/* * Copyright (c) 2009 JogAmp Community. All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, are * permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, this list of * conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, this list * of conditions and the following disclaimer in the documentation and/or other materials * provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY JogAmp Community ``AS IS'' AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND * FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL JogAmp Community OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * The views and conclusions contained in the software and documentation are those of the * authors and should not be interpreted as representing official policies, either expressed * or implied, of JogAmp Community. */ package com.jogamp.opencl; import com.jogamp.opencl.llb.CL; import com.jogamp.common.nio.Buffers; import com.jogamp.opencl.CLDevice.Type; import com.jogamp.opencl.CLSampler.AddressingMode; import com.jogamp.opencl.CLSampler.FilteringMode; import com.jogamp.common.nio.PointerBuffer; import com.jogamp.opencl.llb.CLContextBinding; import com.jogamp.opencl.llb.impl.CLImageFormatImpl; import java.io.BufferedReader; import java.io.IOException; import java.io.InputStream; import java.io.InputStreamReader; import java.nio.Buffer; import java.nio.ByteBuffer; import java.nio.DoubleBuffer; import java.nio.FloatBuffer; import java.nio.IntBuffer; import java.nio.LongBuffer; import java.nio.ShortBuffer; import java.util.ArrayList; import java.util.Collection; import java.util.HashMap; import java.util.HashSet; import java.util.List; import java.util.Map; import java.util.Set; import static java.lang.System.*; import static com.jogamp.opencl.CLException.*; import static com.jogamp.common.nio.Buffers.*; import static com.jogamp.common.os.Platform.*; import static com.jogamp.opencl.llb.CL.*; import static com.jogamp.opencl.CLBuffer.*; import static java.util.Collections.*; /** * CLContext is responsible for managing objects such as command-queues, memory, * program and kernel objects and for executing kernels on one or more devices * specified in the context. *

* Must be released if no longer used to free native resources. {@link #release()} will * also free all associated {@link CLResource} like programs, samplers, command queues and memory * objects. *

*

* For a code example see {@link CLPlatform}. *

* * concurrency:
* CLContext is threadsafe. * * @author Michael Bien, et al. */ public class CLContext extends CLObjectResource { protected CLDevice[] devices; protected final Set programs; protected final Set samplers; protected final Set> memoryObjects; protected final Map> queuesMap; protected final CLPlatform platform; private final ErrorDispatcher errorHandler; protected CLContext(CLPlatform platform, long contextID, ErrorDispatcher dispatcher) { super(contextID); this.platform = platform; this.programs = synchronizedSet(new HashSet()); this.samplers = synchronizedSet(new HashSet()); this.memoryObjects = synchronizedSet(new HashSet>()); this.queuesMap = new HashMap>(); this.errorHandler = dispatcher; /* addCLErrorHandler(new CLErrorHandler() { public void onError(String errinfo, ByteBuffer private_info, long cb) { java.util.logging.Logger.getLogger(getClass().getName()).warning(errinfo); } }); */ } private synchronized void initDevices(CLContextBinding cl) { if (devices == null) { PointerBuffer deviceCount = PointerBuffer.allocateDirect(1); int ret = cl.clGetContextInfo(ID, CL_CONTEXT_DEVICES, 0, null, deviceCount); checkForError(ret, "can not enumerate devices"); ByteBuffer deviceIDs = Buffers.newDirectByteBuffer((int)deviceCount.get()); ret = cl.clGetContextInfo(ID, CL_CONTEXT_DEVICES, deviceIDs.capacity(), deviceIDs, null); checkForError(ret, "can not enumerate devices"); devices = new CLDevice[deviceIDs.capacity() / (is32Bit() ? 