src/gpu/tessellate/WangsFormula.h - skia - Git at Google

 /*
  * Copyright 2020 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_WangsFormula_DEFINED
 #define skgpu_tessellate_WangsFormula_DEFINED

 #include "include/core/SkM44.h"
 #include "include/core/SkMatrix.h"
 #include "include/core/SkPoint.h"
 #include "include/core/SkTypes.h"
 #include "src/base/SkFloatBits.h"
 #include "src/base/SkUtils.h"
 #include "src/base/SkVx.h"

 #include <math.h>
 #include <algorithm>
 #include <cstdint>
 #include <limits>

 #define AI [[maybe_unused]] SK_ALWAYS_INLINE

 // Wang's formula gives the minimum number of evenly spaced (in the parametric sense) line segments
 // that a bezier curve must be chopped into in order to guarantee all lines stay within a distance
 // of "1/precision" pixels from the true curve. Its definition for a bezier curve of degree "n" is
 // as follows:
 //
 //     maxLength = max([length(p[i+2] - 2p[i+1] + p[i]) for (0 <= i <= n-2)])
 //     numParametricSegments = sqrt(maxLength * precision * n*(n - 1)/8)
 //
 // (Goldman, Ron. (2003). 5.6.3 Wang's Formula. "Pyramid Algorithms: A Dynamic Programming Approach
 // to Curves and Surfaces for Geometric Modeling". Morgan Kaufmann Publishers.)
 namespace skgpu::wangs_formula {

 // Returns the value by which to multiply length in Wang's formula. (See above.)
 template<int Degree> constexpr float length_term(float precision) {
     return (Degree * (Degree - 1) / 8.f) * precision;
 }
 template<int Degree> constexpr float length_term_p2(float precision) {
     return ((Degree * Degree) * ((Degree - 1) * (Degree - 1)) / 64.f) * (precision * precision);
 }

 AI float root4(float x) {
     return sqrtf(sqrtf(x));
 }

 // For finite positive x > 1, return ceil(log2(x)) otherwise, return 0.
 // For +/- NaN return 0.
 // For +infinity return 128.
 // For -infinity return 0.
 //
 //     nextlog2((-inf..1]) -> 0
 //     nextlog2((1..2]) -> 1
 //     nextlog2((2..4]) -> 2
 //     nextlog2((4..8]) -> 3
 //     ...
 AI int nextlog2(float x) {
     if (x <= 1) {
         return 0;
     }

     uint32_t bits = SkFloat2Bits(x);
     static constexpr uint32_t kDigitsAfterBinaryPoint = std::numeric_limits<float>::digits - 1;

     // The constant is a significand of all 1s -- 0b0'00000000'111'1111111111'111111111. So, if
     // the significand of x is all 0s (and therefore an integer power of two) this will not
     // increment the exponent, but if it is just one ULP above the power of two the carry will
     // ripple into the exponent incrementing the exponent by 1.
     bits += (1u << kDigitsAfterBinaryPoint) - 1u;

     // Shift the exponent down, and adjust it by the exponent offset so that 2^0 is really 0 instead
     // of 127. Remember that 1 was added to the exponent, if x is NaN, then the exponent will
     // carry a 1 into the sign bit during the addition to bits. Be sure to strip off the sign bit.
     // In addition, infinity is an exponent of all 1's, and a significand of all 0, so
     // the exponent is not affected during the addition to bits, and the exponent remains all 1's.
     const int exp = ((bits >> kDigitsAfterBinaryPoint) & 0b1111'1111) - 127;

     // Return 0 for x <= 1.
     return exp > 0 ? exp : 0;
 }

 // Returns nextlog2(sqrt(x)):
 //
 //   log2(sqrt(x)) == log2(x^(1/2)) == log2(x)/2 == log2(x)/log2(4) == log4(x)
 //
 AI int nextlog4(float x) {
     return (nextlog2(x) + 1) >> 1;
 }

 // Returns nextlog2(sqrt(sqrt(x))):
 //
 //   log2(sqrt(sqrt(x))) == log2(x^(1/4)) == log2(x)/4 == log2(x)/log2(16) == log16(x)
 //
 AI int nextlog16(float x) {
     return (nextlog2(x) + 3) >> 2;
 }

