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//
// MIT license
// Copyright (C) 2024 Intel Corporation
// SPDX-License-Identifier: MIT
//
//
// 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
//
#ifndef GGML_SYCL_COMMON_HPP
#define GGML_SYCL_COMMON_HPP
#include <fstream>
#include <iostream>
#include "dpct/helper.hpp"
#include "ggml-sycl.h"
#include "presets.hpp"
#if GGML_SYCL_DNNL
#include "dnnl.hpp"
#include "dnnl_sycl.hpp"
#endif
#define GGML_COMMON_DECL_SYCL
#define GGML_COMMON_IMPL_SYCL
/* suppress warning spam */
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wnested-anon-types"
#include "ggml-common.h"
#pragma clang diagnostic pop
void* ggml_sycl_host_malloc(size_t size);
void ggml_sycl_host_free(void* ptr);
static int g_ggml_sycl_debug = 0;
#define GGML_SYCL_DEBUG(...) \
 do { \
 if (g_ggml_sycl_debug) \
 fprintf(stderr, __VA_ARGS__); \
 } while (0)
#define CHECK_TRY_ERROR(expr) \
 [&]() { \
 try { \
 expr; \
 return dpct::success; \
 } catch (std::exception const& e) { \
 std::cerr << e.what() << "\nException caught at file:" << __FILE__ \
 << ", line:" << __LINE__ << ", func:" << __func__ \
 << std::endl; \
 return dpct::default_error; \
 } \
 }()
#define __SYCL_ARCH__ DPCT_COMPATIBILITY_TEMP
#define VER_4VEC 610 // todo for hardward optimize.
#define VER_GEN9 700 // todo for hardward optimize.
#define VER_GEN12 1000000 // todo for hardward optimize.
#define VER_GEN13 (VER_GEN12 + 1030) // todo for hardward optimize.
#define GGML_SYCL_MAX_NODES 8192 // TODO: adapt to hardwares
// define for XMX in Intel GPU
// TODO: currently, it's not used for XMX really.
#if !defined(GGML_SYCL_FORCE_MMQ)
 #define SYCL_USE_XMX
#endif
// max batch size to use MMQ kernels when tensor cores are available
#define MMQ_MAX_BATCH_SIZE 32
#if defined(_MSC_VER)
#pragma warning(disable : 4244 4267) // possible loss of data
#endif
// dmmv = dequantize_mul_mat_vec
#ifndef GGML_SYCL_DMMV_X
#define GGML_SYCL_DMMV_X 32
#endif
#ifndef GGML_SYCL_MMV_Y
#define GGML_SYCL_MMV_Y 1
#endif
typedef sycl::queue *queue_ptr;
enum ggml_sycl_backend_gpu_mode {
 SYCL_UNSET_GPU_MODE = -1,
 SYCL_SINGLE_GPU_MODE = 0,
 SYCL_MUL_GPU_MODE
};
static_assert(sizeof(sycl::half) == sizeof(ggml_fp16_t), "wrong fp16 size");
static void crash() {
 int* ptr = NULL;
 *ptr = 0;
}
[[noreturn]] static void ggml_sycl_error(
 const char* stmt,
 const char* func,
 const char* file,
 const int line,
 const char* msg) {
 fprintf(stderr, "SYCL error: %s: %s\n", stmt, msg);
 fprintf(stderr, " in function %s at %s:%d\n", func, file, line);
 GGML_ABORT("SYCL error");
}
#define SYCL_CHECK(err) \
 do { \
 auto err_ = (err); \
 if (err_ != 0) \
 ggml_sycl_error( \
 #err, \
 __func__, \
 __FILE__, \
 __LINE__, \
 "Meet error in this line code!"); \
 } while (0)
#if DPCT_COMPAT_RT_VERSION >= 11100
#define GGML_SYCL_ASSUME(x) __builtin_assume(x)
#else
#define GGML_SYCL_ASSUME(x)
#endif // DPCT_COMPAT_RT_VERSION >= 11100
#ifdef GGML_SYCL_F16
typedef sycl::half dfloat; // dequantize float
typedef sycl::half2 dfloat2;
#else
typedef float dfloat; // dequantize float
typedef sycl::float2 dfloat2;
#endif // GGML_SYCL_F16
#define MMVQ_MAX_BATCH_SIZE 8
static const int8_t kvalues_iq4nl[16]={-127, -104, -83, -65, -49, -35, -22, -10, 1, 13, 25, 38, 53, 69, 89, 113};
static int g_all_sycl_device_count = -1;
static bool g_ggml_backend_sycl_buffer_type_initialized = false;
static ggml_sycl_backend_gpu_mode g_ggml_sycl_backend_gpu_mode =
