/usr/include/Field3D/FieldSampler.h is in libfield3d-dev 1.7.2-1+b2.
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#ifndef __F3DUTIL_FIELDSAMPLER_H__
#define __F3DUTIL_FIELDSAMPLER_H__
//------------------------------------------------------------------------------
// Project includes
#include "Types.h"
//----------------------------------------------------------------------------//
#include "ns.h"
FIELD3D_NAMESPACE_OPEN
//------------------------------------------------------------------------------
// detail namespace
//------------------------------------------------------------------------------
namespace detail {
//! Min operation on mixed types
template <typename T, typename T2>
T min(const T a, const T2 b)
{
return std::min(a, static_cast<T>(b));
}
//! Max operation on mixed types
template <typename T, typename T2>
T max(const T a, const T2 b)
{
return std::max(a, static_cast<T>(b));
}
//! Min operation on mixed vector types
template <typename T, typename T2>
FIELD3D_VEC3_T<T> min(const FIELD3D_VEC3_T<T> &a,
const FIELD3D_VEC3_T<T2> &b)
{
return FIELD3D_VEC3_T<T>(std::min(a.x, static_cast<T>(b.x)),
std::min(a.y, static_cast<T>(b.y)),
std::min(a.z, static_cast<T>(b.z)));
}
//! Max operation on mixed vector types
template <typename T, typename T2>
FIELD3D_VEC3_T<T> max(const FIELD3D_VEC3_T<T> &a,
const FIELD3D_VEC3_T<T2> &b)
{
return FIELD3D_VEC3_T<T>(std::max(a.x, static_cast<T>(b.x)),
std::max(a.y, static_cast<T>(b.y)),
std::max(a.z, static_cast<T>(b.z)));
}
//! Typedefs float or V3f, depending on Dims_T
template <int Dims_T>
struct ScalarOrVector;
template <>
struct ScalarOrVector<1>
{
typedef float type;
};
template <>
struct ScalarOrVector<3>
{
typedef V3f type;
};
}
//------------------------------------------------------------------------------
// FieldSampler
//------------------------------------------------------------------------------
//! Interface for sampling a vector of fields of the same type
template <typename WrapperVec_T, int Dims_T>
struct FieldSampler
{
enum Mode {
Min,
Max
};
typedef typename WrapperVec_T::value_type::field_type Field_T;
typedef typename Field_T::value_type Data_T;
typedef typename detail::ScalarOrVector<Dims_T>::type Input_T;
// Ordinary fields
static void sample(const WrapperVec_T &f, const V3d &wsP, float *value,
size_t &numHits)
{
// Reinterpret the pointer according to Dims_T
Input_T *data = reinterpret_cast<Input_T*>(value);
// Loop over fields in vector
for (size_t i = 0, end = f.size(); i < end; ++i) {
V3d vsP;
// Apply world to object transform
if (f[i].doOsToWs) {
V3d osP;
f[i].wsToOs.multVecMatrix(wsP, osP);
f[i].mapping->worldToVoxel(osP, vsP);
} else {
f[i].mapping->worldToVoxel(wsP, vsP);
}
// Sample
if (f[i].vsBounds.intersects(vsP)) {
// Count as within field
numHits++;
// Sample and remap
if (f[i].valueRemapOp) {
const Data_T unremapped = f[i].interp.sample(*f[i].field, vsP);
*data += f[i].valueRemapOp->remap(unremapped);
} else {
*data += f[i].interp.sample(*f[i].field, vsP);
}
}
}
}
// Ordinary fields
static void sampleMultiple(const WrapperVec_T &f, const size_t neval,
const float *wsPs, float *value, size_t *numHits)
{
// Loop over fields in vector
for (size_t i = 0; i < f.size(); ++i) {
const typename WrapperVec_T::value_type &field = f[i];
// Reinterpret the pointer according to Dims_T
Input_T *data = reinterpret_cast<Input_T*>(value);
if (field.doOsToWs || field.valueRemapOp) {
// Loop over samples
for (size_t ieval = 0; ieval < neval; ++ieval) {
const V3d wsP(*reinterpret_cast<const V3f*>(wsPs + 3 * ieval));
V3d vsP;
// Apply world to object transform
if (field.doOsToWs) {
V3d osP;
field.wsToOs.multVecMatrix(wsP, osP);
field.mapping->worldToVoxel(osP, vsP);
} else {
field.mapping->worldToVoxel(wsP, vsP);
}
// Sample
if (field.vsBounds.intersects(vsP)) {
// Count as within field
numHits[ieval]++;
// Sample and remap
if (field.valueRemapOp) {
const Data_T unremapped = field.interp.sample(*field.field, vsP);
data[ieval] += field.valueRemapOp->remap(unremapped);
} else {
data[ieval] += field.interp.sample(*field.field, vsP);
}
}
}
} else {
