src/core/SkMipMap.cpp - platform/external/skia - Git at Google

 /*
  * Copyright 2013 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "SkMipMap.h"
 #include "SkBitmap.h"
 #include "SkColorPriv.h"
 #include "SkMath.h"
 #include "SkNx.h"
 #include "SkTypes.h"

 //
 // ColorTypeFilter is the "Type" we pass to some downsample template functions.
 // It controls how we expand a pixel into a large type, with space between each component,
 // so we can then perform our simple filter (either box or triangle) and store the intermediates
 // in the expanded type.
 //

 struct ColorTypeFilter_8888 {
     typedef uint32_t Type;
 #if defined(SKNX_IS_FAST)
     static Sk4h Expand(uint32_t x) {
         return SkNx_cast<uint16_t>(Sk4b::Load(&x));
     }
     static uint32_t Compact(const Sk4h& x) {
         uint32_t r;
         SkNx_cast<uint8_t>(x).store(&r);
         return r;
     }
 #else
     static uint64_t Expand(uint32_t x) {
         return (x & 0xFF00FF) | ((uint64_t)(x & 0xFF00FF00) << 24);
     }
     static uint32_t Compact(uint64_t x) {
         return (uint32_t)((x & 0xFF00FF) | ((x >> 24) & 0xFF00FF00));
     }
 #endif
 };

 struct ColorTypeFilter_565 {
     typedef uint16_t Type;
     static uint32_t Expand(uint16_t x) {
         return (x & ~SK_G16_MASK_IN_PLACE) | ((x & SK_G16_MASK_IN_PLACE) << 16);
     }
     static uint16_t Compact(uint32_t x) {
         return (x & ~SK_G16_MASK_IN_PLACE) | ((x >> 16) & SK_G16_MASK_IN_PLACE);
     }
 };

 struct ColorTypeFilter_4444 {
     typedef uint16_t Type;
     static uint32_t Expand(uint16_t x) {
         return (x & 0xF0F) | ((x & ~0xF0F) << 12);
     }
     static uint16_t Compact(uint32_t x) {
         return (x & 0xF0F) | ((x >> 12) & ~0xF0F);
     }
 };

 struct ColorTypeFilter_8 {
     typedef uint8_t Type;
     static unsigned Expand(unsigned x) {
         return x;
     }
     static uint8_t Compact(unsigned x) {
         return (uint8_t)x;
     }
 };

 template <typename T> T add_121(const T& a, const T& b, const T& c) {
     return a + b + b + c;
 }

 //
 //  To produce each mip level, we need to filter down by 1/2 (e.g. 100x100 -> 50,50)
 //  If the starting dimension is odd, we floor the size of the lower level (e.g. 101 -> 50)
 //  In those (odd) cases, we use a triangle filter, with 1-pixel overlap between samplings,
 //  else for even cases, we just use a 2x box filter.
 //
 //  This produces 4 possible filters: 2x2 2x3 3x2 3x3 where WxH indicates the number of src pixels
 //  we need to sample in each dimension to produce 1 dst pixel.
 //

 template <typename F> void downsample_2_2(void* dst, const void* src, size_t srcRB, int count) {
     auto p0 = static_cast<const typename F::Type*>(src);
     auto p1 = (const typename F::Type*)((const char*)p0 + srcRB);
     auto d = static_cast<typename F::Type*>(dst);

     for (int i = 0; i < count; ++i) {
         auto c00 = F::Expand(p0[0]);
         auto c01 = F::Expand(p0[1]);
         auto c10 = F::Expand(p1[0]);
         auto c11 = F::Expand(p1[1]);

         auto c = c00 + c10 + c01 + c11;
         d[i] = F::Compact(c >> 2);
         p0 += 2;
         p1 += 2;
     }
 }

 template <typename F> void downsample_3_2(void* dst, const void* src, size_t srcRB, int count) {
     SkASSERT(count > 0);
     auto p0 = static_cast<const typename F::Type*>(src);
     auto p1 = (const typename F::Type*)((const char*)p0 + srcRB);
     auto d = static_cast<typename F::Type*>(dst);

