454 lines
15 KiB
C++
454 lines
15 KiB
C++
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#include "stdfx.h"
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#include "tfxparam.h"
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#include "tpixelutils.h"
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#include "trop.h"
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#include "tparamset.h"
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//****************************************************************************
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// Local namespace stuff
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//****************************************************************************
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namespace
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{
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inline void pixelConvert(TPixel32 &dst, const TPixel32 &src) { dst = src; }
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inline void pixelConvert(TPixel64 &dst, const TPixel32 &src) { dst = toPixel64(src); }
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inline TRect gridAlign(const TRect &rect, TPoint origin, double step)
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{
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TRect result(rect);
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result -= origin;
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result.x0 = step * tfloor(result.x0 / step);
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result.y0 = step * tfloor(result.y0 / step);
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result.x1 = step * tceil((result.x1 + 1) / step) - 1;
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result.y1 = step * tceil((result.y1 + 1) / step) - 1;
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result += origin;
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return result;
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}
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inline TRectD gridAlign(const TRectD &rect, TPointD origin, double step)
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{
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TRectD result(rect);
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result -= origin;
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result.x0 = step * tfloor(result.x0 / step);
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result.y0 = step * tfloor(result.y0 / step);
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result.x1 = step * tceil(result.x1 / step);
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result.y1 = step * tceil(result.y1 / step);
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result += origin;
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return result;
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}
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}
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//****************************************************************************
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// Mosaic Namespace
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//****************************************************************************
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namespace mosaic
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{
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/*!
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The mosaic::CellBuilder class is the virtual base class used by MosaicFx
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to render a Mosaic cell with supplied colors.
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*/
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template <typename PIXEL>
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class CellBuilder
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{
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protected:
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int m_lx, m_ly;
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double m_radius;
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int m_wrap;
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public:
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CellBuilder(int cellLx, int cellLy, double radius, int wrap)
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: m_lx(cellLx), m_ly(cellLy), m_radius(radius), m_wrap(wrap) {}
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virtual ~CellBuilder() {}
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virtual void doCell(
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PIXEL *cellBuffer, const PIXEL &cellColor, const PIXEL &bgColor,
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int x0, int y0, int x1, int y1) = 0;
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};
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} //namespace mosaic
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//****************************************************************************
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// CellBuilder implementations
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//****************************************************************************
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namespace mosaic
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{
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template <typename PIXEL, typename GRAY>
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class MaskCellBuilder : public CellBuilder<PIXEL>
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{
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protected:
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TRasterPT<GRAY> m_mask;
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public:
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MaskCellBuilder(int cellLx, int cellLy, double radius, int wrap)
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: CellBuilder<PIXEL>(cellLx, cellLy, radius, wrap) {}
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void doCell(
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PIXEL *cellBuffer, const PIXEL &cellColor, const PIXEL &bgColor,
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int x0, int y0, int x1, int y1)
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{
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//Apply the mask to the cell. 0 pixels are bgColored, GRAY::maxChannelValue
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//ones are cellColored.
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PIXEL *pix, *line = cellBuffer, *lineEnd;
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GRAY *grPix, *grLine = m_mask->pixels(y0) + x0, *grLineEnd;
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int x, y, grWrap = m_mask->getWrap(), lx = x1 - x0;
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for (y = y0; y < y1; ++y, line += this->m_wrap, grLine += grWrap) {
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lineEnd = line + lx;
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grLineEnd = grLine + lx;
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for (x = x0, pix = line, grPix = grLine; x < x1; ++x, ++pix, ++grPix)
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*pix = blend(bgColor, cellColor, grPix->value / (double)GRAY::maxChannelValue);
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}
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}
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};
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template <typename PIXEL, typename GRAY>
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class SquareBuilder : public MaskCellBuilder<PIXEL, GRAY>
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{
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public:
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SquareBuilder(int cellLx, int cellLy, double radius, int wrap)
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: MaskCellBuilder<PIXEL, GRAY>(cellLx, cellLy, radius, wrap)
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{
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//Build the mask corresponding to a square of passed radius
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GRAY *pix, *pixRev, *line, *lineEnd, *lineRev;
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this->m_mask = TRasterPT<GRAY>(cellLx, cellLy);
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//For each pixel in the lower-left quadrant, fill in the corresponding mask value.
