virtualx-engine/thirdparty/bullet/Bullet3OpenCL/BroadphaseCollision/b3GpuGridBroadphase.cpp

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#include "b3GpuGridBroadphase.h"
#include "Bullet3Geometry/b3AabbUtil.h"
#include "kernels/gridBroadphaseKernels.h"
#include "kernels/sapKernels.h"
//#include "kernels/gridBroadphase.cl"
#include "Bullet3OpenCL/Initialize/b3OpenCLUtils.h"
#include "Bullet3OpenCL/ParallelPrimitives/b3LauncherCL.h"
#define B3_BROADPHASE_SAP_PATH "src/Bullet3OpenCL/BroadphaseCollision/kernels/sap.cl"
#define B3_GRID_BROADPHASE_PATH "src/Bullet3OpenCL/BroadphaseCollision/kernels/gridBroadphase.cl"
cl_kernel kCalcHashAABB;
cl_kernel kClearCellStart;
cl_kernel kFindCellStart;
cl_kernel kFindOverlappingPairs;
cl_kernel m_copyAabbsKernel;
cl_kernel m_sap2Kernel;
//int maxPairsPerBody = 64;
int maxBodiesPerCell = 256;//??
b3GpuGridBroadphase::b3GpuGridBroadphase(cl_context ctx,cl_device_id device, cl_command_queue q )
:m_context(ctx),
m_device(device),
m_queue(q),
m_allAabbsGPU1(ctx,q),
m_smallAabbsMappingGPU(ctx,q),
m_largeAabbsMappingGPU(ctx,q),
m_gpuPairs(ctx,q),
m_hashGpu(ctx,q),
m_cellStartGpu(ctx,q),
m_paramsGPU(ctx,q)
{
b3Vector3 gridSize = b3MakeVector3(3,3,3);
b3Vector3 invGridSize = b3MakeVector3(1.f/gridSize[0],1.f/gridSize[1],1.f/gridSize[2]);
m_paramsCPU.m_gridSize[0] = 128;
m_paramsCPU.m_gridSize[1] = 128;
m_paramsCPU.m_gridSize[2] = 128;
m_paramsCPU.m_gridSize[3] = maxBodiesPerCell;
m_paramsCPU.setMaxBodiesPerCell(maxBodiesPerCell);
m_paramsCPU.m_invCellSize[0] = invGridSize[0];
m_paramsCPU.m_invCellSize[1] = invGridSize[1];
m_paramsCPU.m_invCellSize[2] = invGridSize[2];
m_paramsCPU.m_invCellSize[3] = 0.f;
m_paramsGPU.push_back(m_paramsCPU);
cl_int errNum=0;
{
const char* sapSrc = sapCL;
cl_program sapProg = b3OpenCLUtils::compileCLProgramFromString(m_context,m_device,sapSrc,&errNum,"",B3_BROADPHASE_SAP_PATH);
b3Assert(errNum==CL_SUCCESS);
m_copyAabbsKernel= b3OpenCLUtils::compileCLKernelFromString(m_context, m_device,sapSrc, "copyAabbsKernel",&errNum,sapProg );
m_sap2Kernel = b3OpenCLUtils::compileCLKernelFromString(m_context, m_device,sapSrc, "computePairsKernelTwoArrays",&errNum,sapProg );
b3Assert(errNum==CL_SUCCESS);
}
{
cl_program gridProg = b3OpenCLUtils::compileCLProgramFromString(m_context,m_device,gridBroadphaseCL,&errNum,"",B3_GRID_BROADPHASE_PATH);
b3Assert(errNum==CL_SUCCESS);
kCalcHashAABB = b3OpenCLUtils::compileCLKernelFromString(m_context, m_device,gridBroadphaseCL, "kCalcHashAABB",&errNum,gridProg);
b3Assert(errNum==CL_SUCCESS);
kClearCellStart = b3OpenCLUtils::compileCLKernelFromString(m_context, m_device,gridBroadphaseCL, "kClearCellStart",&errNum,gridProg);
b3Assert(errNum==CL_SUCCESS);
kFindCellStart = b3OpenCLUtils::compileCLKernelFromString(m_context, m_device,gridBroadphaseCL, "kFindCellStart",&errNum,gridProg);
b3Assert(errNum==CL_SUCCESS);
kFindOverlappingPairs = b3OpenCLUtils::compileCLKernelFromString(m_context, m_device,gridBroadphaseCL, "kFindOverlappingPairs",&errNum,gridProg);
b3Assert(errNum==CL_SUCCESS);
}
m_sorter = new b3RadixSort32CL(m_context,m_device,m_queue);
}
b3GpuGridBroadphase::~b3GpuGridBroadphase()
{
clReleaseKernel( kCalcHashAABB);
clReleaseKernel( kClearCellStart);
clReleaseKernel( kFindCellStart);
clReleaseKernel( kFindOverlappingPairs);
