/// compute interpolation parameters from keyframes and an iterator
/// to the next keyframe (the first with time > t)
static void
interParams(const KeyFrameSet &keyFrames,
double t,
const KeyFrameSet::const_iterator &itup,
double *tcur,
double *vcur,
double *vcurDerivRight,
Natron::KeyframeType *interp,
double *tnext,
double *vnext,
double *vnextDerivLeft,
Natron::KeyframeType *interpNext)
{
assert(itup == keyFrames.end() || t < itup->getTime());
if (itup == keyFrames.begin()) {
//if all keys have a greater time
// get the first keyframe
*tnext = itup->getTime();
*vnext = itup->getValue();
*vnextDerivLeft = itup->getLeftDerivative();
*interpNext = itup->getInterpolation();
*tcur = *tnext - 1.;
*vcur = *vnext;
*vcurDerivRight = 0.;
*interp = Natron::KEYFRAME_NONE;
} else if (itup == keyFrames.end()) {
//if we found no key that has a greater time
// get the last keyframe
KeyFrameSet::const_reverse_iterator itlast = keyFrames.rbegin();
*tcur = itlast->getTime();
*vcur = itlast->getValue();
*vcurDerivRight = itlast->getRightDerivative();
*interp = itlast->getInterpolation();
*tnext = *tcur + 1.;
*vnext = *vcur;
*vnextDerivLeft = 0.;
*interpNext = Natron::KEYFRAME_NONE;
} else {
// between two keyframes
// get the last keyframe with time <= t
KeyFrameSet::const_iterator itcur = itup;
--itcur;
assert(itcur->getTime() <= t);
*tcur = itcur->getTime();
*vcur = itcur->getValue();
*vcurDerivRight = itcur->getRightDerivative();
*interp = itcur->getInterpolation();
*tnext = itup->getTime();
*vnext = itup->getValue();
*vnextDerivLeft = itup->getLeftDerivative();
*interpNext = itup->getInterpolation();
}
}
KeyFrameSet::iterator Curve::refreshDerivatives(Curve::CurveChangedReason reason, KeyFrameSet::iterator key)
{
// PRIVATE - should not lock
double tcur = key->getTime();
double vcur = key->getValue();
double tprev, vprev, tnext, vnext, vprevDerivRight, vnextDerivLeft;
Natron::KeyframeType prevType, nextType;
if (key == _imp->keyFrames.begin()) {
tprev = tcur;
vprev = vcur;
vprevDerivRight = 0.;
prevType = Natron::KEYFRAME_NONE;
} else {
KeyFrameSet::const_iterator prev = key;
--prev;
tprev = prev->getTime();
vprev = prev->getValue();
vprevDerivRight = prev->getRightDerivative();
prevType = prev->getInterpolation();
//if prev is the first keyframe, and not edited by the user then interpolate linearly
if (prev == _imp->keyFrames.begin() && prevType != Natron::KEYFRAME_FREE &&
prevType != Natron::KEYFRAME_BROKEN) {
prevType = Natron::KEYFRAME_LINEAR;
}
}
KeyFrameSet::const_iterator next = key;
++next;
if (next == _imp->keyFrames.end()) {
tnext = tcur;
vnext = vcur;
vnextDerivLeft = 0.;
nextType = Natron::KEYFRAME_NONE;
} else {
tnext = next->getTime();
vnext = next->getValue();
vnextDerivLeft = next->getLeftDerivative();
nextType = next->getInterpolation();
KeyFrameSet::const_iterator nextnext = next;
++nextnext;
//if next is thelast keyframe, and not edited by the user then interpolate linearly
if (nextnext == _imp->keyFrames.end() && nextType != Natron::KEYFRAME_FREE &&
nextType != Natron::KEYFRAME_BROKEN) {
nextType = Natron::KEYFRAME_LINEAR;
}
}
double vcurDerivLeft,vcurDerivRight;
assert(key->getInterpolation() != Natron::KEYFRAME_NONE &&
key->getInterpolation() != Natron::KEYFRAME_BROKEN &&
key->getInterpolation() != Natron::KEYFRAME_FREE);
