unsupported/Eigen/CXX11/src/Tensor/TensorDeviceSycl.h - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Mehdi Goli    Codeplay Software Ltd.
 // Ralph Potter  Codeplay Software Ltd.
 // Luke Iwanski  Codeplay Software Ltd.
 // Contact: <eigen@codeplay.com>
 // Copyright (C) 2016 Benoit Steiner <benoit.steiner.goog@gmail.com>

 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #if defined(EIGEN_USE_SYCL) && !defined(EIGEN_CXX11_TENSOR_TENSOR_DEVICE_SYCL_H)
 #define EIGEN_CXX11_TENSOR_TENSOR_DEVICE_SYCL_H

 namespace Eigen {

   #define ConvertToActualTypeSycl(Scalar, buf_acc) reinterpret_cast<typename cl::sycl::global_ptr<Scalar>::pointer_t>((&(*buf_acc.get_pointer())))

   template <typename Scalar> class MemCopyFunctor {
   public:
     typedef cl::sycl::accessor<uint8_t, 1, cl::sycl::access::mode::read, cl::sycl::access::target::global_buffer> read_accessor;
     typedef cl::sycl::accessor<uint8_t, 1, cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer> write_accessor;

     MemCopyFunctor(read_accessor src_acc, write_accessor dst_acc, size_t rng, size_t i, size_t offset): m_src_acc(src_acc), m_dst_acc(dst_acc), m_rng(rng), m_i(i), m_offset(offset) {}

     void operator()(cl::sycl::nd_item<1> itemID) {
       auto src_ptr = ConvertToActualTypeSycl(Scalar, m_src_acc);
       auto dst_ptr = ConvertToActualTypeSycl(Scalar, m_dst_acc);
       auto globalid = itemID.get_global_linear_id();
       if (globalid < m_rng) {
         dst_ptr[globalid + m_i] = src_ptr[globalid + m_offset];
       }
     }

   private:
     read_accessor m_src_acc;
     write_accessor m_dst_acc;
     size_t m_rng;
     size_t m_i;
     size_t m_offset;
   };

   struct memsetkernelFunctor{
    typedef cl::sycl::accessor<uint8_t, 1, cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer> AccType;
    AccType m_acc;
    const size_t m_rng, m_c;
    memsetkernelFunctor(AccType acc, const size_t rng, const size_t c):m_acc(acc), m_rng(rng), m_c(c){}
    void operator()(cl::sycl::nd_item<1> itemID) {
      auto globalid=itemID.get_global_linear_id();
      if (globalid< m_rng) m_acc[globalid] = m_c;
    }

   };

 EIGEN_STRONG_INLINE auto get_sycl_supported_devices()->decltype(cl::sycl::device::get_devices()){
   auto devices = cl::sycl::device::get_devices();
   std::vector<cl::sycl::device>::iterator it =devices.begin();
   while(it!=devices.end()) {
     /// get_devices returns all the available opencl devices. Either use device_selector or exclude devices that computecpp does not support (AMD OpenCL for CPU )
     auto s=  (*it).template get_info<cl::sycl::info::device::vendor>();
     std::transform(s.begin(), s.end(), s.begin(), ::tolower);
     if((*it).is_cpu() && s.find("amd")!=std::string::npos){ // remove amd cpu as it is not supported by computecpp
       it=devices.erase(it);
     }
     else{
       ++it;
     }
   }
   return devices;
 }

 struct QueueInterface {
   /// class members:
   bool exception_caught_ = false;

   mutable std::mutex mutex_;