     auto c02 = F::Expand(p0[0]);
     auto c12 = F::Expand(p1[0]);
     for (int i = 0; i < count; ++i) {
         auto c00 = c02;
         auto c01 = F::Expand(p0[1]);
              c02 = F::Expand(p0[2]);
         auto c10 = c12;
         auto c11 = F::Expand(p1[1]);
              c12 = F::Expand(p1[2]);

         auto c = add_121(c00, c01, c02) + add_121(c10, c11, c12);
         d[i] = F::Compact(c >> 3);
         p0 += 2;
         p1 += 2;
     }
 }

 template <typename F> void downsample_2_3(void* dst, const void* src, size_t srcRB, int count) {
     auto p0 = static_cast<const typename F::Type*>(src);
     auto p1 = (const typename F::Type*)((const char*)p0 + srcRB);
     auto p2 = (const typename F::Type*)((const char*)p1 + srcRB);
     auto d = static_cast<typename F::Type*>(dst);

     for (int i = 0; i < count; ++i) {
         auto c00 = F::Expand(p0[0]);
         auto c01 = F::Expand(p0[1]);
         auto c10 = F::Expand(p1[0]);
         auto c11 = F::Expand(p1[1]);
         auto c20 = F::Expand(p2[0]);
         auto c21 = F::Expand(p2[1]);

         auto c = add_121(c00, c10, c20) + add_121(c01, c11, c21);
         d[i] = F::Compact(c >> 3);
         p0 += 2;
         p1 += 2;
         p2 += 2;
     }
 }

 template <typename F> void downsample_3_3(void* dst, const void* src, size_t srcRB, int count) {
     auto p0 = static_cast<const typename F::Type*>(src);
     auto p1 = (const typename F::Type*)((const char*)p0 + srcRB);
     auto p2 = (const typename F::Type*)((const char*)p1 + srcRB);
     auto d = static_cast<typename F::Type*>(dst);

     auto c02 = F::Expand(p0[0]);
     auto c12 = F::Expand(p1[0]);
     auto c22 = F::Expand(p2[0]);
     for (int i = 0; i < count; ++i) {
         auto c00 = c02;
         auto c01 = F::Expand(p0[1]);
              c02 = F::Expand(p0[2]);
         auto c10 = c12;
         auto c11 = F::Expand(p1[1]);
              c12 = F::Expand(p1[2]);
         auto c20 = c22;
         auto c21 = F::Expand(p2[1]);
              c22 = F::Expand(p2[2]);

         auto c = add_121(c00, c01, c02) + (add_121(c10, c11, c12) << 1) + add_121(c20, c21, c22);
         d[i] = F::Compact(c >> 4);
         p0 += 2;
         p1 += 2;
         p2 += 2;
     }
 }

 ///////////////////////////////////////////////////////////////////////////////////////////////////

 size_t SkMipMap::AllocLevelsSize(int levelCount, size_t pixelSize) {
     if (levelCount < 0) {
         return 0;
     }
     int64_t size = sk_64_mul(levelCount + 1, sizeof(Level)) + pixelSize;
     if (!sk_64_isS32(size)) {
         return 0;
     }
     return sk_64_asS32(size);
 }

 SkMipMap* SkMipMap::Build(const SkPixmap& src, SkDiscardableFactoryProc fact) {
     typedef void FilterProc(void*, const void* srcPtr, size_t srcRB, int count);

     FilterProc* proc_2_2 = nullptr;
     FilterProc* proc_2_3 = nullptr;
     FilterProc* proc_3_2 = nullptr;
     FilterProc* proc_3_3 = nullptr;

