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Carla/source/modules/juce_graphics/geometry/juce_EdgeTable.cpp

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  1. /*

  2.   ==============================================================================

  3. 

  4.    This file is part of the JUCE library.

  5.    Copyright (c) 2013 - Raw Material Software Ltd.

  6. 

  7.    Permission is granted to use this software under the terms of either:

  8.    a) the GPL v2 (or any later version)

  9.    b) the Affero GPL v3

  10. 

  11.    Details of these licenses can be found at: www.gnu.org/licenses

  12. 

  13.    JUCE is distributed in the hope that it will be useful, but WITHOUT ANY

  14.    WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR

  15.    A PARTICULAR PURPOSE.  See the GNU General Public License for more details.

  16. 

  17.    ------------------------------------------------------------------------------

  18. 

  19.    To release a closed-source product which uses JUCE, commercial licenses are

  20.    available: visit www.juce.com for more information.

  21. 

  22.   ==============================================================================

  23. */

  24. 

  25. const int juce_edgeTableDefaultEdgesPerLine = 32;

  26. 

  27. //==============================================================================

  28. EdgeTable::EdgeTable (const Rectangle<int>& area,

  29.                       const Path& path, const AffineTransform& transform)

  30.    : bounds (area),

  31.      maxEdgesPerLine (juce_edgeTableDefaultEdgesPerLine),

  32.      lineStrideElements (juce_edgeTableDefaultEdgesPerLine * 2 + 1),

  33.      needToCheckEmptiness (true)

  34. {

  35.     allocate();

  36.     int* t = table;

  37. 

  38.     for (int i = bounds.getHeight(); --i >= 0;)

  39.     {

  40.         *t = 0;

  41.         t += lineStrideElements;

  42.     }

  43. 

  44.     const int leftLimit   = bounds.getX() << 8;

  45.     const int topLimit    = bounds.getY() << 8;

  46.     const int rightLimit  = bounds.getRight() << 8;

  47.     const int heightLimit = bounds.getHeight() << 8;

  48. 

  49.     PathFlatteningIterator iter (path, transform);

  50. 

  51.     while (iter.next())

  52.     {

  53.         int y1 = roundToInt (iter.y1 * 256.0f);

  54.         int y2 = roundToInt (iter.y2 * 256.0f);

  55. 

  56.         if (y1 != y2)

  57.         {

  58.             y1 -= topLimit;

  59.             y2 -= topLimit;

  60. 

  61.             const int startY = y1;

  62.             int direction = -1;

  63. 

  64.             if (y1 > y2)

  65.             {

  66.                 std::swap (y1, y2);

  67.                 direction = 1;

  68.             }

  69. 

  70.             if (y1 < 0)

  71.                 y1 = 0;

  72. 

  73.             if (y2 > heightLimit)

  74.                 y2 = heightLimit;

  75. 

  76.             if (y1 < y2)

  77.             {

  78.                 const double startX = 256.0f * iter.x1;

  79.                 const double multiplier = (iter.x2 - iter.x1) / (iter.y2 - iter.y1);

  80.                 const int stepSize = jlimit (1, 256, 256 / (1 + (int) std::abs (multiplier)));

  81. 

  82.                 do

  83.                 {

  84.                     const int step = jmin (stepSize, y2 - y1, 256 - (y1 & 255));

  85.                     int x = roundToInt (startX + multiplier * ((y1 + (step >> 1)) - startY));

  86. 

  87.                     if (x < leftLimit)

  88.                         x = leftLimit;

  89.                     else if (x >= rightLimit)

  90.                         x = rightLimit - 1;

  91. 

  92.                     addEdgePoint (x, y1 >> 8, direction * step);

  93.                     y1 += step;

  94.                 }

  95.                 while (y1 < y2);

  96.             }

  97.         }

  98.     }

  99. 

  100.     sanitiseLevels (path.isUsingNonZeroWinding());

  101. }

  102. 

  103. EdgeTable::EdgeTable (const Rectangle<int>& rectangleToAdd)

  104.    : bounds (rectangleToAdd),

  105.      maxEdgesPerLine (juce_edgeTableDefaultEdgesPerLine),

  106.      lineStrideElements (juce_edgeTableDefaultEdgesPerLine * 2 + 1),

  107.      needToCheckEmptiness (true)

  108. {

  109.     allocate();

  110.     table[0] = 0;

  111. 