4 : 8)]; for (int i = 0; i < devices.length; i++) { devices[i] = new CLDevice(this, is32Bit() ? deviceIDs.getInt() : deviceIDs.getLong()); } } } /** * Creates a context on all available devices (CL_DEVICE_TYPE_ALL). * The platform to be used is implementation dependent. */ public static CLContext create() { return create((CLPlatform)null, Type.ALL); } /** * Creates a context on the specified device types. * The platform to be used is implementation dependent. */ public static CLContext create(Type... deviceTypes) { return create(null, deviceTypes); } /** * Creates a context on the specified platform on all available devices (CL_DEVICE_TYPE_ALL). */ public static CLContext create(CLPlatform platform) { return create(platform, Type.ALL); } /** * Creates a context on the specified platform and with the specified * device types. */ public static CLContext create(CLPlatform platform, Type... deviceTypes) { if(platform == null) { platform = CLPlatform.getDefault(); } long type = toDeviceBitmap(deviceTypes); PointerBuffer properties = setupContextProperties(platform); ErrorDispatcher dispatcher = new ErrorDispatcher(); return new CLContext(platform, createContextFromType(platform, dispatcher, properties, type), dispatcher); } /** * Creates a context on the specified devices. */ public static CLContext create(CLDevice... devices) { if(devices == null) { throw new IllegalArgumentException("no devices specified"); }else if(devices[0] == null) { throw new IllegalArgumentException("first device was null"); } CLPlatform platform = devices[0].getPlatform(); PointerBuffer properties = setupContextProperties(platform); ErrorDispatcher dispatcher = new ErrorDispatcher(); CLContext context = new CLContext(platform, createContext(platform, dispatcher, properties, devices), dispatcher); if(devices != null) { for (int i = 0; i < devices.length; i++) { devices[i].setContext(context); } } return context; } protected static long createContextFromType(CLPlatform platform, CLErrorHandler handler, PointerBuffer properties, long deviceType) { IntBuffer status = newDirectIntBuffer(1); CLContextBinding cl = platform.getContextBinding(); long context = cl.clCreateContextFromType(properties, deviceType, handler, status); checkForError(status.get(), "can not create CL context"); return context; } protected static long createContext(CLPlatform platform, CLErrorHandler handler, PointerBuffer properties, CLDevice... devices) { IntBuffer status = newDirectIntBuffer(1); PointerBuffer pb = null; if(devices != null && devices.length != 0) { pb = PointerBuffer.allocateDirect(devices.length); for (int i = 0; i < devices.length; i++) { CLDevice device = devices[i]; if(device == null) { throw new IllegalArgumentException("device at index "+i+" was null."); } pb.put(i, device.ID); } } CLContextBinding cl = platform.getContextBinding(); long context = cl.clCreateContext(properties, pb, handler, status); checkForError(status.get(), "can not create CL context"); return context; } private static PointerBuffer setupContextProperties(CLPlatform platform) { if(platform == null) { throw new RuntimeException("no OpenCL installation found"); } return PointerBuffer.allocateDirect(3).put(CL_CONTEXT_PLATFORM) .put(platform.ID).put(0) // 0 terminated array .rewind(); } /** * Creates a program from the given sources, the returned program is not build yet. */ public CLProgram createProgram(String src) { CLProgram program = CLProgram.create(this, src); programs.add(program); return program; } /** * Creates a program and reads the source from stream, the returned program is not build yet. * The InputStream is automatically closed after the sources have been read. * @throws IOException when a IOException occurred while reading or closing the stream. */ public CLProgram createProgram(InputStream source) throws IOException { if(source == null) throw new IllegalArgumentException("input stream for program source must not be null"); BufferedReader reader = new BufferedReader(new InputStreamReader(source)); StringBuilder sb = new StringBuilder(2048); String line; try { while ((line = reader.readLine()) != null) sb.append(line).append("\n"); } finally { reader.close(); } return createProgram(sb.toString()); } /** * Creates a program from the given binaries, the program is not build yet. *
Creating a program will fail if:
*

