llvm-docs/doxygen/handler_8hpp_source.html

 //==-------- handler.hpp --- SYCL command group handler --------------------==//

 //

 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.

 // See https://llvm.org/LICENSE.txt for license information.

 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception

 //

 //===----------------------------------------------------------------------===//


 #pragma once


 #include <sycl/access/access.hpp>

 #include <sycl/accessor.hpp>

 #include <sycl/context.hpp>

 #include <sycl/detail/cg.hpp>

 #include <sycl/detail/cg_types.hpp>

 #include <sycl/detail/common.hpp>

 #include <sycl/detail/defines_elementary.hpp>

 #include <sycl/detail/export.hpp>

 #include <sycl/detail/impl_utils.hpp>

 #include <sycl/detail/kernel_desc.hpp>

 #include <sycl/detail/pi.h>

 #include <sycl/detail/pi.hpp>

 #include <sycl/detail/reduction_forward.hpp>

 #include <sycl/detail/string.hpp>

 #include <sycl/detail/string_view.hpp>

 #include <sycl/device.hpp>

 #include <sycl/event.hpp>

 #include <sycl/exception.hpp>

 #include <sycl/ext/intel/experimental/fp_control_kernel_properties.hpp>

 #include <sycl/ext/intel/experimental/kernel_execution_properties.hpp>

 #include <sycl/ext/oneapi/bindless_images_descriptor.hpp>

 #include <sycl/ext/oneapi/bindless_images_interop.hpp>

 #include <sycl/ext/oneapi/bindless_images_memory.hpp>

 #include <sycl/ext/oneapi/device_global/device_global.hpp>

 #include <sycl/ext/oneapi/device_global/properties.hpp>

 #include <sycl/ext/oneapi/experimental/graph.hpp>

 #include <sycl/ext/oneapi/experimental/root_group.hpp>

 #include <sycl/ext/oneapi/kernel_properties/properties.hpp>

 #include <sycl/ext/oneapi/properties/properties.hpp>

 #include <sycl/group.hpp>

 #include <sycl/id.hpp>

 #include <sycl/interop_handle.hpp>

 #include <sycl/item.hpp>

 #include <sycl/kernel.hpp>

 #include <sycl/kernel_bundle.hpp>

 #include <sycl/kernel_bundle_enums.hpp>

 #include <sycl/kernel_handler.hpp>

 #include <sycl/nd_item.hpp>

 #include <sycl/nd_range.hpp>

 #include <sycl/property_list.hpp>

 #include <sycl/range.hpp>

 #include <sycl/sampler.hpp>


 #include <assert.h>

 #include <functional>

 #include <memory>

 #include <stddef.h>

 #include <stdint.h>

 #include <string>

 #include <tuple>

 #include <type_traits>

 #include <utility>

 #include <vector>


 // TODO: refactor this header

 // 41(!!!) includes of SYCL headers + 10 includes of standard headers.

 // 3300+ lines of code


 // SYCL_LANGUAGE_VERSION is 4 digit year followed by 2 digit revision

 #if !SYCL_LANGUAGE_VERSION || SYCL_LANGUAGE_VERSION < 202001

 #define __SYCL_NONCONST_FUNCTOR__

 #endif


 // replace _KERNELFUNCPARAM(KernelFunc) with   KernelType KernelFunc

 //                                     or     const KernelType &KernelFunc

 #ifdef __SYCL_NONCONST_FUNCTOR__

 #define _KERNELFUNCPARAMTYPE KernelType

 #else

 #define _KERNELFUNCPARAMTYPE const KernelType &

 #endif

 #define _KERNELFUNCPARAM(a) _KERNELFUNCPARAMTYPE a


 #if defined(__SYCL_UNNAMED_LAMBDA__)

 // We can't use nested types (e.g. struct S defined inside main() routine) to

 // name kernels. At the same time, we have to provide a unique kernel name for

 // sycl::fill and the only thing we can use to introduce that uniqueness (in

 // general) is the template parameter T which might be exactly that nested type.

 // That means we cannot support sycl::fill(void *, T&, size_t) for such types in

 // general. However, we can do better than that when unnamed lambdas are

 // enabled, so do it here! See also https://github.com/intel/llvm/issues/469.

 template <typename DataT, int Dimensions, sycl::access::mode AccessMode,

           sycl::access::target AccessTarget,

           sycl::access::placeholder IsPlaceholder>

 using __fill = sycl::detail::auto_name;

 template <typename T> using __usmfill = sycl::detail::auto_name;

 template <typename T> using __usmfill2d = sycl::detail::auto_name;

 template <typename T> using __usmmemcpy2d = sycl::detail::auto_name;


 template <typename T_Src, typename T_Dst, int Dims,

           sycl::access::mode AccessMode, sycl::access::target AccessTarget,

           sycl::access::placeholder IsPlaceholder>

 using __copyAcc2Ptr = sycl::detail::auto_name;


 template <typename T_Src, typename T_Dst, int Dims,

           sycl::access::mode AccessMode, sycl::access::target AccessTarget,

           sycl::access::placeholder IsPlaceholder>

 using __copyPtr2Acc = sycl::detail::auto_name;


 template <typename T_Src, int Dims_Src, sycl::access::mode AccessMode_Src,

           sycl::access::target AccessTarget_Src, typename T_Dst, int Dims_Dst,

           sycl::access::mode AccessMode_Dst,

           sycl::access::target AccessTarget_Dst,

           sycl::access::placeholder IsPlaceholder_Src,

           sycl::access::placeholder IsPlaceholder_Dst>

 using __copyAcc2Acc = sycl::detail::auto_name;

 #else

 // Limited fallback path for when unnamed lambdas aren't available. Cannot

 // handle nested types.

 template <typename DataT, int Dimensions, sycl::access::mode AccessMode,

           sycl::access::target AccessTarget,

           sycl::access::placeholder IsPlaceholder>

 class __fill;

 template <typename T> class __usmfill;

 template <typename T> class __usmfill2d;

 template <typename T> class __usmmemcpy2d;


 template <typename T_Src, typename T_Dst, int Dims,

           sycl::access::mode AccessMode, sycl::access::target AccessTarget,

           sycl::access::placeholder IsPlaceholder>

 class __copyAcc2Ptr;


 template <typename T_Src, typename T_Dst, int Dims,

           sycl::access::mode AccessMode, sycl::access::target AccessTarget,

           sycl::access::placeholder IsPlaceholder>

 class __copyPtr2Acc;


 template <typename T_Src, int Dims_Src, sycl::access::mode AccessMode_Src,

           sycl::access::target AccessTarget_Src, typename T_Dst, int Dims_Dst,

           sycl::access::mode AccessMode_Dst,

           sycl::access::target AccessTarget_Dst,

           sycl::access::placeholder IsPlaceholder_Src,

           sycl::access::placeholder IsPlaceholder_Dst>

 class __copyAcc2Acc;

 #endif


 // For unit testing purposes

 class MockHandler;


 namespace sycl {

 inline namespace _V1 {


 // Forward declaration


 class handler;

 template <typename T, int Dimensions, typename AllocatorT, typename Enable>

 class buffer;


 namespace ext::intel::experimental {

 template <class _name, class _dataT, int32_t _min_capacity, class _propertiesT,

           class>

 class pipe;

 }


 namespace ext::oneapi::experimental::detail {

 class graph_impl;

 } // namespace ext::oneapi::experimental::detail

 namespace detail {


 class handler_impl;

 class kernel_impl;

 class queue_impl;

 class stream_impl;

 template <typename DataT, int Dimensions, access::mode AccessMode,

           access::target AccessTarget, access::placeholder IsPlaceholder>

 class image_accessor;

 template <typename RetType, typename Func, typename Arg>

 static Arg member_ptr_helper(RetType (Func::*)(Arg) const);


 // Non-const version of the above template to match functors whose 'operator()'

 // is declared w/o the 'const' qualifier.

 template <typename RetType, typename Func, typename Arg>

 static Arg member_ptr_helper(RetType (Func::*)(Arg));


 // Version with two arguments to handle the case when kernel_handler is passed

 // to a lambda

 template <typename RetType, typename Func, typename Arg1, typename Arg2>

 static Arg1 member_ptr_helper(RetType (Func::*)(Arg1, Arg2) const);


 // Non-const version of the above template to match functors whose 'operator()'

 // is declared w/o the 'const' qualifier.

 template <typename RetType, typename Func, typename Arg1, typename Arg2>

 static Arg1 member_ptr_helper(RetType (Func::*)(Arg1, Arg2));


 template <typename F, typename SuggestedArgType>

 decltype(member_ptr_helper(&F::operator())) argument_helper(int);


 template <typename F, typename SuggestedArgType>

 SuggestedArgType argument_helper(...);


 template <typename F, typename SuggestedArgType>

 using lambda_arg_type = decltype(argument_helper<F, SuggestedArgType>(0));


 // Used when parallel_for range is rounded-up.

 template <typename Name> class __pf_kernel_wrapper;


 template <typename Type> struct get_kernel_wrapper_name_t {

   using name = __pf_kernel_wrapper<Type>;

 };


 __SYCL_EXPORT device getDeviceFromHandler(handler &);


 // Checks if a device_global has any registered kernel usage.

 __SYCL_EXPORT bool isDeviceGlobalUsedInKernel(const void *DeviceGlobalPtr);


 // Extracts a pointer to the value inside a dynamic parameter

 __SYCL_EXPORT void *getValueFromDynamicParameter(

     ext::oneapi::experimental::detail::dynamic_parameter_base

         &DynamicParamBase);


 #if __SYCL_ID_QUERIES_FIT_IN_INT__

 template <typename T> struct NotIntMsg;


 template <int Dims> struct NotIntMsg<range<Dims>> {

   constexpr static const char *Msg =

       "Provided range is out of integer limits. Pass "

       "`-fno-sycl-id-queries-fit-in-int' to disable range check.";

 };


 template <int Dims> struct NotIntMsg<id<Dims>> {

   constexpr static const char *Msg =

       "Provided offset is out of integer limits. Pass "

       "`-fno-sycl-id-queries-fit-in-int' to disable offset check.";

 };

 #endif


 // Helper for merging properties with ones defined in an optional kernel functor

 // getter.

 template <typename KernelType, typename PropertiesT, typename Cond = void>

 struct GetMergedKernelProperties {

   using type = PropertiesT;

 };

 template <typename KernelType, typename PropertiesT>

 struct GetMergedKernelProperties<

     KernelType, PropertiesT,

     std::enable_if_t<ext::oneapi::experimental::detail::

                          HasKernelPropertiesGetMethod<KernelType>::value>> {

   using get_method_properties =

       typename ext::oneapi::experimental::detail::HasKernelPropertiesGetMethod<

           KernelType>::properties_t;

   static_assert(

       ext::oneapi::experimental::is_property_list<get_method_properties>::value,

       "get(sycl::ext::oneapi::experimental::properties_tag) member in kernel "

       "functor class must return a valid property list.");

   using type = ext::oneapi::experimental::detail::merged_properties_t<

       PropertiesT, get_method_properties>;

 };


 #if __SYCL_ID_QUERIES_FIT_IN_INT__

 template <typename T, typename ValT>

 typename std::enable_if_t<std::is_same<ValT, size_t>::value ||

                           std::is_same<ValT, unsigned long long>::value>

 checkValueRangeImpl(ValT V) {

   static constexpr size_t Limit =

       static_cast<size_t>((std::numeric_limits<int>::max)());

   if (V > Limit)

     throw sycl::exception(make_error_code(errc::nd_range), NotIntMsg<T>::Msg);

 }

 #endif


 template <int Dims, typename T>

 typename std::enable_if_t<std::is_same_v<T, range<Dims>> ||

                           std::is_same_v<T, id<Dims>>>

 checkValueRange(const T &V) {

 #if __SYCL_ID_QUERIES_FIT_IN_INT__

   for (size_t Dim = 0; Dim < Dims; ++Dim)

     checkValueRangeImpl<T>(V[Dim]);


   {

     unsigned long long Product = 1;

     for (size_t Dim = 0; Dim < Dims; ++Dim) {

       Product *= V[Dim];

       // check value now to prevent product overflow in the end

       checkValueRangeImpl<T>(Product);

     }

   }

 #else

   (void)V;

 #endif

 }


 template <int Dims>

 void checkValueRange(const range<Dims> &R, const id<Dims> &O) {

 #if __SYCL_ID_QUERIES_FIT_IN_INT__

   checkValueRange<Dims>(R);

   checkValueRange<Dims>(O);


   for (size_t Dim = 0; Dim < Dims; ++Dim) {

     unsigned long long Sum = R[Dim] + O[Dim];


     checkValueRangeImpl<range<Dims>>(Sum);

   }

 #else

   (void)R;

   (void)O;

 #endif

 }


 template <int Dims, typename T>

 typename std::enable_if_t<std::is_same_v<T, nd_range<Dims>>>

 checkValueRange(const T &V) {

 #if __SYCL_ID_QUERIES_FIT_IN_INT__

   checkValueRange<Dims>(V.get_global_range());

   checkValueRange<Dims>(V.get_local_range());

   checkValueRange<Dims>(V.get_offset());


   checkValueRange<Dims>(V.get_global_range(), V.get_offset());

 #else

   (void)V;

 #endif

 }


 template <int Dims> class RoundedRangeIDGenerator {

   id<Dims> Id;

   id<Dims> InitId;

   range<Dims> UserRange;

   range<Dims> RoundedRange;

   bool Done = false;


 public:

   RoundedRangeIDGenerator(const id<Dims> &Id, const range<Dims> &UserRange,

                           const range<Dims> &RoundedRange)

       : Id(Id), InitId(Id), UserRange(UserRange), RoundedRange(RoundedRange) {

     for (int i = 0; i < Dims; ++i)

       if (Id[i] >= UserRange[i])

         Done = true;

   }


   explicit operator bool() { return !Done; }


   void updateId() {

     for (int i = 0; i < Dims; ++i) {

       Id[i] += RoundedRange[i];

       if (Id[i] < UserRange[i])

         return;

       Id[i] = InitId[i];

     }

     Done = true;

   }


   id<Dims> getId() { return Id; }


   template <typename KernelType> auto getItem() {

     if constexpr (std::is_invocable_v<KernelType, item<Dims> &> ||

                   std::is_invocable_v<KernelType, item<Dims> &, kernel_handler>)

       return detail::Builder::createItem<Dims, true>(UserRange, getId(), {});

     else {

       static_assert(std::is_invocable_v<KernelType, item<Dims, false> &> ||

                         std::is_invocable_v<KernelType, item<Dims, false> &,

                                             kernel_handler>,

                     "Kernel must be invocable with an item!");

       return detail::Builder::createItem<Dims, false>(UserRange, getId());

     }

   }

 };


 // TODO: The wrappers can be optimized further so that the body

 // essentially looks like this:

 //   for (auto z = it[2]; z < UserRange[2]; z += it.get_range(2))

 //     for (auto y = it[1]; y < UserRange[1]; y += it.get_range(1))

 //       for (auto x = it[0]; x < UserRange[0]; x += it.get_range(0))

 //         KernelFunc({x,y,z});

 template <typename TransformedArgType, int Dims, typename KernelType>

 class RoundedRangeKernel {

 public:

   range<Dims> UserRange;

   KernelType KernelFunc;

   void operator()(item<Dims> It) const {

     auto RoundedRange = It.get_range();

     for (RoundedRangeIDGenerator Gen(It.get_id(), UserRange, RoundedRange); Gen;

          Gen.updateId()) {

       auto item = Gen.template getItem<KernelType>();

       KernelFunc(item);

     }

   }

 };


 template <typename TransformedArgType, int Dims, typename KernelType>

 class RoundedRangeKernelWithKH {

 public:

   range<Dims> UserRange;

   KernelType KernelFunc;

   void operator()(item<Dims> It, kernel_handler KH) const {

     auto RoundedRange = It.get_range();

     for (RoundedRangeIDGenerator Gen(It.get_id(), UserRange, RoundedRange); Gen;

          Gen.updateId()) {

       auto item = Gen.template getItem<KernelType>();

       KernelFunc(item, KH);

     }

   }

 };


 using std::enable_if_t;

 using sycl::detail::queue_impl;


 // Returns true if x*y will overflow in T;

 // otherwise, returns false and stores x*y in dst.

 template <typename T>

 static std::enable_if_t<std::is_unsigned_v<T>, bool>

 multiply_with_overflow_check(T &dst, T x, T y) {

   dst = x * y;

   return (y != 0) && (x > (std::numeric_limits<T>::max)() / y);

 }


 template <int Dims> bool range_size_fits_in_size_t(const range<Dims> &r) {

   size_t acc = 1;

   for (int i = 0; i < Dims; ++i) {

     bool did_overflow = multiply_with_overflow_check(acc, acc, r[i]);

     if (did_overflow)

       return false;

   }

   return true;

 }

 } // namespace detail


 class __SYCL_EXPORT handler {

 private:

   handler(std::shared_ptr<detail::queue_impl> Queue, bool IsHost);


   handler(std::shared_ptr<detail::queue_impl> Queue,

           std::shared_ptr<detail::queue_impl> PrimaryQueue,

           std::shared_ptr<detail::queue_impl> SecondaryQueue, bool IsHost);


   handler(std::shared_ptr<ext::oneapi::experimental::detail::graph_impl> Graph);


   template <typename T, typename F = typename std::remove_const_t<

                             typename std::remove_reference_t<T>>>

   F *storePlainArg(T &&Arg) {

     CGData.MArgsStorage.emplace_back(sizeof(T));

     auto Storage = reinterpret_cast<F *>(CGData.MArgsStorage.back().data());

     *Storage = Arg;

     return Storage;

   }


   void setType(detail::CG::CGTYPE Type) { MCGType = Type; }


   detail::CG::CGTYPE getType() { return MCGType; }


   void throwIfActionIsCreated() {

     if (detail::CG::None != getType())

       throw sycl::exception(make_error_code(errc::runtime),

                             "Attempt to set multiple actions for the "

                             "command group. Command group must consist of "

                             "a single kernel or explicit memory operation.");

   }


   constexpr static int AccessTargetMask = 0x7ff;

   template <typename KernelName, typename KernelType>

   void throwOnLocalAccessorMisuse() const {

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     using KI = sycl::detail::KernelInfo<NameT>;


     auto *KernelArgs = &KI::getParamDesc(0);


     for (unsigned I = 0; I < KI::getNumParams(); ++I) {

       const detail::kernel_param_kind_t &Kind = KernelArgs[I].kind;

       const access::target AccTarget =

           static_cast<access::target>(KernelArgs[I].info & AccessTargetMask);

       if ((Kind == detail::kernel_param_kind_t::kind_accessor) &&

           (AccTarget == target::local))

         throw sycl::exception(

             make_error_code(errc::kernel_argument),

             "A local accessor must not be used in a SYCL kernel function "

             "that is invoked via single_task or via the simple form of "

             "parallel_for that takes a range parameter.");

     }

   }


   void

   extractArgsAndReqsFromLambda(char *LambdaPtr, size_t KernelArgsNum,

                                const detail::kernel_param_desc_t *KernelArgs,

                                bool IsESIMD);


   void extractArgsAndReqs();


   void processArg(void *Ptr, const detail::kernel_param_kind_t &Kind,

                   const int Size, const size_t Index, size_t &IndexShift,

                   bool IsKernelCreatedFromSource, bool IsESIMD);


   detail::string getKernelName();


   template <typename LambdaNameT> bool lambdaAndKernelHaveEqualName() {

     // TODO It is unclear a kernel and a lambda/functor must to be equal or not

     // for parallel_for with sycl::kernel and lambda/functor together

     // Now if they are equal we extract argumets from lambda/functor for the

     // kernel. Else it is necessary use set_atg(s) for resolve the order and

     // values of arguments for the kernel.

     assert(MKernel && "MKernel is not initialized");

     const std::string LambdaName = detail::KernelInfo<LambdaNameT>::getName();

     detail::string KernelName = getKernelName();

     return KernelName == LambdaName;

   }


   void saveCodeLoc(detail::code_location CodeLoc) { MCodeLoc = CodeLoc; }


   event finalize();


   void addStream(const std::shared_ptr<detail::stream_impl> &Stream) {

     MStreamStorage.push_back(Stream);

   }


   void addReduction(const std::shared_ptr<const void> &ReduObj);


   template <typename T, int Dimensions, typename AllocatorT, typename Enable>

   void

   addReduction(const std::shared_ptr<buffer<T, Dimensions, AllocatorT, Enable>>

                    &ReduBuf) {

     detail::markBufferAsInternal(getSyclObjImpl(*ReduBuf));

     addReduction(std::shared_ptr<const void>(ReduBuf));

   }


   ~handler() = default;


   // TODO: Private and unusued. Remove when ABI break is allowed.

   bool is_host() { return MIsHost; }


 #ifdef __SYCL_DEVICE_ONLY__

   // In device compilation accessor isn't inherited from host base classes, so

   // can't detect by it. Since we don't expect it to be ever called in device

   // execution, just use blind void *.

   void associateWithHandler(void *AccBase, access::target AccTarget);

   void associateWithHandler(void *AccBase, image_target AccTarget);

 #else

   void associateWithHandlerCommon(detail::AccessorImplPtr AccImpl,

                                   int AccTarget);

   void associateWithHandler(detail::AccessorBaseHost *AccBase,

                             access::target AccTarget);

   void associateWithHandler(detail::UnsampledImageAccessorBaseHost *AccBase,

                             image_target AccTarget);

   void associateWithHandler(detail::SampledImageAccessorBaseHost *AccBase,

                             image_target AccTarget);

 #endif


   // Recursively calls itself until arguments pack is fully processed.

