/*
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*
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* permitted provided that the following conditions are met:
*
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* of conditions and the following disclaimer in the documentation and/or other materials
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package com.jogamp.opencl;
import com.jogamp.opencl.util.CLUtil;
import com.jogamp.common.nio.Buffers;
import com.jogamp.common.nio.NativeSizeBuffer;
import com.jogamp.opencl.llb.CLKernelBinding;
import java.nio.Buffer;
import java.nio.ByteBuffer;
import static com.jogamp.opencl.CLException.*;
import static com.jogamp.opencl.llb.CL.*;
import static com.jogamp.common.os.Platform.*;
/**
* High level abstraction for an OpenCL Kernel.
* A kernel is a function declared in a program. A kernel is identified by the kernel
qualifier
* applied to any function in a program. A kernel object encapsulates the specific kernel
* function declared in a program and the argument values to be used when executing this
* kernel
function.
*
* Example: *
* CLKernel addKernel = program.createCLKernel("add"); * addKernel.setArgs(clBufferA, clBufferB); * ... * queue.putEnqueue1DKernel(addKernel, 0, clBufferA.getSize(), 0); ** CLKernel provides utility methods for setting vector types (float4, int2...) with up to 4 elements. Larger * vectors like float16 can be set using {@link #setArg(int, java.nio.Buffer)}. * * Arguments pointing to {@link CLBuffer}s or {@link CLImage}s can be set using {@link #setArg(int, com.jogamp.opencl.CLMemory) } * or its relative putArg(..) methods. * *
* CLKernel is not threadsafe. However it is perfectly safe to create a new instance of a CLKernel for every * involved Thread. *
* @see CLProgram#createCLKernel(java.lang.String) * @see CLProgram#createCLKernels() * @author Michael Bien */ public class CLKernel extends CLObjectResource implements Cloneable { public final String name; public final int numArgs; private final CLProgram program; private final CLKernelBinding binding; private final ByteBuffer buffer; private int argIndex; private boolean force32BitArgs; CLKernel(CLProgram program, long id) { this(program, null, id); } CLKernel(CLProgram program, String name, long id) { super(program.getContext(), id); this.program = program; this.buffer = Buffers.newDirectByteBuffer(8*4); binding = program.getPlatform().getKernelBinding(); if(name == null) { // get function name NativeSizeBuffer size = NativeSizeBuffer.wrap(buffer); int ret = binding.clGetKernelInfo(ID, CL_KERNEL_FUNCTION_NAME, 0, null, size); checkForError(ret, "error while asking for kernel function name"); ByteBuffer bb = Buffers.newDirectByteBuffer((int)size.get(0)); ret = binding.clGetKernelInfo(ID, CL_KERNEL_FUNCTION_NAME, bb.capacity(), bb, null); checkForError(ret, "error while asking for kernel function name"); this.name = CLUtil.clString2JavaString(bb, bb.capacity()); }else{ this.name = name; } // get number of arguments int ret = binding.clGetKernelInfo(ID, CL_KERNEL_NUM_ARGS, buffer.capacity(), buffer, null); checkForError(ret, "error while asking for number of function arguments."); numArgs = buffer.getInt(0); } public CLKernel putArg(Buffer value) { setArg(argIndex++, value); return this; } public CLKernel putArg(CLMemory> value) { setArg(argIndex, value); argIndex++; return this; } public CLKernel putArg(short value) { setArg(argIndex, value); argIndex++; return this; } public CLKernel putArg(short x, short y) { setArg(argIndex, x, y); argIndex++; return this; } public CLKernel putArg(short x, short y, short z) { setArg(argIndex, x, y, z); argIndex++; return this; } public CLKernel putArg(short x, short y, short z, short w) { setArg(argIndex, x, y, z, w); argIndex++; return this; } public CLKernel putArg(int value) { setArg(argIndex, value); argIndex++; return this; } public CLKernel putArg(int x, int y) { setArg(argIndex, x, y); argIndex++; return this; } public CLKernel putArg(int x, int y, int z) { setArg(argIndex, x, y, z); argIndex++; return this; } public CLKernel putArg(int x, int y, int z, int w) { setArg(argIndex, x, y, z, w); argIndex++; return this; } public CLKernel putArg(long value) { setArg(argIndex, value); argIndex++; return this; } public CLKernel putArg(long x, long y) { setArg(argIndex, x, y); argIndex++; return this; } public CLKernel putArg(long x, long y, long z) { setArg(argIndex, x, y, z); argIndex++; return this; } public CLKernel putArg(long x, long y, long z, long w) { setArg(argIndex, x, y, z, w); argIndex++; return this; } public CLKernel putArg(float value) { setArg(argIndex, value); argIndex++; return this; } public CLKernel putArg(float x, float y) { setArg(argIndex, x, y); argIndex++; return