   /// std::map is the container used to make sure that we create only one buffer
   /// per pointer. The lifespan of the buffer now depends on the lifespan of SyclDevice.
   /// If a non-read-only pointer is needed to be accessed on the host we should manually deallocate it.
   mutable std::map<const uint8_t *, cl::sycl::buffer<uint8_t, 1>> buffer_map;
   /// sycl queue
   mutable cl::sycl::queue m_queue;
   /// creating device by using cl::sycl::selector or cl::sycl::device both are the same and can be captured through dev_Selector typename
   /// SyclStreamDevice is not owned. it is the caller's responsibility to destroy it.
   template<typename dev_Selector> explicit QueueInterface(const dev_Selector& s):
 #ifdef EIGEN_EXCEPTIONS
   m_queue(cl::sycl::queue(s, [&](cl::sycl::exception_list l) {
     for (const auto& e : l) {
       try {
         if (e) {
            exception_caught_ = true;
            std::rethrow_exception(e);
         }
       } catch (cl::sycl::exception e) {
         std::cerr << e.what() << std::endl;
       }
     }
   }))
 #else
 m_queue(cl::sycl::queue(s, [&](cl::sycl::exception_list l) {
   for (const auto& e : l) {
       if (e) {
          exception_caught_ = true;
          std::cerr << "Error detected Inside Sycl Device."<< std::endl;

       }
   }
 }))
 #endif
   {}

   /// Allocating device pointer. This pointer is actually an 8 bytes host pointer used as key to access the sycl device buffer.
   /// The reason is that we cannot use device buffer as a pointer as a m_data in Eigen leafNode expressions. So we create a key
   /// pointer to be used in Eigen expression construction. When we convert the Eigen construction into the sycl construction we
   /// use this pointer as a key in our buffer_map and we make sure that we dedicate only one buffer only for this pointer.
   /// The device pointer would be deleted by calling deallocate function.
   EIGEN_STRONG_INLINE void* allocate(size_t num_bytes) const {
     auto buf = cl::sycl::buffer<uint8_t,1>(cl::sycl::range<1>(num_bytes));
     auto ptr =buf.get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::host_buffer>().get_pointer();
     buf.set_final_data(nullptr);
     std::lock_guard<std::mutex> lock(mutex_);
     buffer_map.insert(std::pair<const uint8_t *, cl::sycl::buffer<uint8_t, 1>>(static_cast<const uint8_t*>(ptr),buf));
     return static_cast<void*>(ptr);
   }

   /// This is used to deallocate the device pointer. p is used as a key inside
   /// the map to find the device buffer and delete it.
   EIGEN_STRONG_INLINE void deallocate(void *p) const {
     std::lock_guard<std::mutex> lock(mutex_);
     auto it = buffer_map.find(static_cast<const uint8_t*>(p));
     if (it != buffer_map.end()) {
       auto num_bytes =it->second.get_size();
       buffer_map.erase(it);
       // Temporary solution for memory leak in computecpp. It will be fixed in the next computecpp version
       std::allocator<uint8_t> a1; // Default allocator for buffer<uint8_t,1>
       a1.deallocate(static_cast<uint8_t*>(p), num_bytes);
     }
   }

   EIGEN_STRONG_INLINE void deallocate_all() const {
     std::lock_guard<std::mutex> lock(mutex_);
     buffer_map.clear();
   }

   EIGEN_STRONG_INLINE std::map<const uint8_t *, cl::sycl::buffer<uint8_t,1>>::iterator find_buffer(const void* ptr) const {
     std::lock_guard<std::mutex> lock(mutex_);
     auto it1 = buffer_map.find(static_cast<const uint8_t*>(ptr));
     if (it1 != buffer_map.end()){
       return it1;
     }
     else{
       for(std::map<const uint8_t *, cl::sycl::buffer<uint8_t,1>>::iterator it=buffer_map.begin(); it!=buffer_map.end(); ++it){
         auto size = it->second.get_size();
         if((it->first <  (static_cast<const uint8_t*>(ptr))) && ((static_cast<const uint8_t*>(ptr)) < (it->first + size)) ) return it;
       }
     }
     std::cerr << "No sycl buffer found. Make sure that you have allocated memory for your buffer by calling allocate function in SyclDevice"<< std::endl;
     abort();
   }

   // This function checks if the runtime recorded an error for the
   // underlying stream device.
   EIGEN_STRONG_INLINE bool ok() const {
     if (!exception_caught_) {
       m_queue.wait_and_throw();
     }
     return !exception_caught_;
   }

   // destructor
   ~QueueInterface() { buffer_map.clear(); }
 };

 struct SyclDevice {
   // class member.
   QueueInterface* m_queue_stream;
   /// QueueInterface is not owned. it is the caller's responsibility to destroy it.
   explicit SyclDevice(QueueInterface* queue_stream) : m_queue_stream(queue_stream){}

