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rocm-systems/rocclr/runtime/platform/command.hpp
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foreman bafc102e17 P4 to Git Change 1477581 by wchau@wchau_WIN_OCL_HSA on 2017/11/01 16:33:34
SWDEV-136305 - [OCL 2.1 Plat] API calls for all drivers

Affected files ...

... //depot/stg/opencl/drivers/opencl/api/opencl/amdocl/cl_command.cpp#15 edit
... //depot/stg/opencl/drivers/opencl/api/opencl/amdocl/cl_svm.cpp#22 edit
... //depot/stg/opencl/drivers/opencl/runtime/platform/command.hpp#87 edit
... //depot/stg/opencl/drivers/opencl/runtime/platform/context.hpp#27 edit
2017-11-01 16:53:27 -04:00

1324 baris
44 KiB
C++

//
// Copyright 2010 Advanced Micro Devices, Inc. All rights reserved.
//
/*! \file command.hpp
* \brief Declarations for Event, Command and HostQueue objects.
*
* \author Laurent Morichetti (laurent.morichetti@amd.com)
* \date October 2008
*/
#ifndef COMMAND_HPP_
#define COMMAND_HPP_
#include "top.hpp"
#include "thread/monitor.hpp"
#include "thread/thread.hpp"
#include "platform/agent.hpp"
#include "platform/object.hpp"
#include "platform/context.hpp"
#include "platform/ndrange.hpp"
#include "platform/kernel.hpp"
#include "device/device.hpp"
#include "utils/concurrent.hpp"
#include "platform/memory.hpp"
#include "platform/perfctr.hpp"
#include "platform/threadtrace.hpp"
#include "CL/cl_ext.h"
#include <algorithm>
#include <atomic>
#include <functional>
#include <vector>
namespace amd {
/*! \addtogroup Runtime
* @{
*
* \addtogroup Commands Event, Commands and Command-Queue
* @{
*/
class Command;
class HostQueue;
/*! \brief Encapsulates the status of a command.
*
* \details An event object encapsulates the status of a Command
* it is associated with and can be used to synchronize operations
* in a Context.
*/
class Event : public RuntimeObject {
typedef void(CL_CALLBACK* CallBackFunction)(cl_event event, cl_int command_exec_status,
void* user_data);
struct CallBackEntry : public HeapObject {
struct CallBackEntry* next_; //!< the next entry in the callback list.
std::atomic<CallBackFunction> callback_; //!< callback function pointer.
void* data_; //!< user data passed to the callback function.
cl_int status_; //!< execution status triggering the callback.
CallBackEntry(cl_int status, CallBackFunction callback, void* data)
: callback_(callback), data_(data), status_(status) {}
};
public:
typedef std::vector<Event*> EventWaitList;
private:
Monitor lock_;
std::atomic<CallBackEntry*> callbacks_; //!< linked list of callback entries.
volatile cl_int status_; //!< current execution status.
std::atomic_flag notified_; //!< Command queue was notified
protected:
static const EventWaitList nullWaitList;
struct ProfilingInfo {
ProfilingInfo(bool enabled = false) : enabled_(enabled) {
if (enabled) {
clear();
callback_ = NULL;
}
}
uint64_t queued_;
uint64_t submitted_;
uint64_t start_;
uint64_t end_;
bool enabled_;
ProfilingCallback* callback_;
void clear() {
queued_ = 0ULL;
submitted_ = 0ULL;
start_ = 0ULL;
end_ = 0ULL;
}
void setCallback(ProfilingCallback* callback) {
if (callback == NULL) {
return;
}
enabled_ = true;
clear();
callback_ = callback;
}
} profilingInfo_;
//! Construct a new event.
Event();
//! Construct a new event associated to the given command \a queue.
Event(HostQueue& queue);
//! Destroy the event.
virtual ~Event();
//! Release the resources associated with this event.
virtual void releaseResources() {}
//! Record the profiling info for the given change of \a status.
// If the given \a timeStamp is 0 and profiling is enabled,
// use the current host clock time instead.
uint64_t recordProfilingInfo(cl_int status, uint64_t timeStamp = 0);
//! Process the callbacks for the given \a status change.
void processCallbacks(cl_int status) const;
public:
//! Return the context for this event.
virtual const Context& context() const = 0;
//! Return the command this event is associated with.
inline Command& command();
inline const Command& command() const;
//! Return the profiling info.
const ProfilingInfo& profilingInfo() const { return profilingInfo_; }
//! Return this command's execution status.
cl_int status() const { return status_; }
//! Insert the given \a callback into the callback stack.
bool setCallback(cl_int status, CallBackFunction callback, void* data);
/*! \brief Set the event status.
*
* \details If the status becomes CL_COMPLETE, notify all threads
* awaiting this command's completion. If the given \a timeStamp is 0
* and profiling is enabled, use the current host clock time instead.
*
* \see amd::Event::awaitCompletion
*/
bool setStatus(cl_int status, uint64_t timeStamp = 0);
//! Signal all threads waiting on this event.
void signal() {
ScopedLock lock(lock_);
lock_.notifyAll();
}
/*! \brief Suspend the current thread until the status of the Command
* associated with this event changes to CL_COMPLETE. Return true if the
* command successfully completed.
*/
virtual bool awaitCompletion();
/*! \brief Notifies current command queue about execution status
*/
bool notifyCmdQueue();
//! RTTI internal implementation
virtual ObjectType objectType() const { return ObjectTypeEvent; }
};
/*! \brief An operation that is submitted to a command queue.
