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sketcherMinimizerMaths.h
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sketcherMinimizerMaths.h
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/*
* sketcherMinimizerMaths.h
*
*
* Created by Nicola Zonta on 15/3/2011.
* Copyright Schrodinger, LLC. All rights reserved
*
*/
#ifndef sketcherMINIMIZERMATHS_H
#define sketcherMINIMIZERMATHS_H
#include <cassert>
#include <cmath>
#include <iostream>
#include <cmath>
#include <vector>
#define MACROCYCLE 9 // smallest MACROCYCLE
#define BONDLENGTH 50
#define FRACTION_OF_BONDLENGTH_FOR_CLASH 0.25
#define SKETCHER_EPSILON 0.0001f
#ifndef M_PI
#define M_PI 3.1415926535897931
#endif
inline float roundToTwoDecimalDigits(float f)
{
return static_cast<float>(floor(f * 100 + 0.5) * 0.01);
}
inline float roundToPrecision(float f, int precision)
{
return static_cast<float>(floor(f * pow(10.f, precision) + 0.5) *
pow(0.1, precision));
}
/* class to represent a point or vector in 2d */
class sketcherMinimizerPointF
{
public:
sketcherMinimizerPointF() = default;
sketcherMinimizerPointF(const sketcherMinimizerPointF& p)
: xp(p.x()), yp(p.y())
{
}
sketcherMinimizerPointF(float xpos, float ypos) : xp(xpos), yp(ypos) {}
sketcherMinimizerPointF& operator=(const sketcherMinimizerPointF& p)
{
if (this != &p) {
xp = p.x();
yp = p.y();
}
return *this;
}
inline float x() const { return xp; }
inline float y() const { return yp; }
inline float& rx() { return xp; }
inline float& ry() { return yp; }
void setX(float x) { xp = x; }
void setY(float y) { yp = y; }
float squareLength() const
{
float dd = x() * x() + y() * y();
return dd;
}
/* return the length of the vector */
float length() const
{
float dd = squareLength();
if (dd > SKETCHER_EPSILON) {
return sqrt(dd);
} else {
return 0;
}
}
/* normalize the vector */
void normalize()
{
float q = length();
if (q > SKETCHER_EPSILON) {
xp /= q;
yp /= q;
}
}
/* rotate the vector by the angle with given sine and cosine */
void rotate(float s, float c)
{
float x = xp;
float y = yp;
xp = x * c + y * s;
yp = -x * s + y * c;
}
/* parallel component of this along the give axis */
sketcherMinimizerPointF
parallelComponent(const sketcherMinimizerPointF& axis)
{
float dotProduct = x() * axis.x() + y() * axis.y();
return axis * dotProduct / axis.squareLength();
}
/* round the coordinates to the given number of decimal figures */
void round(int precision = 2)
{
if (precision == 2) {
xp = roundToTwoDecimalDigits(xp);
yp = roundToTwoDecimalDigits(yp);
} else {
xp = roundToPrecision(xp, precision);
yp = roundToPrecision(yp, precision);
}
}
sketcherMinimizerPointF& operator+=(const sketcherMinimizerPointF& p)
{
xp += p.xp;
yp += p.yp;
return *this;
}
sketcherMinimizerPointF& operator-=(const sketcherMinimizerPointF& p)
{
xp -= p.xp;
yp -= p.yp;
return *this;
}
template <typename T> sketcherMinimizerPointF& operator*=(T c)
{
xp *= static_cast<float>(c);
yp *= static_cast<float>(c);
return *this;
}
template <typename T> sketcherMinimizerPointF& operator/=(T c)
{
xp /= static_cast<float>(c);
yp /= static_cast<float>(c);
return *this;
}
// friend inline bool operator==(const sketcherMinimizerPointF &p1, const
// sketcherMinimizerPointF &p2) ;
