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bullet3/Demos/MiniCL_VectorAdd/MiniCL.cpp
erwin.coumans fb6146f0be Added MiniCL, a limited subset of OpenCL, the open standard for parallel programming of heterogeneous systems. 
MiniCL includes a cross-platform run-time frontend based on pthreads, Win32 Threads, or libspe2 for Cell SPU.
It is there, to bridge the gap until OpenCL is more widely available.

See Bullet/Demos/VectorAdd, influenced by NVidia OpenCL Jumpstart Guide:
http://developer.download.nvidia.com/OpenCL/NVIDIA_OpenCL_JumpStart_Guide.pdf
2009-05-22 01:43:37 +00:00

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#include <MiniCL/cl.h>
#define __PHYSICS_COMMON_H__ 1
#ifdef WIN32
#include "BulletMultiThreaded/Win32ThreadSupport.h"
#else
#include "BulletMultiThreaded/SequentialThreadSupport.h"
#endif
#include "BulletMultiThreaded/MiniCLTaskScheduler.h"
#include "BulletMultiThreaded/MiniCLTask/MiniCLTask.h"
#include "LinearMath/btMinMax.h"
/*
m_threadSupportCollision = new Win32ThreadSupport(Win32ThreadSupport::Win32ThreadConstructionInfo(
"collision",
processCollisionTask,
createCollisionLocalStoreMemory,
maxNumOutstandingTasks));
if (!m_spuCollisionTaskProcess)
m_spuCollisionTaskProcess = new SpuCollisionTaskProcess(m_threadInterface,m_maxNumOutstandingTasks);
m_spuCollisionTaskProcess->initialize2(dispatchInfo.m_useEpa);
m_spuCollisionTaskProcess->addWorkToTask(pairPtr,i,endIndex);
//make sure all SPU work is done
m_spuCollisionTaskProcess->flush2();
*/
CL_API_ENTRY cl_int CL_API_CALL clGetDeviceInfo(
cl_device_id device ,
cl_device_info param_name ,
size_t param_value_size ,
void * param_value ,
size_t * /* param_value_size_ret */) CL_API_SUFFIX__VERSION_1_0
{
switch (param_name)
{
case CL_DEVICE_NAME:
{
char deviceName[] = "CPU";
int nameLen = strlen(deviceName)+1;
assert(param_value_size>strlen(deviceName));
if (nameLen < param_value_size)
{
sprintf((char*)param_value,"CPU");
} else
{
printf("error: param_value_size should be at least %d, but it is %d\n",nameLen,param_value_size);
}
break;
}
case CL_DEVICE_TYPE:
{
if (param_value_size>=sizeof(cl_device_type))
{
cl_device_type* deviceType = (cl_device_type*)param_value;
*deviceType = CL_DEVICE_TYPE_CPU;
} else
{
printf("error: param_value_size should be at least %d\n",sizeof(cl_device_type));
}
break;
}
case CL_DEVICE_MAX_COMPUTE_UNITS:
{
if (param_value_size>=sizeof(cl_uint))
{
cl_uint* numUnits = (cl_uint*)param_value;
*numUnits= 4;
} else
{
printf("error: param_value_size should be at least %d\n",sizeof(cl_uint));
}
break;
}
case CL_DEVICE_MAX_WORK_ITEM_SIZES:
{
size_t workitem_size[3];
if (param_value_size>=sizeof(workitem_size))
{
size_t* workItemSize = (size_t*)param_value;
workItemSize[0] = 64;
workItemSize[1] = 24;
workItemSize[2] = 16;
} else
{
printf("error: param_value_size should be at least %d\n",sizeof(cl_uint));
}
break;
}
default:
{
printf("error: unsupported param_name:%d\n",param_name);
}
}
return 0;
}
CL_API_ENTRY cl_int CL_API_CALL clReleaseMemObject(cl_mem /* memobj */) CL_API_SUFFIX__VERSION_1_0
