third_party/skia/src/gpu/tessellate/CullTest.h - cobalt - Git at Google

 /*
  * Copyright 2021 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef skgpu_tessellate_CullTest_DEFINED
 #define skgpu_tessellate_CullTest_DEFINED

 #include "include/core/SkMatrix.h"
 #include "src/gpu/tessellate/Tessellation.h"

 namespace skgpu {

 // This class determines whether the given local-space points will be contained in the cull bounds
 // post transform. For the versions that take >1 point, it returns whether any region of their
 // device-space bounding box will be in the cull bounds.
 //
 // NOTE: Our view matrix is not a normal matrix. M*p maps to the float4 [x, y, -x, -y] in device
 // space. We do this to aid in quick bounds calculations. The matrix also does not have a
 // translation element. Instead we unapply the translation to the cull bounds ahead of time.
 class CullTest {
 public:
     CullTest() = default;

     CullTest(const SkRect& devCullBounds, const SkMatrix& m) {
         this->set(devCullBounds, m);
     }

     void set(const SkRect& devCullBounds, const SkMatrix& m) {
         SkASSERT(!m.hasPerspective());
         // [fMatX, fMatY] maps path coordinates to the float4 [x, y, -x, -y] in device space.
         fMatX = {m.getScaleX(), m.getSkewY(), -m.getScaleX(), -m.getSkewY()};
         fMatY = {m.getSkewX(), m.getScaleY(), -m.getSkewX(), -m.getScaleY()};
         // Store the cull bounds as [l, t, -r, -b] for faster math.
         // Also subtract the matrix translate from the cull bounds ahead of time, rather than adding
         // it to every point every time we test.
         fCullBounds = {devCullBounds.fLeft - m.getTranslateX(),
                        devCullBounds.fTop - m.getTranslateY(),
                        m.getTranslateX() - devCullBounds.fRight,
                        m.getTranslateY() - devCullBounds.fBottom};
     }

     // Returns whether M*p will be in the viewport.
     bool isVisible(SkPoint p) const {
         // devPt = [x, y, -x, -y] in device space.
         auto devPt = fMatX*p.fX + fMatY*p.fY;
         // i.e., l < x && t < y && r > x && b > y.
         return skvx::all(fCullBounds < devPt);
     }

     // Returns whether any region of the bounding box of M * p0..2 will be in the viewport.
     bool areVisible3(const SkPoint p[3]) const {
         // Transform p0..2 to device space.
         auto val0 = fMatY * p[0].fY;
         auto val1 = fMatY * p[1].fY;
         auto val2 = fMatY * p[2].fY;
         val0 = fMatX*p[0].fX + val0;
         val1 = fMatX*p[1].fX + val1;
         val2 = fMatX*p[2].fX + val2;
         // At this point: valN = {xN, yN, -xN, -yN} in device space.

         // Find the device-space bounding box of p0..2.
         val0 = skvx::max(val0, val1);
         val0 = skvx::max(val0, val2);
         // At this point: val0 = [r, b, -l, -t] of the device-space bounding box of p0..2.

         // Does fCullBounds intersect the device-space bounding box of p0..2?
         // i.e., l0 < r1 && t0 < b1 && r0 > l1 && b0 > t1.
         return skvx::all(fCullBounds < val0);
     }

     // Returns whether any region of the bounding box of M * p0..3 will be in the viewport.
     bool areVisible4(const SkPoint p[4]) const {
         // Transform p0..3 to device space.
         auto val0 = fMatY * p[0].fY;
         auto val1 = fMatY * p[1].fY;
         auto val2 = fMatY * p[2].fY;
         auto val3 = fMatY * p[3].fY;
         val0 = fMatX*p[0].fX + val0;
         val1 = fMatX*p[1].fX + val1;
         val2 = fMatX*p[2].fX + val2;
         val3 = fMatX*p[3].fX + val3;
         // At this point: valN = {xN, yN, -xN, -yN} in device space.

         // Find the device-space bounding box of p0..3.
         val0 = skvx::max(val0, val1);
         val2 = skvx::max(val2, val3);
         val0 = skvx::max(val0, val2);
         // At this point: val0 = [r, b, -l, -t] of the device-space bounding box of p0..3.