*
* %Command is the abstract base type of all OpenCL operations
* submitted to a HostQueue for execution. Classes derived from
* %Command must implement the submit() function.
*
*/
class Command : public Event {
private:
//! The command queue this command is enqueue into. NULL if not yet enqueue.
HostQueue* queue_;
//! Next GPU command in the queue list
Command* next_;
const cl_command_type type_; //!< This command's OpenCL type.
volatile cl_int exception_; //!< The first raised exception.
void* data_;
protected:
//! The Events that need to complete before this command is submitted.
EventWaitList eventWaitList_;
//! Construct a new command of the given OpenCL type.
Command(HostQueue& queue, cl_command_type type,
const EventWaitList& eventWaitList = nullWaitList);
//! Construct a new command of the given OpenCL type.
Command(cl_command_type type)
: Event(),
queue_(NULL),
next_(NULL),
type_(type),
exception_(0),
data_(NULL),
eventWaitList_(nullWaitList) {}
bool terminate() {
if (Agent::shouldPostEventEvents() && type() != 0) {
Agent::postEventFree(as_cl(static_cast<Event*>(this)));
}
return true;
}
public:
//! Return the queue this command is enqueued into.
HostQueue* queue() const { return queue_; }
//! Enqueue this command into the associated command queue.
void enqueue();
//! Return the event encapsulating this command's status.
const Event& event() const { return *this; }
Event& event() { return *this; }
//! Return the list of events this command needs to wait on before dispatch
const EventWaitList& eventWaitList() const { return eventWaitList_; }
//! Return this command's OpenCL type.
cl_command_type type() const { return type_; }
//! Return the first raised exception or 0 if none.
cl_int exception() const { return exception_; }
//! Set the exception for this command.
void setException(cl_int exception) { exception_ = exception; }
//! Return the opaque, device specific data for this command.
void* data() const { return data_; }
//! Set the opaque, device specific data for this command.
void setData(void* data) { data_ = data; }
/*! \brief The execution engine for this command.
*
* \details All derived class must implement this virtual function.
*
* \note This function will execute in the command queue thread.
*/
virtual void submit(device::VirtualDevice& device) = 0;
//! Release the resources associated with this event.
virtual void releaseResources();
//! Set the next GPU command
void setNext(Command* next) { next_ = next; }
//! Get the next GPU command
Command* getNext() const { return next_; }
//! Return the context for this event.
virtual const Context& context() const;
};
class UserEvent : public Command {
const Context& context_;
public:
UserEvent(Context& context) : Command(CL_COMMAND_USER), context_(context) {
setStatus(CL_SUBMITTED);
}
virtual void submit(device::VirtualDevice& device) { ShouldNotCallThis(); }
virtual const Context& context() const { return context_; }
};
class ClGlEvent : public Command {
private:
const Context& context_;
bool waitForFence();
public:
ClGlEvent(Context& context) : Command(CL_COMMAND_GL_FENCE_SYNC_OBJECT_KHR), context_(context) {
setStatus(CL_SUBMITTED);
}
virtual void submit(device::VirtualDevice& device) { ShouldNotCallThis(); }
bool awaitCompletion() { return waitForFence(); }
virtual const Context& context() const { return context_; }
};
inline Command& Event::command() { return *static_cast<Command*>(this); }
inline const Command& Event::command() const { return *static_cast<const Command*>(this); }
class Kernel;
class NDRangeContainer;
//! A memory command that holds a single memory object reference.
//
class OneMemoryArgCommand : public Command {
protected:
Memory* memory_;
public:
OneMemoryArgCommand(HostQueue& queue, cl_command_type type, const EventWaitList& eventWaitList,
Memory& memory)
: Command(queue, type, eventWaitList), memory_(&memory) {
memory_->retain();
}
virtual void releaseResources() {
memory_->release();
DEBUG_ONLY(memory_ = NULL);
Command::releaseResources();
}
bool validateMemory();
};
//! A memory command that holds a single memory object reference.
//
class TwoMemoryArgsCommand : public Command {
protected:
Memory* memory1_;
Memory* memory2_;
public:
TwoMemoryArgsCommand(HostQueue& queue, cl_command_type type, const EventWaitList& eventWaitList,
Memory& memory1, Memory& memory2)
: Command(queue, type, eventWaitList), memory1_(&memory1), memory2_(&memory2) {
memory1_->retain();
memory2_->retain();
}
virtual void releaseResources() {
memory1_->release();
memory2_->release();
DEBUG_ONLY(memory1_ = memory2_ = NULL);
Command::releaseResources();
}
bool validateMemory();
};
/*! \brief A generic read memory command.
*
* \details Used for operations on both buffers and images. Backends
* are expected to handle any required translation. Buffers
* are treated as 1D structures so origin_[0] and size_[0]
* are equivalent to offset_ and count_ respectively.
*
* @todo Find a cleaner way of merging the row and slice pitch concepts at this level.
*
*/
class ReadMemoryCommand : public OneMemoryArgCommand {
private:
Coord3D origin_; //!< Origin of the region to read.
