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


 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */
 #include "SkBitmapProcState.h"
 #include "SkColorPriv.h"
 #include "SkFilterProc.h"
 #include "SkPaint.h"
 #include "SkShader.h"   // for tilemodes
 #include "SkUtilsArm.h"

 #if !SK_ARM_NEON_IS_NONE
 // These are defined in src/opts/SkBitmapProcState_arm_neon.cpp
 extern const SkBitmapProcState::SampleProc16 gSkBitmapProcStateSample16_neon[];
 extern const SkBitmapProcState::SampleProc32 gSkBitmapProcStateSample32_neon[];
 extern void  S16_D16_filter_DX_neon(const SkBitmapProcState&, const uint32_t*, int, uint16_t*);
 extern void  Clamp_S16_D16_filter_DX_shaderproc_neon(const SkBitmapProcState&, int, int, uint16_t*, int);
 extern void  Repeat_S16_D16_filter_DX_shaderproc_neon(const SkBitmapProcState&, int, int, uint16_t*, int);
 extern void  SI8_opaque_D32_filter_DX_neon(const SkBitmapProcState&, const uint32_t*, int, SkPMColor*);
 extern void  SI8_opaque_D32_filter_DX_shaderproc_neon(const SkBitmapProcState&, int, int, uint32_t*, int);
 extern void  Clamp_SI8_opaque_D32_filter_DX_shaderproc_neon(const SkBitmapProcState&, int, int, uint32_t*, int);
 #endif

 #define   NAME_WRAP(x)  x
 #include "SkBitmapProcState_filter.h"
 #include "SkBitmapProcState_procs.h"

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

 /**
  *  For the purposes of drawing bitmaps, if a matrix is "almost" translate
  *  go ahead and treat it as if it were, so that subsequent code can go fast.
  */
 static bool just_trans_clamp(const SkMatrix& matrix, const SkBitmap& bitmap) {
     SkMatrix::TypeMask mask = matrix.getType();

     if (mask & (SkMatrix::kAffine_Mask | SkMatrix::kPerspective_Mask)) {
         return false;
     }
     if (mask & SkMatrix::kScale_Mask) {
         SkScalar sx = matrix[SkMatrix::kMScaleX];
         SkScalar sy = matrix[SkMatrix::kMScaleY];
         int w = bitmap.width();
         int h = bitmap.height();
         int sw = SkScalarRound(SkScalarMul(sx, SkIntToScalar(w)));
         int sh = SkScalarRound(SkScalarMul(sy, SkIntToScalar(h)));
         return sw == w && sh == h;
     }
     // if we got here, we're either kTranslate_Mask or identity
     return true;
 }

 static bool just_trans_general(const SkMatrix& matrix) {
     SkMatrix::TypeMask mask = matrix.getType();

     if (mask & (SkMatrix::kAffine_Mask | SkMatrix::kPerspective_Mask)) {
         return false;
     }
     if (mask & SkMatrix::kScale_Mask) {
         const SkScalar tol = SK_Scalar1 / 32768;

         if (!SkScalarNearlyZero(matrix[SkMatrix::kMScaleX] - SK_Scalar1, tol)) {
             return false;
         }
         if (!SkScalarNearlyZero(matrix[SkMatrix::kMScaleY] - SK_Scalar1, tol)) {
             return false;
         }
     }
     // if we got here, treat us as either kTranslate_Mask or identity
     return true;
 }

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

 static bool valid_for_filtering(unsigned dimension) {
     // for filtering, width and height must fit in 14bits, since we use steal
     // 2 bits from each to store our 4bit subpixel data
     return (dimension & ~0x3FFF) == 0;
 }

 bool SkBitmapProcState::chooseProcs(const SkMatrix& inv, const SkPaint& paint) {
     if (fOrigBitmap.width() == 0 || fOrigBitmap.height() == 0) {
         return false;
     }

     const SkMatrix* m;
     bool trivial_matrix = (inv.getType() & ~SkMatrix::kTranslate_Mask) == 0;
     bool clamp_clamp = SkShader::kClamp_TileMode == fTileModeX &&
                        SkShader::kClamp_TileMode == fTileModeY;

     if (clamp_clamp || trivial_matrix) {
         m = &inv;
     } else {
         fUnitInvMatrix = inv;
         fUnitInvMatrix.postIDiv(fOrigBitmap.width(), fOrigBitmap.height());
         m = &fUnitInvMatrix;
     }

     fBitmap = &fOrigBitmap;
     if (fOrigBitmap.hasMipMap()) {
         int shift = fOrigBitmap.extractMipLevel(&fMipBitmap,
                                                 SkScalarToFixed(m->getScaleX()),
                                                 SkScalarToFixed(m->getSkewY()));

         if (shift > 0) {
             if (m != &fUnitInvMatrix) {
                 fUnitInvMatrix = *m;
                 m = &fUnitInvMatrix;
             }

             SkScalar scale = SkFixedToScalar(SK_Fixed1 >> shift);
             fUnitInvMatrix.postScale(scale, scale);

             // now point here instead of fOrigBitmap
             fBitmap = &fMipBitmap;
         }
     }

     // wack our matrix to exactly no-scale, if we're really close to begin with
     {
         bool fixupMatrix = clamp_clamp ?
         just_trans_clamp(*m, *fBitmap) : just_trans_general(*m);
         if (fixupMatrix) {
 #ifdef SK_IGNORE_TRANS_CLAMP_FIX
             if (m != &fUnitInvMatrix) {    // can't mutate the original
                 fUnitInvMatrix = inv;
                 m = &fUnitInvMatrix;
             }
             fUnitInvMatrix.set(SkMatrix::kMScaleX, SK_Scalar1);
             fUnitInvMatrix.set(SkMatrix::kMScaleY, SK_Scalar1);
 #else
             // If we can be treated just like translate, construct that inverse
             // such that we landed in the proper place. Given that m may have
             // some slight scale, we have to invert it to compute this new
             // matrix.
             SkMatrix forward;
             if (m->invert(&forward)) {
                 SkScalar tx = -SkScalarRoundToScalar(forward.getTranslateX());
                 SkScalar ty = -SkScalarRoundToScalar(forward.getTranslateY());
                 fUnitInvMatrix.setTranslate(tx, ty);
                 m = &fUnitInvMatrix;
                 // now the following code will sniff m, and decide to take the
                 // fast case (since m is purely translate).
             }
 #endif
         }
     }

     // Below this point, we should never refer to the inv parameter, since we
     // may be using a munged version for "our" inverse.

     fInvMatrix      = m;
     fInvProc        = m->getMapXYProc();
     fInvType        = m->getType();
     fInvSx          = SkScalarToFixed(m->getScaleX());
     fInvSxFractionalInt = SkScalarToFractionalInt(m->getScaleX());
     fInvKy          = SkScalarToFixed(m->getSkewY());
     fInvKyFractionalInt = SkScalarToFractionalInt(m->getSkewY());

     fAlphaScale = SkAlpha255To256(paint.getAlpha());