   // The version for regular(standard layout) argument.

   template <typename T, typename... Ts>

   void setArgsHelper(int ArgIndex, T &&Arg, Ts &&...Args) {

     set_arg(ArgIndex, std::move(Arg));

     setArgsHelper(++ArgIndex, std::move(Args)...);

   }


   void setArgsHelper(int) {}


   void setLocalAccessorArgHelper(int ArgIndex,

                                  detail::LocalAccessorBaseHost &LocalAccBase) {

     detail::LocalAccessorImplPtr LocalAccImpl =

         detail::getSyclObjImpl(LocalAccBase);

     detail::LocalAccessorImplHost *Req = LocalAccImpl.get();

     MLocalAccStorage.push_back(std::move(LocalAccImpl));

     MArgs.emplace_back(detail::kernel_param_kind_t::kind_accessor, Req,

                        static_cast<int>(access::target::local), ArgIndex);

   }


   // setArgHelper for local accessor argument (legacy accessor interface)

   template <typename DataT, int Dims, access::mode AccessMode,

             access::placeholder IsPlaceholder>

   void setArgHelper(int ArgIndex,

                     accessor<DataT, Dims, AccessMode, access::target::local,

                              IsPlaceholder> &&Arg) {

     (void)ArgIndex;

     (void)Arg;

 #ifndef __SYCL_DEVICE_ONLY__

     setLocalAccessorArgHelper(ArgIndex, Arg);

 #endif

   }


   // setArgHelper for local accessor argument (up to date accessor interface)

   template <typename DataT, int Dims>

   void setArgHelper(int ArgIndex, local_accessor<DataT, Dims> &&Arg) {

     (void)ArgIndex;

     (void)Arg;

 #ifndef __SYCL_DEVICE_ONLY__

     setLocalAccessorArgHelper(ArgIndex, Arg);

 #endif

   }


   // setArgHelper for non local accessor argument.

   template <typename DataT, int Dims, access::mode AccessMode,

             access::target AccessTarget, access::placeholder IsPlaceholder>

   typename std::enable_if_t<AccessTarget != access::target::local, void>

   setArgHelper(

       int ArgIndex,

       accessor<DataT, Dims, AccessMode, AccessTarget, IsPlaceholder> &&Arg) {

     detail::AccessorBaseHost *AccBase = (detail::AccessorBaseHost *)&Arg;

     detail::AccessorImplPtr AccImpl = detail::getSyclObjImpl(*AccBase);

     detail::AccessorImplHost *Req = AccImpl.get();

     // Add accessor to the list of requirements.

     CGData.MRequirements.push_back(Req);

     // Store copy of the accessor.

     CGData.MAccStorage.push_back(std::move(AccImpl));

     // Add accessor to the list of arguments.

     MArgs.emplace_back(detail::kernel_param_kind_t::kind_accessor, Req,

                        static_cast<int>(AccessTarget), ArgIndex);

   }


   template <typename T> void setArgHelper(int ArgIndex, T &&Arg) {

     auto StoredArg = static_cast<void *>(storePlainArg(Arg));


     if (!std::is_same<cl_mem, T>::value && std::is_pointer<T>::value) {

       MArgs.emplace_back(detail::kernel_param_kind_t::kind_pointer, StoredArg,

                          sizeof(T), ArgIndex);

     } else {

       MArgs.emplace_back(detail::kernel_param_kind_t::kind_std_layout,

                          StoredArg, sizeof(T), ArgIndex);

     }

   }


   void setArgHelper(int ArgIndex, sampler &&Arg) {

     auto StoredArg = static_cast<void *>(storePlainArg(Arg));

     MArgs.emplace_back(detail::kernel_param_kind_t::kind_sampler, StoredArg,

                        sizeof(sampler), ArgIndex);

   }


   // setArgHelper for graph dynamic_parameters

   template <typename T>

   void

   setArgHelper(int ArgIndex,

                ext::oneapi::experimental::dynamic_parameter<T> DynamicParam) {

     // Extract and copy arg so we can move it into setArgHelper

     T ArgValue =

         *static_cast<T *>(detail::getValueFromDynamicParameter(DynamicParam));

     // Set the arg in the handler as normal

     setArgHelper(ArgIndex, std::move(ArgValue));

     // Register the dynamic parameter with the handler for later association

     // with the node being added

     registerDynamicParameter(DynamicParam, ArgIndex);

   }


   void registerDynamicParameter(

       ext::oneapi::experimental::detail::dynamic_parameter_base

           &DynamicParamBase,

       int ArgIndex);


   // TODO: Unusued. Remove when ABI break is allowed.

   void verifyKernelInvoc(const kernel &Kernel) {

     std::ignore = Kernel;

     return;

   }


   /* The kernel passed to StoreLambda can take an id, an item or an nd_item as

    * its argument. Since esimd plugin directly invokes the kernel (doesn’t use

    * piKernelSetArg), the kernel argument type must be known to the plugin.

    * However, passing kernel argument type to the plugin requires changing ABI

    * in HostKernel class. To overcome this problem, helpers below wrap the

    * “original” kernel with a functor that always takes an nd_item as argument.

    * A functor is used instead of a lambda because extractArgsAndReqsFromLambda

    * needs access to the “original” kernel and keeps references to its internal

    * data, i.e. the kernel passed as argument cannot be local in scope. The

    * functor itself is again encapsulated in a std::function since functor’s

    * type is unknown to the plugin.

    */


   // For 'id, item w/wo offset, nd_item' kernel arguments

   template <class KernelType, class NormalizedKernelType, int Dims>

   KernelType *ResetHostKernelHelper(const KernelType &KernelFunc) {

     NormalizedKernelType NormalizedKernel(KernelFunc);

     auto NormalizedKernelFunc =

         std::function<void(const sycl::nd_item<Dims> &)>(NormalizedKernel);

     auto HostKernelPtr = new detail::HostKernel<decltype(NormalizedKernelFunc),

                                                 sycl::nd_item<Dims>, Dims>(

         std::move(NormalizedKernelFunc));

     MHostKernel.reset(HostKernelPtr);

     return &HostKernelPtr->MKernel.template target<NormalizedKernelType>()

                 ->MKernelFunc;

   }


   // For 'sycl::id<Dims>' kernel argument

   template <class KernelType, typename ArgT, int Dims>

   std::enable_if_t<std::is_same_v<ArgT, sycl::id<Dims>>, KernelType *>

   ResetHostKernel(const KernelType &KernelFunc) {

     struct NormalizedKernelType {

       KernelType MKernelFunc;

       NormalizedKernelType(const KernelType &KernelFunc)

           : MKernelFunc(KernelFunc) {}

       void operator()(const nd_item<Dims> &Arg) {

         detail::runKernelWithArg(MKernelFunc, Arg.get_global_id());

       }

     };

     return ResetHostKernelHelper<KernelType, struct NormalizedKernelType, Dims>(

         KernelFunc);

   }


   // For 'sycl::nd_item<Dims>' kernel argument

   template <class KernelType, typename ArgT, int Dims>

   std::enable_if_t<std::is_same_v<ArgT, sycl::nd_item<Dims>>, KernelType *>

   ResetHostKernel(const KernelType &KernelFunc) {

     struct NormalizedKernelType {

       KernelType MKernelFunc;

       NormalizedKernelType(const KernelType &KernelFunc)

           : MKernelFunc(KernelFunc) {}

       void operator()(const nd_item<Dims> &Arg) {

         detail::runKernelWithArg(MKernelFunc, Arg);

       }

     };

     return ResetHostKernelHelper<KernelType, struct NormalizedKernelType, Dims>(

         KernelFunc);

   }


   // For 'sycl::item<Dims, without_offset>' kernel argument

   template <class KernelType, typename ArgT, int Dims>

   std::enable_if_t<std::is_same_v<ArgT, sycl::item<Dims, false>>, KernelType *>

   ResetHostKernel(const KernelType &KernelFunc) {

     struct NormalizedKernelType {

       KernelType MKernelFunc;

       NormalizedKernelType(const KernelType &KernelFunc)

           : MKernelFunc(KernelFunc) {}

       void operator()(const nd_item<Dims> &Arg) {

         sycl::item<Dims, false> Item = detail::Builder::createItem<Dims, false>(

             Arg.get_global_range(), Arg.get_global_id());

         detail::runKernelWithArg(MKernelFunc, Item);

       }

     };

     return ResetHostKernelHelper<KernelType, struct NormalizedKernelType, Dims>(

         KernelFunc);

   }


   // For 'sycl::item<Dims, with_offset>' kernel argument

   template <class KernelType, typename ArgT, int Dims>

   std::enable_if_t<std::is_same_v<ArgT, sycl::item<Dims, true>>, KernelType *>

   ResetHostKernel(const KernelType &KernelFunc) {

     struct NormalizedKernelType {

       KernelType MKernelFunc;

       NormalizedKernelType(const KernelType &KernelFunc)

           : MKernelFunc(KernelFunc) {}

       void operator()(const nd_item<Dims> &Arg) {

         sycl::item<Dims, true> Item = detail::Builder::createItem<Dims, true>(

             Arg.get_global_range(), Arg.get_global_id(), Arg.get_offset());

         detail::runKernelWithArg(MKernelFunc, Item);

       }

     };

     return ResetHostKernelHelper<KernelType, struct NormalizedKernelType, Dims>(

         KernelFunc);

   }


   // For 'void' kernel argument (single_task)

   template <class KernelType, typename ArgT, int Dims>

   typename std::enable_if_t<std::is_same_v<ArgT, void>, KernelType *>

   ResetHostKernel(const KernelType &KernelFunc) {

     struct NormalizedKernelType {

       KernelType MKernelFunc;

       NormalizedKernelType(const KernelType &KernelFunc)

           : MKernelFunc(KernelFunc) {}

       void operator()(const nd_item<Dims> &Arg) {

         (void)Arg;

         detail::runKernelWithoutArg(MKernelFunc);

       }

     };

     return ResetHostKernelHelper<KernelType, struct NormalizedKernelType, Dims>(

         KernelFunc);

   }


   // For 'sycl::group<Dims>' kernel argument

   // 'wrapper'-based approach using 'NormalizedKernelType' struct is not used

   // for 'void(sycl::group<Dims>)' since 'void(sycl::group<Dims>)' is not

   // supported in ESIMD.

   template <class KernelType, typename ArgT, int Dims>

   std::enable_if_t<std::is_same_v<ArgT, sycl::group<Dims>>, KernelType *>

   ResetHostKernel(const KernelType &KernelFunc) {

     MHostKernel.reset(

         new detail::HostKernel<KernelType, ArgT, Dims>(KernelFunc));

     return (KernelType *)(MHostKernel->getPtr());

   }


   void verifyUsedKernelBundle(const std::string &KernelName) {

     verifyUsedKernelBundleInternal(detail::string_view{KernelName});

   }

   void verifyUsedKernelBundleInternal(detail::string_view KernelName);


   template <typename KernelName, typename KernelType, int Dims,

             typename LambdaArgType>

   void StoreLambda(KernelType KernelFunc) {

     using KI = detail::KernelInfo<KernelName>;

     constexpr bool IsCallableWithKernelHandler =

         detail::KernelLambdaHasKernelHandlerArgT<KernelType,

                                                  LambdaArgType>::value;


     if (IsCallableWithKernelHandler && MIsHost) {

       throw sycl::feature_not_supported(

           "kernel_handler is not yet supported by host device.",

           PI_ERROR_INVALID_OPERATION);

     }


     KernelType *KernelPtr =

         ResetHostKernel<KernelType, LambdaArgType, Dims>(KernelFunc);


     constexpr bool KernelHasName =

         KI::getName() != nullptr && KI::getName()[0] != '\0';


     // Some host compilers may have different captures from Clang. Currently

     // there is no stable way of handling this when extracting the captures, so

     // a static assert is made to fail for incompatible kernel lambdas.

     static_assert(

         !KernelHasName || sizeof(KernelFunc) == KI::getKernelSize(),

         "Unexpected kernel lambda size. This can be caused by an "

         "external host compiler producing a lambda with an "

         "unexpected layout. This is a limitation of the compiler."

         "In many cases the difference is related to capturing constexpr "

         "variables. In such cases removing constexpr specifier aligns the "

         "captures between the host compiler and the device compiler."

         "\n"

         "In case of MSVC, passing "

         "-fsycl-host-compiler-options='/std:c++latest' "

         "might also help.");


     // Empty name indicates that the compilation happens without integration

     // header, so don't perform things that require it.

     if (KernelHasName) {

       // TODO support ESIMD in no-integration-header case too.

       MArgs.clear();

       extractArgsAndReqsFromLambda(reinterpret_cast<char *>(KernelPtr),

                                    KI::getNumParams(), &KI::getParamDesc(0),

                                    KI::isESIMD());

       MKernelName = KI::getName();

     } else {

       // In case w/o the integration header it is necessary to process

       // accessors from the list(which are associated with this handler) as

       // arguments. We must copy the associated accessors as they are checked

       // later during finalize.

       MArgs = MAssociatedAccesors;

     }


     // If the kernel lambda is callable with a kernel_handler argument, manifest

     // the associated kernel handler.

     if (IsCallableWithKernelHandler) {

       getOrInsertHandlerKernelBundle(/*Insert=*/true);

     }

   }


   template <

       typename KernelName,

       typename PropertiesT = ext::oneapi::experimental::empty_properties_t>

   void processProperties(PropertiesT Props) {

     using KI = detail::KernelInfo<KernelName>;

     static_assert(

         ext::oneapi::experimental::is_property_list<PropertiesT>::value,

         "Template type is not a property list.");

     static_assert(

         !PropertiesT::template has_property<

             sycl::ext::intel::experimental::fp_control_key>() ||

             (PropertiesT::template has_property<

                  sycl::ext::intel::experimental::fp_control_key>() &&

              KI::isESIMD()),

         "Floating point control property is supported for ESIMD kernels only.");

     if constexpr (PropertiesT::template has_property<

                       sycl::ext::intel::experimental::cache_config_key>()) {

       auto Config = Props.template get_property<

           sycl::ext::intel::experimental::cache_config_key>();

       if (Config == sycl::ext::intel::experimental::large_slm) {

         setKernelCacheConfig(PI_EXT_KERNEL_EXEC_INFO_CACHE_LARGE_SLM);

       } else if (Config == sycl::ext::intel::experimental::large_data) {

         setKernelCacheConfig(PI_EXT_KERNEL_EXEC_INFO_CACHE_LARGE_DATA);

       }

     } else {

       std::ignore = Props;

     }


     constexpr bool UsesRootSync = PropertiesT::template has_property<

         sycl::ext::oneapi::experimental::use_root_sync_key>();

     setKernelIsCooperative(UsesRootSync);

   }


   template <int Dims_Src, int Dims_Dst>

   static bool IsCopyingRectRegionAvailable(const range<Dims_Src> Src,

                                            const range<Dims_Dst> Dst) {

     if (Dims_Src > Dims_Dst)

       return false;

     for (size_t I = 0; I < Dims_Src; ++I)

       if (Src[I] > Dst[I])

         return false;

     return true;

   }


   template <typename TSrc, int DimSrc, access::mode ModeSrc,

             access::target TargetSrc, typename TDst, int DimDst,

             access::mode ModeDst, access::target TargetDst,

             access::placeholder IsPHSrc, access::placeholder IsPHDst>

   std::enable_if_t<(DimSrc > 0) && (DimDst > 0), bool>

   copyAccToAccHelper(accessor<TSrc, DimSrc, ModeSrc, TargetSrc, IsPHSrc> Src,

                      accessor<TDst, DimDst, ModeDst, TargetDst, IsPHDst> Dst) {

     if (!MIsHost &&

         IsCopyingRectRegionAvailable(Src.get_range(), Dst.get_range()))

       return false;


     range<1> LinearizedRange(Src.size());

     parallel_for<__copyAcc2Acc<TSrc, DimSrc, ModeSrc, TargetSrc, TDst, DimDst,

                                ModeDst, TargetDst, IsPHSrc, IsPHDst>>(

         LinearizedRange, [=](id<1> Id) {

           size_t Index = Id[0];

           id<DimSrc> SrcId = detail::getDelinearizedId(Src.get_range(), Index);

           id<DimDst> DstId = detail::getDelinearizedId(Dst.get_range(), Index);

           Dst[DstId] = Src[SrcId];

         });

     return true;

   }


   template <typename TSrc, int DimSrc, access::mode ModeSrc,

             access::target TargetSrc, typename TDst, int DimDst,

             access::mode ModeDst, access::target TargetDst,

             access::placeholder IsPHSrc, access::placeholder IsPHDst>

   std::enable_if_t<DimSrc == 0 || DimDst == 0, bool>

   copyAccToAccHelper(accessor<TSrc, DimSrc, ModeSrc, TargetSrc, IsPHSrc> Src,

                      accessor<TDst, DimDst, ModeDst, TargetDst, IsPHDst> Dst) {

     if (!MIsHost)

       return false;


     single_task<__copyAcc2Acc<TSrc, DimSrc, ModeSrc, TargetSrc, TDst, DimDst,

                               ModeDst, TargetDst, IsPHSrc, IsPHDst>>(

         [=]() { *(Dst.get_pointer()) = *(Src.get_pointer()); });

     return true;

   }


 #ifndef __SYCL_DEVICE_ONLY__

   template <typename TSrc, typename TDst, int Dim, access::mode AccMode,

             access::target AccTarget, access::placeholder IsPH>

   std::enable_if_t<(Dim > 0)>

   copyAccToPtrHost(accessor<TSrc, Dim, AccMode, AccTarget, IsPH> Src,

                    TDst *Dst) {

     range<Dim> Range = Src.get_range();

     parallel_for<__copyAcc2Ptr<TSrc, TDst, Dim, AccMode, AccTarget, IsPH>>(

         Range, [=](id<Dim> Index) {

           const size_t LinearIndex = detail::getLinearIndex(Index, Range);

           using TSrcNonConst = typename std::remove_const_t<TSrc>;

           (reinterpret_cast<TSrcNonConst *>(Dst))[LinearIndex] = Src[Index];

         });

   }


   template <typename TSrc, typename TDst, int Dim, access::mode AccMode,

             access::target AccTarget, access::placeholder IsPH>

   std::enable_if_t<Dim == 0>

   copyAccToPtrHost(accessor<TSrc, Dim, AccMode, AccTarget, IsPH> Src,

                    TDst *Dst) {

     single_task<__copyAcc2Ptr<TSrc, TDst, Dim, AccMode, AccTarget, IsPH>>(

         [=]() {

           using TSrcNonConst = typename std::remove_const_t<TSrc>;

