this
// can be converted to "return undefined;" or some variant, but
// that does not help code size.
Node returnNode = IR.returnNode(
IR.hook(cond, thenExpr, elseExpr)
.srcref(n));
parent.replaceChild(n, returnNode);
reportCodeChange();
return returnNode;
}
boolean thenBranchIsExpressionBlock = isFoldableExpressBlock(thenBranch);
boolean elseBranchIsExpressionBlock = isFoldableExpressBlock(elseBranch);
if (thenBranchIsExpressionBlock && elseBranchIsExpressionBlock) {
Node thenOp = getBlockExpression(thenBranch).getFirstChild();
Node elseOp = getBlockExpression(elseBranch).getFirstChild();
if (thenOp.getType() == elseOp.getType()) {
// if(x)a=1;else a=2; -> a=x?1:2;
if (NodeUtil.isAssignmentOp(thenOp)) {
Node lhs = thenOp.getFirstChild();
if (areNodesEqualForInlining(lhs, elseOp.getFirstChild()) &&
// if LHS has side effects, don't proceed [since the optimization
// evaluates LHS before cond]
// NOTE - there are some circumstances where we can
// proceed even if there are side effects...
!mayEffectMutableState(lhs) &&
(!mayHaveSideEffects(cond) ||
(thenOp.isAssign() && thenOp.getFirstChild().isName()))) {
n.removeChild(cond);
Node assignName = thenOp.removeFirstChild();
Node thenExpr = thenOp.removeFirstChild();
Node elseExpr = elseOp.getLastChild();
elseOp.removeChild(elseExpr);
Node hookNode = IR.hook(cond, thenExpr, elseExpr).srcref(n);
Node assign = new Node(thenOp.getType(), assignName, hookNode)
.srcref(thenOp);
Node expr = NodeUtil.newExpr(assign);
parent.replaceChild(n, expr);
reportCodeChange();
return expr;
}
}
}
// if(x)foo();else bar(); -> x?foo():bar()
n.removeChild(cond);
thenOp.detachFromParent();
elseOp.detachFromParent();
Node expr = IR.exprResult(
IR.hook(cond, thenOp, elseOp).srcref(n));
parent.replaceChild(n, expr);
reportCodeChange();
return expr;
}
boolean thenBranchIsVar = isVarBlock(thenBranch);
boolean elseBranchIsVar = isVarBlock(elseBranch);
// if(x)var y=1;else y=2 -> var y=x?1:2
if (thenBranchIsVar && elseBranchIsExpressionBlock &&
getBlockExpression(elseBranch).getFirstChild().isAssign()) {
Node var = getBlockVar(thenBranch);
Node elseAssign = getBlockExpression(elseBranch).getFirstChild();
Node name1 = var.getFirstChild();
Node maybeName2 = elseAssign.getFirstChild();
if (name1.hasChildren()
&& maybeName2.isName()
&& name1.getString().equals(maybeName2.getString())) {
Node thenExpr = name1.removeChildren();
Node elseExpr = elseAssign.getLastChild().detachFromParent();
cond.detachFromParent();
Node hookNode = IR.hook(cond, thenExpr, elseExpr)
.srcref(n);
var.detachFromParent();
name1.addChildrenToBack(hookNode);
parent.replaceChild(n, var);
reportCodeChange();
return var;
}
// if(x)y=1;else var y=2 -> var y=x?1:2
} else if (elseBranchIsVar && thenBranchIsExpressionBlock &&
getBlockExpression(thenBranch).getFirstChild().isAssign()) {
Node var = getBlockVar(elseBranch);
Node thenAssign = getBlockExpression(thenBranch).getFirstChild();
Node maybeName1 = thenAssign.getFirstChild();
Node name2 = var.getFirstChild();
if (name2.hasChildren()
&& maybeName1.isName()
&& maybeName1.getString().equals(name2.getString())) {
Node thenExpr = thenAssign.getLastChild().detachFromParent();
Node elseExpr = name2.removeChildren();
cond.detachFromParent();
Node hookNode = IR.hook(cond, thenExpr, elseExpr)
.srcref(n);
var.detachFromParent();
name2.addChildrenToBack(hookNode);
parent.replaceChild(n, var);
reportCodeChange();
return var;
}
}
return n;
} | src/com/google/javascript/jscomp/PeepholeSubstituteAlternateSyntax.java |
Closure-133 | private String getRemainingJSDocLine() {
String result = stream.getRemainingJSDocLine();
return result;
}
private String getRemainingJSDocLine() {
String result = stream.getRemainingJSDocLine();
unreadToken = NO_UNREAD_TOKEN;
return result;
} | src/com/google/javascript/jscomp/parsing/JsDocInfoParser.java |
Closure-14 | private static Node computeFollowNode(
Node fromNode, Node node, ControlFlowAnalysis cfa) {
/*
* This is the case where:
*
* 1. Parent is null implies that we are transferring control to the end of
* the script.
*
* 2. Parent is a function implies that we are transferring control back to
* the caller of the function.
*
* 3. If the node is a return statement, we should also transfer control
* back to the caller of the function.
*
* 4. If the node is root then we have reached the end of what we have been
* asked to traverse.
*
* In all cases we should transfer control to a "symbolic return" node.
* This will make life easier for DFAs.
*/
Node parent = node.getParent();
if (parent == null || parent.isFunction() ||
(cfa != null && node == cfa.root)) {
return null;
}
// If we are just before a IF/WHILE/DO/FOR:
switch (parent.getType()) {
// The follow() of any of the path from IF would be what follows IF.
case Token.IF:
return computeFollowNode(fromNode, parent, cfa);
case Token.CASE:
case Token.DEFAULT_CASE:
// After the body of a CASE, the control goes to the body of the next
// case, without having to go to the case condition.
if (parent.getNext() != null) {
if (parent.getNext().isCase()) {
return parent.getNext().getFirstChild().getNext();
} else if (parent.getNext().isDefaultCase()) {
return parent.getNext().getFirstChild();
} else {
Preconditions.checkState(false, "Not reachable");
}
} else {
return computeFollowNode(fromNode, parent, cfa);
}
break;
case Token.FOR:
if (NodeUtil.isForIn(parent)) {
return parent;
} else {
return parent.getFirstChild().getNext().getNext();
}
case Token.WHILE:
case Token.DO:
return parent;
case Token.TRY:
// If we are coming out of the TRY block...
if (parent.getFirstChild() == node) {
if (NodeUtil.hasFinally(parent)) { // and have FINALLY block.
return computeFallThrough(parent.getLastChild());
} else { // and have no FINALLY.
return computeFollowNode(fromNode, parent, cfa);
}
// CATCH block.
} else if (NodeUtil.getCatchBlock(parent) == node){
if (NodeUtil.hasFinally(parent)) { // and have FINALLY block.
return computeFallThrough(node.getNext());
} else {
return computeFollowNode(fromNode, parent, cfa);
}
// If we are coming out of the FINALLY block...
} else if (parent.getLastChild() == node){
if (cfa != null) {
for (Node finallyNode : cfa.finallyMap.get(parent)) {
cfa.createEdge(fromNode, Branch.UNCOND, finallyNode);
}
}
return computeFollowNode(fromNode, parent, cfa);
}
}
// Now that we are done with the special cases follow should be its
// immediate sibling, unless its sibling is a function
Node nextSibling = node.getNext();
// Skip function declarations because control doesn't get pass into it.
while (nextSibling != null && nextSibling.isFunction()) {
nextSibling = nextSibling.getNext();
}
if (nextSibling != null) {
return computeFallThrough(nextSibling);
} else {
// If there are no more siblings, control is transferred up the AST.
return computeFollowNode(fromNode, parent, cfa);
}
}
private static Node computeFollowNode(
Node fromNode, Node node, ControlFlowAnalysis cfa) {
/*
* This is the case where:
*
* 1. Parent is null implies that we are transferring control to the end of
* the script.
*
* 2. Parent is a function implies that we are transferring control back to
* the caller of the function.
*
* 3. If the node is a return statement, we should also transfer control
* back to the caller of the function.
*
* 4. If the node is root then we have reached the end of what we have been
* asked to traverse.
*
* In all cases we should transfer control to a "symbolic return" node.
* This will make life easier for DFAs.
*/
Node parent = node.getParent();
if (parent == null || parent.isFunction() ||
(cfa != null && node == cfa.root)) {
return null;
}
// If we are just before a IF/WHILE/DO/FOR:
switch (parent.getType()) {
// The follow() of any of the path from IF would be what follows IF.
case Token.IF:
return computeFollowNode(fromNode, parent, cfa);
case Token.CASE:
case Token.DEFAULT_CASE:
// After the body of a CASE, the control goes to the body of the next
// case, without having to go to the case condition.
if (parent.getNext() != null) {
if (parent.getNext().isCase()) {
return parent.getNext().getFirstChild().getNext();
} else if (parent.getNext().isDefaultCase()) {
return parent.getNext().getFirstChild();
} else {
Preconditions.checkState(false, "Not reachable");
}
} else {
return computeFollowNode(fromNode, parent, cfa);
}
break;
case Token.FOR:
if (NodeUtil.isForIn(parent)) {
return parent;
} else {
return parent.getFirstChild().getNext().getNext();
}
case Token.WHILE:
case Token.DO:
return parent;
case Token.TRY:
// If we are coming out of the TRY block...
if (parent.getFirstChild() == node) {
if (NodeUtil.hasFinally(parent)) { // and have FINALLY block.
return computeFallThrough(parent.getLastChild());
} else { // and have no FINALLY.
return computeFollowNode(fromNode, parent, cfa);
}
// CATCH block.
} else if (NodeUtil.getCatchBlock(parent) == node){
if (NodeUtil.hasFinally(parent)) { // and have FINALLY block.
return computeFallThrough(node.getNext());
} else {
return computeFollowNode(fromNode, parent, cfa);
}
// If we are coming out of the FINALLY block...
} else if (parent.getLastChild() == node){
if (cfa != null) {
for (Node finallyNode : cfa.finallyMap.get(parent)) {
cfa.createEdge(fromNode, Branch.ON_EX, finallyNode);
}
}
return computeFollowNode(fromNode, parent, cfa);
}
}
// Now that we are done with the special cases follow should be its
// immediate sibling, unless its sibling is a function
Node nextSibling = node.getNext();
// Skip function declarations because control doesn't get pass into it.
while (nextSibling != null && nextSibling.isFunction()) {
nextSibling = nextSibling.getNext();
}
if (nextSibling != null) {
return computeFallThrough(nextSibling);
} else {
// If there are no more siblings, control is transferred up the AST.
return computeFollowNode(fromNode, parent, cfa);
}
} | src/com/google/javascript/jscomp/ControlFlowAnalysis.java |
Closure-145 | private boolean isOneExactlyFunctionOrDo(Node n) {
// For labels with block children, we need to ensure that a
// labeled FUNCTION or DO isn't generated when extraneous BLOCKs
// are skipped.