     // pick-up filtering from the paint, but only if the matrix is
     // more complex than identity/translate (i.e. no need to pay the cost
     // of filtering if we're not scaled etc.).
     // note: we explicitly check inv, since m might be scaled due to unitinv
     //       trickery, but we don't want to see that for this test
     fDoFilter = paint.isFilterBitmap() &&
                 (fInvType > SkMatrix::kTranslate_Mask &&
                  valid_for_filtering(fBitmap->width() | fBitmap->height()));

     fShaderProc32 = NULL;
     fShaderProc16 = NULL;
     fSampleProc32 = NULL;
     fSampleProc16 = NULL;

     fMatrixProc = this->chooseMatrixProc(trivial_matrix);
     if (NULL == fMatrixProc) {
         return false;
     }

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

     int index = 0;
     if (fAlphaScale < 256) {  // note: this distinction is not used for D16
         index |= 1;
     }
     if (fInvType <= (SkMatrix::kTranslate_Mask | SkMatrix::kScale_Mask)) {
         index |= 2;
     }
     if (fDoFilter) {
         index |= 4;
     }
     // bits 3,4,5 encoding the source bitmap format
     switch (fBitmap->config()) {
         case SkBitmap::kARGB_8888_Config:
             index |= 0;
             break;
         case SkBitmap::kRGB_565_Config:
             index |= 8;
             break;
         case SkBitmap::kIndex8_Config:
             index |= 16;
             break;
         case SkBitmap::kARGB_4444_Config:
             index |= 24;
             break;
         case SkBitmap::kA8_Config:
             index |= 32;
             fPaintPMColor = SkPreMultiplyColor(paint.getColor());
             break;
         default:
             return false;
     }

 #if !SK_ARM_NEON_IS_ALWAYS
     static const SampleProc32 gSkBitmapProcStateSample32[] = {
         S32_opaque_D32_nofilter_DXDY,
         S32_alpha_D32_nofilter_DXDY,
         S32_opaque_D32_nofilter_DX,
         S32_alpha_D32_nofilter_DX,
         S32_opaque_D32_filter_DXDY,
         S32_alpha_D32_filter_DXDY,
         S32_opaque_D32_filter_DX,
         S32_alpha_D32_filter_DX,

         S16_opaque_D32_nofilter_DXDY,
         S16_alpha_D32_nofilter_DXDY,
         S16_opaque_D32_nofilter_DX,
         S16_alpha_D32_nofilter_DX,
         S16_opaque_D32_filter_DXDY,
         S16_alpha_D32_filter_DXDY,
         S16_opaque_D32_filter_DX,
         S16_alpha_D32_filter_DX,

         SI8_opaque_D32_nofilter_DXDY,
         SI8_alpha_D32_nofilter_DXDY,
         SI8_opaque_D32_nofilter_DX,
         SI8_alpha_D32_nofilter_DX,
         SI8_opaque_D32_filter_DXDY,
         SI8_alpha_D32_filter_DXDY,
         SI8_opaque_D32_filter_DX,
         SI8_alpha_D32_filter_DX,

         S4444_opaque_D32_nofilter_DXDY,
         S4444_alpha_D32_nofilter_DXDY,
         S4444_opaque_D32_nofilter_DX,
         S4444_alpha_D32_nofilter_DX,
         S4444_opaque_D32_filter_DXDY,
         S4444_alpha_D32_filter_DXDY,
         S4444_opaque_D32_filter_DX,
         S4444_alpha_D32_filter_DX,

         // A8 treats alpha/opaque the same (equally efficient)
         SA8_alpha_D32_nofilter_DXDY,
         SA8_alpha_D32_nofilter_DXDY,
         SA8_alpha_D32_nofilter_DX,
         SA8_alpha_D32_nofilter_DX,
         SA8_alpha_D32_filter_DXDY,
         SA8_alpha_D32_filter_DXDY,
         SA8_alpha_D32_filter_DX,
         SA8_alpha_D32_filter_DX
     };

     static const SampleProc16 gSkBitmapProcStateSample16[] = {
         S32_D16_nofilter_DXDY,
         S32_D16_nofilter_DX,
         S32_D16_filter_DXDY,
         S32_D16_filter_DX,

         S16_D16_nofilter_DXDY,
         S16_D16_nofilter_DX,
         S16_D16_filter_DXDY,
         S16_D16_filter_DX,

         SI8_D16_nofilter_DXDY,
         SI8_D16_nofilter_DX,
         SI8_D16_filter_DXDY,
         SI8_D16_filter_DX,

         // Don't support 4444 -> 565
         NULL, NULL, NULL, NULL,
         // Don't support A8 -> 565
         NULL, NULL, NULL, NULL
     };
 #endif

     fSampleProc32 = SK_ARM_NEON_WRAP(gSkBitmapProcStateSample32)[index];
     index >>= 1;    // shift away any opaque/alpha distinction
     fSampleProc16 = SK_ARM_NEON_WRAP(gSkBitmapProcStateSample16)[index];

     // our special-case shaderprocs
     if (SK_ARM_NEON_WRAP(S16_D16_filter_DX) == fSampleProc16) {
         if (clamp_clamp) {
             fShaderProc16 = SK_ARM_NEON_WRAP(Clamp_S16_D16_filter_DX_shaderproc);
         } else if (SkShader::kRepeat_TileMode == fTileModeX &&
                    SkShader::kRepeat_TileMode == fTileModeY) {
             fShaderProc16 = SK_ARM_NEON_WRAP(Repeat_S16_D16_filter_DX_shaderproc);
         }
     } else if (SK_ARM_NEON_WRAP(SI8_opaque_D32_filter_DX) == fSampleProc32 && clamp_clamp) {
         fShaderProc32 = SK_ARM_NEON_WRAP(Clamp_SI8_opaque_D32_filter_DX_shaderproc);
     }

     if (NULL == fShaderProc32) {
         fShaderProc32 = this->chooseShaderProc32();
     }

     // see if our platform has any accelerated overrides
     this->platformProcs();
     return true;
 }

 static void Clamp_S32_D32_nofilter_trans_shaderproc(const SkBitmapProcState& s,
                                                     int x, int y,
                                                     SkPMColor* SK_RESTRICT colors,
                                                     int count) {
     SkASSERT(((s.fInvType & ~SkMatrix::kTranslate_Mask)) == 0);
     SkASSERT(s.fInvKy == 0);
     SkASSERT(count > 0 && colors != NULL);
     SkASSERT(!s.fDoFilter);

     const int maxX = s.fBitmap->width() - 1;
     const int maxY = s.fBitmap->height() - 1;
     int ix = s.fFilterOneX + x;
     int iy = SkClampMax(s.fFilterOneY + y, maxY);
 #ifdef SK_DEBUG
     {
         SkPoint pt;
         s.fInvProc(*s.fInvMatrix, SkIntToScalar(x) + SK_ScalarHalf,
                    SkIntToScalar(y) + SK_ScalarHalf, &pt);
         int iy2 = SkClampMax(SkScalarFloorToInt(pt.fY), maxY);
         int ix2 = SkScalarFloorToInt(pt.fX);

