src/effects/gradients/SkTwoPointRadialGradient.cpp - platform/external/skqp - Gitiles


 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

  #include "SkTwoPointRadialGradient.h"

 /* Two-point radial gradients are specified by two circles, each with a center
    point and radius.  The gradient can be considered to be a series of
    concentric circles, with the color interpolated from the start circle
    (at t=0) to the end circle (at t=1).

    For each point (x, y) in the span, we want to find the
    interpolated circle that intersects that point.  The center
    of the desired circle (Cx, Cy) falls at some distance t
    along the line segment between the start point (Sx, Sy) and
    end point (Ex, Ey):

       Cx = (1 - t) * Sx + t * Ex        (0 <= t <= 1)
       Cy = (1 - t) * Sy + t * Ey

    The radius of the desired circle (r) is also a linear interpolation t
    between the start and end radii (Sr and Er):

       r = (1 - t) * Sr + t * Er

    But

       (x - Cx)^2 + (y - Cy)^2 = r^2

    so

      (x - ((1 - t) * Sx + t * Ex))^2
    + (y - ((1 - t) * Sy + t * Ey))^2
    = ((1 - t) * Sr + t * Er)^2

    Solving for t yields

      [(Sx - Ex)^2 + (Sy - Ey)^2 - (Er - Sr)^2)] * t^2
    + [2 * (Sx - Ex)(x - Sx) + 2 * (Sy - Ey)(y - Sy) - 2 * (Er - Sr) * Sr] * t
    + [(x - Sx)^2 + (y - Sy)^2 - Sr^2] = 0

    To simplify, let Dx = Sx - Ex, Dy = Sy - Ey, Dr = Er - Sr, dx = x - Sx, dy = y - Sy

      [Dx^2 + Dy^2 - Dr^2)] * t^2
    + 2 * [Dx * dx + Dy * dy - Dr * Sr] * t
    + [dx^2 + dy^2 - Sr^2] = 0

    A quadratic in t.  The two roots of the quadratic reflect the two
    possible circles on which the point may fall.  Solving for t yields
    the gradient value to use.

    If a<0, the start circle is entirely contained in the
    end circle, and one of the roots will be <0 or >1 (off the line
    segment).  If a>0, the start circle falls at least partially
    outside the end circle (or vice versa), and the gradient
    defines a "tube" where a point may be on one circle (on the
    inside of the tube) or the other (outside of the tube).  We choose
    one arbitrarily.

    In order to keep the math to within the limits of fixed point,
    we divide the entire quadratic by Dr^2, and replace
    (x - Sx)/Dr with x' and (y - Sy)/Dr with y', giving

    [Dx^2 / Dr^2 + Dy^2 / Dr^2 - 1)] * t^2
    + 2 * [x' * Dx / Dr + y' * Dy / Dr - Sr / Dr] * t
    + [x'^2 + y'^2 - Sr^2/Dr^2] = 0

    (x' and y' are computed by appending the subtract and scale to the
    fDstToIndex matrix in the constructor).

    Since the 'A' component of the quadratic is independent of x' and y', it
    is precomputed in the constructor.  Since the 'B' component is linear in
    x' and y', if x and y are linear in the span, 'B' can be computed
    incrementally with a simple delta (db below).  If it is not (e.g.,
    a perspective projection), it must be computed in the loop.

 */

 namespace {

 inline SkFixed two_point_radial(SkScalar b, SkScalar fx, SkScalar fy,
                                 SkScalar sr2d2, SkScalar foura,
                                 SkScalar oneOverTwoA, bool posRoot) {
     SkScalar c = SkScalarSquare(fx) + SkScalarSquare(fy) - sr2d2;
     if (0 == foura) {
         return SkScalarToFixed(SkScalarDiv(-c, b));
     }

     SkScalar discrim = SkScalarSquare(b) - SkScalarMul(foura, c);
     if (discrim < 0) {
         discrim = -discrim;
     }
     SkScalar rootDiscrim = SkScalarSqrt(discrim);
     SkScalar result;
     if (posRoot) {
         result = SkScalarMul(-b + rootDiscrim, oneOverTwoA);
     } else {
         result = SkScalarMul(-b - rootDiscrim, oneOverTwoA);
     }
     return SkScalarToFixed(result);
 }

 typedef void (* TwoPointRadialShadeProc)(SkScalar fx, SkScalar dx,
         SkScalar fy, SkScalar dy,
         SkScalar b, SkScalar db,
         SkScalar fSr2D2, SkScalar foura, SkScalar fOneOverTwoA, bool posRoot,
         SkPMColor* SK_RESTRICT dstC, const SkPMColor* SK_RESTRICT cache,
         int count);

 void shadeSpan_twopoint_clamp(SkScalar fx, SkScalar dx,
         SkScalar fy, SkScalar dy,
         SkScalar b, SkScalar db,
         SkScalar fSr2D2, SkScalar foura, SkScalar fOneOverTwoA, bool posRoot,
         SkPMColor* SK_RESTRICT dstC, const SkPMColor* SK_RESTRICT cache,
         int count) {
     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 >> SkGradientShaderBase::kCache32Shift];
         fx += dx;
         fy += dy;
         b += db;
     }
 }
 void shadeSpan_twopoint_mirror(SkScalar fx, SkScalar dx,
         SkScalar fy, SkScalar dy,
         SkScalar b, SkScalar db,
         SkScalar fSr2D2, SkScalar foura, SkScalar fOneOverTwoA, bool posRoot,
         SkPMColor* SK_RESTRICT dstC, const SkPMColor* SK_RESTRICT cache,
         int count) {
     for (; count > 0; --count) {
         SkFixed t = two_point_radial(b, fx, fy, fSr2D2, foura,
                                      fOneOverTwoA, posRoot);
         SkFixed index = mirror_tileproc(t);
         SkASSERT(index <= 0xFFFF);
         *dstC++ = cache[index >> SkGradientShaderBase::kCache32Shift];
         fx += dx;
         fy += dy;
         b += db;
     }
 }

 void shadeSpan_twopoint_repeat(SkScalar fx, SkScalar dx,
         SkScalar fy, SkScalar dy,
         SkScalar b, SkScalar db,
         SkScalar fSr2D2, SkScalar foura, SkScalar fOneOverTwoA, bool posRoot,
         SkPMColor* SK_RESTRICT dstC, const SkPMColor* SK_RESTRICT cache,
         int count) {
     for (; count > 0; --count) {
         SkFixed t = two_point_radial(b, fx, fy, fSr2D2, foura,
                                      fOneOverTwoA, posRoot);
         SkFixed index = repeat_tileproc(t);
         SkASSERT(index <= 0xFFFF);
         *dstC++ = cache[index >> SkGradientShaderBase::kCache32Shift];
         fx += dx;
         fy += dy;
         b += db;
     }
 }
 }