// Either a empty statement or an block with more than one child,
// way it isn't a FUNCTION or DO.
return (n.getType() == Token.FUNCTION || n.getType() == Token.DO);
}
private boolean isOneExactlyFunctionOrDo(Node n) {
if (n.getType() == Token.LABEL) {
Node labeledStatement = n.getLastChild();
if (labeledStatement.getType() != Token.BLOCK) {
return isOneExactlyFunctionOrDo(labeledStatement);
} else {
// For labels with block children, we need to ensure that a
// labeled FUNCTION or DO isn't generated when extraneous BLOCKs
// are skipped.
if (getNonEmptyChildCount(n, 2) == 1) {
return isOneExactlyFunctionOrDo(getFirstNonEmptyChild(n));
} else {
// Either a empty statement or an block with more than one child,
// way it isn't a FUNCTION or DO.
return false;
}
}
} else {
return (n.getType() == Token.FUNCTION || n.getType() == Token.DO);
}
} | src/com/google/javascript/jscomp/CodeGenerator.java |
Closure-146 | public TypePair getTypesUnderInequality(JSType that) {
// unions types
if (that instanceof UnionType) {
TypePair p = that.getTypesUnderInequality(this);
return new TypePair(p.typeB, p.typeA);
}
// other types
switch (this.testForEquality(that)) {
case TRUE:
return new TypePair(null, null);
case FALSE:
case UNKNOWN:
return new TypePair(this, that);
}
// switch case is exhaustive
throw new IllegalStateException();
}
public TypePair getTypesUnderInequality(JSType that) {
// unions types
if (that instanceof UnionType) {
TypePair p = that.getTypesUnderInequality(this);
return new TypePair(p.typeB, p.typeA);
}
// other types
switch (this.testForEquality(that)) {
case TRUE:
JSType noType = getNativeType(JSTypeNative.NO_TYPE);
return new TypePair(noType, noType);
case FALSE:
case UNKNOWN:
return new TypePair(this, that);
}
// switch case is exhaustive
throw new IllegalStateException();
} | src/com/google/javascript/rhino/jstype/JSType.java |
Closure-15 | public boolean apply(Node n) {
// When the node is null it means, we reached the implicit return
// where the function returns (possibly without an return statement)
if (n == null) {
return false;
}
// TODO(user): We only care about calls to functions that
// passes one of the dependent variable to a non-side-effect free
// function.
if (n.isCall() && NodeUtil.functionCallHasSideEffects(n)) {
return true;
}
if (n.isNew() && NodeUtil.constructorCallHasSideEffects(n)) {
return true;
}
for (Node c = n.getFirstChild(); c != null; c = c.getNext()) {
if (!ControlFlowGraph.isEnteringNewCfgNode(c) && apply(c)) {
return true;
}
}
return false;
}
public boolean apply(Node n) {
// When the node is null it means, we reached the implicit return
// where the function returns (possibly without an return statement)
if (n == null) {
return false;
}
// TODO(user): We only care about calls to functions that
// passes one of the dependent variable to a non-side-effect free
// function.
if (n.isCall() && NodeUtil.functionCallHasSideEffects(n)) {
return true;
}
if (n.isNew() && NodeUtil.constructorCallHasSideEffects(n)) {
return true;
}
if (n.isDelProp()) {
return true;
}
for (Node c = n.getFirstChild(); c != null; c = c.getNext()) {
if (!ControlFlowGraph.isEnteringNewCfgNode(c) && apply(c)) {
return true;
}
}
return false;
} | src/com/google/javascript/jscomp/FlowSensitiveInlineVariables.java |
Closure-150 | @Override public void visit(NodeTraversal t, Node n, Node parent) {
if (n == scope.getRootNode()) return;
if (n.getType() == Token.LP && parent == scope.getRootNode()) {
handleFunctionInputs(parent);
return;
}
attachLiteralTypes(n);
switch (n.getType()) {
case Token.FUNCTION:
if (parent.getType() == Token.NAME) {
return;
}
defineDeclaredFunction(n, parent);
break;
case Token.CATCH:
defineCatch(n, parent);
break;
case Token.VAR:
defineVar(n, parent);
break;
}
}
@Override public void visit(NodeTraversal t, Node n, Node parent) {
if (n == scope.getRootNode()) return;
if (n.getType() == Token.LP && parent == scope.getRootNode()) {
handleFunctionInputs(parent);
return;
}
super.visit(t, n, parent);
} | src/com/google/javascript/jscomp/TypedScopeCreator.java |
Closure-152 | JSType resolveInternal(ErrorReporter t, StaticScope<JSType> scope) {
setResolvedTypeInternal(this);
call = (ArrowType) safeResolve(call, t, scope);
prototype = (FunctionPrototypeType) safeResolve(prototype, t, scope);
// Warning about typeOfThis if it doesn't resolve to an ObjectType
// is handled further upstream.
// TODO(nicksantos): Handle this correctly if we have a UnionType.
typeOfThis = (ObjectType) safeResolve(typeOfThis, t, scope);
boolean changed = false;
ImmutableList.Builder<ObjectType> resolvedInterfaces =
ImmutableList.builder();
for (ObjectType iface : implementedInterfaces) {
ObjectType resolvedIface = (ObjectType) iface.resolve(t, scope);
resolvedInterfaces.add(resolvedIface);
changed |= (resolvedIface != iface);
}
if (changed) {
implementedInterfaces = resolvedInterfaces.build();
}
if (subTypes != null) {
for (int i = 0; i < subTypes.size(); i++) {
subTypes.set(i, (FunctionType) subTypes.get(i).resolve(t, scope));
}
}
return super.resolveInternal(t, scope);
}
JSType resolveInternal(ErrorReporter t, StaticScope<JSType> scope) {
setResolvedTypeInternal(this);
call = (ArrowType) safeResolve(call, t, scope);
prototype = (FunctionPrototypeType) safeResolve(prototype, t, scope);
// Warning about typeOfThis if it doesn't resolve to an ObjectType
// is handled further upstream.
// TODO(nicksantos): Handle this correctly if we have a UnionType.
JSType maybeTypeOfThis = safeResolve(typeOfThis, t, scope);
if (maybeTypeOfThis instanceof ObjectType) {
typeOfThis = (ObjectType) maybeTypeOfThis;
}
boolean changed = false;
ImmutableList.Builder<ObjectType> resolvedInterfaces =
ImmutableList.builder();
for (ObjectType iface : implementedInterfaces) {
ObjectType resolvedIface = (ObjectType) iface.resolve(t, scope);
resolvedInterfaces.add(resolvedIface);
changed |= (resolvedIface != iface);
}
if (changed) {
implementedInterfaces = resolvedInterfaces.build();
}
if (subTypes != null) {
for (int i = 0; i < subTypes.size(); i++) {
subTypes.set(i, (FunctionType) subTypes.get(i).resolve(t, scope));
}
}
return super.resolveInternal(t, scope);
} | src/com/google/javascript/rhino/jstype/FunctionType.java |
Closure-159 | private void findCalledFunctions(
Node node, Set<String> changed) {
Preconditions.checkArgument(changed != null);
// For each referenced function, add a new reference
if (node.getType() == Token.CALL) {
Node child = node.getFirstChild();
if (child.getType() == Token.NAME) {
changed.add(child.getString());
}
}
for (Node c = node.getFirstChild(); c != null; c = c.getNext()) {
findCalledFunctions(c, changed);
}
}
private void findCalledFunctions(
Node node, Set<String> changed) {
Preconditions.checkArgument(changed != null);
// For each referenced function, add a new reference
if (node.getType() == Token.NAME) {
if (isCandidateUsage(node)) {
changed.add(node.getString());
}
}
for (Node c = node.getFirstChild(); c != null; c = c.getNext()) {
findCalledFunctions(c, changed);
}
} | src/com/google/javascript/jscomp/InlineFunctions.java |
Closure-160 | public void initOptions(CompilerOptions options) {
this.options = options;
if (errorManager == null) {
if (outStream == null) {
setErrorManager(
new LoggerErrorManager(createMessageFormatter(), logger));
} else {
PrintStreamErrorManager printer =
new PrintStreamErrorManager(createMessageFormatter(), outStream);
printer.setSummaryDetailLevel(options.summaryDetailLevel);
setErrorManager(printer);
}
}
// DiagnosticGroups override the plain checkTypes option.
if (options.enables(DiagnosticGroups.CHECK_TYPES)) {
options.checkTypes = true;
} else if (options.disables(DiagnosticGroups.CHECK_TYPES)) {
options.checkTypes = false;
} else if (!options.checkTypes) {
// If DiagnosticGroups did not override the plain checkTypes
// option, and checkTypes is enabled, then turn off the
// parser type warnings.
options.setWarningLevel(
DiagnosticGroup.forType(
RhinoErrorReporter.TYPE_PARSE_ERROR),
CheckLevel.OFF);
}
if (options.checkGlobalThisLevel.isOn()) {
options.setWarningLevel(
DiagnosticGroups.GLOBAL_THIS,
options.checkGlobalThisLevel);
}
// Initialize the warnings guard.
List<WarningsGuard> guards = Lists.newArrayList();
guards.add(
new SuppressDocWarningsGuard(
getDiagnosticGroups().getRegisteredGroups()));
guards.add(options.getWarningsGuard());
// All passes must run the variable check. This synthesizes
// variables later so that the compiler doesn't crash. It also
// checks the externs file for validity. If you don't want to warn
// about missing variable declarations, we shut that specific
// error off.
if (!options.checkSymbols &&
(warningsGuard == null || !warningsGuard.disables(
DiagnosticGroups.CHECK_VARIABLES))) {
guards.add(new DiagnosticGroupWarningsGuard(
DiagnosticGroups.CHECK_VARIABLES, CheckLevel.OFF));
}
this.warningsGuard = new ComposeWarningsGuard(guards);
}
public void initOptions(CompilerOptions options) {
this.options = options;
if (errorManager == null) {
if (outStream == null) {
setErrorManager(
new LoggerErrorManager(createMessageFormatter(), logger));
} else {
PrintStreamErrorManager printer =
new PrintStreamErrorManager(createMessageFormatter(), outStream);
printer.setSummaryDetailLevel(options.summaryDetailLevel);
setErrorManager(printer);
}
}
// DiagnosticGroups override the plain checkTypes option.
if (options.enables(DiagnosticGroups.CHECK_TYPES)) {
options.checkTypes = true;
} else if (options.disables(DiagnosticGroups.CHECK_TYPES)) {
options.checkTypes = false;
} else if (!options.checkTypes) {
// If DiagnosticGroups did not override the plain checkTypes
// option, and checkTypes is enabled, then turn off the
// parser type warnings.
options.setWarningLevel(
DiagnosticGroup.forType(
RhinoErrorReporter.TYPE_PARSE_ERROR),
CheckLevel.OFF);
}
if (options.checkGlobalThisLevel.isOn()) {
options.setWarningLevel(
DiagnosticGroups.GLOBAL_THIS,
options.checkGlobalThisLevel);
}
// Initialize the warnings guard.