 // Represents the upper-left 2x2 matrix of an affine transform for applying to vectors:
 //
 //     VectorXform(p1 - p0) == M * float3(p1, 1) - M * float3(p0, 1)
 //
 class VectorXform {
 public:
     AI VectorXform() : fC0{1.0f, 0.f}, fC1{0.f, 1.f} {}
     AI explicit VectorXform(const SkMatrix& m) { *this = m; }
     AI explicit VectorXform(const SkM44& m) { *this = m; }

     AI VectorXform& operator=(const SkMatrix& m) {
         SkASSERT(!m.hasPerspective());
         fC0 = {m.rc(0,0), m.rc(1,0)};
         fC1 = {m.rc(0,1), m.rc(1,1)};
         return *this;
     }
     AI VectorXform& operator=(const SkM44& m) {
         SkASSERT(m.rc(3,0) == 0.f && m.rc(3,1) == 0.f && m.rc(3,2) == 0.f && m.rc(3,3) == 1.f);
         fC0 = {m.rc(0,0), m.rc(1,0)};
         fC1 = {m.rc(0,1), m.rc(1,1)};
         return *this;
     }
     AI skvx::float2 operator()(skvx::float2 vector) const {
         return fC0 * vector.x() + fC1 * vector.y();
     }
     AI skvx::float4 operator()(skvx::float4 vectors) const {
         return join(fC0 * vectors.x() + fC1 * vectors.y(),
                     fC0 * vectors.z() + fC1 * vectors.w());
     }
 private:
     // First and second columns of 2x2 matrix
     skvx::float2 fC0;
     skvx::float2 fC1;
 };

 // Returns Wang's formula, raised to the 4th power, specialized for a quadratic curve.
 AI float quadratic_p4(float precision,
                       skvx::float2 p0, skvx::float2 p1, skvx::float2 p2,
                       const VectorXform& vectorXform = VectorXform()) {
     skvx::float2 v = -2*p1 + p0 + p2;
     v = vectorXform(v);
     skvx::float2 vv = v*v;
     return (vv[0] + vv[1]) * length_term_p2<2>(precision);
 }
 AI float quadratic_p4(float precision,
                       const SkPoint pts[],
                       const VectorXform& vectorXform = VectorXform()) {
     return quadratic_p4(precision,
                         sk_bit_cast<skvx::float2>(pts[0]),
                         sk_bit_cast<skvx::float2>(pts[1]),
                         sk_bit_cast<skvx::float2>(pts[2]),
                         vectorXform);
 }

 // Returns Wang's formula specialized for a quadratic curve.
 AI float quadratic(float precision,
                    const SkPoint pts[],
                    const VectorXform& vectorXform = VectorXform()) {
     return root4(quadratic_p4(precision, pts, vectorXform));
 }

 // Returns the log2 value of Wang's formula specialized for a quadratic curve, rounded up to the
 // next int.
 AI int quadratic_log2(float precision,
                       const SkPoint pts[],
                       const VectorXform& vectorXform = VectorXform()) {
     // nextlog16(x) == ceil(log2(sqrt(sqrt(x))))
     return nextlog16(quadratic_p4(precision, pts, vectorXform));
 }

 // Returns Wang's formula, raised to the 4th power, specialized for a cubic curve.
 AI float cubic_p4(float precision,
                   skvx::float2 p0, skvx::float2 p1, skvx::float2 p2, skvx::float2 p3,
                   const VectorXform& vectorXform = VectorXform()) {
     skvx::float4 p01{p0, p1};
     skvx::float4 p12{p1, p2};
     skvx::float4 p23{p2, p3};
     skvx::float4 v = -2*p12 + p01 + p23;
     v = vectorXform(v);
     skvx::float4 vv = v*v;
     return std::max(vv[0] + vv[1], vv[2] + vv[3]) * length_term_p2<3>(precision);
 }
 AI float cubic_p4(float precision,
                   const SkPoint pts[],
                   const VectorXform& vectorXform = VectorXform()) {
     return cubic_p4(precision,
                     sk_bit_cast<skvx::float2>(pts[0]),
                     sk_bit_cast<skvx::float2>(pts[1]),
                     sk_bit_cast<skvx::float2>(pts[2]),
                     sk_bit_cast<skvx::float2>(pts[3]),
                     vectorXform);
 }

 // Returns Wang's formula specialized for a cubic curve.
 AI float cubic(float precision,
                const SkPoint pts[],
                const VectorXform& vectorXform = VectorXform()) {
     return root4(cubic_p4(precision, pts, vectorXform));
 }

