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  1. /*
  2. ==============================================================================
  3. This file is part of the JUCE library.
  4. Copyright (c) 2015 - ROLI Ltd.
  5. Permission is granted to use this software under the terms of either:
  6. a) the GPL v2 (or any later version)
  7. b) the Affero GPL v3
  8. Details of these licenses can be found at: www.gnu.org/licenses
  9. JUCE is distributed in the hope that it will be useful, but WITHOUT ANY
  10. WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
  11. A PARTICULAR PURPOSE. See the GNU General Public License for more details.
  12. ------------------------------------------------------------------------------
  13. To release a closed-source product which uses JUCE, commercial licenses are
  14. available: visit www.juce.com for more information.
  15. ==============================================================================
  16. */
  17. #ifndef JUCE_RENDERINGHELPERS_H_INCLUDED
  18. #define JUCE_RENDERINGHELPERS_H_INCLUDED
  19. #if JUCE_MSVC
  20. #pragma warning (push)
  21. #pragma warning (disable: 4127) // "expression is constant" warning
  22. #endif
  23. namespace RenderingHelpers
  24. {
  25. //==============================================================================
  26. /** Holds either a simple integer translation, or an affine transform.
  27. */
  28. class TranslationOrTransform
  29. {
  30. public:
  31. TranslationOrTransform (Point<int> origin) noexcept
  32. : offset (origin), isOnlyTranslated (true), isRotated (false)
  33. {
  34. }
  35. TranslationOrTransform (const TranslationOrTransform& other) noexcept
  36. : complexTransform (other.complexTransform), offset (other.offset),
  37. isOnlyTranslated (other.isOnlyTranslated), isRotated (other.isRotated)
  38. {
  39. }
  40. AffineTransform getTransform() const noexcept
  41. {
  42. return isOnlyTranslated ? AffineTransform::translation (offset)
  43. : complexTransform;
  44. }
  45. AffineTransform getTransformWith (const AffineTransform& userTransform) const noexcept
  46. {
  47. return isOnlyTranslated ? userTransform.translated (offset)
  48. : userTransform.followedBy (complexTransform);
  49. }
  50. void setOrigin (Point<int> delta) noexcept
  51. {
  52. if (isOnlyTranslated)
  53. offset += delta;
  54. else
  55. complexTransform = AffineTransform::translation (delta)
  56. .followedBy (complexTransform);
  57. }
  58. void addTransform (const AffineTransform& t) noexcept
  59. {
  60. if (isOnlyTranslated && t.isOnlyTranslation())
  61. {
  62. const int tx = (int) (t.getTranslationX() * 256.0f);
  63. const int ty = (int) (t.getTranslationY() * 256.0f);
  64. if (((tx | ty) & 0xf8) == 0)
  65. {
  66. offset += Point<int> (tx >> 8, ty >> 8);
  67. return;
  68. }
  69. }
  70. complexTransform = getTransformWith (t);
  71. isOnlyTranslated = false;
  72. isRotated = (complexTransform.mat01 != 0 || complexTransform.mat10 != 0
  73. || complexTransform.mat00 < 0 || complexTransform.mat11 < 0);
  74. }
  75. float getPhysicalPixelScaleFactor() const noexcept
  76. {
  77. return isOnlyTranslated ? 1.0f : std::abs (complexTransform.getScaleFactor());
  78. }
  79. void moveOriginInDeviceSpace (Point<int> delta) noexcept
  80. {
  81. if (isOnlyTranslated)
  82. offset += delta;
  83. else
  84. complexTransform = complexTransform.translated (delta);
  85. }
  86. Rectangle<int> translated (const Rectangle<int>& r) const noexcept
  87. {
  88. jassert (isOnlyTranslated);
  89. return r + offset;
  90. }
  91. Rectangle<float> translated (const Rectangle<float>& r) const noexcept
  92. {
  93. jassert (isOnlyTranslated);
  94. return r + offset.toFloat();
  95. }
  96. template <typename RectangleOrPoint>
  97. RectangleOrPoint transformed (const RectangleOrPoint& r) const noexcept
  98. {
  99. jassert (! isOnlyTranslated);
  100. return r.transformedBy (complexTransform);
  101. }
  102. template <typename Type>
  103. Rectangle<Type> deviceSpaceToUserSpace (const Rectangle<Type>& r) const noexcept
  104. {
  105. return isOnlyTranslated ? r - offset
  106. : r.transformedBy (complexTransform.inverted());
  107. }
  108. AffineTransform complexTransform;
  109. Point<int> offset;
  110. bool isOnlyTranslated, isRotated;
  111. };
  112. //==============================================================================
  113. /** Holds a cache of recently-used glyph objects of some type. */
  114. template <class CachedGlyphType, class RenderTargetType>
  115. class GlyphCache : private DeletedAtShutdown
  116. {
  117. public:
  118. GlyphCache()
  119. {
  120. reset();
  121. }
  122. ~GlyphCache()
  123. {
  124. getSingletonPointer() = nullptr;
  125. }
  126. static GlyphCache& getInstance()
  127. {
  128. GlyphCache*& g = getSingletonPointer();
  129. if (g == nullptr)
  130. g = new GlyphCache();
  131. return *g;
  132. }
  133. //==============================================================================
  134. void reset()
  135. {
  136. const ScopedLock sl (lock);
  137. glyphs.clear();
  138. addNewGlyphSlots (120);
  139. hits.set (0);
  140. misses.set (0);
  141. }
  142. void drawGlyph (RenderTargetType& target, const Font& font, const int glyphNumber, Point<float> pos)
  143. {
  144. if (ReferenceCountedObjectPtr<CachedGlyphType> glyph = findOrCreateGlyph (font, glyphNumber))
  145. {
  146. glyph->lastAccessCount = ++accessCounter;
  147. glyph->draw (target, pos);
  148. }
  149. }
  150. ReferenceCountedObjectPtr<CachedGlyphType> findOrCreateGlyph (const Font& font, int glyphNumber)
  151. {
  152. const ScopedLock sl (lock);
  153. if (CachedGlyphType* g = findExistingGlyph (font, glyphNumber))
  154. {
  155. ++hits;
  156. return g;
  157. }
  158. ++misses;
  159. CachedGlyphType* g = getGlyphForReuse();
  160. jassert (g != nullptr);
  161. g->generate (font, glyphNumber);
  162. return g;
  163. }
  164. private:
  165. friend struct ContainerDeletePolicy<CachedGlyphType>;
  166. ReferenceCountedArray<CachedGlyphType> glyphs;
  167. Atomic<int> accessCounter, hits, misses;
  168. CriticalSection lock;
  169. CachedGlyphType* findExistingGlyph (const Font& font, int glyphNumber) const
  170. {
  171. for (int i = 0; i < glyphs.size(); ++i)
  172. {
  173. CachedGlyphType* const g = glyphs.getUnchecked (i);
  174. if (g->glyph == glyphNumber && g->font == font)
  175. return g;
  176. }
  177. return nullptr;
  178. }
  179. CachedGlyphType* getGlyphForReuse()
  180. {
  181. if (hits.value + misses.value > glyphs.size() * 16)
  182. {
  183. if (misses.value * 2 > hits.value)
  184. addNewGlyphSlots (32);
  185. hits.set (0);
  186. misses.set (0);
  187. }
  188. if (CachedGlyphType* g = findLeastRecentlyUsedGlyph())
  189. return g;
  190. addNewGlyphSlots (32);
  191. return glyphs.getLast();
  192. }
  193. void addNewGlyphSlots (int num)
  194. {
  195. glyphs.ensureStorageAllocated (glyphs.size() + num);
  196. while (--num >= 0)
  197. glyphs.add (new CachedGlyphType());
  198. }
  199. CachedGlyphType* findLeastRecentlyUsedGlyph() const noexcept
  200. {
  201. CachedGlyphType* oldest = nullptr;
  202. int oldestCounter = std::numeric_limits<int>::max();
  203. for (int i = glyphs.size() - 1; --i >= 0;)
  204. {
  205. CachedGlyphType* const glyph = glyphs.getUnchecked(i);
  206. if (glyph->lastAccessCount <= oldestCounter
  207. && glyph->getReferenceCount() == 1)
  208. {
  209. oldestCounter = glyph->lastAccessCount;
  210. oldest = glyph;
  211. }
  212. }
  213. return oldest;
  214. }
  215. static GlyphCache*& getSingletonPointer() noexcept
  216. {
  217. static GlyphCache* g = nullptr;
  218. return g;
  219. }
  220. JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (GlyphCache)
  221. };
  222. //==============================================================================
  223. /** Caches a glyph as an edge-table. */
  224. template <class RendererType>
  225. class CachedGlyphEdgeTable : public ReferenceCountedObject
  226. {
  227. public:
  228. CachedGlyphEdgeTable() : glyph (0), lastAccessCount (0) {}
  229. void draw (RendererType& state, Point<float> pos) const
  230. {
  231. if (snapToIntegerCoordinate)
  232. pos.x = std::floor (pos.x + 0.5f);
  233. if (edgeTable != nullptr)
  234. state.fillEdgeTable (*edgeTable, pos.x, roundToInt (pos.y));
  235. }
  236. void generate (const Font& newFont, const int glyphNumber)
  237. {
  238. font = newFont;
  239. Typeface* const typeface = newFont.getTypeface();
  240. snapToIntegerCoordinate = typeface->isHinted();
  241. glyph = glyphNumber;
  242. const float fontHeight = font.getHeight();
  243. edgeTable = typeface->getEdgeTableForGlyph (glyphNumber,
  244. AffineTransform::scale (fontHeight * font.getHorizontalScale(),
  245. fontHeight), fontHeight);
  246. }
  247. Font font;
  248. ScopedPointer<EdgeTable> edgeTable;
  249. int glyph, lastAccessCount;
  250. bool snapToIntegerCoordinate;
  251. JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (CachedGlyphEdgeTable)
  252. };
  253. //==============================================================================
  254. /** Calculates the alpha values and positions for rendering the edges of a
  255. non-pixel-aligned rectangle.
