chromium/chromium-48.0.2564.103-gcc6.patch

diff -up chromium-48.0.2564.103/third_party/skia/src/opts/SkXfermode_opts.h.gcc6 chromium-48.0.2564.103/third_party/skia/src/opts/SkXfermode_opts.h
--- chromium-48.0.2564.103/third_party/skia/src/opts/SkXfermode_opts.h.gcc6	2016-02-16 15:01:13.200131996 -0500
+++ chromium-48.0.2564.103/third_party/skia/src/opts/SkXfermode_opts.h	2016-02-17 13:31:50.216198258 -0500
@@ -109,76 +109,71 @@ XFERMODE(Lighten) {
 }
 #undef XFERMODE
 
-// Some xfermodes use math like divide or sqrt that's best done in floats.
-// We write it generically, then call it 1 or 2 pixels at a time (T == Sk4f or Sk8f).
-#define XFERMODE(Name) struct Name { template <typename T> T operator()(const T&, const T&); }; \
-    template <typename T> T Name::operator()(const T& d, const T& s)
+// Some xfermodes use math like divide or sqrt that's best done in floats 1 pixel at a time.
+#define XFERMODE(Name) static Sk4f SK_VECTORCALL Name(Sk4f d, Sk4f s)
 
-static_assert(SK_A32_SHIFT == 24, "");
 static inline Sk4f a_rgb(const Sk4f& a, const Sk4f& rgb) {
+    static_assert(SK_A32_SHIFT == 24, "");
     return a * Sk4f(0,0,0,1) + rgb * Sk4f(1,1,1,0);
 }
-static inline Sk8f a_rgb(const Sk8f& a, const Sk8f& rgb) {
-    // TODO: SkNx_blend<0,0,0,1,0,0,0,1>(a, rgb) to let us use _mm256_blend_ps?
-    return a * Sk8f(0,0,0,1,0,0,0,1) + rgb * Sk8f(1,1,1,0,1,1,1,0);
+static inline Sk4f alphas(const Sk4f& f) {
+    return SkNx_dup<SK_A32_SHIFT/8>(f);
 }
-static inline Sk4f alphas(const Sk4f& f) { return SkNx_shuffle<3,3,3,3>        (f); }
-static inline Sk8f alphas(const Sk8f& f) { return SkNx_shuffle<3,3,3,3,7,7,7,7>(f); }
 
 XFERMODE(ColorDodge) {
     auto sa = alphas(s),
          da = alphas(d),
-         isa = T(1)-sa,
-         ida = T(1)-da;
+         isa = Sk4f(1)-sa,
+         ida = Sk4f(1)-da;
 
     auto srcover = s + d*isa,
          dstover = d + s*ida,
-         otherwise = sa * T::Min(da, (d*sa)*(sa-s).approxInvert()) + s*ida + d*isa;
+         otherwise = sa * Sk4f::Min(da, (d*sa)*(sa-s).approxInvert()) + s*ida + d*isa;
 
     // Order matters here, preferring d==0 over s==sa.
-    auto colors = (d ==  0).thenElse(dstover,
-                  (s == sa).thenElse(srcover,
-                                     otherwise));
+    auto colors = (d == Sk4f(0)).thenElse(dstover,
+                  (s ==      sa).thenElse(srcover,
+                                          otherwise));
     return a_rgb(srcover, colors);
 }
 XFERMODE(ColorBurn) {
     auto sa = alphas(s),
          da = alphas(d),
-         isa = T(1)-sa,
-         ida = T(1)-da;
+         isa = Sk4f(1)-sa,
+         ida = Sk4f(1)-da;
 
     auto srcover = s + d*isa,
          dstover = d + s*ida,
-         otherwise = sa*(da-T::Min(da, (da-d)*sa*s.approxInvert())) + s*ida + d*isa;
+         otherwise = sa*(da-Sk4f::Min(da, (da-d)*sa*s.approxInvert())) + s*ida + d*isa;
 
     // Order matters here, preferring d==da over s==0.
-    auto colors = (d == da).thenElse(dstover,
-                  (s ==  0).thenElse(srcover,
-                                     otherwise));
+    auto colors = (d ==      da).thenElse(dstover,
+                  (s == Sk4f(0)).thenElse(srcover,
+                                          otherwise));
     return a_rgb(srcover, colors);
 }
 XFERMODE(SoftLight) {
     auto sa = alphas(s),
          da = alphas(d),
-         isa = T(1)-sa,
-         ida = T(1)-da;
+         isa = Sk4f(1)-sa,
+         ida = Sk4f(1)-da;
 