     const SkColorType ct = src.colorType();
     const SkAlphaType at = src.alphaType();
     switch (ct) {
         case kRGBA_8888_SkColorType:
         case kBGRA_8888_SkColorType:
             proc_2_2 = downsample_2_2<ColorTypeFilter_8888>;
             proc_2_3 = downsample_2_3<ColorTypeFilter_8888>;
             proc_3_2 = downsample_3_2<ColorTypeFilter_8888>;
             proc_3_3 = downsample_3_3<ColorTypeFilter_8888>;
             break;
         case kRGB_565_SkColorType:
             proc_2_2 = downsample_2_2<ColorTypeFilter_565>;
             proc_2_3 = downsample_2_3<ColorTypeFilter_565>;
             proc_3_2 = downsample_3_2<ColorTypeFilter_565>;
             proc_3_3 = downsample_3_3<ColorTypeFilter_565>;
             break;
         case kARGB_4444_SkColorType:
             proc_2_2 = downsample_2_2<ColorTypeFilter_4444>;
             proc_2_3 = downsample_2_3<ColorTypeFilter_4444>;
             proc_3_2 = downsample_3_2<ColorTypeFilter_4444>;
             proc_3_3 = downsample_3_3<ColorTypeFilter_4444>;
             break;
         case kAlpha_8_SkColorType:
         case kGray_8_SkColorType:
             proc_2_2 = downsample_2_2<ColorTypeFilter_8>;
             proc_2_3 = downsample_2_3<ColorTypeFilter_8>;
             proc_3_2 = downsample_3_2<ColorTypeFilter_8>;
             proc_3_3 = downsample_3_3<ColorTypeFilter_8>;
             break;
         default:
             // TODO: We could build miplevels for kIndex8 if the levels were in 8888.
             //       Means using more ram, but the quality would be fine.
             return nullptr;
     }

     // whip through our loop to compute the exact size needed
     size_t  size = 0;
     int     countLevels = 0;
     {
         int width = src.width();
         int height = src.height();
         for (;;) {
             width >>= 1;
             height >>= 1;
             if (0 == width || 0 == height) {
                 break;
             }
             size += SkColorTypeMinRowBytes(ct, width) * height;
             countLevels += 1;
         }
     }
     if (0 == countLevels) {
         return nullptr;
     }

     SkASSERT(countLevels == SkMipMap::ComputeLevelCount(src.width(), src.height()));

     size_t storageSize = SkMipMap::AllocLevelsSize(countLevels, size);
     if (0 == storageSize) {
         return nullptr;
     }

     SkMipMap* mipmap;
     if (fact) {
         SkDiscardableMemory* dm = fact(storageSize);
         if (nullptr == dm) {
             return nullptr;
         }
         mipmap = new SkMipMap(storageSize, dm);
     } else {
         mipmap = new SkMipMap(sk_malloc_throw(storageSize), storageSize);
     }

     // init
     mipmap->fCount = countLevels;
     mipmap->fLevels = (Level*)mipmap->writable_data();

     Level* levels = mipmap->fLevels;
     uint8_t*    baseAddr = (uint8_t*)&levels[countLevels];
     uint8_t*    addr = baseAddr;
     int         width = src.width();
     int         height = src.height();
     uint32_t    rowBytes;
     SkPixmap    srcPM(src);

     for (int i = 0; i < countLevels; ++i) {
         FilterProc* proc;
         if (height & 1) {        // src-height is 3
             if (width & 1) {    // src-width is 3
                 proc = proc_3_3;
             } else {            // src-width is 2
                 proc = proc_2_3;
             }
         } else {                // src-height is 2
             if (width & 1) {    // src-width is 3
                 proc = proc_3_2;
             } else {            // src-width is 2
                 proc = proc_2_2;
             }
         }
         width >>= 1;
         height >>= 1;
         rowBytes = SkToU32(SkColorTypeMinRowBytes(ct, width));

         levels[i].fPixmap = SkPixmap(SkImageInfo::Make(width, height, ct, at), addr, rowBytes);
         levels[i].fScale  = SkSize::Make(SkIntToScalar(width)  / src.width(),
                                          SkIntToScalar(height) / src.height());

         const SkPixmap& dstPM = levels[i].fPixmap;
         const void* srcBasePtr = srcPM.addr();
         void* dstBasePtr = dstPM.writable_addr();

         const size_t srcRB = srcPM.rowBytes();
         for (int y = 0; y < height; y++) {
             proc(dstBasePtr, srcBasePtr, srcRB, width);
             srcBasePtr = (char*)srcBasePtr + srcRB * 2; // jump two rows
             dstBasePtr = (char*)dstBasePtr + dstPM.rowBytes();
         }
         srcPM = dstPM;
         addr += height * rowBytes;
     }
     SkASSERT(addr == baseAddr + size);

     return mipmap;
 }

 int SkMipMap::ComputeLevelCount(int baseWidth, int baseHeight) {
     // OpenGL's spec requires that each mipmap level have height/width equal to
     // max(1, floor(original_height / 2^i)
     // (or original_width) where i is the mipmap level.
     // Continue scaling down until both axes are size 1.
     //
     // This means it maintains isotropic space (both axes scaling down
     // at the same rate) until one axis hits size 1.
     // At that point, OpenGL continues to scale down into anisotropic space
     // (where the scales are not the same between axes).
     //
     // Skia currently does not go into anisotropic space.
     // Once an axis hits size 1 we stop.
     // All this means is rather than use the largest axis we will use the
     // smallest axis.