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

 SkTwoPointRadialGradient::SkTwoPointRadialGradient(
     const SkPoint& start, SkScalar startRadius,
     const SkPoint& end, SkScalar endRadius,
     const Descriptor& desc)
     : SkGradientShaderBase(desc),
       fCenter1(start),
       fCenter2(end),
       fRadius1(startRadius),
       fRadius2(endRadius) {
     init();
 }

 SkShader::BitmapType SkTwoPointRadialGradient::asABitmap(
     SkBitmap* bitmap,
     SkMatrix* matrix,
     SkShader::TileMode* xy) const {
     if (bitmap) {
         this->getGradientTableBitmap(bitmap);
     }
     SkScalar diffL = 0; // just to avoid gcc warning
     if (matrix) {
         diffL = SkScalarSqrt(SkScalarSquare(fDiff.fX) +
                              SkScalarSquare(fDiff.fY));
     }
     if (matrix) {
         if (diffL) {
             SkScalar invDiffL = SkScalarInvert(diffL);
             matrix->setSinCos(-SkScalarMul(invDiffL, fDiff.fY),
                               SkScalarMul(invDiffL, fDiff.fX));
         } else {
             matrix->reset();
         }
         matrix->preConcat(fPtsToUnit);
     }
     if (xy) {
         xy[0] = fTileMode;
         xy[1] = kClamp_TileMode;
     }
     return kTwoPointRadial_BitmapType;
 }

 SkShader::GradientType SkTwoPointRadialGradient::asAGradient(
     SkShader::GradientInfo* info) const {
     if (info) {
         commonAsAGradient(info);
         info->fPoint[0] = fCenter1;
         info->fPoint[1] = fCenter2;
         info->fRadius[0] = fRadius1;
         info->fRadius[1] = fRadius2;
     }
     return kRadial2_GradientType;
 }

 void SkTwoPointRadialGradient::shadeSpan(int x, int y, SkPMColor* dstCParam,
                                          int count) {
     SkASSERT(count > 0);

     SkPMColor* SK_RESTRICT dstC = dstCParam;

     // Zero difference between radii:  fill with transparent black.
     if (fDiffRadius == 0) {
       sk_bzero(dstC, count * sizeof(*dstC));
       return;
     }
     SkMatrix::MapXYProc dstProc = fDstToIndexProc;
     TileProc            proc = fTileProc;
     const SkPMColor* SK_RESTRICT cache = this->getCache32();

     SkScalar foura = fA * 4;
     bool posRoot = fDiffRadius < 0;
     if (fDstToIndexClass != kPerspective_MatrixClass) {
         SkPoint srcPt;
         dstProc(fDstToIndex, SkIntToScalar(x) + SK_ScalarHalf,
                              SkIntToScalar(y) + SK_ScalarHalf, &srcPt);
         SkScalar dx, fx = srcPt.fX;
         SkScalar dy, fy = srcPt.fY;

         if (fDstToIndexClass == kFixedStepInX_MatrixClass) {
             SkFixed fixedX, fixedY;
             (void)fDstToIndex.fixedStepInX(SkIntToScalar(y), &fixedX, &fixedY);
             dx = SkFixedToScalar(fixedX);
             dy = SkFixedToScalar(fixedY);
         } else {
             SkASSERT(fDstToIndexClass == kLinear_MatrixClass);
             dx = fDstToIndex.getScaleX();
             dy = fDstToIndex.getSkewY();
         }
         SkScalar b = (SkScalarMul(fDiff.fX, fx) +
                      SkScalarMul(fDiff.fY, fy) - fStartRadius) * 2;
         SkScalar db = (SkScalarMul(fDiff.fX, dx) +
                       SkScalarMul(fDiff.fY, dy)) * 2;

         TwoPointRadialShadeProc shadeProc = shadeSpan_twopoint_repeat;
         if (SkShader::kClamp_TileMode == fTileMode) {
             shadeProc = shadeSpan_twopoint_clamp;
         } else if (SkShader::kMirror_TileMode == fTileMode) {
             shadeProc = shadeSpan_twopoint_mirror;
         } else {
             SkASSERT(SkShader::kRepeat_TileMode == fTileMode);
         }
         (*shadeProc)(fx, dx, fy, dy, b, db,
                      fSr2D2, foura, fOneOverTwoA, posRoot,
                      dstC, cache, count);
     } else {    // perspective case
         SkScalar dstX = SkIntToScalar(x);
         SkScalar dstY = SkIntToScalar(y);
         for (; count > 0; --count) {
             SkPoint             srcPt;
             dstProc(fDstToIndex, dstX, dstY, &srcPt);
             SkScalar fx = srcPt.fX;
             SkScalar fy = srcPt.fY;
             SkScalar b = (SkScalarMul(fDiff.fX, fx) +
                          SkScalarMul(fDiff.fY, fy) - fStartRadius) * 2;
             SkFixed t = two_point_radial(b, fx, fy, fSr2D2, foura,
                                          fOneOverTwoA, posRoot);
             SkFixed index = proc(t);
             SkASSERT(index <= 0xFFFF);
             *dstC++ = cache[index >> SkGradientShaderBase::kCache32Shift];
             dstX += SK_Scalar1;
         }
     }
 }

 bool SkTwoPointRadialGradient::setContext( const SkBitmap& device,
                                           const SkPaint& paint,
                                           const SkMatrix& matrix){
     // For now, we might have divided by zero, so detect that
     if (0 == fDiffRadius) {
         return false;
     }

     if (!this->INHERITED::setContext(device, paint, matrix)) {
         return false;
     }

     // we don't have a span16 proc
     fFlags &= ~kHasSpan16_Flag;
     return true;
 }

 #ifdef SK_DEVELOPER
 void SkTwoPointRadialGradient::toString(SkString* str) const {
     str->append("SkTwoPointRadialGradient: (");

     str->append("center1: (");
     str->appendScalar(fCenter1.fX);
     str->append(", ");
     str->appendScalar(fCenter1.fY);
     str->append(") radius1: ");
     str->appendScalar(fRadius1);
     str->append(" ");

     str->append("center2: (");
     str->appendScalar(fCenter2.fX);
     str->append(", ");
     str->appendScalar(fCenter2.fY);
     str->append(") radius2: ");
     str->appendScalar(fRadius2);
     str->append(" ");

     this->INHERITED::toString(str);

     str->append(")");
 }
 #endif

 SkTwoPointRadialGradient::SkTwoPointRadialGradient(
     SkFlattenableReadBuffer& buffer)
     : INHERITED(buffer),
       fCenter1(buffer.readPoint()),
       fCenter2(buffer.readPoint()),
       fRadius1(buffer.readScalar()),
       fRadius2(buffer.readScalar()) {
     init();
 };

 void SkTwoPointRadialGradient::flatten(
     SkFlattenableWriteBuffer& buffer) const {
     this->INHERITED::flatten(buffer);
     buffer.writePoint(fCenter1);
     buffer.writePoint(fCenter2);
     buffer.writeScalar(fRadius1);
     buffer.writeScalar(fRadius2);
 }

 void SkTwoPointRadialGradient::init() {
     fDiff = fCenter1 - fCenter2;
     fDiffRadius = fRadius2 - fRadius1;
     // hack to avoid zero-divide for now
     SkScalar inv = fDiffRadius ? SkScalarInvert(fDiffRadius) : 0;
     fDiff.fX = SkScalarMul(fDiff.fX, inv);
     fDiff.fY = SkScalarMul(fDiff.fY, inv);
     fStartRadius = SkScalarMul(fRadius1, inv);
     fSr2D2 = SkScalarSquare(fStartRadius);
     fA = SkScalarSquare(fDiff.fX) + SkScalarSquare(fDiff.fY) - SK_Scalar1;
     fOneOverTwoA = fA ? SkScalarInvert(fA * 2) : 0;

     fPtsToUnit.setTranslate(-fCenter1.fX, -fCenter1.fY);
     fPtsToUnit.postScale(inv, inv);
 }