           *(reinterpret_cast<TSrcNonConst *>(Dst)) = *(Src.get_pointer());

         });

   }


   template <typename TSrc, typename TDst, int Dim, access::mode AccMode,

             access::target AccTarget, access::placeholder IsPH>

   std::enable_if_t<(Dim > 0)>

   copyPtrToAccHost(TSrc *Src,

                    accessor<TDst, Dim, AccMode, AccTarget, IsPH> Dst) {

     range<Dim> Range = Dst.get_range();

     parallel_for<__copyPtr2Acc<TSrc, TDst, Dim, AccMode, AccTarget, IsPH>>(

         Range, [=](id<Dim> Index) {

           const size_t LinearIndex = detail::getLinearIndex(Index, Range);

           Dst[Index] = (reinterpret_cast<const TDst *>(Src))[LinearIndex];

         });

   }


   template <typename TSrc, typename TDst, int Dim, access::mode AccMode,

             access::target AccTarget, access::placeholder IsPH>

   std::enable_if_t<Dim == 0>

   copyPtrToAccHost(TSrc *Src,

                    accessor<TDst, Dim, AccMode, AccTarget, IsPH> Dst) {

     single_task<__copyPtr2Acc<TSrc, TDst, Dim, AccMode, AccTarget, IsPH>>(

         [=]() {

           *(Dst.get_pointer()) = *(reinterpret_cast<const TDst *>(Src));

         });

   }

 #endif // __SYCL_DEVICE_ONLY__


   constexpr static bool isConstOrGlobal(access::target AccessTarget) {

     return AccessTarget == access::target::device ||

            AccessTarget == access::target::constant_buffer;

   }


   constexpr static bool isImageOrImageArray(access::target AccessTarget) {

     return AccessTarget == access::target::image ||

            AccessTarget == access::target::image_array;

   }


   constexpr static bool

   isValidTargetForExplicitOp(access::target AccessTarget) {

     return isConstOrGlobal(AccessTarget) || isImageOrImageArray(AccessTarget);

   }


   constexpr static bool isValidModeForSourceAccessor(access::mode AccessMode) {

     return AccessMode == access::mode::read ||

            AccessMode == access::mode::read_write;

   }


   constexpr static bool

   isValidModeForDestinationAccessor(access::mode AccessMode) {

     return AccessMode == access::mode::write ||

            AccessMode == access::mode::read_write ||

            AccessMode == access::mode::discard_write ||

            AccessMode == access::mode::discard_read_write;

   }


   // PI APIs only support select fill sizes: 1, 2, 4, 8, 16, 32, 64, 128

   constexpr static bool isBackendSupportedFillSize(size_t Size) {

     return Size == 1 || Size == 2 || Size == 4 || Size == 8 || Size == 16 ||

            Size == 32 || Size == 64 || Size == 128;

   }


   template <int Dims, typename LambdaArgType> struct TransformUserItemType {

     using type = std::conditional_t<

         std::is_convertible_v<nd_item<Dims>, LambdaArgType>, nd_item<Dims>,

         std::conditional_t<std::is_convertible_v<item<Dims>, LambdaArgType>,

                            item<Dims>, LambdaArgType>>;

   };


   std::optional<std::array<size_t, 3>> getMaxWorkGroups();

   // We need to use this version to support gcc 7.5.0. Remove when minimal

   // supported gcc version is bumped.

   std::tuple<std::array<size_t, 3>, bool> getMaxWorkGroups_v2();


   template <int Dims>

   std::tuple<range<Dims>, bool> getRoundedRange(range<Dims> UserRange) {

     range<Dims> RoundedRange = UserRange;

     // Disable the rounding-up optimizations under these conditions:

     // 1. The env var SYCL_DISABLE_PARALLEL_FOR_RANGE_ROUNDING is set.

     // 2. The kernel is provided via an interoperability method (this uses a

     // different code path).

     // 3. The range is already a multiple of the rounding factor.

     //

     // Cases 2 and 3 could be supported with extra effort.

     // As an optimization for the common case it is an

     // implementation choice to not support those scenarios.

     // Note that "this_item" is a free function, i.e. not tied to any

     // specific id or item. When concurrent parallel_fors are executing

     // on a device it is difficult to tell which parallel_for the call is

     // being made from. One could replicate portions of the

     // call-graph to make this_item calls kernel-specific but this is

     // not considered worthwhile.


     // Perform range rounding if rounding-up is enabled.

     if (this->DisableRangeRounding())

       return {range<Dims>{}, false};


     // Range should be a multiple of this for reasonable performance.

     size_t MinFactorX = 16;

     // Range should be a multiple of this for improved performance.

     size_t GoodFactor = 32;

     // Range should be at least this to make rounding worthwhile.

     size_t MinRangeX = 1024;


     // Check if rounding parameters have been set through environment:

     // SYCL_PARALLEL_FOR_RANGE_ROUNDING_PARAMS=MinRound:PreferredRound:MinRange

     this->GetRangeRoundingSettings(MinFactorX, GoodFactor, MinRangeX);


     // In SYCL, each dimension of a global range size is specified by

     // a size_t, which can be up to 64 bits.  All backends should be

     // able to accept a kernel launch with a 32-bit global range size

     // (i.e. do not throw an error).  The OpenCL CPU backend will

     // accept every 64-bit global range, but the GPU backends will not

     // generally accept every 64-bit global range.  So, when we get a

     // non-32-bit global range, we wrap the old kernel in a new kernel

     // that has each work item peform multiple invocations the old

     // kernel in a 32-bit global range.

     id<Dims> MaxNWGs = [&] {

       auto [MaxWGs, HasMaxWGs] = getMaxWorkGroups_v2();

       if (!HasMaxWGs) {

         id<Dims> Default;

         for (int i = 0; i < Dims; ++i)

           Default[i] = (std::numeric_limits<int32_t>::max)();

         return Default;

       }


       id<Dims> IdResult;

       size_t Limit = (std::numeric_limits<int>::max)();

       for (int i = 0; i < Dims; ++i)

         IdResult[i] = (std::min)(Limit, MaxWGs[Dims - i - 1]);

       return IdResult;

     }();

     auto M = (std::numeric_limits<uint32_t>::max)();

     range<Dims> MaxRange;

     for (int i = 0; i < Dims; ++i) {

       auto DesiredSize = MaxNWGs[i] * GoodFactor;

       MaxRange[i] =

           DesiredSize <= M ? DesiredSize : (M / GoodFactor) * GoodFactor;

     }


     bool DidAdjust = false;

     auto Adjust = [&](int Dim, size_t Value) {

       if (this->RangeRoundingTrace())

         std::cout << "parallel_for range adjusted at dim " << Dim << " from "

                   << RoundedRange[Dim] << " to " << Value << std::endl;

       RoundedRange[Dim] = Value;

       DidAdjust = true;

     };


 #ifdef __SYCL_EXP_PARALLEL_FOR_RANGE_ROUNDING__

     size_t GoodExpFactor = 1;

     switch (Dims) {

     case 1:

       GoodExpFactor = 32; // Make global range multiple of {32}

       break;

     case 2:

       GoodExpFactor = 16; // Make global range multiple of {16, 16}

       break;

     case 3:

       GoodExpFactor = 8; // Make global range multiple of {8, 8, 8}

       break;

     }


     // Check if rounding parameters have been set through environment:

     // SYCL_PARALLEL_FOR_RANGE_ROUNDING_PARAMS=MinRound:PreferredRound:MinRange

     this->GetRangeRoundingSettings(MinFactorX, GoodExpFactor, MinRangeX);


     for (auto i = 0; i < Dims; ++i)

       if (UserRange[i] % GoodExpFactor) {

         Adjust(i, ((UserRange[i] / GoodExpFactor) + 1) * GoodExpFactor);

       }

 #else

     // Perform range rounding if there are sufficient work-items to

     // need rounding and the user-specified range is not a multiple of

     // a "good" value.

     if (RoundedRange[0] % MinFactorX != 0 && RoundedRange[0] >= MinRangeX) {

       // It is sufficient to round up just the first dimension.

       // Multiplying the rounded-up value of the first dimension

       // by the values of the remaining dimensions (if any)

       // will yield a rounded-up value for the total range.

       Adjust(0, ((RoundedRange[0] + GoodFactor - 1) / GoodFactor) * GoodFactor);

     }

 #endif // __SYCL_EXP_PARALLEL_FOR_RANGE_ROUNDING__

 #ifdef __SYCL_FORCE_PARALLEL_FOR_RANGE_ROUNDING__

     // If we are forcing range rounding kernels to be used, we always want the

     // rounded range kernel to be generated, even if rounding isn't needed

     DidAdjust = true;

 #endif // __SYCL_FORCE_PARALLEL_FOR_RANGE_ROUNDING__


     for (int i = 0; i < Dims; ++i)

       if (RoundedRange[i] > MaxRange[i])

         Adjust(i, MaxRange[i]);


     if (!DidAdjust)

       return {range<Dims>{}, false};

     return {RoundedRange, true};

   }


   template <

       typename KernelName, typename KernelType, int Dims,

       typename PropertiesT = ext::oneapi::experimental::empty_properties_t>

   void parallel_for_lambda_impl(range<Dims> UserRange, PropertiesT Props,

                                 KernelType KernelFunc) {

     throwIfActionIsCreated();

     throwOnLocalAccessorMisuse<KernelName, KernelType>();

     if (!range_size_fits_in_size_t(UserRange))

       throw sycl::exception(make_error_code(errc::runtime),

                             "The total number of work-items in "

                             "a range must fit within size_t");


     using LambdaArgType = sycl::detail::lambda_arg_type<KernelType, item<Dims>>;


     // If 1D kernel argument is an integral type, convert it to sycl::item<1>

     // If user type is convertible from sycl::item/sycl::nd_item, use

     // sycl::item/sycl::nd_item to transport item information

     using TransformedArgType = std::conditional_t<

         std::is_integral<LambdaArgType>::value && Dims == 1, item<Dims>,

         typename TransformUserItemType<Dims, LambdaArgType>::type>;


     static_assert(!std::is_same_v<TransformedArgType, sycl::nd_item<Dims>>,

                   "Kernel argument cannot have a sycl::nd_item type in "

                   "sycl::parallel_for with sycl::range");


     static_assert(std::is_convertible_v<item<Dims>, LambdaArgType> ||

                       std::is_convertible_v<item<Dims, false>, LambdaArgType>,

                   "sycl::parallel_for(sycl::range) kernel must have the "

                   "first argument of sycl::item type, or of a type which is "

                   "implicitly convertible from sycl::item");


     using RefLambdaArgType = std::add_lvalue_reference_t<LambdaArgType>;

     static_assert(

         (std::is_invocable_v<KernelType, RefLambdaArgType> ||

          std::is_invocable_v<KernelType, RefLambdaArgType, kernel_handler>),

         "SYCL kernel lambda/functor has an unexpected signature, it should be "

         "invocable with sycl::item and optionally sycl::kernel_handler");


     // TODO: Properties may change the kernel function, so in order to avoid

     //       conflicts they should be included in the name.

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;


     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());


     // Range rounding can be disabled by the user.

     // Range rounding is not done on the host device.

     // Range rounding is supported only for newer SYCL standards.

 #if !defined(__SYCL_DISABLE_PARALLEL_FOR_RANGE_ROUNDING__) &&                  \

     !defined(DPCPP_HOST_DEVICE_OPENMP) &&                                      \

     !defined(DPCPP_HOST_DEVICE_PERF_NATIVE) && SYCL_LANGUAGE_VERSION >= 202001

     auto [RoundedRange, HasRoundedRange] = getRoundedRange(UserRange);

     if (HasRoundedRange) {

       using NameWT = typename detail::get_kernel_wrapper_name_t<NameT>::name;

       auto Wrapper =

           getRangeRoundedKernelLambda<NameWT, TransformedArgType, Dims>(

               KernelFunc, UserRange);


       using KName = std::conditional_t<std::is_same<KernelType, NameT>::value,

                                        decltype(Wrapper), NameWT>;


       kernel_parallel_for_wrapper<KName, TransformedArgType, decltype(Wrapper),

                                   PropertiesT>(Wrapper);

 #ifndef __SYCL_DEVICE_ONLY__

       // We are executing over the rounded range, but there are still

       // items/ids that are are constructed in ther range rounded

       // kernel use items/ids in the user range, which means that

       // __SYCL_ASSUME_INT can still be violated. So check the bounds

       // of the user range, instead of the rounded range.

       detail::checkValueRange<Dims>(UserRange);

       MNDRDesc.set(RoundedRange);

       StoreLambda<KName, decltype(Wrapper), Dims, TransformedArgType>(

           std::move(Wrapper));

       setType(detail::CG::Kernel);

       setNDRangeUsed(false);

 #endif

     } else

 #endif // !__SYCL_DISABLE_PARALLEL_FOR_RANGE_ROUNDING__ &&

        // !DPCPP_HOST_DEVICE_OPENMP && !DPCPP_HOST_DEVICE_PERF_NATIVE &&

        // SYCL_LANGUAGE_VERSION >= 202001

     {

       (void)UserRange;

       (void)Props;

 #ifndef __SYCL_FORCE_PARALLEL_FOR_RANGE_ROUNDING__

       // If parallel_for range rounding is forced then only range rounded

       // kernel is generated

       kernel_parallel_for_wrapper<NameT, TransformedArgType, KernelType,

                                   PropertiesT>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

       processProperties<NameT, PropertiesT>(Props);

       detail::checkValueRange<Dims>(UserRange);

       MNDRDesc.set(std::move(UserRange));

       StoreLambda<NameT, KernelType, Dims, TransformedArgType>(

           std::move(KernelFunc));

       setType(detail::CG::Kernel);

       setNDRangeUsed(false);

 #endif

 #else

       (void)KernelFunc;

 #endif // __SYCL_FORCE_PARALLEL_FOR_RANGE_ROUNDING__

     }

   }


   template <typename KernelName, typename KernelType, int Dims,

             typename PropertiesT>

   void parallel_for_impl(nd_range<Dims> ExecutionRange, PropertiesT Props,

                          _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // TODO: Properties may change the kernel function, so in order to avoid

     //       conflicts they should be included in the name.

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType =

         sycl::detail::lambda_arg_type<KernelType, nd_item<Dims>>;

     static_assert(

         std::is_convertible_v<sycl::nd_item<Dims>, LambdaArgType>,

         "Kernel argument of a sycl::parallel_for with sycl::nd_range "

         "must be either sycl::nd_item or be convertible from sycl::nd_item");

     using TransformedArgType = sycl::nd_item<Dims>;


     (void)ExecutionRange;

     (void)Props;

     kernel_parallel_for_wrapper<NameT, TransformedArgType, KernelType,

                                 PropertiesT>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     processProperties<NameT, PropertiesT>(Props);

     detail::checkValueRange<Dims>(ExecutionRange);

     MNDRDesc.set(std::move(ExecutionRange));

     StoreLambda<NameT, KernelType, Dims, TransformedArgType>(

         std::move(KernelFunc));

     setType(detail::CG::Kernel);

     setNDRangeUsed(true);

 #endif

   }


   template <int Dims>

   void parallel_for_impl(range<Dims> NumWorkItems, kernel Kernel) {

     throwIfActionIsCreated();

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     detail::checkValueRange<Dims>(NumWorkItems);

     MNDRDesc.set(std::move(NumWorkItems));

     setType(detail::CG::Kernel);

     setNDRangeUsed(false);

     extractArgsAndReqs();

     MKernelName = getKernelName();

   }


   template <

       typename KernelName, typename KernelType, int Dims,

       typename PropertiesT = ext::oneapi::experimental::empty_properties_t>

   void parallel_for_work_group_lambda_impl(range<Dims> NumWorkGroups,

                                            PropertiesT Props,

                                            _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // TODO: Properties may change the kernel function, so in order to avoid

     //       conflicts they should be included in the name.

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType =

         sycl::detail::lambda_arg_type<KernelType, group<Dims>>;

     (void)NumWorkGroups;

     (void)Props;

     kernel_parallel_for_work_group_wrapper<NameT, LambdaArgType, KernelType,

                                            PropertiesT>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     processProperties<NameT, PropertiesT>(Props);

     detail::checkValueRange<Dims>(NumWorkGroups);

     MNDRDesc.setNumWorkGroups(NumWorkGroups);

     StoreLambda<NameT, KernelType, Dims, LambdaArgType>(std::move(KernelFunc));

     setType(detail::CG::Kernel);

     setNDRangeUsed(false);

 #endif // __SYCL_DEVICE_ONLY__

   }


   template <

       typename KernelName, typename KernelType, int Dims,

       typename PropertiesT = ext::oneapi::experimental::empty_properties_t>

   void parallel_for_work_group_lambda_impl(range<Dims> NumWorkGroups,

                                            range<Dims> WorkGroupSize,

                                            PropertiesT Props,

                                            _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // TODO: Properties may change the kernel function, so in order to avoid

     //       conflicts they should be included in the name.

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType =

         sycl::detail::lambda_arg_type<KernelType, group<Dims>>;

     (void)NumWorkGroups;

     (void)WorkGroupSize;

     (void)Props;

     kernel_parallel_for_work_group_wrapper<NameT, LambdaArgType, KernelType,

                                            PropertiesT>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     processProperties<NameT, PropertiesT>(Props);

     nd_range<Dims> ExecRange =

         nd_range<Dims>(NumWorkGroups * WorkGroupSize, WorkGroupSize);

     detail::checkValueRange<Dims>(ExecRange);

     MNDRDesc.set(std::move(ExecRange));

     StoreLambda<NameT, KernelType, Dims, LambdaArgType>(std::move(KernelFunc));

     setType(detail::CG::Kernel);

 #endif // __SYCL_DEVICE_ONLY__

   }


 #ifdef SYCL_LANGUAGE_VERSION

 #define __SYCL_KERNEL_ATTR__ [[clang::sycl_kernel]]

 #else

 #define __SYCL_KERNEL_ATTR__

 #endif


   // NOTE: the name of this function - "kernel_single_task" - is used by the

   // Front End to determine kernel invocation kind.

   template <typename KernelName, typename KernelType, typename... Props>

 #ifdef __SYCL_DEVICE_ONLY__

   [[__sycl_detail__::add_ir_attributes_function(

       "sycl-single-task",

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::name...,

       nullptr,

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::value...)]]

 #endif

   __SYCL_KERNEL_ATTR__ void

   kernel_single_task(_KERNELFUNCPARAM(KernelFunc)) {

 #ifdef __SYCL_DEVICE_ONLY__

     KernelFunc();

 #else

     (void)KernelFunc;

 #endif

   }


   // NOTE: the name of this function - "kernel_single_task" - is used by the

   // Front End to determine kernel invocation kind.

   template <typename KernelName, typename KernelType, typename... Props>

 #ifdef __SYCL_DEVICE_ONLY__

   [[__sycl_detail__::add_ir_attributes_function(

       "sycl-single-task",

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::name...,

       nullptr,

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::value...)]]

 #endif

   __SYCL_KERNEL_ATTR__ void

   kernel_single_task(_KERNELFUNCPARAM(KernelFunc), kernel_handler KH) {

 #ifdef __SYCL_DEVICE_ONLY__

     KernelFunc(KH);

 #else

     (void)KernelFunc;

     (void)KH;

 #endif

   }


   // NOTE: the name of these functions - "kernel_parallel_for" - are used by the

   // Front End to determine kernel invocation kind.

   template <typename KernelName, typename ElementType, typename KernelType,

             typename... Props>

 #ifdef __SYCL_DEVICE_ONLY__

   [[__sycl_detail__::add_ir_attributes_function(

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::name...,

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::value...)]]

 #endif

   __SYCL_KERNEL_ATTR__ void

   kernel_parallel_for(_KERNELFUNCPARAM(KernelFunc)) {

 #ifdef __SYCL_DEVICE_ONLY__

     KernelFunc(detail::Builder::getElement(detail::declptr<ElementType>()));

 #else

     (void)KernelFunc;

 #endif

   }


   // NOTE: the name of these functions - "kernel_parallel_for" - are used by the

   // Front End to determine kernel invocation kind.

   template <typename KernelName, typename ElementType, typename KernelType,

             typename... Props>

 #ifdef __SYCL_DEVICE_ONLY__

   [[__sycl_detail__::add_ir_attributes_function(

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::name...,

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::value...)]]

