void FunctionToolbar::setFrame(double frame) {
m_frameNavigator->setFrame(tround(frame), false);
if (m_curve)
m_valueFld->setValue(m_curve->getValue(frame));
else
m_valueFld->setValue(0);
}
bool doGetBBox(double frame, TRectD &bBox,
const TRenderSettings &ri) override {
if (m_input.isConnected() && m_controller.isConnected()) {
TRectD controlBox, inputBox;
TRenderSettings ri2(ri);
ri2.m_affine = TAffine();
m_controller->getBBox(frame, controlBox, ri2);
TRenderSettings ri3(ri);
int shrink = tround((ri.m_shrinkX + ri.m_shrinkY) / 2.0);
// Should be there no need for the alias...
SandorFxRenderData *artContourData =
buildRenderData(frame, shrink, controlBox, "");
ri3.m_data.push_back(artContourData);
return m_input->doGetBBox(frame, bBox, ri3);
} else if (m_input.isConnected()) {
m_input->doGetBBox(frame, bBox, ri);
return false;
}
bBox = TRectD();
return false;
}
TPoint StylePicker::getRasterPoint(const TPointD &p) const {
if (TToonzImageP ti = m_image) {
// DpiScale dpiScale(ti);
TDimension size = ti->getSize();
return TPoint(tround(0.5 * size.lx + p.x), /// dpiScale.getSx()),
tround(0.5 * size.ly + p.y)); /// dpiScale.getSy()));
} else if (TRasterImageP ri = m_image) {
// DpiScale dpiScale(ri);
TDimension size = ri->getRaster()->getSize();
return TPoint(tround(0.5 * size.lx + p.x), // /dpiScale.getSx()),
tround(0.5 * size.ly + p.y)); // /dpiScale.getSy()));
} else
return TPoint(tround(p.x), tround(p.y));
}
// Builds the specified number of samples count, inside the specified distance
// from the origin. If the pattern is radial, paths to the samples points are
// calculated.
BlurPattern::BlurPattern(double distance, unsigned int samplesCount,
bool radial) {
const double randFactor = 2.0 * distance / RAND_MAX;
m_samples.resize(samplesCount);
// Build the samples
unsigned int i;
for (i = 0; i < samplesCount; ++i) {
// NOTE: The following method ensures a perfectly flat probability
// distribution.
TPoint candidatePoint(tround(rand() * randFactor - distance),
tround(rand() * randFactor - distance));
double distanceSq = sq(distance);
while (sq(candidatePoint.x) + sq(candidatePoint.y) > distanceSq)
candidatePoint = TPoint(tround(rand() * randFactor - distance),
tround(rand() * randFactor - distance));
m_samples[i] = candidatePoint;
}
m_samplePaths.resize(samplesCount);
// If necessary, build the paths
if (radial) {
for (i = 0; i < samplesCount; ++i) {
TPoint &sample = m_samples[i];
int l = std::max(abs(sample.x), abs(sample.y));
m_samplePaths[i].reserve(l);
double dx = sample.x / (double)l;
double dy = sample.y / (double)l;
double x, y;
int j;
for (j = 0, x = dx, y = dy; j < l; x += dx, y += dy, ++j)
m_samplePaths[i].push_back(TPoint(tround(x), tround(y)));
}
}
}
void RenderCommand::flashRender()
{
ToonzScene *scene = TApp::instance()->getCurrentScene()->getScene();
TSceneProperties *sprop = scene->getProperties();
FILE *fileP = fopen(m_fp, "wb");
if (!fileP)
return;
ProgressDialog pb("rendering " + toQString(m_fp), "Cancel", 0, m_numFrames);
pb.show();
TDimension cameraSize = scene->getCurrentCamera()->getRes();
double frameRate = sprop->getOutputProperties()->getFrameRate();
TFlash flash(
cameraSize.lx,
cameraSize.ly,
m_numFrames,
frameRate,
sprop->getOutputProperties()->getFileFormatProperties("swf"));
flash.setBackgroundColor(sprop->getBgColor());
std::vector<TXshSoundColumn *> columns;
scene->getSoundColumns(columns);
if (!columns.empty()) {
TXsheet::SoundProperties *prop = new TXsheet::SoundProperties();
prop->m_frameRate = frameRate;
TSoundTrack *st = scene->getXsheet()->makeSound(prop);
if (st)
flash.putSound(st, 0);
}
int i = 0;
for (i = 0; i < m_numFrames; ++i, m_r += m_stepd) {
flash.beginFrame(m_step * i + 1);
TRasterFxP rfx = buildSceneFx(scene, m_r, 0, false);
assert(rfx);
rfx->compute(flash, tround(m_r)); // WARNING: This should accept a DOUBLE...