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

 #if SK_SUPPORT_GPU

 #include "GrTBackendEffectFactory.h"

 // For brevity
 typedef GrGLUniformManager::UniformHandle UniformHandle;

 class GrGLRadial2Gradient : public GrGLGradientEffect {

 public:

     GrGLRadial2Gradient(const GrBackendEffectFactory& factory, const GrDrawEffect&);
     virtual ~GrGLRadial2Gradient() { }

     virtual void emitCode(GrGLShaderBuilder*,
                           const GrDrawEffect&,
                           EffectKey,
                           const char* outputColor,
                           const char* inputColor,
                           const TransformedCoordsArray&,
                           const TextureSamplerArray&) SK_OVERRIDE;
     virtual void setData(const GrGLUniformManager&, const GrDrawEffect&) SK_OVERRIDE;

     static EffectKey GenKey(const GrDrawEffect&, const GrGLCaps& caps);

 protected:

     UniformHandle   fVSParamUni;
     UniformHandle   fFSParamUni;

     const char* fVSVaryingName;
     const char* fFSVaryingName;

     bool fIsDegenerate;

     // @{
     /// Values last uploaded as uniforms

     SkScalar fCachedCenter;
     SkScalar fCachedRadius;
     bool     fCachedPosRoot;

     // @}

 private:

     typedef GrGLGradientEffect INHERITED;

 };

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

 class GrRadial2Gradient : public GrGradientEffect {
 public:
     static GrEffectRef* Create(GrContext* ctx,
                                const SkTwoPointRadialGradient& shader,
                                const SkMatrix& matrix,
                                SkShader::TileMode tm) {
         AutoEffectUnref effect(SkNEW_ARGS(GrRadial2Gradient, (ctx, shader, matrix, tm)));
         return CreateEffectRef(effect);
     }

     virtual ~GrRadial2Gradient() { }

     static const char* Name() { return "Two-Point Radial Gradient"; }
     virtual const GrBackendEffectFactory& getFactory() const SK_OVERRIDE {
         return GrTBackendEffectFactory<GrRadial2Gradient>::getInstance();
     }

     // The radial gradient parameters can collapse to a linear (instead of quadratic) equation.
     bool isDegenerate() const { return SK_Scalar1 == fCenterX1; }
     SkScalar center() const { return fCenterX1; }
     SkScalar radius() const { return fRadius0; }
     bool isPosRoot() const { return SkToBool(fPosRoot); }

     typedef GrGLRadial2Gradient GLEffect;

 private:
     virtual bool onIsEqual(const GrEffect& sBase) const SK_OVERRIDE {
         const GrRadial2Gradient& s = CastEffect<GrRadial2Gradient>(sBase);
         return (INHERITED::onIsEqual(sBase) &&
                 this->fCenterX1 == s.fCenterX1 &&
                 this->fRadius0 == s.fRadius0 &&
                 this->fPosRoot == s.fPosRoot);
     }

     GrRadial2Gradient(GrContext* ctx,
                       const SkTwoPointRadialGradient& shader,
                       const SkMatrix& matrix,
                       SkShader::TileMode tm)
         : INHERITED(ctx, shader, matrix, tm)
         , fCenterX1(shader.getCenterX1())
         , fRadius0(shader.getStartRadius())
         , fPosRoot(shader.getDiffRadius() < 0) { }

     GR_DECLARE_EFFECT_TEST;

     // @{
     // Cache of values - these can change arbitrarily, EXCEPT
     // we shouldn't change between degenerate and non-degenerate?!

     SkScalar fCenterX1;
     SkScalar fRadius0;
     SkBool8  fPosRoot;

     // @}

     typedef GrGradientEffect INHERITED;
 };

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

 GR_DEFINE_EFFECT_TEST(GrRadial2Gradient);

 GrEffectRef* GrRadial2Gradient::TestCreate(SkRandom* random,
                                            GrContext* context,
                                            const GrDrawTargetCaps&,
                                            GrTexture**) {
     SkPoint center1 = {random->nextUScalar1(), random->nextUScalar1()};
     SkScalar radius1 = random->nextUScalar1();
     SkPoint center2;
     SkScalar radius2;
     do {
         center2.set(random->nextUScalar1(), random->nextUScalar1());
         radius2 = random->nextUScalar1 ();
         // There is a bug in two point radial gradients with identical radii
     } while (radius1 == radius2);

     SkColor colors[kMaxRandomGradientColors];
     SkScalar stopsArray[kMaxRandomGradientColors];
     SkScalar* stops = stopsArray;
     SkShader::TileMode tm;
     int colorCount = RandomGradientParams(random, colors, &stops, &tm);
     SkAutoTUnref<SkShader> shader(SkGradientShader::CreateTwoPointRadial(center1, radius1,
                                                                          center2, radius2,
                                                                          colors, stops, colorCount,
                                                                          tm));
     SkPaint paint;
     return shader->asNewEffect(context, paint);
 }

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

 GrGLRadial2Gradient::GrGLRadial2Gradient(const GrBackendEffectFactory& factory,
                                          const GrDrawEffect& drawEffect)
     : INHERITED(factory)
     , fVSVaryingName(NULL)
     , fFSVaryingName(NULL)
     , fCachedCenter(SK_ScalarMax)
     , fCachedRadius(-SK_ScalarMax)
     , fCachedPosRoot(0) {

     const GrRadial2Gradient& data = drawEffect.castEffect<GrRadial2Gradient>();
     fIsDegenerate = data.isDegenerate();
 }

 void GrGLRadial2Gradient::emitCode(GrGLShaderBuilder* builder,
                                    const GrDrawEffect& drawEffect,
                                    EffectKey key,
                                    const char* outputColor,
                                    const char* inputColor,
                                    const TransformedCoordsArray& coords,
                                    const TextureSamplerArray& samplers) {

     this->emitUniforms(builder, key);
     // 2 copies of uniform array, 1 for each of vertex & fragment shader,
     // to work around Xoom bug. Doesn't seem to cause performance decrease
     // in test apps, but need to keep an eye on it.
     fVSParamUni = builder->addUniformArray(GrGLShaderBuilder::kVertex_Visibility,
                                            kFloat_GrSLType, "Radial2VSParams", 6);
     fFSParamUni = builder->addUniformArray(GrGLShaderBuilder::kFragment_Visibility,
                                            kFloat_GrSLType, "Radial2FSParams", 6);