  112.     const int x1 = rectangleToAdd.getX() << 8;

  113.     const int x2 = rectangleToAdd.getRight() << 8;

  114. 

  115.     int* t = table;

  116.     for (int i = rectangleToAdd.getHeight(); --i >= 0;)

  117.     {

  118.         t[0] = 2;

  119.         t[1] = x1;

  120.         t[2] = 255;

  121.         t[3] = x2;

  122.         t[4] = 0;

  123.         t += lineStrideElements;

  124.     }

  125. }

  126. 

  127. EdgeTable::EdgeTable (const RectangleList<int>& rectanglesToAdd)

  128.    : bounds (rectanglesToAdd.getBounds()),

  129.      maxEdgesPerLine (juce_edgeTableDefaultEdgesPerLine),

  130.      lineStrideElements (juce_edgeTableDefaultEdgesPerLine * 2 + 1),

  131.      needToCheckEmptiness (true)

  132. {

  133.     allocate();

  134.     clearLineSizes();

  135. 

  136.     for (const Rectangle<int>* r = rectanglesToAdd.begin(), * const e = rectanglesToAdd.end(); r != e; ++r)

  137.     {

  138.         const int x1 = r->getX() << 8;

  139.         const int x2 = r->getRight() << 8;

  140.         int y = r->getY() - bounds.getY();

  141. 

  142.         for (int j = r->getHeight(); --j >= 0;)

  143.             addEdgePointPair (x1, x2, y++, 255);

  144.     }

  145. 

  146.     sanitiseLevels (true);

  147. }

  148. 

  149. EdgeTable::EdgeTable (const RectangleList<float>& rectanglesToAdd)

  150.    : bounds (rectanglesToAdd.getBounds().getSmallestIntegerContainer()),

  151.      maxEdgesPerLine (rectanglesToAdd.getNumRectangles() * 2),

  152.      lineStrideElements (rectanglesToAdd.getNumRectangles() * 4 + 1),

  153.      needToCheckEmptiness (true)

  154. {

  155.     bounds.setHeight (bounds.getHeight() + 1);

  156.     allocate();

  157.     clearLineSizes();

  158. 

  159.     for (const Rectangle<float>* r = rectanglesToAdd.begin(), * const e = rectanglesToAdd.end(); r != e; ++r)

  160.     {

  161.         const int x1 = roundToInt (r->getX() * 256.0f);

  162.         const int x2 = roundToInt (r->getRight() * 256.0f);

  163. 

  164.         const int y1 = roundToInt (r->getY() * 256.0f) - (bounds.getY() << 8);

  165.         const int y2 = roundToInt (r->getBottom() * 256.0f) - (bounds.getY() << 8);

  166. 

  167.         if (x2 <= x1 || y2 <= y1)

  168.             continue;

  169. 

  170.         int y = y1 >> 8;

  171.         const int lastLine = y2 >> 8;

  172. 

  173.         if (y == lastLine)

  174.         {

  175.             addEdgePointPair (x1, x2, y, y2 - y1);

  176.         }

  177.         else

  178.         {

  179.             addEdgePointPair (x1, x2, y++, 255 - (y1 & 255));

  180. 

  181.             while (y < lastLine)

  182.                 addEdgePointPair (x1, x2, y++, 255);

  183. 

  184.             jassert (y < bounds.getHeight());

  185.             addEdgePointPair (x1, x2, y, y2 & 255);

  186.         }

  187.     }

  188. 

  189.     sanitiseLevels (true);

  190. }

  191. 

  192. EdgeTable::EdgeTable (const Rectangle<float>& rectangleToAdd)

  193.    : bounds (Rectangle<int> ((int) std::floor (rectangleToAdd.getX()),

  194.                              roundToInt (rectangleToAdd.getY() * 256.0f) >> 8,

  195.                              2 + (int) rectangleToAdd.getWidth(),

  196.                              2 + (int) rectangleToAdd.getHeight())),

  197.      maxEdgesPerLine (juce_edgeTableDefaultEdgesPerLine),

  198.      lineStrideElements ((juce_edgeTableDefaultEdgesPerLine << 1) + 1),

  199.      needToCheckEmptiness (true)

  200. {

  201.     jassert (! rectangleToAdd.isEmpty());

  202.     allocate();

  203.     table[0] = 0;

  204. 