const Imath::Box3d &vsBounds_d = field.vsBounds;
// Loop over samples
for (size_t ieval = 0; ieval < neval; ++ieval) {
const V3d wsP(*reinterpret_cast<const V3f*>(wsPs + 3 * ieval));
V3d vsP;
// Apply world to object transform
field.mapping->worldToVoxel(wsP, vsP);
// Sample
if (vsBounds_d.intersects(vsP)) {
// Count as within field
numHits[ieval]++;
// Sample
data[ieval] += field.interp.sample(*field.field, vsP);
}
}
}
}
}
// MIP fields
static void sampleMIP(const WrapperVec_T &f, const V3d &wsP,
const float wsSpotSize, float *value, size_t &numHits)
{
// Reinterpret the pointer according to Dims_T
Input_T *data = reinterpret_cast<Input_T*>(value);
// Loop over fields in vector
for (size_t i = 0, end = f.size(); i < end; ++i) {
V3d vsP;
float spotSize = wsSpotSize / f[i].worldScale;
// Apply world to object transform
if (f[i].doOsToWs) {
V3d osP;
f[i].wsToOs.multVecMatrix(wsP, osP);
f[i].mapping->worldToVoxel(osP, vsP);
spotSize = wsSpotSize / f[i].worldScale;
} else {
f[i].mapping->worldToVoxel(wsP, vsP);
}
// Sample
if (f[i].vsBounds.intersects(vsP)) {
// Count as within field
numHits++;
// Sample and remap
if (f[i].valueRemapOp) {
const Data_T unremapped = f[i].interp->sample(vsP, spotSize);
*data += f[i].valueRemapOp->remap(unremapped);
} else {
*data += f[i].interp->sample(vsP, spotSize);
}
}
}
}
// MIP fields
static void sampleMIPMultiple(const WrapperVec_T &f, const size_t neval,
const float *wsPs, const float *wsSpotSizes,
float *value, size_t *numHits)
{
// Loop over fields in vector
for (size_t i = 0; i < f.size(); ++i) {
const typename WrapperVec_T::value_type &field = f[i];
// Reinterpret the pointer according to Dims_T
Input_T *data = reinterpret_cast<Input_T*>(value);
if (field.doOsToWs || field.valueRemapOp) {
if (field.valueRemapOp && field.doWsBoundsOptimization) {
// Loop over samples
for (size_t ieval = 0; ieval < neval; ++ieval) {
const V3f &wsP = *reinterpret_cast<const V3f*>(wsPs + 3 * ieval);
if (field.wsBounds.intersects(wsP)) {
// Apply world to object transform
V3d vsP;
field.wsToVs.multVecMatrix(V3d(wsP), vsP);
// Sample
if (field.vsBounds.intersects(vsP)) {
// Count as within field
numHits[ieval]++;
const float spotSize = wsSpotSizes[ieval] / field.worldScale;
const Data_T unremapped = field.interp->sample(vsP, spotSize);
data[ieval] += field.valueRemapOp->remap(unremapped);
}
}
}
} else {
// Loop over samples
for (size_t ieval = 0; ieval < neval; ++ieval) {
const V3d wsP(*reinterpret_cast<const V3f*>(wsPs + 3 * ieval));
const float wsSpotSize = wsSpotSizes[ieval];
Input_T *idata = data + ieval;
V3d vsP;
float spotSize = wsSpotSize / field.worldScale;
// Apply world to object transform
if (field.doOsToWs) {
V3d osP;
field.wsToOs.multVecMatrix(wsP, osP);
field.mapping->worldToVoxel(osP, vsP);
spotSize = wsSpotSize / field.worldScale;
} else {
field.mapping->worldToVoxel(wsP, vsP);
}
// Sample
if (field.vsBounds.intersects(vsP)) {
// Count as within field
numHits[ieval]++;
if (field.valueRemapOp) {
const Data_T unremapped = field.interp->sample(vsP, spotSize);
*idata += field.valueRemapOp->remap(unremapped);
} else {
*idata += field.interp->sample(vsP, spotSize);
}
}
}
}
} else {
const Imath::Box3d &vsBounds_d = field.vsBounds;
const double worldScale = field.worldScale;
// Loop over samples
for (size_t ieval = 0; ieval < neval; ++ieval) {
const V3d wsP(*reinterpret_cast<const V3f*>(wsPs + 3 * ieval));
V3d vsP;
// Apply world to object transform
field.mapping->worldToVoxel(wsP, vsP);
// Sample
if (vsBounds_d.intersects(vsP)) {
// Count as within field
numHits[ieval]++;
const double spotSize = wsSpotSizes[ieval] / worldScale;
data[ieval] += field.interp->sample(vsP, spotSize);
}
}
}
}
}
// Get min/max
static void getMinMax(const WrapperVec_T &f,
const Box3d &wsBounds, float *min, float *max)
{
// Reinterpret the pointer according to Dims_T
Input_T *minData = reinterpret_cast<Input_T*>(min);
Input_T *maxData = reinterpret_cast<Input_T*>(max);
// Loop over fields in vector
for (size_t field = 0, end = f.size(); field < end; ++field) {
// Data window
const Box3i dw = f[field].field->dataWindow();
