void operator()(tbb::blocked_range2d<int> i_range) const {
ewav::Rand48_Engine r48;
std::normal_distribution<float> gdist{0.0f, 1.0f};
const float maxKmag = float(N / 2) * M_TAU / Domain;
const float dk = float(1) * M_TAU / Domain;
for (int j = i_range.rows().begin(); j != i_range.rows().end(); ++j) {
// kj is the wave number in the j direction.
int realJ = j <= (N / 2) ? j : j - N;
float kj = float(realJ) * M_TAU / Domain;
for (int i = i_range.cols().begin(); i != i_range.cols().end(); ++i) {
// ki is the wave number in the i direction
float ki = float(i) * M_TAU / Domain;
// Magnitude of the wave vector.
float kMag = std::hypot(ki, kj);
// Index into the array.
std::size_t index = (std::size_t(j) * StrideJ) + i;
// If the wavenumber is zero, or we're in the outer ring,
// set it to zero.
if ((i == 0 && realJ == 0) || (kMag > maxKmag)) {
Spectral[index] = Cf(0.0, 0.0);
} else {
r48.seed(ewav::SeedFromWavenumber(Imath::V2f(ki, kj), Seed));
Spectral[index] = dk * dk * Cf(gdist(r48), gdist(r48));
}
}
}
}
void operator()(const tbb::blocked_range2d<unsigned>& r) const
{
unsigned col, row;
const int num_ghost = rp_grid_params.num_ghost;
const int num_eqn = rp_grid_params.num_eqn;
const int num_aux = rp_grid_params.num_aux;
const int num_wave = rp_grid_params.num_wave;
FieldIndexer fi(nx, ny, num_ghost, num_eqn);
FieldIndexer fi_aux(nx, ny, num_ghost, num_aux);
EdgeFieldIndexer efi(nx, ny, num_ghost, num_eqn, num_wave);
for(row = r.rows().begin(); row != r.rows().end(); ++row){
for(col = r.cols().begin(); col != std::min(r.cols().end(), efi.num_col_edge_normal() + 1); ++col) {
rp(q + fi.idx(row, col-1), q + fi.idx(row, col),
aux + fi_aux.idx(row, col-1), aux + fi_aux.idx(row, col), aux_global, 0,
amdq + efi.left_edge(row, col), apdq + efi.left_edge(row, col),
wave + efi.left_edge(row, col), wave_speed + efi.left_edge(row, col));
rp(q + fi.idx(row-1, col), q + fi.idx(row, col),
aux + fi_aux.idx(row-1, col), aux + fi_aux.idx(row, col), aux_global, 1,
amdq + efi.down_edge(row, col), apdq + efi.down_edge(row, col),
wave + efi.down_edge(row, col), wave_speed + efi.down_edge(row, col));
}
}
}
void operator()( const tbb::blocked_range2d<int>& range ) const {
for( int block_row = range.rows().begin(); block_row != range.rows().end(); ++block_row ) {
for( int block_col = range.cols().begin(); block_col != range.cols().end(); ++block_col ) {
typename std::map<std::pair<int, int>, cv::Rect_<int> >::const_iterator block_itr
= block_image_.block_rects_.find( std::pair<int, int>(block_row, block_col));
const cv::Rect_<int>& block_rect = block_itr->second;
DrawBlock( block_rect, block_image_.mean_array_.coeff( block_row, block_col ) );
}
}
}
/**
* @brief operator() for tbb::parallel_for()
* @param[in] range tbb::blocked_range2d<int>
*/
void operator()( const tbb::blocked_range2d<int>& range ) const {
for( int block_row = range.rows().begin(); block_row != range.rows().end(); ++block_row ) {
for( int block_col = range.cols().begin(); block_col != range.cols().end(); ++block_col ) {
cv::Rect_<int> block_rect;
GetBlockROI( block_row, block_col, block_rect );
block_image_.mean_array_.coeffRef( block_row, block_col ) = GetMeanBrightness( block_rect );
block_image_.block_rects_[std::pair<int, int>( block_row, block_col )] = block_rect;
}
}
}
// overload () so it starts updating the cell states
void operator()(const tbb::blocked_range2d<size_t>& r) const
{
/**
@Desc : Overloaded parenthesis () operator
@param1 : TBB 2D blocked range
*/
// Update each cell that the current thread manages
for (size_t i = r.cols().begin(); i != r.cols().end(); ++i)
{
for (size_t j = r.rows().begin(); j != r.rows().end(); ++j)
UpdateState(i, j, g_quad[i][j]);