     // Some common terms.
-    auto m  = (da > 0).thenElse(d / da, 0),
-         s2 = s*2,
-         m4 = m*4;
+    auto m  = (da > Sk4f(0)).thenElse(d / da, Sk4f(0)),
+         s2 = Sk4f(2)*s,
+         m4 = Sk4f(4)*m;
 
     // The logic forks three ways:
     //    1. dark src?
     //    2. light src, dark dst?
     //    3. light src, light dst?
-    auto darkSrc = d*(sa + (s2 - sa)*(T(1) - m)),  // Used in case 1.
-         darkDst = (m4*m4 + m4)*(m - 1) + m*7,     // Used in case 2.
-         liteDst = m.sqrt() - m,                   // Used in case 3.
-         liteSrc = d*sa + da*(s2-sa)*(d*4 <= da).thenElse(darkDst, liteDst); // Case 2 or 3?
+    auto darkSrc = d*(sa + (s2 - sa)*(Sk4f(1) - m)),        // Used in case 1.
+         darkDst = (m4*m4 + m4)*(m - Sk4f(1)) + Sk4f(7)*m,  // Used in case 2.
+         liteDst = m.sqrt() - m,                            // Used in case 3.
+         liteSrc = d*sa + da*(s2-sa)*(Sk4f(4)*d <= da).thenElse(darkDst, liteDst); // Case 2 or 3?
 
     auto alpha  = s + d*isa;
-    auto colors = s*ida + d*isa + (s2 <= sa).thenElse(darkSrc, liteSrc);     // Case 1 or 2/3?
+    auto colors = s*ida + d*isa + (s2 <= sa).thenElse(darkSrc, liteSrc);           // Case 1 or 2/3?
 
     return a_rgb(alpha, colors);
 }
@@ -245,52 +240,53 @@ private:
     typedef SkProcCoeffXfermode INHERITED;
 };
 
-template <typename BlendFn>
-class FloatXfermode : public SkProcCoeffXfermode {
+class Sk4fXfermode : public SkProcCoeffXfermode {
 public:
-    FloatXfermode(const ProcCoeff& rec, SkXfermode::Mode mode)
-        : INHERITED(rec, mode) {}
+    typedef Sk4f (SK_VECTORCALL *ProcF)(Sk4f, Sk4f);
+    Sk4fXfermode(const ProcCoeff& rec, SkXfermode::Mode mode, ProcF procf)
+        : INHERITED(rec, mode)
+        , fProcF(procf) {}
 
     void xfer32(SkPMColor dst[], const SkPMColor src[], int n, const SkAlpha aa[]) const override {
-        BlendFn blend;
-        while (n >= 2) {
-            auto d = Sk8f::FromBytes((const uint8_t*)dst) * (1.0f/255),
-                 s = Sk8f::FromBytes((const uint8_t*)src) * (1.0f/255),
-                 b = blend(d, s);
-            if (aa) {
-                auto a255 = Sk8f(aa[0],aa[0],aa[0],aa[0], aa[1],aa[1],aa[1],aa[1]);
-                (b*a255 + d*(Sk8f(255)-a255) + 0.5).toBytes((uint8_t*)dst);
-                aa += 2;
-            } else {
-                (b * 255 + 0.5).toBytes((uint8_t*)dst);
-            }
-            dst += 2;
-            src += 2;
-            n   -= 2;
-        }
-        if (n) {
-            auto d = Sk4f::FromBytes((const uint8_t*)dst) * (1.0f/255),
-                 s = Sk4f::FromBytes((const uint8_t*)src) * (1.0f/255),
-                 b = blend(d, s);
-            if (aa) {
-                auto a255 = Sk4f(aa[0],aa[0],aa[0],aa[0]);
-                (b*a255 + d*(Sk4f(255)-a255) + 0.5).toBytes((uint8_t*)dst);
-                aa++;
-            } else {
-                (b * 255 + 0.5).toBytes((uint8_t*)dst);
-            }
+        for (int i = 0; i < n; i++) {
+            dst[i] = aa ? this->xfer32(dst[i], src[i], aa[i])
+                        : this->xfer32(dst[i], src[i]);
         }
     }
 
     void xfer16(uint16_t dst[], const SkPMColor src[], int n, const SkAlpha aa[]) const override {
         for (int i = 0; i < n; i++) {
-            SkPMColor dst32 = SkPixel16ToPixel32(dst[i]);           // Convert dst up to 8888.
-            this->xfer32(&dst32, src+i, 1, aa ? aa+i : nullptr);    // Blend 1 pixel.
-            dst[i] = SkPixel32ToPixel16(dst32);                     // Repack dst to 565 and store.
+            SkPMColor dst32 = SkPixel16ToPixel32(dst[i]);
+            dst32 = aa ? this->xfer32(dst32, src[i], aa[i])
+                       : this->xfer32(dst32, src[i]);
+            dst[i] = SkPixel32ToPixel16(dst32);
         }
     }
 