{
return 0;
}
CL_API_ENTRY cl_int CL_API_CALL clReleaseCommandQueue(cl_command_queue /* command_queue */) CL_API_SUFFIX__VERSION_1_0
{
return 0;
}
CL_API_ENTRY cl_int CL_API_CALL clReleaseProgram(cl_program /* program */) CL_API_SUFFIX__VERSION_1_0
{
return 0;
}
CL_API_ENTRY cl_int CL_API_CALL clReleaseKernel(cl_kernel /* kernel */) CL_API_SUFFIX__VERSION_1_0
{
return 0;
}
// Enqueued Commands APIs
CL_API_ENTRY cl_int CL_API_CALL clEnqueueReadBuffer(cl_command_queue command_queue ,
cl_mem buffer ,
cl_bool /* blocking_read */,
size_t /* offset */,
size_t cb ,
void * ptr ,
cl_uint /* num_events_in_wait_list */,
const cl_event * /* event_wait_list */,
cl_event * /* event */) CL_API_SUFFIX__VERSION_1_0
{
MiniCLTaskScheduler* scheduler = (MiniCLTaskScheduler*) command_queue;
///wait for all work items to be completed
scheduler->flush();
memcpy(ptr,buffer,cb);
return 0;
}
CL_API_ENTRY cl_int CL_API_CALL clEnqueueNDRangeKernel(cl_command_queue /* command_queue */,
cl_kernel clKernel ,
cl_uint work_dim ,
const size_t * /* global_work_offset */,
const size_t * global_work_size ,
const size_t * /* local_work_size */,
cl_uint /* num_events_in_wait_list */,
const cl_event * /* event_wait_list */,
cl_event * /* event */) CL_API_SUFFIX__VERSION_1_0
{
MiniCLKernel* kernel = (MiniCLKernel*) clKernel;
for (int ii=0;ii<work_dim;ii++)
{
int maxTask = kernel->m_scheduler->getMaxNumOutstandingTasks();
int numWorkItems = global_work_size[ii];
//at minimum 64 work items per task
int numWorkItemsPerTask = btMax(64,numWorkItems / maxTask);
for (int t=0;t<numWorkItems;)
{
//Performance Hint: tweak this number during benchmarking
int endIndex = (t+numWorkItemsPerTask) < numWorkItems ? t+numWorkItemsPerTask : numWorkItems;
kernel->m_scheduler->issueTask(t,endIndex,kernel->m_kernelProgramCommandId,(char*)&kernel->m_argData[0][0],kernel->m_argSizes);
t = endIndex;
}
}
/*
void* bla = 0;
scheduler->issueTask(bla,2,3);
scheduler->flush();
*/
return 0;
}
CL_API_ENTRY cl_int CL_API_CALL clSetKernelArg(cl_kernel clKernel ,
cl_uint arg_index ,
size_t arg_size ,
const void * arg_value ) CL_API_SUFFIX__VERSION_1_0
{
MiniCLKernel* kernel = (MiniCLKernel* ) clKernel;
assert(arg_size < MINICL_MAX_ARGLENGTH);
if (arg_index>MINI_CL_MAX_ARG)
{
printf("error: clSetKernelArg arg_index (%d) exceeds %d\n",arg_index,MINI_CL_MAX_ARG);
} else
{
if (arg_size>=MINICL_MAX_ARGLENGTH)
{
printf("error: clSetKernelArg argdata too large: %d (maximum is %d)\n",arg_size,MINICL_MAX_ARGLENGTH);
} else
{
memcpy( kernel->m_argData[arg_index],arg_value,arg_size);
kernel->m_argSizes[arg_index] = arg_size;
}
}
return 0;
}
// Kernel Object APIs
CL_API_ENTRY cl_kernel CL_API_CALL clCreateKernel(cl_program program ,
const char * kernel_name ,
cl_int * /* errcode_ret */) CL_API_SUFFIX__VERSION_1_0
{
MiniCLTaskScheduler* scheduler = (MiniCLTaskScheduler*) program;
MiniCLKernel* kernel = new MiniCLKernel();
kernel->m_kernelProgramCommandId = scheduler->findProgramCommandIdByName(kernel_name);
