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// SPDX-FileCopyrightText: Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
// SPDX-License-Identifier: BSD-3-Clause
// This example demonstrates the use of data parallelism in VTK. The
// pipeline ( vtkMPIImageReader -> vtkContourFilter -> vtkElevationFilter )
// is created in parallel and each process is assigned 1 piece to process.
// All satellite processes send the result to the first process which
// collects and renders them.
#include <vtkMPI.h>
#include "vtkActor.h"
#include "vtkAppendPolyData.h"
#include "vtkCamera.h"
#include "vtkConeSource.h"
#include "vtkContourFilter.h"
#include "vtkDataSet.h"
#include "vtkElevationFilter.h"
#include "vtkImageData.h"
#include "vtkInformation.h"
#include "vtkMPIController.h"
#include "vtkMath.h"
#include "vtkPNrrdReader.h"
#include "vtkPolyData.h"
#include "vtkPolyDataMapper.h"
#include "vtkRegressionTestImage.h"
#include "vtkRenderWindow.h"
#include "vtkRenderWindowInteractor.h"
#include "vtkRenderer.h"
#include "vtkStreamingDemandDrivenPipeline.h"
#include "vtkTestUtilities.h"
#include "vtkWindowToImageFilter.h"
#include "vtkDebugLeaks.h"
namespace
{
const float ISO_START = 4250.0;
const float ISO_STEP = -1250.0;
const int ISO_NUM = 3;
// Just pick a tag which is available
const int ISO_VALUE_RMI_TAG = 300;
const int ISO_OUTPUT_TAG = 301;
struct ParallelIsoArgs_tmp
{
int* retVal;
int argc;
char** argv;
};
struct ParallelIsoRMIArgs_tmp
{
vtkContourFilter* ContourFilter;
vtkMultiProcessController* Controller;
vtkElevationFilter* Elevation;
};
// call back to set the iso surface value.
void SetIsoValueRMI(
void* localArg, void* vtkNotUsed(remoteArg), int vtkNotUsed(remoteArgLen), int vtkNotUsed(id))
{
ParallelIsoRMIArgs_tmp* args = (ParallelIsoRMIArgs_tmp*)localArg;
float val;
vtkMultiProcessController* controller = args->Controller;
int myid = controller->GetLocalProcessId();
int numProcs = controller->GetNumberOfProcesses();
vtkContourFilter* iso = args->ContourFilter;
val = iso->GetValue(0);
iso->SetValue(0, val + ISO_STEP);
args->Elevation->UpdatePiece(myid, numProcs, 0);
controller->Send(args->Elevation->GetOutput(), 0, ISO_OUTPUT_TAG);
}
// This will be called by all processes
void MyMain(vtkMultiProcessController* controller, void* arg)
{
vtkPNrrdReader* reader;
vtkContourFilter* iso;
vtkElevationFilter* elev;
int myid, numProcs;
float val;
ParallelIsoArgs_tmp* args = reinterpret_cast<ParallelIsoArgs_tmp*>(arg);
// Obtain the id of the running process and the total
// number of processes
myid = controller->GetLocalProcessId();
numProcs = controller->GetNumberOfProcesses();
// Create the reader, the data file name might have
// to be changed depending on where the data files are.
char* fname =
vtkTestUtilities::ExpandDataFileName(args->argc, args->argv, "Data/headsq/quarter.nhdr");
reader = vtkPNrrdReader::New();
reader->SetFileName(fname);
// reader->SetDataByteOrderToLittleEndian();
// reader->SetDataExtent(0, 63, 0, 63, 1, 93);
// reader->SetFilePrefix(fname);
// reader->SetDataSpacing(3.2, 3.2, 1.5);
delete[] fname;
// Iso-surface.
iso = vtkContourFilter::New();
iso->SetInputConnection(reader->GetOutputPort());
iso->SetValue(0, ISO_START);
iso->ComputeScalarsOff();
iso->ComputeGradientsOff();
// Compute a different color for each process.
elev = vtkElevationFilter::New();
elev->SetInputConnection(iso->GetOutputPort());
val = (myid + 1) / static_cast<float>(numProcs);
elev->SetScalarRange(val, val + 0.001);
// Make sure all processes update at the same time.
elev->UpdatePiece(myid, numProcs, 0);
if (myid != 0)
{
// If I am not the root process
ParallelIsoRMIArgs_tmp args2;
args2.ContourFilter = iso;
args2.Controller = controller;
args2.Elevation = elev;
// Last, set up a RMI call back to change the iso surface value.