Coord3D size_; //!< Size of the region to read.
void* hostPtr_; //!< The host pointer destination.
size_t rowPitch_; //!< Row pitch (for image operations)
size_t slicePitch_; //!< Slice pitch (for image operations)
BufferRect bufRect_; //!< Buffer rectangle information
BufferRect hostRect_; //!< Host memory rectangle information
public:
//! Construct a new ReadMemoryCommand
ReadMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& memory, Coord3D origin, Coord3D size, void* hostPtr,
size_t rowPitch = 0, size_t slicePitch = 0)
: OneMemoryArgCommand(queue, cmdType, eventWaitList, memory),
origin_(origin),
size_(size),
hostPtr_(hostPtr),
rowPitch_(rowPitch),
slicePitch_(slicePitch) {
// Sanity checks
assert(hostPtr != NULL && "hostPtr cannot be null");
assert(size.c[0] > 0 && "invalid");
}
//! Construct a new ReadMemoryCommand
ReadMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& memory, Coord3D origin, Coord3D size, void* hostPtr,
const BufferRect& bufRect, const BufferRect& hostRect)
: OneMemoryArgCommand(queue, cmdType, eventWaitList, memory),
origin_(origin),
size_(size),
hostPtr_(hostPtr),
rowPitch_(0),
slicePitch_(0),
bufRect_(bufRect),
hostRect_(hostRect) {
// Sanity checks
assert(hostPtr != NULL && "hostPtr cannot be null");
assert(size.c[0] > 0 && "invalid");
}
virtual void submit(device::VirtualDevice& device) { device.submitReadMemory(*this); }
//! Return the memory object to read from.
Memory& source() const { return *memory_; }
//! Return the host memory to write to
void* destination() const { return hostPtr_; }
//! Return the origin of the region to read
const Coord3D& origin() const { return origin_; }
//! Return the size of the region to read
const Coord3D& size() const { return size_; }
//! Return the row pitch
size_t rowPitch() const { return rowPitch_; }
//! Return the slice pitch
size_t slicePitch() const { return slicePitch_; }
//! Return the buffer rectangle information
const BufferRect& bufRect() const { return bufRect_; }
//! Return the host rectangle information
const BufferRect& hostRect() const { return hostRect_; }
//! Return true if the entire memory object is read.
bool isEntireMemory() const;
};
/*! \brief A generic write memory command.
*
* \details Used for operations on both buffers and images. Backends
* are expected to handle any required translations. Buffers
* are treated as 1D structures so origin_[0] and size_[0]
* are equivalent to offset_ and count_ respectively.
*/
class WriteMemoryCommand : public OneMemoryArgCommand {
private:
Coord3D origin_; //!< Origin of the region to write to.
Coord3D size_; //!< Size of the region to write to.
const void* hostPtr_; //!< The host pointer source.
size_t rowPitch_; //!< Row pitch (for image operations)
size_t slicePitch_; //!< Slice pitch (for image operations)
BufferRect bufRect_; //!< Buffer rectangle information
BufferRect hostRect_; //!< Host memory rectangle information
public:
WriteMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& memory, Coord3D origin, Coord3D size, const void* hostPtr,
size_t rowPitch = 0, size_t slicePitch = 0)
: OneMemoryArgCommand(queue, cmdType, eventWaitList, memory),
origin_(origin),
size_(size),
hostPtr_(hostPtr),
rowPitch_(rowPitch),
slicePitch_(slicePitch) {
// Sanity checks
assert(hostPtr != NULL && "hostPtr cannot be null");
assert(size.c[0] > 0 && "invalid");
}
WriteMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& memory, Coord3D origin, Coord3D size, const void* hostPtr,
const BufferRect& bufRect, const BufferRect& hostRect)
: OneMemoryArgCommand(queue, cmdType, eventWaitList, memory),
origin_(origin),
size_(size),
hostPtr_(hostPtr),
rowPitch_(0),
slicePitch_(0),
bufRect_(bufRect),
hostRect_(hostRect) {
// Sanity checks
assert(hostPtr != NULL && "hostPtr cannot be null");
assert(size.c[0] > 0 && "invalid");
}
virtual void submit(device::VirtualDevice& device) { device.submitWriteMemory(*this); }
//! Return the host memory to read from
const void* source() const { return hostPtr_; }
//! Return the memory object to write to.
Memory& destination() const { return *memory_; }
//! Return the region origin
const Coord3D& origin() const { return origin_; }
//! Return the region size
const Coord3D& size() const { return size_; }
//! Return the row pitch
size_t rowPitch() const { return rowPitch_; }
//! Return the slice pitch
size_t slicePitch() const { return slicePitch_; }
//! Return the buffer rectangle information
const BufferRect& bufRect() const { return bufRect_; }
//! Return the host rectangle information
const BufferRect& hostRect() const { return hostRect_; }
//! Return true if the entire memory object is written.
bool isEntireMemory() const;
};
/*! \brief A generic fill memory command.
*
* \details Used for operations on both buffers and images. Backends
* are expected to handle any required translations. Buffers
* are treated as 1D structures so origin_[0] and size_[0]
* are equivalent to offset_ and count_ respectively.
*/
class FillMemoryCommand : public OneMemoryArgCommand {
public:
const static size_t MaxFillPatterSize = sizeof(cl_double16);
private:
Coord3D origin_; //!< Origin of the region to write to.