kernel->m_scheduler = scheduler;
return (cl_kernel)kernel;
}
CL_API_ENTRY cl_int CL_API_CALL clBuildProgram(cl_program /* program */,
cl_uint /* num_devices */,
const cl_device_id * /* device_list */,
const char * /* options */,
void (*pfn_notify)(cl_program /* program */, void * /* user_data */),
void * /* user_data */) CL_API_SUFFIX__VERSION_1_0
{
return 0;
}
CL_API_ENTRY cl_program CL_API_CALL clCreateProgramWithBinary(cl_context context ,
cl_uint /* num_devices */,
const cl_device_id * /* device_list */,
const size_t * /* lengths */,
const unsigned char ** /* binaries */,
cl_int * /* binary_status */,
cl_int * /* errcode_ret */) CL_API_SUFFIX__VERSION_1_0
{
return (cl_program)context;
}
// Memory Object APIs
CL_API_ENTRY cl_mem CL_API_CALL clCreateBuffer(cl_context /* context */,
cl_mem_flags flags ,
size_t size,
void * host_ptr ,
cl_int * errcode_ret ) CL_API_SUFFIX__VERSION_1_0
{
cl_mem buf = (cl_mem)malloc(size);
if ((flags&CL_MEM_COPY_HOST_PTR) && host_ptr)
{
memcpy(buf,host_ptr,size);
}
return buf;
}
// Command Queue APIs
CL_API_ENTRY cl_command_queue CL_API_CALL clCreateCommandQueue(cl_context context ,
cl_device_id /* device */,
cl_command_queue_properties /* properties */,
cl_int * /* errcode_ret */) CL_API_SUFFIX__VERSION_1_0
{
return (cl_command_queue) context;
}
extern CL_API_ENTRY cl_int CL_API_CALL clGetContextInfo(cl_context /* context */,
cl_context_info param_name ,
size_t param_value_size ,
void * param_value,
size_t * param_value_size_ret ) CL_API_SUFFIX__VERSION_1_0
{
switch (param_name)
{
case CL_CONTEXT_DEVICES:
{
if (!param_value_size)
{
*param_value_size_ret = 13;
} else
{
sprintf((char*)param_value,"MiniCL_Test.");
}
break;
};
default:
{
printf("unsupported\n");
}
}
return 0;
}
CL_API_ENTRY cl_context CL_API_CALL clCreateContextFromType(cl_context_properties * /* properties */,
cl_device_type /* device_type */,
void (*pfn_notify)(const char *, const void *, size_t, void *) /* pfn_notify */,
void * /* user_data */,
cl_int * /* errcode_ret */) CL_API_SUFFIX__VERSION_1_0
{
int maxNumOutstandingTasks = 4;
#ifdef WIN32
Win32ThreadSupport* threadSupport = new Win32ThreadSupport(Win32ThreadSupport::Win32ThreadConstructionInfo(
"MiniCL",
processMiniCLTask, //processCollisionTask,
createMiniCLLocalStoreMemory,//createCollisionLocalStoreMemory,
maxNumOutstandingTasks));
#else
SequentialThreadSupport::SequentialThreadConstructionInfo stc("MiniCL",processMiniCLTask,createMiniCLLocalStoreMemory);
SequentialThreadSupport* threadSupport = new SequentialThreadSupport(stc);
#endif
MiniCLTaskScheduler* scheduler = new MiniCLTaskScheduler(threadSupport,maxNumOutstandingTasks);
return (cl_context)scheduler;
}
CL_API_ENTRY cl_int CL_API_CALL clReleaseContext(cl_context context ) CL_API_SUFFIX__VERSION_1_0
{
MiniCLTaskScheduler* scheduler = (MiniCLTaskScheduler*) context;
btThreadSupportInterface* threadSupport = scheduler->getThreadSupportInterface();
delete scheduler;
delete threadSupport;
return 0;
}
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