src/gpu/GrQuad.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "GrQuad.h"

 #include "GrTypesPriv.h"

 ///////////////////////////////////////////////////////////////////////////////////////////////////
 // Functions for identifying the quad type from its coordinates, which are kept debug-only since
 // production code should rely on the matrix to derive the quad type more efficiently. These are
 // useful in asserts that the quad type is as expected.
 ///////////////////////////////////////////////////////////////////////////////////////////////////

 #ifdef SK_DEBUG
 // Allow some tolerance from floating point matrix transformations, but SkScalarNearlyEqual doesn't
 // support comparing infinity, and coords_form_rect should return true for infinite edges
 #define NEARLY_EQUAL(f1, f2) (f1 == f2 || SkScalarNearlyEqual(f1, f2, 1e-5f))
 // Similarly, support infinite rectangles by looking at the sign of infinities
 static bool dot_nearly_zero(const SkVector& e1, const SkVector& e2) {
     static constexpr auto dot = SkPoint::DotProduct;
     static constexpr auto sign = SkScalarSignAsScalar;

     SkScalar dotValue = dot(e1, e2);
     if (SkScalarIsNaN(dotValue)) {
         // Form vectors from the signs of infinities, and check their dot product
         dotValue = dot({sign(e1.fX), sign(e1.fY)}, {sign(e2.fX), sign(e2.fY)});
     }

     // Unfortunately must have a pretty healthy tolerance here or transformed rects that are
     // effectively rectilinear will have edge dot products of around .005
     return SkScalarNearlyZero(dotValue, 1e-2f);
 }

 // This is not the most performance critical function; code using GrQuad should rely on the faster
 // quad type from matrix path, so this will only be called as part of SkASSERT.
 static bool coords_form_rect(const float xs[4], const float ys[4]) {
     return (NEARLY_EQUAL(xs[0], xs[1]) && NEARLY_EQUAL(xs[2], xs[3]) &&
             NEARLY_EQUAL(ys[0], ys[2]) && NEARLY_EQUAL(ys[1], ys[3])) ||
            (NEARLY_EQUAL(xs[0], xs[2]) && NEARLY_EQUAL(xs[1], xs[3]) &&
             NEARLY_EQUAL(ys[0], ys[1]) && NEARLY_EQUAL(ys[2], ys[3]));
 }

 static bool coords_rectilinear(const float xs[4], const float ys[4]) {
     SkVector e0{xs[1] - xs[0], ys[1] - ys[0]}; // Connects to e1 and e2(repeat)
     SkVector e1{xs[3] - xs[1], ys[3] - ys[1]}; // connects to e0(repeat) and e3
     SkVector e2{xs[0] - xs[2], ys[0] - ys[2]}; // connects to e0 and e3(repeat)
     SkVector e3{xs[2] - xs[3], ys[2] - ys[3]}; // connects to e1(repeat) and e2

     return dot_nearly_zero(e0, e1) && dot_nearly_zero(e1, e3) &&
            dot_nearly_zero(e2, e0) && dot_nearly_zero(e3, e2);
 }

 GrQuadType GrQuad::quadType() const {
     // Since GrQuad applies any perspective information at construction time, there's only two
     // types to choose from.
     if (coords_form_rect(fX, fY)) {
         return GrQuadType::kRect;
     } else if (coords_rectilinear(fX, fY)) {
         return GrQuadType::kRectilinear;
     } else {
         return GrQuadType::kStandard;
     }
 }

 GrQuadType GrPerspQuad::quadType() const {
     if (this->hasPerspective()) {
         return GrQuadType::kPerspective;
     } else {
         // Rect or standard quad, can ignore w since they are all ones
         if (coords_form_rect(fX, fY)) {
             return GrQuadType::kRect;
         } else if (coords_rectilinear(fX, fY)) {
             return GrQuadType::kRectilinear;
         } else {
             return GrQuadType::kStandard;
         }
     }
 }
 #endif

