// David Eberly, Geometric Tools, Redmond WA 98052
// Copyright (c) 1998-2020
// Distributed under the Boost Software License, Version 1.0.
// https://www.boost.org/LICENSE_1_0.txt
// https://www.geometrictools.com/License/Boost/LICENSE_1_0.txt
// Version: 4.0.2019.08.13
#pragma once
#include <Mathematics/DCPQuery.h>
#include <Mathematics/LCPSolver.h>
#include <Mathematics/AlignedBox.h>
#include <Mathematics/Triangle.h>
#include <Mathematics/Vector3.h>
// Compute the distance between a triangle and an aligned box in 3D. The
// algorithm is based on using an LCP solver for the convex quadratic
// programming problem. For details, see
// https://www.geometrictools.com/Documentation/ConvexQuadraticProgramming.pdf
namespace WwiseGTE
{
template <typename Real>
class DCPQuery<Real, Triangle3<Real>, AlignedBox3<Real>>
{
public:
struct Result
{
bool queryIsSuccessful;
// These members are valid only when queryIsSuccessful is true;
// otherwise, they are all set to zero.
Real distance, sqrDistance;
std::array<Real, 3> triangleParameter, boxParameter;
Vector3<Real> closestPoint[2];
// The number of iterations used by LCPSolver regardless of
// whether the query is successful.
int numLCPIterations;
};
// The default maximum iterations is 81 (n = 9, maxIterations = n*n).
// If the solver fails to converge, try increasing the maximum number
// of iterations.
void SetMaxLCPIterations(int maxLCPIterations)
{
mLCP.SetMaxIterations(maxLCPIterations);
}
Result operator()(Triangle3<Real> const& triangle, AlignedBox3<Real> const& box)
{
Result result;
// Translate the triangle and aligned box so that the aligned box
// becomes a canonical box.
Vector3<Real> K = box.max - box.min;
Vector3<Real> V = triangle.v[0] - box.min;
Vector3<Real> E0 = triangle.v[1] - triangle.v[0];
Vector3<Real> E1 = triangle.v[2] - triangle.v[0];
// Compute quantities to initialize q and M in the LCP.
Real dotVE0 = Dot(V, E0);
Real dotVE1 = Dot(V, E1);
Real dotE0E0 = Dot(E0, E0);
Real dotE0E1 = Dot(E0, E1);
Real dotE1E1 = Dot(E1, E1);
// The LCP has 5 variables and 4 (nontrivial) inequality
// constraints.
std::array<Real, 9> q =
{
-V[0], -V[1], -V[2], dotVE0, dotVE1, K[0], K[1], K[2], (Real)1
};
std::array<std::array<Real, 9>, 9> M;
M[0] = { (Real)1, (Real)0, (Real)0, -E0[0], -E1[0], (Real)1, (Real)0, (Real)0, (Real)0 };
M[1] = { (Real)0, (Real)1, (Real)0, -E0[1], -E1[1], (Real)0, (Real)1, (Real)0, (Real)0 };
M[2] = { (Real)0, (Real)0, (Real)1, -E0[2], -E1[2], (Real)0, (Real)0, (Real)1, (Real)0 };
M[3] = { -E0[0], -E0[1], -E0[2], dotE0E0, dotE0E1, (Real)0, (Real)0, (Real)0, (Real)1 };
M[4] = { -E1[0], -E1[1], -E1[2], dotE0E1, dotE1E1, (Real)0, (Real)0, (Real)0, (Real)1 };
M[5] = { (Real)-1, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0 };
M[6] = { (Real)0, (Real)-1, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0 };
M[7] = { (Real)0, (Real)0, (Real)-1, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0, (Real)0 };
M[8] = { (Real)0, (Real)0, (Real)0, (Real)-1, (Real)-1, (Real)0, (Real)0, (Real)0, (Real)0 };
std::array<Real, 9> w, z;
if (mLCP.Solve(q, M, w, z))
{
result.queryIsSuccessful = true;
result.triangleParameter[0] = (Real)1 - z[3] - z[4];
result.triangleParameter[1] = z[3];
result.triangleParameter[2] = z[4];
result.closestPoint[0] = triangle.v[0] + z[3] * E0 + z[4] * E1;
for (int i = 0; i < 3; ++i)
{
result.boxParameter[i] = z[i] + box.min[i];
result.closestPoint[1][i] = result.boxParameter[i];
}
Vector3<Real> diff = result.closestPoint[1] - result.closestPoint[0];
result.sqrDistance = Dot(diff, diff);
result.distance = std::sqrt(result.sqrDistance);
}
else
{
// If you reach this case, the maximum number of iterations
// was not specified to be large enough or there is a problem
// due to floating-point rounding errors. If you believe the
// latter is true, file a bug report.
result.queryIsSuccessful = false;
for (int i = 0; i < 3; ++i)
{
result.triangleParameter[i] = (Real)0;
result.boxParameter[i] = (Real)0;
result.closestPoint[0][i] = (Real)0;
result.closestPoint[1][i] = (Real)0;
}
result.distance = (Real)0;
result.sqrDistance = (Real)0;
}
result.numLCPIterations = mLCP.GetNumIterations();
return result;
}
private:
LCPSolver<Real, 9> mLCP;
};
}