   /// Creation of sycl accessor for a buffer. This function first tries to find
   /// the buffer in the buffer_map. If found it gets the accessor from it, if not,
   /// the function then adds an entry by creating a sycl buffer for that particular pointer.
   template <cl::sycl::access::mode AcMd> EIGEN_STRONG_INLINE cl::sycl::accessor<uint8_t, 1, AcMd, cl::sycl::access::target::global_buffer>
   get_sycl_accessor(cl::sycl::handler &cgh, const void* ptr) const {
     return (get_sycl_buffer(ptr).template get_access<AcMd, cl::sycl::access::target::global_buffer>(cgh));
   }

   /// Accessing the created sycl device buffer for the device pointer
   EIGEN_STRONG_INLINE cl::sycl::buffer<uint8_t, 1>& get_sycl_buffer(const void * ptr) const {
     return m_queue_stream->find_buffer(ptr)->second;
   }

   /// This is used to prepare the number of threads and also the number of threads per block for sycl kernels
   template<typename Index>
   EIGEN_STRONG_INLINE void parallel_for_setup(Index n, Index &tileSize, Index &rng, Index &GRange)  const {
     tileSize =static_cast<Index>(sycl_queue().get_device(). template get_info<cl::sycl::info::device::max_work_group_size>()/2);
     rng = n;
     if (rng==0) rng=static_cast<Index>(1);
     GRange=rng;
     if (tileSize>GRange) tileSize=GRange;
     else if(GRange>tileSize){
       Index xMode =  static_cast<Index>(GRange % tileSize);
       if (xMode != 0) GRange += static_cast<Index>(tileSize - xMode);
     }
   }
   /// allocate device memory
   EIGEN_STRONG_INLINE void *allocate(size_t num_bytes) const {
       return m_queue_stream->allocate(num_bytes);
   }
   /// deallocate device memory
   EIGEN_STRONG_INLINE void deallocate(void *p) const {
      m_queue_stream->deallocate(p);
    }

   // some runtime conditions that can be applied here
   EIGEN_STRONG_INLINE bool isDeviceSuitable() const { return true; }

   /// the memcpy function
   template<typename T> EIGEN_STRONG_INLINE void memcpy(void *dst, const T *src, size_t n) const {
     auto it1 = m_queue_stream->find_buffer((void*)src);
     auto it2 = m_queue_stream->find_buffer(dst);
     auto offset= (static_cast<const uint8_t*>(static_cast<const void*>(src))) - it1->first;
     auto i= (static_cast<const uint8_t*>(dst)) - it2->first;
     offset/=sizeof(T);
     i/=sizeof(T);
     size_t rng, GRange, tileSize;
     parallel_for_setup(n/sizeof(T), tileSize, rng, GRange);
     sycl_queue().submit([&](cl::sycl::handler &cgh) {
       auto src_acc =it1->second.template get_access<cl::sycl::access::mode::read, cl::sycl::access::target::global_buffer>(cgh);
       auto dst_acc =it2->second.template get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer>(cgh);
       cgh.parallel_for(cl::sycl::nd_range<1>(cl::sycl::range<1>(GRange), cl::sycl::range<1>(tileSize)), MemCopyFunctor<T>(src_acc, dst_acc, rng, i, offset));
     });
     asynchronousExec();
   }