 private:
+    static Sk4f Load(SkPMColor c) {
+        return Sk4f::FromBytes((uint8_t*)&c) * Sk4f(1.0f/255);
+    }
+    static SkPMColor Round(const Sk4f& f) {
+        SkPMColor c;
+        (f * Sk4f(255) + Sk4f(0.5f)).toBytes((uint8_t*)&c);
+        return c;
+    }
+    inline SkPMColor xfer32(SkPMColor dst, SkPMColor src) const {
+        return Round(fProcF(Load(dst), Load(src)));
+    }
+
+    inline SkPMColor xfer32(SkPMColor dst, SkPMColor src, SkAlpha aa) const {
+        Sk4f s(Load(src)),
+             d(Load(dst)),
+             b(fProcF(d,s));
+        // We do aa in full float precision before going back down to bytes, because we can!
+        Sk4f a = Sk4f(aa) * Sk4f(1.0f/255);
+        b = b*a + d*(Sk4f(1)-a);
+        return Round(b);
+    }
+
+    ProcF fProcF;
     typedef SkProcCoeffXfermode INHERITED;
 };
 
@@ -327,7 +323,7 @@ static SkXfermode* create_xfermode(const
     #undef CASE
 
 #define CASE(Mode) \
-    case SkXfermode::k##Mode##_Mode: return new FloatXfermode<Mode>(rec, mode)
+    case SkXfermode::k##Mode##_Mode: return new Sk4fXfermode(rec, mode, &Mode)
         CASE(ColorDodge);
         CASE(ColorBurn);
         CASE(SoftLight);
HONK HONK! TRUCK FULL OF RADIOACTIVE WASTE AND ZOMBIE BITS COMING THROUGH 2016-07-19 18:10:57 +00:00			`diff -up chromium-48.0.2564.103/third_party/skia/src/opts/SkXfermode_opts.h.gcc6 chromium-48.0.2564.103/third_party/skia/src/opts/SkXfermode_opts.h`
			`--- chromium-48.0.2564.103/third_party/skia/src/opts/SkXfermode_opts.h.gcc6 2016-02-16 15:01:13.200131996 -0500`
			`+++ chromium-48.0.2564.103/third_party/skia/src/opts/SkXfermode_opts.h 2016-02-17 13:31:50.216198258 -0500`
			`@@ -109,76 +109,71 @@ XFERMODE(Lighten) {`
			`}`
			`#undef XFERMODE`

			`-// Some xfermodes use math like divide or sqrt that's best done in floats.`
			`-// We write it generically, then call it 1 or 2 pixels at a time (T == Sk4f or Sk8f).`
			`-#define XFERMODE(Name) struct Name { template <typename T> T operator()(const T&, const T&); }; \`
			`- template <typename T> T Name::operator()(const T& d, const T& s)`
			`+// Some xfermodes use math like divide or sqrt that's best done in floats 1 pixel at a time.`
			`+#define XFERMODE(Name) static Sk4f SK_VECTORCALL Name(Sk4f d, Sk4f s)`

			`-static_assert(SK_A32_SHIFT == 24, "");`
			`static inline Sk4f a_rgb(const Sk4f& a, const Sk4f& rgb) {`
			`+ static_assert(SK_A32_SHIFT == 24, "");`
			`return a * Sk4f(0,0,0,1) + rgb * Sk4f(1,1,1,0);`
			`}`
			`-static inline Sk8f a_rgb(const Sk8f& a, const Sk8f& rgb) {`
			`- // TODO: SkNx_blend<0,0,0,1,0,0,0,1>(a, rgb) to let us use _mm256_blend_ps?`
			`- return a * Sk8f(0,0,0,1,0,0,0,1) + rgb * Sk8f(1,1,1,0,1,1,1,0);`
			`+static inline Sk4f alphas(const Sk4f& f) {`
			`+ return SkNx_dup<SK_A32_SHIFT/8>(f);`
			`}`
			`-static inline Sk4f alphas(const Sk4f& f) { return SkNx_shuffle<3,3,3,3> (f); }`
			`-static inline Sk8f alphas(const Sk8f& f) { return SkNx_shuffle<3,3,3,3,7,7,7,7>(f); }`

