Add m-esr52 at 52.6.0

1 files changed, 211 insertions, 0 deletions

diff --git a/gfx/skia/patches/archive/fix-gradient-clamp.patch b/gfx/skia/patches/archive/fix-gradient-clamp.patch
new file mode 100644
index 000000000..91481c2c1
--- /dev/null
+++ b/gfx/skia/patches/archive/fix-gradient-clamp.patch
@@ -0,0 +1,211 @@
+diff --git a/gfx/skia/src/effects/SkGradientShader.cpp b/gfx/skia/src/effects/SkGradientShader.cpp
+--- a/gfx/skia/src/effects/SkGradientShader.cpp
++++ b/gfx/skia/src/effects/SkGradientShader.cpp
+@@ -167,16 +167,17 @@ private:
+ 
+     mutable uint16_t*   fCache16;   // working ptr. If this is NULL, we need to recompute the cache values
+     mutable SkPMColor*  fCache32;   // working ptr. If this is NULL, we need to recompute the cache values
+ 
+     mutable uint16_t*   fCache16Storage;    // storage for fCache16, allocated on demand
+     mutable SkMallocPixelRef* fCache32PixelRef;
+     mutable unsigned    fCacheAlpha;        // the alpha value we used when we computed the cache. larger than 8bits so we can store uninitialized value
+ 
++    static SkPMColor PremultiplyColor(SkColor c0, U8CPU alpha);
+     static void Build16bitCache(uint16_t[], SkColor c0, SkColor c1, int count);
+     static void Build32bitCache(SkPMColor[], SkColor c0, SkColor c1, int count,
+                                 U8CPU alpha);
+     void setCacheAlpha(U8CPU alpha) const;
+     void initCommon();
+ 
+     typedef SkShader INHERITED;
+ };
+@@ -512,16 +513,31 @@ static inline U8CPU dither_fixed_to_8(Sk
+  *  For dithering with premultiply, we want to ceiling the alpha component,
+  *  to ensure that it is always >= any color component.
+  */
+ static inline U8CPU dither_ceil_fixed_to_8(SkFixed n) {
+     n >>= 8;
+     return ((n << 1) - (n | (n >> 8))) >> 8;
+ }
+ 
++SkPMColor Gradient_Shader::PremultiplyColor(SkColor c0, U8CPU paintAlpha)
++{
++    SkFixed a = SkMulDiv255Round(SkColorGetA(c0), paintAlpha);
++    SkFixed r = SkColorGetR(c0);
++    SkFixed g = SkColorGetG(c0);
++    SkFixed b = SkColorGetB(c0);
++    
++    a = SkIntToFixed(a) + 0x8000;
++    r = SkIntToFixed(r) + 0x8000;
++    g = SkIntToFixed(g) + 0x8000;
++    b = SkIntToFixed(b) + 0x8000;
++        
++    return SkPremultiplyARGBInline(a >> 16, r >> 16, g >> 16, b >> 16);
++}
++
+ void Gradient_Shader::Build32bitCache(SkPMColor cache[], SkColor c0, SkColor c1,
+                                       int count, U8CPU paintAlpha) {
+     SkASSERT(count > 1);
+ 
+     // need to apply paintAlpha to our two endpoints
+     SkFixed a = SkMulDiv255Round(SkColorGetA(c0), paintAlpha);
+     SkFixed da;
+     {
+@@ -613,24 +629,24 @@ const uint16_t* Gradient_Shader::getCach
+         }
+     }
+     return fCache16;
+ }
+ 
+ const SkPMColor* Gradient_Shader::getCache32() const {
+     if (fCache32 == NULL) {
+         // double the count for dither entries
+-        const int entryCount = kCache32Count * 2;
++        const int entryCount = kCache32Count * 2 + 2;
+         const size_t allocSize = sizeof(SkPMColor) * entryCount;
+ 
+         if (NULL == fCache32PixelRef) {
+             fCache32PixelRef = SkNEW_ARGS(SkMallocPixelRef,
+                                           (NULL, allocSize, NULL));
+         }
+-        fCache32 = (SkPMColor*)fCache32PixelRef->getAddr();
++        fCache32 = (SkPMColor*)fCache32PixelRef->getAddr() + 1;
+         if (fColorCount == 2) {
+             Build32bitCache(fCache32, fOrigColors[0], fOrigColors[1],
+                             kCache32Count, fCacheAlpha);
+         } else {
+             Rec* rec = fRecs;
+             int prevIndex = 0;
+             for (int i = 1; i < fColorCount; i++) {
+                 int nextIndex = SkFixedToFFFF(rec[i].fPos) >> (16 - kCache32Bits);
+@@ -644,28 +660,31 @@ const SkPMColor* Gradient_Shader::getCac
+             }
+             SkASSERT(prevIndex == kCache32Count - 1);
+         }
+ 
+         if (fMapper) {
+             SkMallocPixelRef* newPR = SkNEW_ARGS(SkMallocPixelRef,
+                                                  (NULL, allocSize, NULL));
+             SkPMColor* linear = fCache32;           // just computed linear data
+-            SkPMColor* mapped = (SkPMColor*)newPR->getAddr();    // storage for mapped data
++            SkPMColor* mapped = (SkPMColor*)newPR->getAddr() + 1;    // storage for mapped data
+             SkUnitMapper* map = fMapper;
+             for (int i = 0; i < kCache32Count; i++) {
+                 int index = map->mapUnit16((i << 8) | i) >> 8;
+                 mapped[i] = linear[index];
+                 mapped[i + kCache32Count] = linear[index + kCache32Count];
+             }
+             fCache32PixelRef->unref();
+             fCache32PixelRef = newPR;
+-            fCache32 = (SkPMColor*)newPR->getAddr();
++            fCache32 = (SkPMColor*)newPR->getAddr() + 1;
+         }
+     }
++    //Write the clamp colours into the first and last entries of fCache32
++    fCache32[-1] = PremultiplyColor(fOrigColors[0], fCacheAlpha);
++    fCache32[kCache32Count * 2] = PremultiplyColor(fOrigColors[fColorCount - 1], fCacheAlpha);
+     return fCache32;
+ }
+ 
+ /*
+  *  Because our caller might rebuild the same (logically the same) gradient
+  *  over and over, we'd like to return exactly the same "bitmap" if possible,
+  *  allowing the client to utilize a cache of our bitmap (e.g. with a GPU).