// This is done so that the root process can let this process
// know that it wants the contour value to change.
controller->AddRMI(SetIsoValueRMI, (void*)&args2, ISO_VALUE_RMI_TAG);
controller->ProcessRMIs();
}
else
{
// Create the rendering part of the pipeline
vtkAppendPolyData* app = vtkAppendPolyData::New();
vtkRenderer* ren = vtkRenderer::New();
vtkRenderWindow* renWindow = vtkRenderWindow::New();
vtkRenderWindowInteractor* iren = vtkRenderWindowInteractor::New();
vtkPolyDataMapper* mapper = vtkPolyDataMapper::New();
vtkActor* actor = vtkActor::New();
vtkCamera* cam = vtkCamera::New();
renWindow->AddRenderer(ren);
iren->SetRenderWindow(renWindow);
ren->SetBackground(0.9, 0.9, 0.9);
renWindow->SetSize(400, 400);
mapper->SetInputConnection(app->GetOutputPort());
actor->SetMapper(mapper);
ren->AddActor(actor);
cam->SetFocalPoint(100, 100, 65);
cam->SetPosition(100, 450, 65);
cam->SetViewUp(0, 0, -1);
cam->SetViewAngle(30);
cam->SetClippingRange(177.0, 536.0);
ren->SetActiveCamera(cam);
// loop through some iso surface values.
for (int j = 0; j < ISO_NUM; ++j)
{
for (int i = 1; i < numProcs; ++i)
{
// trigger the RMI to change the iso surface value.
controller->TriggerRMI(i, ISO_VALUE_RMI_TAG);
}
// set the local value
iso->SetValue(0, iso->GetValue(0) + ISO_STEP);
elev->UpdatePiece(myid, numProcs, 0);
for (int i = 1; i < numProcs; ++i)
{
vtkPolyData* pd = vtkPolyData::New();
controller->Receive(pd, i, ISO_OUTPUT_TAG);
if (j == ISO_NUM - 1)
{
app->AddInputData(pd);
}
pd->Delete();
}
}
// Tell the other processors to stop processing RMIs.
for (int i = 1; i < numProcs; ++i)
{
controller->TriggerRMI(i, vtkMultiProcessController::BREAK_RMI_TAG);
}
vtkPolyData* outputCopy = vtkPolyData::New();
outputCopy->ShallowCopy(elev->GetOutput());
app->AddInputData(outputCopy);
outputCopy->Delete();
app->Update();
outputCopy->RemoveGhostCells();
renWindow->Render();
*(args->retVal) = vtkRegressionTester::Test(args->argc, args->argv, renWindow, 10);
if (*(args->retVal) == vtkRegressionTester::DO_INTERACTOR)
{
iren->Start();
}
// Clean up
app->Delete();
ren->Delete();
renWindow->Delete();
iren->Delete();
mapper->Delete();
actor->Delete();
cam->Delete();
}
// clean up objects in all processes.
reader->Delete();
iso->Delete();
elev->Delete();
}
} // end anon namespace
int ParallelIso(int argc, char* argv[])
{
// This is here to avoid false leak messages from vtkDebugLeaks when
// using mpich. It appears that the root process which spawns all the
// main processes waits in MPI_Init() and calls exit() when
// the others are done, causing apparent memory leaks for any objects
// created before MPI_Init().
MPI_Init(&argc, &argv);
// Note that this will create a vtkMPIController if MPI
// is configured, vtkThreadedController otherwise.
vtkMPIController* controller = vtkMPIController::New();
controller->Initialize(&argc, &argv, 1);
// Added for regression test.
// ----------------------------------------------
int retVal = 1;
ParallelIsoArgs_tmp args;
args.retVal = &retVal;
args.argc = argc;
args.argv = argv;
// ----------------------------------------------
controller->SetSingleMethod(MyMain, &args);
controller->SingleMethodExecute();
controller->Finalize();
controller->Delete();
return !retVal;
}
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