#ifdef BRAVODEMO
TRasterImageP ri(loadBravo(scene->getCurrentCamera()->getRes()));
int lx = ri->getRaster()->getLx();
int ly = ri->getRaster()->getLx();
flash.pushMatrix();
int dx = tround(0.1 * (cameraSize.lx - lx));
int dy = tround(0.1 * (cameraSize.ly - ly));
flash.multMatrix(TTranslation((cameraSize.lx - lx) / 2 - (dx > 0 ? dx : 0), -(cameraSize.ly - ly) / 2 + (dy > 0 ? dy : 0)));
flash.draw(ri, 0);
flash.popMatrix();
#endif
flash.endFrame(i == m_numFrames - 1, 0, true);
if (pb.wasCanceled())
break;
pb.setValue(i + 1);
}
flash.writeMovie(fileP);
fclose(fileP);
TSystem::showDocument(m_fp);
//QDesktopServices::openUrl(QUrl(toQString(m_fp)));
TImageCache::instance()->remove(toString(m_fp.getWideString() + L".0"));
TNotifier::instance()->notify(TSceneNameChange());
}
void TRop::brush(
TRaster32P ras,
const TPoint &aa,
const TPoint &bb,
int radius,
const TPixel32 &col)
{
TPoint a = aa;
TPoint b = bb;
if (a.y > b.y)
tswap(a, b); // a e' piu' in basso di b
int lx = ras->getLx();
int ly = ras->getLy();
ras->lock();
// ----- radius = 0
if (radius == 0) {
// k = +1/-1 se il rettangolo e' inclinato positivamente (0<=m)/negativamente (m<0)
// (se k<0 viene fatta una riflessione sulle ascisse prima di tornare alle
// coordinate "di schermo")
int k = 1;
int dy = b.y - a.y;
int dx = b.x - a.x;
if (dx < 0) {
dx = -dx;
k = -1;
}
assert(dx >= 0);
assert(dy >= 0);
double m; // m sara' definita solo per dx!=0)
if (dx > 0) {
m = dy / (double)dx;
}
//double length = sqrt(dx*dx + dy*dy);
const int alpha = dy, beta = -dx;
const int incE = alpha;
const int incNE = alpha + beta;
const int incN = beta;
// N.B. le coordinate sono relative ad un sist. di rif. con l'origine in a
// l'eq. della retta e' alpha * x + beta * y = 0
int yMin = tmax(a.y, 0) - a.y; // clipping y + cambio riferimento
int yMax = tmin(b.y, ly - 1) - a.y; // (trasporto dell'origine in a)
if (dx > 0 && m <= 1) {
// midpoint algorithm
TPoint segm;
if (dy == 0) // segmento orizzontale: inizializza segm
{
segm.x = 0;
segm.y = yMin;
} else // 0<m<=1 : inizializza segm
{
segm.x = tceil((yMin - 0.5) / m);
segm.y = yMin;
}
int dSegm = tfloor(alpha * (segm.x + 1) + beta * (segm.y + 0.5));
while (segm.y <= yMax) {
int count = 0; // i trati orizzontali di segm vengono disegnati in "blocco"
while (dSegm < 0 && segm.x <= dx) // Est: segm.x<=dx evita il ciclo
{ // infinito quando m=0 (incE=0)
dSegm = dSegm + incE;
segm.x++;
count++;
}
// NordEst
int xMin, xMax;
if (k > 0) {
xMin = tmax(a.x + segm.x - count, a.x, 0); // clipping x + ritorno alle
xMax = tmin(a.x + segm.x, b.x, lx - 1); // coordinate "di schermo"
} else {
xMin = tmax(a.x - segm.x, a.x - dx, 0); // clipping x + riflessione + ritorno
xMax = tmin(a.x - segm.x + count, a.x, lx - 1); // alle coordinate "di schermo"
}
TPixel32 *p = ras->pixels(segm.y + a.y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
dSegm = dSegm + incNE;
segm.x++;
segm.y++;
}
} else // m>1 oppure segmento verticale
{
// midpoint algorithm
TPoint segm;
if (dx == 0) // segmento verticale: inizializza segm
{
segm.x = 0;
segm.y = yMin;
} else // m>1 : inizializza segm
{
segm.x = tround(yMin / m);
segm.y = yMin;
}
int dSegm = tfloor(alpha * (segm.x + 0.5) + beta * (segm.y + 1));
while (segm.y <= yMax) {
int xMin, xMax;
if (k > 0) {
xMin = tmax(a.x + segm.x, 0); // clipping x + ritorno alle
xMax = tmin(a.x + segm.x, lx - 1); // coordinate "di schermo"
} else {
xMin = tmax(a.x - segm.x, 0); // clipping x + riflessione + ritorno
xMax = tmin(a.x - segm.x, lx - 1); // alle coordinate "di schermo"
}
TPixel32 *p = ras->pixels(segm.y + a.y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