     // For radial gradients without perspective we can pass the linear
     // part of the quadratic as a varying.
     GrGLShaderBuilder::VertexBuilder* vertexBuilder =
         (kVec2f_GrSLType == coords[0].type()) ? builder->getVertexBuilder() : NULL;
     if (NULL != vertexBuilder) {
         vertexBuilder->addVarying(kFloat_GrSLType, "Radial2BCoeff",
                                     &fVSVaryingName, &fFSVaryingName);
     }

     // VS
     {
         SkString p2;
         SkString p3;
         builder->getUniformVariable(fVSParamUni).appendArrayAccess(2, &p2);
         builder->getUniformVariable(fVSParamUni).appendArrayAccess(3, &p3);

         // For radial gradients without perspective we can pass the linear
         // part of the quadratic as a varying.
         if (NULL != vertexBuilder) {
             // r2Var = 2 * (r2Parm[2] * varCoord.x - r2Param[3])
             vertexBuilder->vsCodeAppendf("\t%s = 2.0 *(%s * %s.x - %s);\n",
                                            fVSVaryingName, p2.c_str(),
                                            coords[0].getVSName().c_str(), p3.c_str());
         }
     }

     // FS
     {
         SkString coords2D = builder->ensureFSCoords2D(coords, 0);
         SkString cName("c");
         SkString ac4Name("ac4");
         SkString rootName("root");
         SkString t;
         SkString p0;
         SkString p1;
         SkString p2;
         SkString p3;
         SkString p4;
         SkString p5;
         builder->getUniformVariable(fFSParamUni).appendArrayAccess(0, &p0);
         builder->getUniformVariable(fFSParamUni).appendArrayAccess(1, &p1);
         builder->getUniformVariable(fFSParamUni).appendArrayAccess(2, &p2);
         builder->getUniformVariable(fFSParamUni).appendArrayAccess(3, &p3);
         builder->getUniformVariable(fFSParamUni).appendArrayAccess(4, &p4);
         builder->getUniformVariable(fFSParamUni).appendArrayAccess(5, &p5);

         // If we we're able to interpolate the linear component,
         // bVar is the varying; otherwise compute it
         SkString bVar;
         if (NULL != vertexBuilder) {
             bVar = fFSVaryingName;
         } else {
             bVar = "b";
             builder->fsCodeAppendf("\tfloat %s = 2.0 * (%s * %s.x - %s);\n",
                                    bVar.c_str(), p2.c_str(), coords2D.c_str(), p3.c_str());
         }

         // c = (x^2)+(y^2) - params[4]
         builder->fsCodeAppendf("\tfloat %s = dot(%s, %s) - %s;\n",
                                cName.c_str(),
                                coords2D.c_str(),
                                coords2D.c_str(),
                                p4.c_str());

         // If we aren't degenerate, emit some extra code, and accept a slightly
         // more complex coord.
         if (!fIsDegenerate) {

             // ac4 = 4.0 * params[0] * c
             builder->fsCodeAppendf("\tfloat %s = %s * 4.0 * %s;\n",
                                    ac4Name.c_str(), p0.c_str(),
                                    cName.c_str());

             // root = sqrt(b^2-4ac)
             // (abs to avoid exception due to fp precision)
             builder->fsCodeAppendf("\tfloat %s = sqrt(abs(%s*%s - %s));\n",
                                    rootName.c_str(), bVar.c_str(), bVar.c_str(),
                                    ac4Name.c_str());

             // t is: (-b + params[5] * sqrt(b^2-4ac)) * params[1]
             t.printf("(-%s + %s * %s) * %s", bVar.c_str(), p5.c_str(),
                      rootName.c_str(), p1.c_str());
         } else {
             // t is: -c/b
             t.printf("-%s / %s", cName.c_str(), bVar.c_str());
         }

         this->emitColor(builder, t.c_str(), key, outputColor, inputColor, samplers);
     }
 }

 void GrGLRadial2Gradient::setData(const GrGLUniformManager& uman,
                                   const GrDrawEffect& drawEffect) {
     INHERITED::setData(uman, drawEffect);
     const GrRadial2Gradient& data = drawEffect.castEffect<GrRadial2Gradient>();
     SkASSERT(data.isDegenerate() == fIsDegenerate);
     SkScalar centerX1 = data.center();
     SkScalar radius0 = data.radius();
     if (fCachedCenter != centerX1 ||
         fCachedRadius != radius0 ||
         fCachedPosRoot != data.isPosRoot()) {

         SkScalar a = SkScalarMul(centerX1, centerX1) - SK_Scalar1;

         // When we're in the degenerate (linear) case, the second
         // value will be INF but the program doesn't read it. (We
         // use the same 6 uniforms even though we don't need them
         // all in the linear case just to keep the code complexity
         // down).
         float values[6] = {
             SkScalarToFloat(a),
             1 / (2.f * SkScalarToFloat(a)),
             SkScalarToFloat(centerX1),
             SkScalarToFloat(radius0),
             SkScalarToFloat(SkScalarMul(radius0, radius0)),
             data.isPosRoot() ? 1.f : -1.f
         };

         uman.set1fv(fVSParamUni, 0, 6, values);
         uman.set1fv(fFSParamUni, 0, 6, values);
         fCachedCenter = centerX1;
         fCachedRadius = radius0;
         fCachedPosRoot = data.isPosRoot();
     }
 }

 GrGLEffect::EffectKey GrGLRadial2Gradient::GenKey(const GrDrawEffect& drawEffect,
                                                   const GrGLCaps&) {
     enum {
         kIsDegenerate = 1 << kBaseKeyBitCnt,
     };

     EffectKey key = GenBaseGradientKey(drawEffect);
     if (drawEffect.castEffect<GrRadial2Gradient>().isDegenerate()) {
         key |= kIsDegenerate;
     }
     return key;
 }

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

 GrEffectRef* SkTwoPointRadialGradient::asNewEffect(GrContext* context, const SkPaint&) const {
     SkASSERT(NULL != context);
     // invert the localM, translate to center1 (fPtsToUni), rotate so center2 is on x axis.
     SkMatrix matrix;
     if (!this->getLocalMatrix().invert(&matrix)) {
         return NULL;
     }
     matrix.postConcat(fPtsToUnit);

     SkScalar diffLen = fDiff.length();
     if (0 != diffLen) {
         SkScalar invDiffLen = SkScalarInvert(diffLen);
         SkMatrix rot;
         rot.setSinCos(-SkScalarMul(invDiffLen, fDiff.fY),
                        SkScalarMul(invDiffLen, fDiff.fX));
         matrix.postConcat(rot);
     }

     return GrRadial2Gradient::Create(context, *this, matrix, fTileMode);
 }

 #else

 GrEffectRef* SkTwoPointRadialGradient::asNewEffect(GrContext*, const SkPaint&) const {
     SkDEBUGFAIL("Should not call in GPU-less build");
     return NULL;
 }

 #endif

	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkTwoPointRadialGradient.h"

	/* Two-point radial gradients are specified by two circles, each with a center
	point and radius. The gradient can be considered to be a series of
	concentric circles, with the color interpolated from the start circle
	(at t=0) to the end circle (at t=1).