  256. */
  257. struct FloatRectangleRasterisingInfo
  258. {
  259. FloatRectangleRasterisingInfo (const Rectangle<float>& area)
  260. : left (roundToInt (256.0f * area.getX())),
  261. top (roundToInt (256.0f * area.getY())),
  262. right (roundToInt (256.0f * area.getRight())),
  263. bottom (roundToInt (256.0f * area.getBottom()))
  264. {
  265. if ((top >> 8) == (bottom >> 8))
  266. {
  267. topAlpha = bottom - top;
  268. bottomAlpha = 0;
  269. totalTop = top >> 8;
  270. totalBottom = bottom = top = totalTop + 1;
  271. }
  272. else
  273. {
  274. if ((top & 255) == 0)
  275. {
  276. topAlpha = 0;
  277. top = totalTop = (top >> 8);
  278. }
  279. else
  280. {
  281. topAlpha = 255 - (top & 255);
  282. totalTop = (top >> 8);
  283. top = totalTop + 1;
  284. }
  285. bottomAlpha = bottom & 255;
  286. bottom >>= 8;
  287. totalBottom = bottom + (bottomAlpha != 0 ? 1 : 0);
  288. }
  289. if ((left >> 8) == (right >> 8))
  290. {
  291. leftAlpha = right - left;
  292. rightAlpha = 0;
  293. totalLeft = (left >> 8);
  294. totalRight = right = left = totalLeft + 1;
  295. }
  296. else
  297. {
  298. if ((left & 255) == 0)
  299. {
  300. leftAlpha = 0;
  301. left = totalLeft = (left >> 8);
  302. }
  303. else
  304. {
  305. leftAlpha = 255 - (left & 255);
  306. totalLeft = (left >> 8);
  307. left = totalLeft + 1;
  308. }
  309. rightAlpha = right & 255;
  310. right >>= 8;
  311. totalRight = right + (rightAlpha != 0 ? 1 : 0);
  312. }
  313. }
  314. template <class Callback>
  315. void iterate (Callback& callback) const
  316. {
  317. if (topAlpha != 0) callback (totalLeft, totalTop, totalRight - totalLeft, 1, topAlpha);
  318. if (bottomAlpha != 0) callback (totalLeft, bottom, totalRight - totalLeft, 1, bottomAlpha);
  319. if (leftAlpha != 0) callback (totalLeft, totalTop, 1, totalBottom - totalTop, leftAlpha);
  320. if (rightAlpha != 0) callback (right, totalTop, 1, totalBottom - totalTop, rightAlpha);
  321. callback (left, top, right - left, bottom - top, 255);
  322. }
  323. inline bool isOnePixelWide() const noexcept { return right - left == 1 && leftAlpha + rightAlpha == 0; }
  324. inline int getTopLeftCornerAlpha() const noexcept { return (topAlpha * leftAlpha) >> 8; }
  325. inline int getTopRightCornerAlpha() const noexcept { return (topAlpha * rightAlpha) >> 8; }
  326. inline int getBottomLeftCornerAlpha() const noexcept { return (bottomAlpha * leftAlpha) >> 8; }
  327. inline int getBottomRightCornerAlpha() const noexcept { return (bottomAlpha * rightAlpha) >> 8; }
  328. //==============================================================================
  329. int left, top, right, bottom; // bounds of the solid central area, excluding anti-aliased edges
  330. int totalTop, totalLeft, totalBottom, totalRight; // bounds of the total area, including edges
  331. int topAlpha, leftAlpha, bottomAlpha, rightAlpha; // alpha of each anti-aliased edge
  332. };
  333. //==============================================================================
  334. /** Contains classes for calculating the colour of pixels within various types of gradient. */
  335. namespace GradientPixelIterators
  336. {
  337. /** Iterates the colour of pixels in a linear gradient */
  338. class Linear
  339. {
  340. public:
  341. Linear (const ColourGradient& gradient, const AffineTransform& transform,
  342. const PixelARGB* const colours, const int numColours)
  343. : lookupTable (colours),
  344. numEntries (numColours)
  345. {
  346. jassert (numColours >= 0);
  347. Point<float> p1 (gradient.point1);
  348. Point<float> p2 (gradient.point2);
  349. if (! transform.isIdentity())
  350. {
  351. const Line<float> l (p2, p1);
  352. Point<float> p3 = l.getPointAlongLine (0.0f, 100.0f);
  353. p1.applyTransform (transform);
  354. p2.applyTransform (transform);
  355. p3.applyTransform (transform);
  356. p2 = Line<float> (p2, p3).findNearestPointTo (p1);
  357. }
  358. vertical = std::abs (p1.x - p2.x) < 0.001f;
  359. horizontal = std::abs (p1.y - p2.y) < 0.001f;
  360. if (vertical)
  361. {
  362. scale = roundToInt ((numEntries << (int) numScaleBits) / (double) (p2.y - p1.y));
  363. start = roundToInt (p1.y * (float) scale);
  364. }
  365. else if (horizontal)
  366. {
  367. scale = roundToInt ((numEntries << (int) numScaleBits) / (double) (p2.x - p1.x));
  368. start = roundToInt (p1.x * (float) scale);
  369. }
  370. else
  371. {
  372. grad = (p2.getY() - p1.y) / (double) (p1.x - p2.x);
  373. yTerm = p1.getY() - p1.x / grad;
  374. scale = roundToInt ((numEntries << (int) numScaleBits) / (yTerm * grad - (p2.y * grad - p2.x)));
  375. grad *= scale;
  376. }
  377. }
  378. forcedinline void setY (const int y) noexcept
  379. {
  380. if (vertical)
  381. linePix = lookupTable [jlimit (0, numEntries, (y * scale - start) >> (int) numScaleBits)];
  382. else if (! horizontal)
  383. start = roundToInt ((y - yTerm) * grad);
  384. }
  385. inline PixelARGB getPixel (const int x) const noexcept
  386. {
  387. return vertical ? linePix
  388. : lookupTable [jlimit (0, numEntries, (x * scale - start) >> (int) numScaleBits)];
  389. }
  390. private:
  391. const PixelARGB* const lookupTable;
  392. const int numEntries;
  393. PixelARGB linePix;
  394. int start, scale;
  395. double grad, yTerm;
  396. bool vertical, horizontal;
  397. enum { numScaleBits = 12 };
  398. JUCE_DECLARE_NON_COPYABLE (Linear)
  399. };
  400. //==============================================================================
  401. /** Iterates the colour of pixels in a circular radial gradient */
  402. class Radial
  403. {
  404. public:
  405. Radial (const ColourGradient& gradient, const AffineTransform&,
  406. const PixelARGB* const colours, const int numColours)
  407. : lookupTable (colours),
  408. numEntries (numColours),
  409. gx1 (gradient.point1.x),
  410. gy1 (gradient.point1.y)
  411. {
  412. jassert (numColours >= 0);
  413. const Point<float> diff (gradient.point1 - gradient.point2);
  414. maxDist = diff.x * diff.x + diff.y * diff.y;
  415. invScale = numEntries / std::sqrt (maxDist);
  416. jassert (roundToInt (std::sqrt (maxDist) * invScale) <= numEntries);
  417. }
  418. forcedinline void setY (const int y) noexcept
  419. {
  420. dy = y - gy1;
  421. dy *= dy;
  422. }
  423. inline PixelARGB getPixel (const int px) const noexcept
  424. {
  425. double x = px - gx1;
  426. x *= x;
  427. x += dy;
  428. return lookupTable [x >= maxDist ? numEntries : roundToInt (std::sqrt (x) * invScale)];
  429. }
  430. protected:
  431. const PixelARGB* const lookupTable;
  432. const int numEntries;
  433. const double gx1, gy1;
  434. double maxDist, invScale, dy;
  435. JUCE_DECLARE_NON_COPYABLE (Radial)
  436. };
  437. //==============================================================================
  438. /** Iterates the colour of pixels in a skewed radial gradient */
  439. class TransformedRadial : public Radial
  440. {
  441. public:
  442. TransformedRadial (const ColourGradient& gradient, const AffineTransform& transform,
  443. const PixelARGB* const colours, const int numColours)
  444. : Radial (gradient, transform, colours, numColours),
  445. inverseTransform (transform.inverted())
  446. {
  447. tM10 = inverseTransform.mat10;
  448. tM00 = inverseTransform.mat00;
  449. }
  450. forcedinline void setY (const int y) noexcept
  451. {
  452. const float floatY = (float) y;
  453. lineYM01 = inverseTransform.mat01 * floatY + inverseTransform.mat02 - gx1;
  454. lineYM11 = inverseTransform.mat11 * floatY + inverseTransform.mat12 - gy1;
  455. }
  456. inline PixelARGB getPixel (const int px) const noexcept
  457. {
  458. double x = px;
  459. const double y = tM10 * x + lineYM11;
  460. x = tM00 * x + lineYM01;
  461. x *= x;
  462. x += y * y;
  463. if (x >= maxDist)
  464. return lookupTable [numEntries];
  465. return lookupTable [jmin (numEntries, roundToInt (std::sqrt (x) * invScale))];
  466. }
  467. private:
  468. double tM10, tM00, lineYM01, lineYM11;
  469. const AffineTransform inverseTransform;
  470. JUCE_DECLARE_NON_COPYABLE (TransformedRadial)
  471. };
  472. }
  473. #define JUCE_PERFORM_PIXEL_OP_LOOP(op) \
  474. { \
  475. const int destStride = destData.pixelStride; \
  476. do { dest->op; dest = addBytesToPointer (dest, destStride); } while (--width > 0); \
  477. }
  478. //==============================================================================
  479. /** Contains classes for filling edge tables with various fill types. */
  480. namespace EdgeTableFillers
  481. {
  482. /** Fills an edge-table with a solid colour. */
  483. template <class PixelType, bool replaceExisting = false>
  484. class SolidColour
  485. {
  486. public:
  487. SolidColour (const Image::BitmapData& image, const PixelARGB colour)
  488. : destData (image), sourceColour (colour)
  489. {
  490. if (sizeof (PixelType) == 3 && destData.pixelStride == sizeof (PixelType))
  491. {
  492. areRGBComponentsEqual = sourceColour.getRed() == sourceColour.getGreen()
  493. && sourceColour.getGreen() == sourceColour.getBlue();
  494. filler[0].set (sourceColour);
  495. filler[1].set (sourceColour);
  496. filler[2].set (sourceColour);
  497. filler[3].set (sourceColour);
  498. }
  499. else
  500. {
  501. areRGBComponentsEqual = false;
  502. }
  503. }
  504. forcedinline void setEdgeTableYPos (const int y) noexcept
  505. {
  506. linePixels = (PixelType*) destData.getLinePointer (y);
  507. }
  508. forcedinline void handleEdgeTablePixel (const int x, const int alphaLevel) const noexcept
  509. {
  510. if (replaceExisting)
  511. getPixel (x)->set (sourceColour);
  512. else
  513. getPixel (x)->blend (sourceColour, (uint32) alphaLevel);
  514. }
  515. forcedinline void handleEdgeTablePixelFull (const int x) const noexcept
  516. {
  517. if (replaceExisting)
  518. getPixel (x)->set (sourceColour);
  519. else
  520. getPixel (x)->blend (sourceColour);
  521. }
  522. forcedinline void handleEdgeTableLine (const int x, const int width, const int alphaLevel) const noexcept
  523. {
  524. PixelARGB p (sourceColour);
  525. p.multiplyAlpha (alphaLevel);
  526. PixelType* dest = getPixel (x);
  527. if (replaceExisting || p.getAlpha() >= 0xff)
  528. replaceLine (dest, p, width);
  529. else
  530. blendLine (dest, p, width);
  531. }
  532. forcedinline void handleEdgeTableLineFull (const int x, const int width) const noexcept
  533. {
  534. PixelType* dest = getPixel (x);
  535. if (replaceExisting || sourceColour.getAlpha() >= 0xff)
  536. replaceLine (dest, sourceColour, width);
  537. else
  538. blendLine (dest, sourceColour, width);
  539. }
  540. private:
  541. const Image::BitmapData& destData;
  542. PixelType* linePixels;
  543. PixelARGB sourceColour;
  544. PixelRGB filler [4];
  545. bool areRGBComponentsEqual;
  546. forcedinline PixelType* getPixel (const int x) const noexcept
  547. {
  548. return addBytesToPointer (linePixels, x * destData.pixelStride);
  549. }
  550. inline void blendLine (PixelType* dest, const PixelARGB colour, int width) const noexcept
  551. {
  552. JUCE_PERFORM_PIXEL_OP_LOOP (blend (colour))
  553. }
  554. forcedinline void replaceLine (PixelRGB* dest, const PixelARGB colour, int width) const noexcept
  555. {
  556. if (destData.pixelStride == sizeof (*dest))
  557. {
  558. if (areRGBComponentsEqual) // if all the component values are the same, we can cheat..