this; } public CLKernel putArg(float x, float y, float z) { setArg(argIndex, x, y, z); argIndex++; return this; } public CLKernel putArg(float x, float y, float z, float w) { setArg(argIndex, x, y, z, w); argIndex++; return this; } public CLKernel putArg(double value) { setArg(argIndex, value); argIndex++; return this; } public CLKernel putArg(double x, double y) { setArg(argIndex, x, y); argIndex++; return this; } public CLKernel putArg(double x, double y, double z) { setArg(argIndex, x, y, z); argIndex++; return this; } public CLKernel putArg(double x, double y, double z, double w) { setArg(argIndex, x, y, z, w); argIndex++; return this; } /** * Sets the size of a local kernel argument. */ public CLKernel putArgSize(int size) { setArgSize(argIndex, size); argIndex++; return this; } public CLKernel putArgs(CLMemory>... values) { setArgs(argIndex, values); argIndex += values.length; return this; } /** * Resets the argument index to 0. */ public CLKernel rewind() { argIndex = 0; return this; } /** * Returns the argument index used in the relative putArt(...) methods. */ public int position() { return argIndex; } public CLKernel setArg(int argumentIndex, Buffer value) { if(!value.isDirect()) { throw new IllegalArgumentException("buffer must be direct."); } setArgument(argumentIndex, Buffers.sizeOfBufferElem(value)*value.remaining(), value); return this; } public CLKernel setArg(int argumentIndex, CLMemory> value) { setArgument(argumentIndex, is32Bit()?4:8, wrap(value.ID)); return this; } public CLKernel setArg(int argumentIndex, short value) { setArgument(argumentIndex, 2, wrap(value)); return this; } public CLKernel setArg(int argumentIndex, short x, short y) { setArgument(argumentIndex, 2*2, wrap(x, y)); return this; } public CLKernel setArg(int argumentIndex, short x, short y, short z) { setArgument(argumentIndex, 2*3, wrap(x, y, z)); return this; } public CLKernel setArg(int argumentIndex, short x, short y, short z, short w) { setArgument(argumentIndex, 2*4, wrap(x, y, z, w)); return this; } public CLKernel setArg(int argumentIndex, int value) { setArgument(argumentIndex, 4, wrap(value)); return this; } public CLKernel setArg(int argumentIndex, int x, int y) { setArgument(argumentIndex, 4*2, wrap(x, y)); return this; } public CLKernel setArg(int argumentIndex, int x, int y, int z) { setArgument(argumentIndex, 4*3, wrap(x, y, z)); return this; } public CLKernel setArg(int argumentIndex, int x, int y, int z, int w) { setArgument(argumentIndex, 4*4, wrap(x, y, z, w)); return this; } public CLKernel setArg(int argumentIndex, long value) { if(force32BitArgs) { setArgument(argumentIndex, 4, wrap((int)value)); }else{ setArgument(argumentIndex, 8, wrap(value)); } return this; } public CLKernel setArg(int argumentIndex, long x, long y) { if(force32BitArgs) { setArgument(argumentIndex, 4*2, wrap((int)x, (int)y)); }else{ setArgument(argumentIndex, 8*2, wrap(x, y)); } return this; } public CLKernel setArg(int argumentIndex, long x, long y, long z) { if(force32BitArgs) { setArgument(argumentIndex, 4*3, wrap((int)x, (int)y, (int)z)); }else{ setArgument(argumentIndex, 8*3, wrap(x, y, z)); } return this; } public CLKernel setArg(int argumentIndex, long x, long y, long z, long w) { if(force32BitArgs) { setArgument(argumentIndex, 4*4, wrap((int)x, (int)y, (int)z, (int)w)); }else{ setArgument(argumentIndex, 8*4, wrap(x, y, z, w)); } return this; } public CLKernel setArg(int argumentIndex, float value) { setArgument(argumentIndex, 4, wrap(value)); return this; } public CLKernel setArg(int argumentIndex, float x, float y) { setArgument(argumentIndex, 4*2, wrap(x, y)); return this; } public CLKernel setArg(int argumentIndex, float x, float y, float z) { setArgument(argumentIndex, 4*3, wrap(x, y, z)); return this; } public CLKernel setArg(int argumentIndex, float x, float y, float z, float w) { setArgument(argumentIndex, 4*4, wrap(x, y, z, w)); return this; } public CLKernel setArg(int argumentIndex, double value) { if(force32BitArgs) { setArgument(argumentIndex, 4, wrap((float)value)); }else{ setArgument(argumentIndex, 8, wrap(value)); } return this; } public CLKernel setArg(int argumentIndex, double x, double y) { if(force32BitArgs) { setArgument(argumentIndex, 4*2, wrap((float)x, (float)y)); }else{ setArgument(argumentIndex, 8*2, wrap(x, y)); } return this; } public CLKernel setArg(int argumentIndex, double x, double y, double z) { if(force32BitArgs) { setArgument(argumentIndex, 4*3, wrap((float)x, (float)y, (float)z)); }else{ setArgument(argumentIndex, 8*3, wrap(x, y, z)); } return this; } public CLKernel setArg(int argumentIndex, double x, double y, double z, double w) { if(force32BitArgs) { setArgument(argumentIndex, 