// friend inline bool operator!=(const sketcherMinimizerPointF &, const
// sketcherMinimizerPointF &);
inline friend std::ostream& operator<<(std::ostream& out,
sketcherMinimizerPointF& point)
{
out << "(" << point.xp << ", " << point.yp << ")";
return out;
}
friend inline const sketcherMinimizerPointF
operator+(const sketcherMinimizerPointF& p1,
const sketcherMinimizerPointF& p2)
{
return sketcherMinimizerPointF(p1.xp + p2.xp, p1.yp + p2.yp);
}
friend inline const sketcherMinimizerPointF
operator-(const sketcherMinimizerPointF& p1,
const sketcherMinimizerPointF& p2)
{
return sketcherMinimizerPointF(p1.xp - p2.xp, p1.yp - p2.yp);
}
friend inline const sketcherMinimizerPointF
operator*(float c, const sketcherMinimizerPointF& p1)
{
return sketcherMinimizerPointF(p1.xp * c, p1.yp * c);
}
template <typename T>
friend inline const sketcherMinimizerPointF
operator*(const sketcherMinimizerPointF& p1, T c)
{
auto cf = static_cast<float>(c);
return sketcherMinimizerPointF(p1.xp * cf, p1.yp * cf);
}
template <typename T>
friend inline const sketcherMinimizerPointF
operator/(const sketcherMinimizerPointF& p1, T c)
{
auto cf = static_cast<float>(c);
return sketcherMinimizerPointF(p1.xp / cf, p1.yp / cf);
}
friend inline const sketcherMinimizerPointF
operator-(const sketcherMinimizerPointF& p1)
{
return sketcherMinimizerPointF(-p1.xp, -p1.yp);
}
// friend inline const sketcherMinimizerPointF operator/(const
// sketcherMinimizerPointF &, float);
private:
float xp{0.f};
float yp{0.f};
};
/* return true if the two segments intersect and if a result pointer was given,
* set it to the intersection point */
struct sketcherMinimizerMaths {
static bool
intersectionOfSegments(const sketcherMinimizerPointF& s1p1,
const sketcherMinimizerPointF& s1p2,
const sketcherMinimizerPointF& s2p1,
const sketcherMinimizerPointF& s2p2,
sketcherMinimizerPointF* result = nullptr)
{
/*
Suppose the two line segments run from p to p + r and from q to
q + s. Then any point on the first line is representable as p + t r
(for a scalar parameter t) and any point on the second line as q + u
s (for a scalar parameter u).
The two lines intersect if we can find t and u such that:
p + t r = q + u s
Cross both sides with s, getting
(p + t r) × s = (q + u s) × s
And since s × s = 0, this means
t (r × s) = (q − p) × s
And therefore, solving for t:
t = (q − p) × s / (r × s)
In the same way, we can solve for u:
(p + t r) × r = (q + u s) × r
u (s × r) = (p − q) × r
u = (p − q) × r / (s × r)
To reduce the number of computation steps, it's
convenient to rewrite this as follows (remembering that s × r = − r ×
s):
u = (q − p) × r / (r × s)
Now there are five cases:
If r × s = 0 and (q − p) × r = 0, then the two
lines are collinear. If in addition, either 0 ≤ (q − p) · r ≤ r · r
or 0 ≤ (p − q) · s ≤ s · s, then the two lines are overlapping.
If r × s = 0 and (q − p) × r = 0, but neither 0
≤ (q − p) · r ≤ r · r nor 0 ≤ (p − q) · s ≤ s · s, then the two lines
are collinear but disjoint.
If r × s = 0 and (q − p) × r ≠ 0, then the two
lines are parallel and non-intersecting.
If r × s ≠ 0 and 0 ≤ t ≤ 1 and 0 ≤ u ≤ 1, the
two line segments meet at the point p + t r = q + u s.
Otherwise, the two line segments are not
parallel but do not intersect.