  559. {
  560. memset (dest, colour.getRed(), (size_t) width * 3);
  561. }
  562. else
  563. {
  564. if (width >> 5)
  565. {
  566. const int* const intFiller = reinterpret_cast<const int*> (filler);
  567. while (width > 8 && (((pointer_sized_int) dest) & 7) != 0)
  568. {
  569. dest->set (colour);
  570. ++dest;
  571. --width;
  572. }
  573. while (width > 4)
  574. {
  575. int* d = reinterpret_cast<int*> (dest);
  576. *d++ = intFiller[0];
  577. *d++ = intFiller[1];
  578. *d++ = intFiller[2];
  579. dest = reinterpret_cast<PixelRGB*> (d);
  580. width -= 4;
  581. }
  582. }
  583. while (--width >= 0)
  584. {
  585. dest->set (colour);
  586. ++dest;
  587. }
  588. }
  589. }
  590. else
  591. {
  592. JUCE_PERFORM_PIXEL_OP_LOOP (set (colour))
  593. }
  594. }
  595. forcedinline void replaceLine (PixelAlpha* dest, const PixelARGB colour, int width) const noexcept
  596. {
  597. if (destData.pixelStride == sizeof (*dest))
  598. memset (dest, colour.getAlpha(), (size_t) width);
  599. else
  600. JUCE_PERFORM_PIXEL_OP_LOOP (setAlpha (colour.getAlpha()))
  601. }
  602. forcedinline void replaceLine (PixelARGB* dest, const PixelARGB colour, int width) const noexcept
  603. {
  604. JUCE_PERFORM_PIXEL_OP_LOOP (set (colour))
  605. }
  606. JUCE_DECLARE_NON_COPYABLE (SolidColour)
  607. };
  608. //==============================================================================
  609. /** Fills an edge-table with a gradient. */
  610. template <class PixelType, class GradientType>
  611. class Gradient : public GradientType
  612. {
  613. public:
  614. Gradient (const Image::BitmapData& dest, const ColourGradient& gradient, const AffineTransform& transform,
  615. const PixelARGB* const colours, const int numColours)
  616. : GradientType (gradient, transform, colours, numColours - 1),
  617. destData (dest)
  618. {
  619. }
  620. forcedinline void setEdgeTableYPos (const int y) noexcept
  621. {
  622. linePixels = (PixelType*) destData.getLinePointer (y);
  623. GradientType::setY (y);
  624. }
  625. forcedinline void handleEdgeTablePixel (const int x, const int alphaLevel) const noexcept
  626. {
  627. getPixel (x)->blend (GradientType::getPixel (x), (uint32) alphaLevel);
  628. }
  629. forcedinline void handleEdgeTablePixelFull (const int x) const noexcept
  630. {
  631. getPixel (x)->blend (GradientType::getPixel (x));
  632. }
  633. void handleEdgeTableLine (int x, int width, const int alphaLevel) const noexcept
  634. {
  635. PixelType* dest = getPixel (x);
  636. if (alphaLevel < 0xff)
  637. JUCE_PERFORM_PIXEL_OP_LOOP (blend (GradientType::getPixel (x++), (uint32) alphaLevel))
  638. else
  639. JUCE_PERFORM_PIXEL_OP_LOOP (blend (GradientType::getPixel (x++)))
  640. }
  641. void handleEdgeTableLineFull (int x, int width) const noexcept
  642. {
  643. PixelType* dest = getPixel (x);
  644. JUCE_PERFORM_PIXEL_OP_LOOP (blend (GradientType::getPixel (x++)))
  645. }
  646. private:
  647. const Image::BitmapData& destData;
  648. PixelType* linePixels;
  649. forcedinline PixelType* getPixel (const int x) const noexcept
  650. {
  651. return addBytesToPointer (linePixels, x * destData.pixelStride);
  652. }
  653. JUCE_DECLARE_NON_COPYABLE (Gradient)
  654. };
  655. //==============================================================================
  656. /** Fills an edge-table with a non-transformed image. */
  657. template <class DestPixelType, class SrcPixelType, bool repeatPattern>
  658. class ImageFill
  659. {
  660. public:
  661. ImageFill (const Image::BitmapData& dest, const Image::BitmapData& src,
  662. const int alpha, const int x, const int y)
  663. : destData (dest),
  664. srcData (src),
  665. extraAlpha (alpha + 1),
  666. xOffset (repeatPattern ? negativeAwareModulo (x, src.width) - src.width : x),
  667. yOffset (repeatPattern ? negativeAwareModulo (y, src.height) - src.height : y)
  668. {
  669. }
  670. forcedinline void setEdgeTableYPos (int y) noexcept
  671. {
  672. linePixels = (DestPixelType*) destData.getLinePointer (y);
  673. y -= yOffset;
  674. if (repeatPattern)
  675. {
  676. jassert (y >= 0);
  677. y %= srcData.height;
  678. }
  679. sourceLineStart = (SrcPixelType*) srcData.getLinePointer (y);
  680. }
  681. forcedinline void handleEdgeTablePixel (const int x, int alphaLevel) const noexcept
  682. {
  683. alphaLevel = (alphaLevel * extraAlpha) >> 8;
  684. getDestPixel (x)->blend (*getSrcPixel (repeatPattern ? ((x - xOffset) % srcData.width) : (x - xOffset)), (uint32) alphaLevel);
  685. }
  686. forcedinline void handleEdgeTablePixelFull (const int x) const noexcept
  687. {
  688. getDestPixel (x)->blend (*getSrcPixel (repeatPattern ? ((x - xOffset) % srcData.width) : (x - xOffset)), (uint32) extraAlpha);
  689. }
  690. void handleEdgeTableLine (int x, int width, int alphaLevel) const noexcept
  691. {
  692. DestPixelType* dest = getDestPixel (x);
  693. alphaLevel = (alphaLevel * extraAlpha) >> 8;
  694. x -= xOffset;
  695. if (repeatPattern)
  696. {
  697. if (alphaLevel < 0xfe)
  698. JUCE_PERFORM_PIXEL_OP_LOOP (blend (*getSrcPixel (x++ % srcData.width), (uint32) alphaLevel))
  699. else
  700. JUCE_PERFORM_PIXEL_OP_LOOP (blend (*getSrcPixel (x++ % srcData.width)))
  701. }
  702. else
  703. {
  704. jassert (x >= 0 && x + width <= srcData.width);
  705. if (alphaLevel < 0xfe)
  706. JUCE_PERFORM_PIXEL_OP_LOOP (blend (*getSrcPixel (x++), (uint32) alphaLevel))
  707. else
  708. copyRow (dest, getSrcPixel (x), width);
  709. }
  710. }
  711. void handleEdgeTableLineFull (int x, int width) const noexcept
  712. {
  713. DestPixelType* dest = getDestPixel (x);
  714. x -= xOffset;
  715. if (repeatPattern)
  716. {
  717. if (extraAlpha < 0xfe)
  718. JUCE_PERFORM_PIXEL_OP_LOOP (blend (*getSrcPixel (x++ % srcData.width), (uint32) extraAlpha))
  719. else
  720. JUCE_PERFORM_PIXEL_OP_LOOP (blend (*getSrcPixel (x++ % srcData.width)))
  721. }
  722. else
  723. {
  724. jassert (x >= 0 && x + width <= srcData.width);
  725. if (extraAlpha < 0xfe)
  726. JUCE_PERFORM_PIXEL_OP_LOOP (blend (*getSrcPixel (x++), (uint32) extraAlpha))
  727. else
  728. copyRow (dest, getSrcPixel (x), width);
  729. }
  730. }
  731. void clipEdgeTableLine (EdgeTable& et, int x, int y, int width)
  732. {
  733. jassert (x - xOffset >= 0 && x + width - xOffset <= srcData.width);
  734. SrcPixelType* s = (SrcPixelType*) srcData.getLinePointer (y - yOffset);
  735. uint8* mask = (uint8*) (s + x - xOffset);
  736. if (sizeof (SrcPixelType) == sizeof (PixelARGB))
  737. mask += PixelARGB::indexA;
  738. et.clipLineToMask (x, y, mask, sizeof (SrcPixelType), width);
  739. }
  740. private:
  741. const Image::BitmapData& destData;
  742. const Image::BitmapData& srcData;
  743. const int extraAlpha, xOffset, yOffset;
  744. DestPixelType* linePixels;
  745. SrcPixelType* sourceLineStart;
  746. forcedinline DestPixelType* getDestPixel (int const x) const noexcept
  747. {
  748. return addBytesToPointer (linePixels, x * destData.pixelStride);
  749. }
  750. forcedinline SrcPixelType const* getSrcPixel (int const x) const noexcept
  751. {
  752. return addBytesToPointer (sourceLineStart, x * srcData.pixelStride);
  753. }
  754. forcedinline void copyRow (DestPixelType* dest, SrcPixelType const* src, int width) const noexcept
  755. {
  756. const int destStride = destData.pixelStride;
  757. const int srcStride = srcData.pixelStride;
  758. if (destStride == srcStride
  759. && srcData.pixelFormat == Image::RGB
  760. && destData.pixelFormat == Image::RGB)
  761. {
  762. memcpy (dest, src, (size_t) (width * srcStride));
  763. }
  764. else
  765. {
  766. do
  767. {
  768. dest->blend (*src);
  769. dest = addBytesToPointer (dest, destStride);
  770. src = addBytesToPointer (src, srcStride);
  771. } while (--width > 0);
  772. }
  773. }
  774. JUCE_DECLARE_NON_COPYABLE (ImageFill)
  775. };
  776. //==============================================================================
  777. /** Fills an edge-table with a transformed image. */
  778. template <class DestPixelType, class SrcPixelType, bool repeatPattern>
  779. class TransformedImageFill
  780. {
  781. public:
  782. TransformedImageFill (const Image::BitmapData& dest, const Image::BitmapData& src,
  783. const AffineTransform& transform, const int alpha, const Graphics::ResamplingQuality q)
  784. : interpolator (transform,
  785. q != Graphics::lowResamplingQuality ? 0.5f : 0.0f,
  786. q != Graphics::lowResamplingQuality ? -128 : 0),
  787. destData (dest),
  788. srcData (src),
  789. extraAlpha (alpha + 1),
  790. quality (q),
  791. maxX (src.width - 1),
  792. maxY (src.height - 1),
  793. scratchSize (2048)
  794. {
  795. scratchBuffer.malloc (scratchSize);
  796. }
  797. forcedinline void setEdgeTableYPos (const int newY) noexcept
  798. {
  799. y = newY;
  800. linePixels = (DestPixelType*) destData.getLinePointer (newY);
  801. }
  802. forcedinline void handleEdgeTablePixel (const int x, const int alphaLevel) noexcept
  803. {
  804. SrcPixelType p;
  805. generate (&p, x, 1);
  806. getDestPixel (x)->blend (p, (uint32) (alphaLevel * extraAlpha) >> 8);
  807. }
  808. forcedinline void handleEdgeTablePixelFull (const int x) noexcept
  809. {
  810. SrcPixelType p;
  811. generate (&p, x, 1);
  812. getDestPixel (x)->blend (p, (uint32) extraAlpha);
  813. }
  814. void handleEdgeTableLine (const int x, int width, int alphaLevel) noexcept
  815. {
  816. if (width > (int) scratchSize)
  817. {
  818. scratchSize = (size_t) width;
  819. scratchBuffer.malloc (scratchSize);
  820. }
  821. SrcPixelType* span = scratchBuffer;
  822. generate (span, x, width);
  823. DestPixelType* dest = getDestPixel (x);
  824. alphaLevel *= extraAlpha;
  825. alphaLevel >>= 8;
  826. if (alphaLevel < 0xfe)
  827. JUCE_PERFORM_PIXEL_OP_LOOP (blend (*span++, (uint32) alphaLevel))
  828. else
  829. JUCE_PERFORM_PIXEL_OP_LOOP (blend (*span++))
  830. }
  831. forcedinline void handleEdgeTableLineFull (const int x, int width) noexcept
  832. {
  833. handleEdgeTableLine (x, width, 255);
  834. }
  835. void clipEdgeTableLine (EdgeTable& et, int x, int y_, int width)
  836. {
  837. if (width > (int) scratchSize)
  838. {
  839. scratchSize = (size_t) width;
  840. scratchBuffer.malloc (scratchSize);
  841. }
  842. y = y_;
  843. generate (scratchBuffer.getData(), x, width);
  844. et.clipLineToMask (x, y_,
  845. reinterpret_cast<uint8*> (scratchBuffer.getData()) + SrcPixelType::indexA,
  846. sizeof (SrcPixelType), width);
  847. }
  848. private:
  849. forcedinline DestPixelType* getDestPixel (const int x) const noexcept
  850. {
  851. return addBytesToPointer (linePixels, x * destData.pixelStride);
  852. }
  853. //==============================================================================
  854. template <class PixelType>
  855. void generate (PixelType* dest, const int x, int numPixels) noexcept
  856. {
  857. this->interpolator.setStartOfLine ((float) x, (float) y, numPixels);
  858. do
  859. {
  860. int hiResX, hiResY;
  861. this->interpolator.next (hiResX, hiResY);
  862. int loResX = hiResX >> 8;
  863. int loResY = hiResY >> 8;
  864. if (repeatPattern)
  865. {
  866. loResX = negativeAwareModulo (loResX, srcData.width);
  867. loResY = negativeAwareModulo (loResY, srcData.height);
  868. }
  869. if (quality != Graphics::lowResamplingQuality)
  870. {
  871. if (isPositiveAndBelow (loResX, maxX))
  872. {
  873. if (isPositiveAndBelow (loResY, maxY))
  874. {
  875. // In the centre of the image..
  876. render4PixelAverage (dest, this->srcData.getPixelPointer (loResX, loResY),
  877. hiResX & 255, hiResY & 255);
  878. ++dest;
  879. continue;
  880. }
  881. if (! repeatPattern)
  882. {
  883. // At a top or bottom edge..
  884. if (loResY < 0)
  885. render2PixelAverageX (dest, this->srcData.getPixelPointer (loResX, 0), hiResX & 255);
  886. else
  887. render2PixelAverageX (dest, this->srcData.getPixelPointer (loResX, maxY), hiResX & 255);
  888. ++dest;
  889. continue;
  890. }
  891. }
  892. else
  893. {
  894. if (isPositiveAndBelow (loResY, maxY) && ! repeatPattern)
  895. {
  896. // At a left or right hand edge..