4*4, wrap((float)x, (float)y, (float)z, (float)w)); }else{ setArgument(argumentIndex, 8*4, wrap(x, y, z, w)); } return this; } /** * Sets the size of a local kernel argument at the specified index. */ public CLKernel setArgSize(int argumentIndex, int size) { setArgument(argumentIndex, size, null); return this; } public CLKernel setArgs(CLMemory>... values) { setArgs(0, values); return this; } public CLKernel setArgs(Object... values) { if(values == null || values.length == 0) { throw new IllegalArgumentException("values array was empty or null."); } for (int i = 0; i < values.length; i++) { Object value = values[i]; if(value instanceof CLMemory>) { setArg(i, (CLMemory>)value); }else if(value instanceof Short) { setArg(i, (Short)value); }else if(value instanceof Integer) { setArg(i, (Integer)value); }else if(value instanceof Long) { setArg(i, (Long)value); }else if(value instanceof Float) { setArg(i, (Float)value); }else if(value instanceof Double) { setArg(i, (Double)value); }else if(value instanceof Buffer) { setArg(i, (Buffer)value); }else{ throw new IllegalArgumentException(value + " is not a valid argument."); } } return this; } private void setArgs(int startIndex, CLMemory>... values) { for (int i = 0; i < values.length; i++) { setArg(i+startIndex, values[i]); } } private void setArgument(int argumentIndex, int size, Buffer value) { if(argumentIndex >= numArgs || argumentIndex < 0) { throw new IndexOutOfBoundsException("kernel "+ this +" has "+numArgs+ " arguments, can not set argument with index "+argumentIndex); } if(!program.isExecutable()) { throw new IllegalStateException("can not set program" + " arguments for a not executable program. "+program); } int ret = binding.clSetKernelArg(ID, argumentIndex, size, value); if(ret != CL_SUCCESS) { throw newException(ret, "error setting arg "+argumentIndex+" to value "+value+" of size "+size+" of "+this); } } /** * Forces double and long arguments to be passed as float and int to the OpenCL kernel. * This can be used in applications which want to mix kernels with different floating point precision. */ public CLKernel setForce32BitArgs(boolean force) { this.force32BitArgs = force; return this; } public CLProgram getProgram() { return program; } /** * @see #setForce32BitArgs(boolean) */ public boolean isForce32BitArgsEnabled() { return force32BitArgs; } private Buffer wrap(float value) { return buffer.putFloat(0, value); } private Buffer wrap(float a, float b) { return buffer.putFloat(0, a).putFloat(4, b); } private Buffer wrap(float a, float b, float c) { return buffer.putFloat(0, a).putFloat(4, b).putFloat(8, c); } private Buffer wrap(float a, float b, float c, float d) { return buffer.putFloat(0, a).putFloat(4, b).putFloat(8, c).putFloat(12, d); } private Buffer wrap(double value) { return buffer.putDouble(0, value); } private Buffer wrap(double a, double b) { return buffer.putDouble(0, a).putDouble(8, b); } private Buffer wrap(double a, double b, double c) { return buffer.putDouble(0, a).putDouble(8, b).putDouble(16, c); } private Buffer wrap(double a, double b, double c, double d) { return buffer.putDouble(0, a).putDouble(8, b).putDouble(16, c).putDouble(24, d); } private Buffer wrap(short value) { return buffer.putShort(0, value); } private Buffer wrap(short a, short b) { return buffer.putShort(0, a).putShort(2, b); } private Buffer wrap(short a, short b, short c) { return buffer.putShort(0, a).putShort(2, b).putShort(4, c); } private Buffer wrap(short a, short b, short c, short d) { return buffer.putShort(0, a).putShort(2, b).putShort(4, c).putShort(6, d); } private Buffer wrap(int value) { return buffer.putInt(0, value); } private Buffer wrap(int a, int b) { return buffer.putInt(0, a).putInt(4, b); } private Buffer wrap(int a, int b, int c) { return buffer.putInt(0, a).putInt(4, b).putInt(8, c); } private Buffer wrap(int a, int b, int c, int d) { return buffer.putInt(0, a).putInt(4, b).putInt(8, c).putInt(12, d); } private Buffer wrap(long value) { return buffer.putLong(0, value); } private Buffer wrap(long a, long b) { return buffer.putLong(0, a).putLong(8, b); } private Buffer wrap(long a, long b, long c) { return buffer.putLong(0, a).putLong(8, b).putLong(16, c); } private Buffer wrap(long a, long b, long c, long d) { return buffer.putLong(0, a).putLong(8, b).putLong(16, c).putLong(24, d); } /** * Returns the amount of local memory in bytes being used by a kernel. * This includes local memory that may be needed by an implementation to execute the kernel, * variables declared inside the kernel with the__local
address qualifier and local memory
* to be allocated for arguments to the kernel declared as pointers with the __local
address
* qualifier and whose size is specified with clSetKernelArg.