	For each point (x, y) in the span, we want to find the
	interpolated circle that intersects that point. The center
	of the desired circle (Cx, Cy) falls at some distance t
	along the line segment between the start point (Sx, Sy) and
	end point (Ex, Ey):

	Cx = (1 - t) * Sx + t * Ex (0 <= t <= 1)
	Cy = (1 - t) * Sy + t * Ey

	The radius of the desired circle (r) is also a linear interpolation t
	between the start and end radii (Sr and Er):

	r = (1 - t) * Sr + t * Er

	But

	(x - Cx)^2 + (y - Cy)^2 = r^2

	so

	(x - ((1 - t) * Sx + t * Ex))^2
	+ (y - ((1 - t) * Sy + t * Ey))^2
	= ((1 - t) * Sr + t * Er)^2

	Solving for t yields

	[(Sx - Ex)^2 + (Sy - Ey)^2 - (Er - Sr)^2)] * t^2
	+ [2 * (Sx - Ex)(x - Sx) + 2 * (Sy - Ey)(y - Sy) - 2 * (Er - Sr) * Sr] * t
	+ [(x - Sx)^2 + (y - Sy)^2 - Sr^2] = 0

	To simplify, let Dx = Sx - Ex, Dy = Sy - Ey, Dr = Er - Sr, dx = x - Sx, dy = y - Sy

	[Dx^2 + Dy^2 - Dr^2)] * t^2
	+ 2 * [Dx * dx + Dy * dy - Dr * Sr] * t
	+ [dx^2 + dy^2 - Sr^2] = 0

	A quadratic in t. The two roots of the quadratic reflect the two
	possible circles on which the point may fall. Solving for t yields
	the gradient value to use.

	If a<0, the start circle is entirely contained in the
	end circle, and one of the roots will be <0 or >1 (off the line
	segment). If a>0, the start circle falls at least partially
	outside the end circle (or vice versa), and the gradient
	defines a "tube" where a point may be on one circle (on the
	inside of the tube) or the other (outside of the tube). We choose
	one arbitrarily.

	In order to keep the math to within the limits of fixed point,
	we divide the entire quadratic by Dr^2, and replace
	(x - Sx)/Dr with x' and (y - Sy)/Dr with y', giving

	[Dx^2 / Dr^2 + Dy^2 / Dr^2 - 1)] * t^2
	+ 2 * [x' * Dx / Dr + y' * Dy / Dr - Sr / Dr] * t
	+ [x'^2 + y'^2 - Sr^2/Dr^2] = 0

	(x' and y' are computed by appending the subtract and scale to the
	fDstToIndex matrix in the constructor).

	Since the 'A' component of the quadratic is independent of x' and y', it
	is precomputed in the constructor. Since the 'B' component is linear in
	x' and y', if x and y are linear in the span, 'B' can be computed
	incrementally with a simple delta (db below). If it is not (e.g.,
	a perspective projection), it must be computed in the loop.

	*/

	namespace {

	inline SkFixed two_point_radial(SkScalar b, SkScalar fx, SkScalar fy,
	SkScalar sr2d2, SkScalar foura,
	SkScalar oneOverTwoA, bool posRoot) {
	SkScalar c = SkScalarSquare(fx) + SkScalarSquare(fy) - sr2d2;
	if (0 == foura) {
	return SkScalarToFixed(SkScalarDiv(-c, b));
	}

	SkScalar discrim = SkScalarSquare(b) - SkScalarMul(foura, c);
	if (discrim < 0) {
	discrim = -discrim;
	}
	SkScalar rootDiscrim = SkScalarSqrt(discrim);
	SkScalar result;
	if (posRoot) {
	result = SkScalarMul(-b + rootDiscrim, oneOverTwoA);
	} else {
	result = SkScalarMul(-b - rootDiscrim, oneOverTwoA);
	}
	return SkScalarToFixed(result);
	}

	typedef void (* TwoPointRadialShadeProc)(SkScalar fx, SkScalar dx,
	SkScalar fy, SkScalar dy,
	SkScalar b, SkScalar db,
	SkScalar fSr2D2, SkScalar foura, SkScalar fOneOverTwoA, bool posRoot,
	SkPMColor* SK_RESTRICT dstC, const SkPMColor* SK_RESTRICT cache,
	int count);

	void shadeSpan_twopoint_clamp(SkScalar fx, SkScalar dx,
	SkScalar fy, SkScalar dy,
	SkScalar b, SkScalar db,
	SkScalar fSr2D2, SkScalar foura, SkScalar fOneOverTwoA, bool posRoot,
	SkPMColor* SK_RESTRICT dstC, const SkPMColor* SK_RESTRICT cache,
	int count) {
	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 >> SkGradientShaderBase::kCache32Shift];
	fx += dx;
	fy += dy;
	b += db;
	}
	}
	void shadeSpan_twopoint_mirror(SkScalar fx, SkScalar dx,
	SkScalar fy, SkScalar dy,
	SkScalar b, SkScalar db,
	SkScalar fSr2D2, SkScalar foura, SkScalar fOneOverTwoA, bool posRoot,
	SkPMColor* SK_RESTRICT dstC, const SkPMColor* SK_RESTRICT cache,
	int count) {
	for (; count > 0; --count) {
	SkFixed t = two_point_radial(b, fx, fy, fSr2D2, foura,
	fOneOverTwoA, posRoot);
	SkFixed index = mirror_tileproc(t);
	SkASSERT(index <= 0xFFFF);
	*dstC++ = cache[index >> SkGradientShaderBase::kCache32Shift];
	fx += dx;
	fy += dy;
	b += db;
	}
	}

	void shadeSpan_twopoint_repeat(SkScalar fx, SkScalar dx,
	SkScalar fy, SkScalar dy,
	SkScalar b, SkScalar db,
	SkScalar fSr2D2, SkScalar foura, SkScalar fOneOverTwoA, bool posRoot,
	SkPMColor* SK_RESTRICT dstC, const SkPMColor* SK_RESTRICT cache,
	int count) {
	for (; count > 0; --count) {
	SkFixed t = two_point_radial(b, fx, fy, fSr2D2, foura,
	fOneOverTwoA, posRoot);
	SkFixed index = repeat_tileproc(t);
	SkASSERT(index <= 0xFFFF);
	*dstC++ = cache[index >> SkGradientShaderBase::kCache32Shift];
	fx += dx;
	fy += dy;
	b += db;
	}
	}
	}