*/ public CLProgram createProgram(Map binaries) { CLProgram program = CLProgram.create(this, binaries); programs.add(program); return program; } /** * Creates a CLBuffer with the specified flags and element count. No flags creates a MEM.READ_WRITE buffer. */ public final CLBuffer createShortBuffer(int size, Mem... flags) { return createBuffer(newDirectShortBuffer(size), flags); } /** * Creates a CLBuffer with the specified flags and element count. No flags creates a MEM.READ_WRITE buffer. */ public final CLBuffer createIntBuffer(int size, Mem... flags) { return createBuffer(newDirectIntBuffer(size), flags); } /** * Creates a CLBuffer with the specified flags and element count. No flags creates a MEM.READ_WRITE buffer. */ public final CLBuffer createLongBuffer(int size, Mem... flags) { return createBuffer(newDirectLongBuffer(size), flags); } /** * Creates a CLBuffer with the specified flags and element count. No flags creates a MEM.READ_WRITE buffer. */ public final CLBuffer createFloatBuffer(int size, Mem... flags) { return createBuffer(newDirectFloatBuffer(size), flags); } /** * Creates a CLBuffer with the specified flags and element count. No flags creates a MEM.READ_WRITE buffer. */ public final CLBuffer createDoubleBuffer(int size, Mem... flags) { return createBuffer(newDirectDoubleBuffer(size), flags); } /** * Creates a CLBuffer with the specified flags and buffer size in bytes. No flags creates a MEM.READ_WRITE buffer. */ public final CLBuffer createByteBuffer(int size, Mem... flags) { return createByteBuffer(size, Mem.flagsToInt(flags)); } /** * Creates a CLBuffer with the specified flags and buffer size in bytes. */ public final CLBuffer createByteBuffer(int size, int flags) { return createBuffer(newDirectByteBuffer(size), flags); } /** * Creates a CLBuffer with the specified flags. No flags creates a MEM.READ_WRITE buffer. */ public final CLBuffer createBuffer(int size, Mem... flags) { return createBuffer(size, Mem.flagsToInt(flags)); } /** * Creates a CLBuffer with the specified flags. */ public final CLBuffer createBuffer(int size, int flags) { CLBuffer buffer = CLBuffer.create(this, size, flags); memoryObjects.add(buffer); return buffer; } /** * Creates a CLBuffer with the specified flags. No flags creates a MEM.READ_WRITE buffer. */ public final CLBuffer createBuffer(B directBuffer, Mem... flags) { return createBuffer(directBuffer, Mem.flagsToInt(flags)); } /** * Creates a CLBuffer with the specified flags. */ public final CLBuffer createBuffer(B directBuffer, int flags) { CLBuffer buffer = CLBuffer.create(this, directBuffer, flags); memoryObjects.add(buffer); return buffer; } /** * Creates a CLImage2d with the specified format, dimension and flags. */ public final CLImage2d createImage2d(int width, int height, CLImageFormat format, Mem... flags) { return createImage2d(null, width, height, 0, format, flags); } /** * Creates a CLImage2d with the specified format, dimension and flags. */ public final CLImage2d createImage2d(int width, int height, int rowPitch, CLImageFormat format, Mem... flags) { return createImage2d(null, width, height, rowPitch, format, flags); } /** * Creates a CLImage2d with the specified format, dimension and flags. */ public final CLImage2d createImage2d(B directBuffer, int width, int height, CLImageFormat format, Mem... flags) { return createImage2d(directBuffer, width, height, 0, format, flags); } /** * Creates a CLImage2d with the specified format, dimension and flags. */ public final CLImage2d createImage2d(B directBuffer, int width, int height, int rowPitch, CLImageFormat format, Mem... flags) { CLImage2d image = CLImage2d.createImage(this, directBuffer, width, height, rowPitch, format, Mem.flagsToInt(flags)); memoryObjects.add(image); return image; } /** * Creates a CLImage3d with the specified format, dimension and flags. */ public final CLImage3d createImage3d(int width, int height, int depth, CLImageFormat format, Mem... flags) { return createImage3d(null, width, height, depth, format, flags); } /** * Creates a CLImage3d with the specified format, dimension and flags. */ public final CLImage3d createImage3d(int width, int height, int