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LinearGridInterpolator3D Class Reference

#include <LinearGridInterpolator3D.h>

Public Types

typedef ValueType ReturnType
 
typedef Grid3D::Scalar Scalar
 
typedef Grid3D::ValueType ValueType
 

Public Member Functions

ReturnType interpolate (Scalar a, Scalar b, Scalar c)
 
 LinearGridInterpolator3D (const Grid3D &g)
 
void throwGridInterpolator3DException (void)
 

Private Attributes

const Grid3Dgrid
 
const Grid1Dgrida
 
const Grid1Dgridb
 
const Grid1Dgridc
 

Detailed Description

Linear interpolation in a regular 3D grid.

Author
T. Todorov

Definition at line 22 of file LinearGridInterpolator3D.h.

Member Typedef Documentation

◆ ReturnType

typedef ValueType LinearGridInterpolator3D::ReturnType

Definition at line 26 of file LinearGridInterpolator3D.h.

◆ Scalar

typedef Grid3D::Scalar LinearGridInterpolator3D::Scalar

Definition at line 25 of file LinearGridInterpolator3D.h.

◆ ValueType

typedef Grid3D::ValueType LinearGridInterpolator3D::ValueType

Definition at line 24 of file LinearGridInterpolator3D.h.

Constructor & Destructor Documentation

◆ LinearGridInterpolator3D()

LinearGridInterpolator3D::LinearGridInterpolator3D ( const Grid3D g)
inline

Definition at line 28 of file LinearGridInterpolator3D.h.

28 : grid(g), grida(g.grida()), gridb(g.gridb()), gridc(g.gridc()) {}

Member Function Documentation

◆ interpolate()

LinearGridInterpolator3D::ValueType LinearGridInterpolator3D::interpolate ( Scalar  a,
Scalar  b,
Scalar  c 
)

Definition at line 11 of file LinearGridInterpolator3D.cc.