     const int smallestAxis = SkTMin(baseWidth, baseHeight);
     if (smallestAxis < 2) {
         // SkMipMap::Build requires a minimum size of 2.
         return 0;
     }
     const int leadingZeros = SkCLZ(static_cast<uint32_t>(smallestAxis));
     // If the value 00011010 has 3 leading 0s then it has 5 significant bits
     // (the bits which are not leading zeros)
     const int significantBits = (sizeof(uint32_t) * 8) - leadingZeros;
     // This is making the assumption that the size of a byte is 8 bits
     // and that sizeof(uint32_t)'s implementation-defined behavior is 4.
     int mipLevelCount = significantBits;

     // SkMipMap does not include the base mip level.
     // For example, it contains levels 1-x instead of 0-x.
     // This is because the image used to create SkMipMap is the base level.
     // So subtract 1 from the mip level count.
     if (mipLevelCount > 0) {
         --mipLevelCount;
     }

     return mipLevelCount;
 }

 ///////////////////////////////////////////////////////////////////////////////

 bool SkMipMap::extractLevel(const SkSize& scaleSize, Level* levelPtr) const {
     if (nullptr == fLevels) {
         return false;
     }

     SkASSERT(scaleSize.width() >= 0 && scaleSize.height() >= 0);

 #ifndef SK_SUPPORT_LEGACY_ANISOTROPIC_MIPMAP_SCALE
     // Use the smallest scale to match the GPU impl.
     const SkScalar scale = SkTMin(scaleSize.width(), scaleSize.height());
 #else
     // Ideally we'd pick the smaller scale, to match Ganesh.  But ignoring one of the
     // scales can produce some atrocious results, so for now we use the geometric mean.
     // (https://bugs.chromium.org/p/skia/issues/detail?id=4863)
     const SkScalar scale = SkScalarSqrt(scaleSize.width() * scaleSize.height());
 #endif

     if (scale >= SK_Scalar1 || scale <= 0 || !SkScalarIsFinite(scale)) {
         return false;
     }

     SkScalar L = -SkScalarLog2(scale);
     if (!SkScalarIsFinite(L)) {
         return false;
     }
     SkASSERT(L >= 0);
 //    int rndLevel = SkScalarRoundToInt(L);
     int level = SkScalarFloorToInt(L);
 //    SkDebugf("mipmap scale=%g L=%g level=%d rndLevel=%d\n", scale, L, level, rndLevel);

     SkASSERT(level >= 0);
     if (level <= 0) {
         return false;
     }

     if (level > fCount) {
         level = fCount;
     }
     if (levelPtr) {
         *levelPtr = fLevels[level - 1];
     }
     return true;
 }

 // Helper which extracts a pixmap from the src bitmap
 //
 SkMipMap* SkMipMap::Build(const SkBitmap& src, SkDiscardableFactoryProc fact) {
     SkAutoPixmapUnlock srcUnlocker;
     if (!src.requestLock(&srcUnlocker)) {
         return nullptr;
     }
     const SkPixmap& srcPixmap = srcUnlocker.pixmap();
     // Try to catch where we might have returned nullptr for src crbug.com/492818
     if (nullptr == srcPixmap.addr()) {
         sk_throw();
     }
     return Build(srcPixmap, fact);
 }

 int SkMipMap::countLevels() const {
     return fCount;
 }

 bool SkMipMap::getLevel(int index, Level* levelPtr) const {
     if (NULL == fLevels) {
         return false;
     }
     if (index < 0) {
         return false;
     }
     if (index > fCount - 1) {
         return false;
     }
     if (levelPtr) {
         *levelPtr = fLevels[index];
     }
     return true;
 }
	/*
	* Copyright 2013 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkMipMap.h"
	#include "SkBitmap.h"
	#include "SkColorPriv.h"
	#include "SkMath.h"
	#include "SkNx.h"
	#include "SkTypes.h"