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//The other ones are filled by mirroring.
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int i, j;
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double lxHalf = 0.5 * cellLx, lyHalf = 0.5 * cellLy;
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int lxHalfI = tceil(lxHalf), lyHalfI = tceil(lyHalf);
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double val, addValX = radius - lxHalf + 1, addValY = radius - lyHalf + 1;
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for (i = 0; i < lyHalfI; ++i) {
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line = this->m_mask->pixels(i), lineRev = this->m_mask->pixels(cellLy - i - 1);
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lineEnd = line + cellLx;
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for (j = 0, pix = line, pixRev = lineEnd - 1; j < lxHalfI; ++j, ++pix, --pixRev) {
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val = tcrop(addValX + i, 0.0, 1.0) * tcrop(addValY + j, 0.0, 1.0);
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*pix = *pixRev = val * GRAY::maxChannelValue;
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}
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memcpy(lineRev, line, cellLx * sizeof(GRAY));
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}
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}
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};
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template <typename PIXEL, typename GRAY>
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class CircleBuilder : public MaskCellBuilder<PIXEL, GRAY>
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{
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public:
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CircleBuilder(int cellLx, int cellLy, double radius, int wrap)
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: MaskCellBuilder<PIXEL, GRAY>(cellLx, cellLy, radius, wrap)
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{
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//Build the mask corresponding to a square of passed radius
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GRAY *pix, *pixRev, *line, *lineEnd, *lineRev;
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this->m_mask = TRasterPT<GRAY>(cellLx, cellLy);
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//For each pixel in the lower-left quadrant, fill in the corresponding mask value.
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//The other ones are filled by mirroring.
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int i, j;
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double lxHalf = 0.5 * cellLx, lyHalf = 0.5 * cellLy;
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int lxHalfI = tceil(lxHalf), lyHalfI = tceil(lyHalf);
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double val, addValX = 0.5 - lxHalf, addValY = 0.5 - lyHalf;
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for (i = 0; i < lyHalfI; ++i) {
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line = this->m_mask->pixels(i), lineRev = this->m_mask->pixels(cellLy - i - 1);
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lineEnd = line + cellLx;
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for (j = 0, pix = line, pixRev = lineEnd - 1; j < lxHalfI; ++j, ++pix, --pixRev) {
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val = tcrop(radius - sqrt(sq(i + addValX) + sq(j + addValY)), 0.0, 1.0);
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*pix = *pixRev = val * GRAY::maxChannelValue;
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}
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memcpy(lineRev, line, cellLx * sizeof(GRAY));
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}
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}
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};
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} //namespace mosaic
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//****************************************************************************
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// Mosaic Fx
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//****************************************************************************
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class MosaicFx : public TStandardRasterFx
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{
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FX_PLUGIN_DECLARATION(MosaicFx)
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TRasterFxPort m_input;
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TDoubleParamP m_size;
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TDoubleParamP m_distance;
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TPixelParamP m_bgcolor;
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TIntEnumParamP m_shape;
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public:
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MosaicFx()
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: m_size(10.0), m_distance(10.0), m_bgcolor(TPixel32::Transparent), m_shape(new TIntEnumParam(0, "Square"))
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{
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m_size->setMeasureName("fxLength");
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m_distance->setMeasureName("fxLength");
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bindParam(this, "size", m_size);
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bindParam(this, "distance", m_distance);
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bindParam(this, "bg_color", m_bgcolor);
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bindParam(this, "shape", m_shape);
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addInputPort("Source", m_input);
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m_size->setValueRange(0.0, (std::numeric_limits<double>::max)());
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m_distance->setValueRange(0.0, (std::numeric_limits<double>::max)());
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m_shape->addItem(1, "Round");
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}
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~MosaicFx(){};
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bool doGetBBox(double frame, TRectD &bBox, const TRenderSettings &info);
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void doDryCompute(TRectD &rect, double frame, const TRenderSettings &ri);
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void doCompute(TTile &tile, double frame, const TRenderSettings &ri);
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int getMemoryRequirement(const TRectD &rect, double frame, const TRenderSettings &info);
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bool canHandle(const TRenderSettings &info, double frame)
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{
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//We'll return the handled affine only through handledAffine().