clReleaseKernel( m_sap2Kernel);
clReleaseKernel( m_copyAabbsKernel);
delete m_sorter;
}
void b3GpuGridBroadphase::createProxy(const b3Vector3& aabbMin, const b3Vector3& aabbMax, int userPtr , int collisionFilterGroup, int collisionFilterMask)
{
b3SapAabb aabb;
aabb.m_minVec = aabbMin;
aabb.m_maxVec = aabbMax;
aabb.m_minIndices[3] = userPtr;
aabb.m_signedMaxIndices[3] = m_allAabbsCPU1.size();//NOT userPtr;
m_smallAabbsMappingCPU.push_back(m_allAabbsCPU1.size());
m_allAabbsCPU1.push_back(aabb);
}
void b3GpuGridBroadphase::createLargeProxy(const b3Vector3& aabbMin, const b3Vector3& aabbMax, int userPtr , int collisionFilterGroup, int collisionFilterMask)
{
b3SapAabb aabb;
aabb.m_minVec = aabbMin;
aabb.m_maxVec = aabbMax;
aabb.m_minIndices[3] = userPtr;
aabb.m_signedMaxIndices[3] = m_allAabbsCPU1.size();//NOT userPtr;
m_largeAabbsMappingCPU.push_back(m_allAabbsCPU1.size());
m_allAabbsCPU1.push_back(aabb);
}
void b3GpuGridBroadphase::calculateOverlappingPairs(int maxPairs)
{
B3_PROFILE("b3GpuGridBroadphase::calculateOverlappingPairs");
if (0)
{
calculateOverlappingPairsHost(maxPairs);
/*
b3AlignedObjectArray<b3Int4> cpuPairs;
m_gpuPairs.copyToHost(cpuPairs);
printf("host m_gpuPairs.size()=%d\n",m_gpuPairs.size());
for (int i=0;i<m_gpuPairs.size();i++)
{
printf("host pair %d = %d,%d\n",i,cpuPairs[i].x,cpuPairs[i].y);
}
*/
return;
}
int numSmallAabbs = m_smallAabbsMappingGPU.size();
b3OpenCLArray<int> pairCount(m_context,m_queue);
pairCount.push_back(0);
m_gpuPairs.resize(maxPairs);//numSmallAabbs*maxPairsPerBody);
{
int numLargeAabbs = m_largeAabbsMappingGPU.size();
if (numLargeAabbs && numSmallAabbs)
{
B3_PROFILE("sap2Kernel");
b3BufferInfoCL bInfo[] = {
b3BufferInfoCL( m_allAabbsGPU1.getBufferCL() ),
b3BufferInfoCL( m_largeAabbsMappingGPU.getBufferCL() ),
b3BufferInfoCL( m_smallAabbsMappingGPU.getBufferCL() ),
b3BufferInfoCL( m_gpuPairs.getBufferCL() ),
b3BufferInfoCL(pairCount.getBufferCL())};
b3LauncherCL launcher(m_queue, m_sap2Kernel,"m_sap2Kernel");
launcher.setBuffers( bInfo, sizeof(bInfo)/sizeof(b3BufferInfoCL) );
launcher.setConst( numLargeAabbs );
launcher.setConst( numSmallAabbs);
launcher.setConst( 0 );//axis is not used
launcher.setConst( maxPairs );
//@todo: use actual maximum work item sizes of the device instead of hardcoded values
launcher.launch2D( numLargeAabbs, numSmallAabbs,4,64);
int numPairs = pairCount.at(0);
if (numPairs >maxPairs)
{
b3Error("Error running out of pairs: numPairs = %d, maxPairs = %d.\n", numPairs, maxPairs);
numPairs =maxPairs;
}
}
}
if (numSmallAabbs)
{
B3_PROFILE("gridKernel");
m_hashGpu.resize(numSmallAabbs);
{
B3_PROFILE("kCalcHashAABB");
b3LauncherCL launch(m_queue,kCalcHashAABB,"kCalcHashAABB");
launch.setConst(numSmallAabbs);
launch.setBuffer(m_allAabbsGPU1.getBufferCL());
launch.setBuffer(m_smallAabbsMappingGPU.getBufferCL());
launch.setBuffer(m_hashGpu.getBufferCL());
launch.setBuffer(this->m_paramsGPU.getBufferCL());
launch.launch1D(numSmallAabbs);
}
m_sorter->execute(m_hashGpu);
int numCells = this->m_paramsCPU.m_gridSize[0]*this->m_paramsCPU.m_gridSize[1]*this->m_paramsCPU.m_gridSize[2];
m_cellStartGpu.resize(numCells);
//b3AlignedObjectArray<int > cellStartCpu;
{
B3_PROFILE("kClearCellStart");
b3LauncherCL launch(m_queue,kClearCellStart,"kClearCellStart");
launch.setConst(numCells);