 SYCL_UNSET_GPU_MODE;
static void* g_scratch_buffer = nullptr;
static size_t g_scratch_size = 0; // disabled by default
static size_t g_scratch_offset = 0;
[[noreturn]] static inline void bad_arch(const sycl::stream& stream_ct1) {
 stream_ct1 << "ERROR: ggml-sycl was compiled without support for the "
 "current GPU architecture.\n";
 // __trap();
 std::exit(1);
(void)bad_arch; // suppress unused function warning
}
int get_current_device_id();
inline dpct::err0 ggml_sycl_set_device(const int device) try {
int current_device_id;
 SYCL_CHECK(CHECK_TRY_ERROR(current_device_id = get_current_device_id()));
// GGML_SYCL_DEBUG("ggml_sycl_set_device device_id=%d,
 // current_device_id=%d\n", device, current_device);
 if (device == current_device_id) {
 return 0;
 }
return CHECK_TRY_ERROR(dpct::select_device(device));
} catch (sycl::exception const& exc) {
 std::cerr << exc.what() << "Exception caught at file:" << __FILE__
 << ", line:" << __LINE__ << std::endl;
 crash();
 std::exit(1);
}
//////////////////////
struct ggml_sycl_device_info {
 int device_count;
struct sycl_device_info {
 int cc; // compute capability
 // int nsm; // number of streaming multiprocessors
 // size_t smpb; // max. shared memory per block
 bool vmm; // virtual memory support
 size_t total_vram;
 };
sycl_device_info devices[GGML_SYCL_MAX_DEVICES] = {};
std::array<float, GGML_SYCL_MAX_DEVICES> default_tensor_split = {};
int max_work_group_sizes[GGML_SYCL_MAX_DEVICES] = {0};
};
const ggml_sycl_device_info & ggml_sycl_info();
struct ggml_sycl_pool {
 virtual ~ggml_sycl_pool() = default;
virtual void * alloc(size_t size, size_t * actual_size) = 0;
 virtual void free(void * ptr, size_t size) = 0;
};
template<typename T>
struct ggml_sycl_pool_alloc {
 ggml_sycl_pool * pool = nullptr;
 T * ptr = nullptr;
 size_t actual_size = 0;
explicit ggml_sycl_pool_alloc(ggml_sycl_pool & pool) : pool(&pool) {
 }
ggml_sycl_pool_alloc(ggml_sycl_pool & pool, size_t size) : pool(&pool) {
 alloc(size);
 }
~ggml_sycl_pool_alloc() {
 if (ptr != nullptr) {
 pool->free(ptr, actual_size);
 }
 }
// size is in number of elements
 T * alloc(size_t size) {
 GGML_ASSERT(pool != nullptr);
 GGML_ASSERT(ptr == nullptr);
 ptr = (T *) pool->alloc(size * sizeof(T), &this->actual_size);
 return ptr;
 }
T * alloc(ggml_sycl_pool & pool, size_t size) {
 this->pool = &pool;
 return alloc(size);
 }
T * get() {
 return ptr;
 }
ggml_sycl_pool_alloc() = default;
 ggml_sycl_pool_alloc(const ggml_sycl_pool_alloc &) = delete;
 ggml_sycl_pool_alloc(ggml_sycl_pool_alloc &&) = delete;
 ggml_sycl_pool_alloc& operator=(const ggml_sycl_pool_alloc &) = delete;
 ggml_sycl_pool_alloc& operator=(ggml_sycl_pool_alloc &&) = delete;
};
// backend interface
struct ggml_tensor_extra_gpu {
 void* data_device[GGML_SYCL_MAX_DEVICES]; // 1 pointer for each device for split
 // tensors
 dpct::event_ptr events[GGML_SYCL_MAX_DEVICES]
 [GGML_SYCL_MAX_STREAMS]; // events for synchronizing multiple GPUs
};
struct ggml_backend_sycl_context {
 int device;
 std::string name;
queue_ptr qptrs[GGML_SYCL_MAX_DEVICES][GGML_SYCL_MAX_STREAMS] = { { nullptr } };
explicit ggml_backend_sycl_context(int device) :
 device(device),
 name(GGML_SYCL_NAME + std::to_string(device)) {
 }
queue_ptr stream(int device, int stream) {
 if (qptrs[device][stream] == nullptr) {
 qptrs[device][stream] = &(dpct::get_device(device).default_queue());
 }
 return qptrs[device][stream];
 }
