threadedBoundingBox/threadedBoundingBox.cpp

threadedBoundingBox/threadedBoundingBox.cpp
//-
// ==========================================================================
// Copyright 1995,2006,2008 Autodesk, Inc. All rights reserved.
//
// Use of this software is subject to the terms of the Autodesk
// license agreement provided at the time of installation or download,
// or which otherwise accompanies this software in either electronic
// or hard copy form.
// ==========================================================================
//+
// threadedBoundingBox.cpp
//
// This plugin demonstrates the hazards of false sharing in
// multithreaded code. The plugin computes the min X element of the
// bounding box of a selected mesh. The element is computed two ways:
//
// - Allocating an array of elements, one per thread, and building up
// one value in each thread.
//
// - Allocating an array of elements, more than one per thread, and
// building up one value in each thread. Extra intermediate array
// elements are allocated to ensure that each value used by a thread
// is on a separate cache line.
//
// In both cases, the values computed in each thread are finally
// merged into a single min X value.
//
// The observed result is that the second computation is significantly
// faster than the first, at the cost of a small amount of extra
// memory usage. What is happening is that in the first case most (if
// not all) of the points being accumulated are on the same cache
// line, which causes the array of points to ping pong between
// processor caches as elements are computed by different threads
// running on different cores and written into the array. This
// degrades performance significantly (around 30x slower on a dual
// quad core Clovertown system.)
//
// Note that cache lines in current processors are usually 64 bytes,
// but may grow in future. To get the exact value we call an API
// method that returns the cache line size for the current processor
// on which Maya is being run.
#include <float.h>
#include <limits.h>
#ifdef _OPENMP
#include <omp.h> // OpenMP header for omp_get_max_threads
#endif
#include <maya/MIOStream.h>
#include <maya/MSimple.h>
#include <maya/MSelectionList.h>
#include <maya/MGlobal.h>
#include <maya/MFnMesh.h>
#include <maya/MDagPath.h>
#include <maya/MTimer.h>
#include <maya/MFloatPointArray.h>
#include <maya/MThreadUtils.h>
DeclareSimpleCommand( threadedBoundingBox, PLUGIN_COMPANY, "1.0");
float computeMinX(const MFloatPointArray& vertexArray, bool padding)
{
// compute minimum X value using multiple evaluators, one per thread.
const int floatSize = sizeof(float); // 4 bytes per float value
const int cacheLineSize = MThreadUtils::getCacheLineSize();
// spacing is the number of float values that must be adjacent in
// memory to ensure one cache line is filled. We add an extra two
// to ensure separation regardless of alignment.
int spacing = 1;
if(padding) {
spacing = 2+(cacheLineSize/floatSize);
}
// NOTE - omp_get_num_threads() only returns >1 inside threaded code!
// Use omp_get_max_threads() to get actual number of active threads.
int numThreads = 1;
#ifdef _OPENMP
numThreads = omp_get_max_threads();
#endif
// allocate one or more boxes per thread, depending on the spacing computed above.
float* pointArray = new float[numThreads*spacing];
const int nb = vertexArray.length();
const int nbStep = nb / numThreads;
#ifdef _OPENMP
#pragma omp parallel for
#endif
for(int i=0; i<numThreads; i++) {
float& minX = pointArray[i*spacing];
minX = FLT_MAX;
const int n1 = i*nbStep;
const int n2 = (i<(numThreads-1)) ? (i+1)*nbStep : nb;
for (int n=n1; n<n2; n++) {
const MFloatPoint& p = vertexArray[n];
if(p.x < minX) minX = p.x;
}
}
float finalMinX = FLT_MAX;
// accumulate separate boxes
for(int i=0; i<numThreads; i++) {
if(pointArray[i*spacing] < finalMinX) finalMinX = pointArray[i*spacing];
}
// clean up temporary boxes
delete [] pointArray;
return finalMinX;
}
MStatus threadedBoundingBox::doIt( const MArgList& args )
//
// Description:
// Implements the MEL threadedBoundingBox command. This command computes a
// bounding box for the currently selected mesh objects.
// It is a demonstration of the problems of false sharing.
//
// Arguments:
// args - the argument list that was passes to the command from MEL. This
// command takes no arguments.
//
// Return Value:
// MS::kSuccess - command succeeded
// MS::kFailure - command failed (returning this value will cause the
// MEL script that is being run to terminate unless the
// error is caught using a "catch" statement.
//
{
// iterate through the selection list, and find bounding boxes for any selected
// polygons.
//
int numSelected = curSel.length();
for( int s = 0; s < numSelected; s++ )
{
// get the selected item, figure out if it's a polymesh or not
//
MDagPath dagPath;
curSel.getDagPath( s, dagPath );
if( dagPath.extendToShape() != MS::kSuccess )
{
// selection does not correspond to a DAG shape
//
cout<<" Error - object is not a polymesh"<<endl;
stat = MS::kFailure;
return stat;
}
MObject node = dagPath.node();
MFnDependencyNode fnNode( node );
MFnMesh fnMesh( node, &stat );
if( stat != MS::kSuccess )
{
cout<<" Error - unable to create MFnMesh object"<<endl;
return stat;
}
// Retrieve the list of vertices on the polymesh.
MFloatPointArray vertexArray;
// get the vertices
//
stat = fnMesh.getPoints(vertexArray );
if( stat != MS::kSuccess ) {
cout<<" Error - unable to retrieve vertices"<<endl;
return stat;
}
float minX1 = 0.0f;
float minX2 = 0.0f;
cout<<" Poly has "<< vertexArray.length()<<" vertices"<<endl;
bool padding = false;
int numIterations = 100;
MTimer timer;
timer.beginTimer();
for(int i=0; i<numIterations; i++) {
minX1 = computeMinX(vertexArray, padding);
}
timer.endTimer();
printf("Runtime without padding %f\n", timer.elapsedTime());
padding = true;
timer.beginTimer();
for(int i=0; i<numIterations; i++) {
minX2 = computeMinX(vertexArray, padding);
}
timer.endTimer();
printf("Runtime with padding %f\n", timer.elapsedTime());
if(fabs(minX1-minX2)<1e-10) {
cout << "Boxes match" << endl;
} else {
cout << "Boxes do not match" << endl;
stat = MS::kFailure;
return stat;
}
}
setResult( "threadedBoundingBox completed." );
return stat;
}