com.sun.scenario.effect.PerspectiveTransform Maven / Gradle / Ivy
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package com.sun.scenario.effect;
import com.sun.scenario.effect.impl.state.PerspectiveTransformState;
import com.sun.javafx.geom.Point2D;
import com.sun.javafx.geom.BaseBounds;
import com.sun.javafx.geom.DirtyRegionContainer;
import com.sun.javafx.geom.DirtyRegionPool;
import com.sun.javafx.geom.RectBounds;
import com.sun.javafx.geom.Rectangle;
import com.sun.javafx.geom.transform.BaseTransform;
import com.sun.scenario.effect.impl.state.RenderState;
public class PerspectiveTransform extends CoreEffect {
private float tx[][] = new float[3][3];
private float ulx, uly, urx, ury, lrx, lry, llx, lly;
private float devcoords[] = new float[8];
private final PerspectiveTransformState state = new PerspectiveTransformState();
public PerspectiveTransform() {
this(DefaultInput);
}
public PerspectiveTransform(Effect input) {
super(input);
setQuadMapping(0f, 0f, 100f, 0f, 100f, 100f, 0f, 100f);
updatePeerKey("PerspectiveTransform");
}
@Override
Object getState() {
return state;
}
/**
* Returns the input for this {@code Effect}.
*
* @return the input for this {@code Effect}
*/
public final Effect getInput() {
return getInputs().get(0);
}
/**
* Sets the input for this {@code Effect} to a specific
* {@code Effect} or to the default input if {@code input} is
* {@code null}.
*
* @param input the input for this {@code Effect}
*/
public void setInput(Effect input) {
setInput(0, input);
}
/**
* Sets the transform to map the unit square to the indicated
* quadrilateral coordinates.
* The resulting perspective transform will perform the following
* coordinate mappings:
*
* T(0, 0) = (ulx, uly)
* T(0, 1) = (urx, ury)
* T(1, 1) = (lrx, lry)
* T(1, 0) = (llx, lly)
*
* Note that the upper left corner of the unit square {@code (0, 0)}
* is mapped to the coordinates specified by {@code (ulx, uly)} and
* so on around the unit square in a clockwise direction.
*
* @param ulx The X coordinate to which {@code (0, 0)} is mapped.
* @param uly The Y coordinate to which {@code (0, 0)} is mapped.
* @param urx The X coordinate to which {@code (1, 0)} is mapped.
* @param ury The Y coordinate to which {@code (1, 0)} is mapped.
* @param lrx The X coordinate to which {@code (1, 1)} is mapped.
* @param lry The Y coordinate to which {@code (1, 1)} is mapped.
* @param llx The X coordinate to which {@code (0, 1)} is mapped.
* @param lly The Y coordinate to which {@code (0, 1)} is mapped.
*/
private void setUnitQuadMapping(float ulx, float uly,
float urx, float ury,
float lrx, float lry,
float llx, float lly)
{
float dx3 = ulx - urx + lrx - llx;
float dy3 = uly - ury + lry - lly;
tx[2][2] = 1.0F;
if ((dx3 == 0.0F) && (dy3 == 0.0F)) { // TODO: use tolerance (RT-27402)
tx[0][0] = urx - ulx;
tx[0][1] = lrx - urx;
tx[0][2] = ulx;
tx[1][0] = ury - uly;
tx[1][1] = lry - ury;
tx[1][2] = uly;
tx[2][0] = 0.0F;
tx[2][1] = 0.0F;
} else {
float dx1 = urx - lrx;
float dy1 = ury - lry;
float dx2 = llx - lrx;
float dy2 = lly - lry;
float invdet = 1.0F/(dx1*dy2 - dx2*dy1);
tx[2][0] = (dx3*dy2 - dx2*dy3)*invdet;
tx[2][1] = (dx1*dy3 - dx3*dy1)*invdet;
tx[0][0] = urx - ulx + tx[2][0]*urx;
tx[0][1] = llx - ulx + tx[2][1]*llx;
tx[0][2] = ulx;
tx[1][0] = ury - uly + tx[2][0]*ury;
tx[1][1] = lly - uly + tx[2][1]*lly;
tx[1][2] = uly;
}
state.updateTx(tx);
}
public final void setQuadMapping(float ulx, float uly,
float urx, float ury,
float lrx, float lry,
float llx, float lly)
{
this.ulx = ulx;
this.uly = uly;
this.urx = urx;
this.ury = ury;
this.lrx = lrx;
this.lry = lry;
this.llx = llx;
this.lly = lly;
}
@Override
public RectBounds getBounds(BaseTransform transform,
Effect defaultInput)
{
setupDevCoords(transform);
float minx, miny, maxx, maxy;
minx = maxx = devcoords[0];
miny = maxy = devcoords[1];
for (int i = 2; i < devcoords.length; i += 2) {