         // Does fCullBounds intersect the device-space bounding box of p0..3?
         // i.e., l0 < r1 && t0 < b1 && r0 > l1 && b0 > t1.
         return skvx::all(fCullBounds < val0);
     }

 private:
     // [fMatX, fMatY] maps path coordinates to the float4 [x, y, -x, -y] in device space.
     float4 fMatX;
     float4 fMatY;
     float4 fCullBounds;  // [l, t, -r, -b]
 };

 }  // namespace skgpu

 #endif  // skgpu_tessellate_CullTest_DEFINED
	/*
	* Copyright 2021 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef skgpu_tessellate_CullTest_DEFINED
	#define skgpu_tessellate_CullTest_DEFINED

	#include "include/core/SkMatrix.h"
	#include "src/gpu/tessellate/Tessellation.h"

	namespace skgpu {

	// This class determines whether the given local-space points will be contained in the cull bounds
	// post transform. For the versions that take >1 point, it returns whether any region of their
	// device-space bounding box will be in the cull bounds.
	//
	// NOTE: Our view matrix is not a normal matrix. M*p maps to the float4 [x, y, -x, -y] in device
	// space. We do this to aid in quick bounds calculations. The matrix also does not have a
	// translation element. Instead we unapply the translation to the cull bounds ahead of time.
	class CullTest {
	public:
	CullTest() = default;

	CullTest(const SkRect& devCullBounds, const SkMatrix& m) {
	this->set(devCullBounds, m);
	}

	void set(const SkRect& devCullBounds, const SkMatrix& m) {
	SkASSERT(!m.hasPerspective());
	// [fMatX, fMatY] maps path coordinates to the float4 [x, y, -x, -y] in device space.
	fMatX = {m.getScaleX(), m.getSkewY(), -m.getScaleX(), -m.getSkewY()};
	fMatY = {m.getSkewX(), m.getScaleY(), -m.getSkewX(), -m.getScaleY()};
	// Store the cull bounds as [l, t, -r, -b] for faster math.
	// Also subtract the matrix translate from the cull bounds ahead of time, rather than adding
	// it to every point every time we test.
	fCullBounds = {devCullBounds.fLeft - m.getTranslateX(),
	devCullBounds.fTop - m.getTranslateY(),
	m.getTranslateX() - devCullBounds.fRight,
	m.getTranslateY() - devCullBounds.fBottom};
	}

	// Returns whether M*p will be in the viewport.
	bool isVisible(SkPoint p) const {
	// devPt = [x, y, -x, -y] in device space.
	auto devPt = fMatXp.fX + fMatYp.fY;
	// i.e., l < x && t < y && r > x && b > y.
	return skvx::all(fCullBounds < devPt);
	}

	// Returns whether any region of the bounding box of M * p0..2 will be in the viewport.
	bool areVisible3(const SkPoint p[3]) const {
	// Transform p0..2 to device space.
	auto val0 = fMatY * p[0].fY;
	auto val1 = fMatY * p[1].fY;
	auto val2 = fMatY * p[2].fY;
	val0 = fMatX*p[0].fX + val0;
	val1 = fMatX*p[1].fX + val1;
	val2 = fMatX*p[2].fX + val2;
	// At this point: valN = {xN, yN, -xN, -yN} in device space.

	// Find the device-space bounding box of p0..2.
	val0 = skvx::max(val0, val1);
	val0 = skvx::max(val0, val2);
	// At this point: val0 = [r, b, -l, -t] of the device-space bounding box of p0..2.

	// Does fCullBounds intersect the device-space bounding box of p0..2?
	// i.e., l0 < r1 && t0 < b1 && r0 > l1 && b0 > t1.
	return skvx::all(fCullBounds < val0);
	}

	// Returns whether any region of the bounding box of M * p0..3 will be in the viewport.
	bool areVisible4(const SkPoint p[4]) const {
	// Transform p0..3 to device space.
	auto val0 = fMatY * p[0].fY;
	auto val1 = fMatY * p[1].fY;
	auto val2 = fMatY * p[2].fY;
	auto val3 = fMatY * p[3].fY;
	val0 = fMatX*p[0].fX + val0;
	val1 = fMatX*p[1].fX + val1;
	val2 = fMatX*p[2].fX + val2;
	val3 = fMatX*p[3].fX + val3;
	// At this point: valN = {xN, yN, -xN, -yN} in device space.

	// Find the device-space bounding box of p0..3.
	val0 = skvx::max(val0, val1);
	val2 = skvx::max(val2, val3);
	val0 = skvx::max(val0, val2);
	// At this point: val0 = [r, b, -l, -t] of the device-space bounding box of p0..3.

	// Does fCullBounds intersect the device-space bounding box of p0..3?
	// i.e., l0 < r1 && t0 < b1 && r0 > l1 && b0 > t1.
	return skvx::all(fCullBounds < val0);
	}

	private:
	// [fMatX, fMatY] maps path coordinates to the float4 [x, y, -x, -y] in device space.
	float4 fMatX;
	float4 fMatY;
	float4 fCullBounds; // [l, t, -r, -b]
	};

	} // namespace skgpu

	#endif // skgpu_tessellate_CullTest_DEFINED