* If the local memory size, for any pointer argument to the kernel declared with
* the __local
address qualifier, is not specified, its size is assumed to be 0.
*/
public long getLocalMemorySize(CLDevice device) {
return getWorkGroupInfo(device, CL_KERNEL_LOCAL_MEM_SIZE);
}
/**
* Returns the work group size for this kernel on the given device.
* This provides a mechanism for the application to query the work-group size
* that can be used to execute a kernel on a specific device given by device.
* The OpenCL implementation uses the resource requirements of the kernel
* (register usage etc.) to determine what this work-group size should be.
*/
public long getWorkGroupSize(CLDevice device) {
return getWorkGroupInfo(device, CL_KERNEL_WORK_GROUP_SIZE);
}
/**
* Returns the work-group size specified by the __attribute__((reqd_work_group_size(X, Y, Z)))
qualifier in kernel sources.
* If the work-group size is not specified using the above attribute qualifier new long[]{(0, 0, 0)}
is returned.
* The returned array has always three elements.
*/
public long[] getCompileWorkGroupSize(CLDevice device) {
int ret = binding.clGetKernelWorkGroupInfo(ID, device.ID, CL_KERNEL_COMPILE_WORK_GROUP_SIZE, (is32Bit()?4:8)*3, buffer, null);
if(ret != CL_SUCCESS) {
throw newException(ret, "error while asking for CL_KERNEL_COMPILE_WORK_GROUP_SIZE of "+this+" on "+device);
}
if(is32Bit()) {
return new long[] { buffer.getInt(0), buffer.getInt(4), buffer.getInt(8) };
}else {
return new long[] { buffer.getLong(0), buffer.getLong(8), buffer.getLong(16) };
}
}
private long getWorkGroupInfo(CLDevice device, int flag) {
int ret = binding.clGetKernelWorkGroupInfo(ID, device.ID, flag, 8, buffer, null);
if(ret != CL_SUCCESS) {
throw newException(ret, "error while asking for clGetKernelWorkGroupInfo of "+this+" on "+device);
}
return buffer.getLong(0);
}
/**
* Releases all resources of this kernel from its context.
*/
@Override
public synchronized void release() {
super.release();
int ret = binding.clReleaseKernel(ID);
program.onKernelReleased(this);
if(ret != CL_SUCCESS) {
throw newException(ret, "can not release "+this);
}
}
@Override
public String toString() {
return "CLKernel [id: " + ID
+ " name: " + name+"]";
}
@Override
public boolean equals(Object obj) {
if (obj == null) {
return false;
}
if (getClass() != obj.getClass()) {
return false;
}
final CLKernel other = (CLKernel) obj;
if (this.ID != other.ID) {
return false;
}
if (!this.program.equals(other.program)) {
return false;
}
return true;
}
@Override
public int hashCode() {
int hash = 7;
hash = 43 * hash + (int) (this.ID ^ (this.ID >>> 32));
hash = 43 * hash + (this.program != null ? this.program.hashCode() : 0);
return hash;
}
/**
* Returns a new instance of this kernel with uninitialized arguments.
*/
@Override
public CLKernel clone() {
return program.createCLKernel(name).setForce32BitArgs(force32BitArgs);
}
}