if (dSegm <= 0) // NordEst
{
dSegm = dSegm + incNE;
segm.x++;
} else // Nord
{
dSegm = dSegm + incN;
}
segm.y++;
}
}
ras->unlock();
return;
}
HalfCord halfCord(radius);
int x, y;
// ----- punti iniziali coincidenti: disegna un cerchio
if (a == b) {
int yMin = tmax(a.y - radius, 0); // clipping y
int yMax = tmin(a.y + radius, ly - 1); // clipping y
for (y = yMin; y <= yMax; y++) {
int deltay = abs(y - a.y);
int xMin = tmax(a.x - halfCord.getCord(deltay), 0); // clipping x
int xMax = tmin(a.x + halfCord.getCord(deltay), lx - 1); // clipping x
TPixel32 *p = ras->pixels(y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
}
ras->unlock();
return;
}
// ----- rettangolo orizzontale (a.y = b.y, a.x != b.x)
if (a.y == b.y) {
int yMin = tmax((a.y - radius), 0); // clipping y
int yMax = tmin((a.y + radius), ly - 1); // clipping y
int xLeft = tmin(a.x, b.x);
int xRight = tmax(a.x, b.x);
for (y = yMin; y <= yMax; y++) {
int deltay = abs(y - a.y);
int xMin = tmax(xLeft - halfCord.getCord(deltay), 0); // clipping x
int xMax = tmin(xRight + halfCord.getCord(deltay), lx - 1); // clipping x
TPixel32 *p = ras->pixels(y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
}
ras->unlock();
return;
}
// ----- rettangolo verticale (a.x = b.x, a.y != b.y)
if (a.x == b.x) {
int xMin = tmax(a.x - radius, 0); // clipping x
int xMax = tmin(a.x + radius, lx - 1); // clipping x
for (x = xMin; x <= xMax; x++) {
int deltax = abs(x - a.x);
int yMin = tmax(a.y - halfCord.getCord(deltax), 0); // clipping y
int yMax = tmin(b.y + halfCord.getCord(deltax), ly - 1); // clipping y
if (yMin <= yMax) {
TPixel32 *p = ras->pixels(yMin) + x;
TPixel32 *q = ras->pixels(yMax) + x;
int wrap = ras->getWrap();
while (p <= q) {
*p = col;
p += wrap;
}
}
}
ras->unlock();
return;
}
// ----- rettangolo inclinato
// k = +1/-1 se il rettangolo e' inclinato positivamente/negativamente
int k = 1;
int dx = b.x - a.x;
if (dx < 0) {
dx = -dx;
k = -1;
}
int dy = b.y - a.y;
assert(dx > 0);
assert(dy > 0);
double length = sqrt((double)(dx * dx + dy * dy));
const double m = dy / (double)dx;
//punto di tangenza superiore nel sistema di riferimento del cerchio
TPointD up(-radius * dy / length, radius * dx / length);
//semi-ampiezza orizzontale delle "calotte" circolari
int halfAmplCap = tfloor(-up.x);
// A meno di intersezioni relative tra le diverse zone:
// le scanline della "calotta" circolare superiore sono (b.y+cutExt,b.y+radius]
// le scanline del trapezoide circolare superiore sono [b.y-cutIn,b.y+cutExt]
// le scanline del parallelogramma sono (a.y+cutIn,b.y-cutIn)
// le scanline del trapezoide circolare inferiore sono [a.y-cutExt,a.y+cutIn]
// le scanline della "calotta" circolare inferiore sono [a.y-radius,a.y-cutExt)
int cutExt, cutIn;
// vertici del parallelogramma
TPointD rightUp;
TPointD rightDown;
TPointD leftUp;
TPointD leftDown;
double mParall; //coeff. angolare parallelogramma
// NOTA BENE: halfAmplCap=0 <=> (radius=0 (caso a parte) , 1)
if (radius > 1) {
for (cutExt = radius; cutExt >= 0 && halfCord.getCord(cutExt) <= halfAmplCap; cutExt--)
;
cutIn = cutExt; // vedi else successivo
rightUp.x = dx + halfCord.getCord(cutIn);
rightUp.y = dy - cutIn;
rightDown.x = halfCord.getCord(cutIn);
rightDown.y = -cutIn;
leftUp.x = dx - halfCord.getCord(cutIn);
leftUp.y = dy + cutIn;
leftDown.x = -halfCord.getCord(cutIn);
leftDown.y = cutIn;
mParall = dy / (double)dx;
} else // N.B. cutExt != cutIn solo quando radius=1
{
cutExt = radius; // radius=1 => halfAmplCap=0 (non ci sono mai le "calotte" circolari)
cutIn = 0; // anche per radius=1 il limite "interno" dei trapezoidi circolari e' < radius