			`XFERMODE(ColorDodge) {`
			`auto sa = alphas(s),`
			`da = alphas(d),`
			`- isa = T(1)-sa,`
			`- ida = T(1)-da;`
			`+ isa = Sk4f(1)-sa,`
			`+ ida = Sk4f(1)-da;`

			`auto srcover = s + d*isa,`
			`dstover = d + s*ida,`
			`- otherwise = sa * T::Min(da, (dsa)(sa-s).approxInvert()) + sida + disa;`
			`+ otherwise = sa * Sk4f::Min(da, (dsa)(sa-s).approxInvert()) + sida + disa;`

			`// Order matters here, preferring d==0 over s==sa.`
			`- auto colors = (d == 0).thenElse(dstover,`
			`- (s == sa).thenElse(srcover,`
			`- otherwise));`
			`+ auto colors = (d == Sk4f(0)).thenElse(dstover,`
			`+ (s == sa).thenElse(srcover,`
			`+ otherwise));`
			`return a_rgb(srcover, colors);`
			`}`
			`XFERMODE(ColorBurn) {`
			`auto sa = alphas(s),`
			`da = alphas(d),`
			`- isa = T(1)-sa,`
			`- ida = T(1)-da;`
			`+ isa = Sk4f(1)-sa,`
			`+ ida = Sk4f(1)-da;`

			`auto srcover = s + d*isa,`
			`dstover = d + s*ida,`
			`- otherwise = sa(da-T::Min(da, (da-d)sas.approxInvert())) + sida + d*isa;`
			`+ otherwise = sa(da-Sk4f::Min(da, (da-d)sas.approxInvert())) + sida + d*isa;`

			`// Order matters here, preferring d==da over s==0.`
			`- auto colors = (d == da).thenElse(dstover,`
			`- (s == 0).thenElse(srcover,`
			`- otherwise));`
			`+ auto colors = (d == da).thenElse(dstover,`
			`+ (s == Sk4f(0)).thenElse(srcover,`
			`+ otherwise));`
			`return a_rgb(srcover, colors);`
			`}`
			`XFERMODE(SoftLight) {`
			`auto sa = alphas(s),`
			`da = alphas(d),`
			`- isa = T(1)-sa,`
			`- ida = T(1)-da;`
			`+ isa = Sk4f(1)-sa,`
			`+ ida = Sk4f(1)-da;`

			`// Some common terms.`
			`- auto m = (da > 0).thenElse(d / da, 0),`
			`- s2 = s*2,`
			`- m4 = m*4;`
			`+ auto m = (da > Sk4f(0)).thenElse(d / da, Sk4f(0)),`
			`+ s2 = Sk4f(2)*s,`
			`+ m4 = Sk4f(4)*m;`

			`// The logic forks three ways:`
			`// 1. dark src?`
			`// 2. light src, dark dst?`
			`// 3. light src, light dst?`
			`- auto darkSrc = d(sa + (s2 - sa)(T(1) - m)), // Used in case 1.`
			`- darkDst = (m4m4 + m4)(m - 1) + m*7, // Used in case 2.`
			`- liteDst = m.sqrt() - m, // Used in case 3.`
			`- liteSrc = dsa + da(s2-sa)(d4 <= da).thenElse(darkDst, liteDst); // Case 2 or 3?`
			`+ auto darkSrc = d(sa + (s2 - sa)(Sk4f(1) - m)), // Used in case 1.`
			`+ darkDst = (m4m4 + m4)(m - Sk4f(1)) + Sk4f(7)*m, // Used in case 2.`
			`+ liteDst = m.sqrt() - m, // Used in case 3.`
			`+ liteSrc = dsa + da(s2-sa)(Sk4f(4)d <= da).thenElse(darkDst, liteDst); // Case 2 or 3?`

			`auto alpha = s + d*isa;`
			`- auto colors = sida + disa + (s2 <= sa).thenElse(darkSrc, liteSrc); // Case 1 or 2/3?`
			`+ auto colors = sida + disa + (s2 <= sa).thenElse(darkSrc, liteSrc); // Case 1 or 2/3?`

			`return a_rgb(alpha, colors);`
			`}`
			`@@ -245,52 +240,53 @@ private:`
			`typedef SkProcCoeffXfermode INHERITED;`
			`};`

			`-template <typename BlendFn>`
			`-class FloatXfermode : public SkProcCoeffXfermode {`
			`+class Sk4fXfermode : public SkProcCoeffXfermode {`
			`public:`
			`- FloatXfermode(const ProcCoeff& rec, SkXfermode::Mode mode)`
			`- : INHERITED(rec, mode) {}`
			`+ typedef Sk4f (SK_VECTORCALL *ProcF)(Sk4f, Sk4f);`
			`+ Sk4fXfermode(const ProcCoeff& rec, SkXfermode::Mode mode, ProcF procf)`
			`+ : INHERITED(rec, mode)`
			`+ , fProcF(procf) {}`