  205.     const int x1 = roundToInt (rectangleToAdd.getX() * 256.0f);

  206.     const int x2 = roundToInt (rectangleToAdd.getRight() * 256.0f);

  207. 

  208.     int y1 = roundToInt (rectangleToAdd.getY() * 256.0f) - (bounds.getY() << 8);

  209.     jassert (y1 < 256);

  210.     int y2 = roundToInt (rectangleToAdd.getBottom() * 256.0f) - (bounds.getY() << 8);

  211. 

  212.     if (x2 <= x1 || y2 <= y1)

  213.     {

  214.         bounds.setHeight (0);

  215.         return;

  216.     }

  217. 

  218.     int lineY = 0;

  219.     int* t = table;

  220. 

  221.     if ((y1 >> 8) == (y2 >> 8))

  222.     {

  223.         t[0] = 2;

  224.         t[1] = x1;

  225.         t[2] = y2 - y1;

  226.         t[3] = x2;

  227.         t[4] = 0;

  228.         ++lineY;

  229.         t += lineStrideElements;

  230.     }

  231.     else

  232.     {

  233.         t[0] = 2;

  234.         t[1] = x1;

  235.         t[2] = 255 - (y1 & 255);

  236.         t[3] = x2;

  237.         t[4] = 0;

  238.         ++lineY;

  239.         t += lineStrideElements;

  240. 

  241.         while (lineY < (y2 >> 8))

  242.         {

  243.             t[0] = 2;

  244.             t[1] = x1;

  245.             t[2] = 255;

  246.             t[3] = x2;

  247.             t[4] = 0;

  248.             ++lineY;

  249.             t += lineStrideElements;

  250.         }

  251. 

  252.         jassert (lineY < bounds.getHeight());

  253.         t[0] = 2;

  254.         t[1] = x1;

  255.         t[2] = y2 & 255;

  256.         t[3] = x2;

  257.         t[4] = 0;

  258.         ++lineY;

  259.         t += lineStrideElements;

  260.     }

  261. 

  262.     while (lineY < bounds.getHeight())

  263.     {

  264.         t[0] = 0;

  265.         t += lineStrideElements;

  266.         ++lineY;

  267.     }

  268. }

  269. 

  270. EdgeTable::EdgeTable (const EdgeTable& other)

  271. {

  272.     operator= (other);

  273. }

  274. 

  275. EdgeTable& EdgeTable::operator= (const EdgeTable& other)

  276. {

  277.     bounds = other.bounds;

  278.     maxEdgesPerLine = other.maxEdgesPerLine;

  279.     lineStrideElements = other.lineStrideElements;

  280.     needToCheckEmptiness = other.needToCheckEmptiness;

  281. 

  282.     allocate();

  283.     copyEdgeTableData (table, lineStrideElements, other.table, lineStrideElements, bounds.getHeight());

  284.     return *this;

  285. }

  286. 

  287. EdgeTable::~EdgeTable()

  288. {

  289. }

  290. 

  291. //==============================================================================

  292. static size_t getEdgeTableAllocationSize (int lineStride, int height) noexcept

  293. {

  294.     // (leave an extra line at the end for use as scratch space)

  295.     return (size_t) (lineStride * (2 + jmax (0, height)));

  296. }

  297. 

  298. void EdgeTable::allocate()

  299. {

  300.     table.malloc (getEdgeTableAllocationSize (lineStrideElements, bounds.getHeight()));

  301. }

  302. 

  303. void EdgeTable::clearLineSizes() noexcept

  304. {

  305.     int* t = table;

  306.     for (int i = bounds.getHeight(); --i >= 0;)

  307.     {

  308.         *t = 0;

  309.         t += lineStrideElements;

  310.     }

  311. }

  312. 

  313. void EdgeTable::copyEdgeTableData (int* dest, const int destLineStride, const int* src, const int srcLineStride, int numLines) noexcept

  314. {

  315.     while (--numLines >= 0)

  316.     {

  317.         memcpy (dest, src, (size_t) (src[0] * 2 + 1) * sizeof (int));

  318.         src += srcLineStride;

  319.         dest += destLineStride;

  320.     }

  321. }

  322. 

  323. void EdgeTable::sanitiseLevels (const bool useNonZeroWinding) noexcept

  324. {

  325.     // Convert the table from relative windings to absolute levels..