*/
const sketcherMinimizerPointF& p = s1p1;
sketcherMinimizerPointF r = s1p2 - s1p1;
const sketcherMinimizerPointF& q = s2p1;
sketcherMinimizerPointF s = s2p2 - s2p1;
float rxs = crossProduct(r, s);
if (rxs > -SKETCHER_EPSILON &&
rxs < SKETCHER_EPSILON) { // parallel lines
return false;
}
sketcherMinimizerPointF qminusp = q - p;
float t = crossProduct(qminusp, s) / rxs;
if (t < 0 || t > 1) {
return false;
}
float u = crossProduct(qminusp, r) / rxs;
if (u < 0 || u > 1) {
return false;
}
if (result) {
*result = p + t * r;
}
return true;
}
/* signed angle between p1p2 and p2p3 */
static float signedAngle(const sketcherMinimizerPointF& p1,
const sketcherMinimizerPointF& p2,
const sketcherMinimizerPointF& p3)
{
sketcherMinimizerPointF v1 = p1 - p2;
sketcherMinimizerPointF v2 = p3 - p2;
return float(atan2(v1.x() * v2.y() - v1.y() * v2.x(),
v1.x() * v2.x() + v1.y() * v2.y()) *
180 / M_PI);
}
/* unsigned angle between p1p2 and p2p3 */
static float unsignedAngle(const sketcherMinimizerPointF& p1,
const sketcherMinimizerPointF& p2,
const sketcherMinimizerPointF& p3)
{
float x1 = p1.x();
float y1 = p1.y();
float x2 = p2.x();
float y2 = p2.y();
float x3 = p3.x();
float y3 = p3.y();
float v1x = x1 - x2;
float v1y = y1 - y2;
float v2x = x3 - x2;
float v2y = y3 - y2;
float d = sqrt(v1x * v1x + v1y * v1y) * sqrt(v2x * v2x + v2y * v2y);
if (d < SKETCHER_EPSILON) {
d = SKETCHER_EPSILON;
}
float cosine = (v1x * v2x + v1y * v2y) / d;
if (cosine < -1) {
cosine = -1;
} else if (cosine > 1) {
cosine = 1;
}
return float((acos(cosine)) * 180 / M_PI);
}
/* return true if the two points are very close in space */
static bool pointsCoincide(const sketcherMinimizerPointF& p1,
const sketcherMinimizerPointF& p2)
{
return ((p1 - p2).squareLength() < SKETCHER_EPSILON * SKETCHER_EPSILON);
}
/* return true if p1 and p2 are in the same semiplane defined by the given
* segment */
static bool sameSide(const sketcherMinimizerPointF& p1,
const sketcherMinimizerPointF& p2,
const sketcherMinimizerPointF& lineP1,
const sketcherMinimizerPointF& lineP2)
{
float x = lineP2.x() - lineP1.x();
float y = lineP2.y() - lineP1.y();
// ///cerr << "("<<p1.x()<<","<<p1.y()<<") ("<<p2.x
// ()<<","<<p2.y()<<") ("<<lineP1.x()<<","<<lineP1.y()<<")
// ("<<lineP2.x ()<<","<<lineP2.y()<<")"<<endl;
if (fabs(float(x)) > fabs((y))) { // what about q?