 // Returns the log2 value of Wang's formula specialized for a cubic curve, rounded up to the next
 // int.
 AI int cubic_log2(float precision,
                   const SkPoint pts[],
                   const VectorXform& vectorXform = VectorXform()) {
     // nextlog16(x) == ceil(log2(sqrt(sqrt(x))))
     return nextlog16(cubic_p4(precision, pts, vectorXform));
 }

 // Returns the maximum number of line segments a cubic with the given device-space bounding box size
 // would ever need to be divided into, raised to the 4th power. This is simply a special case of the
 // cubic formula where we maximize its value by placing control points on specific corners of the
 // bounding box.
 AI float worst_case_cubic_p4(float precision, float devWidth, float devHeight) {
     float kk = length_term_p2<3>(precision);
     return 4*kk * (devWidth * devWidth + devHeight * devHeight);
 }

 // Returns the maximum number of line segments a cubic with the given device-space bounding box size
 // would ever need to be divided into.
 AI float worst_case_cubic(float precision, float devWidth, float devHeight) {
     return root4(worst_case_cubic_p4(precision, devWidth, devHeight));
 }

 // Returns the maximum log2 number of line segments a cubic with the given device-space bounding box
 // size would ever need to be divided into.
 AI int worst_case_cubic_log2(float precision, float devWidth, float devHeight) {
     // nextlog16(x) == ceil(log2(sqrt(sqrt(x))))
     return nextlog16(worst_case_cubic_p4(precision, devWidth, devHeight));
 }

 // Returns Wang's formula specialized for a conic curve, raised to the second power.
 // Input points should be in projected space.
 //
 // This is not actually due to Wang, but is an analogue from (Theorem 3, corollary 1):
 //   J. Zheng, T. Sederberg. "Estimating Tessellation Parameter Intervals for
 //   Rational Curves and Surfaces." ACM Transactions on Graphics 19(1). 2000.
 AI float conic_p2(float precision,
                   skvx::float2 p0, skvx::float2 p1, skvx::float2 p2,
                   float w,
                   const VectorXform& vectorXform = VectorXform()) {
     p0 = vectorXform(p0);
     p1 = vectorXform(p1);
     p2 = vectorXform(p2);

     // Compute center of bounding box in projected space
     const skvx::float2 C = 0.5f * (min(min(p0, p1), p2) + max(max(p0, p1), p2));

     // Translate by -C. This improves translation-invariance of the formula,
     // see Sec. 3.3 of cited paper
     p0 -= C;
     p1 -= C;
     p2 -= C;

     // Compute max length
     const float max_len = sqrtf(std::max(dot(p0, p0), std::max(dot(p1, p1), dot(p2, p2))));


     // Compute forward differences
     const skvx::float2 dp = -2*w*p1 + p0 + p2;
     const float dw = fabsf(-2 * w + 2);

     // Compute numerator and denominator for parametric step size of linearization. Here, the
     // epsilon referenced from the cited paper is 1/precision.
     const float rp_minus_1 = std::max(0.f, max_len * precision - 1);
     const float numer = sqrtf(dot(dp, dp)) * precision + rp_minus_1 * dw;
     const float denom = 4 * std::min(w, 1.f);

     // Number of segments = sqrt(numer / denom).
     // This assumes parametric interval of curve being linearized is [t0,t1] = [0, 1].
     // If not, the number of segments is (tmax - tmin) / sqrt(denom / numer).
     return numer / denom;
 }
 AI float conic_p2(float precision,
                   const SkPoint pts[],
                   float w,
                   const VectorXform& vectorXform = VectorXform()) {
     return conic_p2(precision,
                     sk_bit_cast<skvx::float2>(pts[0]),
                     sk_bit_cast<skvx::float2>(pts[1]),
                     sk_bit_cast<skvx::float2>(pts[2]),
                     w,
                     vectorXform);
 }

 // Returns the value of Wang's formula specialized for a conic curve.
 AI float conic(float tolerance,
                const SkPoint pts[],
                float w,
                const VectorXform& vectorXform = VectorXform()) {
     return sqrtf(conic_p2(tolerance, pts, w, vectorXform));
 }

 // Returns the log2 value of Wang's formula specialized for a conic curve, rounded up to the next
 // int.
 AI int conic_log2(float tolerance,
                   const SkPoint pts[],
                   float w,
                   const VectorXform& vectorXform = VectorXform()) {
     // nextlog4(x) == ceil(log2(sqrt(x)))
     return nextlog4(conic_p2(tolerance, pts, w, vectorXform));
 }