  326.     int* lineStart = table;

  327. 

  328.     for (int y = bounds.getHeight(); --y >= 0;)

  329.     {

  330.         int num = lineStart[0];

  331. 

  332.         if (num > 0)

  333.         {

  334.             LineItem* items = reinterpret_cast<LineItem*> (lineStart + 1);

  335. 

  336.             // sort the X coords

  337.             std::sort (items, items + num);

  338. 

  339.             // merge duplicate X coords

  340.             for (int i = 0; i < num - 1; ++i)

  341.             {

  342.                 if (items[i].x == items[i + 1].x)

  343.                 {

  344.                     items[i].level += items[i + 1].level;

  345.                     memmove (items + i + 1, items + i + 2, (size_t) (num - i - 2) * sizeof (LineItem));

  346.                     --num;

  347.                     --lineStart[0];

  348.                     --i;

  349.                 }

  350.             }

  351. 

  352.             int level = 0;

  353. 

  354.             if (useNonZeroWinding)

  355.             {

  356.                 while (--num > 0)

  357.                 {

  358.                     level += items->level;

  359.                     int corrected = std::abs (level);

  360.                     if (corrected >> 8)

  361.                         corrected = 255;

  362. 

  363.                     items->level = corrected;

  364.                     ++items;

  365.                 }

  366.             }

  367.             else

  368.             {

  369.                 while (--num > 0)

  370.                 {

  371.                     level += items->level;

  372.                     int corrected = std::abs (level);

  373.                     if (corrected >> 8)

  374.                     {

  375.                         corrected &= 511;

  376.                         if (corrected >> 8)

  377.                             corrected = 511 - corrected;

  378.                     }

  379. 

  380.                     items->level = corrected;

  381.                     ++items;

  382.                 }

  383.             }

  384. 

  385.             items->level = 0; // force the last level to 0, just in case something went wrong in creating the table

  386.         }

  387. 

  388.         lineStart += lineStrideElements;

  389.     }

  390. }

  391. 

  392. void EdgeTable::remapTableForNumEdges (const int newNumEdgesPerLine)

  393. {

  394.     if (newNumEdgesPerLine != maxEdgesPerLine)

  395.     {

  396.         maxEdgesPerLine = newNumEdgesPerLine;

  397. 

  398.         jassert (bounds.getHeight() > 0);

  399.         const int newLineStrideElements = maxEdgesPerLine * 2 + 1;

  400. 

  401.         HeapBlock<int> newTable (getEdgeTableAllocationSize (newLineStrideElements, bounds.getHeight()));

  402. 

  403.         copyEdgeTableData (newTable, newLineStrideElements, table, lineStrideElements, bounds.getHeight());

  404. 

  405.         table.swapWith (newTable);

  406.         lineStrideElements = newLineStrideElements;

  407.     }

  408. }

  409. 

  410. void EdgeTable::optimiseTable()

  411. {

  412.     int maxLineElements = 0;

  413. 

  414.     for (int i = bounds.getHeight(); --i >= 0;)

  415.         maxLineElements = jmax (maxLineElements, table [i * lineStrideElements]);

  416. 

  417.     remapTableForNumEdges (maxLineElements);

  418. }

  419. 

  420. void EdgeTable::addEdgePoint (const int x, const int y, const int winding)

  421. {

  422.     jassert (y >= 0 && y < bounds.getHeight());

  423. 

  424.     int* line = table + lineStrideElements * y;

  425.     const int numPoints = line[0];

  426. 

  427.     if (numPoints >= maxEdgesPerLine)

  428.     {

  429.         remapTableForNumEdges (maxEdgesPerLine + juce_edgeTableDefaultEdgesPerLine);

  430.         jassert (numPoints < maxEdgesPerLine);

  431.         line = table + lineStrideElements * y;

  432.     }

  433. 

  434.     line[0]++;

  435.     int n = numPoints << 1;

  436.     line [n + 1] = x;

  437.     line [n + 2] = winding;

  438. }

  439. 

  440. void EdgeTable::addEdgePointPair (int x1, int x2, int y, int winding)

  441. {

  442.     jassert (y >= 0 && y < bounds.getHeight());

  443. 

  444.     int* line = table + lineStrideElements * y;

  445.     const int numPoints = line[0];

  446. 

