virtualx-engine/thirdparty/thekla_atlas/nvmath/Fitting.h

// This code is in the public domain -- Ignacio Castaño <castano@gmail.com>

#pragma once
#ifndef NV_MATH_FITTING_H
#define NV_MATH_FITTING_H

#include "Vector.h"
#include "Plane.h"

namespace nv
{
    namespace Fit
    {
        Vector3 computeCentroid(int n, const Vector3 * points);
        Vector3 computeCentroid(int n, const Vector3 * points, const float * weights, const Vector3 & metric);

        Vector4 computeCentroid(int n, const Vector4 * points);
        Vector4 computeCentroid(int n, const Vector4 * points, const float * weights, const Vector4 & metric);

        Vector3 computeCovariance(int n, const Vector3 * points, float * covariance);
        Vector3 computeCovariance(int n, const Vector3 * points, const float * weights, const Vector3 & metric, float * covariance);

        Vector4 computeCovariance(int n, const Vector4 * points, float * covariance);
        Vector4 computeCovariance(int n, const Vector4 * points, const float * weights, const Vector4 & metric, float * covariance);

        Vector3 computePrincipalComponent_PowerMethod(int n, const Vector3 * points);
        Vector3 computePrincipalComponent_PowerMethod(int n, const Vector3 * points, const float * weights, const Vector3 & metric);

        Vector3 computePrincipalComponent_EigenSolver(int n, const Vector3 * points);
        Vector3 computePrincipalComponent_EigenSolver(int n, const Vector3 * points, const float * weights, const Vector3 & metric);

		Vector4 computePrincipalComponent_EigenSolver(int n, const Vector4 * points);
        Vector4 computePrincipalComponent_EigenSolver(int n, const Vector4 * points, const float * weights, const Vector4 & metric);

        Vector3 computePrincipalComponent_SVD(int n, const Vector3 * points);
        Vector4 computePrincipalComponent_SVD(int n, const Vector4 * points);

        Plane bestPlane(int n, const Vector3 * points);
        bool isPlanar(int n, const Vector3 * points, float epsilon = NV_EPSILON);

        bool eigenSolveSymmetric3(const float matrix[6], float eigenValues[3], Vector3 eigenVectors[3]);
        bool eigenSolveSymmetric4(const float matrix[10], float eigenValues[4], Vector4 eigenVectors[4]);

        // Returns number of clusters [1-4].
        int compute4Means(int n, const Vector3 * points, const float * weights, const Vector3 & metric, Vector3 * cluster);
    }

} // nv namespace

#endif // NV_MATH_FITTING_H
Import thekla_atlas As requested by reduz, an import of thekla_atlas into thirdparty/ 2017-12-08 15:05:47 +01:00			`// This code is in the public domain -- Ignacio Castaño <castano@gmail.com>`

			`#pragma once`
			`#ifndef NV_MATH_FITTING_H`
			`#define NV_MATH_FITTING_H`

			`#include "Vector.h"`
			`#include "Plane.h"`

			`namespace nv`
			`{`
			`namespace Fit`
			`{`
			`Vector3 computeCentroid(int n, const Vector3 * points);`
			`Vector3 computeCentroid(int n, const Vector3 * points, const float * weights, const Vector3 & metric);`

			`Vector4 computeCentroid(int n, const Vector4 * points);`
			`Vector4 computeCentroid(int n, const Vector4 * points, const float * weights, const Vector4 & metric);`

			`Vector3 computeCovariance(int n, const Vector3 * points, float * covariance);`
			`Vector3 computeCovariance(int n, const Vector3 * points, const float * weights, const Vector3 & metric, float * covariance);`

			`Vector4 computeCovariance(int n, const Vector4 * points, float * covariance);`
			`Vector4 computeCovariance(int n, const Vector4 * points, const float * weights, const Vector4 & metric, float * covariance);`

			`Vector3 computePrincipalComponent_PowerMethod(int n, const Vector3 * points);`
			`Vector3 computePrincipalComponent_PowerMethod(int n, const Vector3 * points, const float * weights, const Vector3 & metric);`

			`Vector3 computePrincipalComponent_EigenSolver(int n, const Vector3 * points);`
			`Vector3 computePrincipalComponent_EigenSolver(int n, const Vector3 * points, const float * weights, const Vector3 & metric);`

			`Vector4 computePrincipalComponent_EigenSolver(int n, const Vector4 * points);`
			`Vector4 computePrincipalComponent_EigenSolver(int n, const Vector4 * points, const float * weights, const Vector4 & metric);`

			`Vector3 computePrincipalComponent_SVD(int n, const Vector3 * points);`
			`Vector4 computePrincipalComponent_SVD(int n, const Vector4 * points);`

			`Plane bestPlane(int n, const Vector3 * points);`
			`bool isPlanar(int n, const Vector3 * points, float epsilon = NV_EPSILON);`

			`bool eigenSolveSymmetric3(const float matrix[6], float eigenValues[3], Vector3 eigenVectors[3]);`
			`bool eigenSolveSymmetric4(const float matrix[10], float eigenValues[4], Vector4 eigenVectors[4]);`

			`// Returns number of clusters [1-4].`
			`int compute4Means(int n, const Vector3 * points, const float * weights, const Vector3 & metric, Vector3 * cluster);`
			`}`

			`} // nv namespace`

			`#endif // NV_MATH_FITTING_H`