float m = y / x;
float d1 = p1.y() - lineP1.y() - m * (p1.x() - lineP1.x());
float d2 = p2.y() - lineP1.y() - m * (p2.x() - lineP1.x());
return (d2 * d1 > 0);
} else {
float m = x / y;
float d1 = p1.x() - lineP1.x() - m * (p1.y() - lineP1.y());
float d2 = p2.x() - lineP1.x() - m * (p2.y() - lineP1.y());
return (d2 * d1 > 0);
}
}
/* return the projection of p on the line defined by the given segment */
static sketcherMinimizerPointF
projectPointOnLine(const sketcherMinimizerPointF& p,
const sketcherMinimizerPointF& sp1,
const sketcherMinimizerPointF& sp2)
{
sketcherMinimizerPointF l1 = p - sp1;
sketcherMinimizerPointF l3 = sp2 - sp1;
float segmentl2 = l3.squareLength();
if (segmentl2 < SKETCHER_EPSILON) {
segmentl2 = SKETCHER_EPSILON;
}
float t = sketcherMinimizerMaths::dotProduct(l1, l3) / segmentl2;
return sp1 + t * l3;
}
/* squared distance of the given point from the given segment */
static float squaredDistancePointSegment(const sketcherMinimizerPointF& p,
const sketcherMinimizerPointF& sp1,
const sketcherMinimizerPointF& sp2,
float* returnT = nullptr)
{
sketcherMinimizerPointF l1 = p - sp1;
sketcherMinimizerPointF l2 = sp2 - p;
sketcherMinimizerPointF l3 = sp2 - sp1;
float segmentl2 = l3.x() * l3.x() + l3.y() * l3.y();
// float l1l = sqrt ( l1.x () * l1.x () + l1.y() * l1.y() );
if (segmentl2 < SKETCHER_EPSILON) {
segmentl2 = SKETCHER_EPSILON;
}
float t = (l1.x() * l3.x() + l1.y() * l3.y()) / segmentl2;
if (returnT != nullptr) {
if (t < 0) {
*returnT = 0;
} else if (t > 1) {
*returnT = 1;
} else {
*returnT = t;
}
}
float squaredistance = 0.f;
if (t < 0.f) {
squaredistance = l1.x() * l1.x() + l1.y() * l1.y();
} else if (t > 1.f) {
squaredistance = l2.x() * l2.x() + l2.y() * l2.y();
} else {
sketcherMinimizerPointF proj = sp1 + t * l3;
sketcherMinimizerPointF l5 = p - proj;
squaredistance = l5.x() * l5.x() + l5.y() * l5.y();
}
if (squaredistance < SKETCHER_EPSILON) {
squaredistance = SKETCHER_EPSILON;
}
return squaredistance;
}
static float squaredDistance(const sketcherMinimizerPointF& p1,
const sketcherMinimizerPointF& p2)
{
return (p1.x() - p2.x()) * (p1.x() - p2.x()) +
(p1.y() - p2.y()) * (p1.y() - p2.y());
}
static std::vector<float> tridiagonalSolve(const std::vector<float>& a,
const std::vector<float>& b,
const std::vector<float>& c,
const std::vector<float>& rhs)
{
assert(a.size() == b.size() && a.size() == c.size() &&
a.size() == rhs.size());
assert(b[0] != 0.f);
auto n = static_cast<unsigned int>(rhs.size());
std::vector<float> u(n);
std::vector<float> gam(n);
float bet = b[0];
u[0] = rhs[0] / bet;
for (unsigned int j = 1; j < n; j++) {
gam[j] = c[j - 1] / bet;
bet = b[j] - a[j] * gam[j];
assert(bet != 0.f);
u[j] = (rhs[j] - a[j] * u[j - 1]) / bet;
}
for (unsigned int j = 1; j < n; j++) {
u[n - j - 1] -= gam[n - j] * u[n - j];
}
return u;
}
/* used by ClosedBezierControlPoints */
static std::vector<float> cyclicSolve(const std::vector<float>& a,
const std::vector<float>& b,
const std::vector<float>& c,
float alpha, float beta,
const std::vector<float>& rhs)
{
assert(a.size() == b.size() && a.size() == c.size());
auto n = static_cast<unsigned int>(b.size());
assert(n > 2);
float gamma = -b[0]; // Avoid subtraction error in forming bb[0].