+  *  To do that, we maintain a private cache of built-bitmaps, based on our
+@@ -875,28 +894,38 @@ void Linear_Gradient::shadeSpan(int x, i
+             dx = dxStorage[0];
+         } else {
+             SkASSERT(fDstToIndexClass == kLinear_MatrixClass);
+             dx = SkScalarToFixed(fDstToIndex.getScaleX());
+         }
+ 
+         if (SkFixedNearlyZero(dx)) {
+             // we're a vertical gradient, so no change in a span
+-            unsigned fi = proc(fx) >> (16 - kCache32Bits);
+-            sk_memset32_dither(dstC, cache[toggle + fi],
+-                                     cache[(toggle ^ TOGGLE_MASK) + fi], count);
++            if (proc == clamp_tileproc) {
++                if (fx < 0) {
++                    sk_memset32(dstC, cache[-1], count);
++                } else if (fx > 0xFFFF) {
++                    sk_memset32(dstC, cache[kCache32Count * 2], count);
++                } else {
++                    unsigned fi = proc(fx) >> (16 - kCache32Bits);
++                    sk_memset32_dither(dstC, cache[toggle + fi],
++                                       cache[(toggle ^ TOGGLE_MASK) + fi], count);
++                }
++            } else {
++                unsigned fi = proc(fx) >> (16 - kCache32Bits);
++                sk_memset32_dither(dstC, cache[toggle + fi],
++                                   cache[(toggle ^ TOGGLE_MASK) + fi], count);
++            }
+         } else if (proc == clamp_tileproc) {
+             SkClampRange range;
+-            range.init(fx, dx, count, 0, 0xFF);
++            range.init(fx, dx, count, cache[-1], cache[kCache32Count * 2]);
+ 
+             if ((count = range.fCount0) > 0) {
+-                sk_memset32_dither(dstC,
+-                                   cache[toggle + range.fV0],
+-                                   cache[(toggle ^ TOGGLE_MASK) + range.fV0],
+-                                   count);
++                 // Do we really want to dither the clamp values?
++                 sk_memset32(dstC, range.fV0, count);
+                 dstC += count;
+             }
+             if ((count = range.fCount1) > 0) {
+                 int unroll = count >> 3;
+                 fx = range.fFx1;
+                 for (int i = 0; i < unroll; i++) {
+                     NO_CHECK_ITER;  NO_CHECK_ITER;
+                     NO_CHECK_ITER;  NO_CHECK_ITER;
+@@ -905,20 +934,17 @@ void Linear_Gradient::shadeSpan(int x, i
+                 }
+                 if ((count &= 7) > 0) {
+                     do {
+                         NO_CHECK_ITER;
+                     } while (--count != 0);
+                 }
+             }
+             if ((count = range.fCount2) > 0) {
+-                sk_memset32_dither(dstC,
+-                                   cache[toggle + range.fV1],
+-                                   cache[(toggle ^ TOGGLE_MASK) + range.fV1],
+-                                   count);
++                sk_memset32(dstC, range.fV1, count);
+             }
+         } else if (proc == mirror_tileproc) {
+             do {
+                 unsigned fi = mirror_8bits(fx >> 8);
+                 SkASSERT(fi <= 0xFF);
+                 fx += dx;
+                 *dstC++ = cache[toggle + fi];
+                 toggle ^= TOGGLE_MASK;
+@@ -1670,19 +1699,24 @@ public:
+             }
+             SkScalar b = (SkScalarMul(fDiff.fX, fx) +
+                          SkScalarMul(fDiff.fY, fy) - fStartRadius) * 2;
+             SkScalar db = (SkScalarMul(fDiff.fX, dx) +
+                           SkScalarMul(fDiff.fY, dy)) * 2;
+             if (proc == clamp_tileproc) {
+                 for (; count > 0; --count) {
+                     SkFixed t = two_point_radial(b, fx, fy, fSr2D2, foura, fOneOverTwoA, posRoot);
+-                    SkFixed index = SkClampMax(t, 0xFFFF);
+-                    SkASSERT(index <= 0xFFFF);
+-                    *dstC++ = cache[index >> (16 - kCache32Bits)];
++                    if (t < 0) {
++                      *dstC++ = cache[-1];
++                    } else if (t > 0xFFFF) {
++                      *dstC++ = cache[kCache32Count * 2];
++                    } else {
++                      SkASSERT(t <= 0xFFFF);
++                      *dstC++ = cache[t >> (16 - kCache32Bits)];
++                    }
+                     fx += dx;
+                     fy += dy;
+                     b += db;
+                 }
+             } else if (proc == mirror_tileproc) {
+                 for (; count > 0; --count) {
+                     SkFixed t = two_point_radial(b, fx, fy, fSr2D2, foura, fOneOverTwoA, posRoot);
+                     SkFixed index = mirror_tileproc(t);