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

 static bool aa_affects_rect(float ql, float qt, float qr, float qb) {
     return !SkScalarIsInt(ql) || !SkScalarIsInt(qr) || !SkScalarIsInt(qt) || !SkScalarIsInt(qb);
 }

 template <typename Q>
 void GrResolveAATypeForQuad(GrAAType requestedAAType, GrQuadAAFlags requestedEdgeFlags,
                             const Q& quad, GrQuadType knownType,
                             GrAAType* outAAType, GrQuadAAFlags* outEdgeFlags) {
     // Most cases will keep the requested types unchanged
     *outAAType = requestedAAType;
     *outEdgeFlags = requestedEdgeFlags;

     switch (requestedAAType) {
         // When aa type is coverage, disable AA if the edge configuration doesn't actually need it
         case GrAAType::kCoverage:
             if (requestedEdgeFlags == GrQuadAAFlags::kNone) {
                 // Turn off anti-aliasing
                 *outAAType = GrAAType::kNone;
             } else {
                 // For coverage AA, if the quad is a rect and it lines up with pixel boundaries
                 // then overall aa and per-edge aa can be completely disabled
                 if (knownType == GrQuadType::kRect && !quad.aaHasEffectOnRect()) {
                     *outAAType = GrAAType::kNone;
                     *outEdgeFlags = GrQuadAAFlags::kNone;
                 }
             }
             break;
         // For no or msaa anti aliasing, override the edge flags since edge flags only make sense
         // when coverage aa is being used.
         case GrAAType::kNone:
             *outEdgeFlags = GrQuadAAFlags::kNone;
             break;
         case GrAAType::kMSAA:
             *outEdgeFlags = GrQuadAAFlags::kAll;
             break;
         case GrAAType::kMixedSamples:
             SK_ABORT("Should not use mixed sample AA with edge AA flags");
             break;
     }
 };

 // Instantiate GrResolve... for GrQuad and GrPerspQuad
 template void GrResolveAATypeForQuad(GrAAType, GrQuadAAFlags, const GrQuad&, GrQuadType,
                                      GrAAType*, GrQuadAAFlags*);
 template void GrResolveAATypeForQuad(GrAAType, GrQuadAAFlags, const GrPerspQuad&, GrQuadType,
                                      GrAAType*, GrQuadAAFlags*);

 GrQuadType GrQuadTypeForTransformedRect(const SkMatrix& matrix) {
     if (matrix.rectStaysRect()) {
         return GrQuadType::kRect;
     } else if (matrix.preservesRightAngles()) {
         return GrQuadType::kRectilinear;
     } else if (matrix.hasPerspective()) {
         return GrQuadType::kPerspective;
     } else {
         return GrQuadType::kStandard;
     }
 }

 GrQuad::GrQuad(const SkRect& rect, const SkMatrix& m) {
     SkMatrix::TypeMask tm = m.getType();
     if (tm <= (SkMatrix::kScale_Mask | SkMatrix::kTranslate_Mask)) {
         auto r = Sk4f::Load(&rect);
         const Sk4f t(m.getTranslateX(), m.getTranslateY(), m.getTranslateX(), m.getTranslateY());
         if (tm <= SkMatrix::kTranslate_Mask) {
             r += t;
         } else {
             const Sk4f s(m.getScaleX(), m.getScaleY(), m.getScaleX(), m.getScaleY());
             r = r * s + t;
         }
         SkNx_shuffle<0, 0, 2, 2>(r).store(fX);
         SkNx_shuffle<1, 3, 1, 3>(r).store(fY);
     } else {
         Sk4f rx(rect.fLeft, rect.fLeft, rect.fRight, rect.fRight);
         Sk4f ry(rect.fTop, rect.fBottom, rect.fTop, rect.fBottom);
         Sk4f sx(m.getScaleX());
         Sk4f kx(m.getSkewX());
         Sk4f tx(m.getTranslateX());
         Sk4f ky(m.getSkewY());
         Sk4f sy(m.getScaleY());
         Sk4f ty(m.getTranslateY());
         auto x = SkNx_fma(sx, rx, SkNx_fma(kx, ry, tx));
         auto y = SkNx_fma(ky, rx, SkNx_fma(sy, ry, ty));
         if (m.hasPerspective()) {
             Sk4f w0(m.getPerspX());
             Sk4f w1(m.getPerspY());
             Sk4f w2(m.get(SkMatrix::kMPersp2));
             auto iw = SkNx_fma(w0, rx, SkNx_fma(w1, ry, w2)).invert();
             x *= iw;
             y *= iw;
         }
         x.store(fX);
         y.store(fY);
     }
 }

 bool GrQuad::aaHasEffectOnRect() const {
     SkASSERT(this->quadType() == GrQuadType::kRect);
     return aa_affects_rect(fX[0], fY[0], fX[3], fY[3]);
 }