// Set up the diagonal of the modified tridiagonal system.
std::vector<float> bb(n);
bb[0] = b[0] - gamma;
bb[n - 1] = b[n - 1] - alpha * beta / gamma;
for (unsigned int i = 1; i < n - 1; i++) {
bb[i] = b[i];
}
// Solve A · x = rhs.
std::vector<float> solution = tridiagonalSolve(a, bb, c, rhs);
std::vector<float> x = solution;
// Set up the vector u.
std::vector<float> u(n);
u[0] = gamma;
u[n - 1] = alpha;
for (unsigned int i = 1; i < n - 1; i++) {
u[i] = 0.f;
}
// Solve A · z = u.
solution = tridiagonalSolve(a, bb, c, u);
std::vector<float> z = solution;
// Form v · x/(1 + v · z).
double fact = (x[0] + beta * x[n - 1] / gamma) /
(1.f + z[0] + beta * z[n - 1] / gamma);
// Now get the solution vector x.
for (unsigned int i = 0; i < n; i++) {
x[i] -= float(fact * z[i]);
}
return x;
}
static sketcherMinimizerPointF
pointOnCubicBezier(const sketcherMinimizerPointF& p1,
const sketcherMinimizerPointF& cp1,
const sketcherMinimizerPointF& cp2,
const sketcherMinimizerPointF& p2, float t)
{
// using Casteljiau's algorithm
auto v1 = (1 - t) * p1 + t * cp1;
auto v2 = (1 - t) * cp1 + t * cp2;
auto v3 = (1 - t) * cp2 + t * p2;
auto v4 = (1 - t) * v1 + t * v2;
auto v5 = (1 - t) * v2 + t * v3;
return (1 - t) * v4 + t * v5;
}
/* find control points to a closed Bezier curve that passes through the
* given points */
static void ClosedBezierControlPoints(
const std::vector<sketcherMinimizerPointF>& knots,
std::vector<sketcherMinimizerPointF>& firstControlPoints,
std::vector<sketcherMinimizerPointF>& secondControlPoints)
{
auto n = static_cast<unsigned int>(knots.size());
if (n <= 2) {
return;
}
// Calculate first Bezier control points
std::vector<float> a(n), b(n), c(n);
for (unsigned int i = 0; i < n; i++) {
a[i] = 1;
b[i] = 4;
c[i] = 1;
}
std::vector<float> rhs(n);
for (unsigned int i = 0; i < n; i++) {
int j = i + 1;
if (j > int(n - 1)) {
j = 0;
}
rhs[i] = 4 * knots[i].x() + 2 * knots[j].x();
}
// Solve the system for X.
std::vector<float> x = cyclicSolve(a, b, c, 1, 1, rhs);
for (unsigned int i = 0; i < n; i++) {
int j = i + 1;
if (j > int(n - 1)) {
j = 0;
}
rhs[i] = 4 * knots[i].y() + 2 * knots[j].y();
}
// Solve the system for Y.
std::vector<float> y = cyclicSolve(a, b, c, 1, 1, rhs);
// Fill output arrays.