         SkASSERT(iy == iy2);
         SkASSERT(ix == ix2);
     }
 #endif
     const SkPMColor* row = s.fBitmap->getAddr32(0, iy);

     // clamp to the left
     if (ix < 0) {
         int n = SkMin32(-ix, count);
         sk_memset32(colors, row[0], n);
         count -= n;
         if (0 == count) {
             return;
         }
         colors += n;
         SkASSERT(-ix == n);
         ix = 0;
     }
     // copy the middle
     if (ix <= maxX) {
         int n = SkMin32(maxX - ix + 1, count);
         memcpy(colors, row + ix, n * sizeof(SkPMColor));
         count -= n;
         if (0 == count) {
             return;
         }
         colors += n;
     }
     SkASSERT(count > 0);
     // clamp to the right
     sk_memset32(colors, row[maxX], count);
 }

 static inline int sk_int_mod(int x, int n) {
     SkASSERT(n > 0);
     if ((unsigned)x >= (unsigned)n) {
         if (x < 0) {
             x = n + ~(~x % n);
         } else {
             x = x % n;
         }
     }
     return x;
 }

 static inline int sk_int_mirror(int x, int n) {
     x = sk_int_mod(x, 2 * n);
     if (x >= n) {
         x = n + ~(x - n);
     }
     return x;
 }

 static void Repeat_S32_D32_nofilter_trans_shaderproc(const SkBitmapProcState& s,
                                                      int x, int y,
                                                      SkPMColor* SK_RESTRICT colors,
                                                      int count) {
     SkASSERT(((s.fInvType & ~SkMatrix::kTranslate_Mask)) == 0);
     SkASSERT(s.fInvKy == 0);
     SkASSERT(count > 0 && colors != NULL);
     SkASSERT(!s.fDoFilter);

     const int stopX = s.fBitmap->width();
     const int stopY = s.fBitmap->height();
     int ix = s.fFilterOneX + x;
     int iy = sk_int_mod(s.fFilterOneY + y, stopY);
 #ifdef SK_DEBUG
     {
         SkPoint pt;
         s.fInvProc(*s.fInvMatrix, SkIntToScalar(x) + SK_ScalarHalf,
                    SkIntToScalar(y) + SK_ScalarHalf, &pt);
         int iy2 = sk_int_mod(SkScalarFloorToInt(pt.fY), stopY);
         int ix2 = SkScalarFloorToInt(pt.fX);

         SkASSERT(iy == iy2);
         SkASSERT(ix == ix2);
     }
 #endif
     const SkPMColor* row = s.fBitmap->getAddr32(0, iy);

     ix = sk_int_mod(ix, stopX);
     for (;;) {
         int n = SkMin32(stopX - ix, count);
         memcpy(colors, row + ix, n * sizeof(SkPMColor));
         count -= n;
         if (0 == count) {
             return;
         }
         colors += n;
         ix = 0;
     }
 }

 static void S32_D32_constX_shaderproc(const SkBitmapProcState& s,
                                       int x, int y,
                                       SkPMColor* SK_RESTRICT colors,
                                       int count) {
     SkASSERT((s.fInvType & ~(SkMatrix::kTranslate_Mask | SkMatrix::kScale_Mask)) == 0);
     SkASSERT(s.fInvKy == 0);
     SkASSERT(count > 0 && colors != NULL);
     SkASSERT(1 == s.fBitmap->width());

     int iY0, iY1, iSubY;

     if (s.fDoFilter) {
         SkBitmapProcState::MatrixProc mproc = s.getMatrixProc();
         uint32_t xy[2];

         mproc(s, xy, 1, x, y);

         iY0 = xy[0] >> 18;
         iY1 = xy[0] & 0x3FFF;
         iSubY = (xy[0] >> 14) & 0xF;
     } else {
         int yTemp;

         if (s.fInvType > SkMatrix::kTranslate_Mask) {
             SkPoint pt;
             s.fInvProc(*s.fInvMatrix,
                        SkIntToScalar(x) + SK_ScalarHalf,
                        SkIntToScalar(y) + SK_ScalarHalf,
                        &pt);
             // When the matrix has a scale component the setup code in
             // chooseProcs multiples the inverse matrix by the inverse of the
             // bitmap's width and height. Since this method is going to do
             // its own tiling and sampling we need to undo that here.
             if (SkShader::kClamp_TileMode != s.fTileModeX ||
                 SkShader::kClamp_TileMode != s.fTileModeY) {
                 yTemp = SkScalarFloorToInt(pt.fY * s.fBitmap->height());
             } else {
                 yTemp = SkScalarFloorToInt(pt.fY);
             }
         } else {
             yTemp = s.fFilterOneY + y;
         }

         const int stopY = s.fBitmap->height();
         switch (s.fTileModeY) {
             case SkShader::kClamp_TileMode:
                 iY0 = SkClampMax(yTemp, stopY-1);
                 break;
             case SkShader::kRepeat_TileMode:
                 iY0 = sk_int_mod(yTemp, stopY);
                 break;
             case SkShader::kMirror_TileMode:
             default:
                 iY0 = sk_int_mirror(yTemp, stopY);
                 break;
         }

 #ifdef SK_DEBUG
         {
             SkPoint pt;
             s.fInvProc(*s.fInvMatrix,
                        SkIntToScalar(x) + SK_ScalarHalf,
                        SkIntToScalar(y) + SK_ScalarHalf,
                        &pt);
             if (s.fInvType > SkMatrix::kTranslate_Mask &&
                 (SkShader::kClamp_TileMode != s.fTileModeX ||
                  SkShader::kClamp_TileMode != s.fTileModeY)) {
                 pt.fY *= s.fBitmap->height();
             }
             int iY2;

             switch (s.fTileModeY) {
             case SkShader::kClamp_TileMode:
                 iY2 = SkClampMax(SkScalarFloorToInt(pt.fY), stopY-1);
                 break;
             case SkShader::kRepeat_TileMode:
                 iY2 = sk_int_mod(SkScalarFloorToInt(pt.fY), stopY);
                 break;
             case SkShader::kMirror_TileMode:
             default:
                 iY2 = sk_int_mirror(SkScalarFloorToInt(pt.fY), stopY);
                 break;
             }