if (minx > devcoords[i]) minx = devcoords[i];
else if (maxx < devcoords[i]) maxx = devcoords[i];
if (miny > devcoords[i+1]) miny = devcoords[i+1];
else if (maxy < devcoords[i+1]) maxy = devcoords[i+1];
}
return new RectBounds(minx, miny, maxx, maxy);
}
private void setupDevCoords(BaseTransform transform) {
devcoords[0] = ulx;
devcoords[1] = uly;
devcoords[2] = urx;
devcoords[3] = ury;
devcoords[4] = lrx;
devcoords[5] = lry;
devcoords[6] = llx;
devcoords[7] = lly;
transform.transform(devcoords, 0, devcoords, 0, 4);
}
@Override
public ImageData filter(FilterContext fctx,
BaseTransform transform,
Rectangle outputClip,
Object renderHelper,
Effect defaultInput)
{
setupTransforms(transform);
RenderState rstate = getRenderState(fctx, transform, outputClip,
renderHelper, defaultInput);
Effect input = getDefaultedInput(0, defaultInput);
Rectangle inputClip = rstate.getInputClip(0, outputClip);
ImageData inputData =
input.filter(fctx, BaseTransform.IDENTITY_TRANSFORM,
inputClip, null, defaultInput);
if (!inputData.validate(fctx)) {
inputData.unref();
return new ImageData(fctx, null, inputData.getUntransformedBounds());
}
ImageData ret = filterImageDatas(fctx, transform, outputClip, rstate, inputData);
inputData.unref();
return ret;
}
@Override
public Rectangle getResultBounds(BaseTransform transform,
Rectangle outputClip,
ImageData... inputDatas)
{
Rectangle ob = new Rectangle(getBounds(transform, null));
ob.intersectWith(outputClip);
return ob;
}
@Override
public Point2D transform(Point2D p, Effect defaultInput) {
setupTransforms(BaseTransform.IDENTITY_TRANSFORM);
Effect input = getDefaultedInput(0, defaultInput);
p = input.transform(p, defaultInput);
BaseBounds b = input.getBounds(BaseTransform.IDENTITY_TRANSFORM, defaultInput);
float sx = (float) ((p.x - b.getMinX()) / b.getWidth());
float sy = (float) ((p.y - b.getMinY()) / b.getHeight());
float dx = tx[0][0] * sx + tx[0][1] * sy + tx[0][2];
float dy = tx[1][0] * sx + tx[1][1] * sy + tx[1][2];
float dw = tx[2][0] * sx + tx[2][1] * sy + tx[2][2];
p = new Point2D(dx / dw, dy / dw);
return p;
}
@Override
public Point2D untransform(Point2D p, Effect defaultInput) {
setupTransforms(BaseTransform.IDENTITY_TRANSFORM);
Effect input = getDefaultedInput(0, defaultInput);
float dx = (float) p.x;
float dy = (float) p.y;
float itx[][] = state.getITX();
float sx = itx[0][0] * dx + itx[0][1] * dy + itx[0][2];
float sy = itx[1][0] * dx + itx[1][1] * dy + itx[1][2];
float sw = itx[2][0] * dx + itx[2][1] * dy + itx[2][2];
BaseBounds b = input.getBounds(BaseTransform.IDENTITY_TRANSFORM, defaultInput);
p = new Point2D(b.getMinX() + (sx / sw) * b.getWidth(),
b.getMinY() + (sy / sw) * b.getHeight());
p = getDefaultedInput(0, defaultInput).untransform(p, defaultInput);
return p;
}
private void setupTransforms(BaseTransform transform) {
setupDevCoords(transform);
setUnitQuadMapping(devcoords[0], devcoords[1],
devcoords[2], devcoords[3],
devcoords[4], devcoords[5],
devcoords[6], devcoords[7]);
}
@Override
public RenderState getRenderState(FilterContext fctx,
BaseTransform transform,
Rectangle outputClip,
Object renderHelper,
Effect defaultInput)
{
// RT-27402
// TODO: We could inverse map the output bounds through the perspective
// transform to see what portions of the input contribute to the result,
// but until we implement such a process we will just use the stock
// object that specifies no clipping of the inputs.
return RenderState.UnclippedUserSpaceRenderState;
}
@Override
public boolean reducesOpaquePixels() {
return true;
}
@Override
public DirtyRegionContainer getDirtyRegions(Effect defaultInput, DirtyRegionPool regionPool) {
DirtyRegionContainer drc = regionPool.checkOut();
//RT-28197 - Dirty regions could be computed in more efficient way
drc.deriveWithNewRegion((RectBounds) getBounds(BaseTransform.IDENTITY_TRANSFORM, defaultInput));
return drc;
}
}
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