11  {
12  /*
13  int i = grida.index(a);
14  int j = gridb.index(b);
15  int k = gridc.index(c);
16 
17  if (i==-1 || j==-1 || k==-1) {
18  // point outside of grid validity!
19  throwGridInterpolator3DException();
20  }
21 
22 
23  Scalar s = (a - grida.node(i)) / grida.step();
24  Scalar t = (b - gridb.node(j)) / gridb.step();
25  Scalar u = (c - gridc.node(k)) / gridc.step();
26 
27  */
28 
29  Scalar s, t, u;
30  int i = grida.index(a, s);
31  int j = gridb.index(b, t);
32  int k = gridc.index(c, u);
33 
34  // test range??
35 
36  grida.normalize(i, s);
37  gridb.normalize(j, t);
38  gridc.normalize(k, u);
39 
40 #ifdef DEBUG_LinearGridInterpolator3D
41  if (InterpolationDebug::debug) {
42  using std::cout;
43  using std::endl;
44  cout << "LinearGridInterpolator3D called with a,b,c " << a << "," << b << "," << c << endl;
45  cout << " i,j,k = " << i << "," << j << "," << k << " s,t,u = " << s << "," << t << "," << u << endl;
46  cout << "Node positions for " << i << "," << j << "," << k << " : " << grida.node(i) << "," << gridb.node(j) << ","
47  << gridc.node(k) << endl;
48  cout << "Node positions for " << i + 1 << "," << j + 1 << "," << k + 1 << " : " << grida.node(i + 1) << ","
49  << gridb.node(j + 1) << "," << gridc.node(k + 1) << endl;
50  cout << "Grid(" << i << "," << j << "," << k << ") = " << grid(i, j, k) << " ";
51  cout << "Grid(" << i << "," << j << "," << k + 1 << ") = " << grid(i, j, k + 1) << endl;
52  cout << "Grid(" << i << "," << j + 1 << "," << k << ") = " << grid(i, j + 1, k) << " ";
53  cout << "Grid(" << i << "," << j + 1 << "," << k + 1 << ") = " << grid(i, j + 1, k + 1) << endl;
54  cout << "Grid(" << i + 1 << "," << j << "," << k << ") = " << grid(i + 1, j, k) << " ";
55  cout << "Grid(" << i + 1 << "," << j << "," << k + 1 << ") = " << grid(i + 1, j, k + 1) << endl;
56  cout << "Grid(" << i + 1 << "," << j + 1 << "," << k << ") = " << grid(i + 1, j + 1, k) << " ";
57  cout << "Grid(" << i + 1 << "," << j + 1 << "," << k + 1 << ") = " << grid(i + 1, j + 1, k + 1) << endl;
58  cout << "number of nodes: " << grida.nodes() << "," << gridb.nodes() << "," << gridc.nodes() << endl;
59 
60  // cout << (1-s)*(1-t)*(1-u)*grid(i, j, k) << " " << (1-s)*(1-t)*u*grid(i, j, k+1) << endl
61  // << (1-s)* t *(1-u)*grid(i, j+1,k) << " " << (1-s)* t *u*grid(i, j+1,k+1) << endl
62  // << s *(1-t)*(1-u)*grid(i+1,j, k) << " " << s *(1-t)*u*grid(i+1,j, k+1) << endl
63  // << s * t *(1-u)*grid(i+1,j+1,k) << " " << s * t *u*grid(i+1,j+1,k+1) << endl;
64  }
65 
66 #endif
67 
68  int ind = grid.index(i, j, k);
69  int s1 = grid.stride1();
70  int s2 = grid.stride2();
71  int s3 = grid.stride3();
72  //chances are this is more numerically precise this way
73 
74  // this code for test to check properly inline of wrapped math...
75 #if defined(CMS_TEST_RAWSSE)
76 
77  __m128 resultSIMD =
78  _mm_mul_ps(_mm_set1_ps((1.f - s) * (1.f - t) * u), _mm_sub_ps(grid(ind + s3).v.vec, grid(ind).v.vec));
79  resultSIMD = _mm_add_ps(
80  resultSIMD,
81  _mm_mul_ps(_mm_set1_ps((1.f - s) * t * u), _mm_sub_ps(grid(ind + s2 + s3).v.vec, grid(ind + s2).v.vec)));
82  resultSIMD = _mm_add_ps(
83  resultSIMD,
84  _mm_mul_ps(_mm_set1_ps(s * (1.f - t) * u), _mm_sub_ps(grid(ind + s1 + s3).v.vec, grid(ind + s1).v.vec)));
85  resultSIMD = _mm_add_ps(
86  resultSIMD,
87  _mm_mul_ps(_mm_set1_ps(s * t * u), _mm_sub_ps(grid(ind + s1 + s2 + s3).v.vec, grid(ind + s1 + s2).v.vec)));
88  resultSIMD =
89  _mm_add_ps(resultSIMD, _mm_mul_ps(_mm_set1_ps((1.f - s) * t), _mm_sub_ps(grid(ind + s2).v.vec, grid(ind).v.vec)));
90  resultSIMD = _mm_add_ps(resultSIMD,
91  _mm_mul_ps(_mm_set1_ps(s * t), _mm_sub_ps(grid(ind + s1 + s2).v.vec, grid(ind + s1).v.vec)));
92  resultSIMD = _mm_add_ps(resultSIMD, _mm_mul_ps(_mm_set1_ps(s), _mm_sub_ps(grid(ind + s1).v.vec, grid(ind).v.vec)));
93  resultSIMD = _mm_add_ps(resultSIMD, grid(ind).v.vec);
94 
95  ValueType result;
96  result.v = resultSIMD;
97 
98 #else
99 
100  ValueType result = ((1.f - s) * (1.f - t) * u) * (grid(ind + s3) - grid(ind));
101  result = result + ((1.f - s) * t * u) * (grid(ind + s2 + s3) - grid(ind + s2));
102  result = result + (s * (1.f - t) * u) * (grid(ind + s1 + s3) - grid(ind + s1));
103  result = result + (s * t * u) * (grid(ind + s1 + s2 + s3) - grid(ind + s1 + s2));
104  result = result + ((1.f - s) * t) * (grid(ind + s2) - grid(ind));
105  result = result + (s * t) * (grid(ind + s1 + s2) - grid(ind + s1));
106  result = result + (s) * (grid(ind + s1) - grid(ind));
107  result = result + grid(ind);
108 
109 #endif
110 
111  // (1-s)*(1-t)*(1-u)*grid(i, j, k) + (1-s)*(1-t)*u*grid(i, j, k+1) +
112  // (1-s)* t *(1-u)*grid(i, j+1,k) + (1-s)* t *u*grid(i, j+1,k+1) +
113  // s *(1-t)*(1-u)*grid(i+1,j, k) + s *(1-t)*u*grid(i+1,j, k+1) +
114  // s * t *(1-u)*grid(i+1,j+1,k) + s * t *u*grid(i+1,j+1,k+1);
115 
116  return result;
117 }

References a, b, HltBtagPostValidation_cff::c, gather_cfg::cout, InterpolationDebug::debug, f, grid, grida, gridb, gridc, mps_fire::i, Grid1D::index(), Grid3D::index(), dqmiolumiharvest::j, dqmdumpme::k, Grid1D::node(), Grid1D::nodes(), Grid1D::normalize(), mps_fire::result, alignCSCRings::s, indexGen::s2, Grid3D::stride1(), Grid3D::stride2(), Grid3D::stride3(), OrderedSet::t, and findQualityFiles::v.