             SkASSERT(iY0 == iY2);
         }
 #endif
     }

     const SkPMColor* row0 = s.fBitmap->getAddr32(0, iY0);
     SkPMColor color;

     if (s.fDoFilter) {
         const SkPMColor* row1 = s.fBitmap->getAddr32(0, iY1);

         if (s.fAlphaScale < 256) {
             Filter_32_alpha(iSubY, *row0, *row1, &color, s.fAlphaScale);
         } else {
             Filter_32_opaque(iSubY, *row0, *row1, &color);
         }
     } else {
         if (s.fAlphaScale < 256) {
             color = SkAlphaMulQ(*row0, s.fAlphaScale);
         } else {
             color = *row0;
         }
     }

     sk_memset32(colors, color, count);
 }

 static void DoNothing_shaderproc(const SkBitmapProcState&, int x, int y,
                                  SkPMColor* SK_RESTRICT colors, int count) {
     // if we get called, the matrix is too tricky, so we just draw nothing
     sk_memset32(colors, 0, count);
 }

 bool SkBitmapProcState::setupForTranslate() {
     SkPoint pt;
     fInvProc(*fInvMatrix, SK_ScalarHalf, SK_ScalarHalf, &pt);

     /*
      *  if the translate is larger than our ints, we can get random results, or
      *  worse, we might get 0x80000000, which wreaks havoc on us, since we can't
      *  negate it.
      */
     const SkScalar too_big = SkIntToScalar(1 << 30);
     if (SkScalarAbs(pt.fX) > too_big || SkScalarAbs(pt.fY) > too_big) {
         return false;
     }

     // Since we know we're not filtered, we re-purpose these fields allow
     // us to go from device -> src coordinates w/ just an integer add,
     // rather than running through the inverse-matrix
     fFilterOneX = SkScalarFloorToInt(pt.fX);
     fFilterOneY = SkScalarFloorToInt(pt.fY);
     return true;
 }

 SkBitmapProcState::ShaderProc32 SkBitmapProcState::chooseShaderProc32() {

     if (SkBitmap::kARGB_8888_Config != fBitmap->config()) {
         return NULL;
     }

 #ifndef SK_IGNORE_1XN_BITMAP_OPT
     static const unsigned kMask = SkMatrix::kTranslate_Mask | SkMatrix::kScale_Mask;

     if (1 == fBitmap->width() && 0 == (fInvType & ~kMask)) {
         if (!fDoFilter && fInvType <= SkMatrix::kTranslate_Mask && !this->setupForTranslate()) {
             return DoNothing_shaderproc;
         }
         return S32_D32_constX_shaderproc;
     }
 #endif

     if (fAlphaScale < 256) {
         return NULL;
     }
     if (fInvType > SkMatrix::kTranslate_Mask) {
         return NULL;
     }
     if (fDoFilter) {
         return NULL;
     }

     SkShader::TileMode tx = (SkShader::TileMode)fTileModeX;
     SkShader::TileMode ty = (SkShader::TileMode)fTileModeY;

     if (SkShader::kClamp_TileMode == tx && SkShader::kClamp_TileMode == ty) {
         if (this->setupForTranslate()) {
             return Clamp_S32_D32_nofilter_trans_shaderproc;
         }
         return DoNothing_shaderproc;
     }
     if (SkShader::kRepeat_TileMode == tx && SkShader::kRepeat_TileMode == ty) {
         if (this->setupForTranslate()) {
             return Repeat_S32_D32_nofilter_trans_shaderproc;
         }
         return DoNothing_shaderproc;
     }
     return NULL;
 }

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

 #ifdef SK_DEBUG

 static void check_scale_nofilter(uint32_t bitmapXY[], int count,
                                  unsigned mx, unsigned my) {
     unsigned y = *bitmapXY++;
     SkASSERT(y < my);

     const uint16_t* xptr = reinterpret_cast<const uint16_t*>(bitmapXY);
     for (int i = 0; i < count; ++i) {
         SkASSERT(xptr[i] < mx);
     }
 }

 static void check_scale_filter(uint32_t bitmapXY[], int count,
                                  unsigned mx, unsigned my) {
     uint32_t YY = *bitmapXY++;
     unsigned y0 = YY >> 18;
     unsigned y1 = YY & 0x3FFF;
     SkASSERT(y0 < my);
     SkASSERT(y1 < my);

     for (int i = 0; i < count; ++i) {
         uint32_t XX = bitmapXY[i];
         unsigned x0 = XX >> 18;
         unsigned x1 = XX & 0x3FFF;
         SkASSERT(x0 < mx);
         SkASSERT(x1 < mx);
     }
 }

 static void check_affine_nofilter(uint32_t bitmapXY[], int count,
                                  unsigned mx, unsigned my) {
     for (int i = 0; i < count; ++i) {
         uint32_t XY = bitmapXY[i];
         unsigned x = XY & 0xFFFF;
         unsigned y = XY >> 16;
         SkASSERT(x < mx);
         SkASSERT(y < my);
     }
 }

 static void check_affine_filter(uint32_t bitmapXY[], int count,
                                  unsigned mx, unsigned my) {
     for (int i = 0; i < count; ++i) {
         uint32_t YY = *bitmapXY++;
         unsigned y0 = YY >> 18;
         unsigned y1 = YY & 0x3FFF;
         SkASSERT(y0 < my);
         SkASSERT(y1 < my);

         uint32_t XX = *bitmapXY++;
         unsigned x0 = XX >> 18;
         unsigned x1 = XX & 0x3FFF;
         SkASSERT(x0 < mx);
         SkASSERT(x1 < mx);
     }
 }

 void SkBitmapProcState::DebugMatrixProc(const SkBitmapProcState& state,
                                         uint32_t bitmapXY[], int count,
                                         int x, int y) {
     SkASSERT(bitmapXY);
     SkASSERT(count > 0);

     state.fMatrixProc(state, bitmapXY, count, x, y);

     void (*proc)(uint32_t bitmapXY[], int count, unsigned mx, unsigned my);

     // There are four formats possible:
     //  scale -vs- affine
     //  filter -vs- nofilter
     if (state.fInvType <= (SkMatrix::kTranslate_Mask | SkMatrix::kScale_Mask)) {
         proc = state.fDoFilter ? check_scale_filter : check_scale_nofilter;
     } else {
         proc = state.fDoFilter ? check_affine_filter : check_affine_nofilter;
     }
     proc(bitmapXY, count, state.fBitmap->width(), state.fBitmap->height());
 }

 SkBitmapProcState::MatrixProc SkBitmapProcState::getMatrixProc() const {
     return DebugMatrixProc;
 }

 #endif

 ///////////////////////////////////////////////////////////////////////////////
 /*
     The storage requirements for the different matrix procs are as follows,
     where each X or Y is 2 bytes, and N is the number of pixels/elements:

     scale/translate     nofilter      Y(4bytes) + N * X
     affine/perspective  nofilter      N * (X Y)
     scale/translate     filter        Y Y + N * (X X)
     affine/perspective  filter        N * (Y Y X X)
  */
 int SkBitmapProcState::maxCountForBufferSize(size_t bufferSize) const {
     int32_t size = static_cast<int32_t>(bufferSize);

     size &= ~3; // only care about 4-byte aligned chunks
     if (fInvType <= (SkMatrix::kTranslate_Mask | SkMatrix::kScale_Mask)) {
         size -= 4;   // the shared Y (or YY) coordinate
         if (size < 0) {
             size = 0;
         }
         size >>= 1;
     } else {
         size >>= 2;
     }

     if (fDoFilter) {
         size >>= 1;
     }

     return size;
 }

	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/
	#include "SkBitmapProcState.h"
	#include "SkColorPriv.h"
	#include "SkFilterProc.h"
	#include "SkPaint.h"
	#include "SkShader.h" // for tilemodes
	#include "SkUtilsArm.h"