// Transform corners to voxel space and compute bounds
Box3i dvsBounds;
if (wsBounds.isInfinite()) {
dvsBounds = dw;
} else {
Box3d vsBounds;
if (f[field].doOsToWs) {
Box3d osBounds;
transformBounds(f[field].wsToOs, wsBounds, osBounds);
worldToVoxel(f[field].mapping, osBounds, vsBounds);
} else {
worldToVoxel(f[field].mapping, wsBounds, vsBounds);
}
dvsBounds = clipBounds(discreteBounds(vsBounds), dw);
// Early termination if no intersection
if (!dw.intersects(dvsBounds)) {
return;
}
}
for (int k = dvsBounds.min.z; k <= dvsBounds.max.z; ++k) {
for (int j = dvsBounds.min.y; j <= dvsBounds.max.y; ++j) {
for (int i = dvsBounds.min.x; i <= dvsBounds.max.x; ++i) {
const Data_T val = f[field].field->fastValue(i, j, k);
*minData = detail::min(val, *minData);
*maxData = detail::max(val, *maxData);
}
}
}
}
}
// Get min/max from MIP (uses finest level)
static void getMinMaxMIP(const WrapperVec_T &f,
const Box3d &wsBounds, float *min, float *max)
{
// Reinterpret the pointer according to Dims_T
Input_T *minData = reinterpret_cast<Input_T*>(min);
Input_T *maxData = reinterpret_cast<Input_T*>(max);
// Loop over fields in vector
for (size_t field = 0, end = f.size(); field < end; ++field) {
// Data window
const Box3i dw = f[field].field->dataWindow();
// Transform corners to voxel space and compute bounds
Box3i dvsBounds;
if (wsBounds.isInfinite()) {
dvsBounds = dw;
} else {
Box3d vsBounds;
if (f[field].doOsToWs) {
Box3d osBounds;
transformBounds(f[field].wsToOs, wsBounds, osBounds);
worldToVoxel(f[field].mapping, osBounds, vsBounds);
} else {
worldToVoxel(f[field].mapping, wsBounds, vsBounds);
}
dvsBounds = clipBounds(discreteBounds(vsBounds), dw);
// Early termination if no intersection
if (!dw.intersects(dvsBounds)) {
return;
}
}
for (int k = dvsBounds.min.z; k <= dvsBounds.max.z; ++k) {
for (int j = dvsBounds.min.y; j <= dvsBounds.max.y; ++j) {
for (int i = dvsBounds.min.x; i <= dvsBounds.max.x; ++i) {
const Data_T val = f[field].field->fastMipValue(0, i, j, k);
*minData = detail::min(val, *minData);
*maxData = detail::max(val, *maxData);
}
}
}
}
}
// Get min/max for pre-filtered data
static void getMinMaxPrefilt(const WrapperVec_T &f,
const Box3d &wsBounds,
float *result,
const Mode mode)
{
// Reinterpret the pointer according to Dims_T
Input_T *data = reinterpret_cast<Input_T*>(result);
// Loop over fields in vector
for (size_t field = 0, end = f.size(); field < end; ++field) {
// Choose the MIP level to check
const size_t numLevels = f[field].field->numLevels();
size_t level = 0;
Box3i dvsBounds;
// Infinite bounds?
if (wsBounds.isInfinite()) {
// Use the coarsest level
level = numLevels - 1;
dvsBounds = f[field].field->mipLevel(level)->dataWindow();
} else {
for (size_t i = 0; i < numLevels; ++i) {
// Update current level
level = i;
// Data window of current level
const Box3i dw = f[field].field->mipLevel(level)->dataWindow();
Box3d vsBounds;
if (f[field].doOsToWs) {
Box3d osBounds;
transformBounds(f[field].wsToOs, wsBounds, osBounds);
worldToVoxel(f[field].field->mipLevel(level)->mapping().get(),
osBounds, vsBounds);
} else {
worldToVoxel(f[field].field->mipLevel(level)->mapping().get(),
wsBounds, vsBounds);
}
dvsBounds = clipBounds(discreteBounds(vsBounds), dw);
// If size of dvsBounds is <= 2, stop
Imath::V3i size = dvsBounds.size();
if (std::max(size.x, std::max(size.y, size.z)) <= 2) {
break;
}
}
}
// Level chosen. Run loop
for (int k = dvsBounds.min.z; k <= dvsBounds.max.z; ++k) {
for (int j = dvsBounds.min.y; j <= dvsBounds.max.y; ++j) {
for (int i = dvsBounds.min.x; i <= dvsBounds.max.x; ++i) {
const Data_T val = f[field].field->fastMipValue(level, i, j, k);
if (mode == Min) {
*data = detail::min(val, *data);
} else {
*data = detail::max(val, *data);
}
}
}
}
}
}
};
//----------------------------------------------------------------------------//
FIELD3D_NAMESPACE_HEADER_CLOSE
//------------------------------------------------------------------------------
#endif // include guard
//------------------------------------------------------------------------------
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