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

	SkTwoPointRadialGradient::SkTwoPointRadialGradient(
	const SkPoint& start, SkScalar startRadius,
	const SkPoint& end, SkScalar endRadius,
	const Descriptor& desc)
	: SkGradientShaderBase(desc),
	fCenter1(start),
	fCenter2(end),
	fRadius1(startRadius),
	fRadius2(endRadius) {
	init();
	}

	SkShader::BitmapType SkTwoPointRadialGradient::asABitmap(
	SkBitmap* bitmap,
	SkMatrix* matrix,
	SkShader::TileMode* xy) const {
	if (bitmap) {
	this->getGradientTableBitmap(bitmap);
	}
	SkScalar diffL = 0; // just to avoid gcc warning
	if (matrix) {
	diffL = SkScalarSqrt(SkScalarSquare(fDiff.fX) +
	SkScalarSquare(fDiff.fY));
	}
	if (matrix) {
	if (diffL) {
	SkScalar invDiffL = SkScalarInvert(diffL);
	matrix->setSinCos(-SkScalarMul(invDiffL, fDiff.fY),
	SkScalarMul(invDiffL, fDiff.fX));
	} else {
	matrix->reset();
	}
	matrix->preConcat(fPtsToUnit);
	}
	if (xy) {
	xy[0] = fTileMode;
	xy[1] = kClamp_TileMode;
	}
	return kTwoPointRadial_BitmapType;
	}

	SkShader::GradientType SkTwoPointRadialGradient::asAGradient(
	SkShader::GradientInfo* info) const {
	if (info) {
	commonAsAGradient(info);
	info->fPoint[0] = fCenter1;
	info->fPoint[1] = fCenter2;
	info->fRadius[0] = fRadius1;
	info->fRadius[1] = fRadius2;
	}
	return kRadial2_GradientType;
	}

	void SkTwoPointRadialGradient::shadeSpan(int x, int y, SkPMColor* dstCParam,
	int count) {
	SkASSERT(count > 0);

	SkPMColor* SK_RESTRICT dstC = dstCParam;

	// Zero difference between radii: fill with transparent black.
	if (fDiffRadius == 0) {
	sk_bzero(dstC, count * sizeof(*dstC));
	return;
	}
	SkMatrix::MapXYProc dstProc = fDstToIndexProc;
	TileProc proc = fTileProc;
	const SkPMColor* SK_RESTRICT cache = this->getCache32();

	SkScalar foura = fA * 4;
	bool posRoot = fDiffRadius < 0;
	if (fDstToIndexClass != kPerspective_MatrixClass) {
	SkPoint srcPt;
	dstProc(fDstToIndex, SkIntToScalar(x) + SK_ScalarHalf,
	SkIntToScalar(y) + SK_ScalarHalf, &srcPt);
	SkScalar dx, fx = srcPt.fX;
	SkScalar dy, fy = srcPt.fY;

	if (fDstToIndexClass == kFixedStepInX_MatrixClass) {
	SkFixed fixedX, fixedY;
	(void)fDstToIndex.fixedStepInX(SkIntToScalar(y), &fixedX, &fixedY);
	dx = SkFixedToScalar(fixedX);
	dy = SkFixedToScalar(fixedY);
	} else {
	SkASSERT(fDstToIndexClass == kLinear_MatrixClass);
	dx = fDstToIndex.getScaleX();
	dy = fDstToIndex.getSkewY();
	}
	SkScalar b = (SkScalarMul(fDiff.fX, fx) +
	SkScalarMul(fDiff.fY, fy) - fStartRadius) * 2;
	SkScalar db = (SkScalarMul(fDiff.fX, dx) +
	SkScalarMul(fDiff.fY, dy)) * 2;

	TwoPointRadialShadeProc shadeProc = shadeSpan_twopoint_repeat;
	if (SkShader::kClamp_TileMode == fTileMode) {
	shadeProc = shadeSpan_twopoint_clamp;
	} else if (SkShader::kMirror_TileMode == fTileMode) {
	shadeProc = shadeSpan_twopoint_mirror;
	} else {
	SkASSERT(SkShader::kRepeat_TileMode == fTileMode);
	}
	(*shadeProc)(fx, dx, fy, dy, b, db,
	fSr2D2, foura, fOneOverTwoA, posRoot,
	dstC, cache, count);
	} else { // perspective case
	SkScalar dstX = SkIntToScalar(x);
	SkScalar dstY = SkIntToScalar(y);
	for (; count > 0; --count) {
	SkPoint srcPt;
	dstProc(fDstToIndex, dstX, dstY, &srcPt);
	SkScalar fx = srcPt.fX;
	SkScalar fy = srcPt.fY;
	SkScalar b = (SkScalarMul(fDiff.fX, fx) +
	SkScalarMul(fDiff.fY, fy) - fStartRadius) * 2;
	SkFixed t = two_point_radial(b, fx, fy, fSr2D2, foura,
	fOneOverTwoA, posRoot);
	SkFixed index = proc(t);
	SkASSERT(index <= 0xFFFF);
	*dstC++ = cache[index >> SkGradientShaderBase::kCache32Shift];
	dstX += SK_Scalar1;
	}
	}
	}

	bool SkTwoPointRadialGradient::setContext( const SkBitmap& device,
	const SkPaint& paint,
	const SkMatrix& matrix){
	// For now, we might have divided by zero, so detect that
	if (0 == fDiffRadius) {
	return false;
	}

	if (!this->INHERITED::setContext(device, paint, matrix)) {
	return false;
	}

	// we don't have a span16 proc
	fFlags &= ~kHasSpan16_Flag;
	return true;
	}

	#ifdef SK_DEVELOPER
	void SkTwoPointRadialGradient::toString(SkString* str) const {
	str->append("SkTwoPointRadialGradient: (");

	str->append("center1: (");
	str->appendScalar(fCenter1.fX);
	str->append(", ");
	str->appendScalar(fCenter1.fY);
	str->append(") radius1: ");
	str->appendScalar(fRadius1);
	str->append(" ");

	str->append("center2: (");
	str->appendScalar(fCenter2.fX);
	str->append(", ");
	str->appendScalar(fCenter2.fY);
	str->append(") radius2: ");
	str->appendScalar(fRadius2);
	str->append(" ");

	this->INHERITED::toString(str);

	str->append(")");
	}
	#endif

	SkTwoPointRadialGradient::SkTwoPointRadialGradient(
	SkFlattenableReadBuffer& buffer)
	: INHERITED(buffer),
	fCenter1(buffer.readPoint()),
	fCenter2(buffer.readPoint()),
	fRadius1(buffer.readScalar()),
	fRadius2(buffer.readScalar()) {
	init();
	};

	void SkTwoPointRadialGradient::flatten(
	SkFlattenableWriteBuffer& buffer) const {
	this->INHERITED::flatten(buffer);
	buffer.writePoint(fCenter1);
	buffer.writePoint(fCenter2);
	buffer.writeScalar(fRadius1);
	buffer.writeScalar(fRadius2);
	}

	void SkTwoPointRadialGradient::init() {
	fDiff = fCenter1 - fCenter2;
	fDiffRadius = fRadius2 - fRadius1;
	// hack to avoid zero-divide for now
	SkScalar inv = fDiffRadius ? SkScalarInvert(fDiffRadius) : 0;
	fDiff.fX = SkScalarMul(fDiff.fX, inv);
	fDiff.fY = SkScalarMul(fDiff.fY, inv);
	fStartRadius = SkScalarMul(fRadius1, inv);
	fSr2D2 = SkScalarSquare(fStartRadius);
	fA = SkScalarSquare(fDiff.fX) + SkScalarSquare(fDiff.fY) - SK_Scalar1;
	fOneOverTwoA = fA ? SkScalarInvert(fA * 2) : 0;

	fPtsToUnit.setTranslate(-fCenter1.fX, -fCenter1.fY);
	fPtsToUnit.postScale(inv, inv);
	}