rightUp.x = dx - up.x;
rightUp.y = dy - up.y;
rightDown.x = -up.x;
rightDown.y = -up.y;
leftUp.x = dx + up.x;
leftUp.y = dy + up.y;
leftDown.x = up.x;
leftDown.y = up.y;
mParall = m;
}
// ----- riempie "calotte" circolari
// ----- riempie "calotta" circolare inferiore
int yMin = tmax(a.y - radius, 0); // clipping y
int yMax = tmin(a.y - cutExt - 1, ly - 1); // clipping y
for (y = yMin; y <= yMax; y++) {
int r = halfCord.getCord(a.y - y);
int xMin = tmax(a.x - r, 0); // clipping x
int xMax = tmin(a.x + r, lx - 1); // clipping x
TPixel32 *p = ras->pixels(y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
}
// ----- riempie "calotta" circolare superiore
yMin = tmax(b.y + cutExt + 1, 0); // clipping y
yMax = tmin(b.y + radius, ly - 1); // clipping y
for (y = yMin; y <= yMax; y++) {
int r = halfCord.getCord(y - b.y);
int xMin = tmax(b.x - r, 0); // clipping x
int xMax = tmin(b.x + r, lx - 1); // clipping x
TPixel32 *p = ras->pixels(y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
}
// ----- riempie trapezoidi
// (se k<0 viene fatta una riflessione sulle ascisse prima di tornare alle
// coordinate "di schermo")
// limite destro assoluto delle scanline trapezoide:
int xSegmMax = tround(dx - up.x); // coordinata x del punto di tangenza inferiore sul cerchio superiore
// limite sinistro assoluto delle scanline:
int xSegmMin = tround(up.x); // coordinata x del punto di tangenza superiore sul cerchio inferiore
// ----- riempie trapezoide inferiore
// N.B. le coordinate sono relative ad un sist. di rif. con l'origine sul centro
// del cerchio inferiore
yMin = tmax(a.y - cutExt, 0) - a.y; // clipping y
yMax = tmin(a.y + cutIn, b.y - cutIn - 1, ly - 1) - a.y; // clipping y
// l'eq. della retta e' alpha * x + beta * y + gammaRight = 0
const int alpha = dy, beta = -dx;
const double gammaRight = rightDown.y * dx - rightDown.x * dy;
const int incE = alpha;
const int incNE = alpha + beta;
const int incN = beta;
if (m <= 1) {
// midpoint algorithm; le scanline vengono disegnate solo
// sul NordEst. L'ultima scanline non viene disegnata
TPoint segmRight(tceil((yMin + 0.5 - rightDown.y) / mParall + rightDown.x) - 1, yMin);
int dSegmRight = tfloor(alpha * (segmRight.x + 1) + beta * (segmRight.y + 0.5) + gammaRight);
while (segmRight.y <= yMax) {
if (dSegmRight < 0) // Est
{
dSegmRight = dSegmRight + incE;
segmRight.x++;
} else // NordEst
{
int xMin, xMax;
if (k > 0) {
xMin = tmax(a.x - halfCord.getCord(abs(segmRight.y)), 0); // clipping x
xMax = tmin(a.x + tmin(segmRight.x, xSegmMax), lx - 1); // clipping x
} else {
xMin = tmax(a.x - tmin(segmRight.x, xSegmMax), 0); // clipping x + ritorno alle
xMax = tmin(a.x + halfCord.getCord(abs(segmRight.y)), lx - 1); // coordinate "di schermo"
}
TPixel32 *p = ras->pixels(segmRight.y + a.y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
dSegmRight = dSegmRight + incNE;
segmRight.x++;
segmRight.y++;
}
}
} else // m>1
{
// midpoint algorithm; le scanline vengono disegnate sempre
TPoint segmRight(tround((yMin - rightDown.y) / mParall + rightDown.x), yMin);
int dSegmRight = tfloor(alpha * (segmRight.x + 0.5) + beta * (segmRight.y + 1) + gammaRight);
while (segmRight.y <= yMax) {
int xMin, xMax;
if (k > 0) {
xMin = tmax(a.x - halfCord.getCord(abs(segmRight.y)), 0); // clipping x
xMax = tmin(a.x + segmRight.x, lx - 1); // clipping x
} else {
xMin = tmax(a.x - segmRight.x, 0); // clipping x + ritorno alle coordinate
xMax = tmin(a.x + halfCord.getCord(abs(segmRight.y)), lx - 1); // "di schermo"
}
TPixel32 *p = ras->pixels(segmRight.y + a.y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