 #endif

   __SYCL_KERNEL_ATTR__ void

   kernel_parallel_for(_KERNELFUNCPARAM(KernelFunc), kernel_handler KH) {

 #ifdef __SYCL_DEVICE_ONLY__

     KernelFunc(detail::Builder::getElement(detail::declptr<ElementType>()), KH);

 #else

     (void)KernelFunc;

     (void)KH;

 #endif

   }


   // NOTE: the name of this function - "kernel_parallel_for_work_group" - is

   // used by the Front End to determine kernel invocation kind.

   template <typename KernelName, typename ElementType, typename KernelType,

             typename... Props>

 #ifdef __SYCL_DEVICE_ONLY__

   [[__sycl_detail__::add_ir_attributes_function(

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::name...,

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::value...)]]

 #endif

   __SYCL_KERNEL_ATTR__ void

   kernel_parallel_for_work_group(_KERNELFUNCPARAM(KernelFunc)) {

 #ifdef __SYCL_DEVICE_ONLY__

     KernelFunc(detail::Builder::getElement(detail::declptr<ElementType>()));

 #else

     (void)KernelFunc;

 #endif

   }


   // NOTE: the name of this function - "kernel_parallel_for_work_group" - is

   // used by the Front End to determine kernel invocation kind.

   template <typename KernelName, typename ElementType, typename KernelType,

             typename... Props>

 #ifdef __SYCL_DEVICE_ONLY__

   [[__sycl_detail__::add_ir_attributes_function(

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::name...,

       ext::oneapi::experimental::detail::PropertyMetaInfo<Props>::value...)]]

 #endif

   __SYCL_KERNEL_ATTR__ void

   kernel_parallel_for_work_group(_KERNELFUNCPARAM(KernelFunc),

                                  kernel_handler KH) {

 #ifdef __SYCL_DEVICE_ONLY__

     KernelFunc(detail::Builder::getElement(detail::declptr<ElementType>()), KH);

 #else

     (void)KernelFunc;

     (void)KH;

 #endif

   }


   template <typename... Props> struct KernelPropertiesUnpackerImpl {

     // Just pass extra Props... as template parameters to the underlying

     // Caller->* member functions. Don't have reflection so try to use

     // templates as much as possible to reduce the amount of boilerplate code

     // needed. All the type checks are expected to be done at the Caller's

     // methods side.


     template <typename... TypesToForward, typename... ArgsTy>

     static void kernel_single_task_unpack(handler *h, ArgsTy... Args) {

       h->kernel_single_task<TypesToForward..., Props...>(Args...);

     }


     template <typename... TypesToForward, typename... ArgsTy>

     static void kernel_parallel_for_unpack(handler *h, ArgsTy... Args) {

       h->kernel_parallel_for<TypesToForward..., Props...>(Args...);

     }


     template <typename... TypesToForward, typename... ArgsTy>

     static void kernel_parallel_for_work_group_unpack(handler *h,

                                                       ArgsTy... Args) {

       h->kernel_parallel_for_work_group<TypesToForward..., Props...>(Args...);

     }

   };


   template <typename PropertiesT>

   struct KernelPropertiesUnpacker : public KernelPropertiesUnpackerImpl<> {

     // This should always fail outside the specialization below but must be

     // dependent to avoid failing even if not instantiated.

     static_assert(

         ext::oneapi::experimental::is_property_list<PropertiesT>::value,

         "Template type is not a property list.");

   };


   template <typename... Props>

   struct KernelPropertiesUnpacker<

       ext::oneapi::experimental::detail::properties_t<Props...>>

       : public KernelPropertiesUnpackerImpl<Props...> {};


   // Helper function to

   //

   //   * Make use of the KernelPropertiesUnpacker above

   //   * Decide if we need an extra kernel_handler parameter

   //

   // The interface uses a \p Lambda callback to propagate that information back

   // to the caller as we need the caller to communicate:

   //

   //   * Name of the method to call

   //   * Provide explicit template type parameters for the call

   //

   // Couldn't think of a better way to achieve both.

   template <typename KernelName, typename KernelType, typename PropertiesT,

             bool HasKernelHandlerArg, typename FuncTy>

   void unpack(_KERNELFUNCPARAM(KernelFunc), FuncTy Lambda) {

 #ifdef __SYCL_DEVICE_ONLY__

     detail::CheckDeviceCopyable<KernelType>();

 #endif // __SYCL_DEVICE_ONLY__

     using MergedPropertiesT =

         typename detail::GetMergedKernelProperties<KernelType,

                                                    PropertiesT>::type;

     using Unpacker = KernelPropertiesUnpacker<MergedPropertiesT>;

 #ifndef __SYCL_DEVICE_ONLY__

     // If there are properties provided by get method then process them.

     if constexpr (ext::oneapi::experimental::detail::

                       HasKernelPropertiesGetMethod<

                           _KERNELFUNCPARAMTYPE>::value) {

       processProperties<KernelName>(

           KernelFunc.get(ext::oneapi::experimental::properties_tag{}));

     }

 #endif

     if constexpr (HasKernelHandlerArg) {

       kernel_handler KH;

       Lambda(Unpacker{}, this, KernelFunc, KH);

     } else {

       Lambda(Unpacker{}, this, KernelFunc);

     }

   }


   // NOTE: to support kernel_handler argument in kernel lambdas, only

   // kernel_***_wrapper functions must be called in this code


   template <

       typename KernelName, typename KernelType,

       typename PropertiesT = ext::oneapi::experimental::empty_properties_t>

   void kernel_single_task_wrapper(_KERNELFUNCPARAM(KernelFunc)) {

     unpack<KernelName, KernelType, PropertiesT,

            detail::KernelLambdaHasKernelHandlerArgT<KernelType>::value>(

         KernelFunc, [&](auto Unpacker, auto... args) {

           Unpacker.template kernel_single_task_unpack<KernelName, KernelType>(

               args...);

         });

   }


   template <

       typename KernelName, typename ElementType, typename KernelType,

       typename PropertiesT = ext::oneapi::experimental::empty_properties_t>

   void kernel_parallel_for_wrapper(_KERNELFUNCPARAM(KernelFunc)) {

     unpack<KernelName, KernelType, PropertiesT,

            detail::KernelLambdaHasKernelHandlerArgT<KernelType,

                                                     ElementType>::value>(

         KernelFunc, [&](auto Unpacker, auto... args) {

           Unpacker.template kernel_parallel_for_unpack<KernelName, ElementType,

                                                        KernelType>(args...);

         });

   }


   template <

       typename KernelName, typename ElementType, typename KernelType,

       typename PropertiesT = ext::oneapi::experimental::empty_properties_t>

   void kernel_parallel_for_work_group_wrapper(_KERNELFUNCPARAM(KernelFunc)) {

     unpack<KernelName, KernelType, PropertiesT,

            detail::KernelLambdaHasKernelHandlerArgT<KernelType,

                                                     ElementType>::value>(

         KernelFunc, [&](auto Unpacker, auto... args) {

           Unpacker.template kernel_parallel_for_work_group_unpack<

               KernelName, ElementType, KernelType>(args...);

         });

   }


   template <

       typename KernelName, typename KernelType,

       typename PropertiesT = ext::oneapi::experimental::empty_properties_t>

   void single_task_lambda_impl(PropertiesT Props,

                                _KERNELFUNCPARAM(KernelFunc)) {

     (void)Props;

     throwIfActionIsCreated();

     throwOnLocalAccessorMisuse<KernelName, KernelType>();

     // TODO: Properties may change the kernel function, so in order to avoid

     //       conflicts they should be included in the name.

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     kernel_single_task_wrapper<NameT, KernelType, PropertiesT>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     // No need to check if range is out of INT_MAX limits as it's compile-time

     // known constant.

     MNDRDesc.set(range<1>{1});

     processProperties<NameT, PropertiesT>(Props);

     StoreLambda<NameT, KernelType, /*Dims*/ 1, void>(KernelFunc);

     setType(detail::CG::Kernel);

 #endif

   }


   void setStateExplicitKernelBundle();

   void setStateSpecConstSet();

   bool isStateExplicitKernelBundle() const;


   std::shared_ptr<detail::kernel_bundle_impl>

   getOrInsertHandlerKernelBundle(bool Insert) const;


   void setHandlerKernelBundle(kernel Kernel);


   void setHandlerKernelBundle(

       const std::shared_ptr<detail::kernel_bundle_impl> &NewKernelBundleImpPtr);


   template <typename FuncT>

   std::enable_if_t<detail::check_fn_signature<std::remove_reference_t<FuncT>,

                                               void()>::value ||

                    detail::check_fn_signature<std::remove_reference_t<FuncT>,

                                               void(interop_handle)>::value>

   host_task_impl(FuncT &&Func) {

     throwIfActionIsCreated();


     MNDRDesc.set(range<1>(1));

     // Need to copy these rather than move so that we can check associated

     // accessors during finalize

     MArgs = MAssociatedAccesors;


     MHostTask.reset(new detail::HostTask(std::move(Func)));


     setType(detail::CG::CodeplayHostTask);

   }


   std::shared_ptr<ext::oneapi::experimental::detail::graph_impl>

   getCommandGraph() const;


   void setUserFacingNodeType(ext::oneapi::experimental::node_type Type);


 public:

   handler(const handler &) = delete;

   handler(handler &&) = delete;

   handler &operator=(const handler &) = delete;

   handler &operator=(handler &&) = delete;


   template <auto &SpecName>

   void set_specialization_constant(

       typename std::remove_reference_t<decltype(SpecName)>::value_type Value) {


     setStateSpecConstSet();


     std::shared_ptr<detail::kernel_bundle_impl> KernelBundleImplPtr =

         getOrInsertHandlerKernelBundle(/*Insert=*/true);


     detail::createSyclObjFromImpl<kernel_bundle<bundle_state::input>>(

         KernelBundleImplPtr)

         .set_specialization_constant<SpecName>(Value);

   }


   template <auto &SpecName>

   typename std::remove_reference_t<decltype(SpecName)>::value_type

   get_specialization_constant() const {


     if (isStateExplicitKernelBundle())

       throw sycl::exception(make_error_code(errc::invalid),

                             "Specialization constants cannot be read after "

                             "explicitly setting the used kernel bundle");


     std::shared_ptr<detail::kernel_bundle_impl> KernelBundleImplPtr =

         getOrInsertHandlerKernelBundle(/*Insert=*/true);


     return detail::createSyclObjFromImpl<kernel_bundle<bundle_state::input>>(

                KernelBundleImplPtr)

         .get_specialization_constant<SpecName>();

   }


   void

   use_kernel_bundle(const kernel_bundle<bundle_state::executable> &ExecBundle);


   template <typename DataT, int Dims, access::mode AccMode,

             access::target AccTarget, access::placeholder isPlaceholder>

   void require(accessor<DataT, Dims, AccMode, AccTarget, isPlaceholder> Acc) {

     if (Acc.is_placeholder())

       associateWithHandler(&Acc, AccTarget);

   }


   template <typename DataT, int Dims, access::mode AccMode,

             access::target AccTarget, access::placeholder isPlaceholder>

   void require(ext::oneapi::experimental::dynamic_parameter<

                accessor<DataT, Dims, AccMode, AccTarget, isPlaceholder>>

                    dynamicParamAcc) {

     using AccT = accessor<DataT, Dims, AccMode, AccTarget, isPlaceholder>;

     AccT Acc = *static_cast<AccT *>(

         detail::getValueFromDynamicParameter(dynamicParamAcc));

     if (Acc.is_placeholder())

       associateWithHandler(&Acc, AccTarget);

   }


   void depends_on(event Event);


   void depends_on(const std::vector<event> &Events);


   template <typename T>

   using remove_cv_ref_t = typename std::remove_cv_t<std::remove_reference_t<T>>;


   template <typename U, typename T>

   using is_same_type = std::is_same<remove_cv_ref_t<U>, remove_cv_ref_t<T>>;


   template <typename T> struct ShouldEnableSetArg {

     static constexpr bool value =

         std::is_trivially_copyable_v<std::remove_reference_t<T>>

 #if SYCL_LANGUAGE_VERSION && SYCL_LANGUAGE_VERSION <= 201707

             && std::is_standard_layout<std::remove_reference_t<T>>::value

 #endif

         || is_same_type<sampler, T>::value // Sampler

         || (!is_same_type<cl_mem, T>::value &&

             std::is_pointer_v<remove_cv_ref_t<T>>) // USM

         || is_same_type<cl_mem, T>::value;         // Interop

   };


   template <typename T>

   typename std::enable_if_t<ShouldEnableSetArg<T>::value, void>

   set_arg(int ArgIndex, T &&Arg) {

     setArgHelper(ArgIndex, std::move(Arg));

   }


   template <typename DataT, int Dims, access::mode AccessMode,

             access::target AccessTarget, access::placeholder IsPlaceholder>

   void

   set_arg(int ArgIndex,

           accessor<DataT, Dims, AccessMode, AccessTarget, IsPlaceholder> Arg) {

     setArgHelper(ArgIndex, std::move(Arg));

   }


   template <typename DataT, int Dims>

   void set_arg(int ArgIndex, local_accessor<DataT, Dims> Arg) {

     setArgHelper(ArgIndex, std::move(Arg));

   }


   // set_arg for graph dynamic_parameters

   template <typename T>

   void set_arg(int argIndex,

                ext::oneapi::experimental::dynamic_parameter<T> &dynamicParam) {

     setArgHelper(argIndex, dynamicParam);

   }


   template <typename... Ts> void set_args(Ts &&...Args) {

     setArgsHelper(0, std::move(Args)...);

   }


   template <typename KernelName = detail::auto_name, typename KernelType>

   void single_task(_KERNELFUNCPARAM(KernelFunc)) {

     single_task_lambda_impl<KernelName>(

         ext::oneapi::experimental::empty_properties_t{}, KernelFunc);

   }


   template <typename KernelName = detail::auto_name, typename KernelType>

   void parallel_for(range<1> NumWorkItems, _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_lambda_impl<KernelName>(

         NumWorkItems, ext::oneapi::experimental::empty_properties_t{},

         std::move(KernelFunc));

   }


   template <typename KernelName = detail::auto_name, typename KernelType>

   void parallel_for(range<2> NumWorkItems, _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_lambda_impl<KernelName>(

         NumWorkItems, ext::oneapi::experimental::empty_properties_t{},

         std::move(KernelFunc));

   }


   template <typename KernelName = detail::auto_name, typename KernelType>

   void parallel_for(range<3> NumWorkItems, _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_lambda_impl<KernelName>(

         NumWorkItems, ext::oneapi::experimental::empty_properties_t{},

         std::move(KernelFunc));

   }


   template <typename FuncT>

   std::enable_if_t<detail::check_fn_signature<std::remove_reference_t<FuncT>,

                                               void()>::value ||

                    detail::check_fn_signature<std::remove_reference_t<FuncT>,

                                               void(interop_handle)>::value>

   host_task(FuncT &&Func) {

     host_task_impl(Func);

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims>

   __SYCL2020_DEPRECATED("offsets are deprecated in SYCL2020")

   void parallel_for(range<Dims> NumWorkItems, id<Dims> WorkItemOffset,

                     _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType = sycl::detail::lambda_arg_type<KernelType, item<Dims>>;

     using TransformedArgType = std::conditional_t<

         std::is_integral<LambdaArgType>::value && Dims == 1, item<Dims>,

         typename TransformUserItemType<Dims, LambdaArgType>::type>;

     (void)NumWorkItems;

     (void)WorkItemOffset;

     kernel_parallel_for_wrapper<NameT, TransformedArgType>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     detail::checkValueRange<Dims>(NumWorkItems, WorkItemOffset);

     MNDRDesc.set(std::move(NumWorkItems), std::move(WorkItemOffset));

     StoreLambda<NameT, KernelType, Dims, TransformedArgType>(

         std::move(KernelFunc));

     setType(detail::CG::Kernel);

     setNDRangeUsed(false);

 #endif

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims>

   void parallel_for_work_group(range<Dims> NumWorkGroups,

                                _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_work_group_lambda_impl<KernelName>(

         NumWorkGroups, ext::oneapi::experimental::empty_properties_t{},

         KernelFunc);

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims>

   void parallel_for_work_group(range<Dims> NumWorkGroups,

                                range<Dims> WorkGroupSize,

                                _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_work_group_lambda_impl<KernelName>(

         NumWorkGroups, WorkGroupSize,

         ext::oneapi::experimental::empty_properties_t{}, KernelFunc);

   }


   void single_task(kernel Kernel) {

     throwIfActionIsCreated();

     // Ignore any set kernel bundles and use the one associated with the kernel

     setHandlerKernelBundle(Kernel);

     // No need to check if range is out of INT_MAX limits as it's compile-time

     // known constant

     MNDRDesc.set(range<1>{1});

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     setType(detail::CG::Kernel);

     extractArgsAndReqs();

     MKernelName = getKernelName();

   }


   void parallel_for(range<1> NumWorkItems, kernel Kernel) {

     parallel_for_impl(NumWorkItems, Kernel);

   }


   void parallel_for(range<2> NumWorkItems, kernel Kernel) {

     parallel_for_impl(NumWorkItems, Kernel);

   }


   void parallel_for(range<3> NumWorkItems, kernel Kernel) {

     parallel_for_impl(NumWorkItems, Kernel);

   }


   template <int Dims>

   __SYCL2020_DEPRECATED("offsets are deprecated in SYCL 2020")

   void parallel_for(range<Dims> NumWorkItems, id<Dims> WorkItemOffset,

                     kernel Kernel) {

     throwIfActionIsCreated();

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     detail::checkValueRange<Dims>(NumWorkItems, WorkItemOffset);

     MNDRDesc.set(std::move(NumWorkItems), std::move(WorkItemOffset));

     setType(detail::CG::Kernel);

     setNDRangeUsed(false);

     extractArgsAndReqs();

     MKernelName = getKernelName();

   }


   template <int Dims> void parallel_for(nd_range<Dims> NDRange, kernel Kernel) {

     throwIfActionIsCreated();

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     detail::checkValueRange<Dims>(NDRange);

     MNDRDesc.set(std::move(NDRange));

     setType(detail::CG::Kernel);

     setNDRangeUsed(true);

     extractArgsAndReqs();

     MKernelName = getKernelName();

   }


   template <typename KernelName = detail::auto_name, typename KernelType>

   void single_task(kernel Kernel, _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // Ignore any set kernel bundles and use the one associated with the kernel

     setHandlerKernelBundle(Kernel);

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     (void)Kernel;

     kernel_single_task<NameT>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     // No need to check if range is out of INT_MAX limits as it's compile-time

     // known constant

     MNDRDesc.set(range<1>{1});

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     setType(detail::CG::Kernel);

     if (!MIsHost && !lambdaAndKernelHaveEqualName<NameT>()) {

       extractArgsAndReqs();

       MKernelName = getKernelName();

     } else

       StoreLambda<NameT, KernelType, /*Dims*/ 1, void>(std::move(KernelFunc));

 #else

     detail::CheckDeviceCopyable<KernelType>();

 #endif

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims>

   void parallel_for(kernel Kernel, range<Dims> NumWorkItems,

                     _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // Ignore any set kernel bundles and use the one associated with the kernel

     setHandlerKernelBundle(Kernel);

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType = sycl::detail::lambda_arg_type<KernelType, item<Dims>>;

     (void)Kernel;

     (void)NumWorkItems;

     kernel_parallel_for_wrapper<NameT, LambdaArgType>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     detail::checkValueRange<Dims>(NumWorkItems);

     MNDRDesc.set(std::move(NumWorkItems));

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     setType(detail::CG::Kernel);

     setNDRangeUsed(false);

     if (!MIsHost && !lambdaAndKernelHaveEqualName<NameT>()) {

       extractArgsAndReqs();

       MKernelName = getKernelName();

     } else

       StoreLambda<NameT, KernelType, Dims, LambdaArgType>(

           std::move(KernelFunc));