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if ((m_size->getValue(frame) + m_distance->getValue(frame)) == 0.0)
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return true;
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return false;
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}
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TAffine handledAffine(const TRenderSettings &info, double frame)
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{
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//Return the default implementation: only the scale part of the affine
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//can be handled. Rotations and other distortions would need us have to
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//implement diagonal grid lines - and we don't want to!
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//Also, no translational component will be dealt for the same reason.
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TAffine scalePart(TRasterFx::handledAffine(info, frame));
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//Plus, we want to avoid dealing with antialiases even on plain orthogonal
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//lines! So, we ensure that the step size will be flattened to integer.
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double stepSize = m_size->getValue(frame) + m_distance->getValue(frame);
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double scale = tceil(stepSize * scalePart.a11) / stepSize;
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return TScale(scale, scale);
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}
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};
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//-------------------------------------------------------------------
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template <typename PIXEL>
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void doMosaic(TRasterPT<PIXEL> ras, TRasterPT<PIXEL> cellsRas, int step, const TPoint &pos,
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TPixel32 bgcolor, mosaic::CellBuilder<PIXEL> &cellBuilder)
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{
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//Perform the mosaic's flattening operation on each grid cell.
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//Cells are identified directly as we traverse the raster.
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int lx = ras->getLx(), ly = ras->getLy();
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int wrap = ras->getWrap();
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int cellLx = cellsRas->getLx(), cellLy = cellsRas->getLy(), cellWrap = cellsRas->getWrap();
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int cellX, cellY;
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int x0, y0, x1, y1;
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PIXEL actualBgColor;
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pixelConvert(actualBgColor, bgcolor);
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ras->lock();
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cellsRas->lock();
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PIXEL *buffer = ras->pixels(0);
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PIXEL *cellsBuf = cellsRas->pixels(0);
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for (cellY = 0; cellY < cellLy; ++cellY)
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for (cellX = 0; cellX < cellLx; ++cellX) {
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//Build the cell geometry
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x0 = pos.x + cellX * step, y0 = pos.y + cellY * step;
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x1 = x0 + step, y1 = y0 + step;
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//Retrieve the cell buffer position and its eventual adjustment
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int u0 = tmax(x0, 0), v0 = tmax(y0, 0);
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int u1 = tmin(x1, lx), v1 = tmin(y1, ly);
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PIXEL *cb = buffer + u0 + v0 * wrap;
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u0 -= x0, v0 -= y0, u1 -= x0, v1 -= y0;
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//Retrieve the cell color
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PIXEL *color = cellsBuf + cellX + cellY * cellWrap;
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PIXEL cellBGColor = actualBgColor;
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double mFactor = color->m / (double)PIXEL::maxChannelValue;
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cellBGColor.r *= mFactor;
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cellBGColor.g *= mFactor;
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cellBGColor.b *= mFactor;
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cellBGColor.m *= mFactor;
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cellBuilder.doCell(cb, *color, cellBGColor, u0, v0, u1, v1);
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}
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cellsRas->unlock();
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ras->unlock();
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}
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//-------------------------------------------------------------------
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bool MosaicFx::doGetBBox(double frame, TRectD &bBox, const TRenderSettings &info)
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{
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//Remember: info.m_affine MUST NOT BE CONSIDERED in doGetBBox's implementation
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//Retrieve the input bbox without applied affines.