	//
	// ColorTypeFilter is the "Type" we pass to some downsample template functions.
	// It controls how we expand a pixel into a large type, with space between each component,
	// so we can then perform our simple filter (either box or triangle) and store the intermediates
	// in the expanded type.
	//

	struct ColorTypeFilter_8888 {
	typedef uint32_t Type;
	#if defined(SKNX_IS_FAST)
	static Sk4h Expand(uint32_t x) {
	return SkNx_cast<uint16_t>(Sk4b::Load(&x));
	}
	static uint32_t Compact(const Sk4h& x) {
	uint32_t r;
	SkNx_cast<uint8_t>(x).store(&r);
	return r;
	}
	#else
	static uint64_t Expand(uint32_t x) {
	return (x & 0xFF00FF) \| ((uint64_t)(x & 0xFF00FF00) << 24);
	}
	static uint32_t Compact(uint64_t x) {
	return (uint32_t)((x & 0xFF00FF) \| ((x >> 24) & 0xFF00FF00));
	}
	#endif
	};

	struct ColorTypeFilter_565 {
	typedef uint16_t Type;
	static uint32_t Expand(uint16_t x) {
	return (x & ~SK_G16_MASK_IN_PLACE) \| ((x & SK_G16_MASK_IN_PLACE) << 16);
	}
	static uint16_t Compact(uint32_t x) {
	return (x & ~SK_G16_MASK_IN_PLACE) \| ((x >> 16) & SK_G16_MASK_IN_PLACE);
	}
	};

	struct ColorTypeFilter_4444 {
	typedef uint16_t Type;
	static uint32_t Expand(uint16_t x) {
	return (x & 0xF0F) \| ((x & ~0xF0F) << 12);
	}
	static uint16_t Compact(uint32_t x) {
	return (x & 0xF0F) \| ((x >> 12) & ~0xF0F);
	}
	};

	struct ColorTypeFilter_8 {
	typedef uint8_t Type;
	static unsigned Expand(unsigned x) {
	return x;
	}
	static uint8_t Compact(unsigned x) {
	return (uint8_t)x;
	}
	};

	template <typename T> T add_121(const T& a, const T& b, const T& c) {
	return a + b + b + c;
	}

	//
	// To produce each mip level, we need to filter down by 1/2 (e.g. 100x100 -> 50,50)
	// If the starting dimension is odd, we floor the size of the lower level (e.g. 101 -> 50)
	// In those (odd) cases, we use a triangle filter, with 1-pixel overlap between samplings,
	// else for even cases, we just use a 2x box filter.
	//
	// This produces 4 possible filters: 2x2 2x3 3x2 3x3 where WxH indicates the number of src pixels
	// we need to sample in each dimension to produce 1 dst pixel.
	//

	template <typename F> void downsample_2_2(void* dst, const void* src, size_t srcRB, int count) {
	auto p0 = static_cast<const typename F::Type*>(src);
	auto p1 = (const typename F::Type)((const char)p0 + srcRB);
	auto d = static_cast<typename F::Type*>(dst);

	for (int i = 0; i < count; ++i) {
	auto c00 = F::Expand(p0[0]);
	auto c01 = F::Expand(p0[1]);
	auto c10 = F::Expand(p1[0]);
	auto c11 = F::Expand(p1[1]);

	auto c = c00 + c10 + c01 + c11;
	d[i] = F::Compact(c >> 2);
	p0 += 2;
	p1 += 2;
	}
	}

	template <typename F> void downsample_3_2(void* dst, const void* src, size_t srcRB, int count) {
	SkASSERT(count > 0);
	auto p0 = static_cast<const typename F::Type*>(src);
	auto p1 = (const typename F::Type)((const char)p0 + srcRB);
	auto d = static_cast<typename F::Type*>(dst);

