/* Copyright (c) 2003,2004,2005 Clarence Dang All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #define DEBUG_KP_FLOOD_FILL 0 #include #include #include #include #include #include #include #include #include kpFloodFill::kpFloodFill (TQPixmap *pixmap, int x, int y, const kpColor &color, int processedColorSimilarity) : m_pixmapPtr (pixmap), m_x (x), m_y (y), m_color (color), m_processedColorSimilarity (processedColorSimilarity), m_initState (0) { } kpFloodFill::~kpFloodFill () { } // private int kpFloodFill::fillLinesListSize (const TQValueList &fillLines) const { return (fillLines.size () * kpFloodFill::FillLine::size ()); } // public int kpFloodFill::size () const { int fillLinesCacheSize = 0; for (TQValueVector < TQValueList >::const_iterator it = m_fillLinesCache.begin (); it != m_fillLinesCache.end (); it++) { fillLinesCacheSize += fillLinesListSize (*it); } return fillLinesListSize (m_fillLines) + kpPixmapFX::imageSize (m_image) + fillLinesCacheSize; } TQRect kpFloodFill::boundingRect () const { return m_boundingRect; } bool kpFloodFill::fill () { if (m_initState < 2 && !prepare ()) { kdError () << "kpFloodFill:fill() could not prepare()!" << endl; return false; } // not trying to do a NOP fill if (m_boundingRect.isValid ()) { TQApplication::setOverrideCursor (TQt::waitCursor); TQPainter painter, maskPainter; TQBitmap maskBitmap; if (m_pixmapPtr->tqmask () || m_color.isTransparent ()) { maskBitmap = kpPixmapFX::getNonNullMask (*m_pixmapPtr); maskPainter.begin (&maskBitmap); maskPainter.setPen (m_color.maskColor ()); } if (m_color.isOpaque ()) { painter.begin (m_pixmapPtr); painter.setPen (m_color.toTQColor ()); } const TQValueList ::ConstIterator fillLinesEnd = m_fillLines.end (); for (TQValueList ::ConstIterator it = m_fillLines.begin (); it != fillLinesEnd; it++) { TQPoint p1 = TQPoint ((*it).m_x1, (*it).m_y); TQPoint p2 = TQPoint ((*it).m_x2, (*it).m_y); if (painter.isActive ()) painter.drawLine (p1, p2); if (maskPainter.isActive ()) maskPainter.drawLine (p1, p2); } if (painter.isActive ()) painter.end (); if (maskPainter.isActive ()) maskPainter.end (); if (!maskBitmap.isNull ()) m_pixmapPtr->setMask (maskBitmap); TQApplication::restoreOverrideCursor (); } else { #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "kpFloodFill::fill() performing NOP fill" << endl; #endif } return true; } bool kpFloodFill::prepareColorToChange () { #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "kpFloodFill::prepareColorToChange" << endl; #endif m_colorToChange = kpPixmapFX::getColorAtPixel (*m_pixmapPtr, TQPoint (m_x, m_y)); if (m_colorToChange.isOpaque ()) { #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "\tcolorToChange: r=" << m_colorToChange.red () << ", b=" << m_colorToChange.blue () << ", g=" << m_colorToChange.green () << endl; #endif } else { #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "\tcolorToChange: transparent" << endl; #endif } m_initState = 1; return true; } // Derived from the zSprite2 Graphics Engine bool kpFloodFill::prepare () { #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "kpFloodFill::prepare()" << endl; #endif m_boundingRect = TQRect (); if (m_initState < 1 && !prepareColorToChange ()) { kdError () << "kpFloodFill:prepare() could not prepareColorToChange()!" << endl; return false; } #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "\tperforming NOP check" << endl; #endif // get the color we need to tqreplace if (m_processedColorSimilarity == 0 && m_color == m_colorToChange) { // need to do absolutely nothing (this