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

	#if SK_SUPPORT_GPU

	#include "GrTBackendEffectFactory.h"

	// For brevity
	typedef GrGLUniformManager::UniformHandle UniformHandle;

	class GrGLRadial2Gradient : public GrGLGradientEffect {

	public:

	GrGLRadial2Gradient(const GrBackendEffectFactory& factory, const GrDrawEffect&);
	virtual ~GrGLRadial2Gradient() { }

	virtual void emitCode(GrGLShaderBuilder*,
	const GrDrawEffect&,
	EffectKey,
	const char* outputColor,
	const char* inputColor,
	const TransformedCoordsArray&,
	const TextureSamplerArray&) SK_OVERRIDE;
	virtual void setData(const GrGLUniformManager&, const GrDrawEffect&) SK_OVERRIDE;

	static EffectKey GenKey(const GrDrawEffect&, const GrGLCaps& caps);

	protected:

	UniformHandle fVSParamUni;
	UniformHandle fFSParamUni;

	const char* fVSVaryingName;
	const char* fFSVaryingName;

	bool fIsDegenerate;

	// @{
	/// Values last uploaded as uniforms

	SkScalar fCachedCenter;
	SkScalar fCachedRadius;
	bool fCachedPosRoot;

	// @}

	private:

	typedef GrGLGradientEffect INHERITED;

	};

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

	class GrRadial2Gradient : public GrGradientEffect {
	public:
	static GrEffectRef* Create(GrContext* ctx,
	const SkTwoPointRadialGradient& shader,
	const SkMatrix& matrix,
	SkShader::TileMode tm) {
	AutoEffectUnref effect(SkNEW_ARGS(GrRadial2Gradient, (ctx, shader, matrix, tm)));
	return CreateEffectRef(effect);
	}

	virtual ~GrRadial2Gradient() { }

	static const char* Name() { return "Two-Point Radial Gradient"; }
	virtual const GrBackendEffectFactory& getFactory() const SK_OVERRIDE {
	return GrTBackendEffectFactory<GrRadial2Gradient>::getInstance();
	}

	// The radial gradient parameters can collapse to a linear (instead of quadratic) equation.
	bool isDegenerate() const { return SK_Scalar1 == fCenterX1; }
	SkScalar center() const { return fCenterX1; }
	SkScalar radius() const { return fRadius0; }
	bool isPosRoot() const { return SkToBool(fPosRoot); }

	typedef GrGLRadial2Gradient GLEffect;

	private:
	virtual bool onIsEqual(const GrEffect& sBase) const SK_OVERRIDE {
	const GrRadial2Gradient& s = CastEffect<GrRadial2Gradient>(sBase);
	return (INHERITED::onIsEqual(sBase) &&
	this->fCenterX1 == s.fCenterX1 &&
	this->fRadius0 == s.fRadius0 &&
	this->fPosRoot == s.fPosRoot);
	}

	GrRadial2Gradient(GrContext* ctx,
	const SkTwoPointRadialGradient& shader,
	const SkMatrix& matrix,
	SkShader::TileMode tm)
	: INHERITED(ctx, shader, matrix, tm)
	, fCenterX1(shader.getCenterX1())
	, fRadius0(shader.getStartRadius())
	, fPosRoot(shader.getDiffRadius() < 0) { }

	GR_DECLARE_EFFECT_TEST;

	// @{
	// Cache of values - these can change arbitrarily, EXCEPT
	// we shouldn't change between degenerate and non-degenerate?!

	SkScalar fCenterX1;
	SkScalar fRadius0;
	SkBool8 fPosRoot;

	// @}

	typedef GrGradientEffect INHERITED;
	};

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

	GR_DEFINE_EFFECT_TEST(GrRadial2Gradient);

	GrEffectRef* GrRadial2Gradient::TestCreate(SkRandom* random,
	GrContext* context,
	const GrDrawTargetCaps&,
	GrTexture**) {
	SkPoint center1 = {random->nextUScalar1(), random->nextUScalar1()};
	SkScalar radius1 = random->nextUScalar1();
	SkPoint center2;
	SkScalar radius2;
	do {
	center2.set(random->nextUScalar1(), random->nextUScalar1());
	radius2 = random->nextUScalar1 ();
	// There is a bug in two point radial gradients with identical radii
	} while (radius1 == radius2);

	SkColor colors[kMaxRandomGradientColors];
	SkScalar stopsArray[kMaxRandomGradientColors];
	SkScalar* stops = stopsArray;
	SkShader::TileMode tm;
	int colorCount = RandomGradientParams(random, colors, &stops, &tm);
	SkAutoTUnref<SkShader> shader(SkGradientShader::CreateTwoPointRadial(center1, radius1,
	center2, radius2,
	colors, stops, colorCount,
	tm));
	SkPaint paint;
	return shader->asNewEffect(context, paint);
	}

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

	GrGLRadial2Gradient::GrGLRadial2Gradient(const GrBackendEffectFactory& factory,
	const GrDrawEffect& drawEffect)
	: INHERITED(factory)
	, fVSVaryingName(NULL)
	, fFSVaryingName(NULL)
	, fCachedCenter(SK_ScalarMax)
	, fCachedRadius(-SK_ScalarMax)
	, fCachedPosRoot(0) {

	const GrRadial2Gradient& data = drawEffect.castEffect<GrRadial2Gradient>();
	fIsDegenerate = data.isDegenerate();
	}

	void GrGLRadial2Gradient::emitCode(GrGLShaderBuilder* builder,
	const GrDrawEffect& drawEffect,
	EffectKey key,
	const char* outputColor,
	const char* inputColor,
	const TransformedCoordsArray& coords,
	const TextureSamplerArray& samplers) {

	this->emitUniforms(builder, key);
	// 2 copies of uniform array, 1 for each of vertex & fragment shader,
	// to work around Xoom bug. Doesn't seem to cause performance decrease
	// in test apps, but need to keep an eye on it.
	fVSParamUni = builder->addUniformArray(GrGLShaderBuilder::kVertex_Visibility,
	kFloat_GrSLType, "Radial2VSParams", 6);
	fFSParamUni = builder->addUniformArray(GrGLShaderBuilder::kFragment_Visibility,
	kFloat_GrSLType, "Radial2FSParams", 6);

