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TrackerShapeToBounds.cc
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5 #include "CLHEP/Units/GlobalSystemOfUnits.h"
6 #include <algorithm>
7 #include <iostream>
8 //#define DEBUG
9 
10 /* find out about the rotations of the detectors:
11 
12  (the code should also find out about other detector-types (pixes-fw, ...)
13  currently not implemented, of course)
14 
15  - for pixel-barrels:
16  detectors are modelled by boxes, ORCA convention for the local frame:
17  . the thickness is in global r-direction of global-CMS
18  . the longer side if in z-direction of global-CMS
19  . the shorter side is in phi-direction of global-CMS
20  ORCA convention of the local-frame:
21  . the local z-axis is defined to be in direction of the thickness of the box
22  . the local y-axis is defined to be in direction of the longer side of the box
23  . the local x-axis is thus in direction of the shorter side of the box
24 
25  1. So first look how the detector box is defined in DDD (which axis direction
26  is the thickness, which axis-direction is the shorter side,...)
27  2. Define a rotation which reorientates the box to Orca-conventions
28  in the local frame, if necessary
29  3. combine the global rotation from DDD with the rotation defined in 2.
30  */
31 
32 Bounds* TrackerShapeToBounds::buildBounds(const cms::DDSolidShape& shape, const std::vector<double>& par) const {
33  switch (shape) {
35  return buildBox(par);
36  break;
38  return buildTrap(par);
39  break;
43  return buildOpen();
44  break;
45  default:
46  std::cout << "Wrong DDshape to build...." << cms::dd::name(cms::DDSolidShapeMap, shape) << std::endl;
47  Bounds* bounds = nullptr;
48  return bounds;
49  }
50 }
51 
52 Bounds* TrackerShapeToBounds::buildBox(const std::vector<double>& paras) const {
53  int indexX = 0;
54  int indexY = 1;
55  int indexZ = 2;
56  Bounds* bounds = nullptr;
57 
58  if (paras[1] < paras[0] && paras[0] < paras[2]) {
59  indexX = 0;
60  indexY = 2;
61  indexZ = 1;
62  }
63 
64  bounds = new RectangularPlaneBounds(paras[indexX] / cm, // width - shorter side
65  paras[indexY] / cm, // length - longer side
66  paras[indexZ] / cm); // thickness
67  return bounds;
68 }
69 
70 Bounds* TrackerShapeToBounds::buildTrap(const std::vector<double>& paras) const {
71  Bounds* bounds = nullptr;
72  /*
73  TrapezoidalPlaneBounds (float be, float te, float a, float t)
74  constructed from:
75  half bottom edge (smaller side width)
76  half top edge (larger side width)
77  half apothem (distance from top to bottom sides, measured perpendicularly to them)
78  half thickness.
79 
80  if we have indexX=0, indexY=1 and indeZ=2
81  4 = be (ORCA x)
82  9 = te (ORCA x)
83  0 = a (ORCA y)
84  3 = t (ORCA z)
85 
86  if we have indexX=0, indexY=2 and indeZ=1
87  4 = be (ORCA x)
88  9 = te (ORCA x)
89  3 = a (ORCA y)
90  0 = t (ORCA z)
91 
92  so, so we have the indexes:
93  if indexX==0, indexY==1, indexZ==2, then everything is ok and
94  the following orcaCorrection-rotation will be a unit-matrix.
95  */
96 
97  if (paras[0] < 5) {
98  bounds = new TrapezoidalPlaneBounds(paras[4] / cm, paras[9] / cm, paras[3] / cm, paras[0] / cm);
99  } else if (paras[0] > paras[3]) {
100  bounds = new TrapezoidalPlaneBounds(paras[4] / cm, paras[9] / cm, paras[0] / cm, paras[3] / cm);
101  }
102  return bounds;
103 }
104 
106  OpenBounds* bounds = new OpenBounds();
107  return bounds;
108 }
Bounds * buildOpen() const
std::string name(Mapping a, V value)
Definition: DDSolidShapes.h:31
Bounds * buildTrap(const std::vector< double > &) const
const std::array< const cms::dd::NameValuePair< DDSolidShape >, 21 > DDSolidShapeMap
Definition: DDSolidShapes.h:99
Bounds * buildBox(const std::vector< double > &) const
Bounds * buildBounds(const cms::DDSolidShape &, const std::vector< double > &) const
Unlimited (trivial) bounds.
Definition: OpenBounds.h:9
tuple cout
Definition: gather_cfg.py:144
Definition: Bounds.h:18
DDSolidShape
Definition: DDSolidShapes.h:73