is a significant optimisation // for people who randomly click a lot over already-filled areas) m_initState = 2; // sync with all "return true"'s return true; } #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "\tconverting to image" << endl; #endif // is this the only way to read pixels? m_image = kpPixmapFX::convertToImage (*m_pixmapPtr); if (m_image.isNull ()) { kdError () << "kpFloodFill::prepare() could not convert to TQImage" << endl; return false; } #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "\tcreating fillLinesCache" << endl; #endif // ready cache m_fillLinesCache.resize (m_pixmapPtr->height ()); #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "\tcreating fill lines" << endl; #endif // draw initial line addLine (m_y, findMinX (m_y, m_x), findMaxX (m_y, m_x)); for (TQValueList ::ConstIterator it = m_fillLines.begin (); it != m_fillLines.end (); it++) { #if DEBUG_KP_FLOOD_FILL && 0 kdDebug () << "Expanding from y=" << (*it).m_y << " x1=" << (*it).m_x1 << " x2=" << (*it).m_x2 << endl; #endif // make more lines above and below current line findAndAddLines (*it, -1); findAndAddLines (*it, +1); } #if DEBUG_KP_FLOOD_FILL && 1 kdDebug () << "\tfinalising memory usage" << endl; #endif // finalize memory usage m_image.reset (); m_fillLinesCache.clear (); m_initState = 2; // sync with all "return true"'s return true; } void kpFloodFill::addLine (int y, int x1, int x2) { #if DEBUG_KP_FLOOD_FILL && 0 kdDebug () << "kpFillCommand::fillAddLine (" << y << "," << x1 << "," << x2 << ")" << endl; #endif m_fillLines.append (FillLine (y, x1, x2)); m_fillLinesCache [y].append (FillLine (y /* OPT */, x1, x2)); m_boundingRect = m_boundingRect.unite (TQRect (TQPoint (x1, y), TQPoint (x2, y))); } kpColor kpFloodFill::pixelColor (int x, int y, bool *beenHere) const { if (beenHere) *beenHere = false; if (y >= (int) m_fillLinesCache.count ()) { kdError () << "kpFloodFill::pixelColor(" << x << "," << y << ") y out of range=" << m_pixmapPtr->height () << endl; return kpColor::invalid; } const TQValueList ::ConstIterator theEnd = m_fillLinesCache [y].end (); for (TQValueList ::ConstIterator it = m_fillLinesCache [y].begin (); it != theEnd; it++) { if (x >= (*it).m_x1 && x <= (*it).m_x2) { if (beenHere) *beenHere = true; return m_color; } } return kpPixmapFX::getColorAtPixel (m_image, TQPoint (x, y)); } bool kpFloodFill::shouldGoTo (int x, int y) const { bool beenThere; const kpColor col = pixelColor (x, y, &beenThere); return (!beenThere && col.isSimilarTo (m_colorToChange, m_processedColorSimilarity)); } void kpFloodFill::findAndAddLines (const FillLine &fillLine, int dy) { // out of bounds? if (fillLine.m_y + dy < 0 || fillLine.m_y + dy >= m_pixmapPtr->height ()) return; for (int xnow = fillLine.m_x1; xnow <= fillLine.m_x2; xnow++) { // At current position, right colour? if (shouldGoTo (xnow, fillLine.m_y + dy)) { // Find minimum and maximum x values int minxnow = findMinX (fillLine.m_y + dy, xnow); int maxxnow = findMaxX (fillLine.m_y + dy, xnow); // Draw line addLine (fillLine.m_y + dy, minxnow, maxxnow); // Move x pointer xnow = maxxnow; } } } // finds the minimum x value at a certain line to be filled int kpFloodFill::findMinX (int y, int x) const { for (;;) { if (x < 0) return 0; if (shouldGoTo (x, y)) x--; else return x + 1; } } // finds the maximum x value at a certain line to be filled int kpFloodFill::findMaxX (int y, int x) const { for (;;) { if (x > m_pixmapPtr->width () - 1) return m_pixmapPtr->width () - 1; if (shouldGoTo (x, y)) x++; else return x - 1; } }