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if (!(m_input.getFx() && m_input->doGetBBox(frame, bBox, info)))
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return false;
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//Now, the grid has a given step size; the fx result is almost the same,
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//except that it must be ceiled to the grid step.
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double step = m_size->getValue(frame) + m_distance->getValue(frame);
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if (!step)
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return true;
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bBox = ::gridAlign(bBox, TPointD(), step);
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return true;
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}
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//-------------------------------------------------------------------
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void MosaicFx::doDryCompute(TRectD &rect, double frame, const TRenderSettings &ri)
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{
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if (!m_input.isConnected())
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return;
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double scale = ri.m_affine.a11; //Legitimate due to handledAffine's implementation
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double stepD = (m_size->getValue(frame) + m_distance->getValue(frame)) * scale;
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int step = tround(stepD);
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if (step <= 0)
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return;
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TRectD bboxD;
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m_input->getBBox(frame, bboxD, ri);
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TRectD tileBoxD(::gridAlign(rect * bboxD, TPointD(), stepD));
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TRectD srcRectD(
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tround(tileBoxD.x0 / stepD), tround(tileBoxD.y0 / stepD),
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tround(tileBoxD.x1 / stepD), tround(tileBoxD.y1 / stepD));
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int enlargement =
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(ri.m_quality == TRenderSettings::StandardResampleQuality) ? 1.0 : (ri.m_quality == TRenderSettings::ImprovedResampleQuality) ? 2.0 : (ri.m_quality == TRenderSettings::HighResampleQuality) ? 3.0 : 0.0;
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srcRectD = srcRectD.enlarge(enlargement);
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TRenderSettings riLow(ri);
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riLow.m_affine = TScale(1.0 / stepD) * ri.m_affine;
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m_input->dryCompute(srcRectD, frame, riLow);
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}
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//-------------------------------------------------------------------
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void MosaicFx::doCompute(TTile &tile, double frame, const TRenderSettings &ri)
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{
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if (!m_input.isConnected())
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return;
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//ri's affine is the one that has already been carried due to upstream geom fxs.
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//It is handled; so, we can transfer geometrical data directly.
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double scale = ri.m_affine.a11; //Legitimate due to handledAffine's implementation
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double stepD = (m_size->getValue(frame) + m_distance->getValue(frame)) * scale;
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int step = stepD = tround(stepD);
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if (step <= 0) {
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//No blur will be done. The underlying fx may pass by.
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m_input->compute(tile, frame, ri);
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return;
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}
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double radius = 0.5 * tcrop(m_size->getValue(frame) * scale, 0.0, stepD);
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TPixel32 bgcolor = m_bgcolor->getPremultipliedValue(frame);
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//Build the tile rect.
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TDimension tileSize(tile.getRaster()->getSize());
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TRectD tileRectD(tile.m_pos, TDimensionD(tileSize.lx, tileSize.ly));
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//Observe that TRasterFx's documentation ensures
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//that passed tile's position is always integer, even if it's double-defined.
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//Retrieve the input bbox
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TRectD bboxD;
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m_input->getBBox(frame, bboxD, ri);
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//Build the grid geometry. We require that the source tile is enlarged to cover
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//a full grid step.
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TRectD tileBoxD(::gridAlign(tileRectD * bboxD, TPointD(), stepD));
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//Now, we'll extract cell colors by computing tileBox with a res-reducing affine.
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//So, the source tile will be
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TRect srcRect(
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tround(tileBoxD.x0 / stepD), tround(tileBoxD.y0 / stepD),
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tround(tileBoxD.x1 / stepD) - 1, tround(tileBoxD.y1 / stepD) - 1);
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//The calculated source rect must be enlarged by a small amount, since the
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//resample algrotihms add some transparency to the edges.