Coord3D size_; //!< Size of the region to write to.
char pattern_[MaxFillPatterSize]; //!< The fill pattern
size_t patternSize_; //!< Pattern size
public:
FillMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& memory, const void* pattern, size_t patternSize, Coord3D origin,
Coord3D size)
: OneMemoryArgCommand(queue, cmdType, eventWaitList, memory),
origin_(origin),
size_(size),
patternSize_(patternSize) {
// Sanity checks
assert(pattern != NULL && "pattern cannot be null");
assert(size.c[0] > 0 && "invalid");
memcpy(pattern_, pattern, patternSize);
}
virtual void submit(device::VirtualDevice& device) { device.submitFillMemory(*this); }
//! Return the pattern memory to fill with
const void* pattern() const { return reinterpret_cast<const void*>(pattern_); }
//! Return the pattern size
const size_t patternSize() const { return patternSize_; }
//! Return the memory object to write to.
Memory& memory() const { return *memory_; }
//! Return the region origin
const Coord3D& origin() const { return origin_; }
//! Return the region size
const Coord3D& size() const { return size_; }
//! Return true if the entire memory object is written.
bool isEntireMemory() const;
};
/*! \brief A generic copy memory command
*
* \details Used for both buffers and images. Backends are expected
* to handle any required translation. Buffers are treated
* as 1D structures so origin_[0] and size_[0] are
* equivalent to offset_ and count_ respectively.
*/
class CopyMemoryCommand : public TwoMemoryArgsCommand {
private:
Coord3D srcOrigin_; //!< Origin of the source region.
Coord3D dstOrigin_; //!< Origin of the destination region.
Coord3D size_; //!< Size of the region to copy.
BufferRect srcRect_; //!< Source buffer rectangle information
BufferRect dstRect_; //!< Destination buffer rectangle information
public:
CopyMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& srcMemory, Memory& dstMemory, Coord3D srcOrigin, Coord3D dstOrigin,
Coord3D size)
: TwoMemoryArgsCommand(queue, cmdType, eventWaitList, srcMemory, dstMemory),
srcOrigin_(srcOrigin),
dstOrigin_(dstOrigin),
size_(size) {
// Sanity checks
assert(size.c[0] > 0 && "invalid");
}
CopyMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& srcMemory, Memory& dstMemory, Coord3D srcOrigin, Coord3D dstOrigin,
Coord3D size, const BufferRect& srcRect, const BufferRect& dstRect)
: TwoMemoryArgsCommand(queue, cmdType, eventWaitList, srcMemory, dstMemory),
srcOrigin_(srcOrigin),
dstOrigin_(dstOrigin),
size_(size),
srcRect_(srcRect),
dstRect_(dstRect) {
// Sanity checks
assert(size.c[0] > 0 && "invalid");
}
virtual void submit(device::VirtualDevice& device) { device.submitCopyMemory(*this); }
//! Return the host memory to read from
Memory& source() const { return *memory1_; }
//! Return the memory object to write to.
Memory& destination() const { return *memory2_; }
//! Return the source origin
const Coord3D& srcOrigin() const { return srcOrigin_; }
//! Return the offset in bytes in the destination.
const Coord3D& dstOrigin() const { return dstOrigin_; }
//! Return the number of bytes to copy.
const Coord3D& size() const { return size_; }
//! Return the source buffer rectangle information
const BufferRect& srcRect() const { return srcRect_; }
//! Return the destination buffer rectangle information
const BufferRect& dstRect() const { return dstRect_; }
//! Return true if the both memories are is read/written in their entirety.
bool isEntireMemory() const;
};
/*! \brief A generic map memory command. Makes a memory object accessible to the host.
*
* @todo:dgladdin Need to think more about how the pitch parameters operate in
* the context of unified buffer/image commands.
*/
class MapMemoryCommand : public OneMemoryArgCommand {
private:
cl_map_flags mapFlags_; //!< Flags controlling the map.
bool blocking_; //!< True for blocking maps
Coord3D origin_; //!< Origin of the region to map.
Coord3D size_; //!< Size of the region to map.
const void* mapPtr_; //!< Host-space pointer that the object is currently mapped at
public:
//! Construct a new MapMemoryCommand
MapMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& memory, cl_map_flags mapFlags, bool blocking, Coord3D origin,
Coord3D size, size_t* imgRowPitch = nullptr, size_t* imgSlicePitch = nullptr,
void* mapPtr = nullptr)
: OneMemoryArgCommand(queue, cmdType, eventWaitList, memory),
mapFlags_(mapFlags),
blocking_(blocking),
origin_(origin),
size_(size),
mapPtr_(mapPtr) {
// Sanity checks
assert(size.c[0] > 0 && "invalid");
}
virtual void submit(device::VirtualDevice& device) { device.submitMapMemory(*this); }
//! Read the memory object
Memory& memory() const { return *memory_; }
//! Read the map control flags
cl_map_flags mapFlags() const { return mapFlags_; }
//! Read the origin
const Coord3D& origin() const { return origin_; }
//! Read the size
const Coord3D& size() const { return size_; }
//! Read the blocking flag
bool blocking() const { return blocking_; }
//! Returns true if the entire memory object is mapped
bool isEntireMemory() const;
//! Read the map pointer
const void* mapPtr() const { return mapPtr_; }
};
/*! \brief A generic unmap memory command.
*
* @todo:dgladdin Need to think more about how the pitch parameters operate in
* the context of unified buffer/image commands.