Natron::autoComputeDerivatives(prevType,
key->getInterpolation(),
nextType,
tprev, vprev,
tcur, vcur,
tnext, vnext,
vprevDerivRight,
vnextDerivLeft,
&vcurDerivLeft, &vcurDerivRight);
KeyFrame newKey(*key);
newKey.setLeftDerivative(vcurDerivLeft);
newKey.setRightDerivative(vcurDerivRight);
std::pair<KeyFrameSet::iterator,bool> newKeyIt = _imp->keyFrames.insert(newKey);
// keyframe at this time exists, erase and insert again
if (!newKeyIt.second) {
_imp->keyFrames.erase(newKeyIt.first);
newKeyIt = _imp->keyFrames.insert(newKey);
assert(newKeyIt.second);
}
key = newKeyIt.first;
if (reason != DERIVATIVES_CHANGED) {
key = evaluateCurveChanged(DERIVATIVES_CHANGED,key);
}
return key;
}
void
CurveGui::nextPointForSegment(const double x, // < in curve coordinates
const KeyFrameSet & keys,
const bool isPeriodic,
const double parametricXMin,
const double parametricXMax,
KeyFrameSet::const_iterator* lastUpperIt,
double* x2WidgetCoords,
KeyFrame* x1Key,
bool* isx1Key)
{
// always running in the main thread
assert( qApp && qApp->thread() == QThread::currentThread() );
assert( !keys.empty() );
*isx1Key = false;
// If non periodic and out of curve range, draw straight lines from widget border to
// the keyframe on the side
if (!isPeriodic && x < keys.begin()->getTime()) {
*x2WidgetCoords = keys.begin()->getTime();
double y;
_imp->curveWidget->toWidgetCoordinates(x2WidgetCoords, &y);
*x1Key = *keys.begin();
*isx1Key = true;
return;
} else if (!isPeriodic && x >= keys.rbegin()->getTime()) {
*x2WidgetCoords = _imp->curveWidget->width() - 1;
return;
}
// We're between 2 keyframes or the curve is periodic, get the upper and lower keyframes widget coordinates
// Points to the first keyframe with a greater time (in widget coords) than x1
KeyFrameSet::const_iterator upperIt = keys.end();
// If periodic, bring back x in the period range (in widget coordinates)
double xClamped = x;
double period = parametricXMax - parametricXMin;
{
//KeyFrameSet::const_iterator start = keys.begin();
const double xMin = parametricXMin;// + start->getTime();
const double xMax = parametricXMax;// + start->getTime();
if ((x < xMin || x > xMax) && isPeriodic) {
xClamped = std::fmod(x - xMin, period) + parametricXMin;
if (xClamped < xMin) {
xClamped += period;
}
assert(xClamped >= xMin && xClamped <= xMax);
}
}
{
KeyFrameSet::const_iterator itKeys = keys.begin();
if ( *lastUpperIt != keys.end() ) {
// If we already have called this function before, start from the previously
// computed iterator to avoid n square complexity
itKeys = *lastUpperIt;
} else {
// Otherwise start from the begining
itKeys = keys.begin();
}
*lastUpperIt = keys.end();
for (; itKeys != keys.end(); ++itKeys) {
if (itKeys->getTime() > xClamped) {
upperIt = itKeys;
*lastUpperIt = upperIt;
break;
}
}
}
double tprev, vprev, vprevDerivRight, tnext, vnext, vnextDerivLeft;
if ( upperIt == keys.end() ) {
// We are in a periodic curve: we are in-between the last keyframe and the parametric xMax
// If the curve is non periodic, it should have been handled in the 2 cases above: we only draw a straightline
// from the widget border to the first/last keyframe
assert(isPeriodic);
KeyFrameSet::const_iterator start = keys.begin();
KeyFrameSet::const_reverse_iterator last = keys.rbegin();