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int enlargement =
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(ri.m_quality == TRenderSettings::StandardResampleQuality) ? 1 : (ri.m_quality == TRenderSettings::ImprovedResampleQuality) ? 2 : (ri.m_quality == TRenderSettings::HighResampleQuality) ? 3 : 0;
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assert(enlargement > 0);
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srcRect = srcRect.enlarge(enlargement);
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TRenderSettings riLow(ri);
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riLow.m_affine = TScale(1.0 / stepD) * ri.m_affine;
|
||
|
|
||
|
//Compute the input tile.
|
||
|
TRasterP srcRas(tile.getRaster()->create(srcRect.getLx(), srcRect.getLy()));
|
||
|
TTile inTile(srcRas, TPointD(srcRect.x0, srcRect.y0));
|
||
|
|
||
|
m_input->compute(inTile, frame, riLow);
|
||
|
|
||
|
//Eliminate the enlargement performed above
|
||
|
TRect r(enlargement, enlargement, srcRas->getLx() - 1 - enlargement, srcRas->getLy() - 1 - enlargement);
|
||
|
srcRas = srcRas->extract(r);
|
||
|
|
||
|
//Now, discriminate the tile's pixel size
|
||
|
TRaster32P srcRas32(srcRas);
|
||
|
TRaster64P srcRas64(srcRas);
|
||
|
|
||
|
TPoint pos(tround(tileBoxD.x0 - tileRectD.x0), tround(tileBoxD.y0 - tileRectD.y0));
|
||
|
if (srcRas32) {
|
||
|
typedef mosaic::CellBuilder<TPixel32> cb;
|
||
|
cb *cellsBuilder = (m_shape->getValue() == 0) ? (cb *)new mosaic::SquareBuilder<TPixel32, TPixelGR8>(step, step, radius, tile.getRaster()->getWrap()) : (cb *)new mosaic::CircleBuilder<TPixel32, TPixelGR8>(step, step, radius, tile.getRaster()->getWrap());
|
||
|
|
||
|
doMosaic<TPixel32>(tile.getRaster(), srcRas32, step, pos, bgcolor, *cellsBuilder);
|
||
|
|
||
|
delete cellsBuilder;
|
||
|
} else if (srcRas64) {
|
||
|
typedef mosaic::CellBuilder<TPixel64> cb;
|
||
|
cb *cellsBuilder = (m_shape->getValue() == 0) ? (cb *)new mosaic::SquareBuilder<TPixel64, TPixelGR16>(step, step, radius, tile.getRaster()->getWrap()) : (cb *)new mosaic::CircleBuilder<TPixel64, TPixelGR16>(step, step, radius, tile.getRaster()->getWrap());
|
||
|
|
||
|
doMosaic<TPixel64>(tile.getRaster(), srcRas64, step, pos, bgcolor, *cellsBuilder);
|
||
|
|
||
|
delete cellsBuilder;
|
||
|
} else
|
||
|
assert(false);
|
||
|
}
|
||
|
|
||
|
//------------------------------------------------------------------
|
||
|
|
||
|
int MosaicFx::getMemoryRequirement(const TRectD &rect, double frame, const TRenderSettings &info)
|
||
|
{
|
||
|
double scale = info.m_affine.a11;
|
||
|
double stepD = (m_size->getValue(frame) + m_distance->getValue(frame)) * scale;
|
||
|
|
||
|
TRectD srcRect(rect.x0 / stepD, rect.y0 / stepD,
|
||
|
rect.x1 / stepD, rect.y1 / stepD);
|
||
|
|
||
|
return TRasterFx::memorySize(srcRect, info.m_bpp);
|
||
|
}
|
||
|
|
||
|
//------------------------------------------------------------------
|
||
|
|
||
|
FX_PLUGIN_IDENTIFIER(MosaicFx, "mosaicFx");
|