if (dSegmRight <= 0) // NordEst
{
dSegmRight = dSegmRight + incNE;
segmRight.x++;
} else // Nord
{
dSegmRight = dSegmRight + incN;
}
segmRight.y++;
}
}
// ----- riempie trapezoide superiore
// N.B. le coordinate sono relative ad un sist. di rif. con l'origine sul centro
// del cerchio superiore
yMin = tmax(b.y - cutIn, a.y + cutIn + 1, 0) - b.y; // clipping y
yMax = tmin(b.y + cutExt, ly - 1) - b.y; // clipping y
// l'eq. della retta e' alpha * x + beta * y + gammaLeft = 0
const double gammaLeft = leftDown.y * dx - leftDown.x * dy;
if (m <= 1) {
// midpoint algorithm; le scanline vengono disegnate solo
// sul NordEst. L'ultima scanline non viene disegnata
TPoint segmLeft(tceil((yMin - 0.5 - leftDown.y) / mParall + leftDown.x), yMin);
int dSegmLeft = tfloor(alpha * (segmLeft.x + 1) + beta * (segmLeft.y + 0.5) + gammaLeft);
while (segmLeft.y <= yMax) {
int xMin, xMax;
if (k > 0) {
xMin = tmax(b.x + tmax(segmLeft.x, xSegmMin - dx), 0); // clipping x
xMax = tmin(b.x + halfCord.getCord(abs(segmLeft.y)), lx - 1); // clipping x
} else {
xMin = tmax(b.x - halfCord.getCord(abs(segmLeft.y)), 0); // clipping x + ritorno alle
xMax = tmin(b.x - tmax(segmLeft.x, xSegmMin - dx), lx - 1); // coordinate "di schermo"
}
TPixel32 *p = ras->pixels(segmLeft.y + b.y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
while (dSegmLeft < 0) {
dSegmLeft = dSegmLeft + incE;
segmLeft.x++;
}
dSegmLeft = dSegmLeft + incNE;
segmLeft.x++;
segmLeft.y++;
}
} else // m>1
{
// midpoint algorithm; le scanline vengono disegnate sempre
TPoint segmLeft(tround((yMin - leftDown.y) / mParall + leftDown.x), yMin);
int dSegmLeft = tfloor(alpha * (segmLeft.x + 0.5) + beta * (segmLeft.y + 1) + gammaLeft);
while (segmLeft.y <= yMax) {
int xMin, xMax;
if (k > 0) {
xMin = tmax(b.x + segmLeft.x, 0); // clipping x
xMax = tmin(b.x + halfCord.getCord(abs(segmLeft.y)), lx - 1); // clipping x
} else {
xMin = tmax(b.x - halfCord.getCord(abs(segmLeft.y)), 0); // clipping x + ritorno alle
xMax = tmin(b.x - segmLeft.x, lx - 1); // coordinate "di schermo"
}
TPixel32 *p = ras->pixels(segmLeft.y + b.y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
if (dSegmLeft <= 0) // NordEst
{
dSegmLeft = dSegmLeft + incNE;
segmLeft.x++;
} else // Nord
{
dSegmLeft = dSegmLeft + incN;
}
segmLeft.y++;
}
}
// ----- parallelogramma (in alternativa a "parallelogrammoide circolare")
// N.B. le coordinate sono relative ad un sist. di rif. con l'origine sul centro
// del cerchio inferiore
// retta destra di equaz. alpha * x + beta * y + gammaRight = 0
// retta sinistra di equaz. alpha * x + beta * y + gammaLeft = 0
yMin = tmax(a.y + cutIn + 1, 0) - a.y; //clipping y
yMax = tmin(b.y - cutIn - 1, ly - 1) - a.y; //clipping y
if (m <= 1) {
// midpoint algorithm; le scanline vengono disegnate solo
// sul NordEst. L'ultima scanline non viene disegnata
TPoint segmRight(tceil((yMin + 0.5 - rightDown.y) / mParall + rightDown.x) - 1, yMin);
TPoint segmLeft = TPoint(tceil((yMin - 0.5 - leftDown.y) / mParall + leftDown.x), yMin);
int dSegmRight = tfloor(alpha * (segmRight.x + 1) + beta * (segmRight.y + 0.5) + gammaRight);
int dSegmLeft = tfloor(alpha * (segmLeft.x + 1) + beta * (segmLeft.y + 0.5) + gammaLeft);
while (segmRight.y <= yMax) {
if (dSegmRight < 0) // segmRight a Est
{
dSegmRight = dSegmRight + incE;
segmRight.x++;
} else // segmRight a NordEst
{
int xMin, xMax;
if (k > 0) {
xMin = tmax(a.x + tmax(segmLeft.x, xSegmMin), 0); // clipping x
xMax = tmin(a.x + tmin(segmRight.x, xSegmMax), lx - 1); // clipping x
} else {
xMin = tmax(a.x - tmin(segmRight.x, xSegmMax), 0); // clipping x + ritorno alle