 #endif

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims>

   __SYCL2020_DEPRECATED("offsets are deprecated in SYCL 2020")

   void parallel_for(kernel Kernel, range<Dims> NumWorkItems,

                     id<Dims> WorkItemOffset, _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // Ignore any set kernel bundles and use the one associated with the kernel

     setHandlerKernelBundle(Kernel);

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType = sycl::detail::lambda_arg_type<KernelType, item<Dims>>;

     (void)Kernel;

     (void)NumWorkItems;

     (void)WorkItemOffset;

     kernel_parallel_for_wrapper<NameT, LambdaArgType>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     detail::checkValueRange<Dims>(NumWorkItems, WorkItemOffset);

     MNDRDesc.set(std::move(NumWorkItems), std::move(WorkItemOffset));

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     setType(detail::CG::Kernel);

     setNDRangeUsed(false);

     if (!MIsHost && !lambdaAndKernelHaveEqualName<NameT>()) {

       extractArgsAndReqs();

       MKernelName = getKernelName();

     } else

       StoreLambda<NameT, KernelType, Dims, LambdaArgType>(

           std::move(KernelFunc));

 #endif

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims>

   void parallel_for(kernel Kernel, nd_range<Dims> NDRange,

                     _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // Ignore any set kernel bundles and use the one associated with the kernel

     setHandlerKernelBundle(Kernel);

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType =

         sycl::detail::lambda_arg_type<KernelType, nd_item<Dims>>;

     (void)Kernel;

     (void)NDRange;

     kernel_parallel_for_wrapper<NameT, LambdaArgType>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     detail::checkValueRange<Dims>(NDRange);

     MNDRDesc.set(std::move(NDRange));

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     setType(detail::CG::Kernel);

     setNDRangeUsed(true);

     if (!MIsHost && !lambdaAndKernelHaveEqualName<NameT>()) {

       extractArgsAndReqs();

       MKernelName = getKernelName();

     } else

       StoreLambda<NameT, KernelType, Dims, LambdaArgType>(

           std::move(KernelFunc));

 #endif

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims>

   void parallel_for_work_group(kernel Kernel, range<Dims> NumWorkGroups,

                                _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // Ignore any set kernel bundles and use the one associated with the kernel

     setHandlerKernelBundle(Kernel);

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType =

         sycl::detail::lambda_arg_type<KernelType, group<Dims>>;

     (void)Kernel;

     (void)NumWorkGroups;

     kernel_parallel_for_work_group_wrapper<NameT, LambdaArgType>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     detail::checkValueRange<Dims>(NumWorkGroups);

     MNDRDesc.setNumWorkGroups(NumWorkGroups);

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     StoreLambda<NameT, KernelType, Dims, LambdaArgType>(std::move(KernelFunc));

     setType(detail::CG::Kernel);

 #endif // __SYCL_DEVICE_ONLY__

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims>

   void parallel_for_work_group(kernel Kernel, range<Dims> NumWorkGroups,

                                range<Dims> WorkGroupSize,

                                _KERNELFUNCPARAM(KernelFunc)) {

     throwIfActionIsCreated();

     // Ignore any set kernel bundles and use the one associated with the kernel

     setHandlerKernelBundle(Kernel);

     using NameT =

         typename detail::get_kernel_name_t<KernelName, KernelType>::name;

     verifyUsedKernelBundle(detail::KernelInfo<NameT>::getName());

     using LambdaArgType =

         sycl::detail::lambda_arg_type<KernelType, group<Dims>>;

     (void)Kernel;

     (void)NumWorkGroups;

     (void)WorkGroupSize;

     kernel_parallel_for_work_group_wrapper<NameT, LambdaArgType>(KernelFunc);

 #ifndef __SYCL_DEVICE_ONLY__

     nd_range<Dims> ExecRange =

         nd_range<Dims>(NumWorkGroups * WorkGroupSize, WorkGroupSize);

     detail::checkValueRange<Dims>(ExecRange);

     MNDRDesc.set(std::move(ExecRange));

     MKernel = detail::getSyclObjImpl(std::move(Kernel));

     StoreLambda<NameT, KernelType, Dims, LambdaArgType>(std::move(KernelFunc));

     setType(detail::CG::Kernel);

 #endif // __SYCL_DEVICE_ONLY__

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             typename PropertiesT>

   std::enable_if_t<

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   single_task(PropertiesT Props, _KERNELFUNCPARAM(KernelFunc)) {

     single_task_lambda_impl<KernelName, KernelType, PropertiesT>(Props,

                                                                  KernelFunc);

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             typename PropertiesT>

   std::enable_if_t<

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   parallel_for(range<1> NumWorkItems, PropertiesT Props,

                _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_lambda_impl<KernelName, KernelType, 1, PropertiesT>(

         NumWorkItems, Props, std::move(KernelFunc));

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             typename PropertiesT>

   std::enable_if_t<

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   parallel_for(range<2> NumWorkItems, PropertiesT Props,

                _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_lambda_impl<KernelName, KernelType, 2, PropertiesT>(

         NumWorkItems, Props, std::move(KernelFunc));

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             typename PropertiesT>

   std::enable_if_t<

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   parallel_for(range<3> NumWorkItems, PropertiesT Props,

                _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_lambda_impl<KernelName, KernelType, 3, PropertiesT>(

         NumWorkItems, Props, std::move(KernelFunc));

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             typename PropertiesT, int Dims>

   std::enable_if_t<

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   parallel_for(nd_range<Dims> Range, PropertiesT Properties,

                _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_impl<KernelName>(Range, Properties, std::move(KernelFunc));

   }


   template <typename KernelName = detail::auto_name, typename PropertiesT,

             typename... RestT>

   std::enable_if_t<

       (sizeof...(RestT) > 1) &&

       detail::AreAllButLastReductions<RestT...>::value &&

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   parallel_for(range<1> Range, PropertiesT Properties, RestT &&...Rest) {

     throwIfGraphAssociated<ext::oneapi::experimental::detail::

                                UnsupportedGraphFeatures::sycl_reductions>();

     detail::reduction_parallel_for<KernelName>(*this, Range, Properties,

                                                std::forward<RestT>(Rest)...);

   }


   template <typename KernelName = detail::auto_name, typename PropertiesT,

             typename... RestT>

   std::enable_if_t<

       (sizeof...(RestT) > 1) &&

       detail::AreAllButLastReductions<RestT...>::value &&

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   parallel_for(range<2> Range, PropertiesT Properties, RestT &&...Rest) {

     throwIfGraphAssociated<ext::oneapi::experimental::detail::

                                UnsupportedGraphFeatures::sycl_reductions>();

     detail::reduction_parallel_for<KernelName>(*this, Range, Properties,

                                                std::forward<RestT>(Rest)...);

   }


   template <typename KernelName = detail::auto_name, typename PropertiesT,

             typename... RestT>

   std::enable_if_t<

       (sizeof...(RestT) > 1) &&

       detail::AreAllButLastReductions<RestT...>::value &&

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   parallel_for(range<3> Range, PropertiesT Properties, RestT &&...Rest) {

     throwIfGraphAssociated<ext::oneapi::experimental::detail::

                                UnsupportedGraphFeatures::sycl_reductions>();

     detail::reduction_parallel_for<KernelName>(*this, Range, Properties,

                                                std::forward<RestT>(Rest)...);

   }


   template <typename KernelName = detail::auto_name, typename... RestT>

   std::enable_if_t<detail::AreAllButLastReductions<RestT...>::value>

   parallel_for(range<1> Range, RestT &&...Rest) {

     parallel_for<KernelName>(Range,

                              ext::oneapi::experimental::empty_properties_t{},

                              std::forward<RestT>(Rest)...);

   }


   template <typename KernelName = detail::auto_name, typename... RestT>

   std::enable_if_t<detail::AreAllButLastReductions<RestT...>::value>

   parallel_for(range<2> Range, RestT &&...Rest) {

     parallel_for<KernelName>(Range,

                              ext::oneapi::experimental::empty_properties_t{},

                              std::forward<RestT>(Rest)...);

   }


   template <typename KernelName = detail::auto_name, typename... RestT>

   std::enable_if_t<detail::AreAllButLastReductions<RestT...>::value>

   parallel_for(range<3> Range, RestT &&...Rest) {

     parallel_for<KernelName>(Range,

                              ext::oneapi::experimental::empty_properties_t{},

                              std::forward<RestT>(Rest)...);

   }


   template <typename KernelName = detail::auto_name, int Dims,

             typename PropertiesT, typename... RestT>

   std::enable_if_t<

       (sizeof...(RestT) > 1) &&

       detail::AreAllButLastReductions<RestT...>::value &&

       ext::oneapi::experimental::is_property_list<PropertiesT>::value>

   parallel_for(nd_range<Dims> Range, PropertiesT Properties, RestT &&...Rest) {

     throwIfGraphAssociated<ext::oneapi::experimental::detail::

                                UnsupportedGraphFeatures::sycl_reductions>();

     detail::reduction_parallel_for<KernelName>(*this, Range, Properties,

                                                std::forward<RestT>(Rest)...);

   }


   template <typename KernelName = detail::auto_name, int Dims,

             typename... RestT>

   std::enable_if_t<detail::AreAllButLastReductions<RestT...>::value>

   parallel_for(nd_range<Dims> Range, RestT &&...Rest) {

     parallel_for<KernelName>(Range,

                              ext::oneapi::experimental::empty_properties_t{},

                              std::forward<RestT>(Rest)...);

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims, typename PropertiesT>

   void parallel_for_work_group(range<Dims> NumWorkGroups, PropertiesT Props,

                                _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_work_group_lambda_impl<KernelName, KernelType, Dims,

                                         PropertiesT>(NumWorkGroups, Props,

                                                      KernelFunc);

   }


   template <typename KernelName = detail::auto_name, typename KernelType,

             int Dims, typename PropertiesT>

   void parallel_for_work_group(range<Dims> NumWorkGroups,

                                range<Dims> WorkGroupSize, PropertiesT Props,

                                _KERNELFUNCPARAM(KernelFunc)) {

     parallel_for_work_group_lambda_impl<KernelName, KernelType, Dims,

                                         PropertiesT>(

         NumWorkGroups, WorkGroupSize, Props, KernelFunc);

   }


   // Clean up KERNELFUNC macro.

 #undef _KERNELFUNCPARAM


   // Explicit copy operations API


   template <typename T_Src, typename T_Dst, int Dims, access::mode AccessMode,

             access::target AccessTarget,

             access::placeholder IsPlaceholder = access::placeholder::false_t>

   void copy(accessor<T_Src, Dims, AccessMode, AccessTarget, IsPlaceholder> Src,

             std::shared_ptr<T_Dst> Dst) {

     if (Src.is_placeholder())

       checkIfPlaceholderIsBoundToHandler(Src);


     throwIfActionIsCreated();

     static_assert(isValidTargetForExplicitOp(AccessTarget),

                   "Invalid accessor target for the copy method.");

     static_assert(isValidModeForSourceAccessor(AccessMode),

                   "Invalid accessor mode for the copy method.");

     // Make sure data shared_ptr points to is not released until we finish

     // work with it.

     CGData.MSharedPtrStorage.push_back(Dst);

     typename std::shared_ptr<T_Dst>::element_type *RawDstPtr = Dst.get();

     copy(Src, RawDstPtr);

   }


   template <typename T_Src, typename T_Dst, int Dims, access::mode AccessMode,

             access::target AccessTarget,

             access::placeholder IsPlaceholder = access::placeholder::false_t>

   void

   copy(std::shared_ptr<T_Src> Src,

        accessor<T_Dst, Dims, AccessMode, AccessTarget, IsPlaceholder> Dst) {

     if (Dst.is_placeholder())

       checkIfPlaceholderIsBoundToHandler(Dst);


     throwIfActionIsCreated();

     static_assert(isValidTargetForExplicitOp(AccessTarget),

                   "Invalid accessor target for the copy method.");

     static_assert(isValidModeForDestinationAccessor(AccessMode),

                   "Invalid accessor mode for the copy method.");

     // TODO: Add static_assert with is_device_copyable when vec is

     // device-copyable.

     // Make sure data shared_ptr points to is not released until we finish

     // work with it.

     CGData.MSharedPtrStorage.push_back(Src);

     typename std::shared_ptr<T_Src>::element_type *RawSrcPtr = Src.get();

     copy(RawSrcPtr, Dst);

   }


   template <typename T_Src, typename T_Dst, int Dims, access::mode AccessMode,

             access::target AccessTarget,

             access::placeholder IsPlaceholder = access::placeholder::false_t>

   void copy(accessor<T_Src, Dims, AccessMode, AccessTarget, IsPlaceholder> Src,

             T_Dst *Dst) {

     if (Src.is_placeholder())

       checkIfPlaceholderIsBoundToHandler(Src);


     throwIfActionIsCreated();

     static_assert(isValidTargetForExplicitOp(AccessTarget),

                   "Invalid accessor target for the copy method.");

     static_assert(isValidModeForSourceAccessor(AccessMode),

                   "Invalid accessor mode for the copy method.");

 #ifndef __SYCL_DEVICE_ONLY__

     if (MIsHost) {

       // TODO: Temporary implementation for host. Should be handled by memory

       // manager.

       copyAccToPtrHost(Src, Dst);

       return;

     }

 #endif

     setType(detail::CG::CopyAccToPtr);


     detail::AccessorBaseHost *AccBase = (detail::AccessorBaseHost *)&Src;

     detail::AccessorImplPtr AccImpl = detail::getSyclObjImpl(*AccBase);


     CGData.MRequirements.push_back(AccImpl.get());

     MSrcPtr = static_cast<void *>(AccImpl.get());

     MDstPtr = static_cast<void *>(Dst);

     // Store copy of accessor to the local storage to make sure it is alive

     // until we finish

     CGData.MAccStorage.push_back(std::move(AccImpl));

   }


   template <typename T_Src, typename T_Dst, int Dims, access::mode AccessMode,

             access::target AccessTarget,

             access::placeholder IsPlaceholder = access::placeholder::false_t>

   void

   copy(const T_Src *Src,

        accessor<T_Dst, Dims, AccessMode, AccessTarget, IsPlaceholder> Dst) {

     if (Dst.is_placeholder())

       checkIfPlaceholderIsBoundToHandler(Dst);


     throwIfActionIsCreated();

     static_assert(isValidTargetForExplicitOp(AccessTarget),

                   "Invalid accessor target for the copy method.");

     static_assert(isValidModeForDestinationAccessor(AccessMode),

                   "Invalid accessor mode for the copy method.");

     // TODO: Add static_assert with is_device_copyable when vec is

     // device-copyable.

 #ifndef __SYCL_DEVICE_ONLY__

     if (MIsHost) {

       // TODO: Temporary implementation for host. Should be handled by memory

       // manager.

       copyPtrToAccHost(Src, Dst);

       return;

     }

 #endif

     setType(detail::CG::CopyPtrToAcc);


     detail::AccessorBaseHost *AccBase = (detail::AccessorBaseHost *)&Dst;

     detail::AccessorImplPtr AccImpl = detail::getSyclObjImpl(*AccBase);


     CGData.MRequirements.push_back(AccImpl.get());

     MSrcPtr = const_cast<T_Src *>(Src);

     MDstPtr = static_cast<void *>(AccImpl.get());

     // Store copy of accessor to the local storage to make sure it is alive

     // until we finish

     CGData.MAccStorage.push_back(std::move(AccImpl));

   }


   template <

       typename T_Src, int Dims_Src, access::mode AccessMode_Src,

       access::target AccessTarget_Src, typename T_Dst, int Dims_Dst,

       access::mode AccessMode_Dst, access::target AccessTarget_Dst,

       access::placeholder IsPlaceholder_Src = access::placeholder::false_t,

       access::placeholder IsPlaceholder_Dst = access::placeholder::false_t>

   void copy(accessor<T_Src, Dims_Src, AccessMode_Src, AccessTarget_Src,

                      IsPlaceholder_Src>

                 Src,

             accessor<T_Dst, Dims_Dst, AccessMode_Dst, AccessTarget_Dst,

                      IsPlaceholder_Dst>

                 Dst) {

     if (Src.is_placeholder())

       checkIfPlaceholderIsBoundToHandler(Src);

     if (Dst.is_placeholder())

       checkIfPlaceholderIsBoundToHandler(Dst);


     throwIfActionIsCreated();

     static_assert(isValidTargetForExplicitOp(AccessTarget_Src),

                   "Invalid source accessor target for the copy method.");

     static_assert(isValidTargetForExplicitOp(AccessTarget_Dst),

                   "Invalid destination accessor target for the copy method.");

     static_assert(isValidModeForSourceAccessor(AccessMode_Src),

                   "Invalid source accessor mode for the copy method.");

     static_assert(isValidModeForDestinationAccessor(AccessMode_Dst),

                   "Invalid destination accessor mode for the copy method.");

     if (Dst.get_size() < Src.get_size())

       throw sycl::invalid_object_error(

           "The destination accessor size is too small to copy the memory into.",

           PI_ERROR_INVALID_OPERATION);


     if (copyAccToAccHelper(Src, Dst))

       return;

     setType(detail::CG::CopyAccToAcc);


     detail::AccessorBaseHost *AccBaseSrc = (detail::AccessorBaseHost *)&Src;

     detail::AccessorImplPtr AccImplSrc = detail::getSyclObjImpl(*AccBaseSrc);


     detail::AccessorBaseHost *AccBaseDst = (detail::AccessorBaseHost *)&Dst;

     detail::AccessorImplPtr AccImplDst = detail::getSyclObjImpl(*AccBaseDst);


     CGData.MRequirements.push_back(AccImplSrc.get());

     CGData.MRequirements.push_back(AccImplDst.get());

     MSrcPtr = AccImplSrc.get();

     MDstPtr = AccImplDst.get();

     // Store copy of accessor to the local storage to make sure it is alive

     // until we finish

     CGData.MAccStorage.push_back(std::move(AccImplSrc));

     CGData.MAccStorage.push_back(std::move(AccImplDst));

   }


   template <typename T, int Dims, access::mode AccessMode,

             access::target AccessTarget,

             access::placeholder IsPlaceholder = access::placeholder::false_t>

   void

   update_host(accessor<T, Dims, AccessMode, AccessTarget, IsPlaceholder> Acc) {

     if (Acc.is_placeholder())

       checkIfPlaceholderIsBoundToHandler(Acc);


     throwIfActionIsCreated();

     static_assert(isValidTargetForExplicitOp(AccessTarget),

                   "Invalid accessor target for the update_host method.");

     setType(detail::CG::UpdateHost);


     detail::AccessorBaseHost *AccBase = (detail::AccessorBaseHost *)&Acc;

     detail::AccessorImplPtr AccImpl = detail::getSyclObjImpl(*AccBase);


     MDstPtr = static_cast<void *>(AccImpl.get());

     CGData.MRequirements.push_back(AccImpl.get());

     CGData.MAccStorage.push_back(std::move(AccImpl));

   }


 public:

   template <typename T, int Dims, access::mode AccessMode,

             access::target AccessTarget,

             access::placeholder IsPlaceholder = access::placeholder::false_t,

             typename PropertyListT = property_list>

   void

   fill(accessor<T, Dims, AccessMode, AccessTarget, IsPlaceholder, PropertyListT>

            Dst,

        const T &Pattern) {

     assert(!MIsHost && "fill() should no longer be callable on a host device.");


     if (Dst.is_placeholder())

       checkIfPlaceholderIsBoundToHandler(Dst);


     throwIfActionIsCreated();

     setUserFacingNodeType(ext::oneapi::experimental::node_type::memfill);

     // TODO add check:T must be an integral scalar value or a SYCL vector type

     static_assert(isValidTargetForExplicitOp(AccessTarget),

                   "Invalid accessor target for the fill method.");

     // CG::Fill will result in piEnqueuFillBuffer/Image which requires that mem

     // data is contiguous. Thus we check range and offset when dim > 1

     // Images don't allow ranged accessors and are fine.

     if constexpr (isBackendSupportedFillSize(sizeof(T)) &&

                   ((Dims <= 1) || isImageOrImageArray(AccessTarget))) {

       StageFillCG(Dst, Pattern);