Referenced by RectangularCartesianMFGrid::uncheckedValueInTesla(), RectangularCylindricalMFGrid::uncheckedValueInTesla(), TrapezoidalCylindricalMFGrid::uncheckedValueInTesla(), SpecialCylindricalMFGrid::uncheckedValueInTesla(), and TrapezoidalCartesianMFGrid::uncheckedValueInTesla().

◆ throwGridInterpolator3DException()

void LinearGridInterpolator3D::throwGridInterpolator3DException ( void  )

Definition at line 6 of file LinearGridInterpolator3D.cc.

6  {
7  throw GridInterpolator3DException(
8  grida.lower(), gridb.lower(), gridc.lower(), grida.upper(), gridb.upper(), gridc.upper());
9 }

References grida, gridb, gridc, Grid1D::lower(), and Grid1D::upper().

Member Data Documentation

◆ grid

const Grid3D& LinearGridInterpolator3D::grid
private

Definition at line 36 of file LinearGridInterpolator3D.h.

Referenced by interpolate().

◆ grida

const Grid1D& LinearGridInterpolator3D::grida
private

Definition at line 37 of file LinearGridInterpolator3D.h.

Referenced by interpolate(), and throwGridInterpolator3DException().

◆ gridb

const Grid1D& LinearGridInterpolator3D::gridb
private

Definition at line 38 of file LinearGridInterpolator3D.h.

Referenced by interpolate(), and throwGridInterpolator3DException().

◆ gridc

const Grid1D& LinearGridInterpolator3D::gridc
private

Definition at line 39 of file LinearGridInterpolator3D.h.

Referenced by interpolate(), and throwGridInterpolator3DException().

mps_fire.i
i
Definition: mps_fire.py:355
LinearGridInterpolator3D::grid
const Grid3D & grid
Definition: LinearGridInterpolator3D.h:36
Grid3D::stride2
int stride2() const
Definition: Grid3D.h:53
f
double f[11][100]
Definition: MuScleFitUtils.cc:78
LinearGridInterpolator3D::ValueType
Grid3D::ValueType ValueType
Definition: LinearGridInterpolator3D.h:24
gather_cfg.cout
cout
Definition: gather_cfg.py:144
LinearGridInterpolator3D::gridb
const Grid1D & gridb
Definition: LinearGridInterpolator3D.h:38
Grid3D::index
int index(int i, int j, int k) const
Definition: Grid3D.h:51
Grid1D::nodes
int nodes() const
Definition: Grid1D.h:21
GridInterpolator3DException
Definition: MagExceptions.h:32
Grid1D::upper
Scalar upper() const
Definition: Grid1D.h:20
indexGen.s2
s2
Definition: indexGen.py:107
findQualityFiles.v
v
Definition: findQualityFiles.py:179
InterpolationDebug::debug
static const bool debug
Definition: InterpolationDebug.h:13
alignCSCRings.s
s
Definition: alignCSCRings.py:92
Grid1D::index
int index(Scalar a, Scalar &f) const
Definition: Grid1D.h:29
dqmdumpme.k
k
Definition: dqmdumpme.py:60
OrderedSet.t
t
Definition: OrderedSet.py:90
b
double b
Definition: hdecay.h:118
Grid3D::stride3
int stride3() const
Definition: Grid3D.h:54
LinearGridInterpolator3D::gridc
const Grid1D & gridc
Definition: LinearGridInterpolator3D.h:39
LinearGridInterpolator3D::grida
const Grid1D & grida
Definition: LinearGridInterpolator3D.h:37
a
double a
Definition: hdecay.h:119
LinearGridInterpolator3D::Scalar
Grid3D::Scalar Scalar
Definition: LinearGridInterpolator3D.h:25
HltBtagPostValidation_cff.c
c
Definition: HltBtagPostValidation_cff.py:31
Grid3D::stride1
int stride1() const
Definition: Grid3D.h:52
Grid1D::node
Scalar node(int i) const
Definition: Grid1D.h:24
mps_fire.result
result
Definition: mps_fire.py:303
dqmiolumiharvest.j
j
Definition: dqmiolumiharvest.py:66
Grid1D::normalize
void normalize(int &ind, Scalar &f) const
Definition: Grid1D.h:36
g
The Signals That Services Can Subscribe To This is based on ActivityRegistry and is current per Services can connect to the signals distributed by the ActivityRegistry in order to monitor the activity of the application Each possible callback has some defined which we here list in angle e g
Definition: Activities.doc:4
Grid1D::lower
Scalar lower() const
Definition: Grid1D.h:19
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