depth, int rowPitch, int slicePitch, CLImageFormat format, Mem... flags) { return createImage3d(null, width, height, depth, rowPitch, slicePitch, format, flags); } /** * Creates a CLImage3d with the specified format, dimension and flags. */ public final CLImage3d createImage3d(B directBuffer, int width, int height, int depth, CLImageFormat format, Mem... flags) { return createImage3d(directBuffer, width, height, depth, 0, 0, format, flags); } /** * Creates a CLImage3d with the specified format, dimension and flags. */ public final CLImage3d createImage3d(B directBuffer, int width, int height, int depth, int rowPitch, int slicePitch, CLImageFormat format, Mem... flags) { CLImage3d image = CLImage3d.createImage(this, directBuffer, width, height, depth, rowPitch, slicePitch, format, Mem.flagsToInt(flags)); memoryObjects.add(image); return image; } CLCommandQueue createCommandQueue(CLDevice device, long properties) { CLCommandQueue queue = CLCommandQueue.create(this, device, properties); synchronized(queuesMap) { List list = queuesMap.get(device); if(list == null) { list = new ArrayList(); queuesMap.put(device, list); } list.add(queue); } return queue; } public CLSampler createSampler(AddressingMode addrMode, FilteringMode filtMode, boolean normalizedCoords) { CLSampler sampler = CLSampler.create(this, addrMode, filtMode, normalizedCoords); samplers.add(sampler); return sampler; } void onProgramReleased(CLProgram program) { programs.remove(program); } void onMemoryReleased(CLMemory buffer) { memoryObjects.remove(buffer); } void onCommandQueueReleased(CLDevice device, CLCommandQueue queue) { synchronized(queuesMap) { List list = queuesMap.get(device); list.remove(queue); // remove empty lists from map if(list.isEmpty()) queuesMap.remove(device); } } void onSamplerReleased(CLSampler sampler) { samplers.remove(sampler); } public void addCLErrorHandler(CLErrorHandler handler) { errorHandler.addHandler(handler); } public void removeCLErrorHandler(CLErrorHandler handler) { errorHandler.removeHandler(handler); } private void release(Collection resources) { // resources remove themselves when released, see above if(!resources.isEmpty()) { CLResource[] array = resources.toArray(new CLResource[resources.size()]); for (CLResource resource : array) { resource.release(); } } } /** * Releases this context and all resources. */ @Override public synchronized void release() { super.release(); try{ //release all resources release(programs); release(memoryObjects); release(samplers); for (List queues : queuesMap.values()) { release(queues); } }finally{ int ret = platform.getContextBinding().clReleaseContext(ID); checkForError(ret, "error releasing context"); } } protected void overrideContext(CLDevice device) { device.setContext(this); } private CLImageFormat[] getSupportedImageFormats(int flags, int type) { CLContextBinding binding = platform.getContextBinding(); int[] entries = new int[1]; int ret = binding.clGetSupportedImageFormats(ID, flags, type, 0, null, entries, 0); if(ret != CL_SUCCESS) { throw newException(ret, "error calling clGetSupportedImageFormats"); } int count = entries[0]; if(count == 0) { return new CLImageFormat[0]; } CLImageFormat[] formats = new CLImageFormat[count]; CLImageFormatImpl impl = CLImageFormatImpl.create(newDirectByteBuffer(count * CLImageFormatImpl.size())); ret = binding.clGetSupportedImageFormats(ID, flags, type, count, impl, null); if(ret != CL_SUCCESS) { throw newException(ret, "error calling clGetSupportedImageFormats"); } ByteBuffer buffer = impl.getBuffer(); for (int i = 0; i < formats.length; i++) { formats[i] = new CLImageFormat(CLImageFormatImpl.create(buffer.slice())); buffer.position(i*CLImageFormatImpl.size()); } return formats; } /** * Returns all supported 2d image formats with the (optional) memory allocation flags. */ public CLImageFormat[] getSupportedImage2dFormats(Mem... flags) { return getSupportedImageFormats(flags==null?0:Mem.flagsToInt(flags), CL_MEM_OBJECT_IMAGE2D); } /** * Returns all supported 3d image formats with the (optional) memory allocation flags. */ public CLImageFormat[] getSupportedImage3dFormats(Mem... flags) { return