  447.     if (numPoints + 1 >= maxEdgesPerLine)

  448.     {

  449.         remapTableForNumEdges (maxEdgesPerLine + juce_edgeTableDefaultEdgesPerLine);

  450.         jassert (numPoints < maxEdgesPerLine);

  451.         line = table + lineStrideElements * y;

  452.     }

  453. 

  454.     line[0] += 2;

  455.     int n = numPoints << 1;

  456.     line [n + 1] = x1;

  457.     line [n + 2] = winding;

  458.     line [n + 3] = x2;

  459.     line [n + 4] = -winding;

  460. }

  461. 

  462. void EdgeTable::translate (float dx, const int dy) noexcept

  463. {

  464.     bounds.translate ((int) std::floor (dx), dy);

  465. 

  466.     int* lineStart = table;

  467.     const int intDx = (int) (dx * 256.0f);

  468. 

  469.     for (int i = bounds.getHeight(); --i >= 0;)

  470.     {

  471.         int* line = lineStart;

  472.         lineStart += lineStrideElements;

  473.         int num = *line++;

  474. 

  475.         while (--num >= 0)

  476.         {

  477.             *line += intDx;

  478.             line += 2;

  479.         }

  480.     }

  481. }

  482. 

  483. void EdgeTable::intersectWithEdgeTableLine (const int y, const int* const otherLine)

  484. {

  485.     jassert (y >= 0 && y < bounds.getHeight());

  486. 

  487.     int* srcLine = table + lineStrideElements * y;

  488.     int srcNum1 = *srcLine;

  489. 

  490.     if (srcNum1 == 0)

  491.         return;

  492. 

  493.     int srcNum2 = *otherLine;

  494. 

  495.     if (srcNum2 == 0)

  496.     {

  497.         *srcLine = 0;

  498.         return;

  499.     }

  500. 

  501.     const int right = bounds.getRight() << 8;

  502. 

  503.     // optimise for the common case where our line lies entirely within a

  504.     // single pair of points, as happens when clipping to a simple rect.

  505.     if (srcNum2 == 2 && otherLine[2] >= 255)

  506.     {

  507.         clipEdgeTableLineToRange (srcLine, otherLine[1], jmin (right, otherLine[3]));

  508.         return;

  509.     }

  510. 

  511.     bool isUsingTempSpace = false;

  512. 

  513.     const int* src1 = srcLine + 1;

  514.     int x1 = *src1++;

  515. 

  516.     const int* src2 = otherLine + 1;

  517.     int x2 = *src2++;

  518. 

  519.     int destIndex = 0, destTotal = 0;

  520.     int level1 = 0, level2 = 0;

  521.     int lastX = std::numeric_limits<int>::min(), lastLevel = 0;

  522. 

  523.     while (srcNum1 > 0 && srcNum2 > 0)

  524.     {

  525.         int nextX;

  526. 

  527.         if (x1 <= x2)

  528.         {

  529.             if (x1 == x2)

  530.             {

  531.                 level2 = *src2++;

  532.                 x2 = *src2++;

  533.                 --srcNum2;

  534.             }

  535. 

  536.             nextX = x1;

  537.             level1 = *src1++;

  538.             x1 = *src1++;

  539.             --srcNum1;

  540.         }

  541.         else

  542.         {

  543.             nextX = x2;

  544.             level2 = *src2++;

  545.             x2 = *src2++;

  546.             --srcNum2;

  547.         }

  548. 

  549.         if (nextX > lastX)

  550.         {

  551.             if (nextX >= right)

  552.                 break;

  553. 

  554.             lastX = nextX;

  555. 

  556.             const int nextLevel = (level1 * (level2 + 1)) >> 8;

  557.             jassert (isPositiveAndBelow (nextLevel, (int) 256));

  558. 

  559.             if (nextLevel != lastLevel)

  560.             {

  561.                 if (destTotal >= maxEdgesPerLine)

  562.                 {

  563.                     srcLine[0] = destTotal;

  564. 

  565.                     if (isUsingTempSpace)

  566.                     {

  567.                         const size_t tempSize = (size_t) srcNum1 * 2 * sizeof (int);

  568.                         int* const oldTemp = static_cast<int*> (alloca (tempSize));

  569.                         memcpy (oldTemp, src1, tempSize);

  570. 