launch.setBuffer(m_cellStartGpu.getBufferCL());
launch.launch1D(numCells);
//m_cellStartGpu.copyToHost(cellStartCpu);
//printf("??\n");
}
{
B3_PROFILE("kFindCellStart");
b3LauncherCL launch(m_queue,kFindCellStart,"kFindCellStart");
launch.setConst(numSmallAabbs);
launch.setBuffer(m_hashGpu.getBufferCL());
launch.setBuffer(m_cellStartGpu.getBufferCL());
launch.launch1D(numSmallAabbs);
//m_cellStartGpu.copyToHost(cellStartCpu);
//printf("??\n");
}
{
B3_PROFILE("kFindOverlappingPairs");
b3LauncherCL launch(m_queue,kFindOverlappingPairs,"kFindOverlappingPairs");
launch.setConst(numSmallAabbs);
launch.setBuffer(m_allAabbsGPU1.getBufferCL());
launch.setBuffer(m_smallAabbsMappingGPU.getBufferCL());
launch.setBuffer(m_hashGpu.getBufferCL());
launch.setBuffer(m_cellStartGpu.getBufferCL());
launch.setBuffer(m_paramsGPU.getBufferCL());
//launch.setBuffer(0);
launch.setBuffer(pairCount.getBufferCL());
launch.setBuffer(m_gpuPairs.getBufferCL());
launch.setConst(maxPairs);
launch.launch1D(numSmallAabbs);
int numPairs = pairCount.at(0);
if (numPairs >maxPairs)
{
b3Error("Error running out of pairs: numPairs = %d, maxPairs = %d.\n", numPairs, maxPairs);
numPairs =maxPairs;
}
m_gpuPairs.resize(numPairs);
if (0)
{
b3AlignedObjectArray<b3Int4> pairsCpu;
m_gpuPairs.copyToHost(pairsCpu);
int sz = m_gpuPairs.size();
printf("m_gpuPairs.size()=%d\n",sz);
for (int i=0;i<m_gpuPairs.size();i++)
{
printf("pair %d = %d,%d\n",i,pairsCpu[i].x,pairsCpu[i].y);
}
printf("?!?\n");
}
}
}
//calculateOverlappingPairsHost(maxPairs);
}
void b3GpuGridBroadphase::calculateOverlappingPairsHost(int maxPairs)
{
m_hostPairs.resize(0);
m_allAabbsGPU1.copyToHost(m_allAabbsCPU1);
for (int i=0;i<m_allAabbsCPU1.size();i++)
{
for (int j=i+1;j<m_allAabbsCPU1.size();j++)
{
if (b3TestAabbAgainstAabb2(m_allAabbsCPU1[i].m_minVec, m_allAabbsCPU1[i].m_maxVec,
m_allAabbsCPU1[j].m_minVec,m_allAabbsCPU1[j].m_maxVec))
{
b3Int4 pair;
int a = m_allAabbsCPU1[j].m_minIndices[3];
int b = m_allAabbsCPU1[i].m_minIndices[3];
if (a<=b)
{
pair.x = a;
pair.y = b;//store the original index in the unsorted aabb array
} else
{
pair.x = b;
pair.y = a;//store the original index in the unsorted aabb array
}
if (m_hostPairs.size()<maxPairs)
{
m_hostPairs.push_back(pair);
}
}
}
}
m_gpuPairs.copyFromHost(m_hostPairs);
}
//call writeAabbsToGpu after done making all changes (createProxy etc)
void b3GpuGridBroadphase::writeAabbsToGpu()
{
m_allAabbsGPU1.copyFromHost(m_allAabbsCPU1);
m_smallAabbsMappingGPU.copyFromHost(m_smallAabbsMappingCPU);
m_largeAabbsMappingGPU.copyFromHost(m_largeAabbsMappingCPU);
}
cl_mem b3GpuGridBroadphase::getAabbBufferWS()
{
return this->m_allAabbsGPU1.getBufferCL();
}
int b3GpuGridBroadphase::getNumOverlap()
{
return m_gpuPairs.size();
}
cl_mem b3GpuGridBroadphase::getOverlappingPairBuffer()
{
return m_gpuPairs.getBufferCL();
}
b3OpenCLArray<b3SapAabb>& b3GpuGridBroadphase::getAllAabbsGPU()
{
return m_allAabbsGPU1;
}
b3AlignedObjectArray<b3SapAabb>& b3GpuGridBroadphase::getAllAabbsCPU()
{
return m_allAabbsCPU1;
}
b3OpenCLArray<b3Int4>& b3GpuGridBroadphase::getOverlappingPairsGPU()
{
return m_gpuPairs;
}
b3OpenCLArray<int>& b3GpuGridBroadphase::getSmallAabbIndicesGPU()
{
return m_smallAabbsMappingGPU;
}
b3OpenCLArray<int>& b3GpuGridBroadphase::getLargeAabbIndicesGPU()
{
return m_largeAabbsMappingGPU;
}