*/
class UnmapMemoryCommand : public OneMemoryArgCommand {
private:
//! Host-space pointer that the object is currently mapped at
void* mapPtr_;
public:
//! Construct a new MapMemoryCommand
UnmapMemoryCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& memory, void* mapPtr)
: OneMemoryArgCommand(queue, cmdType, eventWaitList, memory), mapPtr_(mapPtr) {}
virtual void submit(device::VirtualDevice& device) { device.submitUnmapMemory(*this); }
virtual void releaseResources();
//! Read the memory object
Memory& memory() const { return *memory_; }
//! Read the map pointer
void* mapPtr() const { return mapPtr_; }
};
/*! \brief Migrate memory objects command.
*
* \details Used for operations on both buffers and images. Backends
* are expected to handle any required translations.
*/
class MigrateMemObjectsCommand : public Command {
private:
cl_mem_migration_flags migrationFlags_; //!< Migration flags
std::vector<amd::Memory*> memObjects_; //!< The list of memory objects
public:
//! Construct a new AcquireExtObjectsCommand
MigrateMemObjectsCommand(HostQueue& queue, cl_command_type type,
const EventWaitList& eventWaitList,
const std::vector<amd::Memory*>& memObjects,
cl_mem_migration_flags flags)
: Command(queue, type, eventWaitList), migrationFlags_(flags) {
std::vector<amd::Memory*>::const_iterator itr;
for (itr = memObjects.begin(); itr != memObjects.end(); itr++) {
(*itr)->retain();
memObjects_.push_back(*itr);
}
}
virtual void submit(device::VirtualDevice& device) { device.submitMigrateMemObjects(*this); }
//! Release all resources associated with this command
void releaseResources() {
std::vector<amd::Memory*>::const_iterator itr;
for (itr = memObjects_.begin(); itr != memObjects_.end(); itr++) {
(*itr)->release();
}
Command::releaseResources();
}
//! Returns the migration flags
cl_mem_migration_flags migrationFlags() const { return migrationFlags_; }
//! Returns the number of memory objects in the command
cl_uint numMemObjects() const { return (cl_uint)memObjects_.size(); }
//! Returns a pointer to the memory objects
const std::vector<amd::Memory*>& memObjects() const { return memObjects_; }
bool validateMemory();
};
//! To execute a kernel on a specific device.
class NDRangeKernelCommand : public Command {
private:
Kernel& kernel_;
NDRangeContainer sizes_;
address parameters_;
public:
//! Construct an ExecuteKernel command
NDRangeKernelCommand(HostQueue& queue, const EventWaitList& eventWaitList, Kernel& kernel,
const NDRangeContainer& sizes);
virtual void submit(device::VirtualDevice& device) { device.submitKernel(*this); }
//! Release all resources associated with this command (
void releaseResources();
//! Return the kernel.
const Kernel& kernel() const { return kernel_; }
//! Return the parameters given to this kernel.
const_address parameters() const { return parameters_; }
//! Return the kernel NDRange.
const NDRangeContainer& sizes() const { return sizes_; }
//! Set the local work size.
void setLocalWorkSize(const NDRange& local) { sizes_.local() = local; }
cl_int validateMemory();
};
class NativeFnCommand : public Command {
private:
void(CL_CALLBACK* nativeFn_)(void*);
char* args_;
size_t argsSize_;
std::vector<Memory*> memObjects_;
std::vector<size_t> memOffsets_;
public:
NativeFnCommand(HostQueue& queue, const EventWaitList& eventWaitList,
void(CL_CALLBACK* nativeFn)(void*), const void* args, size_t argsSize,
size_t numMemObjs, const cl_mem* memObjs, const void** memLocs);
~NativeFnCommand() { delete[] args_; }
void releaseResources() {
std::for_each(memObjects_.begin(), memObjects_.end(), std::mem_fun(&Memory::release));
Command::releaseResources();
}
virtual void submit(device::VirtualDevice& device) { device.submitNativeFn(*this); }
cl_int invoke();
};
class Marker : public Command {
public:
//! Create a new Marker
Marker(HostQueue& queue, bool userVisible, const EventWaitList& eventWaitList = nullWaitList,
const Event* waitingEvent = NULL)
: Command(queue, userVisible ? CL_COMMAND_MARKER : 0, eventWaitList),
waitingEvent_(waitingEvent) {}
//! The actual command implementation.
virtual void submit(device::VirtualDevice& device) { device.submitMarker(*this); }
const Event* waitingEvent() const { return waitingEvent_; }
private:
const Event* waitingEvent_; //!< Waiting event associated with the marker
};
/*! \brief Maps CL objects created from external ones and syncs the contents (blocking).