	auto c02 = F::Expand(p0[0]);
	auto c12 = F::Expand(p1[0]);
	for (int i = 0; i < count; ++i) {
	auto c00 = c02;
	auto c01 = F::Expand(p0[1]);
	c02 = F::Expand(p0[2]);
	auto c10 = c12;
	auto c11 = F::Expand(p1[1]);
	c12 = F::Expand(p1[2]);

	auto c = add_121(c00, c01, c02) + add_121(c10, c11, c12);
	d[i] = F::Compact(c >> 3);
	p0 += 2;
	p1 += 2;
	}
	}

	template <typename F> void downsample_2_3(void* dst, const void* src, size_t srcRB, int count) {
	auto p0 = static_cast<const typename F::Type*>(src);
	auto p1 = (const typename F::Type)((const char)p0 + srcRB);
	auto p2 = (const typename F::Type)((const char)p1 + srcRB);
	auto d = static_cast<typename F::Type*>(dst);

	for (int i = 0; i < count; ++i) {
	auto c00 = F::Expand(p0[0]);
	auto c01 = F::Expand(p0[1]);
	auto c10 = F::Expand(p1[0]);
	auto c11 = F::Expand(p1[1]);
	auto c20 = F::Expand(p2[0]);
	auto c21 = F::Expand(p2[1]);

	auto c = add_121(c00, c10, c20) + add_121(c01, c11, c21);
	d[i] = F::Compact(c >> 3);
	p0 += 2;
	p1 += 2;
	p2 += 2;
	}
	}

	template <typename F> void downsample_3_3(void* dst, const void* src, size_t srcRB, int count) {
	auto p0 = static_cast<const typename F::Type*>(src);
	auto p1 = (const typename F::Type)((const char)p0 + srcRB);
	auto p2 = (const typename F::Type)((const char)p1 + srcRB);
	auto d = static_cast<typename F::Type*>(dst);

	auto c02 = F::Expand(p0[0]);
	auto c12 = F::Expand(p1[0]);
	auto c22 = F::Expand(p2[0]);
	for (int i = 0; i < count; ++i) {
	auto c00 = c02;
	auto c01 = F::Expand(p0[1]);
	c02 = F::Expand(p0[2]);
	auto c10 = c12;
	auto c11 = F::Expand(p1[1]);
	c12 = F::Expand(p1[2]);
	auto c20 = c22;
	auto c21 = F::Expand(p2[1]);
	c22 = F::Expand(p2[2]);

	auto c = add_121(c00, c01, c02) + (add_121(c10, c11, c12) << 1) + add_121(c20, c21, c22);
	d[i] = F::Compact(c >> 4);
	p0 += 2;
	p1 += 2;
	p2 += 2;
	}
	}

	///////////////////////////////////////////////////////////////////////////////////////////////////

	size_t SkMipMap::AllocLevelsSize(int levelCount, size_t pixelSize) {
	if (levelCount < 0) {
	return 0;
	}
	int64_t size = sk_64_mul(levelCount + 1, sizeof(Level)) + pixelSize;
	if (!sk_64_isS32(size)) {
	return 0;
	}
	return sk_64_asS32(size);
	}

	SkMipMap* SkMipMap::Build(const SkPixmap& src, SkDiscardableFactoryProc fact) {
	typedef void FilterProc(void, const void srcPtr, size_t srcRB, int count);

	FilterProc* proc_2_2 = nullptr;
	FilterProc* proc_2_3 = nullptr;
	FilterProc* proc_3_2 = nullptr;
	FilterProc* proc_3_3 = nullptr;