     } else if constexpr (Dims == 0) {

       // Special case for zero-dim accessors.

       parallel_for<__fill<T, Dims, AccessMode, AccessTarget, IsPlaceholder>>(

           range<1>(1), [=](id<1>) { Dst = Pattern; });

     } else {

       // Dim > 1

       bool OffsetUsable = (Dst.get_offset() == sycl::id<Dims>{});

       detail::AccessorBaseHost *AccBase = (detail::AccessorBaseHost *)&Dst;

       bool RangesUsable =

           (AccBase->getAccessRange() == AccBase->getMemoryRange());

       if (OffsetUsable && RangesUsable &&

           isBackendSupportedFillSize(sizeof(T))) {

         StageFillCG(Dst, Pattern);

       } else {

         range<Dims> Range = Dst.get_range();

         parallel_for<__fill<T, Dims, AccessMode, AccessTarget, IsPlaceholder>>(

             Range, [=](id<Dims> Index) { Dst[Index] = Pattern; });

       }

     }

   }


   template <typename T> void fill(void *Ptr, const T &Pattern, size_t Count) {

     throwIfActionIsCreated();

     setUserFacingNodeType(ext::oneapi::experimental::node_type::memfill);

     static_assert(is_device_copyable<T>::value,

                   "Pattern must be device copyable");

     parallel_for<__usmfill<T>>(range<1>(Count), [=](id<1> Index) {

       T *CastedPtr = static_cast<T *>(Ptr);

       CastedPtr[Index] = Pattern;

     });

   }


   void ext_oneapi_barrier() {

     throwIfActionIsCreated();

     setType(detail::CG::Barrier);

   }


   void ext_oneapi_barrier(const std::vector<event> &WaitList);


   void memcpy(void *Dest, const void *Src, size_t Count);


   template <typename T> void copy(const T *Src, T *Dest, size_t Count) {

     this->memcpy(Dest, Src, Count * sizeof(T));

   }


   void memset(void *Dest, int Value, size_t Count);


   void prefetch(const void *Ptr, size_t Count);


   void mem_advise(const void *Ptr, size_t Length, int Advice);


   template <typename T = unsigned char,

             typename = std::enable_if_t<std::is_same_v<T, unsigned char>>>

   void ext_oneapi_memcpy2d(void *Dest, size_t DestPitch, const void *Src,

                            size_t SrcPitch, size_t Width, size_t Height);


   template <typename T>

   void ext_oneapi_copy2d(const T *Src, size_t SrcPitch, T *Dest,

                          size_t DestPitch, size_t Width, size_t Height);


   template <typename T = unsigned char,

             typename = std::enable_if_t<std::is_same_v<T, unsigned char>>>

   void ext_oneapi_memset2d(void *Dest, size_t DestPitch, int Value,

                            size_t Width, size_t Height);


   template <typename T>

   void ext_oneapi_fill2d(void *Dest, size_t DestPitch, const T &Pattern,

                          size_t Width, size_t Height);


   template <typename T, typename PropertyListT>

   void memcpy(ext::oneapi::experimental::device_global<T, PropertyListT> &Dest,

               const void *Src, size_t NumBytes = sizeof(T),

               size_t DestOffset = 0) {

     throwIfGraphAssociated<

         ext::oneapi::experimental::detail::UnsupportedGraphFeatures::

             sycl_ext_oneapi_device_global>();

     if (sizeof(T) < DestOffset + NumBytes)

       throw sycl::exception(make_error_code(errc::invalid),

                             "Copy to device_global is out of bounds.");


     constexpr bool IsDeviceImageScoped = PropertyListT::template has_property<

         ext::oneapi::experimental::device_image_scope_key>();


     if (!detail::isDeviceGlobalUsedInKernel(&Dest)) {

       // If the corresponding device_global isn't used in any kernels, we fall

       // back to doing the memory operation on host-only.

       memcpyToHostOnlyDeviceGlobal(&Dest, Src, sizeof(T), IsDeviceImageScoped,

                                    NumBytes, DestOffset);

       return;

     }


     memcpyToDeviceGlobal(&Dest, Src, IsDeviceImageScoped, NumBytes, DestOffset);

   }


   template <typename T, typename PropertyListT>

   void

   memcpy(void *Dest,

          const ext::oneapi::experimental::device_global<T, PropertyListT> &Src,

          size_t NumBytes = sizeof(T), size_t SrcOffset = 0) {

     throwIfGraphAssociated<

         ext::oneapi::experimental::detail::UnsupportedGraphFeatures::

             sycl_ext_oneapi_device_global>();

     if (sizeof(T) < SrcOffset + NumBytes)

       throw sycl::exception(make_error_code(errc::invalid),

                             "Copy from device_global is out of bounds.");


     constexpr bool IsDeviceImageScoped = PropertyListT::template has_property<

         ext::oneapi::experimental::device_image_scope_key>();


     if (!detail::isDeviceGlobalUsedInKernel(&Src)) {

       // If the corresponding device_global isn't used in any kernels, we fall

       // back to doing the memory operation on host-only.

       memcpyFromHostOnlyDeviceGlobal(Dest, &Src, IsDeviceImageScoped, NumBytes,

                                      SrcOffset);

       return;

     }


     memcpyFromDeviceGlobal(Dest, &Src, IsDeviceImageScoped, NumBytes,

                            SrcOffset);

   }


   template <typename T, typename PropertyListT>

   void copy(const std::remove_all_extents_t<T> *Src,

             ext::oneapi::experimental::device_global<T, PropertyListT> &Dest,

             size_t Count = sizeof(T) / sizeof(std::remove_all_extents_t<T>),

             size_t StartIndex = 0) {

     this->memcpy(Dest, Src, Count * sizeof(std::remove_all_extents_t<T>),

                  StartIndex * sizeof(std::remove_all_extents_t<T>));

   }


   template <typename T, typename PropertyListT>

   void

   copy(const ext::oneapi::experimental::device_global<T, PropertyListT> &Src,

        std::remove_all_extents_t<T> *Dest,

        size_t Count = sizeof(T) / sizeof(std::remove_all_extents_t<T>),

        size_t StartIndex = 0) {

     this->memcpy(Dest, Src, Count * sizeof(std::remove_all_extents_t<T>),

                  StartIndex * sizeof(std::remove_all_extents_t<T>));

   }

   void ext_oneapi_graph(ext::oneapi::experimental::command_graph<

                         ext::oneapi::experimental::graph_state::executable>

                             Graph);


   void ext_oneapi_copy(

       void *Src, ext::oneapi::experimental::image_mem_handle Dest,

       const ext::oneapi::experimental::image_descriptor &DestImgDesc);


   void ext_oneapi_copy(

       void *Src, sycl::range<3> SrcOffset, sycl::range<3> SrcExtent,

       ext::oneapi::experimental::image_mem_handle Dest,

       sycl::range<3> DestOffset,

       const ext::oneapi::experimental::image_descriptor &DestImgDesc,

       sycl::range<3> CopyExtent);


   void ext_oneapi_copy(

       ext::oneapi::experimental::image_mem_handle Src, void *Dest,

       const ext::oneapi::experimental::image_descriptor &SrcImgDesc);


   void

   ext_oneapi_copy(ext::oneapi::experimental::image_mem_handle Src,

                   sycl::range<3> SrcOffset,

                   const ext::oneapi::experimental::image_descriptor &SrcImgDesc,

                   void *Dest, sycl::range<3> DestOffset,

                   sycl::range<3> DestExtent, sycl::range<3> CopyExtent);


   void ext_oneapi_copy(

       void *Src, void *Dest,

       const ext::oneapi::experimental::image_descriptor &DeviceImgDesc,

       size_t DeviceRowPitch);


   void ext_oneapi_copy(

       void *Src, sycl::range<3> SrcOffset, void *Dest,

       sycl::range<3> DestOffset,

       const ext::oneapi::experimental::image_descriptor &DeviceImgDesc,

       size_t DeviceRowPitch, sycl::range<3> HostExtent,

       sycl::range<3> CopyExtent);


   void ext_oneapi_wait_external_semaphore(

       sycl::ext::oneapi::experimental::interop_semaphore_handle

           SemaphoreHandle);


   void ext_oneapi_signal_external_semaphore(

       sycl::ext::oneapi::experimental::interop_semaphore_handle

           SemaphoreHandle);


 private:

   std::shared_ptr<detail::handler_impl> MImpl;

   std::shared_ptr<detail::queue_impl> MQueue;


   mutable detail::CG::StorageInitHelper CGData;

   std::vector<detail::LocalAccessorImplPtr> MLocalAccStorage;

   std::vector<std::shared_ptr<detail::stream_impl>> MStreamStorage;

   std::vector<detail::ArgDesc> MArgs;

   std::vector<detail::ArgDesc> MAssociatedAccesors;

   detail::NDRDescT MNDRDesc;

   detail::string MKernelName;

   std::shared_ptr<detail::kernel_impl> MKernel;

   detail::CG::CGTYPE MCGType = detail::CG::None;

   void *MSrcPtr = nullptr;

   void *MDstPtr = nullptr;

   size_t MLength = 0;

   std::vector<char> MPattern;

   std::unique_ptr<detail::HostKernelBase> MHostKernel;

   std::unique_ptr<detail::HostTask> MHostTask;

   std::vector<detail::EventImplPtr> MEventsWaitWithBarrier;


   std::shared_ptr<ext::oneapi::experimental::detail::graph_impl> MGraph;

   std::shared_ptr<ext::oneapi::experimental::detail::exec_graph_impl>

       MExecGraph;

   std::shared_ptr<ext::oneapi::experimental::detail::node_impl> MSubgraphNode;

   std::unique_ptr<detail::CG> MGraphNodeCG;


   bool MIsHost = false;


   detail::code_location MCodeLoc = {};

   bool MIsFinalized = false;

   event MLastEvent;


   // Make queue_impl class friend to be able to call finalize method.

   friend class detail::queue_impl;

   // Make accessor class friend to keep the list of associated accessors.

   template <typename DataT, int Dims, access::mode AccMode,

             access::target AccTarget, access::placeholder isPlaceholder,

             typename PropertyListT>

   friend class accessor;

   friend device detail::getDeviceFromHandler(handler &);


   template <typename DataT, int Dimensions, access::mode AccessMode,

             access::target AccessTarget, access::placeholder IsPlaceholder>

   friend class detail::image_accessor;

   // Make stream class friend to be able to keep the list of associated streams

   friend class stream;

   friend class detail::stream_impl;

   // Make reduction friends to store buffers and arrays created for it

   // in handler from reduction methods.

   template <typename T, class BinaryOperation, int Dims, size_t Extent,

             bool ExplicitIdentity, typename RedOutVar>

   friend class detail::reduction_impl_algo;


   friend inline void detail::reduction::finalizeHandler(handler &CGH);

   template <class FunctorTy>

   friend void detail::reduction::withAuxHandler(handler &CGH, FunctorTy Func);


   template <typename KernelName, detail::reduction::strategy Strategy, int Dims,

             typename PropertiesT, typename... RestT>

   friend void detail::reduction_parallel_for(handler &CGH, range<Dims> NDRange,

                                              PropertiesT Properties,

                                              RestT... Rest);


   template <typename KernelName, detail::reduction::strategy Strategy, int Dims,

             typename PropertiesT, typename... RestT>

   friend void

   detail::reduction_parallel_for(handler &CGH, nd_range<Dims> NDRange,

                                  PropertiesT Properties, RestT... Rest);


 #ifndef __SYCL_DEVICE_ONLY__

   friend void detail::associateWithHandler(handler &,

                                            detail::AccessorBaseHost *,

                                            access::target);

   friend void detail::associateWithHandler(

       handler &, detail::UnsampledImageAccessorBaseHost *, image_target);

   friend void detail::associateWithHandler(

       handler &, detail::SampledImageAccessorBaseHost *, image_target);

 #endif


   friend class ::MockHandler;

   friend class detail::queue_impl;


   // Make pipe class friend to be able to call ext_intel_read/write_host_pipe

   // method.

   template <class _name, class _dataT, int32_t _min_capacity,

             class _propertiesT, class>

   friend class ext::intel::experimental::pipe;


   void ext_intel_read_host_pipe(const std::string &Name, void *Ptr, size_t Size,

                                 bool Block = false) {

     ext_intel_read_host_pipe(detail::string_view(Name), Ptr, Size, Block);

   }

   void ext_intel_read_host_pipe(detail::string_view Name, void *Ptr,

                                 size_t Size, bool Block = false);


   void ext_intel_write_host_pipe(const std::string &Name, void *Ptr,

                                  size_t Size, bool Block = false) {

     ext_intel_write_host_pipe(detail::string_view(Name), Ptr, Size, Block);

   }

   void ext_intel_write_host_pipe(detail::string_view Name, void *Ptr,

                                  size_t Size, bool Block = false);

   friend class ext::oneapi::experimental::detail::graph_impl;

   friend class ext::oneapi::experimental::detail::dynamic_parameter_impl;


   bool DisableRangeRounding();


   bool RangeRoundingTrace();


   void GetRangeRoundingSettings(size_t &MinFactor, size_t &GoodFactor,

                                 size_t &MinRange);


   template <typename WrapperT, typename TransformedArgType, int Dims,

             typename KernelType,

             std::enable_if_t<detail::KernelLambdaHasKernelHandlerArgT<

                 KernelType, TransformedArgType>::value> * = nullptr>

   auto getRangeRoundedKernelLambda(KernelType KernelFunc,

                                    range<Dims> UserRange) {

     return detail::RoundedRangeKernelWithKH<TransformedArgType, Dims,

                                             KernelType>{UserRange, KernelFunc};

   }


   template <typename WrapperT, typename TransformedArgType, int Dims,

             typename KernelType,

             std::enable_if_t<!detail::KernelLambdaHasKernelHandlerArgT<

                 KernelType, TransformedArgType>::value> * = nullptr>

   auto getRangeRoundedKernelLambda(KernelType KernelFunc,

                                    range<Dims> UserRange) {

     return detail::RoundedRangeKernel<TransformedArgType, Dims, KernelType>{

         UserRange, KernelFunc};

   }


   const std::shared_ptr<detail::context_impl> &getContextImplPtr() const;


   // Checks if 2D memory operations are supported by the underlying platform.

   bool supportsUSMMemcpy2D();

   bool supportsUSMFill2D();

   bool supportsUSMMemset2D();


   // Helper function for getting a loose bound on work-items.

   id<2> computeFallbackKernelBounds(size_t Width, size_t Height);


   // Common function for launching a 2D USM memcpy kernel to avoid redefinitions

   // of the kernel from copy and memcpy.

   template <typename T>

   void commonUSMCopy2DFallbackKernel(const void *Src, size_t SrcPitch,

                                      void *Dest, size_t DestPitch, size_t Width,

                                      size_t Height) {

     // Otherwise the data is accessible on the device so we do the operation

     // there instead.

     // Limit number of work items to be resistant to big copies.

     id<2> Chunk = computeFallbackKernelBounds(Height, Width);

     id<2> Iterations = (Chunk + id<2>{Height, Width} - 1) / Chunk;

     parallel_for<__usmmemcpy2d<T>>(

         range<2>{Chunk[0], Chunk[1]}, [=](id<2> Index) {

           T *CastedDest = static_cast<T *>(Dest);

           const T *CastedSrc = static_cast<const T *>(Src);

           for (uint32_t I = 0; I < Iterations[0]; ++I) {

             for (uint32_t J = 0; J < Iterations[1]; ++J) {

               id<2> adjustedIndex = Index + Chunk * id<2>{I, J};

               if (adjustedIndex[0] < Height && adjustedIndex[1] < Width) {

                 CastedDest[adjustedIndex[0] * DestPitch + adjustedIndex[1]] =

                     CastedSrc[adjustedIndex[0] * SrcPitch + adjustedIndex[1]];

               }

             }

           }

         });

   }


   // Common function for launching a 2D USM memcpy host-task to avoid

   // redefinitions of the kernel from copy and memcpy.

   template <typename T>

   void commonUSMCopy2DFallbackHostTask(const void *Src, size_t SrcPitch,

                                        void *Dest, size_t DestPitch,

                                        size_t Width, size_t Height) {

     // If both pointers are host USM or unknown (assumed non-USM) we use a

     // host-task to satisfy dependencies.

     host_task([=] {

       const T *CastedSrc = static_cast<const T *>(Src);

       T *CastedDest = static_cast<T *>(Dest);

       for (size_t I = 0; I < Height; ++I) {

         const T *SrcItBegin = CastedSrc + SrcPitch * I;

         T *DestItBegin = CastedDest + DestPitch * I;

         std::copy(SrcItBegin, SrcItBegin + Width, DestItBegin);

       }

     });

   }


   // StageFillCG()  Supporting function to fill()

   template <typename T, int Dims, access::mode AccessMode,

             access::target AccessTarget,

             access::placeholder IsPlaceholder = access::placeholder::false_t,

             typename PropertyListT = property_list>

   void StageFillCG(

       accessor<T, Dims, AccessMode, AccessTarget, IsPlaceholder, PropertyListT>

           Dst,

       const T &Pattern) {

     setType(detail::CG::Fill);

     detail::AccessorBaseHost *AccBase = (detail::AccessorBaseHost *)&Dst;

     detail::AccessorImplPtr AccImpl = detail::getSyclObjImpl(*AccBase);


     MDstPtr = static_cast<void *>(AccImpl.get());

     CGData.MRequirements.push_back(AccImpl.get());

     CGData.MAccStorage.push_back(std::move(AccImpl));


     MPattern.resize(sizeof(T));

     auto PatternPtr = reinterpret_cast<T *>(MPattern.data());

     *PatternPtr = Pattern;

   }


   // Common function for launching a 2D USM fill kernel to avoid redefinitions

   // of the kernel from memset and fill.

   template <typename T>

   void commonUSMFill2DFallbackKernel(void *Dest, size_t DestPitch,

                                      const T &Pattern, size_t Width,

                                      size_t Height) {

     // Otherwise the data is accessible on the device so we do the operation

     // there instead.