firstControlPoints.resize(n);
secondControlPoints.resize(n);
for (unsigned int i = 0; i < n; i++) {
firstControlPoints[i] = sketcherMinimizerPointF(x[i], y[i]);
secondControlPoints[i] = sketcherMinimizerPointF(
2 * knots[i].x() - x[i], 2 * knots[i].y() - y[i]);
}
}
/* return the mirror image of the given point wrt the given segment */
static sketcherMinimizerPointF
mirrorPoint(const sketcherMinimizerPointF& point,
const sketcherMinimizerPointF& segmentPoint1,
const sketcherMinimizerPointF& segmentPoint2)
{
sketcherMinimizerPointF segmentV = segmentPoint2 - segmentPoint1;
sketcherMinimizerPointF v2 = point - segmentPoint1;
sketcherMinimizerPointF parallelComponent =
v2.parallelComponent(segmentV);
sketcherMinimizerPointF normalComponent = v2 - parallelComponent;
return segmentPoint1 + parallelComponent - normalComponent;
}
/* dot product of two vectors */
static float dotProduct(const sketcherMinimizerPointF& a,
const sketcherMinimizerPointF& b)
{
return (a.x() * b.x() + a.y() * b.y());
}
/* cross product of two vectors */
static float crossProduct(const sketcherMinimizerPointF& a,
const sketcherMinimizerPointF& b)
{
return (a.x() * b.y() - a.y() * b.x());
}
static float cannonBallDistance(float originX, float originY, float originZ,
float directionX, float directionY,
float directionZ, float targetX,
float targetY, float targetZ, float ballR,
float targetR, float cutOff = 4.f)
// how far can a cannonball of radius ballR shot from origin travel befor
// hitting a target ball of targetR radius
{
// assume that direction is normalized
float targetdX = targetX - originX;
float targetdY = targetY - originY;
float targetdZ = targetZ - originZ;
float rR = ballR + targetR;
float d2 = (targetdX * targetdX) + (targetdY * targetdY) +
(targetdZ * targetdZ);
if (d2 > (cutOff + rR) * (cutOff + rR)) {
return cutOff;
}
if (d2 < rR * rR) {
return 0;
}
float d = sqrt(d2);
if (d > SKETCHER_EPSILON) {
targetdX /= d;
targetdY /= d;
targetdZ /= d;
}
float cos = targetdX * directionX + targetdY * directionY +
targetdZ * directionZ;
if (cos < 0) {
return cutOff;
}
float sin = sqrt(1 - (cos * cos));
float f = d * sin;
if (f > rR) {
return cutOff;
}
float result = sqrt(d2 - (f * f)) - sqrt((rR * rR) - (f * f));
if (result > cutOff) {
return cutOff;
}
return result;
}
/* length of a 3d vector */
static float length3D(float x, float y, float z)
{
float m = x * x + y * y + z * z;
if (m > SKETCHER_EPSILON) {
m = sqrt(m);
}
return m;
}
/* dot product of two 3d vectors */
static float dotProduct3D(float x1, float y1, float z1, float x2, float y2,
float z2)
{
return x1 * x2 + y1 * y2 + z1 * z2;
}
/* cross product of two 3d vectors */
static void crossProduct3D(float x1, float y1, float z1, float x2, float y2,
float z2, float& xr, float& yr, float& zr)
{
xr = y1 * z2 - z1 * y2;
yr = z1 * x2 - x1 * z2;
zr = x1 * y2 - y1 * x2;
}
static float distance3D(float x1, float y1, float z1, float x2, float y2,
float z2)
{
return length3D(x2 - x1, y2 - y1, z2 - z1);
}
/* angle between two 3d vectors */
static float angle3D(float x1, float y1, float z1, float x2, float y2,
float z2, float x3, float y3, float z3)
{
float xa = x1 - x2;
float ya = y1 - y2;
float za = z1 - z2;
float xb = x3 - x2;
float yb = y3 - y2;
float zb = z3 - z2;
float l1 = length3D(xa, ya, za);
float l2 = length3D(xb, yb, zb);
float dp = dotProduct3D(xa, ya, za, xb, yb, zb);
return static_cast<float>(acos(dp / (l1 * l2)) * 180.f / M_PI);
}
/* dihedral angle defined by 4 3d points */
static float dihedral3D(float x1, float y1, float z1, float x2, float y2,
float z2, float x3, float y3, float z3, float x4,
float y4, float z4)
{
float xa, ya, za;
crossProduct3D(x1 - x2, y1 - y2, z1 - z2, x3 - x2, y3 - y2, z3 - z2, xa,
ya, za);
float xb, yb, zb;
crossProduct3D(x2 - x3, y2 - y3, z2 - z3, x4 - x3, y4 - y3, z4 - z3, xb,
yb, zb);
return angle3D(xa, ya, za, 0, 0, 0, xb, yb, zb);
}
}; // struct sketcherMinimizerMaths
#endif // sketcherMINIMIZERMATHS_H