 GrPerspQuad::GrPerspQuad(const SkRect& rect, const SkMatrix& m) {
     SkMatrix::TypeMask tm = m.getType();
     if (tm <= (SkMatrix::kScale_Mask | SkMatrix::kTranslate_Mask)) {
         auto r = Sk4f::Load(&rect);
         const Sk4f t(m.getTranslateX(), m.getTranslateY(), m.getTranslateX(), m.getTranslateY());
         if (tm <= SkMatrix::kTranslate_Mask) {
             r += t;
         } else {
             const Sk4f s(m.getScaleX(), m.getScaleY(), m.getScaleX(), m.getScaleY());
             r = r * s + t;
         }
         SkNx_shuffle<0, 0, 2, 2>(r).store(fX);
         SkNx_shuffle<1, 3, 1, 3>(r).store(fY);
         fW[0] = fW[1] = fW[2] = fW[3] = 1.f;
         fIW[0] = fIW[1] = fIW[2] = fIW[3] = 1.f;
     } else {
         Sk4f rx(rect.fLeft, rect.fLeft, rect.fRight, rect.fRight);
         Sk4f ry(rect.fTop, rect.fBottom, rect.fTop, rect.fBottom);
         Sk4f sx(m.getScaleX());
         Sk4f kx(m.getSkewX());
         Sk4f tx(m.getTranslateX());
         Sk4f ky(m.getSkewY());
         Sk4f sy(m.getScaleY());
         Sk4f ty(m.getTranslateY());
         SkNx_fma(sx, rx, SkNx_fma(kx, ry, tx)).store(fX);
         SkNx_fma(ky, rx, SkNx_fma(sy, ry, ty)).store(fY);
         if (m.hasPerspective()) {
             Sk4f w0(m.getPerspX());
             Sk4f w1(m.getPerspY());
             Sk4f w2(m.get(SkMatrix::kMPersp2));
             auto w = SkNx_fma(w0, rx, SkNx_fma(w1, ry, w2));
             w.store(fW);
             w.invert().store(fIW);
         } else {
             fW[0] = fW[1] = fW[2] = fW[3] = 1.f;
             fIW[0] = fIW[1] = fIW[2] = fIW[3] = 1.f;
         }
     }
 }

 bool GrPerspQuad::aaHasEffectOnRect() const {
     SkASSERT(this->quadType() == GrQuadType::kRect);
     // If rect, ws must all be 1s so no need to divide
     return aa_affects_rect(fX[0], fY[0], fX[3], fY[3]);
 }
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "GrQuad.h"

	#include "GrTypesPriv.h"

	///////////////////////////////////////////////////////////////////////////////////////////////////
	// Functions for identifying the quad type from its coordinates, which are kept debug-only since
	// production code should rely on the matrix to derive the quad type more efficiently. These are
	// useful in asserts that the quad type is as expected.
	///////////////////////////////////////////////////////////////////////////////////////////////////

	#ifdef SK_DEBUG
	// Allow some tolerance from floating point matrix transformations, but SkScalarNearlyEqual doesn't
	// support comparing infinity, and coords_form_rect should return true for infinite edges
	#define NEARLY_EQUAL(f1, f2) (f1 == f2 \|\| SkScalarNearlyEqual(f1, f2, 1e-5f))
	// Similarly, support infinite rectangles by looking at the sign of infinities
	static bool dot_nearly_zero(const SkVector& e1, const SkVector& e2) {
	static constexpr auto dot = SkPoint::DotProduct;
	static constexpr auto sign = SkScalarSignAsScalar;

	SkScalar dotValue = dot(e1, e2);
	if (SkScalarIsNaN(dotValue)) {
	// Form vectors from the signs of infinities, and check their dot product
	dotValue = dot({sign(e1.fX), sign(e1.fY)}, {sign(e2.fX), sign(e2.fY)});
	}

	// Unfortunately must have a pretty healthy tolerance here or transformed rects that are
	// effectively rectilinear will have edge dot products of around .005
	return SkScalarNearlyZero(dotValue, 1e-2f);
	}

	// This is not the most performance critical function; code using GrQuad should rely on the faster
	// quad type from matrix path, so this will only be called as part of SkASSERT.
	static bool coords_form_rect(const float xs[4], const float ys[4]) {
	return (NEARLY_EQUAL(xs[0], xs[1]) && NEARLY_EQUAL(xs[2], xs[3]) &&
	NEARLY_EQUAL(ys[0], ys[2]) && NEARLY_EQUAL(ys[1], ys[3])) \|\|
	(NEARLY_EQUAL(xs[0], xs[2]) && NEARLY_EQUAL(xs[1], xs[3]) &&
	NEARLY_EQUAL(ys[0], ys[1]) && NEARLY_EQUAL(ys[2], ys[3]));
	}