List<WarningsGuard> guards = Lists.newArrayList();
guards.add(
new SuppressDocWarningsGuard(
getDiagnosticGroups().getRegisteredGroups()));
guards.add(options.getWarningsGuard());
ComposeWarningsGuard composedGuards = new ComposeWarningsGuard(guards);
// All passes must run the variable check. This synthesizes
// variables later so that the compiler doesn't crash. It also
// checks the externs file for validity. If you don't want to warn
// about missing variable declarations, we shut that specific
// error off.
if (!options.checkSymbols &&
!composedGuards.enables(DiagnosticGroups.CHECK_VARIABLES)) {
composedGuards.addGuard(new DiagnosticGroupWarningsGuard(
DiagnosticGroups.CHECK_VARIABLES, CheckLevel.OFF));
}
this.warningsGuard = composedGuards;
} | src/com/google/javascript/jscomp/Compiler.java |
Closure-161 | private Node tryFoldArrayAccess(Node n, Node left, Node right) {
Node parent = n.getParent();
// If GETPROP/GETELEM is used as assignment target the array literal is
// acting as a temporary we can't fold it here:
// "[][0] += 1"
if (right.getType() != Token.NUMBER) {
// Sometimes people like to use complex expressions to index into
// arrays, or strings to index into array methods.
return n;
}
double index = right.getDouble();
int intIndex = (int) index;
if (intIndex != index) {
error(INVALID_GETELEM_INDEX_ERROR, right);
return n;
}
if (intIndex < 0) {
error(INDEX_OUT_OF_BOUNDS_ERROR, right);
return n;
}
Node elem = left.getFirstChild();
for (int i = 0; elem != null && i < intIndex; i++) {
elem = elem.getNext();
}
if (elem == null) {
error(INDEX_OUT_OF_BOUNDS_ERROR, right);
return n;
}
if (elem.getType() == Token.EMPTY) {
elem = NodeUtil.newUndefinedNode(elem);
} else {
left.removeChild(elem);
}
// Replace the entire GETELEM with the value
n.getParent().replaceChild(n, elem);
reportCodeChange();
return elem;
}
private Node tryFoldArrayAccess(Node n, Node left, Node right) {
Node parent = n.getParent();
// If GETPROP/GETELEM is used as assignment target the array literal is
// acting as a temporary we can't fold it here:
// "[][0] += 1"
if (isAssignmentTarget(n)) {
return n;
}
if (right.getType() != Token.NUMBER) {
// Sometimes people like to use complex expressions to index into
// arrays, or strings to index into array methods.
return n;
}
double index = right.getDouble();
int intIndex = (int) index;
if (intIndex != index) {
error(INVALID_GETELEM_INDEX_ERROR, right);
return n;
}
if (intIndex < 0) {
error(INDEX_OUT_OF_BOUNDS_ERROR, right);
return n;
}
Node elem = left.getFirstChild();
for (int i = 0; elem != null && i < intIndex; i++) {
elem = elem.getNext();
}
if (elem == null) {
error(INDEX_OUT_OF_BOUNDS_ERROR, right);
return n;
}
if (elem.getType() == Token.EMPTY) {
elem = NodeUtil.newUndefinedNode(elem);
} else {
left.removeChild(elem);
}
// Replace the entire GETELEM with the value
n.getParent().replaceChild(n, elem);
reportCodeChange();
return elem;
} | src/com/google/javascript/jscomp/PeepholeFoldConstants.java |
Closure-164 | public boolean isSubtype(JSType other) {
if (!(other instanceof ArrowType)) {
return false;
}
ArrowType that = (ArrowType) other;
// This is described in Draft 2 of the ES4 spec,
// Section 3.4.7: Subtyping Function Types.
// this.returnType <: that.returnType (covariant)
if (!this.returnType.isSubtype(that.returnType)) {
return false;
}
// that.paramType[i] <: this.paramType[i] (contravariant)
//
// If this.paramType[i] is required,
// then that.paramType[i] is required.
//
// In theory, the "required-ness" should work in the other direction as
// well. In other words, if we have
//
// function f(number, number) {}
// function g(number) {}
//
// Then f *should* not be a subtype of g, and g *should* not be
// a subtype of f. But in practice, we do not implement it this way.
// We want to support the use case where you can pass g where f is
// expected, and pretend that g ignores the second argument.
// That way, you can have a single "no-op" function, and you don't have
// to create a new no-op function for every possible type signature.
//
// So, in this case, g < f, but f !< g
Node thisParam = parameters.getFirstChild();
Node thatParam = that.parameters.getFirstChild();
while (thisParam != null && thatParam != null) {
JSType thisParamType = thisParam.getJSType();
JSType thatParamType = thatParam.getJSType();
if (thisParamType != null) {
if (thatParamType == null ||
!thatParamType.isSubtype(thisParamType)) {
return false;
}
}
boolean thisIsVarArgs = thisParam.isVarArgs();
boolean thatIsVarArgs = thatParam.isVarArgs();
// "that" can't be a supertype, because it's missing a required argument.
// NOTE(nicksantos): In our type system, we use {function(...?)} and
// {function(...NoType)} to to indicate that arity should not be
// checked. Strictly speaking, this is not a correct formulation,
// because now a sub-function can required arguments that are var_args
// in the super-function. So we special-case this.
// don't advance if we have variable arguments
if (!thisIsVarArgs) {
thisParam = thisParam.getNext();
}
if (!thatIsVarArgs) {
thatParam = thatParam.getNext();
}
// both var_args indicates the end
if (thisIsVarArgs && thatIsVarArgs) {
thisParam = null;
thatParam = null;
}
}
// "that" can't be a supertype, because it's missing a required arguement.
return true;
}
public boolean isSubtype(JSType other) {
if (!(other instanceof ArrowType)) {
return false;
}
ArrowType that = (ArrowType) other;
// This is described in Draft 2 of the ES4 spec,
// Section 3.4.7: Subtyping Function Types.
// this.returnType <: that.returnType (covariant)
if (!this.returnType.isSubtype(that.returnType)) {
return false;
}
// that.paramType[i] <: this.paramType[i] (contravariant)
//
// If this.paramType[i] is required,
// then that.paramType[i] is required.
//
// In theory, the "required-ness" should work in the other direction as
// well. In other words, if we have
//
// function f(number, number) {}
// function g(number) {}
//
// Then f *should* not be a subtype of g, and g *should* not be
// a subtype of f. But in practice, we do not implement it this way.
// We want to support the use case where you can pass g where f is
// expected, and pretend that g ignores the second argument.
// That way, you can have a single "no-op" function, and you don't have
// to create a new no-op function for every possible type signature.
//
// So, in this case, g < f, but f !< g
Node thisParam = parameters.getFirstChild();
Node thatParam = that.parameters.getFirstChild();
while (thisParam != null && thatParam != null) {
JSType thisParamType = thisParam.getJSType();
JSType thatParamType = thatParam.getJSType();
if (thisParamType != null) {
if (thatParamType == null ||
!thatParamType.isSubtype(thisParamType)) {
return false;
}
}
boolean thisIsVarArgs = thisParam.isVarArgs();
boolean thatIsVarArgs = thatParam.isVarArgs();
boolean thisIsOptional = thisIsVarArgs || thisParam.isOptionalArg();
boolean thatIsOptional = thatIsVarArgs || thatParam.isOptionalArg();
// "that" can't be a supertype, because it's missing a required argument.
if (!thisIsOptional && thatIsOptional) {
// NOTE(nicksantos): In our type system, we use {function(...?)} and
// {function(...NoType)} to to indicate that arity should not be
// checked. Strictly speaking, this is not a correct formulation,
// because now a sub-function can required arguments that are var_args
// in the super-function. So we special-case this.
boolean isTopFunction =
thatIsVarArgs &&
(thatParamType == null ||
thatParamType.isUnknownType() ||
thatParamType.isNoType());
if (!isTopFunction) {
return false;
}
}
// don't advance if we have variable arguments
if (!thisIsVarArgs) {
thisParam = thisParam.getNext();
}
if (!thatIsVarArgs) {
thatParam = thatParam.getNext();
}
// both var_args indicates the end
if (thisIsVarArgs && thatIsVarArgs) {
thisParam = null;
thatParam = null;
}
}
// "that" can't be a supertype, because it's missing a required arguement.
if (thisParam != null
&& !thisParam.isOptionalArg() && !thisParam.isVarArgs()
&& thatParam == null) {
return false;
}
return true;
} | src/com/google/javascript/rhino/jstype/ArrowType.java |
Closure-166 | public void matchConstraint(JSType constraint) {
// We only want to match constraints on anonymous types.
if (hasReferenceName()) {
return;
}
// Handle the case where the constraint object is a record type.
//
// param constraint {{prop: (number|undefined)}}
// function f(constraint) {}
// f({});
//
// We want to modify the object literal to match the constraint, by
// taking any each property on the record and trying to match
// properties on this object.
if (constraint.isRecordType()) {
matchRecordTypeConstraint(constraint.toObjectType());
}
}
public void matchConstraint(JSType constraint) {
// We only want to match constraints on anonymous types.
if (hasReferenceName()) {
return;
}
// Handle the case where the constraint object is a record type.
//
// param constraint {{prop: (number|undefined)}}
// function f(constraint) {}
// f({});
//
// We want to modify the object literal to match the constraint, by
// taking any each property on the record and trying to match
// properties on this object.
if (constraint.isRecordType()) {
matchRecordTypeConstraint(constraint.toObjectType());
} else if (constraint.isUnionType()) {
for (JSType alt : constraint.toMaybeUnionType().getAlternates()) {
if (alt.isRecordType()) {
matchRecordTypeConstraint(alt.toObjectType());
}
}
}
} | src/com/google/javascript/rhino/jstype/PrototypeObjectType.java |
Closure-168 | @Override public void visit(NodeTraversal t, Node n, Node parent) {
if (t.inGlobalScope()) {
return;
}
if (n.isReturn() && n.getFirstChild() != null) {
data.get(t.getScopeRoot()).recordNonEmptyReturn();
}
if (t.getScopeDepth() <= 2) {
// The first-order function analyzer looks at two types of variables:
//
// 1) Local variables that are assigned in inner scopes ("escaped vars")
//
// 2) Local variables that are assigned more than once.
//
// We treat all global variables as escaped by default, so there's
// no reason to do this extra computation for them.
return;
}
if (n.isName() && NodeUtil.isLValue(n) &&
// Be careful of bleeding functions, which create variables
// in the inner scope, not the scope where the name appears.
!NodeUtil.isBleedingFunctionName(n)) {
String name = n.getString();
Scope scope = t.getScope();
Var var = scope.getVar(name);
if (var != null) {
Scope ownerScope = var.getScope();
if (ownerScope.isLocal()) {
data.get(ownerScope.getRootNode()).recordAssignedName(name);
}
if (scope != ownerScope && ownerScope.isLocal()) {
data.get(ownerScope.getRootNode()).recordEscapedVarName(name);
}
}
} else if (n.isGetProp() && n.isUnscopedQualifiedName() &&
NodeUtil.isLValue(n)) {
String name = NodeUtil.getRootOfQualifiedName(n).getString();
Scope scope = t.getScope();
Var var = scope.getVar(name);
if (var != null) {
Scope ownerScope = var.getScope();
if (scope != ownerScope && ownerScope.isLocal()) {
data.get(ownerScope.getRootNode())
.recordEscapedQualifiedName(n.getQualifiedName());
}
}
}
}
@Override public void visit(NodeTraversal t, Node n, Node parent) {
if (t.inGlobalScope()) {
return;
}
if (n.isReturn() && n.getFirstChild() != null) {
data.get(t.getScopeRoot()).recordNonEmptyReturn();
}
if (t.getScopeDepth() <= 1) {
// The first-order function analyzer looks at two types of variables:
//
// 1) Local variables that are assigned in inner scopes ("escaped vars")
//
// 2) Local variables that are assigned more than once.
//
// We treat all global variables as escaped by default, so there's
// no reason to do this extra computation for them.
return;
}
if (n.isName() && NodeUtil.isLValue(n) &&
// Be careful of bleeding functions, which create variables
// in the inner scope, not the scope where the name appears.