   /// The memcpyHostToDevice is used to copy the device only pointer to a host pointer. Using the device
   /// pointer created as a key we find the sycl buffer and get the host accessor with discard_write mode
   /// on it. Using a discard_write accessor guarantees that we do not bring back the current value of the
   /// buffer to host. Then we use the memcpy to copy the data to the host accessor. The first time that
   /// this buffer is accessed, the data will be copied to the device.
   template<typename T> EIGEN_STRONG_INLINE void memcpyHostToDevice(T *dst, const T *src, size_t n) const {
     auto host_acc= get_sycl_buffer(dst). template get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::host_buffer>();
     ::memcpy(host_acc.get_pointer(), src, n);
   }
   /// The memcpyDeviceToHost is used to copy the data from host to device. Here, in order to avoid double copying the data. We create a sycl
   /// buffer with map_allocator for the destination pointer with a discard_write accessor on it. The lifespan of the buffer is bound to the
   /// lifespan of the memcpyDeviceToHost function. We create a kernel to copy the data, from the device- only source buffer to the destination
   /// buffer with map_allocator on the gpu in parallel. At the end of the function call the destination buffer would be destroyed and the data
   /// would be available on the dst pointer using fast copy technique (map_allocator). In this case we can make sure that we copy the data back
   /// to the cpu only once per function call.
   template<typename T> EIGEN_STRONG_INLINE void memcpyDeviceToHost(void *dst, const T *src, size_t n) const {
     auto it = m_queue_stream->find_buffer(src);
     auto offset =static_cast<const uint8_t*>(static_cast<const void*>(src))- it->first;
     offset/=sizeof(T);
     size_t rng, GRange, tileSize;
     parallel_for_setup(n/sizeof(T), tileSize, rng, GRange);
     // Assuming that the dst is the start of the destination pointer
     auto dest_buf = cl::sycl::buffer<uint8_t, 1, cl::sycl::map_allocator<uint8_t> >(static_cast<uint8_t*>(dst), cl::sycl::range<1>(n));
     sycl_queue().submit([&](cl::sycl::handler &cgh) {
       auto src_acc= it->second.template get_access<cl::sycl::access::mode::read, cl::sycl::access::target::global_buffer>(cgh);
       auto dst_acc =dest_buf.template get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer>(cgh);
       cgh.parallel_for( cl::sycl::nd_range<1>(cl::sycl::range<1>(GRange), cl::sycl::range<1>(tileSize)), MemCopyFunctor<T>(src_acc, dst_acc, rng, 0, offset));
     });
     asynchronousExec();
   }
   /// returning the sycl queue
   EIGEN_STRONG_INLINE cl::sycl::queue& sycl_queue() const { return m_queue_stream->m_queue;}
   /// Here is the implementation of memset function on sycl.
   EIGEN_STRONG_INLINE void memset(void *data, int c, size_t n) const {
     size_t rng, GRange, tileSize;
     parallel_for_setup(n, tileSize, rng, GRange);
     sycl_queue().submit(memsetCghFunctor(get_sycl_buffer(static_cast<uint8_t*>(static_cast<void*>(data))),rng, GRange, tileSize, c ));
     asynchronousExec();
   }

   struct memsetCghFunctor{
     cl::sycl::buffer<uint8_t, 1>& m_buf;
     const size_t& rng , GRange, tileSize;
     const int  &c;
     memsetCghFunctor(cl::sycl::buffer<uint8_t, 1>& buff,  const size_t& rng_,  const size_t& GRange_,  const size_t& tileSize_, const int& c_)
     :m_buf(buff), rng(rng_), GRange(GRange_), tileSize(tileSize_), c(c_){}

     void operator()(cl::sycl::handler &cgh) const {
       auto buf_acc = m_buf.template get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer>(cgh);
       cgh.parallel_for(cl::sycl::nd_range<1>(cl::sycl::range<1>(GRange), cl::sycl::range<1>(tileSize)), memsetkernelFunctor(buf_acc, rng, c));
     }
   };

   EIGEN_STRONG_INLINE size_t firstLevelCacheSize() const {
     // FIXME
     return 48*1024;
   }

   EIGEN_STRONG_INLINE size_t lastLevelCacheSize() const {
     // We won't try to take advantage of the l2 cache for the time being, and
     // there is no l3 cache on cuda devices.
     return firstLevelCacheSize();
   }
   /// No need for sycl it should act the same as CPU version
   EIGEN_STRONG_INLINE int majorDeviceVersion() const { return 1; }

   EIGEN_STRONG_INLINE void synchronize() const {
     sycl_queue().wait_and_throw(); //pass
   }

     EIGEN_STRONG_INLINE void asynchronousExec() const {
       sycl_queue().throw_asynchronous();//pass
     }
   // This function checks if the runtime recorded an error for the
   // underlying stream device.
   EIGEN_STRONG_INLINE bool ok() const {
     return m_queue_stream->ok();
   }
 };