	#if !SK_ARM_NEON_IS_NONE
	// These are defined in src/opts/SkBitmapProcState_arm_neon.cpp
	extern const SkBitmapProcState::SampleProc16 gSkBitmapProcStateSample16_neon[];
	extern const SkBitmapProcState::SampleProc32 gSkBitmapProcStateSample32_neon[];
	extern void S16_D16_filter_DX_neon(const SkBitmapProcState&, const uint32_t, int, uint16_t);
	extern void Clamp_S16_D16_filter_DX_shaderproc_neon(const SkBitmapProcState&, int, int, uint16_t*, int);
	extern void Repeat_S16_D16_filter_DX_shaderproc_neon(const SkBitmapProcState&, int, int, uint16_t*, int);
	extern void SI8_opaque_D32_filter_DX_neon(const SkBitmapProcState&, const uint32_t, int, SkPMColor);
	extern void SI8_opaque_D32_filter_DX_shaderproc_neon(const SkBitmapProcState&, int, int, uint32_t*, int);
	extern void Clamp_SI8_opaque_D32_filter_DX_shaderproc_neon(const SkBitmapProcState&, int, int, uint32_t*, int);
	#endif

	#define NAME_WRAP(x) x
	#include "SkBitmapProcState_filter.h"
	#include "SkBitmapProcState_procs.h"

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

	/**
	* For the purposes of drawing bitmaps, if a matrix is "almost" translate
	* go ahead and treat it as if it were, so that subsequent code can go fast.
	*/
	static bool just_trans_clamp(const SkMatrix& matrix, const SkBitmap& bitmap) {
	SkMatrix::TypeMask mask = matrix.getType();

	if (mask & (SkMatrix::kAffine_Mask \| SkMatrix::kPerspective_Mask)) {
	return false;
	}
	if (mask & SkMatrix::kScale_Mask) {
	SkScalar sx = matrix[SkMatrix::kMScaleX];
	SkScalar sy = matrix[SkMatrix::kMScaleY];
	int w = bitmap.width();
	int h = bitmap.height();
	int sw = SkScalarRound(SkScalarMul(sx, SkIntToScalar(w)));
	int sh = SkScalarRound(SkScalarMul(sy, SkIntToScalar(h)));
	return sw == w && sh == h;
	}
	// if we got here, we're either kTranslate_Mask or identity
	return true;
	}

	static bool just_trans_general(const SkMatrix& matrix) {
	SkMatrix::TypeMask mask = matrix.getType();

	if (mask & (SkMatrix::kAffine_Mask \| SkMatrix::kPerspective_Mask)) {
	return false;
	}
	if (mask & SkMatrix::kScale_Mask) {
	const SkScalar tol = SK_Scalar1 / 32768;

	if (!SkScalarNearlyZero(matrix[SkMatrix::kMScaleX] - SK_Scalar1, tol)) {
	return false;
	}
	if (!SkScalarNearlyZero(matrix[SkMatrix::kMScaleY] - SK_Scalar1, tol)) {
	return false;
	}
	}
	// if we got here, treat us as either kTranslate_Mask or identity
	return true;
	}

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

	static bool valid_for_filtering(unsigned dimension) {
	// for filtering, width and height must fit in 14bits, since we use steal
	// 2 bits from each to store our 4bit subpixel data
	return (dimension & ~0x3FFF) == 0;
	}

	bool SkBitmapProcState::chooseProcs(const SkMatrix& inv, const SkPaint& paint) {
	if (fOrigBitmap.width() == 0 \|\| fOrigBitmap.height() == 0) {
	return false;
	}

	const SkMatrix* m;
	bool trivial_matrix = (inv.getType() & ~SkMatrix::kTranslate_Mask) == 0;
	bool clamp_clamp = SkShader::kClamp_TileMode == fTileModeX &&
	SkShader::kClamp_TileMode == fTileModeY;

	if (clamp_clamp \|\| trivial_matrix) {
	m = &inv;
	} else {
	fUnitInvMatrix = inv;
	fUnitInvMatrix.postIDiv(fOrigBitmap.width(), fOrigBitmap.height());
	m = &fUnitInvMatrix;
	}

	fBitmap = &fOrigBitmap;
	if (fOrigBitmap.hasMipMap()) {
	int shift = fOrigBitmap.extractMipLevel(&fMipBitmap,
	SkScalarToFixed(m->getScaleX()),
	SkScalarToFixed(m->getSkewY()));

	if (shift > 0) {
	if (m != &fUnitInvMatrix) {
	fUnitInvMatrix = *m;
	m = &fUnitInvMatrix;
	}

	SkScalar scale = SkFixedToScalar(SK_Fixed1 >> shift);
	fUnitInvMatrix.postScale(scale, scale);

	// now point here instead of fOrigBitmap
	fBitmap = &fMipBitmap;
	}
	}

	// wack our matrix to exactly no-scale, if we're really close to begin with
	{
	bool fixupMatrix = clamp_clamp ?
	just_trans_clamp(m, fBitmap) : just_trans_general(*m);
	if (fixupMatrix) {
	#ifdef SK_IGNORE_TRANS_CLAMP_FIX
	if (m != &fUnitInvMatrix) { // can't mutate the original
	fUnitInvMatrix = inv;
	m = &fUnitInvMatrix;
	}
	fUnitInvMatrix.set(SkMatrix::kMScaleX, SK_Scalar1);
	fUnitInvMatrix.set(SkMatrix::kMScaleY, SK_Scalar1);
	#else
	// If we can be treated just like translate, construct that inverse
	// such that we landed in the proper place. Given that m may have
	// some slight scale, we have to invert it to compute this new
	// matrix.
	SkMatrix forward;
	if (m->invert(&forward)) {
	SkScalar tx = -SkScalarRoundToScalar(forward.getTranslateX());
	SkScalar ty = -SkScalarRoundToScalar(forward.getTranslateY());
	fUnitInvMatrix.setTranslate(tx, ty);
	m = &fUnitInvMatrix;
	// now the following code will sniff m, and decide to take the
	// fast case (since m is purely translate).
	}
	#endif
	}
	}

	// Below this point, we should never refer to the inv parameter, since we
	// may be using a munged version for "our" inverse.

	fInvMatrix = m;
	fInvProc = m->getMapXYProc();
	fInvType = m->getType();
	fInvSx = SkScalarToFixed(m->getScaleX());
	fInvSxFractionalInt = SkScalarToFractionalInt(m->getScaleX());
	fInvKy = SkScalarToFixed(m->getSkewY());
	fInvKyFractionalInt = SkScalarToFractionalInt(m->getSkewY());

	fAlphaScale = SkAlpha255To256(paint.getAlpha());