 }  // namespace skgpu::wangs_formula

 #undef AI

 #endif  // skgpu_tessellate_WangsFormula_DEFINED
	/*
	* Copyright 2020 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_WangsFormula_DEFINED
	#define skgpu_tessellate_WangsFormula_DEFINED

	#include "include/core/SkM44.h"
	#include "include/core/SkMatrix.h"
	#include "include/core/SkPoint.h"
	#include "include/core/SkTypes.h"
	#include "src/base/SkFloatBits.h"
	#include "src/base/SkUtils.h"
	#include "src/base/SkVx.h"

	#include <math.h>
	#include <algorithm>
	#include <cstdint>
	#include <limits>

	#define AI [[maybe_unused]] SK_ALWAYS_INLINE

	// Wang's formula gives the minimum number of evenly spaced (in the parametric sense) line segments
	// that a bezier curve must be chopped into in order to guarantee all lines stay within a distance
	// of "1/precision" pixels from the true curve. Its definition for a bezier curve of degree "n" is
	// as follows:
	//
	// maxLength = max([length(p[i+2] - 2p[i+1] + p[i]) for (0 <= i <= n-2)])
	// numParametricSegments = sqrt(maxLength * precision * n*(n - 1)/8)
	//
	// (Goldman, Ron. (2003). 5.6.3 Wang's Formula. "Pyramid Algorithms: A Dynamic Programming Approach
	// to Curves and Surfaces for Geometric Modeling". Morgan Kaufmann Publishers.)
	namespace skgpu::wangs_formula {

	// Returns the value by which to multiply length in Wang's formula. (See above.)
	template<int Degree> constexpr float length_term(float precision) {
	return (Degree * (Degree - 1) / 8.f) * precision;
	}
	template<int Degree> constexpr float length_term_p2(float precision) {
	return ((Degree * Degree) * ((Degree - 1) * (Degree - 1)) / 64.f) * (precision * precision);
	}

	AI float root4(float x) {
	return sqrtf(sqrtf(x));
	}

	// For finite positive x > 1, return ceil(log2(x)) otherwise, return 0.
	// For +/- NaN return 0.
	// For +infinity return 128.
	// For -infinity return 0.
	//
	// nextlog2((-inf..1]) -> 0
	// nextlog2((1..2]) -> 1
	// nextlog2((2..4]) -> 2
	// nextlog2((4..8]) -> 3
	// ...
	AI int nextlog2(float x) {
	if (x <= 1) {
	return 0;
	}

	uint32_t bits = SkFloat2Bits(x);
	static constexpr uint32_t kDigitsAfterBinaryPoint = std::numeric_limits<float>::digits - 1;

	// The constant is a significand of all 1s -- 0b0'00000000'111'1111111111'111111111. So, if
	// the significand of x is all 0s (and therefore an integer power of two) this will not
	// increment the exponent, but if it is just one ULP above the power of two the carry will
	// ripple into the exponent incrementing the exponent by 1.
	bits += (1u << kDigitsAfterBinaryPoint) - 1u;

	// Shift the exponent down, and adjust it by the exponent offset so that 2^0 is really 0 instead
	// of 127. Remember that 1 was added to the exponent, if x is NaN, then the exponent will
	// carry a 1 into the sign bit during the addition to bits. Be sure to strip off the sign bit.
	// In addition, infinity is an exponent of all 1's, and a significand of all 0, so
	// the exponent is not affected during the addition to bits, and the exponent remains all 1's.
	const int exp = ((bits >> kDigitsAfterBinaryPoint) & 0b1111'1111) - 127;

	// Return 0 for x <= 1.
	return exp > 0 ? exp : 0;
	}

	// Returns nextlog2(sqrt(x)):
	//
	// log2(sqrt(x)) == log2(x^(1/2)) == log2(x)/2 == log2(x)/log2(4) == log4(x)
	//
	AI int nextlog4(float x) {
	return (nextlog2(x) + 1) >> 1;
	}

	// Returns nextlog2(sqrt(sqrt(x))):
	//
	// log2(sqrt(sqrt(x))) == log2(x^(1/4)) == log2(x)/4 == log2(x)/log2(16) == log16(x)
	//
	AI int nextlog16(float x) {
	return (nextlog2(x) + 3) >> 2;
	}