 }  // end namespace Eigen

 #endif  // EIGEN_CXX11_TENSOR_TENSOR_DEVICE_SYCL_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Mehdi Goli Codeplay Software Ltd.
	// Ralph Potter Codeplay Software Ltd.
	// Luke Iwanski Codeplay Software Ltd.
	// Contact: <eigen@codeplay.com>
	// Copyright (C) 2016 Benoit Steiner <benoit.steiner.goog@gmail.com>

	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#if defined(EIGEN_USE_SYCL) && !defined(EIGEN_CXX11_TENSOR_TENSOR_DEVICE_SYCL_H)
	#define EIGEN_CXX11_TENSOR_TENSOR_DEVICE_SYCL_H

	namespace Eigen {

	#define ConvertToActualTypeSycl(Scalar, buf_acc) reinterpret_cast<typename cl::sycl::global_ptr<Scalar>::pointer_t>((&(*buf_acc.get_pointer())))

	template <typename Scalar> class MemCopyFunctor {
	public:
	typedef cl::sycl::accessor<uint8_t, 1, cl::sycl::access::mode::read, cl::sycl::access::target::global_buffer> read_accessor;
	typedef cl::sycl::accessor<uint8_t, 1, cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer> write_accessor;

	MemCopyFunctor(read_accessor src_acc, write_accessor dst_acc, size_t rng, size_t i, size_t offset): m_src_acc(src_acc), m_dst_acc(dst_acc), m_rng(rng), m_i(i), m_offset(offset) {}

	void operator()(cl::sycl::nd_item<1> itemID) {
	auto src_ptr = ConvertToActualTypeSycl(Scalar, m_src_acc);
	auto dst_ptr = ConvertToActualTypeSycl(Scalar, m_dst_acc);
	auto globalid = itemID.get_global_linear_id();
	if (globalid < m_rng) {
	dst_ptr[globalid + m_i] = src_ptr[globalid + m_offset];
	}
	}

	private:
	read_accessor m_src_acc;
	write_accessor m_dst_acc;
	size_t m_rng;
	size_t m_i;
	size_t m_offset;
	};

	struct memsetkernelFunctor{
	typedef cl::sycl::accessor<uint8_t, 1, cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer> AccType;
	AccType m_acc;
	const size_t m_rng, m_c;
	memsetkernelFunctor(AccType acc, const size_t rng, const size_t c):m_acc(acc), m_rng(rng), m_c(c){}
	void operator()(cl::sycl::nd_item<1> itemID) {
	auto globalid=itemID.get_global_linear_id();
	if (globalid< m_rng) m_acc[globalid] = m_c;
	}

	};

	EIGEN_STRONG_INLINE auto get_sycl_supported_devices()->decltype(cl::sycl::device::get_devices()){
	auto devices = cl::sycl::device::get_devices();
	std::vector<cl::sycl::device>::iterator it =devices.begin();
	while(it!=devices.end()) {
	/// get_devices returns all the available opencl devices. Either use device_selector or exclude devices that computecpp does not support (AMD OpenCL for CPU )
	auto s= (*it).template get_info<cl::sycl::info::device::vendor>();
	std::transform(s.begin(), s.end(), s.begin(), ::tolower);
	if((*it).is_cpu() && s.find("amd")!=std::string::npos){ // remove amd cpu as it is not supported by computecpp
	it=devices.erase(it);
	}
	else{
	++it;
	}
	}
	return devices;
	}

	struct QueueInterface {
	/// class members:
	bool exception_caught_ = false;

	mutable std::mutex mutex_;

	/// std::map is the container used to make sure that we create only one buffer
	/// per pointer. The lifespan of the buffer now depends on the lifespan of SyclDevice.
	/// If a non-read-only pointer is needed to be accessed on the host we should manually deallocate it.
	mutable std::map<const uint8_t *, cl::sycl::buffer<uint8_t, 1>> buffer_map;
	/// sycl queue
	mutable cl::sycl::queue m_queue;
	/// creating device by using cl::sycl::selector or cl::sycl::device both are the same and can be captured through dev_Selector typename
	/// SyclStreamDevice is not owned. it is the caller's responsibility to destroy it.
	template<typename dev_Selector> explicit QueueInterface(const dev_Selector& s):
	#ifdef EIGEN_EXCEPTIONS
	m_queue(cl::sycl::queue(s, [&](cl::sycl::exception_list l) {
	for (const auto& e : l) {
	try {
	if (e) {
	exception_caught_ = true;
	std::rethrow_exception(e);
	}
	} catch (cl::sycl::exception e) {
	std::cerr << e.what() << std::endl;
	}
	}
	}))
	#else
	m_queue(cl::sycl::queue(s, [&](cl::sycl::exception_list l) {
	for (const auto& e : l) {
	if (e) {
	exception_caught_ = true;
	std::cerr << "Error detected Inside Sycl Device."<< std::endl;