	// pick-up filtering from the paint, but only if the matrix is
	// more complex than identity/translate (i.e. no need to pay the cost
	// of filtering if we're not scaled etc.).
	// note: we explicitly check inv, since m might be scaled due to unitinv
	// trickery, but we don't want to see that for this test
	fDoFilter = paint.isFilterBitmap() &&
	(fInvType > SkMatrix::kTranslate_Mask &&
	valid_for_filtering(fBitmap->width() \| fBitmap->height()));

	fShaderProc32 = NULL;
	fShaderProc16 = NULL;
	fSampleProc32 = NULL;
	fSampleProc16 = NULL;

	fMatrixProc = this->chooseMatrixProc(trivial_matrix);
	if (NULL == fMatrixProc) {
	return false;
	}

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

	int index = 0;
	if (fAlphaScale < 256) { // note: this distinction is not used for D16
	index \|= 1;
	}
	if (fInvType <= (SkMatrix::kTranslate_Mask \| SkMatrix::kScale_Mask)) {
	index \|= 2;
	}
	if (fDoFilter) {
	index \|= 4;
	}
	// bits 3,4,5 encoding the source bitmap format
	switch (fBitmap->config()) {
	case SkBitmap::kARGB_8888_Config:
	index \|= 0;
	break;
	case SkBitmap::kRGB_565_Config:
	index \|= 8;
	break;
	case SkBitmap::kIndex8_Config:
	index \|= 16;
	break;
	case SkBitmap::kARGB_4444_Config:
	index \|= 24;
	break;
	case SkBitmap::kA8_Config:
	index \|= 32;
	fPaintPMColor = SkPreMultiplyColor(paint.getColor());
	break;
	default:
	return false;
	}

	#if !SK_ARM_NEON_IS_ALWAYS
	static const SampleProc32 gSkBitmapProcStateSample32[] = {
	S32_opaque_D32_nofilter_DXDY,
	S32_alpha_D32_nofilter_DXDY,
	S32_opaque_D32_nofilter_DX,
	S32_alpha_D32_nofilter_DX,
	S32_opaque_D32_filter_DXDY,
	S32_alpha_D32_filter_DXDY,
	S32_opaque_D32_filter_DX,
	S32_alpha_D32_filter_DX,

	S16_opaque_D32_nofilter_DXDY,
	S16_alpha_D32_nofilter_DXDY,
	S16_opaque_D32_nofilter_DX,
	S16_alpha_D32_nofilter_DX,
	S16_opaque_D32_filter_DXDY,
	S16_alpha_D32_filter_DXDY,
	S16_opaque_D32_filter_DX,
	S16_alpha_D32_filter_DX,

	SI8_opaque_D32_nofilter_DXDY,
	SI8_alpha_D32_nofilter_DXDY,
	SI8_opaque_D32_nofilter_DX,
	SI8_alpha_D32_nofilter_DX,
	SI8_opaque_D32_filter_DXDY,
	SI8_alpha_D32_filter_DXDY,
	SI8_opaque_D32_filter_DX,
	SI8_alpha_D32_filter_DX,

	S4444_opaque_D32_nofilter_DXDY,
	S4444_alpha_D32_nofilter_DXDY,
	S4444_opaque_D32_nofilter_DX,
	S4444_alpha_D32_nofilter_DX,
	S4444_opaque_D32_filter_DXDY,
	S4444_alpha_D32_filter_DXDY,
	S4444_opaque_D32_filter_DX,
	S4444_alpha_D32_filter_DX,

	// A8 treats alpha/opaque the same (equally efficient)
	SA8_alpha_D32_nofilter_DXDY,
	SA8_alpha_D32_nofilter_DXDY,
	SA8_alpha_D32_nofilter_DX,
	SA8_alpha_D32_nofilter_DX,
	SA8_alpha_D32_filter_DXDY,
	SA8_alpha_D32_filter_DXDY,
	SA8_alpha_D32_filter_DX,
	SA8_alpha_D32_filter_DX
	};

	static const SampleProc16 gSkBitmapProcStateSample16[] = {
	S32_D16_nofilter_DXDY,
	S32_D16_nofilter_DX,
	S32_D16_filter_DXDY,
	S32_D16_filter_DX,

	S16_D16_nofilter_DXDY,
	S16_D16_nofilter_DX,
	S16_D16_filter_DXDY,
	S16_D16_filter_DX,

	SI8_D16_nofilter_DXDY,
	SI8_D16_nofilter_DX,
	SI8_D16_filter_DXDY,
	SI8_D16_filter_DX,

	// Don't support 4444 -> 565
	NULL, NULL, NULL, NULL,
	// Don't support A8 -> 565
	NULL, NULL, NULL, NULL
	};
	#endif

	fSampleProc32 = SK_ARM_NEON_WRAP(gSkBitmapProcStateSample32)[index];
	index >>= 1; // shift away any opaque/alpha distinction
	fSampleProc16 = SK_ARM_NEON_WRAP(gSkBitmapProcStateSample16)[index];

	// our special-case shaderprocs
	if (SK_ARM_NEON_WRAP(S16_D16_filter_DX) == fSampleProc16) {
	if (clamp_clamp) {
	fShaderProc16 = SK_ARM_NEON_WRAP(Clamp_S16_D16_filter_DX_shaderproc);
	} else if (SkShader::kRepeat_TileMode == fTileModeX &&
	SkShader::kRepeat_TileMode == fTileModeY) {
	fShaderProc16 = SK_ARM_NEON_WRAP(Repeat_S16_D16_filter_DX_shaderproc);
	}
	} else if (SK_ARM_NEON_WRAP(SI8_opaque_D32_filter_DX) == fSampleProc32 && clamp_clamp) {
	fShaderProc32 = SK_ARM_NEON_WRAP(Clamp_SI8_opaque_D32_filter_DX_shaderproc);
	}

	if (NULL == fShaderProc32) {
	fShaderProc32 = this->chooseShaderProc32();
	}

	// see if our platform has any accelerated overrides
	this->platformProcs();
	return true;
	}

	static void Clamp_S32_D32_nofilter_trans_shaderproc(const SkBitmapProcState& s,
	int x, int y,
	SkPMColor* SK_RESTRICT colors,
	int count) {
	SkASSERT(((s.fInvType & ~SkMatrix::kTranslate_Mask)) == 0);
	SkASSERT(s.fInvKy == 0);
	SkASSERT(count > 0 && colors != NULL);
	SkASSERT(!s.fDoFilter);

	const int maxX = s.fBitmap->width() - 1;
	const int maxY = s.fBitmap->height() - 1;
	int ix = s.fFilterOneX + x;
	int iy = SkClampMax(s.fFilterOneY + y, maxY);
	#ifdef SK_DEBUG
	{
	SkPoint pt;
	s.fInvProc(*s.fInvMatrix, SkIntToScalar(x) + SK_ScalarHalf,
	SkIntToScalar(y) + SK_ScalarHalf, &pt);
	int iy2 = SkClampMax(SkScalarFloorToInt(pt.fY), maxY);
	int ix2 = SkScalarFloorToInt(pt.fX);