tprev = last->getTime();
vprev = last->getValue();
vprevDerivRight = last->getRightDerivative();
tnext = std::fmod(last->getTime() - start->getTime(), period) + tprev;
//xClamped += period;
vnext = start->getValue();
vnextDerivLeft = start->getLeftDerivative();
} else if ( upperIt == keys.begin() ) {
// We are in a periodic curve: we are in-between the parametric xMin and the first keyframe
// If the curve is non periodic, it should have been handled in the 2 cases above: we only draw a straightline
// from the widget border to the first/last keyframe
assert(isPeriodic);
KeyFrameSet::const_reverse_iterator last = keys.rbegin();
tprev = last->getTime();
//xClamped -= period;
vprev = last->getValue();
vprevDerivRight = last->getRightDerivative();
tnext = std::fmod(last->getTime() - upperIt->getTime(), period) + tprev;
vnext = upperIt->getValue();
vnextDerivLeft = upperIt->getLeftDerivative();
} else {
// in-between 2 keyframes
KeyFrameSet::const_iterator prev = upperIt;
--prev;
tprev = prev->getTime();
vprev = prev->getValue();
vprevDerivRight = prev->getRightDerivative();
tnext = upperIt->getTime();
vnext = upperIt->getValue();
vnextDerivLeft = upperIt->getLeftDerivative();
}
double normalizeTimeRange = tnext - tprev;
if (normalizeTimeRange == 0) {
// Only 1 keyframe, draw a horizontal line
*x2WidgetCoords = _imp->curveWidget->width() - 1;
return;
}
assert(normalizeTimeRange > 0.);
double t = ( xClamped - tprev ) / normalizeTimeRange;
double P3 = vnext;
double P0 = vprev;
// Hermite coefficients P0' and P3' are for t normalized in [0,1]
double P3pl = vnextDerivLeft / normalizeTimeRange; // normalize for t \in [0,1]
double P0pr = vprevDerivRight / normalizeTimeRange; // normalize for t \in [0,1]
double secondDer = 6. * (1. - t) * (P3 - P3pl / 3. - P0 - 2. * P0pr / 3.) +
6. * t * (P0 - P3 + 2 * P3pl / 3. + P0pr / 3. );
double secondDerWidgetCoord = _imp->curveWidget->toWidgetCoordinates(0, secondDer).y();
double normalizedSecondDerWidgetCoord = std::abs(secondDerWidgetCoord / normalizeTimeRange);
// compute delta_x so that the y difference between the derivative and the curve is at most
// 1 pixel (use the second order Taylor expansion of the function)
double delta_x = std::max(2. / std::max(std::sqrt(normalizedSecondDerWidgetCoord), 0.1), 1.);
// The x widget coordinate of the next keyframe
double tNextWidgetCoords = _imp->curveWidget->toWidgetCoordinates(tnext, 0).x();
// The widget coordinate of the x passed in parameter but clamped to the curve period
double xClampedWidgetCoords = _imp->curveWidget->toWidgetCoordinates(xClamped, 0).x();
// The real x passed in parameter in widget coordinates
double xWidgetCoords = _imp->curveWidget->toWidgetCoordinates(x, 0).x();
double x2ClampedWidgetCoords = xClampedWidgetCoords + delta_x;
double deltaXtoNext = (tNextWidgetCoords - xClampedWidgetCoords);
// If nearby next key, clamp to it
if (x2ClampedWidgetCoords > tNextWidgetCoords && deltaXtoNext > 1e-6) {
// x2 is the position of the next keyframe with the period removed
*x2WidgetCoords = xWidgetCoords + deltaXtoNext;
x1Key->setValue(vnext);
x1Key->setTime(x + (tnext - xClamped));
*isx1Key = true;
} else {
// just add the delta to the x widget coord
*x2WidgetCoords = xWidgetCoords + delta_x;
}
} // nextPointForSegment