  571.                         remapTableForNumEdges (jmax (256, destTotal * 2));

  572.                         srcLine = table + lineStrideElements * y;

  573. 

  574.                         int* const newTemp = table + lineStrideElements * bounds.getHeight();

  575.                         memcpy (newTemp, oldTemp, tempSize);

  576.                         src1 = newTemp;

  577.                     }

  578.                     else

  579.                     {

  580.                         remapTableForNumEdges (jmax (256, destTotal * 2));

  581.                         srcLine = table + lineStrideElements * y;

  582.                     }

  583.                 }

  584. 

  585.                 ++destTotal;

  586.                 lastLevel = nextLevel;

  587. 

  588.                 if (! isUsingTempSpace)

  589.                 {

  590.                     isUsingTempSpace = true;

  591.                     int* const temp = table + lineStrideElements * bounds.getHeight();

  592.                     memcpy (temp, src1, (size_t) srcNum1 * 2 * sizeof (int));

  593.                     src1 = temp;

  594.                 }

  595. 

  596.                 srcLine[++destIndex] = nextX;

  597.                 srcLine[++destIndex] = nextLevel;

  598.             }

  599.         }

  600.     }

  601. 

  602.     if (lastLevel > 0)

  603.     {

  604.         if (destTotal >= maxEdgesPerLine)

  605.         {

  606.             srcLine[0] = destTotal;

  607.             remapTableForNumEdges (jmax (256, destTotal * 2));

  608.             srcLine = table + lineStrideElements * y;

  609.         }

  610. 

  611.         ++destTotal;

  612.         srcLine[++destIndex] = right;

  613.         srcLine[++destIndex] = 0;

  614.     }

  615. 

  616.     srcLine[0] = destTotal;

  617. }

  618. 

  619. void EdgeTable::clipEdgeTableLineToRange (int* dest, const int x1, const int x2) noexcept

  620. {

  621.     int* lastItem = dest + (dest[0] * 2 - 1);

  622. 

  623.     if (x2 < lastItem[0])

  624.     {

  625.         if (x2 <= dest[1])

  626.         {

  627.             dest[0] = 0;

  628.             return;

  629.         }

  630. 

  631.         while (x2 < lastItem[-2])

  632.         {

  633.             --(dest[0]);

  634.             lastItem -= 2;

  635.         }

  636. 

  637.         lastItem[0] = x2;

  638.         lastItem[1] = 0;

  639.     }

  640. 

  641.     if (x1 > dest[1])

  642.     {

  643.         while (lastItem[0] > x1)

  644.             lastItem -= 2;

  645. 

  646.         const int itemsRemoved = (int) (lastItem - (dest + 1)) / 2;

  647. 

  648.         if (itemsRemoved > 0)

  649.         {

  650.             dest[0] -= itemsRemoved;

  651.             memmove (dest + 1, lastItem, (size_t) dest[0] * (sizeof (int) * 2));

  652.         }

  653. 

  654.         dest[1] = x1;

  655.     }

  656. }

  657. 

  658. 

  659. //==============================================================================

  660. void EdgeTable::clipToRectangle (const Rectangle<int>& r)

  661. {

  662.     const Rectangle<int> clipped (r.getIntersection (bounds));

  663. 

  664.     if (clipped.isEmpty())

  665.     {

  666.         needToCheckEmptiness = false;

  667.         bounds.setHeight (0);

  668.     }

  669.     else

  670.     {

  671.         const int top = clipped.getY() - bounds.getY();

  672.         const int bottom = clipped.getBottom() - bounds.getY();

  673. 

  674.         if (bottom < bounds.getHeight())

  675.             bounds.setHeight (bottom);

  676. 

  677.         for (int i = top; --i >= 0;)

  678.             table [lineStrideElements * i] = 0;

  679. 

  680.         if (clipped.getX() > bounds.getX() || clipped.getRight() < bounds.getRight())

  681.         {

  682.             const int x1 = clipped.getX() << 8;

  683.             const int x2 = jmin (bounds.getRight(), clipped.getRight()) << 8;

  684.             int* line = table + lineStrideElements * top;

  685. 

  686.             for (int i = bottom - top; --i >= 0;)

  687.             {

  688.                 if (line[0] != 0)

  689.                     clipEdgeTableLineToRange (line, x1, x2);

  690. 

  691.                 line += lineStrideElements;

  692.             }

  693.         }

  694. 