	static bool coords_rectilinear(const float xs[4], const float ys[4]) {
	SkVector e0{xs[1] - xs[0], ys[1] - ys[0]}; // Connects to e1 and e2(repeat)
	SkVector e1{xs[3] - xs[1], ys[3] - ys[1]}; // connects to e0(repeat) and e3
	SkVector e2{xs[0] - xs[2], ys[0] - ys[2]}; // connects to e0 and e3(repeat)
	SkVector e3{xs[2] - xs[3], ys[2] - ys[3]}; // connects to e1(repeat) and e2

	return dot_nearly_zero(e0, e1) && dot_nearly_zero(e1, e3) &&
	dot_nearly_zero(e2, e0) && dot_nearly_zero(e3, e2);
	}

	GrQuadType GrQuad::quadType() const {
	// Since GrQuad applies any perspective information at construction time, there's only two
	// types to choose from.
	if (coords_form_rect(fX, fY)) {
	return GrQuadType::kRect;
	} else if (coords_rectilinear(fX, fY)) {
	return GrQuadType::kRectilinear;
	} else {
	return GrQuadType::kStandard;
	}
	}

	GrQuadType GrPerspQuad::quadType() const {
	if (this->hasPerspective()) {
	return GrQuadType::kPerspective;
	} else {
	// Rect or standard quad, can ignore w since they are all ones
	if (coords_form_rect(fX, fY)) {
	return GrQuadType::kRect;
	} else if (coords_rectilinear(fX, fY)) {
	return GrQuadType::kRectilinear;
	} else {
	return GrQuadType::kStandard;
	}
	}
	}
	#endif

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

	static bool aa_affects_rect(float ql, float qt, float qr, float qb) {
	return !SkScalarIsInt(ql) \|\| !SkScalarIsInt(qr) \|\| !SkScalarIsInt(qt) \|\| !SkScalarIsInt(qb);
	}

	template <typename Q>
	void GrResolveAATypeForQuad(GrAAType requestedAAType, GrQuadAAFlags requestedEdgeFlags,
	const Q& quad, GrQuadType knownType,
	GrAAType* outAAType, GrQuadAAFlags* outEdgeFlags) {
	// Most cases will keep the requested types unchanged
	*outAAType = requestedAAType;
	*outEdgeFlags = requestedEdgeFlags;

	switch (requestedAAType) {
	// When aa type is coverage, disable AA if the edge configuration doesn't actually need it
	case GrAAType::kCoverage:
	if (requestedEdgeFlags == GrQuadAAFlags::kNone) {
	// Turn off anti-aliasing
	*outAAType = GrAAType::kNone;
	} else {
	// For coverage AA, if the quad is a rect and it lines up with pixel boundaries
	// then overall aa and per-edge aa can be completely disabled
	if (knownType == GrQuadType::kRect && !quad.aaHasEffectOnRect()) {
	*outAAType = GrAAType::kNone;
	*outEdgeFlags = GrQuadAAFlags::kNone;
	}
	}
	break;
	// For no or msaa anti aliasing, override the edge flags since edge flags only make sense
	// when coverage aa is being used.
	case GrAAType::kNone:
	*outEdgeFlags = GrQuadAAFlags::kNone;
	break;
	case GrAAType::kMSAA:
	*outEdgeFlags = GrQuadAAFlags::kAll;
	break;
	case GrAAType::kMixedSamples:
	SK_ABORT("Should not use mixed sample AA with edge AA flags");
	break;
	}
	};

	// Instantiate GrResolve... for GrQuad and GrPerspQuad
	template void GrResolveAATypeForQuad(GrAAType, GrQuadAAFlags, const GrQuad&, GrQuadType,
	GrAAType, GrQuadAAFlags);
	template void GrResolveAATypeForQuad(GrAAType, GrQuadAAFlags, const GrPerspQuad&, GrQuadType,
	GrAAType, GrQuadAAFlags);

	GrQuadType GrQuadTypeForTransformedRect(const SkMatrix& matrix) {
	if (matrix.rectStaysRect()) {
	return GrQuadType::kRect;
	} else if (matrix.preservesRightAngles()) {
	return GrQuadType::kRectilinear;
	} else if (matrix.hasPerspective()) {
	return GrQuadType::kPerspective;
	} else {
	return GrQuadType::kStandard;
	}
	}