	}
	}
	}))
	#endif
	{}

	/// Allocating device pointer. This pointer is actually an 8 bytes host pointer used as key to access the sycl device buffer.
	/// The reason is that we cannot use device buffer as a pointer as a m_data in Eigen leafNode expressions. So we create a key
	/// pointer to be used in Eigen expression construction. When we convert the Eigen construction into the sycl construction we
	/// use this pointer as a key in our buffer_map and we make sure that we dedicate only one buffer only for this pointer.
	/// The device pointer would be deleted by calling deallocate function.
	EIGEN_STRONG_INLINE void* allocate(size_t num_bytes) const {
	auto buf = cl::sycl::buffer<uint8_t,1>(cl::sycl::range<1>(num_bytes));
	auto ptr =buf.get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::host_buffer>().get_pointer();
	buf.set_final_data(nullptr);
	std::lock_guard<std::mutex> lock(mutex_);
	buffer_map.insert(std::pair<const uint8_t , cl::sycl::buffer<uint8_t, 1>>(static_cast<const uint8_t>(ptr),buf));
	return static_cast<void*>(ptr);
	}

	/// This is used to deallocate the device pointer. p is used as a key inside
	/// the map to find the device buffer and delete it.
	EIGEN_STRONG_INLINE void deallocate(void *p) const {
	std::lock_guard<std::mutex> lock(mutex_);
	auto it = buffer_map.find(static_cast<const uint8_t*>(p));
	if (it != buffer_map.end()) {
	auto num_bytes =it->second.get_size();
	buffer_map.erase(it);
	// Temporary solution for memory leak in computecpp. It will be fixed in the next computecpp version
	std::allocator<uint8_t> a1; // Default allocator for buffer<uint8_t,1>
	a1.deallocate(static_cast<uint8_t*>(p), num_bytes);
	}
	}

	EIGEN_STRONG_INLINE void deallocate_all() const {
	std::lock_guard<std::mutex> lock(mutex_);
	buffer_map.clear();
	}

	EIGEN_STRONG_INLINE std::map<const uint8_t , cl::sycl::buffer<uint8_t,1>>::iterator find_buffer(const void ptr) const {
	std::lock_guard<std::mutex> lock(mutex_);
	auto it1 = buffer_map.find(static_cast<const uint8_t*>(ptr));
	if (it1 != buffer_map.end()){
	return it1;
	}
	else{
	for(std::map<const uint8_t *, cl::sycl::buffer<uint8_t,1>>::iterator it=buffer_map.begin(); it!=buffer_map.end(); ++it){
	auto size = it->second.get_size();
	if((it->first < (static_cast<const uint8_t>(ptr))) && ((static_cast<const uint8_t>(ptr)) < (it->first + size)) ) return it;
	}
	}
	std::cerr << "No sycl buffer found. Make sure that you have allocated memory for your buffer by calling allocate function in SyclDevice"<< std::endl;
	abort();
	}

	// This function checks if the runtime recorded an error for the
	// underlying stream device.
	EIGEN_STRONG_INLINE bool ok() const {
	if (!exception_caught_) {
	m_queue.wait_and_throw();
	}
	return !exception_caught_;
	}

	// destructor
	~QueueInterface() { buffer_map.clear(); }
	};

	struct SyclDevice {
	// class member.
	QueueInterface* m_queue_stream;
	/// QueueInterface is not owned. it is the caller's responsibility to destroy it.
	explicit SyclDevice(QueueInterface* queue_stream) : m_queue_stream(queue_stream){}