  695.         needToCheckEmptiness = true;

  696.     }

  697. }

  698. 

  699. void EdgeTable::excludeRectangle (const Rectangle<int>& r)

  700. {

  701.     const Rectangle<int> clipped (r.getIntersection (bounds));

  702. 

  703.     if (! clipped.isEmpty())

  704.     {

  705.         const int top = clipped.getY() - bounds.getY();

  706.         const int bottom = clipped.getBottom() - bounds.getY();

  707. 

  708.         const int rectLine[] = { 4, std::numeric_limits<int>::min(), 255,

  709.                                  clipped.getX() << 8, 0,

  710.                                  clipped.getRight() << 8, 255,

  711.                                  std::numeric_limits<int>::max(), 0 };

  712. 

  713.         for (int i = top; i < bottom; ++i)

  714.             intersectWithEdgeTableLine (i, rectLine);

  715. 

  716.         needToCheckEmptiness = true;

  717.     }

  718. }

  719. 

  720. void EdgeTable::clipToEdgeTable (const EdgeTable& other)

  721. {

  722.     const Rectangle<int> clipped (other.bounds.getIntersection (bounds));

  723. 

  724.     if (clipped.isEmpty())

  725.     {

  726.         needToCheckEmptiness = false;

  727.         bounds.setHeight (0);

  728.     }

  729.     else

  730.     {

  731.         const int top = clipped.getY() - bounds.getY();

  732.         const int bottom = clipped.getBottom() - bounds.getY();

  733. 

  734.         if (bottom < bounds.getHeight())

  735.             bounds.setHeight (bottom);

  736. 

  737.         if (clipped.getRight() < bounds.getRight())

  738.             bounds.setRight (clipped.getRight());

  739. 

  740.         for (int i = 0; i < top; ++i)

  741.             table [lineStrideElements * i] = 0;

  742. 

  743.         const int* otherLine = other.table + other.lineStrideElements * (clipped.getY() - other.bounds.getY());

  744. 

  745.         for (int i = top; i < bottom; ++i)

  746.         {

  747.             intersectWithEdgeTableLine (i, otherLine);

  748.             otherLine += other.lineStrideElements;

  749.         }

  750. 

  751.         needToCheckEmptiness = true;

  752.     }

  753. }

  754. 

  755. void EdgeTable::clipLineToMask (int x, int y, const uint8* mask, int maskStride, int numPixels)

  756. {

  757.     y -= bounds.getY();

  758. 

  759.     if (y < 0 || y >= bounds.getHeight())

  760.         return;

  761. 

  762.     needToCheckEmptiness = true;

  763. 

  764.     if (numPixels <= 0)

  765.     {

  766.         table [lineStrideElements * y] = 0;

  767.         return;

  768.     }

  769. 

  770.     int* tempLine = static_cast<int*> (alloca ((size_t) (numPixels * 2 + 4) * sizeof (int)));

  771.     int destIndex = 0, lastLevel = 0;

  772. 

  773.     while (--numPixels >= 0)

  774.     {

  775.         const int alpha = *mask;

  776.         mask += maskStride;

  777. 

  778.         if (alpha != lastLevel)

  779.         {

  780.             tempLine[++destIndex] = (x << 8);

  781.             tempLine[++destIndex] = alpha;

  782.             lastLevel = alpha;

  783.         }

  784. 

  785.         ++x;

  786.     }

  787. 

  788.     if (lastLevel > 0)

  789.     {

  790.         tempLine[++destIndex] = (x << 8);

  791.         tempLine[++destIndex] = 0;

  792.     }

  793. 

  794.     tempLine[0] = destIndex >> 1;

  795. 

  796.     intersectWithEdgeTableLine (y, tempLine);

  797. }

  798. 

  799. bool EdgeTable::isEmpty() noexcept

  800. {

  801.     if (needToCheckEmptiness)

  802.     {

  803.         needToCheckEmptiness = false;

  804.         int* t = table;

  805. 

  806.         for (int i = bounds.getHeight(); --i >= 0;)

  807.         {

  808.             if (t[0] > 1)

  809.                 return false;

  810. 

  811.             t += lineStrideElements;

  812.         }

  813. 

  814.         bounds.setHeight (0);

  815.     }

  816. 

  817.     return bounds.getHeight() == 0;

  818. }