	SkASSERT(iy == iy2);
	SkASSERT(ix == ix2);
	}
	#endif
	const SkPMColor* row = s.fBitmap->getAddr32(0, iy);

	// clamp to the left
	if (ix < 0) {
	int n = SkMin32(-ix, count);
	sk_memset32(colors, row[0], n);
	count -= n;
	if (0 == count) {
	return;
	}
	colors += n;
	SkASSERT(-ix == n);
	ix = 0;
	}
	// copy the middle
	if (ix <= maxX) {
	int n = SkMin32(maxX - ix + 1, count);
	memcpy(colors, row + ix, n * sizeof(SkPMColor));
	count -= n;
	if (0 == count) {
	return;
	}
	colors += n;
	}
	SkASSERT(count > 0);
	// clamp to the right
	sk_memset32(colors, row[maxX], count);
	}

	static inline int sk_int_mod(int x, int n) {
	SkASSERT(n > 0);
	if ((unsigned)x >= (unsigned)n) {
	if (x < 0) {
	x = n + ~(~x % n);
	} else {
	x = x % n;
	}
	}
	return x;
	}

	static inline int sk_int_mirror(int x, int n) {
	x = sk_int_mod(x, 2 * n);
	if (x >= n) {
	x = n + ~(x - n);
	}
	return x;
	}

	static void Repeat_S32_D32_nofilter_trans_shaderproc(const SkBitmapProcState& s,
	int x, int y,
	SkPMColor* SK_RESTRICT colors,
	int count) {
	SkASSERT(((s.fInvType & ~SkMatrix::kTranslate_Mask)) == 0);
	SkASSERT(s.fInvKy == 0);
	SkASSERT(count > 0 && colors != NULL);
	SkASSERT(!s.fDoFilter);

	const int stopX = s.fBitmap->width();
	const int stopY = s.fBitmap->height();
	int ix = s.fFilterOneX + x;
	int iy = sk_int_mod(s.fFilterOneY + y, stopY);
	#ifdef SK_DEBUG
	{
	SkPoint pt;
	s.fInvProc(*s.fInvMatrix, SkIntToScalar(x) + SK_ScalarHalf,
	SkIntToScalar(y) + SK_ScalarHalf, &pt);
	int iy2 = sk_int_mod(SkScalarFloorToInt(pt.fY), stopY);
	int ix2 = SkScalarFloorToInt(pt.fX);

	SkASSERT(iy == iy2);
	SkASSERT(ix == ix2);
	}
	#endif
	const SkPMColor* row = s.fBitmap->getAddr32(0, iy);

	ix = sk_int_mod(ix, stopX);
	for (;;) {
	int n = SkMin32(stopX - ix, count);
	memcpy(colors, row + ix, n * sizeof(SkPMColor));
	count -= n;
	if (0 == count) {
	return;
	}
	colors += n;
	ix = 0;
	}
	}

	static void S32_D32_constX_shaderproc(const SkBitmapProcState& s,
	int x, int y,
	SkPMColor* SK_RESTRICT colors,
	int count) {
	SkASSERT((s.fInvType & ~(SkMatrix::kTranslate_Mask \| SkMatrix::kScale_Mask)) == 0);
	SkASSERT(s.fInvKy == 0);
	SkASSERT(count > 0 && colors != NULL);
	SkASSERT(1 == s.fBitmap->width());

	int iY0, iY1, iSubY;

	if (s.fDoFilter) {
	SkBitmapProcState::MatrixProc mproc = s.getMatrixProc();
	uint32_t xy[2];

	mproc(s, xy, 1, x, y);

	iY0 = xy[0] >> 18;
	iY1 = xy[0] & 0x3FFF;
	iSubY = (xy[0] >> 14) & 0xF;
	} else {
	int yTemp;

	if (s.fInvType > SkMatrix::kTranslate_Mask) {
	SkPoint pt;
	s.fInvProc(*s.fInvMatrix,
	SkIntToScalar(x) + SK_ScalarHalf,
	SkIntToScalar(y) + SK_ScalarHalf,
	&pt);
	// When the matrix has a scale component the setup code in
	// chooseProcs multiples the inverse matrix by the inverse of the
	// bitmap's width and height. Since this method is going to do
	// its own tiling and sampling we need to undo that here.
	if (SkShader::kClamp_TileMode != s.fTileModeX \|\|
	SkShader::kClamp_TileMode != s.fTileModeY) {
	yTemp = SkScalarFloorToInt(pt.fY * s.fBitmap->height());
	} else {
	yTemp = SkScalarFloorToInt(pt.fY);
	}
	} else {
	yTemp = s.fFilterOneY + y;
	}

	const int stopY = s.fBitmap->height();
	switch (s.fTileModeY) {
	case SkShader::kClamp_TileMode:
	iY0 = SkClampMax(yTemp, stopY-1);
	break;
	case SkShader::kRepeat_TileMode:
	iY0 = sk_int_mod(yTemp, stopY);
	break;
	case SkShader::kMirror_TileMode:
	default:
	iY0 = sk_int_mirror(yTemp, stopY);
	break;
	}

	#ifdef SK_DEBUG
	{
	SkPoint pt;
	s.fInvProc(*s.fInvMatrix,
	SkIntToScalar(x) + SK_ScalarHalf,
	SkIntToScalar(y) + SK_ScalarHalf,
	&pt);
	if (s.fInvType > SkMatrix::kTranslate_Mask &&
	(SkShader::kClamp_TileMode != s.fTileModeX \|\|
	SkShader::kClamp_TileMode != s.fTileModeY)) {
	pt.fY *= s.fBitmap->height();
	}
	int iY2;

	switch (s.fTileModeY) {
	case SkShader::kClamp_TileMode:
	iY2 = SkClampMax(SkScalarFloorToInt(pt.fY), stopY-1);
	break;
	case SkShader::kRepeat_TileMode:
	iY2 = sk_int_mod(SkScalarFloorToInt(pt.fY), stopY);
	break;
	case SkShader::kMirror_TileMode:
	default:
	iY2 = sk_int_mirror(SkScalarFloorToInt(pt.fY), stopY);
	break;
	}

	SkASSERT(iY0 == iY2);
	}
	#endif
	}

	const SkPMColor* row0 = s.fBitmap->getAddr32(0, iY0);
	SkPMColor color;

	if (s.fDoFilter) {
	const SkPMColor* row1 = s.fBitmap->getAddr32(0, iY1);

	if (s.fAlphaScale < 256) {
	Filter_32_alpha(iSubY, row0, row1, &color, s.fAlphaScale);
	} else {
	Filter_32_opaque(iSubY, row0, row1, &color);
	}
	} else {
	if (s.fAlphaScale < 256) {
	color = SkAlphaMulQ(*row0, s.fAlphaScale);
	} else {
	color = *row0;
	}
	}

	sk_memset32(colors, color, count);
	}

	static void DoNothing_shaderproc(const SkBitmapProcState&, int x, int y,
	SkPMColor* SK_RESTRICT colors, int count) {
	// if we get called, the matrix is too tricky, so we just draw nothing
	sk_memset32(colors, 0, count);
	}

	bool SkBitmapProcState::setupForTranslate() {
	SkPoint pt;
	fInvProc(*fInvMatrix, SK_ScalarHalf, SK_ScalarHalf, &pt);