	// Represents the upper-left 2x2 matrix of an affine transform for applying to vectors:
	//
	// VectorXform(p1 - p0) == M * float3(p1, 1) - M * float3(p0, 1)
	//
	class VectorXform {
	public:
	AI VectorXform() : fC0{1.0f, 0.f}, fC1{0.f, 1.f} {}
	AI explicit VectorXform(const SkMatrix& m) { *this = m; }
	AI explicit VectorXform(const SkM44& m) { *this = m; }

	AI VectorXform& operator=(const SkMatrix& m) {
	SkASSERT(!m.hasPerspective());
	fC0 = {m.rc(0,0), m.rc(1,0)};
	fC1 = {m.rc(0,1), m.rc(1,1)};
	return *this;
	}
	AI VectorXform& operator=(const SkM44& m) {
	SkASSERT(m.rc(3,0) == 0.f && m.rc(3,1) == 0.f && m.rc(3,2) == 0.f && m.rc(3,3) == 1.f);
	fC0 = {m.rc(0,0), m.rc(1,0)};
	fC1 = {m.rc(0,1), m.rc(1,1)};
	return *this;
	}
	AI skvx::float2 operator()(skvx::float2 vector) const {
	return fC0 * vector.x() + fC1 * vector.y();
	}
	AI skvx::float4 operator()(skvx::float4 vectors) const {
	return join(fC0 * vectors.x() + fC1 * vectors.y(),
	fC0 * vectors.z() + fC1 * vectors.w());
	}
	private:
	// First and second columns of 2x2 matrix
	skvx::float2 fC0;
	skvx::float2 fC1;
	};

	// Returns Wang's formula, raised to the 4th power, specialized for a quadratic curve.
	AI float quadratic_p4(float precision,
	skvx::float2 p0, skvx::float2 p1, skvx::float2 p2,
	const VectorXform& vectorXform = VectorXform()) {
	skvx::float2 v = -2*p1 + p0 + p2;
	v = vectorXform(v);
	skvx::float2 vv = v*v;
	return (vv[0] + vv[1]) * length_term_p2<2>(precision);
	}
	AI float quadratic_p4(float precision,
	const SkPoint pts[],
	const VectorXform& vectorXform = VectorXform()) {
	return quadratic_p4(precision,
	sk_bit_cast<skvx::float2>(pts[0]),
	sk_bit_cast<skvx::float2>(pts[1]),
	sk_bit_cast<skvx::float2>(pts[2]),
	vectorXform);
	}

	// Returns Wang's formula specialized for a quadratic curve.
	AI float quadratic(float precision,
	const SkPoint pts[],
	const VectorXform& vectorXform = VectorXform()) {
	return root4(quadratic_p4(precision, pts, vectorXform));
	}

	// Returns the log2 value of Wang's formula specialized for a quadratic curve, rounded up to the
	// next int.
	AI int quadratic_log2(float precision,
	const SkPoint pts[],
	const VectorXform& vectorXform = VectorXform()) {
	// nextlog16(x) == ceil(log2(sqrt(sqrt(x))))
	return nextlog16(quadratic_p4(precision, pts, vectorXform));
	}

	// Returns Wang's formula, raised to the 4th power, specialized for a cubic curve.
	AI float cubic_p4(float precision,
	skvx::float2 p0, skvx::float2 p1, skvx::float2 p2, skvx::float2 p3,
	const VectorXform& vectorXform = VectorXform()) {
	skvx::float4 p01{p0, p1};
	skvx::float4 p12{p1, p2};
	skvx::float4 p23{p2, p3};
	skvx::float4 v = -2*p12 + p01 + p23;
	v = vectorXform(v);
	skvx::float4 vv = v*v;
	return std::max(vv[0] + vv[1], vv[2] + vv[3]) * length_term_p2<3>(precision);
	}
	AI float cubic_p4(float precision,
	const SkPoint pts[],
	const VectorXform& vectorXform = VectorXform()) {
	return cubic_p4(precision,
	sk_bit_cast<skvx::float2>(pts[0]),
	sk_bit_cast<skvx::float2>(pts[1]),
	sk_bit_cast<skvx::float2>(pts[2]),
	sk_bit_cast<skvx::float2>(pts[3]),
	vectorXform);
	}

	// Returns Wang's formula specialized for a cubic curve.
	AI float cubic(float precision,
	const SkPoint pts[],
	const VectorXform& vectorXform = VectorXform()) {
	return root4(cubic_p4(precision, pts, vectorXform));
	}