	GrQuad::GrQuad(const SkRect& rect, const SkMatrix& m) {
	SkMatrix::TypeMask tm = m.getType();
	if (tm <= (SkMatrix::kScale_Mask \| SkMatrix::kTranslate_Mask)) {
	auto r = Sk4f::Load(&rect);
	const Sk4f t(m.getTranslateX(), m.getTranslateY(), m.getTranslateX(), m.getTranslateY());
	if (tm <= SkMatrix::kTranslate_Mask) {
	r += t;
	} else {
	const Sk4f s(m.getScaleX(), m.getScaleY(), m.getScaleX(), m.getScaleY());
	r = r * s + t;
	}
	SkNx_shuffle<0, 0, 2, 2>(r).store(fX);
	SkNx_shuffle<1, 3, 1, 3>(r).store(fY);
	} else {
	Sk4f rx(rect.fLeft, rect.fLeft, rect.fRight, rect.fRight);
	Sk4f ry(rect.fTop, rect.fBottom, rect.fTop, rect.fBottom);
	Sk4f sx(m.getScaleX());
	Sk4f kx(m.getSkewX());
	Sk4f tx(m.getTranslateX());
	Sk4f ky(m.getSkewY());
	Sk4f sy(m.getScaleY());
	Sk4f ty(m.getTranslateY());
	auto x = SkNx_fma(sx, rx, SkNx_fma(kx, ry, tx));
	auto y = SkNx_fma(ky, rx, SkNx_fma(sy, ry, ty));
	if (m.hasPerspective()) {
	Sk4f w0(m.getPerspX());
	Sk4f w1(m.getPerspY());
	Sk4f w2(m.get(SkMatrix::kMPersp2));
	auto iw = SkNx_fma(w0, rx, SkNx_fma(w1, ry, w2)).invert();
	x *= iw;
	y *= iw;
	}
	x.store(fX);
	y.store(fY);
	}
	}

	bool GrQuad::aaHasEffectOnRect() const {
	SkASSERT(this->quadType() == GrQuadType::kRect);
	return aa_affects_rect(fX[0], fY[0], fX[3], fY[3]);
	}

	GrPerspQuad::GrPerspQuad(const SkRect& rect, const SkMatrix& m) {
	SkMatrix::TypeMask tm = m.getType();
	if (tm <= (SkMatrix::kScale_Mask \| SkMatrix::kTranslate_Mask)) {
	auto r = Sk4f::Load(&rect);
	const Sk4f t(m.getTranslateX(), m.getTranslateY(), m.getTranslateX(), m.getTranslateY());
	if (tm <= SkMatrix::kTranslate_Mask) {
	r += t;
	} else {
	const Sk4f s(m.getScaleX(), m.getScaleY(), m.getScaleX(), m.getScaleY());
	r = r * s + t;
	}
	SkNx_shuffle<0, 0, 2, 2>(r).store(fX);
	SkNx_shuffle<1, 3, 1, 3>(r).store(fY);
	fW[0] = fW[1] = fW[2] = fW[3] = 1.f;
	fIW[0] = fIW[1] = fIW[2] = fIW[3] = 1.f;
	} else {
	Sk4f rx(rect.fLeft, rect.fLeft, rect.fRight, rect.fRight);
	Sk4f ry(rect.fTop, rect.fBottom, rect.fTop, rect.fBottom);
	Sk4f sx(m.getScaleX());
	Sk4f kx(m.getSkewX());
	Sk4f tx(m.getTranslateX());
	Sk4f ky(m.getSkewY());
	Sk4f sy(m.getScaleY());
	Sk4f ty(m.getTranslateY());
	SkNx_fma(sx, rx, SkNx_fma(kx, ry, tx)).store(fX);
	SkNx_fma(ky, rx, SkNx_fma(sy, ry, ty)).store(fY);
	if (m.hasPerspective()) {
	Sk4f w0(m.getPerspX());
	Sk4f w1(m.getPerspY());
	Sk4f w2(m.get(SkMatrix::kMPersp2));
	auto w = SkNx_fma(w0, rx, SkNx_fma(w1, ry, w2));
	w.store(fW);
	w.invert().store(fIW);
	} else {
	fW[0] = fW[1] = fW[2] = fW[3] = 1.f;
	fIW[0] = fIW[1] = fIW[2] = fIW[3] = 1.f;
	}
	}
	}

	bool GrPerspQuad::aaHasEffectOnRect() const {
	SkASSERT(this->quadType() == GrQuadType::kRect);
	// If rect, ws must all be 1s so no need to divide
	return aa_affects_rect(fX[0], fY[0], fX[3], fY[3]);
	}