	/*
	* if the translate is larger than our ints, we can get random results, or
	* worse, we might get 0x80000000, which wreaks havoc on us, since we can't
	* negate it.
	*/
	const SkScalar too_big = SkIntToScalar(1 << 30);
	if (SkScalarAbs(pt.fX) > too_big \|\| SkScalarAbs(pt.fY) > too_big) {
	return false;
	}

	// Since we know we're not filtered, we re-purpose these fields allow
	// us to go from device -> src coordinates w/ just an integer add,
	// rather than running through the inverse-matrix
	fFilterOneX = SkScalarFloorToInt(pt.fX);
	fFilterOneY = SkScalarFloorToInt(pt.fY);
	return true;
	}

	SkBitmapProcState::ShaderProc32 SkBitmapProcState::chooseShaderProc32() {

	if (SkBitmap::kARGB_8888_Config != fBitmap->config()) {
	return NULL;
	}

	#ifndef SK_IGNORE_1XN_BITMAP_OPT
	static const unsigned kMask = SkMatrix::kTranslate_Mask \| SkMatrix::kScale_Mask;

	if (1 == fBitmap->width() && 0 == (fInvType & ~kMask)) {
	if (!fDoFilter && fInvType <= SkMatrix::kTranslate_Mask && !this->setupForTranslate()) {
	return DoNothing_shaderproc;
	}
	return S32_D32_constX_shaderproc;
	}
	#endif

	if (fAlphaScale < 256) {
	return NULL;
	}
	if (fInvType > SkMatrix::kTranslate_Mask) {
	return NULL;
	}
	if (fDoFilter) {
	return NULL;
	}

	SkShader::TileMode tx = (SkShader::TileMode)fTileModeX;
	SkShader::TileMode ty = (SkShader::TileMode)fTileModeY;

	if (SkShader::kClamp_TileMode == tx && SkShader::kClamp_TileMode == ty) {
	if (this->setupForTranslate()) {
	return Clamp_S32_D32_nofilter_trans_shaderproc;
	}
	return DoNothing_shaderproc;
	}
	if (SkShader::kRepeat_TileMode == tx && SkShader::kRepeat_TileMode == ty) {
	if (this->setupForTranslate()) {
	return Repeat_S32_D32_nofilter_trans_shaderproc;
	}
	return DoNothing_shaderproc;
	}
	return NULL;
	}

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

	#ifdef SK_DEBUG

	static void check_scale_nofilter(uint32_t bitmapXY[], int count,
	unsigned mx, unsigned my) {
	unsigned y = *bitmapXY++;
	SkASSERT(y < my);

	const uint16_t* xptr = reinterpret_cast<const uint16_t*>(bitmapXY);
	for (int i = 0; i < count; ++i) {
	SkASSERT(xptr[i] < mx);
	}
	}

	static void check_scale_filter(uint32_t bitmapXY[], int count,
	unsigned mx, unsigned my) {
	uint32_t YY = *bitmapXY++;
	unsigned y0 = YY >> 18;
	unsigned y1 = YY & 0x3FFF;
	SkASSERT(y0 < my);
	SkASSERT(y1 < my);

	for (int i = 0; i < count; ++i) {
	uint32_t XX = bitmapXY[i];
	unsigned x0 = XX >> 18;
	unsigned x1 = XX & 0x3FFF;
	SkASSERT(x0 < mx);
	SkASSERT(x1 < mx);
	}
	}

	static void check_affine_nofilter(uint32_t bitmapXY[], int count,
	unsigned mx, unsigned my) {
	for (int i = 0; i < count; ++i) {
	uint32_t XY = bitmapXY[i];
	unsigned x = XY & 0xFFFF;
	unsigned y = XY >> 16;
	SkASSERT(x < mx);
	SkASSERT(y < my);
	}
	}

	static void check_affine_filter(uint32_t bitmapXY[], int count,
	unsigned mx, unsigned my) {
	for (int i = 0; i < count; ++i) {
	uint32_t YY = *bitmapXY++;
	unsigned y0 = YY >> 18;
	unsigned y1 = YY & 0x3FFF;
	SkASSERT(y0 < my);
	SkASSERT(y1 < my);

	uint32_t XX = *bitmapXY++;
	unsigned x0 = XX >> 18;
	unsigned x1 = XX & 0x3FFF;
	SkASSERT(x0 < mx);
	SkASSERT(x1 < mx);
	}
	}

	void SkBitmapProcState::DebugMatrixProc(const SkBitmapProcState& state,
	uint32_t bitmapXY[], int count,
	int x, int y) {
	SkASSERT(bitmapXY);
	SkASSERT(count > 0);

	state.fMatrixProc(state, bitmapXY, count, x, y);

	void (*proc)(uint32_t bitmapXY[], int count, unsigned mx, unsigned my);

	// There are four formats possible:
	// scale -vs- affine
	// filter -vs- nofilter
	if (state.fInvType <= (SkMatrix::kTranslate_Mask \| SkMatrix::kScale_Mask)) {
	proc = state.fDoFilter ? check_scale_filter : check_scale_nofilter;
	} else {
	proc = state.fDoFilter ? check_affine_filter : check_affine_nofilter;
	}
	proc(bitmapXY, count, state.fBitmap->width(), state.fBitmap->height());
	}

	SkBitmapProcState::MatrixProc SkBitmapProcState::getMatrixProc() const {
	return DebugMatrixProc;
	}

	#endif

	///////////////////////////////////////////////////////////////////////////////
	/*
	The storage requirements for the different matrix procs are as follows,
	where each X or Y is 2 bytes, and N is the number of pixels/elements:

	scale/translate nofilter Y(4bytes) + N * X
	affine/perspective nofilter N * (X Y)
	scale/translate filter Y Y + N * (X X)
	affine/perspective filter N * (Y Y X X)
	*/
	int SkBitmapProcState::maxCountForBufferSize(size_t bufferSize) const {
	int32_t size = static_cast<int32_t>(bufferSize);

	size &= ~3; // only care about 4-byte aligned chunks
	if (fInvType <= (SkMatrix::kTranslate_Mask \| SkMatrix::kScale_Mask)) {
	size -= 4; // the shared Y (or YY) coordinate
	if (size < 0) {
	size = 0;
	}
	size >>= 1;
	} else {
	size >>= 2;
	}

	if (fDoFilter) {
	size >>= 1;
	}

	return size;
	}