  897. if (loResX < 0)
  898. render2PixelAverageY (dest, this->srcData.getPixelPointer (0, loResY), hiResY & 255);
  899. else
  900. render2PixelAverageY (dest, this->srcData.getPixelPointer (maxX, loResY), hiResY & 255);
  901. ++dest;
  902. continue;
  903. }
  904. }
  905. }
  906. if (! repeatPattern)
  907. {
  908. if (loResX < 0) loResX = 0;
  909. if (loResY < 0) loResY = 0;
  910. if (loResX > maxX) loResX = maxX;
  911. if (loResY > maxY) loResY = maxY;
  912. }
  913. dest->set (*(const PixelType*) this->srcData.getPixelPointer (loResX, loResY));
  914. ++dest;
  915. } while (--numPixels > 0);
  916. }
  917. //==============================================================================
  918. void render4PixelAverage (PixelARGB* const dest, const uint8* src, const int subPixelX, const int subPixelY) noexcept
  919. {
  920. uint32 c[4] = { 256 * 128, 256 * 128, 256 * 128, 256 * 128 };
  921. uint32 weight = (uint32) ((256 - subPixelX) * (256 - subPixelY));
  922. c[0] += weight * src[0];
  923. c[1] += weight * src[1];
  924. c[2] += weight * src[2];
  925. c[3] += weight * src[3];
  926. src += this->srcData.pixelStride;
  927. weight = (uint32) (subPixelX * (256 - subPixelY));
  928. c[0] += weight * src[0];
  929. c[1] += weight * src[1];
  930. c[2] += weight * src[2];
  931. c[3] += weight * src[3];
  932. src += this->srcData.lineStride;
  933. weight = (uint32) (subPixelX * subPixelY);
  934. c[0] += weight * src[0];
  935. c[1] += weight * src[1];
  936. c[2] += weight * src[2];
  937. c[3] += weight * src[3];
  938. src -= this->srcData.pixelStride;
  939. weight = (uint32) ((256 - subPixelX) * subPixelY);
  940. c[0] += weight * src[0];
  941. c[1] += weight * src[1];
  942. c[2] += weight * src[2];
  943. c[3] += weight * src[3];
  944. dest->setARGB ((uint8) (c[PixelARGB::indexA] >> 16),
  945. (uint8) (c[PixelARGB::indexR] >> 16),
  946. (uint8) (c[PixelARGB::indexG] >> 16),
  947. (uint8) (c[PixelARGB::indexB] >> 16));
  948. }
  949. void render2PixelAverageX (PixelARGB* const dest, const uint8* src, const uint32 subPixelX) noexcept
  950. {
  951. uint32 c[4] = { 128, 128, 128, 128 };
  952. uint32 weight = 256 - subPixelX;
  953. c[0] += weight * src[0];
  954. c[1] += weight * src[1];
  955. c[2] += weight * src[2];
  956. c[3] += weight * src[3];
  957. src += this->srcData.pixelStride;
  958. weight = subPixelX;
  959. c[0] += weight * src[0];
  960. c[1] += weight * src[1];
  961. c[2] += weight * src[2];
  962. c[3] += weight * src[3];
  963. dest->setARGB ((uint8) (c[PixelARGB::indexA] >> 8),
  964. (uint8) (c[PixelARGB::indexR] >> 8),
  965. (uint8) (c[PixelARGB::indexG] >> 8),
  966. (uint8) (c[PixelARGB::indexB] >> 8));
  967. }
  968. void render2PixelAverageY (PixelARGB* const dest, const uint8* src, const uint32 subPixelY) noexcept
  969. {
  970. uint32 c[4] = { 128, 128, 128, 128 };
  971. uint32 weight = 256 - subPixelY;
  972. c[0] += weight * src[0];
  973. c[1] += weight * src[1];
  974. c[2] += weight * src[2];
  975. c[3] += weight * src[3];
  976. src += this->srcData.lineStride;
  977. weight = subPixelY;
  978. c[0] += weight * src[0];
  979. c[1] += weight * src[1];
  980. c[2] += weight * src[2];
  981. c[3] += weight * src[3];
  982. dest->setARGB ((uint8) (c[PixelARGB::indexA] >> 8),
  983. (uint8) (c[PixelARGB::indexR] >> 8),
  984. (uint8) (c[PixelARGB::indexG] >> 8),
  985. (uint8) (c[PixelARGB::indexB] >> 8));
  986. }
  987. //==============================================================================
  988. void render4PixelAverage (PixelRGB* const dest, const uint8* src, const uint32 subPixelX, const uint32 subPixelY) noexcept
  989. {
  990. uint32 c[3] = { 256 * 128, 256 * 128, 256 * 128 };
  991. uint32 weight = (256 - subPixelX) * (256 - subPixelY);
  992. c[0] += weight * src[0];
  993. c[1] += weight * src[1];
  994. c[2] += weight * src[2];
  995. src += this->srcData.pixelStride;
  996. weight = subPixelX * (256 - subPixelY);
  997. c[0] += weight * src[0];
  998. c[1] += weight * src[1];
  999. c[2] += weight * src[2];
  1000. src += this->srcData.lineStride;
  1001. weight = subPixelX * subPixelY;
  1002. c[0] += weight * src[0];
  1003. c[1] += weight * src[1];
  1004. c[2] += weight * src[2];
  1005. src -= this->srcData.pixelStride;
  1006. weight = (256 - subPixelX) * subPixelY;
  1007. c[0] += weight * src[0];
  1008. c[1] += weight * src[1];
  1009. c[2] += weight * src[2];
  1010. dest->setARGB ((uint8) 255,
  1011. (uint8) (c[PixelRGB::indexR] >> 16),
  1012. (uint8) (c[PixelRGB::indexG] >> 16),
  1013. (uint8) (c[PixelRGB::indexB] >> 16));
  1014. }
  1015. void render2PixelAverageX (PixelRGB* const dest, const uint8* src, const uint32 subPixelX) noexcept
  1016. {
  1017. uint32 c[3] = { 128, 128, 128 };
  1018. const uint32 weight = 256 - subPixelX;
  1019. c[0] += weight * src[0];
  1020. c[1] += weight * src[1];
  1021. c[2] += weight * src[2];
  1022. src += this->srcData.pixelStride;
  1023. c[0] += subPixelX * src[0];
  1024. c[1] += subPixelX * src[1];
  1025. c[2] += subPixelX * src[2];
  1026. dest->setARGB ((uint8) 255,
  1027. (uint8) (c[PixelRGB::indexR] >> 8),
  1028. (uint8) (c[PixelRGB::indexG] >> 8),
  1029. (uint8) (c[PixelRGB::indexB] >> 8));
  1030. }
  1031. void render2PixelAverageY (PixelRGB* const dest, const uint8* src, const uint32 subPixelY) noexcept
  1032. {
  1033. uint32 c[3] = { 128, 128, 128 };
  1034. const uint32 weight = 256 - subPixelY;
  1035. c[0] += weight * src[0];
  1036. c[1] += weight * src[1];
  1037. c[2] += weight * src[2];
  1038. src += this->srcData.lineStride;
  1039. c[0] += subPixelY * src[0];
  1040. c[1] += subPixelY * src[1];
  1041. c[2] += subPixelY * src[2];
  1042. dest->setARGB ((uint8) 255,
  1043. (uint8) (c[PixelRGB::indexR] >> 8),
  1044. (uint8) (c[PixelRGB::indexG] >> 8),
  1045. (uint8) (c[PixelRGB::indexB] >> 8));
  1046. }
  1047. //==============================================================================
  1048. void render4PixelAverage (PixelAlpha* const dest, const uint8* src, const uint32 subPixelX, const uint32 subPixelY) noexcept
  1049. {
  1050. uint32 c = 256 * 128;
  1051. c += src[0] * ((256 - subPixelX) * (256 - subPixelY));
  1052. src += this->srcData.pixelStride;
  1053. c += src[1] * (subPixelX * (256 - subPixelY));
  1054. src += this->srcData.lineStride;
  1055. c += src[1] * (subPixelX * subPixelY);
  1056. src -= this->srcData.pixelStride;
  1057. c += src[0] * ((256 - subPixelX) * subPixelY);
  1058. *((uint8*) dest) = (uint8) (c >> 16);
  1059. }
  1060. void render2PixelAverageX (PixelAlpha* const dest, const uint8* src, const uint32 subPixelX) noexcept
  1061. {
  1062. uint32 c = 128;
  1063. c += src[0] * (256 - subPixelX);
  1064. src += this->srcData.pixelStride;
  1065. c += src[0] * subPixelX;
  1066. *((uint8*) dest) = (uint8) (c >> 8);
  1067. }
  1068. void render2PixelAverageY (PixelAlpha* const dest, const uint8* src, const uint32 subPixelY) noexcept
  1069. {
  1070. uint32 c = 128;
  1071. c += src[0] * (256 - subPixelY);
  1072. src += this->srcData.lineStride;
  1073. c += src[0] * subPixelY;
  1074. *((uint8*) dest) = (uint8) (c >> 8);
  1075. }
  1076. //==============================================================================
  1077. class TransformedImageSpanInterpolator
  1078. {
  1079. public:
  1080. TransformedImageSpanInterpolator (const AffineTransform& transform,
  1081. const float offsetFloat, const int offsetInt) noexcept
  1082. : inverseTransform (transform.inverted()),
  1083. pixelOffset (offsetFloat), pixelOffsetInt (offsetInt)
  1084. {}
  1085. void setStartOfLine (float sx, float sy, const int numPixels) noexcept
  1086. {
  1087. jassert (numPixels > 0);
  1088. sx += pixelOffset;
  1089. sy += pixelOffset;
  1090. float x1 = sx, y1 = sy;
  1091. sx += (float) numPixels;
  1092. inverseTransform.transformPoints (x1, y1, sx, sy);
  1093. xBresenham.set ((int) (x1 * 256.0f), (int) (sx * 256.0f), numPixels, pixelOffsetInt);
  1094. yBresenham.set ((int) (y1 * 256.0f), (int) (sy * 256.0f), numPixels, pixelOffsetInt);
  1095. }
  1096. void next (int& px, int& py) noexcept
  1097. {
  1098. px = xBresenham.n; xBresenham.stepToNext();
  1099. py = yBresenham.n; yBresenham.stepToNext();
  1100. }
  1101. private:
  1102. class BresenhamInterpolator
  1103. {
  1104. public:
  1105. BresenhamInterpolator() noexcept {}
  1106. void set (const int n1, const int n2, const int steps, const int offsetInt) noexcept
  1107. {
  1108. numSteps = steps;
  1109. step = (n2 - n1) / numSteps;
  1110. remainder = modulo = (n2 - n1) % numSteps;
  1111. n = n1 + offsetInt;
  1112. if (modulo <= 0)
  1113. {
  1114. modulo += numSteps;
  1115. remainder += numSteps;
  1116. --step;
  1117. }
  1118. modulo -= numSteps;
  1119. }
  1120. forcedinline void stepToNext() noexcept
  1121. {
  1122. modulo += remainder;
  1123. n += step;
  1124. if (modulo > 0)
  1125. {
  1126. modulo -= numSteps;
  1127. ++n;
  1128. }
  1129. }
  1130. int n;
  1131. private:
  1132. int numSteps, step, modulo, remainder;
  1133. };
  1134. const AffineTransform inverseTransform;
  1135. BresenhamInterpolator xBresenham, yBresenham;
  1136. const float pixelOffset;
  1137. const int pixelOffsetInt;
  1138. JUCE_DECLARE_NON_COPYABLE (TransformedImageSpanInterpolator)
  1139. };
  1140. //==============================================================================
  1141. TransformedImageSpanInterpolator interpolator;
  1142. const Image::BitmapData& destData;
  1143. const Image::BitmapData& srcData;
  1144. const int extraAlpha;
  1145. const Graphics::ResamplingQuality quality;
  1146. const int maxX, maxY;
  1147. int y;
  1148. DestPixelType* linePixels;
  1149. HeapBlock<SrcPixelType> scratchBuffer;
  1150. size_t scratchSize;
  1151. JUCE_DECLARE_NON_COPYABLE (TransformedImageFill)
  1152. };
  1153. //==============================================================================
  1154. template <class Iterator>
  1155. void renderImageTransformed (Iterator& iter, const Image::BitmapData& destData, const Image::BitmapData& srcData,
  1156. const int alpha, const AffineTransform& transform, Graphics::ResamplingQuality quality, bool tiledFill)
  1157. {
  1158. switch (destData.pixelFormat)
  1159. {
  1160. case Image::ARGB:
  1161. switch (srcData.pixelFormat)
  1162. {
  1163. case Image::ARGB:
  1164. if (tiledFill) { TransformedImageFill<PixelARGB, PixelARGB, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1165. else { TransformedImageFill<PixelARGB, PixelARGB, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1166. break;
  1167. case Image::RGB:
  1168. if (tiledFill) { TransformedImageFill<PixelARGB, PixelRGB, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1169. else { TransformedImageFill<PixelARGB, PixelRGB, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1170. break;