queue_ptr stream() {
 return stream(device, 0);
 }
#if GGML_SYCL_DNNL
 dnnl::engine make_engine(sycl::queue* q) {
 // Get the device associated with the queue
 sycl::device dev = q->get_device();
 // Get the context associated with the queue
 sycl::context ctx = q->get_context();
 const dnnl::engine eng = dnnl::sycl_interop::make_engine(dev, ctx);
 return eng;
 }
std::unordered_map<sycl::queue*, dnnl::stream> stream_map;
 std::unordered_map<sycl::queue*, dnnl::engine> engine_map;
 dnnl::stream stream_dnnl(int device, int _stream) {
 auto q = stream(device, _stream);
 return stream_dnnl(q);
 }
 dnnl::engine engine_dnnl(sycl::queue* qptr) {
 auto it = engine_map.find(qptr);
 if (it == engine_map.end()) {
 auto eng = make_engine(qptr);
 engine_map[qptr] = eng;
 return eng;
 }
 else
 {
 return it->second;
 }
 }
 dnnl::stream stream_dnnl(sycl::queue* qptr) {
 auto it = stream_map.find(qptr);
 if (it == stream_map.end()) {
 auto eng = engine_dnnl(qptr);
 auto stream = dnnl::sycl_interop::make_stream(eng, *qptr);
 stream_map[qptr] = stream;
 return stream;
 }
 else
 {
 return it->second;
 }
 }
 dnnl::stream stream_dnnl() {
 return stream_dnnl(device, 0);
 }
#endif
// pool
 std::unique_ptr<ggml_sycl_pool> pools[GGML_SYCL_MAX_DEVICES];
std::unique_ptr<ggml_sycl_pool> host_pools[GGML_SYCL_MAX_DEVICES];
static std::unique_ptr<ggml_sycl_pool> new_pool_for_device(queue_ptr qptr, int device);
static std::unique_ptr<ggml_sycl_pool> new_pool_for_host(queue_ptr qptr, int device);
ggml_sycl_pool & pool(int device) {
 if (pools[device] == nullptr) {
 pools[device] = new_pool_for_device(stream(device,0), device);
 }
 return *pools[device];
 }
ggml_sycl_pool & pool() {
 return pool(device);
 }
ggml_sycl_pool & host_pool(int device) {
 if (host_pools[device] == nullptr) {
 host_pools[device] = new_pool_for_host(stream(device, 0), device);
 }
 return *host_pools[device];
 }
ggml_sycl_pool & host_pool() { return host_pool(device); }
};
// common device functions
static __dpct_inline__ float warp_reduce_sum(float x,
 const sycl::nd_item<3>& item_ct1) {
#pragma unroll
 for (int mask = WARP_SIZE / 2; mask > 0; mask >>= 1) {
 /*
 DPCT1096:98: The right-most dimension of the work-group used in the SYCL
 kernel that calls this function may be less than "32". The function
 "dpct::permute_sub_group_by_xor" may return an unexpected result on the
 CPU device. Modify the size of the work-group to ensure that the value
 of the right-most dimension is a multiple of "32".
 */
 x += dpct::permute_sub_group_by_xor(item_ct1.get_sub_group(), x, mask);
 }
 return x;
}
static __dpct_inline__ sycl::float2
warp_reduce_sum(sycl::float2 a, const sycl::nd_item<3>& item_ct1) {
#pragma unroll
 for (int mask = WARP_SIZE / 2; mask > 0; mask >>= 1) {
 a.x() += dpct::permute_sub_group_by_xor(item_ct1.get_sub_group(), a.x(),
 mask);
 a.y() += dpct::permute_sub_group_by_xor(item_ct1.get_sub_group(), a.y(),
 mask);
 }
 return a;
}
static __dpct_inline__ float warp_reduce_max(float x,
 const sycl::nd_item<3>& item_ct1) {
#pragma unroll
 for (int mask = WARP_SIZE / 2; mask > 0; mask >>= 1) {
 /*
 DPCT1096:97: The right-most dimension of the work-group used in the SYCL
 kernel that calls this function may be less than "32". The function
 "dpct::permute_sub_group_by_xor" may return an unexpected result on the
 CPU device. Modify the size of the work-group to ensure that the value
 of the right-most dimension is a multiple of "32".