!NodeUtil.isBleedingFunctionName(n)) {
String name = n.getString();
Scope scope = t.getScope();
Var var = scope.getVar(name);
if (var != null) {
Scope ownerScope = var.getScope();
if (ownerScope.isLocal()) {
data.get(ownerScope.getRootNode()).recordAssignedName(name);
}
if (scope != ownerScope && ownerScope.isLocal()) {
data.get(ownerScope.getRootNode()).recordEscapedVarName(name);
}
}
} else if (n.isGetProp() && n.isUnscopedQualifiedName() &&
NodeUtil.isLValue(n)) {
String name = NodeUtil.getRootOfQualifiedName(n).getString();
Scope scope = t.getScope();
Var var = scope.getVar(name);
if (var != null) {
Scope ownerScope = var.getScope();
if (scope != ownerScope && ownerScope.isLocal()) {
data.get(ownerScope.getRootNode())
.recordEscapedQualifiedName(n.getQualifiedName());
}
}
}
} | src/com/google/javascript/jscomp/TypedScopeCreator.java |
Closure-17 | private JSType getDeclaredType(String sourceName, JSDocInfo info,
Node lValue, @Nullable Node rValue) {
if (info != null && info.hasType()) {
return getDeclaredTypeInAnnotation(sourceName, lValue, info);
} else if (rValue != null && rValue.isFunction() &&
shouldUseFunctionLiteralType(
JSType.toMaybeFunctionType(rValue.getJSType()), info, lValue)) {
return rValue.getJSType();
} else if (info != null) {
if (info.hasEnumParameterType()) {
if (rValue != null && rValue.isObjectLit()) {
return rValue.getJSType();
} else {
return createEnumTypeFromNodes(
rValue, lValue.getQualifiedName(), info, lValue);
}
} else if (info.isConstructor() || info.isInterface()) {
return createFunctionTypeFromNodes(
rValue, lValue.getQualifiedName(), info, lValue);
} else {
// Check if this is constant, and if it has a known type.
if (info.isConstant()) {
JSType knownType = null;
if (rValue != null) {
if (rValue.getJSType() != null && !rValue.getJSType().isUnknownType()) {
// If rValue has a type-cast, we use the type in the type-cast.
// If rValue's type was already computed during scope creation,
// then we can safely use that.
return rValue.getJSType();
} else if (rValue.isOr()) {
// Check for a very specific JS idiom:
// var x = x || TYPE;
// This is used by Closure's base namespace for esoteric
// reasons.
Node firstClause = rValue.getFirstChild();
Node secondClause = firstClause.getNext();
boolean namesMatch = firstClause.isName()
&& lValue.isName()
&& firstClause.getString().equals(lValue.getString());
if (namesMatch && secondClause.getJSType() != null
&& !secondClause.getJSType().isUnknownType()) {
return secondClause.getJSType();
}
}
}
}
}
}
return getDeclaredTypeInAnnotation(sourceName, lValue, info);
}
private JSType getDeclaredType(String sourceName, JSDocInfo info,
Node lValue, @Nullable Node rValue) {
if (info != null && info.hasType()) {
return getDeclaredTypeInAnnotation(sourceName, lValue, info);
} else if (rValue != null && rValue.isFunction() &&
shouldUseFunctionLiteralType(
JSType.toMaybeFunctionType(rValue.getJSType()), info, lValue)) {
return rValue.getJSType();
} else if (info != null) {
if (info.hasEnumParameterType()) {
if (rValue != null && rValue.isObjectLit()) {
return rValue.getJSType();
} else {
return createEnumTypeFromNodes(
rValue, lValue.getQualifiedName(), info, lValue);
}
} else if (info.isConstructor() || info.isInterface()) {
return createFunctionTypeFromNodes(
rValue, lValue.getQualifiedName(), info, lValue);
} else {
// Check if this is constant, and if it has a known type.
if (info.isConstant()) {
JSType knownType = null;
if (rValue != null) {
JSDocInfo rValueInfo = rValue.getJSDocInfo();
if (rValueInfo != null && rValueInfo.hasType()) {
// If rValue has a type-cast, we use the type in the type-cast.
return rValueInfo.getType().evaluate(scope, typeRegistry);
} else if (rValue.getJSType() != null
&& !rValue.getJSType().isUnknownType()) {
// If rValue's type was already computed during scope creation,
// then we can safely use that.
return rValue.getJSType();
} else if (rValue.isOr()) {
// Check for a very specific JS idiom:
// var x = x || TYPE;
// This is used by Closure's base namespace for esoteric
// reasons.
Node firstClause = rValue.getFirstChild();
Node secondClause = firstClause.getNext();
boolean namesMatch = firstClause.isName()
&& lValue.isName()
&& firstClause.getString().equals(lValue.getString());
if (namesMatch && secondClause.getJSType() != null
&& !secondClause.getJSType().isUnknownType()) {
return secondClause.getJSType();
}
}
}
}
}
}
return getDeclaredTypeInAnnotation(sourceName, lValue, info);
} | src/com/google/javascript/jscomp/TypedScopeCreator.java |
Closure-172 | private boolean isQualifiedNameInferred(
String qName, Node n, JSDocInfo info,
Node rhsValue, JSType valueType) {
if (valueType == null) {
return true;
}
// Prototypes of constructors and interfaces are always declared.
if (qName != null && qName.endsWith(".prototype")) {
return false;
}
boolean inferred = true;
if (info != null) {
inferred = !(info.hasType()
|| info.hasEnumParameterType()
|| (isConstantSymbol(info, n) && valueType != null
&& !valueType.isUnknownType())
|| FunctionTypeBuilder.isFunctionTypeDeclaration(info));
}
if (inferred && rhsValue != null && rhsValue.isFunction()) {
if (info != null) {
return false;
} else if (!scope.isDeclared(qName, false) &&
n.isUnscopedQualifiedName()) {
// Check if this is in a conditional block.
// Functions assigned in conditional blocks are inferred.
for (Node current = n.getParent();
!(current.isScript() || current.isFunction());
current = current.getParent()) {
if (NodeUtil.isControlStructure(current)) {
return true;
}
}
// Check if this is assigned in an inner scope.
// Functions assigned in inner scopes are inferred.
AstFunctionContents contents =
getFunctionAnalysisResults(scope.getRootNode());
if (contents == null ||
!contents.getEscapedQualifiedNames().contains(qName)) {
return false;
}
}
}
return inferred;
}
private boolean isQualifiedNameInferred(
String qName, Node n, JSDocInfo info,
Node rhsValue, JSType valueType) {
if (valueType == null) {
return true;
}
// Prototypes of constructors and interfaces are always declared.
if (qName != null && qName.endsWith(".prototype")) {
String className = qName.substring(0, qName.lastIndexOf(".prototype"));
Var slot = scope.getSlot(className);
JSType classType = slot == null ? null : slot.getType();
if (classType != null
&& (classType.isConstructor() || classType.isInterface())) {
return false;
}
}
boolean inferred = true;
if (info != null) {
inferred = !(info.hasType()
|| info.hasEnumParameterType()
|| (isConstantSymbol(info, n) && valueType != null
&& !valueType.isUnknownType())
|| FunctionTypeBuilder.isFunctionTypeDeclaration(info));
}
if (inferred && rhsValue != null && rhsValue.isFunction()) {
if (info != null) {
return false;
} else if (!scope.isDeclared(qName, false) &&
n.isUnscopedQualifiedName()) {
// Check if this is in a conditional block.
// Functions assigned in conditional blocks are inferred.
for (Node current = n.getParent();
!(current.isScript() || current.isFunction());
current = current.getParent()) {
if (NodeUtil.isControlStructure(current)) {
return true;
}
}
// Check if this is assigned in an inner scope.
// Functions assigned in inner scopes are inferred.
AstFunctionContents contents =
getFunctionAnalysisResults(scope.getRootNode());
if (contents == null ||
!contents.getEscapedQualifiedNames().contains(qName)) {
return false;
}
}
}
return inferred;
} | src/com/google/javascript/jscomp/TypedScopeCreator.java |
Closure-176 | private void updateScopeForTypeChange(
FlowScope scope, Node left, JSType leftType, JSType resultType) {
Preconditions.checkNotNull(resultType);
switch (left.getType()) {
case Token.NAME:
String varName = left.getString();
Var var = syntacticScope.getVar(varName);
boolean isVarDeclaration = left.hasChildren();
// When looking at VAR initializers for declared VARs, we tend
// to use the declared type over the type it's being
// initialized to in the global scope.
//
// For example,
// /** @param {number} */ var f = goog.abstractMethod;
// it's obvious that the programmer wants you to use
// the declared function signature, not the inferred signature.
//
// Or,
// /** @type {Object.<string>} */ var x = {};
// the one-time anonymous object on the right side
// is as narrow as it can possibly be, but we need to make
// sure we back-infer the <string> element constraint on
// the left hand side, so we use the left hand side.
boolean isVarTypeBetter = !isVarDeclaration || var == null || var.isTypeInferred();
// Makes it easier to check for NPEs.
// TODO(nicksantos): This might be a better check once we have
// back-inference of object/array constraints. It will probably
// introduce more type warnings. It uses the result type iff it's
// strictly narrower than the declared var type.
//
//boolean isVarTypeBetter = isVarDeclaration &&
// (varType.restrictByNotNullOrUndefined().isSubtype(resultType)
// || !resultType.isSubtype(varType));
if (isVarTypeBetter) {
redeclareSimpleVar(scope, left, resultType);
}
left.setJSType(isVarDeclaration || leftType == null ?
resultType : null);
if (var != null && var.isTypeInferred()) {
JSType oldType = var.getType();
var.setType(oldType == null ?
resultType : oldType.getLeastSupertype(resultType));
}
break;
case Token.GETPROP:
String qualifiedName = left.getQualifiedName();
if (qualifiedName != null) {
scope.inferQualifiedSlot(left, qualifiedName,
leftType == null ? unknownType : leftType,
resultType);
}
left.setJSType(resultType);
ensurePropertyDefined(left, resultType);
break;
}
}
private void updateScopeForTypeChange(
FlowScope scope, Node left, JSType leftType, JSType resultType) {
Preconditions.checkNotNull(resultType);
switch (left.getType()) {
case Token.NAME:
String varName = left.getString();
Var var = syntacticScope.getVar(varName);
JSType varType = var == null ? null : var.getType();
boolean isVarDeclaration = left.hasChildren()
&& varType != null && !var.isTypeInferred();
// When looking at VAR initializers for declared VARs, we tend
// to use the declared type over the type it's being
// initialized to in the global scope.
//
// For example,
// /** @param {number} */ var f = goog.abstractMethod;
// it's obvious that the programmer wants you to use
// the declared function signature, not the inferred signature.
//
// Or,
// /** @type {Object.<string>} */ var x = {};
// the one-time anonymous object on the right side
// is as narrow as it can possibly be, but we need to make
// sure we back-infer the <string> element constraint on
// the left hand side, so we use the left hand side.
boolean isVarTypeBetter = isVarDeclaration &&
// Makes it easier to check for NPEs.
!resultType.isNullType() && !resultType.isVoidType();
// TODO(nicksantos): This might be a better check once we have
// back-inference of object/array constraints. It will probably
// introduce more type warnings. It uses the result type iff it's
// strictly narrower than the declared var type.