xMax = tmin(a.x - tmax(segmLeft.x, xSegmMin), lx - 1); // coordinate "di schermo"
}
TPixel32 *p = ras->pixels(segmRight.y + a.y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
dSegmRight = dSegmRight + incNE;
segmRight.x++;
segmRight.y++;
while (dSegmLeft < 0) // segmLeft a Est
{
dSegmLeft = dSegmLeft + incE;
segmLeft.x++;
}
// segmLeft a NordEst
dSegmLeft = dSegmLeft + incNE;
segmLeft.x++;
segmLeft.y++;
}
}
} else // m>1
{
// midpoint algorithm; le scanline vengono disegnate sempre
TPoint segmRight(tround((yMin - rightDown.y) / mParall + rightDown.x), yMin);
TPoint segmLeft(tround((yMin - leftDown.y) / mParall + leftDown.x), yMin);
int dSegmRight = tfloor(alpha * (segmRight.x + 0.5) + beta * (segmRight.y + 1) + gammaRight);
int dSegmLeft = tfloor(alpha * (segmLeft.x + 0.5) + beta * (segmLeft.y + 1) + gammaLeft);
while (segmRight.y <= yMax) {
int xMin, xMax;
if (k > 0) {
xMin = tmax(a.x + segmLeft.x, 0); // clipping x
xMax = tmin(a.x + segmRight.x, lx - 1); // clipping x
} else {
xMin = tmax(a.x - segmRight.x, 0); // clipping x + ritorno alle
xMax = tmin(a.x - segmLeft.x, lx - 1); // coordinate "di schermo"
}
TPixel32 *p = ras->pixels(segmRight.y + a.y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
if (dSegmRight <= 0) // segmRight a NordEst
{
dSegmRight = dSegmRight + incNE;
segmRight.x++;
} else // segmRight a Nord
{
dSegmRight = dSegmRight + incN;
}
segmRight.y++;
if (dSegmLeft <= 0) // segmLeft a NordEst
{
dSegmLeft = dSegmLeft + incNE;
segmLeft.x++;
} else // segmLeft a Nord
{
dSegmLeft = dSegmLeft + incN;
}
}
}
// ---- parallelogrammoide circolare (in alternativa a parallelogramma)
// N.B. coordinate di schermo (riflessione per k<0 )
yMin = tmax(b.y - cutIn, 0);
yMax = tmin(a.y + cutIn, ly - 1);
for (y = yMin; y <= yMax; y++) {
int xMin, xMax;
if (k > 0) {
xMin = tmax(a.x - halfCord.getCord(abs(y - a.y)), 0); // clipping x
xMax = tmin(b.x + halfCord.getCord(abs(b.y - y)), lx - 1); // clipping x
} else {
xMin = tmax(b.x - halfCord.getCord(abs(b.y - y)), 0); // clipping x + ritorno alle
xMax = tmin(a.x + halfCord.getCord(abs(y - a.y)), lx - 1); // coordinate "di schermo"
}
TPixel32 *p = ras->pixels(y) + xMin;
TPixel32 *q = p + (xMax - xMin);
while (p <= q)
*p++ = col;
}
ras->unlock();
}
void ImageViewer::paintGL() {
if (m_lutCalibrator && m_lutCalibrator->isValid()) m_fbo->bind();
TDimension viewerSize(width(), height());
TAffine aff = m_viewAff;
// if (!m_visualSettings.m_defineLoadbox && m_flipbook &&
// m_flipbook->getLoadbox()!=TRect())
// offs =
// convert(m_flipbook->getLoadbox().getP00())-TPointD(m_flipbook->getImageSize().lx/2.0,
// m_flipbook->getImageSize().ly/2.0);
TDimension imageSize;
TRect loadbox;
if (m_flipbook) {
QString title =
(!m_image)
? m_flipbook->getTitle() + tr(" :: Zoom : ") +
QString::number(tround(sqrt(m_viewAff.det()) * 100)) + " %"
: m_flipbook->getLevelZoomTitle() + tr(" :: Zoom : ") +
QString::number(tround(sqrt(m_viewAff.det()) * 100)) + " %";
m_flipbook->parentWidget()->setWindowTitle(title);
imageSize = m_flipbook->getImageSize();
if (m_visualSettings.m_useLoadbox && m_flipbook->getLoadbox() != TRect())
loadbox = m_flipbook->getLoadbox();
}
m_visualSettings.m_sceneProperties =
TApp::instance()->getCurrentScene()->getScene()->getProperties();
// enable checks only in the color model
m_visualSettings.m_useChecks = m_isColorModel;
ImagePainter::paintImage(m_image, imageSize, viewerSize, aff,
m_visualSettings, m_compareSettings, loadbox);
// when fx parameter is modified with showing the fx preview,
// a flipbook shows a red border line before the rendered result is shown.