 */
 x = sycl::fmax(x, dpct::permute_sub_group_by_xor(
 item_ct1.get_sub_group(), x, mask));
 }
 return x;
}
// Helper for vec loading aligned data
template <typename Tp, int n>
inline sycl::vec<Tp, n> vec_aligned_load(const Tp* aligned_ptr) {
 return *reinterpret_cast<const sycl::vec<Tp, n>*>(aligned_ptr);
}
// Helper for accessing pointers with no warnings
template <typename Tp, int dim>
static __dpct_inline__ Tp* get_pointer(sycl::local_accessor<Tp, dim> acc) {
 return acc.template get_multi_ptr<sycl::access::decorated::no>().get();
}
int64_t downsample_sycl_global_range(int64_t accumulate_block_num, int64_t block_size);
typedef void (*ggml_sycl_op_flatten_t)(ggml_backend_sycl_context & ctx, const ggml_tensor *src0,
 const ggml_tensor *src1,
 ggml_tensor *dst, const float *src0_dd,
 const float *src1_dd, float *dst_dd,
 const queue_ptr &main_stream);
template<float (*bin_op)(const float, const float), typename src0_t, typename src1_t, typename dst_t>
static void k_bin_bcast(const src0_t * src0, const src1_t * src1, dst_t * dst,
 int ne0, int ne1, int ne2, int ne3,
 int ne10, int ne11, int ne12, int ne13,
 /*int s0, */ int s1, int s2, int s3,
 /*int s10,*/ int s11, int s12, int s13,
 const sycl::nd_item<3> &item_ct1) {
 const int i0s = item_ct1.get_local_range(2) * item_ct1.get_group(2) +
 item_ct1.get_local_id(2);
 const int i1 = (item_ct1.get_local_range(1) * item_ct1.get_group(1) +
 item_ct1.get_local_id(1));
 const int i2 = (item_ct1.get_local_range(0) * item_ct1.get_group(0) +
 item_ct1.get_local_id(0)) /
 ne3;
 const int i3 = (item_ct1.get_local_range(0) * item_ct1.get_group(0) +
 item_ct1.get_local_id(0)) %
 ne3;
if (i0s >= ne0 || i1 >= ne1 || i2 >= ne2 || i3 >= ne3) {
 return;
 }
const int i11 = i1 % ne11;
 const int i12 = i2 % ne12;
 const int i13 = i3 % ne13;
const size_t i_src0 = i3*s3 + i2*s2 + i1*s1;
 const size_t i_src1 = i13*s13 + i12*s12 + i11*s11;
 const size_t i_dst = i_src0;
const src0_t * src0_row = src0 + i_src0;
 const src1_t * src1_row = src1 + i_src1;
 dst_t * dst_row = dst + i_dst;
for (int i0 = i0s; i0 < ne0;
 i0 += item_ct1.get_local_range(2) * item_ct1.get_group_range(2)) {
 const int i10 = i0 % ne10;
 dst_row[i0] = (dst_t)bin_op(src0 ? (float)src0_row[i0] : 0.0f, (float)src1_row[i10]);
 }
}
template<float (*bin_op)(const float, const float), typename src0_t, typename src1_t, typename dst_t>
static void k_bin_bcast_unravel(const src0_t * src0, const src1_t * src1, dst_t * dst,
 int ne0, int ne1, int ne2, int ne3,
 int ne10, int ne11, int ne12, int ne13,
 /*int s0, */ int s1, int s2, int s3,
 /*int s10,*/ int s11, int s12, int s13,
 const sycl::nd_item<3> &item_ct1) {
const int i = item_ct1.get_local_range(2) * item_ct1.get_group(2) +
 item_ct1.get_local_id(2);
const int i3 = i/(ne2*ne1*ne0);
 const int i2 = (i/(ne1*ne0)) % ne2;