//
//boolean isVarTypeBetter = isVarDeclaration &&
// (varType.restrictByNotNullOrUndefined().isSubtype(resultType)
// || !resultType.isSubtype(varType));
if (isVarTypeBetter) {
redeclareSimpleVar(scope, left, varType);
} else {
redeclareSimpleVar(scope, left, resultType);
}
left.setJSType(resultType);
if (var != null && var.isTypeInferred()) {
JSType oldType = var.getType();
var.setType(oldType == null ?
resultType : oldType.getLeastSupertype(resultType));
}
break;
case Token.GETPROP:
String qualifiedName = left.getQualifiedName();
if (qualifiedName != null) {
scope.inferQualifiedSlot(left, qualifiedName,
leftType == null ? unknownType : leftType,
resultType);
}
left.setJSType(resultType);
ensurePropertyDefined(left, resultType);
break;
}
} | src/com/google/javascript/jscomp/TypeInference.java |
Closure-18 | Node parseInputs() {
boolean devMode = options.devMode != DevMode.OFF;
// If old roots exist (we are parsing a second time), detach each of the
// individual file parse trees.
if (externsRoot != null) {
externsRoot.detachChildren();
}
if (jsRoot != null) {
jsRoot.detachChildren();
}
// Parse main JS sources.
jsRoot = IR.block();
jsRoot.setIsSyntheticBlock(true);
externsRoot = IR.block();
externsRoot.setIsSyntheticBlock(true);
externAndJsRoot = IR.block(externsRoot, jsRoot);
externAndJsRoot.setIsSyntheticBlock(true);
if (options.tracer.isOn()) {
tracker = new PerformanceTracker(jsRoot, options.tracer);
addChangeHandler(tracker.getCodeChangeHandler());
}
Tracer tracer = newTracer("parseInputs");
try {
// Parse externs sources.
for (CompilerInput input : externs) {
Node n = input.getAstRoot(this);
if (hasErrors()) {
return null;
}
externsRoot.addChildToBack(n);
}
// Modules inferred in ProcessCommonJS pass.
if (options.transformAMDToCJSModules || options.processCommonJSModules) {
processAMDAndCommonJSModules();
}
hoistExterns(externsRoot);
// Check if the sources need to be re-ordered.
boolean staleInputs = false;
if (options.dependencyOptions.needsManagement() && options.closurePass) {
for (CompilerInput input : inputs) {
// Forward-declare all the provided types, so that they
// are not flagged even if they are dropped from the process.
for (String provide : input.getProvides()) {
getTypeRegistry().forwardDeclareType(provide);
}
}
try {
inputs =
(moduleGraph == null ? new JSModuleGraph(modules) : moduleGraph)
.manageDependencies(options.dependencyOptions, inputs);
staleInputs = true;
} catch (CircularDependencyException e) {
report(JSError.make(
JSModule.CIRCULAR_DEPENDENCY_ERROR, e.getMessage()));
// If in IDE mode, we ignore the error and keep going.
if (hasErrors()) {
return null;
}
} catch (MissingProvideException e) {
report(JSError.make(
MISSING_ENTRY_ERROR, e.getMessage()));
// If in IDE mode, we ignore the error and keep going.
if (hasErrors()) {
return null;
}
}
}
hoistNoCompileFiles();
if (staleInputs) {
repartitionInputs();
}
// Build the AST.
for (CompilerInput input : inputs) {
Node n = input.getAstRoot(this);
if (n == null) {
continue;
}
if (devMode) {
runSanityCheck();
if (hasErrors()) {
return null;
}
}
if (options.sourceMapOutputPath != null ||
options.nameReferenceReportPath != null) {
// Annotate the nodes in the tree with information from the
// input file. This information is used to construct the SourceMap.
SourceInformationAnnotator sia =
new SourceInformationAnnotator(
input.getName(), options.devMode != DevMode.OFF);
NodeTraversal.traverse(this, n, sia);
}
jsRoot.addChildToBack(n);
}
if (hasErrors()) {
return null;
}
return externAndJsRoot;
} finally {
stopTracer(tracer, "parseInputs");
}
}
Node parseInputs() {
boolean devMode = options.devMode != DevMode.OFF;
// If old roots exist (we are parsing a second time), detach each of the
// individual file parse trees.
if (externsRoot != null) {
externsRoot.detachChildren();
}
if (jsRoot != null) {
jsRoot.detachChildren();
}
// Parse main JS sources.
jsRoot = IR.block();
jsRoot.setIsSyntheticBlock(true);
externsRoot = IR.block();
externsRoot.setIsSyntheticBlock(true);
externAndJsRoot = IR.block(externsRoot, jsRoot);
externAndJsRoot.setIsSyntheticBlock(true);
if (options.tracer.isOn()) {
tracker = new PerformanceTracker(jsRoot, options.tracer);
addChangeHandler(tracker.getCodeChangeHandler());
}
Tracer tracer = newTracer("parseInputs");
try {
// Parse externs sources.
for (CompilerInput input : externs) {
Node n = input.getAstRoot(this);
if (hasErrors()) {
return null;
}
externsRoot.addChildToBack(n);
}
// Modules inferred in ProcessCommonJS pass.
if (options.transformAMDToCJSModules || options.processCommonJSModules) {
processAMDAndCommonJSModules();
}
hoistExterns(externsRoot);
// Check if the sources need to be re-ordered.
boolean staleInputs = false;
if (options.dependencyOptions.needsManagement()) {
for (CompilerInput input : inputs) {
// Forward-declare all the provided types, so that they
// are not flagged even if they are dropped from the process.
for (String provide : input.getProvides()) {
getTypeRegistry().forwardDeclareType(provide);
}
}
try {
inputs =
(moduleGraph == null ? new JSModuleGraph(modules) : moduleGraph)
.manageDependencies(options.dependencyOptions, inputs);
staleInputs = true;
} catch (CircularDependencyException e) {
report(JSError.make(
JSModule.CIRCULAR_DEPENDENCY_ERROR, e.getMessage()));
// If in IDE mode, we ignore the error and keep going.
if (hasErrors()) {
return null;
}
} catch (MissingProvideException e) {
report(JSError.make(
MISSING_ENTRY_ERROR, e.getMessage()));
// If in IDE mode, we ignore the error and keep going.
if (hasErrors()) {
return null;
}
}
}
hoistNoCompileFiles();
if (staleInputs) {
repartitionInputs();
}
// Build the AST.
for (CompilerInput input : inputs) {
Node n = input.getAstRoot(this);
if (n == null) {
continue;
}
if (devMode) {
runSanityCheck();
if (hasErrors()) {
return null;
}
}
if (options.sourceMapOutputPath != null ||
options.nameReferenceReportPath != null) {
// Annotate the nodes in the tree with information from the
// input file. This information is used to construct the SourceMap.
SourceInformationAnnotator sia =
new SourceInformationAnnotator(
input.getName(), options.devMode != DevMode.OFF);
NodeTraversal.traverse(this, n, sia);
}
jsRoot.addChildToBack(n);
}
if (hasErrors()) {
return null;
}
return externAndJsRoot;
} finally {
stopTracer(tracer, "parseInputs");
}
} | src/com/google/javascript/jscomp/Compiler.java |
Closure-19 | protected void declareNameInScope(FlowScope scope, Node node, JSType type) {
switch (node.getType()) {
case Token.NAME:
scope.inferSlotType(node.getString(), type);
break;
case Token.GETPROP:
String qualifiedName = node.getQualifiedName();
Preconditions.checkNotNull(qualifiedName);
JSType origType = node.getJSType();
origType = origType == null ? getNativeType(UNKNOWN_TYPE) : origType;
scope.inferQualifiedSlot(node, qualifiedName, origType, type);
break;
// "this" references aren't currently modeled in the CFG.
default:
throw new IllegalArgumentException("Node cannot be refined. \n" +
node.toStringTree());
}
}
protected void declareNameInScope(FlowScope scope, Node node, JSType type) {
switch (node.getType()) {
case Token.NAME:
scope.inferSlotType(node.getString(), type);
break;
case Token.GETPROP:
String qualifiedName = node.getQualifiedName();
Preconditions.checkNotNull(qualifiedName);
JSType origType = node.getJSType();
origType = origType == null ? getNativeType(UNKNOWN_TYPE) : origType;
scope.inferQualifiedSlot(node, qualifiedName, origType, type);
break;
case Token.THIS:
// "this" references aren't currently modeled in the CFG.
break;
default:
throw new IllegalArgumentException("Node cannot be refined. \n" +
node.toStringTree());
}
} | src/com/google/javascript/jscomp/type/ChainableReverseAbstractInterpreter.java |
Closure-2 | private void checkInterfaceConflictProperties(NodeTraversal t, Node n,
String functionName, HashMap<String, ObjectType> properties,
HashMap<String, ObjectType> currentProperties,
ObjectType interfaceType) {
ObjectType implicitProto = interfaceType.getImplicitPrototype();
Set<String> currentPropertyNames;
// This can be the case if interfaceType is proxy to a non-existent
// object (which is a bad type annotation, but shouldn't crash).
currentPropertyNames = implicitProto.getOwnPropertyNames();
for (String name : currentPropertyNames) {
ObjectType oType = properties.get(name);
if (oType != null) {
if (!interfaceType.getPropertyType(name).isEquivalentTo(
oType.getPropertyType(name))) {
compiler.report(
t.makeError(n, INCOMPATIBLE_EXTENDED_PROPERTY_TYPE,
functionName, name, oType.toString(),
interfaceType.toString()));
}
}
currentProperties.put(name, interfaceType);
}
for (ObjectType iType : interfaceType.getCtorExtendedInterfaces()) {
checkInterfaceConflictProperties(t, n, functionName, properties,
currentProperties, iType);
}
}
private void checkInterfaceConflictProperties(NodeTraversal t, Node n,
String functionName, HashMap<String, ObjectType> properties,
HashMap<String, ObjectType> currentProperties,
ObjectType interfaceType) {
ObjectType implicitProto = interfaceType.getImplicitPrototype();
Set<String> currentPropertyNames;
if (implicitProto == null) {
// This can be the case if interfaceType is proxy to a non-existent
// object (which is a bad type annotation, but shouldn't crash).
currentPropertyNames = ImmutableSet.of();
} else {
currentPropertyNames = implicitProto.getOwnPropertyNames();
}
for (String name : currentPropertyNames) {
ObjectType oType = properties.get(name);
if (oType != null) {
if (!interfaceType.getPropertyType(name).isEquivalentTo(
oType.getPropertyType(name))) {
compiler.report(
t.makeError(n, INCOMPATIBLE_EXTENDED_PROPERTY_TYPE,
functionName, name, oType.toString(),
interfaceType.toString()));
}
}
currentProperties.put(name, interfaceType);
}
for (ObjectType iType : interfaceType.getCtorExtendedInterfaces()) {
checkInterfaceConflictProperties(t, n, functionName, properties,
currentProperties, iType);
}
} | src/com/google/javascript/jscomp/TypeCheck.java |
Closure-20 | private Node tryFoldSimpleFunctionCall(Node n) {
Preconditions.checkState(n.isCall());
Node callTarget = n.getFirstChild();
if (callTarget != null && callTarget.isName() &&
callTarget.getString().equals("String")) {
// Fold String(a) to '' + (a) on immutable literals,
// which allows further optimizations
//
// We can't do this in the general case, because String(a) has
// slightly different semantics than '' + (a). See
// http://code.google.com/p/closure-compiler/issues/detail?id=759
Node value = callTarget.getNext();
if (value != null) {
Node addition = IR.add(
IR.string("").srcref(callTarget),
value.detachFromParent());
n.getParent().replaceChild(n, addition);
reportCodeChange();
return addition;
}
}
return n;
}
private Node tryFoldSimpleFunctionCall(Node n) {
Preconditions.checkState(n.isCall());
Node callTarget = n.getFirstChild();
if (callTarget != null && callTarget.isName() &&
callTarget.getString().equals("String")) {
// Fold String(a) to '' + (a) on immutable literals,
// which allows further optimizations
//
// We can't do this in the general case, because String(a) has
// slightly different semantics than '' + (a). See
// http://code.google.com/p/closure-compiler/issues/detail?id=759
Node value = callTarget.getNext();
if (value != null && value.getNext() == null &&
NodeUtil.isImmutableValue(value)) {
Node addition = IR.add(
IR.string("").srcref(callTarget),
value.detachFromParent());
n.getParent().replaceChild(n, addition);
reportCodeChange();
return addition;
}
}
return n;
} | src/com/google/javascript/jscomp/PeepholeSubstituteAlternateSyntax.java |
Closure-21 | public void visit(NodeTraversal t, Node n, Node parent) {
// VOID nodes appear when there are extra semicolons at the BLOCK level.