*
*/
class ExtObjectsCommand : public Command {
private:
std::vector<amd::Memory*> memObjects_; //!< The list of Memory based classes
public:
//! Construct a new AcquireExtObjectsCommand
ExtObjectsCommand(HostQueue& queue, const EventWaitList& eventWaitList, cl_uint num_objects,
const std::vector<amd::Memory*>& memoryObjects, cl_command_type type)
: Command(queue, type, eventWaitList) {
for (std::vector<amd::Memory*>::const_iterator itr = memoryObjects.begin();
itr != memoryObjects.end(); itr++) {
(*itr)->retain();
memObjects_.push_back(*itr);
}
}
//! Release all resources associated with this command
void releaseResources() {
for (std::vector<amd::Memory*>::const_iterator itr = memObjects_.begin();
itr != memObjects_.end(); itr++) {
(*itr)->release();
}
Command::releaseResources();
}
//! Get number of GL objects
cl_uint getNumObjects() { return (cl_uint)memObjects_.size(); }
//! Get pointer to GL object list
const std::vector<amd::Memory*>& getMemList() const { return memObjects_; }
bool validateMemory();
virtual bool processGLResource(device::Memory* mem) = 0;
};
class AcquireExtObjectsCommand : public ExtObjectsCommand {
public:
//! Construct a new AcquireExtObjectsCommand
AcquireExtObjectsCommand(HostQueue& queue, const EventWaitList& eventWaitList,
cl_uint num_objects, const std::vector<amd::Memory*>& memoryObjects,
cl_command_type type)
: ExtObjectsCommand(queue, eventWaitList, num_objects, memoryObjects, type) {}
virtual void submit(device::VirtualDevice& device) { device.submitAcquireExtObjects(*this); }
virtual bool processGLResource(device::Memory* mem);
};
class ReleaseExtObjectsCommand : public ExtObjectsCommand {
public:
//! Construct a new ReleaseExtObjectsCommand
ReleaseExtObjectsCommand(HostQueue& queue, const EventWaitList& eventWaitList,
cl_uint num_objects, const std::vector<amd::Memory*>& memoryObjects,
cl_command_type type)
: ExtObjectsCommand(queue, eventWaitList, num_objects, memoryObjects, type) {}
virtual void submit(device::VirtualDevice& device) { device.submitReleaseExtObjects(*this); }
virtual bool processGLResource(device::Memory* mem);
};
class PerfCounterCommand : public Command {
public:
typedef std::vector<PerfCounter*> PerfCounterList;
enum State {
Begin = 0, //!< Issue a begin command
End = 1 //!< Issue an end command
};
//! Construct a new PerfCounterCommand
PerfCounterCommand(HostQueue& queue, const EventWaitList& eventWaitList,
const PerfCounterList& counterList, State state)
: Command(queue, 1, eventWaitList), counterList_(counterList), state_(state) {
for (uint i = 0; i < counterList_.size(); ++i) {
counterList_[i]->retain();
}
}
void releaseResources() {
for (uint i = 0; i < counterList_.size(); ++i) {
counterList_[i]->release();
}
Command::releaseResources();
}
//! Gets the number of PerfCounter objects
size_t getNumCounters() const { return counterList_.size(); }
//! Gets the list of all counters
const PerfCounterList& getCounters() const { return counterList_; }
//! Gets the performance counter state
State getState() const { return state_; }
//! Process the command on the device queue
virtual void submit(device::VirtualDevice& device) { device.submitPerfCounter(*this); }
private:
PerfCounterList counterList_; //!< The list of performance counters
State state_; //!< State of the issued command
};
/*! \brief Thread Trace memory objects command.
*
* \details Used for bindig memory objects to therad trace mechanism.
*/
class ThreadTraceMemObjectsCommand : public Command {
public:
//! Construct a new ThreadTraceMemObjectsCommand
ThreadTraceMemObjectsCommand(HostQueue& queue, const EventWaitList& eventWaitList,
size_t numMemoryObjects, const cl_mem* memoryObjects,
size_t sizeMemoryObject, ThreadTrace& threadTrace,
cl_command_type type)
: Command(queue, type, eventWaitList),
sizeMemObjects_(sizeMemoryObject),
threadTrace_(threadTrace) {
memObjects_.resize(numMemoryObjects);
for (size_t i = 0; i < numMemoryObjects; ++i) {
Memory* obj = as_amd(memoryObjects[i]);
obj->retain();
memObjects_[i] = obj;
}
threadTrace_.retain();
}
//! Release all resources associated with this command
void releaseResources() {
threadTrace_.release();
for (std::vector<amd::Memory*>::const_iterator itr = memObjects_.begin();
itr != memObjects_.end(); itr++) {
(*itr)->release();
}
Command::releaseResources();
}
//! Get number of CL memory objects
cl_uint getNumObjects() { return (cl_uint)memObjects_.size(); }
//! Get pointer to CL memory object list
const std::vector<amd::Memory*>& getMemList() const { return memObjects_; }
//! Submit command to bind memory object to the Thread Trace mechanism
virtual void submit(device::VirtualDevice& device) { device.submitThreadTraceMemObjects(*this); }
//! Return the thread trace object.
ThreadTrace& getThreadTrace() const { return threadTrace_; }
//! Get memory object size
const size_t getMemoryObjectSize() const { return sizeMemObjects_; }
//! Validate memory bound to the thread thrace
bool validateMemory();
private:
std::vector<amd::Memory*> memObjects_; //!< The list of memory objects,bound to the thread trace
size_t sizeMemObjects_; //!< The size of each memory object from memObjects_ list (all memory
//!objects have the smae size)
ThreadTrace& threadTrace_; //!< The Thread Trace object
};
/*! \brief Thread Trace command.
*
* \details Used for issue begin/end/pause/resume for therad trace object.