 const int i1 = (i/ne0) % ne1;
 const int i0 = i % ne0;
if (i0 >= ne0 || i1 >= ne1 || i2 >= ne2 || i3 >= ne3) {
 return;
 }
const int i11 = i1 % ne11;
 const int i12 = i2 % ne12;
 const int i13 = i3 % ne13;
const size_t i_src0 = i3*s3 + i2*s2 + i1*s1;
 const size_t i_src1 = i13*s13 + i12*s12 + i11*s11;
 const size_t i_dst = i_src0;
const src0_t * src0_row = src0 + i_src0;
 const src1_t * src1_row = src1 + i_src1;
 dst_t * dst_row = dst + i_dst;
const int i10 = i0 % ne10;
 dst_row[i0] = (dst_t)bin_op(src0 ? (float)src0_row[i0] : 0.0f, (float)src1_row[i10]);
}
template<float (*bin_op)(const float, const float)>
struct bin_bcast_sycl {
 template <typename src0_t, typename src1_t, typename dst_t>
 void operator()(ggml_backend_sycl_context & ctx,
 const struct ggml_tensor *src0,
 const struct ggml_tensor *src1, struct ggml_tensor *dst,
 const src0_t *src0_dd, const src1_t *src1_dd, dst_t *dst_dd,
 queue_ptr stream) {
GGML_TENSOR_BINARY_OP_LOCALS
int nr0 = ne10/ne0;
 int nr1 = ne11/ne1;
 int nr2 = ne12/ne2;
 int nr3 = ne13/ne3;
int nr[4] = { nr0, nr1, nr2, nr3 };
// collapse dimensions until first broadcast dimension
 int64_t cne0[] = {ne0, ne1, ne2, ne3};
 int64_t cne1[] = {ne10, ne11, ne12, ne13};
 size_t cnb0[] = {nb0, nb1, nb2, nb3};
 size_t cnb1[] = {nb10, nb11, nb12, nb13};
 auto collapse = [](int64_t cne[]) {
 cne[0] *= cne[1];
 cne[1] = cne[2];
 cne[2] = cne[3];
 cne[3] = 1;
 };
auto collapse_nb = [](size_t cnb[], int64_t cne[]) {
 cnb[1] *= cne[1];
 cnb[2] *= cne[2];
 cnb[3] *= cne[3];
 };
for (int i = 0; i < 4; i++) {
 if (nr[i] != 1) {
 break;
 }
 if (i > 0) {
 collapse_nb(cnb0, cne0);
 collapse_nb(cnb1, cne1);
 collapse(cne0);
 collapse(cne1);
 }
 }
 {
 int64_t ne0 = cne0[0];
 int64_t ne1 = cne0[1];
 int64_t ne2 = cne0[2];
 int64_t ne3 = cne0[3];
int64_t ne10 = cne1[0];
 int64_t ne11 = cne1[1];
 int64_t ne12 = cne1[2];
 int64_t ne13 = cne1[3];
size_t nb0 = cnb0[0];
 size_t nb1 = cnb0[1];
 size_t nb2 = cnb0[2];
 size_t nb3 = cnb0[3];
size_t nb10 = cnb1[0];
 size_t nb11 = cnb1[1];
 size_t nb12 = cnb1[2];
 size_t nb13 = cnb1[3];
size_t s0 = nb0 / sizeof(dst_t);
 size_t s1 = nb1 / sizeof(dst_t);
 size_t s2 = nb2 / sizeof(dst_t);
 size_t s3 = nb3 / sizeof(dst_t);
size_t s10 = nb10 / sizeof(src1_t);
 size_t s11 = nb11 / sizeof(src1_t);
 size_t s12 = nb12 / sizeof(src1_t);
 size_t s13 = nb13 / sizeof(src1_t);
GGML_ASSERT(s0 == 1);
 GGML_ASSERT(s10 == 1);
const int block_size = 128;
int64_t hne0 = std::max(ne0/2LL, 1LL);
sycl::range<3> block_dims(1, 1, 1);
 block_dims[2] = std::min<unsigned int>(hne0, block_size);
 block_dims[1] = std::min<unsigned int>(
 ne1, block_size / (unsigned int)block_dims[2]);
 block_dims[0] = std::min(
 std::min<unsigned int>(
 ne2 * ne3, block_size / (unsigned int)block_dims[2] /
 (unsigned int)block_dims[1]),
 64U);
sycl::range<3> block_nums(