	// For radial gradients without perspective we can pass the linear
	// part of the quadratic as a varying.
	GrGLShaderBuilder::VertexBuilder* vertexBuilder =
	(kVec2f_GrSLType == coords[0].type()) ? builder->getVertexBuilder() : NULL;
	if (NULL != vertexBuilder) {
	vertexBuilder->addVarying(kFloat_GrSLType, "Radial2BCoeff",
	&fVSVaryingName, &fFSVaryingName);
	}

	// VS
	{
	SkString p2;
	SkString p3;
	builder->getUniformVariable(fVSParamUni).appendArrayAccess(2, &p2);
	builder->getUniformVariable(fVSParamUni).appendArrayAccess(3, &p3);

	// For radial gradients without perspective we can pass the linear
	// part of the quadratic as a varying.
	if (NULL != vertexBuilder) {
	// r2Var = 2 * (r2Parm[2] * varCoord.x - r2Param[3])
	vertexBuilder->vsCodeAppendf("\t%s = 2.0 (%s %s.x - %s);\n",
	fVSVaryingName, p2.c_str(),
	coords[0].getVSName().c_str(), p3.c_str());
	}
	}

	// FS
	{
	SkString coords2D = builder->ensureFSCoords2D(coords, 0);
	SkString cName("c");
	SkString ac4Name("ac4");
	SkString rootName("root");
	SkString t;
	SkString p0;
	SkString p1;
	SkString p2;
	SkString p3;
	SkString p4;
	SkString p5;
	builder->getUniformVariable(fFSParamUni).appendArrayAccess(0, &p0);
	builder->getUniformVariable(fFSParamUni).appendArrayAccess(1, &p1);
	builder->getUniformVariable(fFSParamUni).appendArrayAccess(2, &p2);
	builder->getUniformVariable(fFSParamUni).appendArrayAccess(3, &p3);
	builder->getUniformVariable(fFSParamUni).appendArrayAccess(4, &p4);
	builder->getUniformVariable(fFSParamUni).appendArrayAccess(5, &p5);

	// If we we're able to interpolate the linear component,
	// bVar is the varying; otherwise compute it
	SkString bVar;
	if (NULL != vertexBuilder) {
	bVar = fFSVaryingName;
	} else {
	bVar = "b";
	builder->fsCodeAppendf("\tfloat %s = 2.0 * (%s * %s.x - %s);\n",
	bVar.c_str(), p2.c_str(), coords2D.c_str(), p3.c_str());
	}

	// c = (x^2)+(y^2) - params[4]
	builder->fsCodeAppendf("\tfloat %s = dot(%s, %s) - %s;\n",
	cName.c_str(),
	coords2D.c_str(),
	coords2D.c_str(),
	p4.c_str());

	// If we aren't degenerate, emit some extra code, and accept a slightly
	// more complex coord.
	if (!fIsDegenerate) {

	// ac4 = 4.0 * params[0] * c
	builder->fsCodeAppendf("\tfloat %s = %s * 4.0 * %s;\n",
	ac4Name.c_str(), p0.c_str(),
	cName.c_str());

	// root = sqrt(b^2-4ac)
	// (abs to avoid exception due to fp precision)
	builder->fsCodeAppendf("\tfloat %s = sqrt(abs(%s*%s - %s));\n",
	rootName.c_str(), bVar.c_str(), bVar.c_str(),
	ac4Name.c_str());

	// t is: (-b + params[5] * sqrt(b^2-4ac)) * params[1]
	t.printf("(-%s + %s * %s) * %s", bVar.c_str(), p5.c_str(),
	rootName.c_str(), p1.c_str());
	} else {
	// t is: -c/b
	t.printf("-%s / %s", cName.c_str(), bVar.c_str());
	}

	this->emitColor(builder, t.c_str(), key, outputColor, inputColor, samplers);
	}
	}

	void GrGLRadial2Gradient::setData(const GrGLUniformManager& uman,
	const GrDrawEffect& drawEffect) {
	INHERITED::setData(uman, drawEffect);
	const GrRadial2Gradient& data = drawEffect.castEffect<GrRadial2Gradient>();
	SkASSERT(data.isDegenerate() == fIsDegenerate);
	SkScalar centerX1 = data.center();
	SkScalar radius0 = data.radius();
	if (fCachedCenter != centerX1 \|\|
	fCachedRadius != radius0 \|\|
	fCachedPosRoot != data.isPosRoot()) {

	SkScalar a = SkScalarMul(centerX1, centerX1) - SK_Scalar1;

	// When we're in the degenerate (linear) case, the second
	// value will be INF but the program doesn't read it. (We
	// use the same 6 uniforms even though we don't need them
	// all in the linear case just to keep the code complexity
	// down).
	float values[6] = {
	SkScalarToFloat(a),
	1 / (2.f * SkScalarToFloat(a)),
	SkScalarToFloat(centerX1),
	SkScalarToFloat(radius0),
	SkScalarToFloat(SkScalarMul(radius0, radius0)),
	data.isPosRoot() ? 1.f : -1.f
	};

	uman.set1fv(fVSParamUni, 0, 6, values);
	uman.set1fv(fFSParamUni, 0, 6, values);
	fCachedCenter = centerX1;
	fCachedRadius = radius0;
	fCachedPosRoot = data.isPosRoot();
	}
	}

	GrGLEffect::EffectKey GrGLRadial2Gradient::GenKey(const GrDrawEffect& drawEffect,
	const GrGLCaps&) {
	enum {
	kIsDegenerate = 1 << kBaseKeyBitCnt,
	};

	EffectKey key = GenBaseGradientKey(drawEffect);
	if (drawEffect.castEffect<GrRadial2Gradient>().isDegenerate()) {
	key \|= kIsDegenerate;
	}
	return key;
	}

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

	GrEffectRef* SkTwoPointRadialGradient::asNewEffect(GrContext* context, const SkPaint&) const {
	SkASSERT(NULL != context);
	// invert the localM, translate to center1 (fPtsToUni), rotate so center2 is on x axis.
	SkMatrix matrix;
	if (!this->getLocalMatrix().invert(&matrix)) {
	return NULL;
	}
	matrix.postConcat(fPtsToUnit);

	SkScalar diffLen = fDiff.length();
	if (0 != diffLen) {
	SkScalar invDiffLen = SkScalarInvert(diffLen);
	SkMatrix rot;
	rot.setSinCos(-SkScalarMul(invDiffLen, fDiff.fY),
	SkScalarMul(invDiffLen, fDiff.fX));
	matrix.postConcat(rot);
	}

	return GrRadial2Gradient::Create(context, *this, matrix, fTileMode);
	}

	#else

	GrEffectRef* SkTwoPointRadialGradient::asNewEffect(GrContext*, const SkPaint&) const {
	SkDEBUGFAIL("Should not call in GPU-less build");
	return NULL;
	}

	#endif