     // Limit number of work items to be resistant to big fill operations.

     id<2> Chunk = computeFallbackKernelBounds(Height, Width);

     id<2> Iterations = (Chunk + id<2>{Height, Width} - 1) / Chunk;

     parallel_for<__usmfill2d<T>>(

         range<2>{Chunk[0], Chunk[1]}, [=](id<2> Index) {

           T *CastedDest = static_cast<T *>(Dest);

           for (uint32_t I = 0; I < Iterations[0]; ++I) {

             for (uint32_t J = 0; J < Iterations[1]; ++J) {

               id<2> adjustedIndex = Index + Chunk * id<2>{I, J};

               if (adjustedIndex[0] < Height && adjustedIndex[1] < Width) {

                 CastedDest[adjustedIndex[0] * DestPitch + adjustedIndex[1]] =

                     Pattern;

               }

             }

           }

         });

   }


   // Common function for launching a 2D USM fill kernel or host_task to avoid

   // redefinitions of the kernel from memset and fill.

   template <typename T>

   void commonUSMFill2DFallbackHostTask(void *Dest, size_t DestPitch,

                                        const T &Pattern, size_t Width,

                                        size_t Height) {

     // If the pointer is host USM or unknown (assumed non-USM) we use a

     // host-task to satisfy dependencies.

     host_task([=] {

       T *CastedDest = static_cast<T *>(Dest);

       for (size_t I = 0; I < Height; ++I) {

         T *ItBegin = CastedDest + DestPitch * I;

         std::fill(ItBegin, ItBegin + Width, Pattern);

       }

     });

   }


   // Implementation of ext_oneapi_memcpy2d using command for native 2D memcpy.

   void ext_oneapi_memcpy2d_impl(void *Dest, size_t DestPitch, const void *Src,

                                 size_t SrcPitch, size_t Width, size_t Height);


   // Untemplated version of ext_oneapi_fill2d using command for native 2D fill.

   void ext_oneapi_fill2d_impl(void *Dest, size_t DestPitch, const void *Value,

                               size_t ValueSize, size_t Width, size_t Height);


   // Implementation of ext_oneapi_memset2d using command for native 2D memset.

   void ext_oneapi_memset2d_impl(void *Dest, size_t DestPitch, int Value,

                                 size_t Width, size_t Height);


   // Implementation of memcpy to device_global.

   void memcpyToDeviceGlobal(const void *DeviceGlobalPtr, const void *Src,

                             bool IsDeviceImageScoped, size_t NumBytes,

                             size_t Offset);


   // Implementation of memcpy from device_global.

   void memcpyFromDeviceGlobal(void *Dest, const void *DeviceGlobalPtr,

                               bool IsDeviceImageScoped, size_t NumBytes,

                               size_t Offset);


   // Implementation of memcpy to an unregistered device_global.

   void memcpyToHostOnlyDeviceGlobal(const void *DeviceGlobalPtr,

                                     const void *Src, size_t DeviceGlobalTSize,

                                     bool IsDeviceImageScoped, size_t NumBytes,

                                     size_t Offset);


   // Implementation of memcpy from an unregistered device_global.

   void memcpyFromHostOnlyDeviceGlobal(void *Dest, const void *DeviceGlobalPtr,

                                       bool IsDeviceImageScoped, size_t NumBytes,

                                       size_t Offset);


   template <typename T, int Dims, access::mode AccessMode,

             access::target AccessTarget,

             access::placeholder IsPlaceholder = access::placeholder::false_t,

             typename PropertyListT = property_list>

   void checkIfPlaceholderIsBoundToHandler(

       accessor<T, Dims, AccessMode, AccessTarget, IsPlaceholder, PropertyListT>

           Acc) {

     auto *AccBase = reinterpret_cast<detail::AccessorBaseHost *>(&Acc);

     detail::AccessorImplPtr AccImpl = detail::getSyclObjImpl(*AccBase);

     detail::AccessorImplHost *Req = AccImpl.get();

     if (std::find_if(MAssociatedAccesors.begin(), MAssociatedAccesors.end(),

                      [&](const detail::ArgDesc &AD) {

                        return AD.MType ==

                                   detail::kernel_param_kind_t::kind_accessor &&

                               AD.MPtr == Req &&

                               AD.MSize == static_cast<int>(AccessTarget);

                      }) == MAssociatedAccesors.end())

       throw sycl::exception(make_error_code(errc::kernel_argument),

                             "placeholder accessor must be bound by calling "

                             "handler::require() before it can be used.");

   }


   // Set value of the gpu cache configuration for the kernel.

   void setKernelCacheConfig(sycl::detail::pi::PiKernelCacheConfig);

   // Set value of the kernel is cooperative flag

   void setKernelIsCooperative(bool);


   template <

       ext::oneapi::experimental::detail::UnsupportedGraphFeatures FeatureT>

   void throwIfGraphAssociated() const {


     if (getCommandGraph()) {

       std::string FeatureString =

           ext::oneapi::experimental::detail::UnsupportedFeatureToString(

               FeatureT);

       throw sycl::exception(sycl::make_error_code(errc::invalid),

                             "The " + FeatureString +

                                 " feature is not yet available "

                                 "for use with the SYCL Graph extension.");

     }

   }


   // Set that an ND Range was used during a call to parallel_for

   void setNDRangeUsed(bool Value);

 };

 } // namespace _V1

 } // namespace sycl

access.hpp

accessor.hpp
The file contains implementations of accessor class.

bindless_images_descriptor.hpp

bindless_images_interop.hpp

bindless_images_memory.hpp

cg.hpp

cg_types.hpp

__copyAcc2Acc
Definition: handler.hpp:143

__copyAcc2Ptr
Definition: handler.hpp:130

__copyPtr2Acc
Definition: handler.hpp:135

__fill
Definition: handler.hpp:122

__usmfill2d
Definition: handler.hpp:124

__usmfill
Definition: handler.hpp:123

__usmmemcpy2d
Definition: handler.hpp:125

sycl::_V1::accessor
Definition: accessor.hpp:246

sycl::_V1::buffer
Defines a shared array that can be used by kernels in queues.
Definition: buffer.hpp:169

sycl::_V1::detail::AccessorBaseHost
Definition: accessor.hpp:534

sycl::_V1::detail::AccessorBaseHost::getMemoryRange
range< 3 > & getMemoryRange()
Definition: accessor.cpp:77

sycl::_V1::detail::AccessorBaseHost::getAccessRange
range< 3 > & getAccessRange()
Definition: accessor.cpp:76

sycl::_V1::detail::AccessorImplHost
Definition: accessor_impl.hpp:41

sycl::_V1::detail::CG::CGTYPE
CGTYPE
Type of the command group.
Definition: cg.hpp:56

sycl::_V1::detail::CG::CopyAccToPtr
@ CopyAccToPtr
Definition: cg.hpp:59

sycl::_V1::detail::CG::UpdateHost
@ UpdateHost
Definition: cg.hpp:65

sycl::_V1::detail::CG::CodeplayHostTask
@ CodeplayHostTask
Definition: cg.hpp:69

sycl::_V1::detail::CG::Barrier
@ Barrier
Definition: cg.hpp:62

sycl::_V1::detail::CG::Kernel
@ Kernel
Definition: cg.hpp:58

sycl::_V1::detail::CG::CopyPtrToAcc
@ CopyPtrToAcc
Definition: cg.hpp:60

sycl::_V1::detail::CG::CopyAccToAcc
@ CopyAccToAcc
Definition: cg.hpp:61

sycl::_V1::detail::CG::Fill
@ Fill
Definition: cg.hpp:64

sycl::_V1::detail::CG::None
@ None
Definition: cg.hpp:57

sycl::_V1::detail::HostKernel
Definition: cg_types.hpp:263

sycl::_V1::detail::LocalAccessorBaseHost
Definition: accessor.hpp:603

sycl::_V1::detail::LocalAccessorImplHost
Definition: accessor_impl.hpp:153

sycl::_V1::detail::NDRDescT
Definition: cg_types.hpp:53

sycl::_V1::detail::RoundedRangeIDGenerator
Definition: handler.hpp:322

sycl::_V1::detail::RoundedRangeIDGenerator::RoundedRangeIDGenerator
RoundedRangeIDGenerator(const id< Dims > &Id, const range< Dims > &UserRange, const range< Dims > &RoundedRange)
Definition: handler.hpp:330

sycl::_V1::detail::RoundedRangeIDGenerator::getId
id< Dims > getId()
Definition: handler.hpp:350

sycl::_V1::detail::RoundedRangeIDGenerator::getItem
auto getItem()
Definition: handler.hpp:352

sycl::_V1::detail::RoundedRangeIDGenerator::updateId
void updateId()
Definition: handler.hpp:340

sycl::_V1::detail::RoundedRangeKernelWithKH
Definition: handler.hpp:388

sycl::_V1::detail::RoundedRangeKernelWithKH::operator()
void operator()(item< Dims > It, kernel_handler KH) const
Definition: handler.hpp:392

sycl::_V1::detail::RoundedRangeKernelWithKH::KernelFunc
KernelType KernelFunc
Definition: handler.hpp:391

sycl::_V1::detail::RoundedRangeKernelWithKH::UserRange
range< Dims > UserRange
Definition: handler.hpp:390

sycl::_V1::detail::RoundedRangeKernel
Definition: handler.hpp:373

sycl::_V1::detail::RoundedRangeKernel::operator()
void operator()(item< Dims > It) const
Definition: handler.hpp:377

sycl::_V1::detail::RoundedRangeKernel::KernelFunc
KernelType KernelFunc
Definition: handler.hpp:376

sycl::_V1::detail::RoundedRangeKernel::UserRange
range< Dims > UserRange
Definition: handler.hpp:375

sycl::_V1::detail::SampledImageAccessorBaseHost
Definition: accessor.hpp:708

sycl::_V1::detail::UnsampledImageAccessorBaseHost
Definition: accessor.hpp:640

sycl::_V1::detail::__pf_kernel_wrapper
Definition: handler.hpp:204

sycl::_V1::detail::auto_name
This class is the default KernelName template parameter type for kernel invocation APIs such as singl...
Definition: kernel.hpp:45

sycl::_V1::detail::image_accessor
Definition: accessor.hpp:813

sycl::_V1::detail::queue_impl
Definition: queue_impl.hpp:70

sycl::_V1::detail::reduction_impl_algo
Definition: reduction.hpp:832

sycl::_V1::detail::stream_impl
Definition: stream_impl.hpp:25

sycl::_V1::detail::string_view
Definition: string_view.hpp:21

sycl::_V1::detail::string
Definition: string.hpp:21

sycl::_V1::device
The SYCL device class encapsulates a single SYCL device on which kernels may be executed.
Definition: device.hpp:64

sycl::_V1::event
An event object can be used to synchronize memory transfers, enqueues of kernels and signaling barrie...
Definition: event.hpp:44

sycl::exception
Definition: exception.hpp:68

sycl::_V1::ext::intel::experimental::pipe
Definition: pipes.hpp:56

sycl::_V1::ext::oneapi::experimental::command_graph
Graph in the modifiable state.
Definition: graph.hpp:392

sycl::_V1::ext::oneapi::experimental::detail::dynamic_parameter_base
Definition: graph.hpp:428

sycl::_V1::ext::oneapi::experimental::detail::dynamic_parameter_impl
Definition: graph_impl.hpp:1444

sycl::_V1::ext::oneapi::experimental::detail::graph_impl
Implementation details of command_graph<modifiable>.
Definition: graph_impl.hpp:794

sycl::_V1::ext::oneapi::experimental::device_global
Definition: device_global.hpp:135

sycl::_V1::ext::oneapi::experimental::dynamic_parameter
Definition: graph.hpp:448

sycl::_V1::handler
Command group handler class.
Definition: handler.hpp:458

sycl::_V1::handler::fill
void fill(void *Ptr, const T &Pattern, size_t Count)
Fills the specified memory with the specified pattern.
Definition: handler.hpp:2869

sycl::_V1::handler::parallel_for
void parallel_for(range< 2 > NumWorkItems, kernel Kernel)
Definition: handler.hpp:2147

sycl::_V1::handler::parallel_for
void parallel_for(kernel Kernel, range< Dims > NumWorkItems, _KERNELFUNCPARAM(KernelFunc))
Defines and invokes a SYCL kernel function for the specified range.
Definition: handler.hpp:2237

sycl::_V1::handler::single_task
void single_task(_KERNELFUNCPARAM(KernelFunc))
Defines and invokes a SYCL kernel function as a function object type.
Definition: handler.hpp:2008

sycl::_V1::handler::copy
void copy(const std::remove_all_extents_t< T > *Src, ext::oneapi::experimental::device_global< T, PropertyListT > &Dest, size_t Count=sizeof(T)/sizeof(std::remove_all_extents_t< T >), size_t StartIndex=0)
Copies elements of type std::remove_all_extents_t<T> from a USM memory region to a device_global.
Definition: handler.hpp:3099

sycl::_V1::handler::parallel_for
void parallel_for(nd_range< Dims > NDRange, kernel Kernel)
Defines and invokes a SYCL kernel function for the specified range and offsets.
Definition: handler.hpp:2185

sycl::_V1::handler::parallel_for
void parallel_for(range< 1 > NumWorkItems, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2014

sycl::_V1::handler::parallel_for_work_group
void parallel_for_work_group(range< Dims > NumWorkGroups, range< Dims > WorkGroupSize, PropertiesT Props, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2571

sycl::_V1::handler::parallel_for
std::enable_if_t<(sizeof...(RestT) > 1) &&detail::AreAllButLastReductions< RestT... >::value &&ext::oneapi::experimental::is_property_list< PropertiesT >::value > parallel_for(range< 2 > Range, PropertiesT Properties, RestT &&...Rest)
Definition: handler.hpp:2492

sycl::_V1::handler::copy
void copy(accessor< T_Src, Dims, AccessMode, AccessTarget, IsPlaceholder > Src, std::shared_ptr< T_Dst > Dst)
Copies the content of memory object accessed by Src into the memory pointed by Dst.
Definition: handler.hpp:2594

sycl::_V1::handler::parallel_for
std::enable_if_t<(sizeof...(RestT) > 1) &&detail::AreAllButLastReductions< RestT... >::value &&ext::oneapi::experimental::is_property_list< PropertiesT >::value > parallel_for(nd_range< Dims > Range, PropertiesT Properties, RestT &&...Rest)
Definition: handler.hpp:2542

sycl::_V1::handler::copy
void copy(const ext::oneapi::experimental::device_global< T, PropertyListT > &Src, std::remove_all_extents_t< T > *Dest, size_t Count=sizeof(T)/sizeof(std::remove_all_extents_t< T >), size_t StartIndex=0)
Copies elements of type std::remove_all_extents_t<T> from a device_global to a USM memory region.
Definition: handler.hpp:3119

sycl::_V1::handler::parallel_for
void parallel_for(range< 3 > NumWorkItems, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2028

sycl::_V1::handler::operator=
handler & operator=(handler &&)=delete

sycl::_V1::handler::parallel_for
std::enable_if_t<(sizeof...(RestT) > 1) &&detail::AreAllButLastReductions< RestT... >::value &&ext::oneapi::experimental::is_property_list< PropertiesT >::value > parallel_for(range< 3 > Range, PropertiesT Properties, RestT &&...Rest)
Definition: handler.hpp:2505

sycl::_V1::handler::handler
handler(handler &&)=delete

sycl::_V1::handler::copy
void copy(accessor< T_Src, Dims_Src, AccessMode_Src, AccessTarget_Src, IsPlaceholder_Src > Src, accessor< T_Dst, Dims_Dst, AccessMode_Dst, AccessTarget_Dst, IsPlaceholder_Dst > Dst)
Copies the content of memory object accessed by Src to the memory object accessed by Dst.
Definition: handler.hpp:2739

sycl::_V1::handler::copy
void copy(const T *Src, T *Dest, size_t Count)
Copies data from one memory region to another, each is either a host pointer or a pointer within USM ...
Definition: handler.hpp:2918

sycl::_V1::handler::parallel_for_work_group
void parallel_for_work_group(range< Dims > NumWorkGroups, range< Dims > WorkGroupSize, _KERNELFUNCPARAM(KernelFunc))
Hierarchical kernel invocation method of a kernel defined as a lambda encoding the body of each work-...
Definition: handler.hpp:2116

sycl::_V1::handler::parallel_for
void parallel_for(range< 3 > NumWorkItems, kernel Kernel)
Definition: handler.hpp:2151

sycl::_V1::handler::parallel_for
void parallel_for(range< 1 > NumWorkItems, kernel Kernel)
Definition: handler.hpp:2143

sycl::_V1::handler::single_task
void single_task(kernel Kernel, _KERNELFUNCPARAM(KernelFunc))
Defines and invokes a SYCL kernel function.
Definition: handler.hpp:2203

sycl::_V1::handler::operator=
handler & operator=(const handler &)=delete

sycl::_V1::handler::parallel_for
void parallel_for(kernel Kernel, nd_range< Dims > NDRange, _KERNELFUNCPARAM(KernelFunc))
Defines and invokes a SYCL kernel function for the specified range and offsets.
Definition: handler.hpp:2315

sycl::_V1::handler::parallel_for_work_group
void parallel_for_work_group(kernel Kernel, range< Dims > NumWorkGroups, range< Dims > WorkGroupSize, _KERNELFUNCPARAM(KernelFunc))
Hierarchical kernel invocation method of a kernel.
Definition: handler.hpp:2397

sycl::_V1::handler::require
void require(accessor< DataT, Dims, AccMode, AccTarget, isPlaceholder > Acc)
Requires access to the memory object associated with the placeholder accessor.
Definition: handler.hpp:1905

sycl::_V1::handler::fill
void fill(accessor< T, Dims, AccessMode, AccessTarget, IsPlaceholder, PropertyListT > Dst, const T &Pattern)
Fills memory pointed by accessor with the pattern given.
Definition: handler.hpp:2823

sycl::_V1::handler::update_host
void update_host(accessor< T, Dims, AccessMode, AccessTarget, IsPlaceholder > Acc)
Provides guarantees that the memory object accessed via Acc is updated on the host after command grou...
Definition: handler.hpp:2792

sycl::_V1::handler::set_arg
void set_arg(int argIndex, ext::oneapi::experimental::dynamic_parameter< T > &dynamicParam)
Definition: handler.hpp:1986

sycl::_V1::handler::parallel_for
std::enable_if_t< ext::oneapi::experimental::is_property_list< PropertiesT >::value > parallel_for(range< 2 > NumWorkItems, PropertiesT Props, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2446

sycl::_V1::handler::is_same_type
std::is_same< remove_cv_ref_t< U >, remove_cv_ref_t< T > > is_same_type
Definition: handler.hpp:1945

sycl::_V1::handler::set_arg
std::enable_if_t< ShouldEnableSetArg< T >::value, void > set_arg(int ArgIndex, T &&Arg)
Sets argument for OpenCL interoperability kernels.
Definition: handler.hpp:1967

sycl::_V1::handler::parallel_for_work_group
void parallel_for_work_group(range< Dims > NumWorkGroups, PropertiesT Props, _KERNELFUNCPARAM(KernelFunc))
}@
Definition: handler.hpp:2562

sycl::_V1::handler::require
void require(ext::oneapi::experimental::dynamic_parameter< accessor< DataT, Dims, AccMode, AccTarget, isPlaceholder >> dynamicParamAcc)
Requires access to the memory object associated with the placeholder accessor contained in a dynamic_...
Definition: handler.hpp:1921

sycl::_V1::handler::single_task
std::enable_if_t< ext::oneapi::experimental::is_property_list< PropertiesT >::value > single_task(PropertiesT Props, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2427

sycl::_V1::handler::single_task
void single_task(kernel Kernel)
Invokes a SYCL kernel.
Definition: handler.hpp:2130

sycl::_V1::handler::parallel_for
std::enable_if_t< detail::AreAllButLastReductions< RestT... >::value > parallel_for(nd_range< Dims > Range, RestT &&...Rest)
Definition: handler.hpp:2552

sycl::_V1::handler::copy
void copy(const T_Src *Src, accessor< T_Dst, Dims, AccessMode, AccessTarget, IsPlaceholder > Dst)
Copies the content of memory pointed by Src into the memory object accessed by Dst.
Definition: handler.hpp:2693

sycl::_V1::handler::parallel_for
std::enable_if_t< ext::oneapi::experimental::is_property_list< PropertiesT >::value > parallel_for(range< 3 > NumWorkItems, PropertiesT Props, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2456

sycl::_V1::handler::copy
void copy(std::shared_ptr< T_Src > Src, accessor< T_Dst, Dims, AccessMode, AccessTarget, IsPlaceholder > Dst)
Copies the content of memory pointed by Src into the memory object accessed by Dst.
Definition: handler.hpp:2622

sycl::_V1::handler::handler
handler(const handler &)=delete

sycl::_V1::handler::copy
void copy(accessor< T_Src, Dims, AccessMode, AccessTarget, IsPlaceholder > Src, T_Dst *Dst)
Copies the content of memory object accessed by Src into the memory pointed by Dst.
Definition: handler.hpp:2651

sycl::_V1::handler::remove_cv_ref_t
typename std::remove_cv_t< std::remove_reference_t< T > > remove_cv_ref_t
Definition: handler.hpp:1942

sycl::_V1::handler::parallel_for
std::enable_if_t< ext::oneapi::experimental::is_property_list< PropertiesT >::value > parallel_for(nd_range< Dims > Range, PropertiesT Properties, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2466

sycl::_V1::handler::parallel_for
std::enable_if_t< detail::AreAllButLastReductions< RestT... >::value > parallel_for(range< 1 > Range, RestT &&...Rest)
Definition: handler.hpp:2514

sycl::_V1::handler::parallel_for
std::enable_if_t< detail::AreAllButLastReductions< RestT... >::value > parallel_for(range< 2 > Range, RestT &&...Rest)
Definition: handler.hpp:2522

sycl::_V1::handler::parallel_for
std::enable_if_t< detail::AreAllButLastReductions< RestT... >::value > parallel_for(range< 3 > Range, RestT &&...Rest)
Definition: handler.hpp:2530

