[SYCL] Initial implementation of GHistIndexMatrix (#10045)

Co-authored-by: Dmitry Razdoburdin <>
2024-02-18 21:27:15 +01:00 · 2024-02-18 21:27:15 +01:00 · 057f03cacc
commit 057f03cacc
parent 7cc256e246
6 changed files with 510 additions and 6 deletions
--- a/plugin/CMakeLists.txt
+++ b/plugin/CMakeLists.txt
@ -1,10 +1,7 @@
 if(PLUGIN_SYCL)
  set(CMAKE_CXX_COMPILER "icpx")
-  add_library(plugin_sycl OBJECT
+  file(GLOB_RECURSE SYCL_SOURCES "sycl/*.cc")
-    ${xgboost_SOURCE_DIR}/plugin/sycl/objective/regression_obj.cc
+  add_library(plugin_sycl OBJECT ${SYCL_SOURCES})
    ${xgboost_SOURCE_DIR}/plugin/sycl/objective/multiclass_obj.cc
    ${xgboost_SOURCE_DIR}/plugin/sycl/device_manager.cc
    ${xgboost_SOURCE_DIR}/plugin/sycl/predictor/predictor.cc)
  target_include_directories(plugin_sycl
    PRIVATE
    ${xgboost_SOURCE_DIR}/include
--- a/plugin/sycl/data.h
+++ b/plugin/sycl/data.h
@ -26,8 +26,13 @@
 namespace xgboost {
 namespace sycl {
-enum class MemoryType { shared, on_device};
+template <typename T>
 using AtomicRef = ::sycl::atomic_ref<T,
                                    ::sycl::memory_order::relaxed,
                                    ::sycl::memory_scope::device,
                                    ::sycl::access::address_space::ext_intel_global_device_space>;
 enum class MemoryType { shared, on_device};
 template <typename T>
 class USMDeleter {
--- a/plugin/sycl/data/gradient_index.cc
+++ b/plugin/sycl/data/gradient_index.cc
@ -0,0 +1,177 @@
 /*!
 * Copyright 2017-2024 by Contributors
 * \file gradient_index.cc
 */
 #include <vector>
 #include <limits>
 #include <algorithm>
 #include "gradient_index.h"
 #include <CL/sycl.hpp>
 namespace xgboost {
 namespace sycl {
 namespace common {
 uint32_t SearchBin(const bst_float* cut_values, const uint32_t* cut_ptrs, Entry const& e) {
  auto beg = cut_ptrs[e.index];
  auto end = cut_ptrs[e.index + 1];
  auto it = std::upper_bound(cut_values + beg, cut_values + end, e.fvalue);
  uint32_t idx = it - cut_values;
  if (idx == end) {
    idx -= 1;
  }
  return idx;
 }
 template <typename BinIdxType>
 void mergeSort(BinIdxType* begin, BinIdxType* end, BinIdxType* buf) {
  const size_t total_len = end - begin;
  for (size_t block_len = 1; block_len < total_len; block_len <<= 1) {
    for (size_t cur_block = 0; cur_block + block_len < total_len; cur_block += 2 * block_len) {
      size_t start = cur_block;
      size_t mid = start + block_len;
      size_t finish = mid + block_len < total_len ? mid + block_len : total_len;
      size_t left_pos = start;
      size_t right_pos = mid;
      size_t pos = start;
      while (left_pos < mid || right_pos < finish) {
        if (left_pos < mid && (right_pos == finish || begin[left_pos] < begin[right_pos])) {
          buf[pos++] = begin[left_pos++];
        } else {
          buf[pos++] = begin[right_pos++];
        }
      }
      for (size_t i = start; i < finish; i++) begin[i] = buf[i];
    }
  }
 }
 template <typename BinIdxType>
 void GHistIndexMatrix::SetIndexData(::sycl::queue qu,
                                    BinIdxType* index_data,
                                    const DeviceMatrix &dmat,
                                    size_t nbins,
                                    size_t row_stride,
                                    uint32_t* offsets) {
  if (nbins == 0) return;
  const xgboost::Entry *data_ptr = dmat.data.DataConst();
  const bst_row_t *offset_vec = dmat.row_ptr.DataConst();
  const size_t num_rows = dmat.row_ptr.Size() - 1;
  const bst_float* cut_values = cut_device.Values().DataConst();
  const uint32_t* cut_ptrs = cut_device.Ptrs().DataConst();