  1171. default:
  1172. if (tiledFill) { TransformedImageFill<PixelARGB, PixelAlpha, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1173. else { TransformedImageFill<PixelARGB, PixelAlpha, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1174. break;
  1175. }
  1176. break;
  1177. case Image::RGB:
  1178. switch (srcData.pixelFormat)
  1179. {
  1180. case Image::ARGB:
  1181. if (tiledFill) { TransformedImageFill<PixelRGB, PixelARGB, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1182. else { TransformedImageFill<PixelRGB, PixelARGB, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1183. break;
  1184. case Image::RGB:
  1185. if (tiledFill) { TransformedImageFill<PixelRGB, PixelRGB, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1186. else { TransformedImageFill<PixelRGB, PixelRGB, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1187. break;
  1188. default:
  1189. if (tiledFill) { TransformedImageFill<PixelRGB, PixelAlpha, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1190. else { TransformedImageFill<PixelRGB, PixelAlpha, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1191. break;
  1192. }
  1193. break;
  1194. default:
  1195. switch (srcData.pixelFormat)
  1196. {
  1197. case Image::ARGB:
  1198. if (tiledFill) { TransformedImageFill<PixelAlpha, PixelARGB, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1199. else { TransformedImageFill<PixelAlpha, PixelARGB, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1200. break;
  1201. case Image::RGB:
  1202. if (tiledFill) { TransformedImageFill<PixelAlpha, PixelRGB, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1203. else { TransformedImageFill<PixelAlpha, PixelRGB, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1204. break;
  1205. default:
  1206. if (tiledFill) { TransformedImageFill<PixelAlpha, PixelAlpha, true> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1207. else { TransformedImageFill<PixelAlpha, PixelAlpha, false> r (destData, srcData, transform, alpha, quality); iter.iterate (r); }
  1208. break;
  1209. }
  1210. break;
  1211. }
  1212. }
  1213. template <class Iterator>
  1214. void renderImageUntransformed (Iterator& iter, const Image::BitmapData& destData, const Image::BitmapData& srcData, const int alpha, int x, int y, bool tiledFill)
  1215. {
  1216. switch (destData.pixelFormat)
  1217. {
  1218. case Image::ARGB:
  1219. switch (srcData.pixelFormat)
  1220. {
  1221. case Image::ARGB:
  1222. if (tiledFill) { ImageFill<PixelARGB, PixelARGB, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1223. else { ImageFill<PixelARGB, PixelARGB, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1224. break;
  1225. case Image::RGB:
  1226. if (tiledFill) { ImageFill<PixelARGB, PixelRGB, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1227. else { ImageFill<PixelARGB, PixelRGB, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1228. break;
  1229. default:
  1230. if (tiledFill) { ImageFill<PixelARGB, PixelAlpha, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1231. else { ImageFill<PixelARGB, PixelAlpha, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1232. break;
  1233. }
  1234. break;
  1235. case Image::RGB:
  1236. switch (srcData.pixelFormat)
  1237. {
  1238. case Image::ARGB:
  1239. if (tiledFill) { ImageFill<PixelRGB, PixelARGB, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1240. else { ImageFill<PixelRGB, PixelARGB, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1241. break;
  1242. case Image::RGB:
  1243. if (tiledFill) { ImageFill<PixelRGB, PixelRGB, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1244. else { ImageFill<PixelRGB, PixelRGB, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1245. break;
  1246. default:
  1247. if (tiledFill) { ImageFill<PixelRGB, PixelAlpha, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1248. else { ImageFill<PixelRGB, PixelAlpha, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1249. break;
  1250. }
  1251. break;
  1252. default:
  1253. switch (srcData.pixelFormat)
  1254. {
  1255. case Image::ARGB:
  1256. if (tiledFill) { ImageFill<PixelAlpha, PixelARGB, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1257. else { ImageFill<PixelAlpha, PixelARGB, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1258. break;
  1259. case Image::RGB:
  1260. if (tiledFill) { ImageFill<PixelAlpha, PixelRGB, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1261. else { ImageFill<PixelAlpha, PixelRGB, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1262. break;
  1263. default:
  1264. if (tiledFill) { ImageFill<PixelAlpha, PixelAlpha, true> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1265. else { ImageFill<PixelAlpha, PixelAlpha, false> r (destData, srcData, alpha, x, y); iter.iterate (r); }
  1266. break;
  1267. }
  1268. break;
  1269. }
  1270. }
  1271. template <class Iterator, class DestPixelType>
  1272. void renderSolidFill (Iterator& iter, const Image::BitmapData& destData, const PixelARGB fillColour, const bool replaceContents, DestPixelType*)
  1273. {
  1274. if (replaceContents)
  1275. {
  1276. EdgeTableFillers::SolidColour<DestPixelType, true> r (destData, fillColour);
  1277. iter.iterate (r);
  1278. }
  1279. else
  1280. {
  1281. EdgeTableFillers::SolidColour<DestPixelType, false> r (destData, fillColour);
  1282. iter.iterate (r);
  1283. }
  1284. }
  1285. template <class Iterator, class DestPixelType>
  1286. void renderGradient (Iterator& iter, const Image::BitmapData& destData, const ColourGradient& g, const AffineTransform& transform,
  1287. const PixelARGB* const lookupTable, const int numLookupEntries, const bool isIdentity, DestPixelType*)
  1288. {
  1289. if (g.isRadial)
  1290. {
  1291. if (isIdentity)
  1292. {
  1293. EdgeTableFillers::Gradient<DestPixelType, GradientPixelIterators::Radial> renderer (destData, g, transform, lookupTable, numLookupEntries);
  1294. iter.iterate (renderer);
  1295. }
  1296. else
  1297. {
  1298. EdgeTableFillers::Gradient<DestPixelType, GradientPixelIterators::TransformedRadial> renderer (destData, g, transform, lookupTable, numLookupEntries);
  1299. iter.iterate (renderer);
  1300. }
  1301. }
  1302. else
  1303. {
  1304. EdgeTableFillers::Gradient<DestPixelType, GradientPixelIterators::Linear> renderer (destData, g, transform, lookupTable, numLookupEntries);
  1305. iter.iterate (renderer);
  1306. }
  1307. }
  1308. }
  1309. //==============================================================================
  1310. template <class SavedStateType>
  1311. struct ClipRegions
  1312. {
  1313. class Base : public SingleThreadedReferenceCountedObject
  1314. {
  1315. public:
  1316. Base() {}
  1317. virtual ~Base() {}
  1318. typedef ReferenceCountedObjectPtr<Base> Ptr;
  1319. virtual Ptr clone() const = 0;
  1320. virtual Ptr applyClipTo (const Ptr& target) const = 0;
  1321. virtual Ptr clipToRectangle (const Rectangle<int>&) = 0;
  1322. virtual Ptr clipToRectangleList (const RectangleList<int>&) = 0;
  1323. virtual Ptr excludeClipRectangle (const Rectangle<int>&) = 0;
  1324. virtual Ptr clipToPath (const Path&, const AffineTransform&) = 0;
  1325. virtual Ptr clipToEdgeTable (const EdgeTable& et) = 0;
  1326. virtual Ptr clipToImageAlpha (const Image&, const AffineTransform&, const Graphics::ResamplingQuality) = 0;
  1327. virtual void translate (Point<int> delta) = 0;
  1328. virtual bool clipRegionIntersects (const Rectangle<int>&) const = 0;
  1329. virtual Rectangle<int> getClipBounds() const = 0;
  1330. virtual void fillRectWithColour (SavedStateType&, const Rectangle<int>&, const PixelARGB colour, bool replaceContents) const = 0;
  1331. virtual void fillRectWithColour (SavedStateType&, const Rectangle<float>&, const PixelARGB colour) const = 0;
  1332. virtual void fillAllWithColour (SavedStateType&, const PixelARGB colour, bool replaceContents) const = 0;
  1333. virtual void fillAllWithGradient (SavedStateType&, ColourGradient&, const AffineTransform&, bool isIdentity) const = 0;
  1334. virtual void renderImageTransformed (SavedStateType&, const Image&, const int alpha, const AffineTransform&, Graphics::ResamplingQuality, bool tiledFill) const = 0;
  1335. virtual void renderImageUntransformed (SavedStateType&, const Image&, const int alpha, int x, int y, bool tiledFill) const = 0;
  1336. };
  1337. //==============================================================================
  1338. class EdgeTableRegion : public Base
  1339. {
  1340. public:
  1341. EdgeTableRegion (const EdgeTable& e) : edgeTable (e) {}
  1342. EdgeTableRegion (const Rectangle<int>& r) : edgeTable (r) {}
  1343. EdgeTableRegion (const Rectangle<float>& r) : edgeTable (r) {}
  1344. EdgeTableRegion (const RectangleList<int>& r) : edgeTable (r) {}
  1345. EdgeTableRegion (const RectangleList<float>& r) : edgeTable (r) {}
  1346. EdgeTableRegion (const Rectangle<int>& bounds, const Path& p, const AffineTransform& t) : edgeTable (bounds, p, t) {}
  1347. EdgeTableRegion (const EdgeTableRegion& other) : Base(), edgeTable (other.edgeTable) {}
  1348. typedef typename Base::Ptr Ptr;
  1349. Ptr clone() const { return new EdgeTableRegion (*this); }
  1350. Ptr applyClipTo (const Ptr& target) const { return target->clipToEdgeTable (edgeTable); }
  1351. Ptr clipToRectangle (const Rectangle<int>& r)
  1352. {
  1353. edgeTable.clipToRectangle (r);
  1354. return edgeTable.isEmpty() ? nullptr : this;
  1355. }
  1356. Ptr clipToRectangleList (const RectangleList<int>& r)
  1357. {
  1358. RectangleList<int> inverse (edgeTable.getMaximumBounds());
  1359. if (inverse.subtract (r))
  1360. for (const Rectangle<int>* i = inverse.begin(), * const e = inverse.end(); i != e; ++i)
  1361. edgeTable.excludeRectangle (*i);
  1362. return edgeTable.isEmpty() ? nullptr : this;
  1363. }
  1364. Ptr excludeClipRectangle (const Rectangle<int>& r)
  1365. {
  1366. edgeTable.excludeRectangle (r);
  1367. return edgeTable.isEmpty() ? nullptr : this;
  1368. }
  1369. Ptr clipToPath (const Path& p, const AffineTransform& transform)
  1370. {
  1371. EdgeTable et (edgeTable.getMaximumBounds(), p, transform);
  1372. edgeTable.clipToEdgeTable (et);
  1373. return edgeTable.isEmpty() ? nullptr : this;
  1374. }
  1375. Ptr clipToEdgeTable (const EdgeTable& et)
  1376. {
  1377. edgeTable.clipToEdgeTable (et);
  1378. return edgeTable.isEmpty() ? nullptr : this;
  1379. }
  1380. Ptr clipToImageAlpha (const Image& image, const AffineTransform& transform, const Graphics::ResamplingQuality quality)
  1381. {
  1382. const Image::BitmapData srcData (image, Image::BitmapData::readOnly);
  1383. if (transform.isOnlyTranslation())
  1384. {
  1385. // If our translation doesn't involve any distortion, just use a simple blit..