*/
class ThreadTraceCommand : public Command {
private:
void* threadTraceConfig_;
public:
enum State {
Begin = 0, //!< Issue a begin command
End = 1, //!< Issue an end command
Pause = 2, //!< Issue a pause command
Resume = 3 //!< Issue a resume command
};
//! Construct a new ThreadTraceCommand
ThreadTraceCommand(HostQueue& queue, const EventWaitList& eventWaitList,
const void* threadTraceConfig, ThreadTrace& threadTrace, State state,
cl_command_type type)
: Command(queue, type, eventWaitList), threadTrace_(threadTrace), state_(state) {
const unsigned int size = *static_cast<const unsigned int*>(threadTraceConfig);
threadTraceConfig_ = static_cast<void*>(new char[size]);
if (threadTraceConfig_) {
memcpy(threadTraceConfig_, threadTraceConfig, size);
}
threadTrace_.retain();
}
//! Release all resources associated with this command
void releaseResources() {
threadTrace_.release();
Command::releaseResources();
}
//! Get the thread trace object
ThreadTrace& getThreadTrace() const { return threadTrace_; }
//! Get the thread trace command state
State getState() const { return state_; }
//! Process the command on the device queue
virtual void submit(device::VirtualDevice& device) { device.submitThreadTrace(*this); }
// Accessor methods
void* threadTraceConfig() const { return threadTraceConfig_; }
private:
ThreadTrace& threadTrace_; //!< The list of performance counters
State state_; //!< State of the issued command
};
class SignalCommand : public OneMemoryArgCommand {
private:
cl_uint markerValue_;
cl_ulong markerOffset_;
public:
SignalCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& memory, cl_uint value, cl_ulong offset = 0)
: OneMemoryArgCommand(queue, cmdType, eventWaitList, memory),
markerValue_(value),
markerOffset_(offset) {}
virtual void submit(device::VirtualDevice& device) { device.submitSignal(*this); }
const cl_uint markerValue() { return markerValue_; }
Memory& memory() { return *memory_; }
const cl_ulong markerOffset() { return markerOffset_; }
};
class MakeBuffersResidentCommand : public Command {
private:
std::vector<amd::Memory*> memObjects_;
cl_bus_address_amd* busAddresses_;
public:
MakeBuffersResidentCommand(HostQueue& queue, cl_command_type type,
const EventWaitList& eventWaitList,
const std::vector<amd::Memory*>& memObjects,
cl_bus_address_amd* busAddr)
: Command(queue, type, eventWaitList), busAddresses_(busAddr) {
std::vector<amd::Memory*>::const_iterator itr;
for (itr = memObjects.begin(); itr != memObjects.end(); itr++) {
(*itr)->retain();
memObjects_.push_back(*itr);
}
}
virtual void submit(device::VirtualDevice& device) { device.submitMakeBuffersResident(*this); }
void releaseResources() {
std::vector<amd::Memory*>::const_iterator itr;
for (itr = memObjects_.begin(); itr != memObjects_.end(); itr++) {
(*itr)->release();
}
Command::releaseResources();
}
bool validateMemory();
const std::vector<amd::Memory*>& memObjects() const { return memObjects_; }
cl_bus_address_amd* busAddress() const { return busAddresses_; }
};
//! A deallocation command used to free SVM or system pointers.
class SvmFreeMemoryCommand : public Command {
public:
typedef void(CL_CALLBACK* freeCallBack)(cl_command_queue, cl_uint, void**, void*);
private:
std::vector<void*> svmPointers_; //!< List of pointers to deallocate
freeCallBack pfnFreeFunc_; //!< User-defined deallocation callback
void* userData_; //!< Data passed to user-defined callback
public:
SvmFreeMemoryCommand(HostQueue& queue, const EventWaitList& eventWaitList, cl_uint numSvmPointers,
void** svmPointers, freeCallBack pfnFreeFunc, void* userData)
: Command(queue, CL_COMMAND_SVM_FREE, eventWaitList),
//! We copy svmPointers since it can be reused/deallocated after
// command creation
svmPointers_(svmPointers, svmPointers + numSvmPointers),
pfnFreeFunc_(pfnFreeFunc),
userData_(userData) {}
virtual void submit(device::VirtualDevice& device) { device.submitSvmFreeMemory(*this); }
std::vector<void*>& svmPointers() { return svmPointers_; }
freeCallBack pfnFreeFunc() const { return pfnFreeFunc_; }
void* userData() const { return userData_; }
};
//! A copy command where the origin and destination memory locations are SVM
// pointers.
class SvmCopyMemoryCommand : public Command {
private:
void* dst_; //!< Destination pointer
const void* src_; //!< Source pointer
size_t srcSize_; //!< Size (in bytes) of the source buffer
public:
SvmCopyMemoryCommand(HostQueue& queue, const EventWaitList& eventWaitList, void* dst,
const void* src, size_t srcSize)
: Command(queue, CL_COMMAND_SVM_MEMCPY, eventWaitList),
dst_(dst),
src_(src),
srcSize_(srcSize) {}
virtual void submit(device::VirtualDevice& device) { device.submitSvmCopyMemory(*this); }
void* dst() const { return dst_; }
const void* src() const { return src_; }
size_t srcSize() const { return srcSize_; }
};
//! A fill command where the pattern and destination memory locations are SVM
// pointers.