getSupportedImageFormats(flags==null?0:Mem.flagsToInt(flags), CL_MEM_OBJECT_IMAGE3D); } /** * Returns the CLPlatform this context is running on. */ @Override public CLPlatform getPlatform() { return platform; } @Override public CLContext getContext() { return this; } /** * Returns a read only shapshot of all programs associated with this context. */ public List getPrograms() { synchronized(programs) { return unmodifiableList(new ArrayList(programs)); } } /** * Returns a read only shapshot of all allocated memory objects associated with this context. */ public List> getMemoryObjects() { synchronized(memoryObjects) { return unmodifiableList(new ArrayList>(memoryObjects)); } } /** * Returns a read only shapshot of all samplers associated with this context. */ public List getSamplers() { synchronized(samplers) { return unmodifiableList(new ArrayList(samplers)); } } /** * Returns the device with maximal FLOPS from this context. * The device speed is estimated by calculating the product of * MAX_COMPUTE_UNITS and MAX_CLOCK_FREQUENCY. * @see #getMaxFlopsDevice(com.jogamp.opencl.CLDevice.Type) */ public CLDevice getMaxFlopsDevice() { return CLPlatform.findMaxFlopsDevice(getDevices()); } /** * Returns the device with maximal FLOPS of the specified device type from this context. * The device speed is estimated by calculating the product of * MAX_COMPUTE_UNITS and MAX_CLOCK_FREQUENCY. */ public CLDevice getMaxFlopsDevice(CLDevice.Type type) { return CLPlatform.findMaxFlopsDevice(getDevices(), type); } /** * Returns all devices associated with this CLContext. */ public CLDevice[] getDevices() { initDevices(platform.getContextBinding()); return devices; } /** * Return the low level OpenCL interface. */ public CL getCL() { return getPlatform().getCLBinding(); } CLDevice getDevice(long dID) { CLDevice[] deviceArray = getDevices(); for (int i = 0; i < deviceArray.length; i++) { if(dID == deviceArray[i].ID) return deviceArray[i]; } return null; } protected static long toDeviceBitmap(Type[] deviceTypes) { long bitmap = 0; if (deviceTypes != null) { for (int i = 0; i < deviceTypes.length; i++) { Type type = deviceTypes[i]; if(type == null) { throw new IllegalArgumentException("Device type at index "+i+" was null."); } bitmap |= type.TYPE; } } return bitmap; } @Override public String toString() { return getClass().getSimpleName()+" [id: " + ID + ", platform: " + getPlatform().getName() + ", profile: " + getPlatform().getProfile() + ", devices: " + getDevices().length + "]"; } @Override public boolean equals(Object obj) { if (obj == null) { return false; } if (getClass() != obj.getClass()) { return false; } final CLContext other = (CLContext) obj; if (this.ID != other.ID) { return false; } return true; } @Override public int hashCode() { int hash = 7; hash = 23 * hash + (int) (this.ID ^ (this.ID >>> 32)); return hash; } protected static ErrorDispatcher createErrorHandler() { return new ErrorDispatcher(); } protected static class ErrorDispatcher implements CLErrorHandler { private CLErrorHandler[] clientHandlers = new CLErrorHandler[0]; @Override public synchronized void onError(String errinfo, ByteBuffer private_info, long cb) { CLErrorHandler[] handlers = this.clientHandlers; for (int i = 0; i < handlers.length; i++) { handlers[i].onError(errinfo, private_info, cb); } } private synchronized void addHandler(CLErrorHandler handler) { if(handler == null) { throw new IllegalArgumentException("handler was null."); } CLErrorHandler[] handlers = new CLErrorHandler[clientHandlers.length+1]; arraycopy(clientHandlers, 0, handlers, 0, clientHandlers.length); handlers[handlers.length-1] = handler; clientHandlers = handlers; } private synchronized void removeHandler(CLErrorHandler handler) { if(handler == null) { throw new IllegalArgumentException("handler was null."); } for (int i = 0; i < clientHandlers.length; i++) { if(handler.equals(clientHandlers[i])) { CLErrorHandler[] handlers = new CLErrorHandler[clientHandlers.length-1]; arraycopy(clientHandlers, 0, handlers, 0, i); arraycopy(clientHandlers, i, handlers, 0, handlers.length-i); clientHandlers = handlers; return; } } } } }