  1386. const int tx = (int) (transform.getTranslationX() * 256.0f);
  1387. const int ty = (int) (transform.getTranslationY() * 256.0f);
  1388. if (quality == Graphics::lowResamplingQuality || ((tx | ty) & 224) == 0)
  1389. {
  1390. const int imageX = ((tx + 128) >> 8);
  1391. const int imageY = ((ty + 128) >> 8);
  1392. if (image.getFormat() == Image::ARGB)
  1393. straightClipImage (srcData, imageX, imageY, (PixelARGB*) 0);
  1394. else
  1395. straightClipImage (srcData, imageX, imageY, (PixelAlpha*) 0);
  1396. return edgeTable.isEmpty() ? nullptr : this;
  1397. }
  1398. }
  1399. if (transform.isSingularity())
  1400. return Ptr();
  1401. {
  1402. Path p;
  1403. p.addRectangle (0, 0, (float) srcData.width, (float) srcData.height);
  1404. EdgeTable et2 (edgeTable.getMaximumBounds(), p, transform);
  1405. edgeTable.clipToEdgeTable (et2);
  1406. }
  1407. if (! edgeTable.isEmpty())
  1408. {
  1409. if (image.getFormat() == Image::ARGB)
  1410. transformedClipImage (srcData, transform, quality, (PixelARGB*) 0);
  1411. else
  1412. transformedClipImage (srcData, transform, quality, (PixelAlpha*) 0);
  1413. }
  1414. return edgeTable.isEmpty() ? nullptr : this;
  1415. }
  1416. void translate (Point<int> delta)
  1417. {
  1418. edgeTable.translate ((float) delta.x, delta.y);
  1419. }
  1420. bool clipRegionIntersects (const Rectangle<int>& r) const
  1421. {
  1422. return edgeTable.getMaximumBounds().intersects (r);
  1423. }
  1424. Rectangle<int> getClipBounds() const
  1425. {
  1426. return edgeTable.getMaximumBounds();
  1427. }
  1428. void fillRectWithColour (SavedStateType& state, const Rectangle<int>& area, const PixelARGB colour, bool replaceContents) const
  1429. {
  1430. const Rectangle<int> totalClip (edgeTable.getMaximumBounds());
  1431. const Rectangle<int> clipped (totalClip.getIntersection (area));
  1432. if (! clipped.isEmpty())
  1433. {
  1434. EdgeTableRegion et (clipped);
  1435. et.edgeTable.clipToEdgeTable (edgeTable);
  1436. state.fillWithSolidColour (et.edgeTable, colour, replaceContents);
  1437. }
  1438. }
  1439. void fillRectWithColour (SavedStateType& state, const Rectangle<float>& area, const PixelARGB colour) const
  1440. {
  1441. const Rectangle<float> totalClip (edgeTable.getMaximumBounds().toFloat());
  1442. const Rectangle<float> clipped (totalClip.getIntersection (area));
  1443. if (! clipped.isEmpty())
  1444. {
  1445. EdgeTableRegion et (clipped);
  1446. et.edgeTable.clipToEdgeTable (edgeTable);
  1447. state.fillWithSolidColour (et.edgeTable, colour, false);
  1448. }
  1449. }
  1450. void fillAllWithColour (SavedStateType& state, const PixelARGB colour, bool replaceContents) const
  1451. {
  1452. state.fillWithSolidColour (edgeTable, colour, replaceContents);
  1453. }
  1454. void fillAllWithGradient (SavedStateType& state, ColourGradient& gradient, const AffineTransform& transform, bool isIdentity) const
  1455. {
  1456. state.fillWithGradient (edgeTable, gradient, transform, isIdentity);
  1457. }
  1458. void renderImageTransformed (SavedStateType& state, const Image& src, const int alpha, const AffineTransform& transform, Graphics::ResamplingQuality quality, bool tiledFill) const
  1459. {
  1460. state.renderImageTransformed (edgeTable, src, alpha, transform, quality, tiledFill);
  1461. }
  1462. void renderImageUntransformed (SavedStateType& state, const Image& src, const int alpha, int x, int y, bool tiledFill) const
  1463. {
  1464. state.renderImageUntransformed (edgeTable, src, alpha, x, y, tiledFill);
  1465. }
  1466. EdgeTable edgeTable;
  1467. private:
  1468. template <class SrcPixelType>
  1469. void transformedClipImage (const Image::BitmapData& srcData, const AffineTransform& transform, const Graphics::ResamplingQuality quality, const SrcPixelType*)
  1470. {
  1471. EdgeTableFillers::TransformedImageFill<SrcPixelType, SrcPixelType, false> renderer (srcData, srcData, transform, 255, quality);
  1472. for (int y = 0; y < edgeTable.getMaximumBounds().getHeight(); ++y)
  1473. renderer.clipEdgeTableLine (edgeTable, edgeTable.getMaximumBounds().getX(), y + edgeTable.getMaximumBounds().getY(),
  1474. edgeTable.getMaximumBounds().getWidth());
  1475. }
  1476. template <class SrcPixelType>
  1477. void straightClipImage (const Image::BitmapData& srcData, int imageX, int imageY, const SrcPixelType*)
  1478. {
  1479. Rectangle<int> r (imageX, imageY, srcData.width, srcData.height);
  1480. edgeTable.clipToRectangle (r);
  1481. EdgeTableFillers::ImageFill<SrcPixelType, SrcPixelType, false> renderer (srcData, srcData, 255, imageX, imageY);
  1482. for (int y = 0; y < r.getHeight(); ++y)
  1483. renderer.clipEdgeTableLine (edgeTable, r.getX(), y + r.getY(), r.getWidth());
  1484. }
  1485. EdgeTableRegion& operator= (const EdgeTableRegion&);
  1486. };
  1487. //==============================================================================
  1488. class RectangleListRegion : public Base
  1489. {
  1490. public:
  1491. RectangleListRegion (const Rectangle<int>& r) : clip (r) {}
  1492. RectangleListRegion (const RectangleList<int>& r) : clip (r) {}
  1493. RectangleListRegion (const RectangleListRegion& other) : Base(), clip (other.clip) {}
  1494. typedef typename Base::Ptr Ptr;
  1495. Ptr clone() const { return new RectangleListRegion (*this); }
  1496. Ptr applyClipTo (const Ptr& target) const { return target->clipToRectangleList (clip); }
  1497. Ptr clipToRectangle (const Rectangle<int>& r)
  1498. {
  1499. clip.clipTo (r);
  1500. return clip.isEmpty() ? nullptr : this;
  1501. }
  1502. Ptr clipToRectangleList (const RectangleList<int>& r)
  1503. {
  1504. clip.clipTo (r);
  1505. return clip.isEmpty() ? nullptr : this;
  1506. }
  1507. Ptr excludeClipRectangle (const Rectangle<int>& r)
  1508. {
  1509. clip.subtract (r);
  1510. return clip.isEmpty() ? nullptr : this;
  1511. }
  1512. Ptr clipToPath (const Path& p, const AffineTransform& transform) { return toEdgeTable()->clipToPath (p, transform); }
  1513. Ptr clipToEdgeTable (const EdgeTable& et) { return toEdgeTable()->clipToEdgeTable (et); }
  1514. Ptr clipToImageAlpha (const Image& image, const AffineTransform& transform, const Graphics::ResamplingQuality quality)
  1515. {
  1516. return toEdgeTable()->clipToImageAlpha (image, transform, quality);
  1517. }
  1518. void translate (Point<int> delta) { clip.offsetAll (delta); }
  1519. bool clipRegionIntersects (const Rectangle<int>& r) const { return clip.intersects (r); }
  1520. Rectangle<int> getClipBounds() const { return clip.getBounds(); }
  1521. void fillRectWithColour (SavedStateType& state, const Rectangle<int>& area, const PixelARGB colour, bool replaceContents) const
  1522. {
  1523. SubRectangleIterator iter (clip, area);
  1524. state.fillWithSolidColour (iter, colour, replaceContents);
  1525. }
  1526. void fillRectWithColour (SavedStateType& state, const Rectangle<float>& area, const PixelARGB colour) const
  1527. {
  1528. SubRectangleIteratorFloat iter (clip, area);
  1529. state.fillWithSolidColour (iter, colour, false);
  1530. }
  1531. void fillAllWithColour (SavedStateType& state, const PixelARGB colour, bool replaceContents) const
  1532. {
  1533. state.fillWithSolidColour (*this, colour, replaceContents);
  1534. }
  1535. void fillAllWithGradient (SavedStateType& state, ColourGradient& gradient, const AffineTransform& transform, bool isIdentity) const
  1536. {
  1537. state.fillWithGradient (*this, gradient, transform, isIdentity);
  1538. }
  1539. void renderImageTransformed (SavedStateType& state, const Image& src, const int alpha, const AffineTransform& transform, Graphics::ResamplingQuality quality, bool tiledFill) const
  1540. {
  1541. state.renderImageTransformed (*this, src, alpha, transform, quality, tiledFill);
  1542. }
  1543. void renderImageUntransformed (SavedStateType& state, const Image& src, const int alpha, int x, int y, bool tiledFill) const
  1544. {
  1545. state.renderImageUntransformed (*this, src, alpha, x, y, tiledFill);
  1546. }
  1547. RectangleList<int> clip;
  1548. //==============================================================================
  1549. template <class Renderer>
  1550. void iterate (Renderer& r) const noexcept
  1551. {
  1552. for (const Rectangle<int>* i = clip.begin(), * const e = clip.end(); i != e; ++i)
  1553. {
  1554. const int x = i->getX();
  1555. const int w = i->getWidth();
  1556. jassert (w > 0);
  1557. const int bottom = i->getBottom();
  1558. for (int y = i->getY(); y < bottom; ++y)
  1559. {
  1560. r.setEdgeTableYPos (y);
  1561. r.handleEdgeTableLineFull (x, w);
  1562. }
  1563. }
  1564. }
  1565. private:
  1566. //==============================================================================
  1567. class SubRectangleIterator
  1568. {
  1569. public:
  1570. SubRectangleIterator (const RectangleList<int>& clipList, const Rectangle<int>& clipBounds)
  1571. : clip (clipList), area (clipBounds)
  1572. {}
  1573. template <class Renderer>
  1574. void iterate (Renderer& r) const noexcept
  1575. {
  1576. for (const Rectangle<int>* i = clip.begin(), * const e = clip.end(); i != e; ++i)
  1577. {
  1578. const Rectangle<int> rect (i->getIntersection (area));
  1579. if (! rect.isEmpty())
  1580. {
  1581. const int x = rect.getX();
  1582. const int w = rect.getWidth();
  1583. const int bottom = rect.getBottom();
  1584. for (int y = rect.getY(); y < bottom; ++y)
  1585. {
  1586. r.setEdgeTableYPos (y);
  1587. r.handleEdgeTableLineFull (x, w);
  1588. }
  1589. }
  1590. }
  1591. }
  1592. private:
  1593. const RectangleList<int>& clip;
  1594. const Rectangle<int> area;
  1595. JUCE_DECLARE_NON_COPYABLE (SubRectangleIterator)
  1596. };
  1597. //==============================================================================
  1598. class SubRectangleIteratorFloat
  1599. {
  1600. public:
  1601. SubRectangleIteratorFloat (const RectangleList<int>& clipList, const Rectangle<float>& clipBounds) noexcept
  1602. : clip (clipList), area (clipBounds)
  1603. {
  1604. }
  1605. template <class Renderer>
  1606. void iterate (Renderer& r) const noexcept
  1607. {
  1608. const RenderingHelpers::FloatRectangleRasterisingInfo f (area);
  1609. for (const Rectangle<int>* i = clip.begin(), * const e = clip.end(); i != e; ++i)
  1610. {
  1611. const int clipLeft = i->getX();
  1612. const int clipRight = i->getRight();
  1613. const int clipTop = i->getY();
  1614. const int clipBottom = i->getBottom();
  1615. if (f.totalBottom > clipTop && f.totalTop < clipBottom
  1616. && f.totalRight > clipLeft && f.totalLeft < clipRight)
  1617. {
  1618. if (f.isOnePixelWide())
  1619. {
  1620. if (f.topAlpha != 0 && f.totalTop >= clipTop)
  1621. {
  1622. r.setEdgeTableYPos (f.totalTop);
  1623. r.handleEdgeTablePixel (f.left, f.topAlpha);
  1624. }
  1625. const int endY = jmin (f.bottom, clipBottom);
  1626. for (int y = jmax (clipTop, f.top); y < endY; ++y)
  1627. {
  1628. r.setEdgeTableYPos (y);
  1629. r.handleEdgeTablePixelFull (f.left);
  1630. }
  1631. if (f.bottomAlpha != 0 && f.bottom < clipBottom)
  1632. {
  1633. r.setEdgeTableYPos (f.bottom);
  1634. r.handleEdgeTablePixel (f.left, f.bottomAlpha);
  1635. }
  1636. }
  1637. else
  1638. {
  1639. const int clippedLeft = jmax (f.left, clipLeft);
  1640. const int clippedWidth = jmin (f.right, clipRight) - clippedLeft;
  1641. const bool doLeftAlpha = f.leftAlpha != 0 && f.totalLeft >= clipLeft;
  1642. const bool doRightAlpha = f.rightAlpha != 0 && f.right < clipRight;
  1643. if (f.topAlpha != 0 && f.totalTop >= clipTop)
  1644. {
  1645. r.setEdgeTableYPos (f.totalTop);
  1646. if (doLeftAlpha) r.handleEdgeTablePixel (f.totalLeft, f.getTopLeftCornerAlpha());
  1647. if (clippedWidth > 0) r.handleEdgeTableLine (clippedLeft, clippedWidth, f.topAlpha);
  1648. if (doRightAlpha) r.handleEdgeTablePixel (f.right, f.getTopRightCornerAlpha());
  1649. }
  1650. const int endY = jmin (f.bottom, clipBottom);
  1651. for (int y = jmax (clipTop, f.top); y < endY; ++y)
  1652. {
  1653. r.setEdgeTableYPos (y);
  1654. if (doLeftAlpha) r.handleEdgeTablePixel (f.totalLeft, f.leftAlpha);
  1655. if (clippedWidth > 0) r.handleEdgeTableLineFull (clippedLeft, clippedWidth);
  1656. if (doRightAlpha) r.handleEdgeTablePixel (f.right, f.rightAlpha);
  1657. }
  1658. if (f.bottomAlpha != 0 && f.bottom < clipBottom)
  1659. {
  1660. r.setEdgeTableYPos (f.bottom);
  1661. if (doLeftAlpha) r.handleEdgeTablePixel (f.totalLeft, f.getBottomLeftCornerAlpha());