if (m_isRemakingPreviewFx) {
glPushMatrix();
glLoadIdentity();
glColor3d(1.0, 0.0, 0.0);
glBegin(GL_LINE_LOOP);
glVertex2d(5, 5);
glVertex2d(5, height() - 5);
glVertex2d(width() - 5, height() - 5);
glVertex2d(width() - 5, 5);
glEnd();
glBegin(GL_LINE_LOOP);
glVertex2d(10, 10);
glVertex2d(10, height() - 10);
glVertex2d(width() - 10, height() - 10);
glVertex2d(width() - 10, 10);
glEnd();
glPopMatrix();
}
if (!m_image) {
if (m_lutCalibrator && m_lutCalibrator->isValid())
m_lutCalibrator->onEndDraw(m_fbo);
return;
}
if (safeAreaToggle.getStatus() && !m_isColorModel) {
TRasterImageP rimg = (TRasterImageP)m_image;
TVectorImageP vimg = (TVectorImageP)m_image;
TToonzImageP timg = (TToonzImageP)m_image;
TRect bbox;
TPointD centerD;
TRect bounds;
if (rimg) {
centerD = rimg->getRaster()->getCenterD();
bounds = rimg->getRaster()->getBounds();
} else if (timg) {
centerD = timg->getRaster()->getCenterD();
bounds = timg->getRaster()->getBounds();
}
if (!vimg) {
TAffine aff = TTranslation(viewerSize.lx * 0.5, viewerSize.ly * 0.5) *
m_viewAff * TTranslation(-centerD);
TRectD bbox = aff * TRectD(0, 0, bounds.getLx() - 1, bounds.getLy() - 1);
drawSafeArea(bbox);
}
}
TPoint fromPos, toPos;
if (m_visualSettings.m_defineLoadbox && m_flipbook) {
TRect loadbox =
convert(getImgToWidgetAffine() * convert(m_flipbook->getLoadbox()));
if (loadbox != TRect()) {
TPoint p00 = loadbox.getP00();
TPoint p11 = loadbox.getP11();
fromPos =
TPoint(p00.x - width() * 0.5,
height() * 0.5 - p00.y); // m_flipbook->getLoadbox().getP00();
toPos =
TPoint(p11.x - width() * 0.5,
height() * 0.5 - p11.y); // m_flipbook->getLoadbox().getP11();
}
} else if (m_draggingZoomSelection || m_rectRGBPick) {
fromPos = TPoint(m_pressedMousePos.x - width() * 0.5,
height() * 0.5 - m_pressedMousePos.y);
toPos = TPoint(m_pos.x() - width() * 0.5, height() * 0.5 - m_pos.y());
}
if (fromPos != TPoint() || toPos != TPoint()) {
if (m_rectRGBPick) {
tglColor(TPixel32::Red);
// TODO: glLineStipple is deprecated in the latest OpenGL. Need to be
// replaced. (shun_iwasawa 2015/12/25)
glLineStipple(1, 0x3F33);
glEnable(GL_LINE_STIPPLE);
glBegin(GL_LINE_STRIP);
// do not draw the rect around the mouse cursor
int margin = (fromPos.y < toPos.y) ? -3 : 3;
glVertex2i(toPos.x, toPos.y + margin);
glVertex2i(toPos.x, fromPos.y);
glVertex2i(fromPos.x, fromPos.y);
glVertex2i(fromPos.x, toPos.y);
margin = (fromPos.x < toPos.x) ? -3 : 3;
glVertex2i(toPos.x + margin, toPos.y);
glEnd();
glDisable(GL_LINE_STIPPLE);
} else {
tglColor(m_draggingZoomSelection ? TPixel32::Red : TPixel32::Blue);
glBegin(GL_LINE_STRIP);
glVertex2i(fromPos.x, fromPos.y);
glVertex2i(fromPos.x, toPos.y);
glVertex2i(toPos.x, toPos.y);
glVertex2i(toPos.x, fromPos.y);
glVertex2i(fromPos.x, fromPos.y);
glEnd();
}
}
if (m_lutCalibrator && m_lutCalibrator->isValid())
m_lutCalibrator->onEndDraw(m_fbo);
}
void doCompute(TTile &tile, double frame,
const TRenderSettings &ri) override {
