12 #pragma implementation
24 if (std::abs(x) <= 1.0)
return std::acos(x);
30 if (j == 0) {
return xx(); }
31 if (j == 1) {
return xy(); }
32 if (j == 2) {
return xz(); }
34 if (j == 0) {
return yx(); }
35 if (j == 1) {
return yy(); }
36 if (j == 2) {
return yz(); }
38 if (j == 0) {
return zx(); }
39 if (j == 1) {
return zy(); }
40 if (j == 2) {
return zz(); }
42 std::cerr <<
"HepRotation subscripting: bad indices "
43 <<
"(" << i <<
"," << j <<
")" << std::endl;
49 double ll = aaxis.
mag();
51 std::cerr <<
"HepRotation::rotate() - "
52 <<
"HepRotation: zero axis" << std::endl;
54 double sa = std::sin(a), ca = std::cos(a);
55 double dx = aaxis.
x()/ll, dy = aaxis.
y()/ll, dz = aaxis.
z()/ll;
57 ca+(1-ca)*dx*dx, (1-ca)*dx*dy-sa*dz, (1-ca)*dx*dz+sa*dy,
58 (1-ca)*dy*dx+sa*dz, ca+(1-ca)*dy*dy, (1-ca)*dy*dz-sa*dx,
59 (1-ca)*dz*dx-sa*dy, (1-ca)*dz*dy+sa*dx, ca+(1-ca)*dz*dz );
67 double c1 = std::cos(a);
68 double s1 = std::sin(a);
80 double c1 = std::cos(a);
81 double s1 = std::sin(a);
93 double c1 = std::cos(a);
94 double s1 = std::sin(a);
100 ryy = s1*y1 + c1*
ryy;
101 ryz = s1*z1 + c1*
ryz;
111 if (std::abs(newZ.
x()-w.
x()) > del ||
112 std::abs(newZ.
y()-w.
y()) > del ||
113 std::abs(newZ.
z()-w.
z()) > del ||
114 std::abs(newX.
mag2()-1.) > del ||
115 std::abs(newY.
mag2()-1.) > del ||
116 std::abs(newZ.
mag2()-1.) > del ||
117 std::abs(newX.
dot(newY)) > del ||
118 std::abs(newY.
dot(newZ)) > del ||
119 std::abs(newZ.
dot(newX)) > del) {
120 std::cerr <<
"HepRotation::rotateAxes: bad axis vectors" << std::endl;
124 newX.
y(), newY.
y(), newZ.
y(),
125 newX.
z(), newY.
z(), newZ.
z()));
130 return (
yx() == 0.0 &&
xx() == 0.0) ? 0.0 : std::atan2(
yx(),
xx());
134 return (
yy() == 0.0 &&
xy() == 0.0) ? 0.0 : std::atan2(
yy(),
xy());
138 return (
yz() == 0.0 &&
xz() == 0.0) ? 0.0 : std::atan2(
yz(),
xz());
154 double cosa = 0.5*(
xx()+
yy()+
zz()-1);
155 double cosa1 = 1-cosa;
160 double x=0,
y=0,
z=0;
161 if (
xx() > cosa) x = std::sqrt((
xx()-cosa)/cosa1);
162 if (
yy() > cosa)
y = std::sqrt((
yy()-cosa)/cosa1);
163 if (
zz() > cosa)
z = std::sqrt((
zz()-cosa)/cosa1);
164 if (
zy() <
yz()) x = -
x;
167 angle = (cosa < -1.) ? std::acos(-1.) : std::acos(cosa);
173 return (
rxx == 1.0 &&
rxy == 0.0 &&
rxz == 0.0 &&
174 ryx == 0.0 &&
ryy == 1.0 &&
ryz == 0.0 &&
175 rzx == 0.0 &&
rzy == 0.0 &&
rzz == 1.0) ?
true :
false;
180 else if (
rzy<r.
rzy)
return -1;
else if (
rzy>r.
rzy)
return 1;
181 else if (
rzx<r.
rzx)
return -1;
else if (
rzx>r.
rzx)
return 1;
182 else if (
ryz<r.
ryz)
return -1;
else if (
ryz>r.
ryz)
return 1;
183 else if (
ryy<r.
ryy)
return -1;
else if (
ryy>r.
ryy)
return 1;
184 else if (
ryx<r.
ryx)
return -1;
else if (
ryx>r.
ryx)
return 1;
185 else if (
rxz<r.
rxz)
return -1;
else if (
rxz>r.
rxz)
return 1;
186 else if (
rxy<r.
rxy)
return -1;
else if (
rxy>r.
rxy)
return 1;
187 else if (
rxx<r.
rxx)
return -1;
else if (
rxx>r.
rxx)
return 1;
std::vector< ExP01TrackerHit * > a
Float_t y1[n_points_granero]
static DLL_API const HepRotation IDENTITY
Float_t x1[n_points_granero]
double dot(const Hep3Vector &) const
int compare(const HepRotation &r) const
void getAngleAxis(double &delta, Hep3Vector &axis) const
static double safe_acos(double x)
double operator()(int, int) const
Hep3Vector cross(const Hep3Vector &) const
HepRotation & rotateY(double delta)
HepRotation & rotateZ(double delta)
HepRotation & rotate(double delta, const Hep3Vector &axis)
HepRotation & transform(const HepRotation &r)
HepRotation & rotateAxes(const Hep3Vector &newX, const Hep3Vector &newY, const Hep3Vector &newZ)
HepRotation & rotateX(double delta)
static constexpr double pi