  1662. if (clippedWidth > 0) r.handleEdgeTableLine (clippedLeft, clippedWidth, f.bottomAlpha);
  1663. if (doRightAlpha) r.handleEdgeTablePixel (f.right, f.getBottomRightCornerAlpha());
  1664. }
  1665. }
  1666. }
  1667. }
  1668. }
  1669. private:
  1670. const RectangleList<int>& clip;
  1671. const Rectangle<float>& area;
  1672. JUCE_DECLARE_NON_COPYABLE (SubRectangleIteratorFloat)
  1673. };
  1674. Ptr toEdgeTable() const { return new EdgeTableRegion (clip); }
  1675. RectangleListRegion& operator= (const RectangleListRegion&);
  1676. };
  1677. };
  1678. //==============================================================================
  1679. template <class SavedStateType>
  1680. class SavedStateBase
  1681. {
  1682. public:
  1683. typedef typename ClipRegions<SavedStateType>::Base BaseRegionType;
  1684. typedef typename ClipRegions<SavedStateType>::EdgeTableRegion EdgeTableRegionType;
  1685. typedef typename ClipRegions<SavedStateType>::RectangleListRegion RectangleListRegionType;
  1686. SavedStateBase (const Rectangle<int>& initialClip)
  1687. : clip (new RectangleListRegionType (initialClip)), transform (Point<int>()),
  1688. interpolationQuality (Graphics::mediumResamplingQuality), transparencyLayerAlpha (1.0f)
  1689. {
  1690. }
  1691. SavedStateBase (const RectangleList<int>& clipList, Point<int> origin)
  1692. : clip (new RectangleListRegionType (clipList)), transform (origin),
  1693. interpolationQuality (Graphics::mediumResamplingQuality), transparencyLayerAlpha (1.0f)
  1694. {
  1695. }
  1696. SavedStateBase (const SavedStateBase& other)
  1697. : clip (other.clip), transform (other.transform), fillType (other.fillType),
  1698. interpolationQuality (other.interpolationQuality),
  1699. transparencyLayerAlpha (other.transparencyLayerAlpha)
  1700. {
  1701. }
  1702. SavedStateType& getThis() noexcept { return *static_cast<SavedStateType*> (this); }
  1703. bool clipToRectangle (const Rectangle<int>& r)
  1704. {
  1705. if (clip != nullptr)
  1706. {
  1707. if (transform.isOnlyTranslated)
  1708. {
  1709. cloneClipIfMultiplyReferenced();
  1710. clip = clip->clipToRectangle (transform.translated (r));
  1711. }
  1712. else if (! transform.isRotated)
  1713. {
  1714. cloneClipIfMultiplyReferenced();
  1715. clip = clip->clipToRectangle (transform.transformed (r));
  1716. }
  1717. else
  1718. {
  1719. Path p;
  1720. p.addRectangle (r);
  1721. clipToPath (p, AffineTransform::identity);
  1722. }
  1723. }
  1724. return clip != nullptr;
  1725. }
  1726. bool clipToRectangleList (const RectangleList<int>& r)
  1727. {
  1728. if (clip != nullptr)
  1729. {
  1730. if (transform.isOnlyTranslated)
  1731. {
  1732. cloneClipIfMultiplyReferenced();
  1733. RectangleList<int> offsetList (r);
  1734. offsetList.offsetAll (transform.offset.x, transform.offset.y);
  1735. clip = clip->clipToRectangleList (offsetList);
  1736. }
  1737. else if (! transform.isRotated)
  1738. {
  1739. cloneClipIfMultiplyReferenced();
  1740. RectangleList<int> scaledList;
  1741. for (const Rectangle<int>* i = r.begin(), * const e = r.end(); i != e; ++i)
  1742. scaledList.add (transform.transformed (*i));
  1743. clip = clip->clipToRectangleList (scaledList);
  1744. }
  1745. else
  1746. {
  1747. clipToPath (r.toPath(), AffineTransform::identity);
  1748. }
  1749. }
  1750. return clip != nullptr;
  1751. }
  1752. static Rectangle<int> getLargestIntegerWithin (Rectangle<float> r)
  1753. {
  1754. const int x1 = (int) std::ceil (r.getX());
  1755. const int y1 = (int) std::ceil (r.getY());
  1756. const int x2 = (int) std::floor (r.getRight());
  1757. const int y2 = (int) std::floor (r.getBottom());
  1758. return Rectangle<int> (x1, y1, x2 - x1, y2 - y1);
  1759. }
  1760. bool excludeClipRectangle (const Rectangle<int>& r)
  1761. {
  1762. if (clip != nullptr)
  1763. {
  1764. cloneClipIfMultiplyReferenced();
  1765. if (transform.isOnlyTranslated)
  1766. {
  1767. clip = clip->excludeClipRectangle (getLargestIntegerWithin (transform.translated (r.toFloat())));
  1768. }
  1769. else if (! transform.isRotated)
  1770. {
  1771. clip = clip->excludeClipRectangle (getLargestIntegerWithin (transform.transformed (r.toFloat())));
  1772. }
  1773. else
  1774. {
  1775. Path p;
  1776. p.addRectangle (r.toFloat());
  1777. p.applyTransform (transform.complexTransform);
  1778. p.addRectangle (clip->getClipBounds().toFloat());
  1779. p.setUsingNonZeroWinding (false);
  1780. clip = clip->clipToPath (p, AffineTransform::identity);
  1781. }
  1782. }
  1783. return clip != nullptr;
  1784. }
  1785. void clipToPath (const Path& p, const AffineTransform& t)
  1786. {
  1787. if (clip != nullptr)
  1788. {
  1789. cloneClipIfMultiplyReferenced();
  1790. clip = clip->clipToPath (p, transform.getTransformWith (t));
  1791. }
  1792. }
  1793. void clipToImageAlpha (const Image& sourceImage, const AffineTransform& t)
  1794. {
  1795. if (clip != nullptr)
  1796. {
  1797. if (sourceImage.hasAlphaChannel())
  1798. {
  1799. cloneClipIfMultiplyReferenced();
  1800. clip = clip->clipToImageAlpha (sourceImage, transform.getTransformWith (t), interpolationQuality);
  1801. }
  1802. else
  1803. {
  1804. Path p;
  1805. p.addRectangle (sourceImage.getBounds());
  1806. clipToPath (p, t);
  1807. }
  1808. }
  1809. }
  1810. bool clipRegionIntersects (const Rectangle<int>& r) const
  1811. {
  1812. if (clip != nullptr)
  1813. {
  1814. if (transform.isOnlyTranslated)
  1815. return clip->clipRegionIntersects (transform.translated (r));
  1816. return getClipBounds().intersects (r);
  1817. }
  1818. return false;
  1819. }
  1820. Rectangle<int> getClipBounds() const
  1821. {
  1822. return clip != nullptr ? transform.deviceSpaceToUserSpace (clip->getClipBounds())
  1823. : Rectangle<int>();
  1824. }
  1825. void setFillType (const FillType& newFill)
  1826. {
  1827. fillType = newFill;
  1828. }
  1829. void fillTargetRect (const Rectangle<int>& r, const bool replaceContents)
  1830. {
  1831. if (fillType.isColour())
  1832. {
  1833. clip->fillRectWithColour (getThis(), r, fillType.colour.getPixelARGB(), replaceContents);
  1834. }
  1835. else
  1836. {
  1837. const Rectangle<int> clipped (clip->getClipBounds().getIntersection (r));
  1838. if (! clipped.isEmpty())
  1839. fillShape (new RectangleListRegionType (clipped), false);
  1840. }
  1841. }
  1842. void fillTargetRect (const Rectangle<float>& r)
  1843. {
  1844. if (fillType.isColour())
  1845. {
  1846. clip->fillRectWithColour (getThis(), r, fillType.colour.getPixelARGB());
  1847. }
  1848. else
  1849. {
  1850. const Rectangle<float> clipped (clip->getClipBounds().toFloat().getIntersection (r));
  1851. if (! clipped.isEmpty())
  1852. fillShape (new EdgeTableRegionType (clipped), false);
  1853. }
  1854. }
  1855. template <typename CoordType>
  1856. void fillRectAsPath (const Rectangle<CoordType>& r)
  1857. {
  1858. Path p;
  1859. p.addRectangle (r);
  1860. fillPath (p, AffineTransform::identity);
  1861. }
  1862. void fillRect (const Rectangle<int>& r, const bool replaceContents)
  1863. {
  1864. if (clip != nullptr)
  1865. {
  1866. if (transform.isOnlyTranslated)
  1867. {
  1868. fillTargetRect (transform.translated (r), replaceContents);
  1869. }
  1870. else if (! transform.isRotated)
  1871. {
  1872. fillTargetRect (transform.transformed (r), replaceContents);
  1873. }
  1874. else
  1875. {
  1876. jassert (! replaceContents); // not implemented..
  1877. fillRectAsPath (r);
  1878. }
  1879. }
  1880. }
  1881. void fillRect (const Rectangle<float>& r)
  1882. {
  1883. if (clip != nullptr)
  1884. {
  1885. if (transform.isOnlyTranslated)
  1886. fillTargetRect (transform.translated (r));
  1887. else if (! transform.isRotated)
  1888. fillTargetRect (transform.transformed (r));
  1889. else
  1890. fillRectAsPath (r);
  1891. }
  1892. }
  1893. void fillRectList (const RectangleList<float>& list)
  1894. {
  1895. if (clip != nullptr)
  1896. {
  1897. if (! transform.isRotated)
  1898. {
  1899. RectangleList<float> transformed (list);
  1900. if (transform.isOnlyTranslated)
  1901. transformed.offsetAll (transform.offset.toFloat());
  1902. else
  1903. transformed.transformAll (transform.getTransform());
  1904. fillShape (new EdgeTableRegionType (transformed), false);
  1905. }
  1906. else
  1907. {
  1908. fillPath (list.toPath(), AffineTransform::identity);
  1909. }
  1910. }
  1911. }
  1912. void fillPath (const Path& path, const AffineTransform& t)
  1913. {
  1914. if (clip != nullptr)
  1915. fillShape (new EdgeTableRegionType (clip->getClipBounds(), path, transform.getTransformWith (t)), false);
  1916. }
  1917. void fillEdgeTable (const EdgeTable& edgeTable, const float x, const int y)
  1918. {
  1919. if (clip != nullptr)
  1920. {
  1921. EdgeTableRegionType* edgeTableClip = new EdgeTableRegionType (edgeTable);
  1922. edgeTableClip->edgeTable.translate (x, y);
  1923. if (fillType.isColour())
  1924. {
  1925. float brightness = fillType.colour.getBrightness() - 0.5f;
  1926. if (brightness > 0.0f)
  1927. edgeTableClip->edgeTable.multiplyLevels (1.0f + 1.6f * brightness);
  1928. }
  1929. fillShape (edgeTableClip, false);
  1930. }
  1931. }
  1932. void drawLine (const Line<float>& line)
  1933. {
  1934. Path p;
  1935. p.addLineSegment (line, 1.0f);
  1936. fillPath (p, AffineTransform::identity);
  1937. }
  1938. void drawImage (const Image& sourceImage, const AffineTransform& trans)
  1939. {
  1940. if (clip != nullptr && ! fillType.colour.isTransparent())
  1941. renderImage (sourceImage, trans, nullptr);
  1942. }
  1943. static bool isOnlyTranslationAllowingError (const AffineTransform& t)
  1944. {
  1945. return (std::abs (t.mat01) < 0.002)
  1946. && (std::abs (t.mat10) < 0.002)
  1947. && (std::abs (t.mat00 - 1.0f) < 0.002)
  1948. && (std::abs (t.mat11 - 1.0f) < 0.002);
  1949. }
  1950. void renderImage (const Image& sourceImage, const AffineTransform& trans,
  1951. const BaseRegionType* const tiledFillClipRegion)
  1952. {
  1953. const AffineTransform t (transform.getTransformWith (trans));
  1954. const int alpha = fillType.colour.getAlpha();
  1955. if (isOnlyTranslationAllowingError (t))
  1956. {
  1957. // If our translation doesn't involve any distortion, just use a simple blit..
  1958. int tx = (int) (t.getTranslationX() * 256.0f);
  1959. int ty = (int) (t.getTranslationY() * 256.0f);
  1960. if (interpolationQuality == Graphics::lowResamplingQuality || ((tx | ty) & 224) == 0)
  1961. {
  1962. tx = ((tx + 128) >> 8);
  1963. ty = ((ty + 128) >> 8);
  1964. if (tiledFillClipRegion != nullptr)
  1965. {
  1966. tiledFillClipRegion->renderImageUntransformed (getThis(), sourceImage, alpha, tx, ty, true);
  1967. }
  1968. else
  1969. {
  1970. Rectangle<int> area (tx, ty, sourceImage.getWidth(), sourceImage.getHeight());
  1971. area = area.getIntersection (getThis().getMaximumBounds());
  1972. if (! area.isEmpty())
  1973. if (typename BaseRegionType::Ptr c = clip->applyClipTo (new EdgeTableRegionType (area)))
  1974. c->renderImageUntransformed (getThis(), sourceImage, alpha, tx, ty, false);
  1975. }
  1976. return;
  1977. }
  1978. }
  1979. if (! t.isSingularity())
  1980. {
  1981. if (tiledFillClipRegion != nullptr)
  1982. {
  1983. tiledFillClipRegion->renderImageTransformed (getThis(), sourceImage, alpha, t, interpolationQuality, true);
  1984. }
  1985. else
  1986. {
  1987. Path p;
  1988. p.addRectangle (sourceImage.getBounds());
  1989. typename BaseRegionType::Ptr c (clip->clone());
  1990. c = c->clipToPath (p, t);
  1991. if (c != nullptr)
  1992. c->renderImageTransformed (getThis(), sourceImage, alpha, t, interpolationQuality, false);
  1993. }
  1994. }
  1995. }
  1996. void fillShape (typename BaseRegionType::Ptr shapeToFill, const bool replaceContents)
  1997. {
  1998. jassert (clip != nullptr);
  1999. shapeToFill = clip->applyClipTo (shapeToFill);
  2000. if (shapeToFill != nullptr)
  2001. {
  2002. if (fillType.isGradient())
  2003. {
  2004. jassert (! replaceContents); // that option is just for solid colours
  2005. ColourGradient g2 (*(fillType.gradient));
  2006. g2.multiplyOpacity (fillType.getOpacity());
  2007. AffineTransform t (transform.getTransformWith (fillType.transform).translated (-0.5f, -0.5f));
  2008. const bool isIdentity = t.isOnlyTranslation();
  2009. if (isIdentity)
  2010. {
  2011. // If our translation doesn't involve any distortion, we can speed it up..