 (ne2 * ne3 + block_dims[0] - 1) / block_dims[0],
 (ne1 + block_dims[1] - 1) / block_dims[1],
 (hne0 + block_dims[2] - 1) / block_dims[2]);
if (block_nums[0] > 65535) {
 // this is the maximum number of blocks in z direction, fallback to 1D grid kernel
 int block_num = (ne0*ne1*ne2*ne3 + block_size - 1) / block_size;
 {
 dpct::has_capability_or_fail(stream->get_device(),
 {sycl::aspect::fp16});
stream->parallel_for(
 sycl::nd_range<3>(sycl::range<3>(1, 1, block_num) *
 sycl::range<3>(1, 1, block_size),
 sycl::range<3>(1, 1, block_size)),
 [=](sycl::nd_item<3> item_ct1) {
 k_bin_bcast_unravel<bin_op>(
 src0_dd, src1_dd, dst_dd, ne0, ne1, ne2, ne3,
 ne10, ne11, ne12, ne13, s1, s2, s3, s11, s12,
 s13, item_ct1);
 });
 }
 } else {
 /*
 DPCT1049:16: The work-group size passed to the SYCL kernel may
 exceed the limit. To get the device limit, query
 info::device::max_work_group_size. Adjust the work-group size if
 needed.
 */
 dpct::has_capability_or_fail(stream->get_device(),
 {sycl::aspect::fp16});
stream->parallel_for(
 sycl::nd_range<3>(block_nums * block_dims, block_dims),
 [=](sycl::nd_item<3> item_ct1) {
 k_bin_bcast<bin_op>(src0_dd, src1_dd, dst_dd, ne0, ne1,
 ne2, ne3, ne10, ne11, ne12, ne13,
 s1, s2, s3, s11, s12, s13,
 item_ct1);
 });
 }
 }
 GGML_UNUSED(ctx);
 }
};
template <class op>
inline void ggml_sycl_op_bin_bcast(ggml_backend_sycl_context & ctx, const ggml_tensor *src0,
 const ggml_tensor *src1, ggml_tensor *dst,
 const float *src0_dd, const float *src1_dd,
 float *dst_dd,
 const queue_ptr &main_stream) {
if (src0->type == GGML_TYPE_F32 && dst->type == GGML_TYPE_F32) {
 op()(ctx, src0, src1, dst, src0_dd, src1_dd, dst_dd, main_stream);
 } else if (src0->type == GGML_TYPE_F16 && dst->type == GGML_TYPE_F16) {
 op()(ctx, src0, src1, dst, (const sycl::half *)src0_dd, src1_dd,
 (sycl::half *)dst_dd, main_stream);
 } else if (src0->type == GGML_TYPE_F16 && dst->type == GGML_TYPE_F32) {
 op()(ctx, src0, src1, dst, (const sycl::half *)src0_dd, src1_dd, dst_dd,
 main_stream);
 } else if (src0->type == GGML_TYPE_I32 && dst->type == GGML_TYPE_I32) {
 op()(ctx, src0, src1, dst, (const int32_t *)src0_dd, (const int32_t *)src1_dd, (int32_t *)dst_dd,
 main_stream);
 } else if (src0->type == GGML_TYPE_I16 && dst->type == GGML_TYPE_I16) {
 op()(ctx, src0, src1, dst, (const int16_t *)src0_dd, (const int16_t *)src1_dd, (int16_t *)dst_dd,
 main_stream);
 } else {
 fprintf(stderr, "%s: unsupported types: dst: %s, src0: %s, src1: %s\n", __func__,
 ggml_type_name(dst->type), ggml_type_name(src0->type), ggml_type_name(src1->type));
 GGML_ABORT("fatal error");
 }
}
bool gpu_has_xmx(sycl::device &dev);
void ggml_sycl_op_flatten(ggml_backend_sycl_context & ctx, const ggml_tensor *src0,
 const ggml_tensor *src1, ggml_tensor *dst,
 const ggml_sycl_op_flatten_t op);
#endif // GGML_SYCL_COMMON_HPP