	const SkColorType ct = src.colorType();
	const SkAlphaType at = src.alphaType();
	switch (ct) {
	case kRGBA_8888_SkColorType:
	case kBGRA_8888_SkColorType:
	proc_2_2 = downsample_2_2<ColorTypeFilter_8888>;
	proc_2_3 = downsample_2_3<ColorTypeFilter_8888>;
	proc_3_2 = downsample_3_2<ColorTypeFilter_8888>;
	proc_3_3 = downsample_3_3<ColorTypeFilter_8888>;
	break;
	case kRGB_565_SkColorType:
	proc_2_2 = downsample_2_2<ColorTypeFilter_565>;
	proc_2_3 = downsample_2_3<ColorTypeFilter_565>;
	proc_3_2 = downsample_3_2<ColorTypeFilter_565>;
	proc_3_3 = downsample_3_3<ColorTypeFilter_565>;
	break;
	case kARGB_4444_SkColorType:
	proc_2_2 = downsample_2_2<ColorTypeFilter_4444>;
	proc_2_3 = downsample_2_3<ColorTypeFilter_4444>;
	proc_3_2 = downsample_3_2<ColorTypeFilter_4444>;
	proc_3_3 = downsample_3_3<ColorTypeFilter_4444>;
	break;
	case kAlpha_8_SkColorType:
	case kGray_8_SkColorType:
	proc_2_2 = downsample_2_2<ColorTypeFilter_8>;
	proc_2_3 = downsample_2_3<ColorTypeFilter_8>;
	proc_3_2 = downsample_3_2<ColorTypeFilter_8>;
	proc_3_3 = downsample_3_3<ColorTypeFilter_8>;
	break;
	default:
	// TODO: We could build miplevels for kIndex8 if the levels were in 8888.
	// Means using more ram, but the quality would be fine.
	return nullptr;
	}

	// whip through our loop to compute the exact size needed
	size_t size = 0;
	int countLevels = 0;
	{
	int width = src.width();
	int height = src.height();
	for (;;) {
	width >>= 1;
	height >>= 1;
	if (0 == width \|\| 0 == height) {
	break;
	}
	size += SkColorTypeMinRowBytes(ct, width) * height;
	countLevels += 1;
	}
	}
	if (0 == countLevels) {
	return nullptr;
	}

	SkASSERT(countLevels == SkMipMap::ComputeLevelCount(src.width(), src.height()));

	size_t storageSize = SkMipMap::AllocLevelsSize(countLevels, size);
	if (0 == storageSize) {
	return nullptr;
	}

	SkMipMap* mipmap;
	if (fact) {
	SkDiscardableMemory* dm = fact(storageSize);
	if (nullptr == dm) {
	return nullptr;
	}
	mipmap = new SkMipMap(storageSize, dm);
	} else {
	mipmap = new SkMipMap(sk_malloc_throw(storageSize), storageSize);
	}

	// init
	mipmap->fCount = countLevels;
	mipmap->fLevels = (Level*)mipmap->writable_data();

	Level* levels = mipmap->fLevels;
	uint8_t* baseAddr = (uint8_t*)&levels[countLevels];
	uint8_t* addr = baseAddr;
	int width = src.width();
	int height = src.height();
	uint32_t rowBytes;
	SkPixmap srcPM(src);

	for (int i = 0; i < countLevels; ++i) {
	FilterProc* proc;
	if (height & 1) { // src-height is 3
	if (width & 1) { // src-width is 3
	proc = proc_3_3;
	} else { // src-width is 2
	proc = proc_2_3;
	}
	} else { // src-height is 2
	if (width & 1) { // src-width is 3
	proc = proc_3_2;
	} else { // src-width is 2
	proc = proc_2_2;
	}
	}
	width >>= 1;
	height >>= 1;
	rowBytes = SkToU32(SkColorTypeMinRowBytes(ct, width));

	levels[i].fPixmap = SkPixmap(SkImageInfo::Make(width, height, ct, at), addr, rowBytes);
	levels[i].fScale = SkSize::Make(SkIntToScalar(width) / src.width(),
	SkIntToScalar(height) / src.height());

	const SkPixmap& dstPM = levels[i].fPixmap;
	const void* srcBasePtr = srcPM.addr();
	void* dstBasePtr = dstPM.writable_addr();

	const size_t srcRB = srcPM.rowBytes();
	for (int y = 0; y < height; y++) {
	proc(dstBasePtr, srcBasePtr, srcRB, width);
	srcBasePtr = (char)srcBasePtr + srcRB 2; // jump two rows
	dstBasePtr = (char*)dstBasePtr + dstPM.rowBytes();
	}
	srcPM = dstPM;
	addr += height * rowBytes;
	}
	SkASSERT(addr == baseAddr + size);

	return mipmap;
	}

	int SkMipMap::ComputeLevelCount(int baseWidth, int baseHeight) {
	// OpenGL's spec requires that each mipmap level have height/width equal to
	// max(1, floor(original_height / 2^i)
	// (or original_width) where i is the mipmap level.
	// Continue scaling down until both axes are size 1.
	//
	// This means it maintains isotropic space (both axes scaling down
	// at the same rate) until one axis hits size 1.
	// At that point, OpenGL continues to scale down into anisotropic space
	// (where the scales are not the same between axes).
	//
	// Skia currently does not go into anisotropic space.
	// Once an axis hits size 1 we stop.
	// All this means is rather than use the largest axis we will use the
	// smallest axis.

