/*
* Copyright (c) 2009 Nokia Corporation and/or its subsidiary(-ies).
* All rights reserved.
* This component and the accompanying materials are made available
* under the terms of "Eclipse Public License v1.0"
* which accompanies this distribution, and is available
* at the URL "http://www.eclipse.org/legal/epl-v10.html".
*
* Initial Contributors:
* Nokia Corporation - initial contribution.
*
* Contributors:
*
* Description:
*
*/
#include "hgqtquadrenderer.h"
#include "hgquad.h"
#include "hgtransformedquad.h"
#include "trace.h"
#include "hgimage.h"
#include <QVector2D>
#include <QPolygon>
#include <QMatrix4x4>
#include <QPainter>
#include <QPixmapCache>
class HgQtImage : public HgImage
{
public:
HgQtImage(HgQtQuadRenderer* renderer)
{
Q_UNUSED(renderer)
}
~HgQtImage()
{
}
int width() const
{
return mPixmap.width();
}
int height() const
{
return mPixmap.height();
}
int mirrorImageWidth() const
{
return width();
}
int mirrorImageHeight() const
{
return height();
}
void setImage(const QImage& image)
{
mPixmap = QPixmap::fromImage(image);
//mMirrorPixmap = QPixmap();
}
void setPixmap(const QPixmap& pixmap)
{
mPixmap = pixmap;
//mMirrorPixmap = QPixmap();
}
void releaseImage()
{
//mPixmap = QPixmap();
//mMirrorPixmap = QPixmap();
}
QImage getQImage() const
{
return mPixmap.toImage();
}
const QPixmap& pixmap() const
{
return mPixmap;
}
const QPixmap& mirrorPixmap(QPainter* painter)
{
Q_UNUSED(painter)
return mPixmap;
/*
if (mPixmap.isNull())
return mPixmap;
if (mMirrorPixmap.isNull())
{
QImage img = mPixmap.toImage();
QImage mirrorImage = img.scaled(QSize(img.width()/3,img.height()/3)).convertToFormat(QImage::Format_ARGB32);
// apply gradient to alpha channel so that mirror image looks like
// it fades under the floor
for (int i = 0; i < mirrorImage.height(); i++)
{
qreal t = qreal(i) / qreal(mirrorImage.height());
int a = (int)(t * 255.0);
uchar* scanline = mirrorImage.scanLine(i);
for (int j = 0; j < mirrorImage.width(); j++)
{
scanline[j*4+0] /= 3;
scanline[j*4+1] /= 3;
scanline[j*4+2] /= 3;
scanline[j*4+3] = 255;
}
}
mMirrorPixmap = QPixmap::fromImage(mirrorImage);
QPaintDevice* device = painter->device();
painter->end();
mMirrorPixmap = mPixmap.scaled(100,100);
int w = mMirrorPixmap.width();
int h = mMirrorPixmap.height();
//QPainter p;
painter->begin(&mMirrorPixmap);
painter->fillRect(0,0,w, h, QColor::fromRgbF(0, 0, 0, 0.5f));
painter->end();
painter->begin(device);
}
return mMirrorPixmap;*/
}
QPixmap mPixmap;
};
class HgQtQuad : public HgTransformedQuad
{
public:
HgQtQuad(HgQtQuadRenderer* renderer) : HgTransformedQuad(-1), mRenderer(renderer)
{
}
~HgQtQuad()
{
}
void draw(QPainter* painter, const QRectF& rect, const QTransform& transform)
{
if (!quad()->visible())
return;
HgQtImage* image = (HgQtImage*)quad()->image();
if (image == NULL)
image = mRenderer->defaultImage();
if (image == NULL)
return;
if (image->pixmap().isNull())
image = mRenderer->defaultImage();
drawImage(painter, image, rect, transform);
}
private:
void computeWarpMatrix(QTransform& tm, int pxWidth, int pxHeight, const QVector2D* points)
{
QPolygonF poly;
poly << points[0].toPointF();
poly << points[1].toPointF();
poly << points[2].toPointF();
poly << points[3].toPointF();
QPolygonF img;
img.append(QPointF(0,pxHeight));
img.append(QPointF(pxWidth,pxHeight));
img.append(QPointF(pxWidth,0));
img.append(QPointF(0,0));
QTransform::quadToQuad(img, poly, tm);
}
void drawImage(QPainter* painter, HgQtImage* image, const QRectF& rect, const QTransform& transform)
{
const QPixmap& pixmap = image->pixmap();
if (pixmap.isNull())
return;
const QVector2D* points = mTransformedPoints;
if (mRenderer->isReflection() && quad()->mirrorImageEnabled())
points = mMirroredPoints;
QPolygonF poly;
poly << points[0].toPointF();
poly << points[1].toPointF();
poly << points[2].toPointF();
poly << points[3].toPointF();
QRectF bounds = poly.boundingRect();
if (!(bounds.intersects(rect) || rect.contains(bounds))) {
return;
}
computeWarpMatrix(mTransform, image->width(), image->height(), points);
painter->setTransform(mTransform * transform);
painter->drawPixmap(QPointF(0,0), pixmap);
}
HgQtQuadRenderer* mRenderer;
QTransform mTransform;
QTransform mMirrorTransform;
};
HgQtQuadRenderer::HgQtQuadRenderer(int maxQuads) :
HgTransformedQuadRenderer(maxQuads),
mDefaultQtImage(NULL)
{
// initialize base class to the end.
init(maxQuads);
QImage image(QSize(200,200), QImage::Format_RGB16);
image.fill(0xFFFFFFFF);
setDefaultImage(image);
QPixmapCache::setCacheLimit(2048);
}
HgQtQuadRenderer::~HgQtQuadRenderer()
{
delete mDefaultQtImage;
}
void HgQtQuadRenderer::drawQuads(QPainter* painter, const QRectF& rect,
const QMatrix4x4& viewMatrix, const QMatrix4x4& projectionMatrix,
Qt::Orientation orientation,
const QTransform& sceneTransform)
{
Q_UNUSED(orientation)
Q_UNUSED(sceneTransform)
transformQuads(viewMatrix, projectionMatrix,
QPointF(rect.width()/2, rect.height()/2), QSizeF(rect.width(), rect.height()));
// save old transform
QTransform temp = painter->transform();
if (mReflectionsEnabled)
{
mIsReflection = true;
drawTransformedQuads(painter, rect, temp);
painter->setTransform(temp);
drawFloor(painter, rect);
}
mIsReflection = false;
drawTransformedQuads(painter, rect, temp);
painter->setTransform(temp);
}
HgImage* HgQtQuadRenderer::createNativeImage()
{
return new HgQtImage(this);
}
HgQtImage* HgQtQuadRenderer::defaultImage()
{
return mDefaultQtImage;
}
void HgQtQuadRenderer::setDefaultImage(QImage defaultImage)
{
HgQuadRenderer::setDefaultImage(defaultImage);
delete mDefaultQtImage;
mDefaultQtImage = 0;
mDefaultQtImage = static_cast<HgQtImage*>(createNativeImage());
mDefaultQtImage->setImage(mDefaultImage);
}
HgTransformedQuad* HgQtQuadRenderer::createNativeQuad()
{
return new HgQtQuad(this);
}
bool HgQtQuadRenderer::isReflection() const
{
return mIsReflection;
}
void HgQtQuadRenderer::drawFloor(QPainter* painter, const QRectF& rect)
{
QRectF floorRect(0, rect.height()/2, rect.width(), rect.height()/2);
QBrush brush(QColor::fromRgbF(0,0,0,0.5f));
painter->setBrush(brush);
painter->drawRect(floorRect);
}