sycl::_V1::handler::parallel_for_work_group
void parallel_for_work_group(kernel Kernel, range< Dims > NumWorkGroups, _KERNELFUNCPARAM(KernelFunc))
Hierarchical kernel invocation method of a kernel.
Definition: handler.hpp:2358

sycl::_V1::handler::ext_oneapi_barrier
void ext_oneapi_barrier()
Prevents any commands submitted afterward to this queue from executing until all commands previously ...
Definition: handler.hpp:2883

sycl::_V1::handler::parallel_for
std::enable_if_t< ext::oneapi::experimental::is_property_list< PropertiesT >::value > parallel_for(range< 1 > NumWorkItems, PropertiesT Props, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2436

sycl::_V1::handler::memcpy
void memcpy(void *Dest, const ext::oneapi::experimental::device_global< T, PropertyListT > &Src, size_t NumBytes=sizeof(T), size_t SrcOffset=0)
Copies data from a device_global to USM memory.
Definition: handler.hpp:3064

sycl::_V1::handler::parallel_for_work_group
void parallel_for_work_group(range< Dims > NumWorkGroups, _KERNELFUNCPARAM(KernelFunc))
Hierarchical kernel invocation method of a kernel defined as a lambda encoding the body of each work-...
Definition: handler.hpp:2095

sycl::_V1::handler::host_task
std::enable_if_t< detail::check_fn_signature< std::remove_reference_t< FuncT >, void()>::value||detail::check_fn_signature< std::remove_reference_t< FuncT >, void(interop_handle)>::value > host_task(FuncT &&Func)
Enqueues a command to the SYCL runtime to invoke Func once.
Definition: handler.hpp:2040

sycl::_V1::handler::set_specialization_constant
void set_specialization_constant(typename std::remove_reference_t< decltype(SpecName)>::value_type Value)
Definition: handler.hpp:1862

sycl::_V1::handler::set_args
void set_args(Ts &&...Args)
Sets arguments for OpenCL interoperability kernels.
Definition: handler.hpp:1996

sycl::_V1::handler::memcpy
void memcpy(ext::oneapi::experimental::device_global< T, PropertyListT > &Dest, const void *Src, size_t NumBytes=sizeof(T), size_t DestOffset=0)
Copies data from a USM memory region to a device_global.
Definition: handler.hpp:3030

sycl::_V1::handler::parallel_for
void parallel_for(range< 2 > NumWorkItems, _KERNELFUNCPARAM(KernelFunc))
Definition: handler.hpp:2021

sycl::_V1::handler::set_arg
void set_arg(int ArgIndex, accessor< DataT, Dims, AccessMode, AccessTarget, IsPlaceholder > Arg)
Definition: handler.hpp:1974

sycl::_V1::handler::parallel_for
std::enable_if_t<(sizeof...(RestT) > 1) &&detail::AreAllButLastReductions< RestT... >::value &&ext::oneapi::experimental::is_property_list< PropertiesT >::value > parallel_for(range< 1 > Range, PropertiesT Properties, RestT &&...Rest)
Reductions.
Definition: handler.hpp:2479

sycl::_V1::handler::get_specialization_constant
std::remove_reference_t< decltype(SpecName)>::value_type get_specialization_constant() const
Definition: handler.hpp:1877

sycl::_V1::handler::set_arg
void set_arg(int ArgIndex, local_accessor< DataT, Dims > Arg)
Definition: handler.hpp:1980

sycl::_V1::id
A unique identifier of an item in an index space.
Definition: id.hpp:36

sycl::_V1::interop_handle
Definition: interop_handle.hpp:48

sycl::_V1::item
Identifies an instance of the function object executing at each point in a range.
Definition: item.hpp:37

sycl::_V1::item::get_id
id< Dimensions > get_id() const
Definition: item.hpp:55

sycl::_V1::item::get_range
range< Dimensions > get_range() const
Definition: item.hpp:69

sycl::_V1::kernel_bundle< bundle_state::executable >

sycl::_V1::kernel
Provides an abstraction of a SYCL kernel.
Definition: kernel.hpp:77

sycl::_V1::local_accessor
Definition: multi_ptr.hpp:73

sycl::nd_item
Identifies an instance of the function object executing at each point in an nd_range.
Definition: nd_item.hpp:48

sycl::_V1::nd_item::get_global_id
id< Dimensions > get_global_id() const
Definition: nd_item.hpp:52

sycl::_V1::nd_item::get_offset
id< Dimensions > get_offset() const
Definition: nd_item.hpp:197

sycl::_V1::nd_item::get_global_range
range< Dimensions > get_global_range() const
Definition: nd_item.hpp:164

sycl::_V1::nd_range
Defines the iteration domain of both the work-groups and the overall dispatch.
Definition: nd_range.hpp:22

sycl::_V1::property_list
Objects of the property_list class are containers for the SYCL properties.
Definition: property_list.hpp:31

sycl::_V1::range
Defines the iteration domain of either a single work-group in a parallel dispatch,...
Definition: range.hpp:26

sycl::_V1::range::size
size_t size() const
Definition: range.hpp:56

context.hpp

common.hpp

defines_elementary.hpp

device_global.hpp

event.hpp

exception.hpp

export.hpp

fp_control_kernel_properties.hpp

graph.hpp

group.hpp

_KERNELFUNCPARAMTYPE
#define _KERNELFUNCPARAMTYPE
Definition: handler.hpp:77

__SYCL_KERNEL_ATTR__
#define __SYCL_KERNEL_ATTR__
Definition: handler.hpp:1545

_KERNELFUNCPARAM
#define _KERNELFUNCPARAM(a)
Definition: handler.hpp:81

id.hpp

impl_utils.hpp

interop_handle.hpp

item.hpp

kernel_bundle.hpp

kernel_bundle_enums.hpp

kernel_desc.hpp

kernel_execution_properties.hpp

kernel_handler.hpp

std
Definition: accessor.hpp:4225

std::cout
__SYCL_EXTERN_STREAM_ATTRS ostream cout
Linked to standard output.

sycl::_V1::access::placeholder
placeholder
Definition: access.hpp:49

sycl::_V1::access::placeholder::false_t
@ false_t

sycl::_V1::access::target
target
Definition: access.hpp:22

sycl::_V1::access::target::image_array
@ image_array

sycl::_V1::access::target::image
@ image

sycl::_V1::access::target::device
@ device

sycl::_V1::access::target::host_task
@ host_task

sycl::_V1::access::mode
mode
Definition: access.hpp:34

sycl::_V1::access::mode::read_write
@ read_write

sycl::_V1::access::mode::discard_read_write
@ discard_read_write

sycl::_V1::access::mode::read
@ read

sycl::_V1::access::mode::write
@ write

sycl::_V1::access::mode::discard_write
@ discard_write

sycl::_V1::detail::reduction::withAuxHandler
void withAuxHandler(handler &CGH, FunctorTy Func)
Definition: reduction.hpp:1166

sycl::_V1::detail::reduction::strategy
strategy
Definition: reduction_forward.hpp:32

sycl::_V1::detail::reduction::finalizeHandler
void finalizeHandler(handler &CGH)
Definition: reduction.hpp:1165

sycl::_V1::detail::kernel_param_kind_t
kernel_param_kind_t
Definition: kernel_desc.hpp:38

sycl::_V1::detail::kernel_param_kind_t::kind_accessor
@ kind_accessor

sycl::_V1::detail::kernel_param_kind_t::kind_pointer
@ kind_pointer

sycl::_V1::detail::kernel_param_kind_t::kind_sampler
@ kind_sampler

sycl::_V1::detail::kernel_param_kind_t::kind_std_layout
@ kind_std_layout

sycl::_V1::detail::getValueFromDynamicParameter
void * getValueFromDynamicParameter(ext::oneapi::experimental::detail::dynamic_parameter_base &DynamicParamBase)
Definition: handler.cpp:74

sycl::_V1::detail::getDeviceFromHandler
device getDeviceFromHandler(handler &CommandGroupHandlerRef)
Definition: accessor.cpp:16

sycl::_V1::detail::getLinearIndex
size_t getLinearIndex(const T< Dims > &Index, const U< Dims > &Range)
Definition: common.hpp:367

sycl::_V1::detail::argument_helper
decltype(member_ptr_helper(&F::operator())) argument_helper(int)
Definition: handler.hpp:195

sycl::_V1::detail::getDelinearizedId
id< 1 > getDelinearizedId(const range< 1 > &, size_t Index)
Definition: id.hpp:313

sycl::_V1::detail::member_ptr_helper
static Arg member_ptr_helper(RetType(Func::*)(Arg) const)

sycl::_V1::detail::isDeviceGlobalUsedInKernel
bool isDeviceGlobalUsedInKernel(const void *DeviceGlobalPtr)
Definition: handler.cpp:39

sycl::_V1::detail::multiply_with_overflow_check
static std::enable_if_t< std::is_unsigned_v< T >, bool > multiply_with_overflow_check(T &dst, T x, T y)
Definition: handler.hpp:409

sycl::_V1::detail::getSyclObjImpl
decltype(Obj::impl) getSyclObjImpl(const Obj &SyclObject)
Definition: impl_utils.hpp:30

sycl::_V1::detail::checkValueRange
std::enable_if_t< std::is_same_v< T, range< Dims > >||std::is_same_v< T, id< Dims > > > checkValueRange(const T &V)
Definition: handler.hpp:273

sycl::_V1::detail::runKernelWithArg
std::enable_if_t< KernelLambdaHasKernelHandlerArgT< KernelType, ArgType >::value > runKernelWithArg(KernelType KernelName, ArgType Arg)
Definition: cg_types.hpp:210

sycl::_V1::detail::markBufferAsInternal
void markBufferAsInternal(const std::shared_ptr< buffer_impl > &BufImpl)
Definition: helpers.cpp:70

sycl::_V1::detail::runKernelWithoutArg
std::enable_if_t< KernelLambdaHasKernelHandlerArgT< KernelType >::value > runKernelWithoutArg(KernelType KernelName)
Definition: cg_types.hpp:196

sycl::_V1::detail::LocalAccessorImplPtr
std::shared_ptr< LocalAccessorImplHost > LocalAccessorImplPtr
Definition: accessor.hpp:601

sycl::_V1::detail::KernelBundleImplPtr
std::shared_ptr< detail::kernel_bundle_impl > KernelBundleImplPtr
Definition: kernel_bundle.hpp:152

sycl::_V1::detail::range_size_fits_in_size_t
bool range_size_fits_in_size_t(const range< Dims > &r)
Definition: handler.hpp:414

sycl::_V1::detail::associateWithHandler
void associateWithHandler(handler &, AccessorBaseHost *, access::target)
Definition: handler_proxy.cpp:17

sycl::_V1::detail::reduction_parallel_for
void reduction_parallel_for(handler &CGH, range< Dims > NDRange, PropertiesT Properties, RestT... Rest)
Definition: reduction.hpp:2711

sycl::_V1::detail::lambda_arg_type
decltype(argument_helper< F, SuggestedArgType >(0)) lambda_arg_type
Definition: handler.hpp:201

sycl::_V1::detail::AccessorImplPtr
std::shared_ptr< AccessorImplHost > AccessorImplPtr
Definition: accessor.hpp:532

sycl::_V1::ext::intel::experimental::large_slm
constexpr cache_config_enum large_slm
Definition: kernel_execution_properties.hpp:24

sycl::_V1::ext::intel::experimental::large_data
constexpr cache_config_enum large_data
Definition: kernel_execution_properties.hpp:26

sycl::_V1::ext::oneapi::experimental::detail::UnsupportedGraphFeatures
UnsupportedGraphFeatures
Definition: graph.hpp:48

sycl::_V1::ext::oneapi::experimental::detail::WorkGroupSize
@ WorkGroupSize
Definition: property.hpp:147

sycl::_V1::ext::oneapi::experimental::detail::UnsupportedFeatureToString
const char * UnsupportedFeatureToString(UnsupportedGraphFeatures Feature)
Definition: graph.hpp:60

sycl::_V1::ext::oneapi::experimental::detail::merged_properties_t
typename merged_properties< LHSPropertiesT, RHSPropertiesT >::type merged_properties_t
Definition: properties.hpp:225

sycl::_V1::ext::oneapi::experimental::detail::properties_t
properties< std::tuple< PropertyValueTs... > > properties_t
Definition: properties.hpp:212

sycl::_V1::ext::oneapi::experimental::graph_state::executable
@ executable
In executable state, the graph is ready to execute.

sycl::_V1::ext::oneapi::experimental::has_property
static constexpr bool has_property()
Definition: annotated_arg.hpp:190

sycl::_V1::ext::oneapi::experimental::get_property
static constexpr auto get_property()
Definition: annotated_arg.hpp:194

sycl::_V1::ext::oneapi::experimental::empty_properties_t
decltype(properties{}) empty_properties_t
Definition: properties.hpp:190

sycl::_V1::ext::oneapi::experimental::node_type
node_type
Definition: graph.hpp:91

sycl::_V1::ext::oneapi::experimental::node_type::memfill
@ memfill

sycl::_V1::y
auto auto y
Definition: common_functions.cpp:47

sycl::_V1::image_target
image_target
Definition: access.hpp:74

sycl::_V1::errc::runtime
@ runtime

sycl::_V1::errc::nd_range
@ nd_range

sycl::_V1::errc::kernel_argument
@ kernel_argument

sycl::_V1::errc::invalid
@ invalid

sycl::_V1::Dimensions
class __SYCL_EBO __SYCL_SPECIAL_CLASS __SYCL_TYPE(local_accessor) local_accessor class __SYCL_EBO __SYCL_SPECIAL_CLASS Dimensions
Definition: accessor.hpp:3233

sycl::_V1::__SYCL2020_DEPRECATED
signed char __SYCL2020_DEPRECATED
Definition: aliases.hpp:94

sycl::_V1::pipe
ext::intel::pipe< name, dataT, min_capacity > pipe
Definition: pipes.hpp:18

sycl::_V1::isPlaceholder
isPlaceholder
Definition: multi_ptr.hpp:505

sycl::_V1::image_channel_order::r
@ r

sycl::_V1::IsPlaceholder
class __SYCL_EBO __SYCL_SPECIAL_CLASS __SYCL_TYPE(local_accessor) local_accessor class __SYCL_EBO __SYCL_SPECIAL_CLASS IsPlaceholder
Definition: accessor.hpp:3234

sycl::_V1::max
max
Definition: integer_functions.cpp:212

sycl::_V1::AccessMode
class __SYCL_EBO __SYCL_SPECIAL_CLASS __SYCL_TYPE(local_accessor) local_accessor class __SYCL_EBO __SYCL_SPECIAL_CLASS AccessMode
Definition: accessor.hpp:3233

sycl::_V1::make_error_code
std::error_code make_error_code(sycl::errc E) noexcept
Constructs an error code using e and sycl_category()
Definition: exception.cpp:87

sycl::_V1::x
autodecltype(x) x
Definition: common_functions.cpp:33

sycl::_V1::value_type
const void value_type
Definition: multi_ptr.hpp:457

sycl
Definition: access.hpp:18

syclcompat::detail::fill
static sycl::event fill(sycl::queue q, void *dev_ptr, const T &pattern, size_t count)
Set pattern to the first count elements of type T starting from dev_ptr.
Definition: memory.hpp:185

nd_item.hpp

nd_range.hpp

properties.hpp

properties.hpp

properties.hpp

pi.h

_pi_kernel_cache_config
_pi_kernel_cache_config
Definition: pi.h:808

PI_EXT_KERNEL_EXEC_INFO_CACHE_LARGE_DATA
@ PI_EXT_KERNEL_EXEC_INFO_CACHE_LARGE_DATA
Definition: pi.h:814

PI_EXT_KERNEL_EXEC_INFO_CACHE_LARGE_SLM
@ PI_EXT_KERNEL_EXEC_INFO_CACHE_LARGE_SLM
Definition: pi.h:812

pi.hpp
C++ wrapper of extern "C" PI interfaces.

property_list.hpp

range.hpp

reduction_forward.hpp

root_group.hpp

sampler.hpp

string.hpp

string_view.hpp

sycl::_V1::detail::AreAllButLastReductions
Predicate returning true if all template type parameters except the last one are reductions.
Definition: reduction_forward.hpp:83

sycl::_V1::detail::CG::StorageInitHelper
Definition: cg.hpp:83

sycl::_V1::detail::CG::StorageInitHelper::MAccStorage
std::vector< detail::AccessorImplPtr > MAccStorage
Storage for accessors.
Definition: cg.hpp:101

sycl::_V1::detail::CG::StorageInitHelper::MRequirements
std::vector< AccessorImplHost * > MRequirements
List of requirements that specify which memory is needed for the command group to be executed.
Definition: cg.hpp:107

sycl::_V1::detail::GetMergedKernelProperties< KernelType, PropertiesT, std::enable_if_t< ext::oneapi::experimental::detail::HasKernelPropertiesGetMethod< KernelType >::value > >::type
ext::oneapi::experimental::detail::merged_properties_t< PropertiesT, get_method_properties > type
Definition: handler.hpp:255

sycl::_V1::detail::GetMergedKernelProperties< KernelType, PropertiesT, std::enable_if_t< ext::oneapi::experimental::detail::HasKernelPropertiesGetMethod< KernelType >::value > >::get_method_properties
typename ext::oneapi::experimental::detail::HasKernelPropertiesGetMethod< KernelType >::properties_t get_method_properties
Definition: handler.hpp:249

sycl::_V1::detail::GetMergedKernelProperties
Definition: handler.hpp:239

sycl::_V1::detail::GetMergedKernelProperties::type
PropertiesT type
Definition: handler.hpp:240

sycl::_V1::detail::KernelInfo
Definition: kernel_desc.hpp:78

sycl::_V1::detail::KernelInfo::getName
static constexpr const char * getName()
Definition: kernel_desc.hpp:84

sycl::_V1::detail::KernelLambdaHasKernelHandlerArgT
Definition: cg_types.hpp:187

sycl::_V1::detail::KernelLambdaHasKernelHandlerArgT::value
constexpr static bool value
Definition: cg_types.hpp:188

sycl::_V1::detail::check_fn_signature
Definition: cg_types.hpp:139

sycl::_V1::detail::code_location
Definition: common.hpp:66

sycl::_V1::detail::get_kernel_name_t::name
Name name
Definition: kernel.hpp:51

sycl::_V1::detail::get_kernel_wrapper_name_t
Definition: handler.hpp:206

sycl::_V1::detail::kernel_param_desc_t
Definition: kernel_desc.hpp:49

sycl::_V1::ext::intel::experimental::cache_config
Definition: kernel_execution_properties.hpp:30

sycl::_V1::ext::intel::experimental::fp_control_key
Definition: fp_control_kernel_properties.hpp:90

sycl::_V1::ext::oneapi::experimental::detail::HasKernelPropertiesGetMethod
Definition: properties.hpp:153

sycl::_V1::ext::oneapi::experimental::detail::PropertyMetaInfo::value
static constexpr std::nullptr_t value
Definition: property.hpp:257

sycl::_V1::ext::oneapi::experimental::detail::PropertyMetaInfo::name
static constexpr const char * name
Definition: property.hpp:256

sycl::_V1::ext::oneapi::experimental::device_image_scope_key
Definition: properties.hpp:25

sycl::_V1::ext::oneapi::experimental::image_descriptor
A struct to describe the properties of an image.
Definition: bindless_images_descriptor.hpp:33

sycl::_V1::ext::oneapi::experimental::image_mem_handle
Opaque image memory handle type.
Definition: bindless_images_memory.hpp:31

sycl::_V1::ext::oneapi::experimental::interop_semaphore_handle
Opaque interop semaphore handle type.
Definition: bindless_images_interop.hpp:26

sycl::_V1::ext::oneapi::experimental::is_property_list
Definition: properties.hpp:193

sycl::_V1::ext::oneapi::experimental::use_root_sync_key
Definition: root_group.hpp:31

sycl::_V1::handler::ShouldEnableSetArg
Definition: handler.hpp:1947

sycl::_V1::is_device_copyable
is_device_copyable is a user specializable class template to indicate that a type T is device copyabl...
Definition: types.hpp:2225

device.hpp

kernel.hpp