	const int smallestAxis = SkTMin(baseWidth, baseHeight);
	if (smallestAxis < 2) {
	// SkMipMap::Build requires a minimum size of 2.
	return 0;
	}
	const int leadingZeros = SkCLZ(static_cast<uint32_t>(smallestAxis));
	// If the value 00011010 has 3 leading 0s then it has 5 significant bits
	// (the bits which are not leading zeros)
	const int significantBits = (sizeof(uint32_t) * 8) - leadingZeros;
	// This is making the assumption that the size of a byte is 8 bits
	// and that sizeof(uint32_t)'s implementation-defined behavior is 4.
	int mipLevelCount = significantBits;

	// SkMipMap does not include the base mip level.
	// For example, it contains levels 1-x instead of 0-x.
	// This is because the image used to create SkMipMap is the base level.
	// So subtract 1 from the mip level count.
	if (mipLevelCount > 0) {
	--mipLevelCount;
	}

	return mipLevelCount;
	}

	///////////////////////////////////////////////////////////////////////////////

	bool SkMipMap::extractLevel(const SkSize& scaleSize, Level* levelPtr) const {
	if (nullptr == fLevels) {
	return false;
	}

	SkASSERT(scaleSize.width() >= 0 && scaleSize.height() >= 0);

	#ifndef SK_SUPPORT_LEGACY_ANISOTROPIC_MIPMAP_SCALE
	// Use the smallest scale to match the GPU impl.
	const SkScalar scale = SkTMin(scaleSize.width(), scaleSize.height());
	#else
	// Ideally we'd pick the smaller scale, to match Ganesh. But ignoring one of the
	// scales can produce some atrocious results, so for now we use the geometric mean.
	// (https://bugs.chromium.org/p/skia/issues/detail?id=4863)
	const SkScalar scale = SkScalarSqrt(scaleSize.width() * scaleSize.height());
	#endif

	if (scale >= SK_Scalar1 \|\| scale <= 0 \|\| !SkScalarIsFinite(scale)) {
	return false;
	}

	SkScalar L = -SkScalarLog2(scale);
	if (!SkScalarIsFinite(L)) {
	return false;
	}
	SkASSERT(L >= 0);
	// int rndLevel = SkScalarRoundToInt(L);
	int level = SkScalarFloorToInt(L);
	// SkDebugf("mipmap scale=%g L=%g level=%d rndLevel=%d\n", scale, L, level, rndLevel);

	SkASSERT(level >= 0);
	if (level <= 0) {
	return false;
	}

	if (level > fCount) {
	level = fCount;
	}
	if (levelPtr) {
	*levelPtr = fLevels[level - 1];
	}
	return true;
	}

	// Helper which extracts a pixmap from the src bitmap
	//
	SkMipMap* SkMipMap::Build(const SkBitmap& src, SkDiscardableFactoryProc fact) {
	SkAutoPixmapUnlock srcUnlocker;
	if (!src.requestLock(&srcUnlocker)) {
	return nullptr;
	}
	const SkPixmap& srcPixmap = srcUnlocker.pixmap();
	// Try to catch where we might have returned nullptr for src crbug.com/492818
	if (nullptr == srcPixmap.addr()) {
	sk_throw();
	}
	return Build(srcPixmap, fact);
	}

	int SkMipMap::countLevels() const {
	return fCount;
	}

	bool SkMipMap::getLevel(int index, Level* levelPtr) const {
	if (NULL == fLevels) {
	return false;
	}
	if (index < 0) {
	return false;
	}
	if (index > fCount - 1) {
	return false;
	}
	if (levelPtr) {
	*levelPtr = fLevels[index];
	}
	return true;
	}