// I've been unable to think of any cases where this indicates a bug,
// and apparently some people like keeping these semicolons around,
// so we'll allow it.
if (n.isEmpty() ||
n.isComma()) {
return;
}
if (parent == null) {
return;
}
// Do not try to remove a block or an expr result. We already handle
// these cases when we visit the child, and the peephole passes will
// fix up the tree in more clever ways when these are removed.
if (n.isExprResult()) {
return;
}
// This no-op statement was there so that JSDoc information could
// be attached to the name. This check should not complain about it.
if (n.isQualifiedName() && n.getJSDocInfo() != null) {
return;
}
boolean isResultUsed = NodeUtil.isExpressionResultUsed(n);
boolean isSimpleOp = NodeUtil.isSimpleOperatorType(n.getType());
if (parent.getType() == Token.COMMA) {
if (isResultUsed) {
return;
}
if (n == parent.getLastChild()) {
for (Node an : parent.getAncestors()) {
int ancestorType = an.getType();
if (ancestorType == Token.COMMA) continue;
if (ancestorType != Token.EXPR_RESULT && ancestorType != Token.BLOCK) return;
else break;
}
}
} else if (parent.getType() != Token.EXPR_RESULT && parent.getType() != Token.BLOCK) {
if (! (parent.getType() == Token.FOR && parent.getChildCount() == 4 && (n == parent.getFirstChild() || n == parent.getFirstChild().getNext().getNext()))) {
return;
}
}
if (
(isSimpleOp || !NodeUtil.mayHaveSideEffects(n, t.getCompiler()))) {
String msg = "This code lacks side-effects. Is there a bug?";
if (n.isString()) {
msg = "Is there a missing '+' on the previous line?";
} else if (isSimpleOp) {
msg = "The result of the '" + Token.name(n.getType()).toLowerCase() +
"' operator is not being used.";
}
t.getCompiler().report(
t.makeError(n, level, USELESS_CODE_ERROR, msg));
// TODO(johnlenz): determine if it is necessary to
// try to protect side-effect free statements as well.
if (!NodeUtil.isStatement(n)) {
problemNodes.add(n);
}
}
}
public void visit(NodeTraversal t, Node n, Node parent) {
// VOID nodes appear when there are extra semicolons at the BLOCK level.
// I've been unable to think of any cases where this indicates a bug,
// and apparently some people like keeping these semicolons around,
// so we'll allow it.
if (n.isEmpty() ||
n.isComma()) {
return;
}
if (parent == null) {
return;
}
// Do not try to remove a block or an expr result. We already handle
// these cases when we visit the child, and the peephole passes will
// fix up the tree in more clever ways when these are removed.
if (n.isExprResult() || n.isBlock()) {
return;
}
// This no-op statement was there so that JSDoc information could
// be attached to the name. This check should not complain about it.
if (n.isQualifiedName() && n.getJSDocInfo() != null) {
return;
}
boolean isResultUsed = NodeUtil.isExpressionResultUsed(n);
boolean isSimpleOp = NodeUtil.isSimpleOperatorType(n.getType());
if (!isResultUsed &&
(isSimpleOp || !NodeUtil.mayHaveSideEffects(n, t.getCompiler()))) {
String msg = "This code lacks side-effects. Is there a bug?";
if (n.isString()) {
msg = "Is there a missing '+' on the previous line?";
} else if (isSimpleOp) {
msg = "The result of the '" + Token.name(n.getType()).toLowerCase() +
"' operator is not being used.";
}
t.getCompiler().report(
t.makeError(n, level, USELESS_CODE_ERROR, msg));
// TODO(johnlenz): determine if it is necessary to
// try to protect side-effect free statements as well.
if (!NodeUtil.isStatement(n)) {
problemNodes.add(n);
}
}
} | src/com/google/javascript/jscomp/CheckSideEffects.java |
Closure-22 | public void visit(NodeTraversal t, Node n, Node parent) {
// VOID nodes appear when there are extra semicolons at the BLOCK level.
// I've been unable to think of any cases where this indicates a bug,
// and apparently some people like keeping these semicolons around,
// so we'll allow it.
if (n.isEmpty() ||
n.isComma()) {
return;
}
if (parent == null) {
return;
}
// Do not try to remove a block or an expr result. We already handle
// these cases when we visit the child, and the peephole passes will
// fix up the tree in more clever ways when these are removed.
if (parent.getType() == Token.COMMA) {
Node gramps = parent.getParent();
if (gramps.isCall() && parent == gramps.getFirstChild()) {
if (n == parent.getFirstChild() && parent.getChildCount() == 2 && n.getNext().isName() && "eval".equals(n.getNext().getString())) {
return;
}
}
// This no-op statement was there so that JSDoc information could
// be attached to the name. This check should not complain about it.
if (n == parent.getLastChild()) {
for (Node an : parent.getAncestors()) {
int ancestorType = an.getType();
if (ancestorType == Token.COMMA)
continue;
if (ancestorType != Token.EXPR_RESULT && ancestorType != Token.BLOCK)
return;
else
break;
}
}
} else if (parent.getType() != Token.EXPR_RESULT && parent.getType() != Token.BLOCK) {
if (parent.getType() == Token.FOR && parent.getChildCount() == 4 && (n == parent.getFirstChild() ||
n == parent.getFirstChild().getNext().getNext())) {
} else {
return;
}
}
boolean isResultUsed = NodeUtil.isExpressionResultUsed(n);
boolean isSimpleOp = NodeUtil.isSimpleOperatorType(n.getType());
if (!isResultUsed &&
(isSimpleOp || !NodeUtil.mayHaveSideEffects(n, t.getCompiler()))) {
if (n.isQualifiedName() && n.getJSDocInfo() != null) {
return;
} else if (n.isExprResult()) {
return;
}
String msg = "This code lacks side-effects. Is there a bug?";
if (n.isString()) {
msg = "Is there a missing '+' on the previous line?";
} else if (isSimpleOp) {
msg = "The result of the '" + Token.name(n.getType()).toLowerCase() +
"' operator is not being used.";
}
t.getCompiler().report(
t.makeError(n, level, USELESS_CODE_ERROR, msg));
// TODO(johnlenz): determine if it is necessary to
// try to protect side-effect free statements as well.
if (!NodeUtil.isStatement(n)) {
problemNodes.add(n);
}
}
}
public void visit(NodeTraversal t, Node n, Node parent) {
// VOID nodes appear when there are extra semicolons at the BLOCK level.
// I've been unable to think of any cases where this indicates a bug,
// and apparently some people like keeping these semicolons around,
// so we'll allow it.
if (n.isEmpty() ||
n.isComma()) {
return;
}
if (parent == null) {
return;
}
// Do not try to remove a block or an expr result. We already handle
// these cases when we visit the child, and the peephole passes will
// fix up the tree in more clever ways when these are removed.
if (n.isExprResult() || n.isBlock()) {
return;
}
// This no-op statement was there so that JSDoc information could
// be attached to the name. This check should not complain about it.
if (n.isQualifiedName() && n.getJSDocInfo() != null) {
return;
}
boolean isResultUsed = NodeUtil.isExpressionResultUsed(n);
boolean isSimpleOp = NodeUtil.isSimpleOperatorType(n.getType());
if (!isResultUsed &&
(isSimpleOp || !NodeUtil.mayHaveSideEffects(n, t.getCompiler()))) {
String msg = "This code lacks side-effects. Is there a bug?";
if (n.isString()) {
msg = "Is there a missing '+' on the previous line?";
} else if (isSimpleOp) {
msg = "The result of the '" + Token.name(n.getType()).toLowerCase() +
"' operator is not being used.";
}
t.getCompiler().report(
t.makeError(n, level, USELESS_CODE_ERROR, msg));
// TODO(johnlenz): determine if it is necessary to
// try to protect side-effect free statements as well.
if (!NodeUtil.isStatement(n)) {
problemNodes.add(n);
}
}
} | src/com/google/javascript/jscomp/CheckSideEffects.java |
Closure-23 | private Node tryFoldArrayAccess(Node n, Node left, Node right) {
Node parent = n.getParent();
// If GETPROP/GETELEM is used as assignment target the array literal is
// acting as a temporary we can't fold it here:
// "[][0] += 1"
if (isAssignmentTarget(n)) {
return n;
}
if (!right.isNumber()) {
// Sometimes people like to use complex expressions to index into
// arrays, or strings to index into array methods.
return n;
}
double index = right.getDouble();
int intIndex = (int) index;
if (intIndex != index) {
error(INVALID_GETELEM_INDEX_ERROR, right);
return n;
}
if (intIndex < 0) {
error(INDEX_OUT_OF_BOUNDS_ERROR, right);
return n;
}
Node current = left.getFirstChild();
Node elem = null;
for (int i = 0; current != null && i < intIndex; i++) {
elem = current;
current = current.getNext();
}
if (elem == null) {
error(INDEX_OUT_OF_BOUNDS_ERROR, right);
return n;
}
if (elem.isEmpty()) {
elem = NodeUtil.newUndefinedNode(elem);
} else {
left.removeChild(elem);
}
// Replace the entire GETELEM with the value
n.getParent().replaceChild(n, elem);
reportCodeChange();
return elem;
}
private Node tryFoldArrayAccess(Node n, Node left, Node right) {
Node parent = n.getParent();
// If GETPROP/GETELEM is used as assignment target the array literal is
// acting as a temporary we can't fold it here:
// "[][0] += 1"
if (isAssignmentTarget(n)) {
return n;
}
if (!right.isNumber()) {
// Sometimes people like to use complex expressions to index into
// arrays, or strings to index into array methods.
return n;
}
double index = right.getDouble();
int intIndex = (int) index;
if (intIndex != index) {
error(INVALID_GETELEM_INDEX_ERROR, right);
return n;
}
if (intIndex < 0) {
error(INDEX_OUT_OF_BOUNDS_ERROR, right);
return n;
}
Node current = left.getFirstChild();
Node elem = null;
for (int i = 0; current != null; i++) {
if (i != intIndex) {
if (mayHaveSideEffects(current)) {
return n;
}
} else {
elem = current;
}
current = current.getNext();
}
if (elem == null) {
error(INDEX_OUT_OF_BOUNDS_ERROR, right);
return n;
}
if (elem.isEmpty()) {
elem = NodeUtil.newUndefinedNode(elem);
} else {
left.removeChild(elem);
}
// Replace the entire GETELEM with the value
n.getParent().replaceChild(n, elem);
reportCodeChange();
return elem;
} | src/com/google/javascript/jscomp/PeepholeFoldConstants.java |
Closure-24 | private void findAliases(NodeTraversal t) {
Scope scope = t.getScope();
for (Var v : scope.getVarIterable()) {
Node n = v.getNode();
int type = n.getType();
Node parent = n.getParent();
if (parent.isVar()) {
if (n.hasChildren() && n.getFirstChild().isQualifiedName()) {
String name = n.getString();
Var aliasVar = scope.getVar(name);
aliases.put(name, aliasVar);
String qualifiedName =
aliasVar.getInitialValue().getQualifiedName();
transformation.addAlias(name, qualifiedName);
// Bleeding functions already get a BAD_PARAMETERS error, so just
// do nothing.