	/// Creation of sycl accessor for a buffer. This function first tries to find
	/// the buffer in the buffer_map. If found it gets the accessor from it, if not,
	/// the function then adds an entry by creating a sycl buffer for that particular pointer.
	template <cl::sycl::access::mode AcMd> EIGEN_STRONG_INLINE cl::sycl::accessor<uint8_t, 1, AcMd, cl::sycl::access::target::global_buffer>
	get_sycl_accessor(cl::sycl::handler &cgh, const void* ptr) const {
	return (get_sycl_buffer(ptr).template get_access<AcMd, cl::sycl::access::target::global_buffer>(cgh));
	}

	/// Accessing the created sycl device buffer for the device pointer
	EIGEN_STRONG_INLINE cl::sycl::buffer<uint8_t, 1>& get_sycl_buffer(const void * ptr) const {
	return m_queue_stream->find_buffer(ptr)->second;
	}

	/// This is used to prepare the number of threads and also the number of threads per block for sycl kernels
	template<typename Index>
	EIGEN_STRONG_INLINE void parallel_for_setup(Index n, Index &tileSize, Index &rng, Index &GRange) const {
	tileSize =static_cast<Index>(sycl_queue().get_device(). template get_info<cl::sycl::info::device::max_work_group_size>()/2);
	rng = n;
	if (rng==0) rng=static_cast<Index>(1);
	GRange=rng;
	if (tileSize>GRange) tileSize=GRange;
	else if(GRange>tileSize){
	Index xMode = static_cast<Index>(GRange % tileSize);
	if (xMode != 0) GRange += static_cast<Index>(tileSize - xMode);
	}
	}
	/// allocate device memory
	EIGEN_STRONG_INLINE void *allocate(size_t num_bytes) const {
	return m_queue_stream->allocate(num_bytes);
	}
	/// deallocate device memory
	EIGEN_STRONG_INLINE void deallocate(void *p) const {
	m_queue_stream->deallocate(p);
	}

	// some runtime conditions that can be applied here
	EIGEN_STRONG_INLINE bool isDeviceSuitable() const { return true; }

	/// the memcpy function
	template<typename T> EIGEN_STRONG_INLINE void memcpy(void dst, const T src, size_t n) const {
	auto it1 = m_queue_stream->find_buffer((void*)src);
	auto it2 = m_queue_stream->find_buffer(dst);
	auto offset= (static_cast<const uint8_t>(static_cast<const void>(src))) - it1->first;
	auto i= (static_cast<const uint8_t*>(dst)) - it2->first;
	offset/=sizeof(T);
	i/=sizeof(T);
	size_t rng, GRange, tileSize;
	parallel_for_setup(n/sizeof(T), tileSize, rng, GRange);
	sycl_queue().submit([&](cl::sycl::handler &cgh) {
	auto src_acc =it1->second.template get_access<cl::sycl::access::mode::read, cl::sycl::access::target::global_buffer>(cgh);
	auto dst_acc =it2->second.template get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer>(cgh);
	cgh.parallel_for(cl::sycl::nd_range<1>(cl::sycl::range<1>(GRange), cl::sycl::range<1>(tileSize)), MemCopyFunctor<T>(src_acc, dst_acc, rng, i, offset));
	});
	asynchronousExec();
	}