}
}
void operator () (const tbb::blocked_range2d<int> &range) const {
int i,j;
for(i=range.rows().begin(); i<range.rows().end(); i++) {
for(j=range.cols().begin(); j<range.cols().end(); j++) {
// TODO replace this by a reducer
int k,l;
int dot_product = 0;
for(k=0; k<FILTERSIDE; k++){
for(l=0; l<FILTERSIDE; l++){
dot_product = dot_product + image[i+k][j+l]*filter[k][l];
}
}
image3[i+FILTERSIDE/2][j+FILTERSIDE/2] = image[i+FILTERSIDE/2][j+FILTERSIDE/2] + dot_product;
}
}
}
MSC_NAMESPACE_BEGIN
void Convolve::operator()(const tbb::blocked_range2d< size_t > &r) const
{
m_filter->convolve(
m_image->width,
m_image->height,
m_image->base * m_image->base,
r.rows().begin(),
r.rows().end(),
r.cols().begin(),
r.cols().end(),
&(m_image->samples[0]),
&(m_image->pixels[0])
);
}
void operator()(const tbb::blocked_range2d<int> &r) const
{
typedef cv::Point3_<GenSOM::value_type> Point3;
// iterate over all pixels in range
float done = 0;
float total = (lookup.height * lookup.width);
for (int y = r.rows().begin(); y < r.rows().end(); ++y) {
for (int x = r.cols().begin(); x < r.cols().end(); ++x) {
SOMClosestN::resultAccess closest =
lookup.closestN(cv::Point2i(x, y));
Point3 weighted(0, 0, 0);
std::vector<DistIndexPair>::const_iterator it = closest.first;
for (int k = 0; it != closest.last; ++k, ++it) {
size_t somidx = it->index;
Point3 pos = vec2Point3(lookup.som.getCoord(somidx));
weighted += weights[k] * pos;
}
if (posToBGR) { // 3D coord -> BGR color
// for 2D SOM: weighted.z == 0 -> use only G and R
Point3 tmp = weighted;
weighted.x = tmp.z; // B
weighted.y = tmp.y; // G
weighted.z = tmp.x; // R
}
output(y, x) = weighted;
done++;
if (po && ((int)done % 1000 == 0)) {
if (!po->update(done / total, true))
return; // abort if told so. This is thread-save.
done = 0;
}
}
}
if (po)
po->update(done / total, true);
}
void operator()( tbb::blocked_range2d<int> &r ) const {
if ( v->next_frame() )
f.render_rect( r.cols().begin(), r.rows().begin(), r.cols().end(), r.rows().end() );
}
void operator() (const tbb::blocked_range2d<int> &r) const
{
// task-local storage
unsigned int serial = 1;
unsigned int mboxsize = sizeof(unsigned int)*(max_objectid() + 20);
unsigned int * local_mbox = (unsigned int *) alloca(mboxsize);
memset(local_mbox,0,mboxsize);
#ifdef MARK_RENDERING_AREA
// compute thread number while first task run
thread_id_t::reference thread_id = thread_ids.local();
if (thread_id == -1) thread_id = thread_number++;
// choose thread color
int pos = thread_id % NUM_COLORS;
if(video->running) {
drawing_area drawing(r.cols().begin(), totaly-r.rows().end(), r.cols().end() - r.cols().begin(), r.rows().end()-r.rows().begin());
for (int i = 1, y = r.rows().begin(); y != r.rows().end(); ++y, i++) {
drawing.set_pos(0, drawing.size_y-i);
for (int x = r.cols().begin(); x != r.cols().end(); x++) {
int d = (y % 3 == 0) ? 2 : 1;
drawing.put_pixel(video->get_color(colors[pos][0]/d, colors[pos][1]/d, colors[pos][2]/d));
}
}
}
#endif
if(video->next_frame()) {
drawing_area drawing(r.cols().begin(), totaly-r.rows().end(), r.cols().end() - r.cols().begin(), r.rows().end()-r.rows().begin());
for (int i = 1, y = r.rows().begin(); y != r.rows().end(); ++y, i++) {
drawing.set_pos(0, drawing.size_y-i);
for (int x = r.cols().begin(); x != r.cols().end(); x++) {
#ifdef MARK_RENDERING_AREA
float alpha = y==r.rows().begin()||y==r.rows().end()-1||x==r.cols().begin()||x==r.cols().end()-1
? border_alpha : inner_alpha;
color_t c = render_one_pixel (x, y, local_mbox, serial, startx, stopx, starty, stopy, colors[pos], alpha);
#else
color_t c = render_one_pixel (x, y, local_mbox, serial, startx, stopx, starty, stopy);
#endif
drawing.put_pixel(c);
}
}
}
}