// Parameters of the scope function also get a BAD_PARAMETERS
// error.
} else {
// TODO(robbyw): Support using locals for private variables.
report(t, n, GOOG_SCOPE_NON_ALIAS_LOCAL, n.getString());
}
}
}
}
private void findAliases(NodeTraversal t) {
Scope scope = t.getScope();
for (Var v : scope.getVarIterable()) {
Node n = v.getNode();
int type = n.getType();
Node parent = n.getParent();
if (parent.isVar() &&
n.hasChildren() && n.getFirstChild().isQualifiedName()) {
String name = n.getString();
Var aliasVar = scope.getVar(name);
aliases.put(name, aliasVar);
String qualifiedName =
aliasVar.getInitialValue().getQualifiedName();
transformation.addAlias(name, qualifiedName);
} else if (v.isBleedingFunction()) {
// Bleeding functions already get a BAD_PARAMETERS error, so just
// do nothing.
} else if (parent.getType() == Token.LP) {
// Parameters of the scope function also get a BAD_PARAMETERS
// error.
} else {
// TODO(robbyw): Support using locals for private variables.
report(t, n, GOOG_SCOPE_NON_ALIAS_LOCAL, n.getString());
}
}
} | src/com/google/javascript/jscomp/ScopedAliases.java |
Closure-25 | private FlowScope traverseNew(Node n, FlowScope scope) {
Node constructor = n.getFirstChild();
scope = traverse(constructor, scope);
JSType constructorType = constructor.getJSType();
JSType type = null;
if (constructorType != null) {
constructorType = constructorType.restrictByNotNullOrUndefined();
if (constructorType.isUnknownType()) {
type = getNativeType(UNKNOWN_TYPE);
} else {
FunctionType ct = constructorType.toMaybeFunctionType();
if (ct == null && constructorType instanceof FunctionType) {
// If constructorType is a NoObjectType, then toMaybeFunctionType will
// return null. But NoObjectType implements the FunctionType
// interface, precisely because it can validly construct objects.
ct = (FunctionType) constructorType;
}
if (ct != null && ct.isConstructor()) {
type = ct.getInstanceType();
}
}
}
n.setJSType(type);
for (Node arg = constructor.getNext(); arg != null; arg = arg.getNext()) {
scope = traverse(arg, scope);
}
return scope;
}
private FlowScope traverseNew(Node n, FlowScope scope) {
scope = traverseChildren(n, scope);
Node constructor = n.getFirstChild();
JSType constructorType = constructor.getJSType();
JSType type = null;
if (constructorType != null) {
constructorType = constructorType.restrictByNotNullOrUndefined();
if (constructorType.isUnknownType()) {
type = getNativeType(UNKNOWN_TYPE);
} else {
FunctionType ct = constructorType.toMaybeFunctionType();
if (ct == null && constructorType instanceof FunctionType) {
// If constructorType is a NoObjectType, then toMaybeFunctionType will
// return null. But NoObjectType implements the FunctionType
// interface, precisely because it can validly construct objects.
ct = (FunctionType) constructorType;
}
if (ct != null && ct.isConstructor()) {
type = ct.getInstanceType();
backwardsInferenceFromCallSite(n, ct);
}
}
}
n.setJSType(type);
return scope;
} | src/com/google/javascript/jscomp/TypeInference.java |
Closure-29 | private boolean isInlinableObject(List<Reference> refs) {
boolean ret = false;
for (Reference ref : refs) {
Node name = ref.getNode();
Node parent = ref.getParent();
Node gramps = ref.getGrandparent();
// Ignore indirect references, like x.y (except x.y(), since
// the function referenced by y might reference 'this').
//
if (parent.isGetProp()) {
Preconditions.checkState(parent.getFirstChild() == name);
// A call target maybe using the object as a 'this' value.
if (gramps.isCall()
&& gramps.getFirstChild() == parent) {
return false;
}
// NOTE(nicksantos): This pass's object-splitting algorithm has
// a blind spot. It assumes that if a property isn't defined on an
// object, then the value is undefined. This is not true, because
// Object.prototype can have arbitrary properties on it.
//
// We short-circuit this problem by bailing out if we see a reference
// to a property that isn't defined on the object literal. This
// isn't a perfect algorithm, but it should catch most cases.
continue;
}
// Only rewrite VAR declarations or simple assignment statements
if (!isVarOrAssignExprLhs(name)) {
return false;
}
Node val = ref.getAssignedValue();
if (val == null) {
// A var with no assignment.
continue;
}
// We're looking for object literal assignments only.
if (!val.isObjectLit()) {
return false;
}
// Make sure that the value is not self-refential. IOW,
// disallow things like x = {b: x.a}.
//
// TODO: Only exclude unorderable self-referential
// assignments. i.e. x = {a: x.b, b: x.a} is not orderable,
// but x = {a: 1, b: x.a} is.
//
// Also, ES5 getters/setters aren't handled by this pass.
for (Node child = val.getFirstChild(); child != null;
child = child.getNext()) {
if (child.isGetterDef() ||
child.isSetterDef()) {
// ES5 get/set not supported.
return false;
}
Node childVal = child.getFirstChild();
// Check if childVal is the parent of any of the passed in
// references, as that is how self-referential assignments
// will happen.
for (Reference t : refs) {
Node refNode = t.getParent();
while (!NodeUtil.isStatementBlock(refNode)) {
if (refNode == childVal) {
// There's a self-referential assignment
return false;
}
refNode = refNode.getParent();
}
}
}
// We have found an acceptable object literal assignment. As
// long as there are no other assignments that mess things up,
// we can inline.
ret = true;
}
return ret;
}
private boolean isInlinableObject(List<Reference> refs) {
boolean ret = false;
Set<String> validProperties = Sets.newHashSet();
for (Reference ref : refs) {
Node name = ref.getNode();
Node parent = ref.getParent();
Node gramps = ref.getGrandparent();
// Ignore indirect references, like x.y (except x.y(), since
// the function referenced by y might reference 'this').
//
if (parent.isGetProp()) {
Preconditions.checkState(parent.getFirstChild() == name);
// A call target maybe using the object as a 'this' value.
if (gramps.isCall()
&& gramps.getFirstChild() == parent) {
return false;
}
// NOTE(nicksantos): This pass's object-splitting algorithm has
// a blind spot. It assumes that if a property isn't defined on an
// object, then the value is undefined. This is not true, because
// Object.prototype can have arbitrary properties on it.
//
// We short-circuit this problem by bailing out if we see a reference
// to a property that isn't defined on the object literal. This
// isn't a perfect algorithm, but it should catch most cases.
String propName = parent.getLastChild().getString();
if (!validProperties.contains(propName)) {
if (NodeUtil.isVarOrSimpleAssignLhs(parent, gramps)) {
validProperties.add(propName);
} else {
return false;
}
}
continue;
}
// Only rewrite VAR declarations or simple assignment statements
if (!isVarOrAssignExprLhs(name)) {
return false;
}
Node val = ref.getAssignedValue();
if (val == null) {
// A var with no assignment.
continue;
}
// We're looking for object literal assignments only.
if (!val.isObjectLit()) {
return false;
}
// Make sure that the value is not self-refential. IOW,
// disallow things like x = {b: x.a}.
//
// TODO: Only exclude unorderable self-referential
// assignments. i.e. x = {a: x.b, b: x.a} is not orderable,
// but x = {a: 1, b: x.a} is.
//
// Also, ES5 getters/setters aren't handled by this pass.
for (Node child = val.getFirstChild(); child != null;
child = child.getNext()) {
if (child.isGetterDef() ||
child.isSetterDef()) {
// ES5 get/set not supported.
return false;
}
validProperties.add(child.getString());
Node childVal = child.getFirstChild();
// Check if childVal is the parent of any of the passed in
// references, as that is how self-referential assignments
// will happen.
for (Reference t : refs) {
Node refNode = t.getParent();
while (!NodeUtil.isStatementBlock(refNode)) {
if (refNode == childVal) {
// There's a self-referential assignment
return false;
}
refNode = refNode.getParent();
}
}
}
// We have found an acceptable object literal assignment. As
// long as there are no other assignments that mess things up,
// we can inline.
ret = true;
}
return ret;
} | src/com/google/javascript/jscomp/InlineObjectLiterals.java |
Closure-31 | Node parseInputs() {
boolean devMode = options.devMode != DevMode.OFF;
// If old roots exist (we are parsing a second time), detach each of the
// individual file parse trees.
if (externsRoot != null) {
externsRoot.detachChildren();
}
if (jsRoot != null) {
jsRoot.detachChildren();
}
// Parse main js sources.
jsRoot = IR.block();
jsRoot.setIsSyntheticBlock(true);
externsRoot = IR.block();
externsRoot.setIsSyntheticBlock(true);
externAndJsRoot = IR.block(externsRoot, jsRoot);
externAndJsRoot.setIsSyntheticBlock(true);
if (options.tracer.isOn()) {
tracker = new PerformanceTracker(jsRoot, options.tracer);
addChangeHandler(tracker.getCodeChangeHandler());
}
Tracer tracer = newTracer("parseInputs");
try {
// Parse externs sources.
for (CompilerInput input : externs) {
Node n = input.getAstRoot(this);
if (hasErrors()) {
return null;
}
externsRoot.addChildToBack(n);
}
// Modules inferred in ProcessCommonJS pass.
if (options.transformAMDToCJSModules || options.processCommonJSModules) {
processAMDAndCommonJSModules();
}
// Check if inputs need to be rebuilt from modules.
boolean staleInputs = false;
// Check if the sources need to be re-ordered.
if (options.dependencyOptions.needsManagement() &&
!options.skipAllPasses &&
options.closurePass) {
for (CompilerInput input : inputs) {
// Forward-declare all the provided types, so that they
// are not flagged even if they are dropped from the process.
for (String provide : input.getProvides()) {
getTypeRegistry().forwardDeclareType(provide);
}
}
try {
inputs =
(moduleGraph == null ? new JSModuleGraph(modules) : moduleGraph)
.manageDependencies(options.dependencyOptions, inputs);
staleInputs = true;
} catch (CircularDependencyException e) {
report(JSError.make(
JSModule.CIRCULAR_DEPENDENCY_ERROR, e.getMessage()));
// If in IDE mode, we ignore the error and keep going.
if (hasErrors()) {
return null;
}
} catch (MissingProvideException e) {
report(JSError.make(
MISSING_ENTRY_ERROR, e.getMessage()));
// If in IDE mode, we ignore the error and keep going.
if (hasErrors()) {
return null;
}
}
}
for (CompilerInput input : inputs) {
Node n = input.getAstRoot(this);
// Inputs can have a null AST during initial parse.
if (n == null) {
continue;
}
if (n.getJSDocInfo() != null) {
JSDocInfo info = n.getJSDocInfo();
if (info.isExterns()) {
// If the input file is explicitly marked as an externs file, then
// assume the programmer made a mistake and throw it into
// the externs pile anyways.
externsRoot.addChildToBack(n);
input.setIsExtern(true);
input.getModule().remove(input);
externs.add(input);
staleInputs = true;
} else if (info.isNoCompile()) {
input.getModule().remove(input);
staleInputs = true;
}
}
}
if (staleInputs) {
fillEmptyModules(modules);
rebuildInputsFromModules();
}
// Build the AST.
for (CompilerInput input : inputs) {
Node n = input.getAstRoot(this);
if (n == null) {
continue;
}
if (devMode) {
runSanityCheck();
if (hasErrors()) {
return null;
}
}
if (options.sourceMapOutputPath != null ||
options.nameReferenceReportPath != null) {
// Annotate the nodes in the tree with information from the
// input file. This information is used to construct the SourceMap.