	/// The memcpyHostToDevice is used to copy the device only pointer to a host pointer. Using the device
	/// pointer created as a key we find the sycl buffer and get the host accessor with discard_write mode
	/// on it. Using a discard_write accessor guarantees that we do not bring back the current value of the
	/// buffer to host. Then we use the memcpy to copy the data to the host accessor. The first time that
	/// this buffer is accessed, the data will be copied to the device.
	template<typename T> EIGEN_STRONG_INLINE void memcpyHostToDevice(T dst, const T src, size_t n) const {
	auto host_acc= get_sycl_buffer(dst). template get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::host_buffer>();
	::memcpy(host_acc.get_pointer(), src, n);
	}
	/// The memcpyDeviceToHost is used to copy the data from host to device. Here, in order to avoid double copying the data. We create a sycl
	/// buffer with map_allocator for the destination pointer with a discard_write accessor on it. The lifespan of the buffer is bound to the
	/// lifespan of the memcpyDeviceToHost function. We create a kernel to copy the data, from the device- only source buffer to the destination
	/// buffer with map_allocator on the gpu in parallel. At the end of the function call the destination buffer would be destroyed and the data
	/// would be available on the dst pointer using fast copy technique (map_allocator). In this case we can make sure that we copy the data back
	/// to the cpu only once per function call.
	template<typename T> EIGEN_STRONG_INLINE void memcpyDeviceToHost(void dst, const T src, size_t n) const {
	auto it = m_queue_stream->find_buffer(src);
	auto offset =static_cast<const uint8_t>(static_cast<const void>(src))- it->first;
	offset/=sizeof(T);
	size_t rng, GRange, tileSize;
	parallel_for_setup(n/sizeof(T), tileSize, rng, GRange);
	// Assuming that the dst is the start of the destination pointer
	auto dest_buf = cl::sycl::buffer<uint8_t, 1, cl::sycl::map_allocator<uint8_t> >(static_cast<uint8_t*>(dst), cl::sycl::range<1>(n));
	sycl_queue().submit([&](cl::sycl::handler &cgh) {
	auto src_acc= it->second.template get_access<cl::sycl::access::mode::read, cl::sycl::access::target::global_buffer>(cgh);
	auto dst_acc =dest_buf.template get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer>(cgh);
	cgh.parallel_for( cl::sycl::nd_range<1>(cl::sycl::range<1>(GRange), cl::sycl::range<1>(tileSize)), MemCopyFunctor<T>(src_acc, dst_acc, rng, 0, offset));
	});
	asynchronousExec();
	}
	/// returning the sycl queue
	EIGEN_STRONG_INLINE cl::sycl::queue& sycl_queue() const { return m_queue_stream->m_queue;}
	/// Here is the implementation of memset function on sycl.
	EIGEN_STRONG_INLINE void memset(void *data, int c, size_t n) const {
	size_t rng, GRange, tileSize;
	parallel_for_setup(n, tileSize, rng, GRange);
	sycl_queue().submit(memsetCghFunctor(get_sycl_buffer(static_cast<uint8_t>(static_cast<void>(data))),rng, GRange, tileSize, c ));
	asynchronousExec();
	}

	struct memsetCghFunctor{
	cl::sycl::buffer<uint8_t, 1>& m_buf;
	const size_t& rng , GRange, tileSize;
	const int &c;
	memsetCghFunctor(cl::sycl::buffer<uint8_t, 1>& buff, const size_t& rng_, const size_t& GRange_, const size_t& tileSize_, const int& c_)
	:m_buf(buff), rng(rng_), GRange(GRange_), tileSize(tileSize_), c(c_){}

	void operator()(cl::sycl::handler &cgh) const {
	auto buf_acc = m_buf.template get_access<cl::sycl::access::mode::discard_write, cl::sycl::access::target::global_buffer>(cgh);
	cgh.parallel_for(cl::sycl::nd_range<1>(cl::sycl::range<1>(GRange), cl::sycl::range<1>(tileSize)), memsetkernelFunctor(buf_acc, rng, c));
	}
	};

	EIGEN_STRONG_INLINE size_t firstLevelCacheSize() const {
	// FIXME
	return 48*1024;
	}

	EIGEN_STRONG_INLINE size_t lastLevelCacheSize() const {
	// We won't try to take advantage of the l2 cache for the time being, and
	// there is no l3 cache on cuda devices.
	return firstLevelCacheSize();
	}
	/// No need for sycl it should act the same as CPU version
	EIGEN_STRONG_INLINE int majorDeviceVersion() const { return 1; }

	EIGEN_STRONG_INLINE void synchronize() const {
	sycl_queue().wait_and_throw(); //pass
	}

	EIGEN_STRONG_INLINE void asynchronousExec() const {
	sycl_queue().throw_asynchronous();//pass
	}
	// This function checks if the runtime recorded an error for the
	// underlying stream device.
	EIGEN_STRONG_INLINE bool ok() const {
	return m_queue_stream->ok();
	}
	};


	} // end namespace Eigen

	#endif // EIGEN_CXX11_TENSOR_TENSOR_DEVICE_SYCL_H