Status status = getFxStatus(m_light, m_lighted);
if (status & NoPortsConnected)
// If no port, just do nothing :)
return;
// Calculate source
if (status & Port1Connected) m_lighted->compute(tile, frame, ri);
// Calculate light
if (status & Port0Connected) {
// Init light infos
TDimension tileSize(tile.getRaster()->getSize());
TRectD tileRect(tile.m_pos, TDimensionD(tileSize.lx, tileSize.ly));
double scale = sqrt(fabs(ri.m_affine.det()));
double blur = m_value->getValue(frame) * scale;
// Build the light interesting rect
TRectD lightRect, blurOutRect;
m_light->getBBox(frame, lightRect, ri);
buildLightRects(tileRect, lightRect, blurOutRect, blur);
if ((lightRect.getLx() <= 0) || (lightRect.getLy() <= 0)) return;
if ((blurOutRect.getLx() <= 0) || (blurOutRect.getLy() <= 0)) return;
// Calculate the light tile
TTile lightTile;
TDimension lightSize(tround(lightRect.getLx()),
tround(lightRect.getLy()));
m_light->allocateAndCompute(lightTile, lightRect.getP00(), lightSize,
tile.getRaster(), frame, ri);
// Init glow parameters
TPixel32 color = m_color->getValue(frame);
double brightness = m_brightness->getValue(frame) / 100.0;
double fade = m_fade->getValue(frame) / 100.0;
// Now, apply the glow
// First, deal with the fade
{
TRasterP light = lightTile.getRaster();
TRaster32P light32 = light;
TRaster64P light64 = light;
if (light32)
::fade(light32, fade, color);
else if (light64)
::fade(light64, fade, toPixel64(color));
else
assert(false);
}
// Then, build the blur
TRasterP blurOut;
if (blur > 0) {
// Build a temporary output to the blur
{
TRasterP light(lightTile.getRaster());
blurOut = light->create(tround(blurOutRect.getLx()),
tround(blurOutRect.getLy()));
// Apply the blur. Please note that SSE2 should not be used for now -
// I've seen it
// doing strange things to the blur...
TPointD displacement(lightRect.getP00() - blurOutRect.getP00());
TRop::blur(blurOut, light, blur, tround(displacement.x),
tround(displacement.y), false);
}
} else
blurOut = lightTile.getRaster();
// Apply the rgbm scale
TRop::rgbmScale(blurOut, blurOut, 1, 1, 1, brightness);
// Apply the add
{
TRectD interestingRect(tileRect * blurOutRect);
TRect interestingTileRect(tround(interestingRect.x0 - tileRect.x0),
tround(interestingRect.y0 - tileRect.y0),
tround(interestingRect.x1 - tileRect.x0) - 1,
tround(interestingRect.y1 - tileRect.y0) - 1);
TRect interestingBlurRect(
tround(interestingRect.x0 - blurOutRect.x0),
tround(interestingRect.y0 - blurOutRect.y0),
tround(interestingRect.x1 - blurOutRect.x0) - 1,
tround(interestingRect.y1 - blurOutRect.y0) - 1);
if ((interestingTileRect.getLx() <= 0) ||
(interestingTileRect.getLy() <= 0))
return;
if ((interestingBlurRect.getLx() <= 0) ||
(interestingBlurRect.getLy() <= 0))
return;
TRasterP tileInterestRas(
tile.getRaster()->extract(interestingTileRect));
TRasterP blurInterestRas(blurOut->extract(interestingBlurRect));
TRop::add(blurInterestRas, tileInterestRas, tileInterestRas);
}
}
}