SourceInformationAnnotator sia =
new SourceInformationAnnotator(
input.getName(), options.devMode != DevMode.OFF);
NodeTraversal.traverse(this, n, sia);
}
jsRoot.addChildToBack(n);
}
if (hasErrors()) {
return null;
}
return externAndJsRoot;
} finally {
stopTracer(tracer, "parseInputs");
}
}
Node parseInputs() {
boolean devMode = options.devMode != DevMode.OFF;
// If old roots exist (we are parsing a second time), detach each of the
// individual file parse trees.
if (externsRoot != null) {
externsRoot.detachChildren();
}
if (jsRoot != null) {
jsRoot.detachChildren();
}
// Parse main js sources.
jsRoot = IR.block();
jsRoot.setIsSyntheticBlock(true);
externsRoot = IR.block();
externsRoot.setIsSyntheticBlock(true);
externAndJsRoot = IR.block(externsRoot, jsRoot);
externAndJsRoot.setIsSyntheticBlock(true);
if (options.tracer.isOn()) {
tracker = new PerformanceTracker(jsRoot, options.tracer);
addChangeHandler(tracker.getCodeChangeHandler());
}
Tracer tracer = newTracer("parseInputs");
try {
// Parse externs sources.
for (CompilerInput input : externs) {
Node n = input.getAstRoot(this);
if (hasErrors()) {
return null;
}
externsRoot.addChildToBack(n);
}
// Modules inferred in ProcessCommonJS pass.
if (options.transformAMDToCJSModules || options.processCommonJSModules) {
processAMDAndCommonJSModules();
}
// Check if inputs need to be rebuilt from modules.
boolean staleInputs = false;
// Check if the sources need to be re-ordered.
if (options.dependencyOptions.needsManagement() &&
options.closurePass) {
for (CompilerInput input : inputs) {
// Forward-declare all the provided types, so that they
// are not flagged even if they are dropped from the process.
for (String provide : input.getProvides()) {
getTypeRegistry().forwardDeclareType(provide);
}
}
try {
inputs =
(moduleGraph == null ? new JSModuleGraph(modules) : moduleGraph)
.manageDependencies(options.dependencyOptions, inputs);
staleInputs = true;
} catch (CircularDependencyException e) {
report(JSError.make(
JSModule.CIRCULAR_DEPENDENCY_ERROR, e.getMessage()));
// If in IDE mode, we ignore the error and keep going.
if (hasErrors()) {
return null;
}
} catch (MissingProvideException e) {
report(JSError.make(
MISSING_ENTRY_ERROR, e.getMessage()));
// If in IDE mode, we ignore the error and keep going.
if (hasErrors()) {
return null;
}
}
}
for (CompilerInput input : inputs) {
Node n = input.getAstRoot(this);
// Inputs can have a null AST during initial parse.
if (n == null) {
continue;
}
if (n.getJSDocInfo() != null) {
JSDocInfo info = n.getJSDocInfo();
if (info.isExterns()) {
// If the input file is explicitly marked as an externs file, then
// assume the programmer made a mistake and throw it into
// the externs pile anyways.
externsRoot.addChildToBack(n);
input.setIsExtern(true);
input.getModule().remove(input);
externs.add(input);
staleInputs = true;
} else if (info.isNoCompile()) {
input.getModule().remove(input);
staleInputs = true;
}
}
}
if (staleInputs) {
fillEmptyModules(modules);
rebuildInputsFromModules();
}
// Build the AST.
for (CompilerInput input : inputs) {
Node n = input.getAstRoot(this);
if (n == null) {
continue;
}
if (devMode) {
runSanityCheck();
if (hasErrors()) {
return null;
}
}
if (options.sourceMapOutputPath != null ||
options.nameReferenceReportPath != null) {
// Annotate the nodes in the tree with information from the
// input file. This information is used to construct the SourceMap.
SourceInformationAnnotator sia =
new SourceInformationAnnotator(
input.getName(), options.devMode != DevMode.OFF);
NodeTraversal.traverse(this, n, sia);
}
jsRoot.addChildToBack(n);
}
if (hasErrors()) {
return null;
}
return externAndJsRoot;
} finally {
stopTracer(tracer, "parseInputs");
}
} | src/com/google/javascript/jscomp/Compiler.java |
Closure-32 | private ExtractionInfo extractMultilineTextualBlock(JsDocToken token,
WhitespaceOption option) {
if (token == JsDocToken.EOC || token == JsDocToken.EOL ||
token == JsDocToken.EOF) {
return new ExtractionInfo("", token);
}
stream.update();
int startLineno = stream.getLineno();
int startCharno = stream.getCharno() + 1;
// Read the content from the first line.
String line = stream.getRemainingJSDocLine();
if (option != WhitespaceOption.PRESERVE) {
line = line.trim();
}
StringBuilder builder = new StringBuilder();
builder.append(line);
state = State.SEARCHING_ANNOTATION;
token = next();
boolean ignoreStar = false;
// Track the start of the line to count whitespace that
// the tokenizer skipped. Because this case is rare, it's easier
// to do this here than in the tokenizer.
do {
switch (token) {
case STAR:
if (ignoreStar) {
// Mark the position after the star as the new start of the line.
} else {
// The star is part of the comment.
if (builder.length() > 0) {
builder.append(' ');
}
builder.append('*');
}
token = next();
continue;
case EOL:
if (option != WhitespaceOption.SINGLE_LINE) {
builder.append("\n");
}
ignoreStar = true;
token = next();
continue;
default:
ignoreStar = false;
state = State.SEARCHING_ANNOTATION;
// All tokens must be separated by a space.
if (token == JsDocToken.EOC ||
token == JsDocToken.EOF ||
// When we're capturing a license block, annotations
// in the block are ok.
(token == JsDocToken.ANNOTATION &&
option != WhitespaceOption.PRESERVE)) {
String multilineText = builder.toString();
if (option != WhitespaceOption.PRESERVE) {
multilineText = multilineText.trim();
}
int endLineno = stream.getLineno();
int endCharno = stream.getCharno();
if (multilineText.length() > 0) {
jsdocBuilder.markText(multilineText, startLineno, startCharno,
endLineno, endCharno);
}
return new ExtractionInfo(multilineText, token);
}
if (builder.length() > 0) {
builder.append(' ');
}
builder.append(toString(token));
line = stream.getRemainingJSDocLine();
if (option != WhitespaceOption.PRESERVE) {
line = trimEnd(line);
}
builder.append(line);
token = next();
}
} while (true);
}
private ExtractionInfo extractMultilineTextualBlock(JsDocToken token,
WhitespaceOption option) {
if (token == JsDocToken.EOC || token == JsDocToken.EOL ||
token == JsDocToken.EOF) {
return new ExtractionInfo("", token);
}
stream.update();
int startLineno = stream.getLineno();
int startCharno = stream.getCharno() + 1;
// Read the content from the first line.
String line = stream.getRemainingJSDocLine();
if (option != WhitespaceOption.PRESERVE) {
line = line.trim();
}
StringBuilder builder = new StringBuilder();
builder.append(line);
state = State.SEARCHING_ANNOTATION;
token = next();
boolean ignoreStar = false;
// Track the start of the line to count whitespace that
// the tokenizer skipped. Because this case is rare, it's easier
// to do this here than in the tokenizer.
int lineStartChar = -1;
do {
switch (token) {
case STAR:
if (ignoreStar) {
// Mark the position after the star as the new start of the line.
lineStartChar = stream.getCharno() + 1;
} else {
// The star is part of the comment.
if (builder.length() > 0) {
builder.append(' ');
}
builder.append('*');
}
token = next();
continue;
case EOL:
if (option != WhitespaceOption.SINGLE_LINE) {
builder.append("\n");
}
ignoreStar = true;
lineStartChar = 0;
token = next();
continue;
default:
ignoreStar = false;
state = State.SEARCHING_ANNOTATION;
boolean isEOC = token == JsDocToken.EOC;
if (!isEOC) {
if (lineStartChar != -1 && option == WhitespaceOption.PRESERVE) {
int numSpaces = stream.getCharno() - lineStartChar;
for (int i = 0; i < numSpaces; i++) {
builder.append(' ');
}
lineStartChar = -1;
} else if (builder.length() > 0) {
// All tokens must be separated by a space.
builder.append(' ');
}
}
if (token == JsDocToken.EOC ||
token == JsDocToken.EOF ||
// When we're capturing a license block, annotations
// in the block are ok.
(token == JsDocToken.ANNOTATION &&
option != WhitespaceOption.PRESERVE)) {
String multilineText = builder.toString();
if (option != WhitespaceOption.PRESERVE) {
multilineText = multilineText.trim();
}
int endLineno = stream.getLineno();
int endCharno = stream.getCharno();
if (multilineText.length() > 0) {
jsdocBuilder.markText(multilineText, startLineno, startCharno,
endLineno, endCharno);
}
return new ExtractionInfo(multilineText, token);
}
builder.append(toString(token));
line = stream.getRemainingJSDocLine();
if (option != WhitespaceOption.PRESERVE) {
line = trimEnd(line);
}
builder.append(line);
token = next();
}
} while (true);
} | src/com/google/javascript/jscomp/parsing/JsDocInfoParser.java |
Closure-33 | public void matchConstraint(ObjectType constraintObj) {
// We only want to match contraints on anonymous types.
// Handle the case where the constraint object is a record type.
//
// param constraintObj {{prop: (number|undefined)}}
// function f(constraintObj) {}
// f({});
//
// We want to modify the object literal to match the constraint, by
// taking any each property on the record and trying to match
// properties on this object.
if (constraintObj.isRecordType()) {
for (String prop : constraintObj.getOwnPropertyNames()) {
JSType propType = constraintObj.getPropertyType(prop);
if (!isPropertyTypeDeclared(prop)) {
JSType typeToInfer = propType;
if (!hasProperty(prop)) {
typeToInfer = getNativeType(JSTypeNative.VOID_TYPE)
.getLeastSupertype(propType);
}
defineInferredProperty(prop, typeToInfer, null);
}
}
}
}
public void matchConstraint(ObjectType constraintObj) {
// We only want to match contraints on anonymous types.
if (hasReferenceName()) {
return;
}
// Handle the case where the constraint object is a record type.
//
// param constraintObj {{prop: (number|undefined)}}
// function f(constraintObj) {}
// f({});
//
// We want to modify the object literal to match the constraint, by
// taking any each property on the record and trying to match
// properties on this object.
if (constraintObj.isRecordType()) {
for (String prop : constraintObj.getOwnPropertyNames()) {
JSType propType = constraintObj.getPropertyType(prop);
if (!isPropertyTypeDeclared(prop)) {
JSType typeToInfer = propType;
if (!hasProperty(prop)) {
typeToInfer = getNativeType(JSTypeNative.VOID_TYPE)
.getLeastSupertype(propType);
}
defineInferredProperty(prop, typeToInfer, null);
}
}
}
} | src/com/google/javascript/rhino/jstype/PrototypeObjectType.java |