class SvmFillMemoryCommand : public Command {
private:
void* dst_; //!< Destination pointer
char pattern_[FillMemoryCommand::MaxFillPatterSize]; //!< The fill pattern
size_t patternSize_; //!< Pattern size
size_t times_; //!< Number of times to fill the
// destination buffer with the source buffer
public:
SvmFillMemoryCommand(HostQueue& queue, const EventWaitList& eventWaitList, void* dst,
const void* pattern, size_t patternSize, size_t size)
: Command(queue, CL_COMMAND_SVM_MEMFILL, eventWaitList),
dst_(dst),
patternSize_(patternSize),
times_(size / patternSize) {
assert(amd::isMultipleOf(size, patternSize));
//! We copy the pattern buffer since it can be reused/deallocated after
// command creation
memcpy(pattern_, pattern, patternSize);
}
virtual void submit(device::VirtualDevice& device) { device.submitSvmFillMemory(*this); }
void* dst() const { return dst_; }
const char* pattern() const { return pattern_; }
size_t patternSize() const { return patternSize_; }
size_t times() const { return times_; }
};
/*! \brief A map memory command where the pointer to be mapped is a SVM shared
* buffer
*/
class SvmMapMemoryCommand : public Command {
private:
Memory* svmMem_; //!< the pointer to the amd::Memory object corresponding the svm pointer mapped
Coord3D size_; //!< the map size
Coord3D origin_; //!< the origin of the mapped svm pointer shift from the beginning of svm space
//!allocated
cl_map_flags flags_; //!< map flags
void* svmPtr_;
public:
SvmMapMemoryCommand(HostQueue& queue, const EventWaitList& eventWaitList, Memory* svmMem,
const size_t size, const size_t offset, cl_map_flags flags, void* svmPtr)
: Command(queue, CL_COMMAND_SVM_MAP, eventWaitList),
svmMem_(svmMem),
size_(size),
origin_(offset),
flags_(flags),
svmPtr_(svmPtr) {}
virtual void submit(device::VirtualDevice& device) { device.submitSvmMapMemory(*this); }
Memory* getSvmMem() const { return svmMem_; }
Coord3D size() const { return size_; }
cl_map_flags mapFlags() const { return flags_; }
Coord3D origin() const { return origin_; }
void* svmPtr() const { return svmPtr_; }
bool isEntireMemory() const;
};
/*! \brief An unmap memory command where the unmapped pointer is a SVM shared
* buffer
*/
class SvmUnmapMemoryCommand : public Command {
private:
Memory* svmMem_; //!< the pointer to the amd::Memory object corresponding the svm pointer mapped
void* svmPtr_; //!< SVM pointer
public:
SvmUnmapMemoryCommand(HostQueue& queue, const EventWaitList& eventWaitList, Memory* svmMem,
void* svmPtr)
: Command(queue, CL_COMMAND_SVM_UNMAP, eventWaitList), svmMem_(svmMem), svmPtr_(svmPtr) {}
virtual void submit(device::VirtualDevice& device) { device.submitSvmUnmapMemory(*this); }
Memory* getSvmMem() const { return svmMem_; }
void* svmPtr() const { return svmPtr_; }
};
/*! \brief A generic transfer memory from/to file command.
*
* \details Currently supports buffers only. Buffers
* are treated as 1D structures so origin_[0] and size_[0]
* are equivalent to offset_ and count_ respectively.
*/
class TransferBufferFileCommand : public OneMemoryArgCommand {
public:
static const uint NumStagingBuffers = 2;
static const size_t StagingBufferSize = 4 * Mi;
static const uint StagingBufferMemType = CL_MEM_USE_PERSISTENT_MEM_AMD;
protected:
const Coord3D origin_; //!< Origin of the region to write to
const Coord3D size_; //!< Size of the region to write to
LiquidFlashFile* file_; //!< The file object for data read
size_t fileOffset_; //!< Offset in the file for data read
amd::Memory* staging_[NumStagingBuffers]; //!< Staging buffers for transfer
public:
TransferBufferFileCommand(cl_command_type type, HostQueue& queue,
const EventWaitList& eventWaitList, Memory& memory,
const Coord3D& origin, const Coord3D& size, LiquidFlashFile* file,
size_t fileOffset)
: OneMemoryArgCommand(queue, type, eventWaitList, memory),
origin_(origin),
size_(size),
file_(file),
fileOffset_(fileOffset) {
// Sanity checks
assert(size.c[0] > 0 && "invalid");
for (uint i = 0; i < NumStagingBuffers; ++i) {
staging_[i] = NULL;
}
}
virtual void releaseResources();
virtual void submit(device::VirtualDevice& device);
//! Return the memory object to write to
Memory& memory() const { return *memory_; }
//! Return the host memory to read from
LiquidFlashFile* file() const { return file_; }
//! Returns file offset
size_t fileOffset() const { return fileOffset_; }
//! Return the region origin
const Coord3D& origin() const { return origin_; }
//! Return the region size
const Coord3D& size() const { return size_; }
//! Return the staging buffer for transfer
Memory& staging(uint i) const { return *staging_[i]; }
bool validateMemory();
};
/*! \brief A P2P copy memory command
*
* \details Used for buffers only. Backends are expected
* to handle any required translation. Buffers are treated
* as 1D structures so origin_[0] and size_[0] are
* equivalent to offset_ and count_ respectively.
*/
class CopyMemoryP2PCommand : public CopyMemoryCommand {
public:
CopyMemoryP2PCommand(HostQueue& queue, cl_command_type cmdType, const EventWaitList& eventWaitList,
Memory& srcMemory, Memory& dstMemory, Coord3D srcOrigin, Coord3D dstOrigin,
Coord3D size)
: CopyMemoryCommand(queue, cmdType, eventWaitList, srcMemory, dstMemory, srcOrigin, dstOrigin, size)
{
}
virtual void submit(device::VirtualDevice& device) { device.submitCopyMemoryP2P(*this); }
bool validateMemory();
};
/*! @}
* @}
*/
} // namespace amd
#endif /*COMMAND_HPP_*/