/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2013 - Raw Material Software Ltd. Permission is granted to use this software under the terms of either: a) the GPL v2 (or any later version) b) the Affero GPL v3 Details of these licenses can be found at: www.gnu.org/licenses JUCE is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. ------------------------------------------------------------------------------ To release a closed-source product which uses JUCE, commercial licenses are available: visit www.juce.com for more information. ============================================================================== */ const int juce_edgeTableDefaultEdgesPerLine = 32; //============================================================================== EdgeTable::EdgeTable (const Rectangle& area, const Path& path, const AffineTransform& transform) : bounds (area), maxEdgesPerLine (juce_edgeTableDefaultEdgesPerLine), lineStrideElements (juce_edgeTableDefaultEdgesPerLine * 2 + 1), needToCheckEmptiness (true) { allocate(); int* t = table; for (int i = bounds.getHeight(); --i >= 0;) { *t = 0; t += lineStrideElements; } const int leftLimit = bounds.getX() << 8; const int topLimit = bounds.getY() << 8; const int rightLimit = bounds.getRight() << 8; const int heightLimit = bounds.getHeight() << 8; PathFlatteningIterator iter (path, transform); while (iter.next()) { int y1 = roundToInt (iter.y1 * 256.0f); int y2 = roundToInt (iter.y2 * 256.0f); if (y1 != y2) { y1 -= topLimit; y2 -= topLimit; const int startY = y1; int direction = -1; if (y1 > y2) { std::swap (y1, y2); direction = 1; } if (y1 < 0) y1 = 0; if (y2 > heightLimit) y2 = heightLimit; if (y1 < y2) { const double startX = 256.0f * iter.x1; const double multiplier = (iter.x2 - iter.x1) / (iter.y2 - iter.y1); const int stepSize = jlimit (1, 256, 256 / (1 + (int) std::abs (multiplier))); do { const int step = jmin (stepSize, y2 - y1, 256 - (y1 & 255)); int x = roundToInt (startX + multiplier * ((y1 + (step >> 1)) - startY)); if (x < leftLimit) x = leftLimit; else if (x >= rightLimit) x = rightLimit - 1; addEdgePoint (x, y1 >> 8, direction * step); y1 += step; } while (y1 < y2); } } } sanitiseLevels (path.isUsingNonZeroWinding()); } EdgeTable::EdgeTable (const Rectangle& rectangleToAdd) : bounds (rectangleToAdd), maxEdgesPerLine (juce_edgeTableDefaultEdgesPerLine), lineStrideElements (juce_edgeTableDefaultEdgesPerLine * 2 + 1), needToCheckEmptiness (true) { allocate(); table[0] = 0; const int x1 = rectangleToAdd.getX() << 8; const int x2 = rectangleToAdd.getRight() << 8; int* t = table; for (int i = rectangleToAdd.getHeight(); --i >= 0;) { t[0] = 2; t[1] = x1; t[2] = 255; t[3] = x2; t[4] = 0; t += lineStrideElements; } } EdgeTable::EdgeTable (const RectangleList& rectanglesToAdd) : bounds (rectanglesToAdd.getBounds()), maxEdgesPerLine (juce_edgeTableDefaultEdgesPerLine), lineStrideElements (juce_edgeTableDefaultEdgesPerLine * 2 + 1), needToCheckEmptiness (true) { allocate(); clearLineSizes(); for (const Rectangle* r = rectanglesToAdd.begin(), * const e = rectanglesToAdd.end(); r != e; ++r) { const int x1 = r->getX() << 8; const int x2 = r->getRight() << 8; int y = r->getY() - bounds.getY(); for (int j = r->getHeight(); --j >= 0;) addEdgePointPair (x1, x2, y++, 255); } sanitiseLevels (true); } EdgeTable::EdgeTable (const RectangleList& rectanglesToAdd) : bounds (rectanglesToAdd.getBounds().getSmallestIntegerContainer()), maxEdgesPerLine (rectanglesToAdd.getNumRectangles() * 2), lineStrideElements (rectanglesToAdd.getNumRectangles() * 4 + 1), needToCheckEmptiness (true) { bounds.setHeight (bounds.getHeight() + 1); allocate(); clearLineSizes(); for (const Rectangle* r = rectanglesToAdd.begin(), * const e = rectanglesToAdd.end(); r != e; ++r) { const int x1 = roundToInt (r->getX() * 256.0f); const int x2 = roundToInt (r->getRight() * 256.0f); const int y1 = roundToInt (r->getY() * 256.0f) - (bounds.getY() << 8); const int y2 = roundToInt (r->getBottom() * 256.0f) - (bounds.getY() << 8); if (x2 <= x1 || y2 <= y1) continue; int y = y1 >> 8; const int lastLine = y2 >> 8; if (y == lastLine) { addEdgePointPair (x1, x2, y, y2 - y1); } else { addEdgePointPair (x1, x2, y++, 255 - (y1 & 255)); while (y < lastLine) addEdgePointPair (x1, x2, y++, 255); jassert (y < bounds.getHeight()); addEdgePointPair (x1, x2, y, y2 & 255); } } sanitiseLevels (true); } EdgeTable::EdgeTable (const Rectangle& rectangleToAdd) : bounds (Rectangle ((int) std::floor (rectangleToAdd.getX()), roundToInt (rectangleToAdd.getY() * 256.0f) >> 8, 2 + (int) rectangleToAdd.getWidth(), 2 + (int) rectangleToAdd.getHeight())), maxEdgesPerLine (juce_edgeTableDefaultEdgesPerLine), lineStrideElements ((juce_edgeTableDefaultEdgesPerLine << 1) + 1), needToCheckEmptiness (true) { jassert (! rectangleToAdd.isEmpty()); allocate(); table[0] = 0; const int x1 = roundToInt (rectangleToAdd.getX() * 256.0f); const int x2 = roundToInt (rectangleToAdd.getRight() * 256.0f); int y1 = roundToInt (rectangleToAdd.getY() * 256.0f) - (bounds.getY() << 8); jassert (y1 < 256); int y2 = roundToInt (rectangleToAdd.getBottom() * 256.0f) - (bounds.getY() << 8); if (x2 <= x1 || y2 <= y1) { bounds.setHeight (0); return; } int lineY = 0; int* t = table; if ((y1 >> 8) == (y2 >> 8)) { t[0] = 2; t[1] = x1; t[2] = y2 - y1; t[3] = x2; t[4] = 0; ++lineY; t += lineStrideElements; } else { t[0] = 2; t[1] = x1; t[2] = 255 - (y1 & 255); t[3] = x2; t[4] = 0; ++lineY; t += lineStrideElements; while (lineY < (y2 >> 8)) { t[0] = 2; t[1] = x1; t[2] = 255; t[3] = x2; t[4] = 0; ++lineY; t += lineStrideElements; } jassert (lineY < bounds.getHeight()); t[0] = 2; t[1] = x1; t[2] = y2 & 255; t[3] = x2; t[4] = 0; ++lineY; t += lineStrideElements; } while (lineY < bounds.getHeight()) { t[0] = 0; t += lineStrideElements; ++lineY; } } EdgeTable::EdgeTable (const EdgeTable& other) { operator= (other); } EdgeTable& EdgeTable::operator= (const EdgeTable& other) { bounds = other.bounds; maxEdgesPerLine = other.maxEdgesPerLine; lineStrideElements = other.lineStrideElements; needToCheckEmptiness = other.needToCheckEmptiness; allocate(); copyEdgeTableData (table, lineStrideElements, other.table, lineStrideElements, bounds.getHeight()); return *this; } EdgeTable::~EdgeTable() { } //============================================================================== static size_t getEdgeTableAllocationSize (int lineStride, int height) noexcept { // (leave an extra line at the end for use as scratch space) return (size_t) (lineStride * (2 + jmax (0, height))); } void EdgeTable::allocate() { table.malloc (getEdgeTableAllocationSize (lineStrideElements, bounds.getHeight())); } void EdgeTable::clearLineSizes() noexcept { int* t = table; for (int i = bounds.getHeight(); --i >= 0;) { *t = 0; t += lineStrideElements; } } void EdgeTable::copyEdgeTableData (int* dest, const int destLineStride, const int* src, const int srcLineStride, int numLines) noexcept { while (--numLines >= 0) { memcpy (dest, src, (size_t) (src[0] * 2 + 1) * sizeof (int)); src += srcLineStride; dest += destLineStride; } } void EdgeTable::sanitiseLevels (const bool useNonZeroWinding) noexcept { // Convert the table from relative windings to absolute levels.. int* lineStart = table; for (int y = bounds.getHeight(); --y >= 0;) { int num = lineStart[0]; if (num > 0) { LineItem* items = reinterpret_cast (lineStart + 1); // sort the X coords std::sort (items, items + num); // merge duplicate X coords for (int i = 0; i < num - 1; ++i) { if (items[i].x == items[i + 1].x) { items[i].level += items[i + 1].level; memmove (items + i + 1, items + i + 2, (size_t) (num - i - 2) * sizeof (LineItem)); --num; --lineStart[0]; --i; } } int level = 0; if (useNonZeroWinding) { while (--num > 0) { level += items->level; int corrected = std::abs (level); if (corrected >> 8) corrected = 255; items->level = corrected; ++items; } } else { while (--num > 0) { level += items->level; int corrected = std::abs (level); if (corrected >> 8) { corrected &= 511; if (corrected >> 8) corrected = 511 - corrected; } items->level = corrected; ++items; } } items->level = 0; // force the last level to 0, just in case something went wrong in creating the table } lineStart += lineStrideElements; } } void EdgeTable::remapTableForNumEdges (const int newNumEdgesPerLine) { if (newNumEdgesPerLine != maxEdgesPerLine) { maxEdgesPerLine = newNumEdgesPerLine; jassert (bounds.getHeight() > 0); const int newLineStrideElements = maxEdgesPerLine * 2 + 1; HeapBlock newTable (getEdgeTableAllocationSize (newLineStrideElements, bounds.getHeight())); copyEdgeTableData (newTable, newLineStrideElements, table, lineStrideElements, bounds.getHeight()); table.swapWith (newTable); lineStrideElements = newLineStrideElements; } } void EdgeTable::optimiseTable() { int maxLineElements = 0; for (int i = bounds.getHeight(); --i >= 0;) maxLineElements = jmax (maxLineElements, table [i * lineStrideElements]); remapTableForNumEdges (maxLineElements); } void EdgeTable::addEdgePoint (const int x, const int y, const int winding) { jassert (y >= 0 && y < bounds.getHeight()); int* line = table + lineStrideElements * y; const int numPoints = line[0]; if (numPoints >= maxEdgesPerLine) { remapTableForNumEdges (maxEdgesPerLine + juce_edgeTableDefaultEdgesPerLine); jassert (numPoints < maxEdgesPerLine); line = table + lineStrideElements * y; } line[0]++; int n = numPoints << 1; line [n + 1] = x; line [n + 2] = winding; } void EdgeTable::addEdgePointPair (int x1, int x2, int y, int winding) { jassert (y >= 0 && y < bounds.getHeight()); int* line = table + lineStrideElements * y; const int numPoints = line[0]; if (numPoints + 1 >= maxEdgesPerLine) { remapTableForNumEdges (maxEdgesPerLine + juce_edgeTableDefaultEdgesPerLine); jassert (numPoints < maxEdgesPerLine); line = table + lineStrideElements * y; } line[0] += 2; int n = numPoints << 1; line [n + 1] = x1; line [n + 2] = winding; line [n + 3] = x2; line [n + 4] = -winding; } void EdgeTable::translate (float dx, const int dy) noexcept { bounds.translate ((int) std::floor (dx), dy); int* lineStart = table; const int intDx = (int) (dx * 256.0f); for (int i = bounds.getHeight(); --i >= 0;) { int* line = lineStart; lineStart += lineStrideElements; int num = *line++; while (--num >= 0) { *line += intDx; line += 2; } } } void EdgeTable::intersectWithEdgeTableLine (const int y, const int* const otherLine) { jassert (y >= 0 && y < bounds.getHeight()); int* srcLine = table + lineStrideElements * y; int srcNum1 = *srcLine; if (srcNum1 == 0) return; int srcNum2 = *otherLine; if (srcNum2 == 0) { *srcLine = 0; return; } const int right = bounds.getRight() << 8; // optimise for the common case where our line lies entirely within a // single pair of points, as happens when clipping to a simple rect. if (srcNum2 == 2 && otherLine[2] >= 255) { clipEdgeTableLineToRange (srcLine, otherLine[1], jmin (right, otherLine[3])); return; } bool isUsingTempSpace = false; const int* src1 = srcLine + 1; int x1 = *src1++; const int* src2 = otherLine + 1; int x2 = *src2++; int destIndex = 0, destTotal = 0; int level1 = 0, level2 = 0; int lastX = std::numeric_limits::min(), lastLevel = 0; while (srcNum1 > 0 && srcNum2 > 0) { int nextX; if (x1 <= x2) { if (x1 == x2) { level2 = *src2++; x2 = *src2++; --srcNum2; } nextX = x1; level1 = *src1++; x1 = *src1++; --srcNum1; } else { nextX = x2; level2 = *src2++; x2 = *src2++; --srcNum2; } if (nextX > lastX) { if (nextX >= right) break; lastX = nextX; const int nextLevel = (level1 * (level2 + 1)) >> 8; jassert (isPositiveAndBelow (nextLevel, (int) 256)); if (nextLevel != lastLevel) { if (destTotal >= maxEdgesPerLine) { srcLine[0] = destTotal; remapTableForNumEdges (jmax (256, destTotal * 2)); srcLine = table + lineStrideElements * y; } ++destTotal; lastLevel = nextLevel; if (! isUsingTempSpace) { isUsingTempSpace = true; int* const temp = table + lineStrideElements * bounds.getHeight(); memcpy (temp, src1, (size_t) (srcNum1 * 2 * sizeof (int))); src1 = temp; } srcLine[++destIndex] = nextX; srcLine[++destIndex] = nextLevel; } } } if (lastLevel > 0) { if (destTotal >= maxEdgesPerLine) { srcLine[0] = destTotal; remapTableForNumEdges (jmax (256, destTotal * 2)); srcLine = table + lineStrideElements * y; } ++destTotal; srcLine[++destIndex] = right; srcLine[++destIndex] = 0; } srcLine[0] = destTotal; } void EdgeTable::clipEdgeTableLineToRange (int* dest, const int x1, const int x2) noexcept { int* lastItem = dest + (dest[0] * 2 - 1); if (x2 < lastItem[0]) { if (x2 <= dest[1]) { dest[0] = 0; return; } while (x2 < lastItem[-2]) { --(dest[0]); lastItem -= 2; } lastItem[0] = x2; lastItem[1] = 0; } if (x1 > dest[1]) { while (lastItem[0] > x1) lastItem -= 2; const int itemsRemoved = (int) (lastItem - (dest + 1)) / 2; if (itemsRemoved > 0) { dest[0] -= itemsRemoved; memmove (dest + 1, lastItem, (size_t) dest[0] * (sizeof (int) * 2)); } dest[1] = x1; } } //============================================================================== void EdgeTable::clipToRectangle (const Rectangle& r) { const Rectangle clipped (r.getIntersection (bounds)); if (clipped.isEmpty()) { needToCheckEmptiness = false; bounds.setHeight (0); } else { const int top = clipped.getY() - bounds.getY(); const int bottom = clipped.getBottom() - bounds.getY(); if (bottom < bounds.getHeight()) bounds.setHeight (bottom); for (int i = top; --i >= 0;) table [lineStrideElements * i] = 0; if (clipped.getX() > bounds.getX() || clipped.getRight() < bounds.getRight()) { const int x1 = clipped.getX() << 8; const int x2 = jmin (bounds.getRight(), clipped.getRight()) << 8; int* line = table + lineStrideElements * top; for (int i = bottom - top; --i >= 0;) { if (line[0] != 0) clipEdgeTableLineToRange (line, x1, x2); line += lineStrideElements; } } needToCheckEmptiness = true; } } void EdgeTable::excludeRectangle (const Rectangle& r) { const Rectangle clipped (r.getIntersection (bounds)); if (! clipped.isEmpty()) { const int top = clipped.getY() - bounds.getY(); const int bottom = clipped.getBottom() - bounds.getY(); const int rectLine[] = { 4, std::numeric_limits::min(), 255, clipped.getX() << 8, 0, clipped.getRight() << 8, 255, std::numeric_limits::max(), 0 }; for (int i = top; i < bottom; ++i) intersectWithEdgeTableLine (i, rectLine); needToCheckEmptiness = true; } } void EdgeTable::clipToEdgeTable (const EdgeTable& other) { const Rectangle clipped (other.bounds.getIntersection (bounds)); if (clipped.isEmpty()) { needToCheckEmptiness = false; bounds.setHeight (0); } else { const int top = clipped.getY() - bounds.getY(); const int bottom = clipped.getBottom() - bounds.getY(); if (bottom < bounds.getHeight()) bounds.setHeight (bottom); if (clipped.getRight() < bounds.getRight()) bounds.setRight (clipped.getRight()); for (int i = 0; i < top; ++i) table [lineStrideElements * i] = 0; const int* otherLine = other.table + other.lineStrideElements * (clipped.getY() - other.bounds.getY()); for (int i = top; i < bottom; ++i) { intersectWithEdgeTableLine (i, otherLine); otherLine += other.lineStrideElements; } needToCheckEmptiness = true; } } void EdgeTable::clipLineToMask (int x, int y, const uint8* mask, int maskStride, int numPixels) { y -= bounds.getY(); if (y < 0 || y >= bounds.getHeight()) return; needToCheckEmptiness = true; if (numPixels <= 0) { table [lineStrideElements * y] = 0; return; } int* tempLine = static_cast (alloca ((size_t) (numPixels * 2 + 4) * sizeof (int))); int destIndex = 0, lastLevel = 0; while (--numPixels >= 0) { const int alpha = *mask; mask += maskStride; if (alpha != lastLevel) { tempLine[++destIndex] = (x << 8); tempLine[++destIndex] = alpha; lastLevel = alpha; } ++x; } if (lastLevel > 0) { tempLine[++destIndex] = (x << 8); tempLine[++destIndex] = 0; } tempLine[0] = destIndex >> 1; intersectWithEdgeTableLine (y, tempLine); } bool EdgeTable::isEmpty() noexcept { if (needToCheckEmptiness) { needToCheckEmptiness = false; int* t = table; for (int i = bounds.getHeight(); --i >= 0;) { if (t[0] > 1) return false; t += lineStrideElements; } bounds.setHeight (0); } return bounds.getHeight() == 0; }