  2012. g2.point1.applyTransform (t);
  2013. g2.point2.applyTransform (t);
  2014. t = AffineTransform::identity;
  2015. }
  2016. shapeToFill->fillAllWithGradient (getThis(), g2, t, isIdentity);
  2017. }
  2018. else if (fillType.isTiledImage())
  2019. {
  2020. renderImage (fillType.image, fillType.transform, shapeToFill);
  2021. }
  2022. else
  2023. {
  2024. shapeToFill->fillAllWithColour (getThis(), fillType.colour.getPixelARGB(), replaceContents);
  2025. }
  2026. }
  2027. }
  2028. void cloneClipIfMultiplyReferenced()
  2029. {
  2030. if (clip->getReferenceCount() > 1)
  2031. clip = clip->clone();
  2032. }
  2033. typename BaseRegionType::Ptr clip;
  2034. RenderingHelpers::TranslationOrTransform transform;
  2035. FillType fillType;
  2036. Graphics::ResamplingQuality interpolationQuality;
  2037. float transparencyLayerAlpha;
  2038. };
  2039. //==============================================================================
  2040. class SoftwareRendererSavedState : public SavedStateBase<SoftwareRendererSavedState>
  2041. {
  2042. typedef SavedStateBase<SoftwareRendererSavedState> BaseClass;
  2043. public:
  2044. SoftwareRendererSavedState (const Image& im, const Rectangle<int>& clipBounds)
  2045. : BaseClass (clipBounds), image (im)
  2046. {
  2047. }
  2048. SoftwareRendererSavedState (const Image& im, const RectangleList<int>& clipList, Point<int> origin)
  2049. : BaseClass (clipList, origin), image (im)
  2050. {
  2051. }
  2052. SoftwareRendererSavedState (const SoftwareRendererSavedState& other)
  2053. : BaseClass (other), image (other.image), font (other.font)
  2054. {
  2055. }
  2056. SoftwareRendererSavedState* beginTransparencyLayer (float opacity)
  2057. {
  2058. SoftwareRendererSavedState* s = new SoftwareRendererSavedState (*this);
  2059. if (clip != nullptr)
  2060. {
  2061. const Rectangle<int> layerBounds (clip->getClipBounds());
  2062. s->image = Image (Image::ARGB, layerBounds.getWidth(), layerBounds.getHeight(), true);
  2063. s->transparencyLayerAlpha = opacity;
  2064. s->transform.moveOriginInDeviceSpace (-layerBounds.getPosition());
  2065. s->cloneClipIfMultiplyReferenced();
  2066. s->clip->translate (-layerBounds.getPosition());
  2067. }
  2068. return s;
  2069. }
  2070. void endTransparencyLayer (SoftwareRendererSavedState& finishedLayerState)
  2071. {
  2072. if (clip != nullptr)
  2073. {
  2074. const Rectangle<int> layerBounds (clip->getClipBounds());
  2075. const ScopedPointer<LowLevelGraphicsContext> g (image.createLowLevelContext());
  2076. g->setOpacity (finishedLayerState.transparencyLayerAlpha);
  2077. g->drawImage (finishedLayerState.image, AffineTransform::translation (layerBounds.getPosition()));
  2078. }
  2079. }
  2080. typedef GlyphCache<CachedGlyphEdgeTable<SoftwareRendererSavedState>, SoftwareRendererSavedState> GlyphCacheType;
  2081. static void clearGlyphCache()
  2082. {
  2083. GlyphCacheType::getInstance().reset();
  2084. }
  2085. //==============================================================================
  2086. void drawGlyph (int glyphNumber, const AffineTransform& trans)
  2087. {
  2088. if (clip != nullptr)
  2089. {
  2090. if (trans.isOnlyTranslation() && ! transform.isRotated)
  2091. {
  2092. GlyphCacheType& cache = GlyphCacheType::getInstance();
  2093. Point<float> pos (trans.getTranslationX(), trans.getTranslationY());
  2094. if (transform.isOnlyTranslated)
  2095. {
  2096. cache.drawGlyph (*this, font, glyphNumber, pos + transform.offset.toFloat());
  2097. }
  2098. else
  2099. {
  2100. pos = transform.transformed (pos);
  2101. Font f (font);
  2102. f.setHeight (font.getHeight() * transform.complexTransform.mat11);
  2103. const float xScale = transform.complexTransform.mat00 / transform.complexTransform.mat11;
  2104. if (std::abs (xScale - 1.0f) > 0.01f)
  2105. f.setHorizontalScale (xScale);
  2106. cache.drawGlyph (*this, f, glyphNumber, pos);
  2107. }
  2108. }
  2109. else
  2110. {
  2111. const float fontHeight = font.getHeight();
  2112. AffineTransform t (transform.getTransformWith (AffineTransform::scale (fontHeight * font.getHorizontalScale(), fontHeight)
  2113. .followedBy (trans)));
  2114. const ScopedPointer<EdgeTable> et (font.getTypeface()->getEdgeTableForGlyph (glyphNumber, t, fontHeight));
  2115. if (et != nullptr)
  2116. fillShape (new EdgeTableRegionType (*et), false);
  2117. }
  2118. }
  2119. }
  2120. Rectangle<int> getMaximumBounds() const { return image.getBounds(); }
  2121. //==============================================================================
  2122. template <typename IteratorType>
  2123. void renderImageTransformed (IteratorType& iter, const Image& src, const int alpha, const AffineTransform& trans, Graphics::ResamplingQuality quality, bool tiledFill) const
  2124. {
  2125. Image::BitmapData destData (image, Image::BitmapData::readWrite);
  2126. const Image::BitmapData srcData (src, Image::BitmapData::readOnly);
  2127. EdgeTableFillers::renderImageTransformed (iter, destData, srcData, alpha, trans, quality, tiledFill);
  2128. }
  2129. template <typename IteratorType>
  2130. void renderImageUntransformed (IteratorType& iter, const Image& src, const int alpha, int x, int y, bool tiledFill) const
  2131. {
  2132. Image::BitmapData destData (image, Image::BitmapData::readWrite);
  2133. const Image::BitmapData srcData (src, Image::BitmapData::readOnly);
  2134. EdgeTableFillers::renderImageUntransformed (iter, destData, srcData, alpha, x, y, tiledFill);
  2135. }
  2136. template <typename IteratorType>
  2137. void fillWithSolidColour (IteratorType& iter, const PixelARGB colour, bool replaceContents) const
  2138. {
  2139. Image::BitmapData destData (image, Image::BitmapData::readWrite);
  2140. switch (destData.pixelFormat)
  2141. {
  2142. case Image::ARGB: EdgeTableFillers::renderSolidFill (iter, destData, colour, replaceContents, (PixelARGB*) 0); break;
  2143. case Image::RGB: EdgeTableFillers::renderSolidFill (iter, destData, colour, replaceContents, (PixelRGB*) 0); break;
  2144. default: EdgeTableFillers::renderSolidFill (iter, destData, colour, replaceContents, (PixelAlpha*) 0); break;
  2145. }
  2146. }
  2147. template <typename IteratorType>
  2148. void fillWithGradient (IteratorType& iter, ColourGradient& gradient, const AffineTransform& trans, bool isIdentity) const
  2149. {
  2150. HeapBlock<PixelARGB> lookupTable;
  2151. const int numLookupEntries = gradient.createLookupTable (trans, lookupTable);
  2152. jassert (numLookupEntries > 0);
  2153. Image::BitmapData destData (image, Image::BitmapData::readWrite);
  2154. switch (destData.pixelFormat)
  2155. {
  2156. case Image::ARGB: EdgeTableFillers::renderGradient (iter, destData, gradient, trans, lookupTable, numLookupEntries, isIdentity, (PixelARGB*) 0); break;
  2157. case Image::RGB: EdgeTableFillers::renderGradient (iter, destData, gradient, trans, lookupTable, numLookupEntries, isIdentity, (PixelRGB*) 0); break;
  2158. default: EdgeTableFillers::renderGradient (iter, destData, gradient, trans, lookupTable, numLookupEntries, isIdentity, (PixelAlpha*) 0); break;
  2159. }
  2160. }
  2161. //==============================================================================
  2162. Image image;
  2163. Font font;
  2164. private:
  2165. SoftwareRendererSavedState& operator= (const SoftwareRendererSavedState&);
  2166. };
  2167. //==============================================================================
  2168. template <class StateObjectType>
  2169. class SavedStateStack
  2170. {
  2171. public:
  2172. SavedStateStack (StateObjectType* const initialState) noexcept
  2173. : currentState (initialState)
  2174. {}
  2175. SavedStateStack() noexcept {}
  2176. void initialise (StateObjectType* state)
  2177. {
  2178. currentState = state;
  2179. }
  2180. inline StateObjectType* operator->() const noexcept { return currentState; }
  2181. inline StateObjectType& operator*() const noexcept { return *currentState; }
  2182. void save()
  2183. {
  2184. stack.add (new StateObjectType (*currentState));
  2185. }
  2186. void restore()
  2187. {
  2188. if (StateObjectType* const top = stack.getLast())
  2189. {
  2190. currentState = top;
  2191. stack.removeLast (1, false);
  2192. }
  2193. else
  2194. {
  2195. jassertfalse; // trying to pop with an empty stack!
  2196. }
  2197. }
  2198. void beginTransparencyLayer (float opacity)
  2199. {
  2200. save();
  2201. currentState = currentState->beginTransparencyLayer (opacity);
  2202. }
  2203. void endTransparencyLayer()
  2204. {
  2205. const ScopedPointer<StateObjectType> finishedTransparencyLayer (currentState);
  2206. restore();
  2207. currentState->endTransparencyLayer (*finishedTransparencyLayer);
  2208. }
  2209. private:
  2210. ScopedPointer<StateObjectType> currentState;
  2211. OwnedArray<StateObjectType> stack;
  2212. JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (SavedStateStack)
  2213. };
  2214. //==============================================================================
  2215. template <class SavedStateType>
  2216. class StackBasedLowLevelGraphicsContext : public LowLevelGraphicsContext
  2217. {
  2218. public:
  2219. bool isVectorDevice() const override { return false; }
  2220. void setOrigin (Point<int> o) override { stack->transform.setOrigin (o); }
  2221. void addTransform (const AffineTransform& t) override { stack->transform.addTransform (t); }
  2222. float getPhysicalPixelScaleFactor() override { return stack->transform.getPhysicalPixelScaleFactor(); }
  2223. Rectangle<int> getClipBounds() const override { return stack->getClipBounds(); }
  2224. bool isClipEmpty() const override { return stack->clip == nullptr; }
  2225. bool clipRegionIntersects (const Rectangle<int>& r) override { return stack->clipRegionIntersects (r); }
  2226. bool clipToRectangle (const Rectangle<int>& r) override { return stack->clipToRectangle (r); }
  2227. bool clipToRectangleList (const RectangleList<int>& r) override { return stack->clipToRectangleList (r); }
  2228. void excludeClipRectangle (const Rectangle<int>& r) override { stack->excludeClipRectangle (r); }
  2229. void clipToPath (const Path& path, const AffineTransform& t) override { stack->clipToPath (path, t); }
  2230. void clipToImageAlpha (const Image& im, const AffineTransform& t) override { stack->clipToImageAlpha (im, t); }
  2231. void saveState() override { stack.save(); }
  2232. void restoreState() override { stack.restore(); }
  2233. void beginTransparencyLayer (float opacity) override { stack.beginTransparencyLayer (opacity); }
  2234. void endTransparencyLayer() override { stack.endTransparencyLayer(); }
  2235. void setFill (const FillType& fillType) override { stack->setFillType (fillType); }
  2236. void setOpacity (float newOpacity) override { stack->fillType.setOpacity (newOpacity); }
  2237. void setInterpolationQuality (Graphics::ResamplingQuality quality) override { stack->interpolationQuality = quality; }
  2238. void fillRect (const Rectangle<int>& r, bool replace) override { stack->fillRect (r, replace); }
  2239. void fillRect (const Rectangle<float>& r) override { stack->fillRect (r); }
  2240. void fillRectList (const RectangleList<float>& list) override { stack->fillRectList (list); }
  2241. void fillPath (const Path& path, const AffineTransform& t) override { stack->fillPath (path, t); }
  2242. void drawImage (const Image& im, const AffineTransform& t) override { stack->drawImage (im, t); }
  2243. void drawGlyph (int glyphNumber, const AffineTransform& t) override { stack->drawGlyph (glyphNumber, t); }
  2244. void drawLine (const Line<float>& line) override { stack->drawLine (line); }
  2245. void setFont (const Font& newFont) override { stack->font = newFont; }
  2246. const Font& getFont() override { return stack->font; }
  2247. protected:
  2248. StackBasedLowLevelGraphicsContext (SavedStateType* initialState) : stack (initialState) {}
  2249. StackBasedLowLevelGraphicsContext() {}
  2250. RenderingHelpers::SavedStateStack<SavedStateType> stack;
  2251. };
  2252. }
  2253. #if JUCE_MSVC
  2254. #pragma warning (pop)
  2255. #endif
  2256. #endif // JUCE_RENDERINGHELPERS_H_INCLUDED