			`void xfer32(SkPMColor dst[], const SkPMColor src[], int n, const SkAlpha aa[]) const override {`
			`- BlendFn blend;`
			`- while (n >= 2) {`
			`- auto d = Sk8f::FromBytes((const uint8_t)dst) (1.0f/255),`
			`- s = Sk8f::FromBytes((const uint8_t)src) (1.0f/255),`
			`- b = blend(d, s);`
			`- if (aa) {`
			`- auto a255 = Sk8f(aa[0],aa[0],aa[0],aa[0], aa[1],aa[1],aa[1],aa[1]);`
			`- (ba255 + d(Sk8f(255)-a255) + 0.5).toBytes((uint8_t*)dst);`
			`- aa += 2;`
			`- } else {`
			`- (b * 255 + 0.5).toBytes((uint8_t*)dst);`
			`- }`
			`- dst += 2;`
			`- src += 2;`
			`- n -= 2;`
			`- }`
			`- if (n) {`
			`- auto d = Sk4f::FromBytes((const uint8_t)dst) (1.0f/255),`
			`- s = Sk4f::FromBytes((const uint8_t)src) (1.0f/255),`
			`- b = blend(d, s);`
			`- if (aa) {`
			`- auto a255 = Sk4f(aa[0],aa[0],aa[0],aa[0]);`
			`- (ba255 + d(Sk4f(255)-a255) + 0.5).toBytes((uint8_t*)dst);`
			`- aa++;`
			`- } else {`
			`- (b * 255 + 0.5).toBytes((uint8_t*)dst);`
			`- }`
			`+ for (int i = 0; i < n; i++) {`
			`+ dst[i] = aa ? this->xfer32(dst[i], src[i], aa[i])`
			`+ : this->xfer32(dst[i], src[i]);`
			`}`
			`}`

			`void xfer16(uint16_t dst[], const SkPMColor src[], int n, const SkAlpha aa[]) const override {`
			`for (int i = 0; i < n; i++) {`
			`- SkPMColor dst32 = SkPixel16ToPixel32(dst[i]); // Convert dst up to 8888.`
			`- this->xfer32(&dst32, src+i, 1, aa ? aa+i : nullptr); // Blend 1 pixel.`
			`- dst[i] = SkPixel32ToPixel16(dst32); // Repack dst to 565 and store.`
			`+ SkPMColor dst32 = SkPixel16ToPixel32(dst[i]);`
			`+ dst32 = aa ? this->xfer32(dst32, src[i], aa[i])`
			`+ : this->xfer32(dst32, src[i]);`
			`+ dst[i] = SkPixel32ToPixel16(dst32);`
			`}`
			`}`

			`private:`
			`+ static Sk4f Load(SkPMColor c) {`
			`+ return Sk4f::FromBytes((uint8_t)&c) Sk4f(1.0f/255);`
			`+ }`
			`+ static SkPMColor Round(const Sk4f& f) {`
			`+ SkPMColor c;`
			`+ (f * Sk4f(255) + Sk4f(0.5f)).toBytes((uint8_t*)&c);`
			`+ return c;`
			`+ }`
			`+ inline SkPMColor xfer32(SkPMColor dst, SkPMColor src) const {`
			`+ return Round(fProcF(Load(dst), Load(src)));`
			`+ }`
			`+`
			`+ inline SkPMColor xfer32(SkPMColor dst, SkPMColor src, SkAlpha aa) const {`
			`+ Sk4f s(Load(src)),`
			`+ d(Load(dst)),`
			`+ b(fProcF(d,s));`
			`+ // We do aa in full float precision before going back down to bytes, because we can!`
			`+ Sk4f a = Sk4f(aa) * Sk4f(1.0f/255);`
			`+ b = ba + d(Sk4f(1)-a);`
			`+ return Round(b);`
			`+ }`
			`+`
			`+ ProcF fProcF;`
			`typedef SkProcCoeffXfermode INHERITED;`
			`};`

			`@@ -327,7 +323,7 @@ static SkXfermode* create_xfermode(const`
			`#undef CASE`

			`#define CASE(Mode) \`
			`- case SkXfermode::k##Mode##_Mode: return new FloatXfermode<Mode>(rec, mode)`
			`+ case SkXfermode::k##Mode##_Mode: return new Sk4fXfermode(rec, mode, &Mode)`
			`CASE(ColorDodge);`
			`CASE(ColorBurn);`
			`CASE(SoftLight);`