	// Returns the log2 value of Wang's formula specialized for a cubic curve, rounded up to the next
	// int.
	AI int cubic_log2(float precision,
	const SkPoint pts[],
	const VectorXform& vectorXform = VectorXform()) {
	// nextlog16(x) == ceil(log2(sqrt(sqrt(x))))
	return nextlog16(cubic_p4(precision, pts, vectorXform));
	}

	// Returns the maximum number of line segments a cubic with the given device-space bounding box size
	// would ever need to be divided into, raised to the 4th power. This is simply a special case of the
	// cubic formula where we maximize its value by placing control points on specific corners of the
	// bounding box.
	AI float worst_case_cubic_p4(float precision, float devWidth, float devHeight) {
	float kk = length_term_p2<3>(precision);
	return 4kk (devWidth * devWidth + devHeight * devHeight);
	}

	// Returns the maximum number of line segments a cubic with the given device-space bounding box size
	// would ever need to be divided into.
	AI float worst_case_cubic(float precision, float devWidth, float devHeight) {
	return root4(worst_case_cubic_p4(precision, devWidth, devHeight));
	}

	// Returns the maximum log2 number of line segments a cubic with the given device-space bounding box
	// size would ever need to be divided into.
	AI int worst_case_cubic_log2(float precision, float devWidth, float devHeight) {
	// nextlog16(x) == ceil(log2(sqrt(sqrt(x))))
	return nextlog16(worst_case_cubic_p4(precision, devWidth, devHeight));
	}

	// Returns Wang's formula specialized for a conic curve, raised to the second power.
	// Input points should be in projected space.
	//
	// This is not actually due to Wang, but is an analogue from (Theorem 3, corollary 1):
	// J. Zheng, T. Sederberg. "Estimating Tessellation Parameter Intervals for
	// Rational Curves and Surfaces." ACM Transactions on Graphics 19(1). 2000.
	AI float conic_p2(float precision,
	skvx::float2 p0, skvx::float2 p1, skvx::float2 p2,
	float w,
	const VectorXform& vectorXform = VectorXform()) {
	p0 = vectorXform(p0);
	p1 = vectorXform(p1);
	p2 = vectorXform(p2);

	// Compute center of bounding box in projected space
	const skvx::float2 C = 0.5f * (min(min(p0, p1), p2) + max(max(p0, p1), p2));

	// Translate by -C. This improves translation-invariance of the formula,
	// see Sec. 3.3 of cited paper
	p0 -= C;
	p1 -= C;
	p2 -= C;

	// Compute max length
	const float max_len = sqrtf(std::max(dot(p0, p0), std::max(dot(p1, p1), dot(p2, p2))));


	// Compute forward differences
	const skvx::float2 dp = -2wp1 + p0 + p2;
	const float dw = fabsf(-2 * w + 2);

	// Compute numerator and denominator for parametric step size of linearization. Here, the
	// epsilon referenced from the cited paper is 1/precision.
	const float rp_minus_1 = std::max(0.f, max_len * precision - 1);
	const float numer = sqrtf(dot(dp, dp)) * precision + rp_minus_1 * dw;
	const float denom = 4 * std::min(w, 1.f);

	// Number of segments = sqrt(numer / denom).
	// This assumes parametric interval of curve being linearized is [t0,t1] = [0, 1].
	// If not, the number of segments is (tmax - tmin) / sqrt(denom / numer).
	return numer / denom;
	}
	AI float conic_p2(float precision,
	const SkPoint pts[],
	float w,
	const VectorXform& vectorXform = VectorXform()) {
	return conic_p2(precision,
	sk_bit_cast<skvx::float2>(pts[0]),
	sk_bit_cast<skvx::float2>(pts[1]),
	sk_bit_cast<skvx::float2>(pts[2]),
	w,
	vectorXform);
	}

	// Returns the value of Wang's formula specialized for a conic curve.
	AI float conic(float tolerance,
	const SkPoint pts[],
	float w,
	const VectorXform& vectorXform = VectorXform()) {
	return sqrtf(conic_p2(tolerance, pts, w, vectorXform));
	}

	// Returns the log2 value of Wang's formula specialized for a conic curve, rounded up to the next
	// int.
	AI int conic_log2(float tolerance,
	const SkPoint pts[],
	float w,
	const VectorXform& vectorXform = VectorXform()) {
	// nextlog4(x) == ceil(log2(sqrt(x)))
	return nextlog4(conic_p2(tolerance, pts, w, vectorXform));
	}

	} // namespace skgpu::wangs_formula

	#undef AI

	#endif // skgpu_tessellate_WangsFormula_DEFINED