  size_t* hit_count_ptr = hit_count_buff.Data();
  // Sparse case only
  if (!offsets) {
    // sort_buff has type uint8_t
    sort_buff.Resize(&qu, num_rows * row_stride * sizeof(BinIdxType));
  }
  BinIdxType* sort_data = reinterpret_cast<BinIdxType*>(sort_buff.Data());
  auto event = qu.submit([&](::sycl::handler& cgh) {
    cgh.parallel_for<>(::sycl::range<1>(num_rows), [=](::sycl::item<1> pid) {
      const size_t i = pid.get_id(0);
      const size_t ibegin = offset_vec[i];
      const size_t iend = offset_vec[i + 1];
      const size_t size = iend - ibegin;
      const size_t start = i * row_stride;
      for (bst_uint j = 0; j < size; ++j) {
        uint32_t idx = SearchBin(cut_values, cut_ptrs, data_ptr[ibegin + j]);
        index_data[start + j] = offsets ? idx - offsets[j] : idx;
        AtomicRef<size_t> hit_count_ref(hit_count_ptr[idx]);
        hit_count_ref.fetch_add(1);
      }
      if (!offsets) {
        // Sparse case only
        mergeSort<BinIdxType>(index_data + start, index_data + start + size, sort_data + start);
        for (bst_uint j = size; j < row_stride; ++j) {
          index_data[start + j] = nbins;
        }
      }
    });
  });
  qu.memcpy(hit_count.data(), hit_count_ptr, nbins * sizeof(size_t), event);
  qu.wait();
 }
 void GHistIndexMatrix::ResizeIndex(size_t n_index, bool isDense) {
  if ((max_num_bins - 1 <= static_cast<int>(std::numeric_limits<uint8_t>::max())) && isDense) {
    index.SetBinTypeSize(BinTypeSize::kUint8BinsTypeSize);
    index.Resize((sizeof(uint8_t)) * n_index);
  } else if ((max_num_bins - 1 > static_cast<int>(std::numeric_limits<uint8_t>::max())  &&
    max_num_bins - 1 <= static_cast<int>(std::numeric_limits<uint16_t>::max())) && isDense) {
    index.SetBinTypeSize(BinTypeSize::kUint16BinsTypeSize);
    index.Resize((sizeof(uint16_t)) * n_index);
  } else {
    index.SetBinTypeSize(BinTypeSize::kUint32BinsTypeSize);
    index.Resize((sizeof(uint32_t)) * n_index);
  }
 }
 void GHistIndexMatrix::Init(::sycl::queue qu,
                            Context const * ctx,
                            const DeviceMatrix& p_fmat_device,
                            int max_bins) {
  nfeatures = p_fmat_device.p_mat->Info().num_col_;
  cut = xgboost::common::SketchOnDMatrix(ctx, p_fmat_device.p_mat, max_bins);
  cut_device.Init(qu, cut);
  max_num_bins = max_bins;
  const uint32_t nbins = cut.Ptrs().back();
  this->nbins = nbins;
  hit_count.resize(nbins, 0);
  hit_count_buff.Resize(&qu, nbins, 0);
  this->p_fmat = p_fmat_device.p_mat;
  const bool isDense = p_fmat_device.p_mat->IsDense();
  this->isDense_ = isDense;
  index.setQueue(qu);
  row_stride = 0;
  for (const auto& batch : p_fmat_device.p_mat->GetBatches<SparsePage>()) {
    const auto& row_offset = batch.offset.ConstHostVector();
    for (auto i = 1ull; i < row_offset.size(); i++) {
      row_stride = std::max(row_stride, static_cast<size_t>(row_offset[i] - row_offset[i - 1]));
    }
  }
  const size_t n_offsets = cut_device.Ptrs().Size() - 1;
  const size_t n_rows = p_fmat_device.row_ptr.Size() - 1;
  const size_t n_index = n_rows * row_stride;
  ResizeIndex(n_index, isDense);
  CHECK_GT(cut_device.Values().Size(), 0U);
  uint32_t* offsets = nullptr;
  if (isDense) {
    index.ResizeOffset(n_offsets);
    offsets = index.Offset();
    qu.memcpy(offsets, cut_device.Ptrs().DataConst(),
              sizeof(uint32_t) * n_offsets).wait_and_throw();
  }
  if (isDense) {
    BinTypeSize curent_bin_size = index.GetBinTypeSize();
    if (curent_bin_size == BinTypeSize::kUint8BinsTypeSize) {
      SetIndexData(qu, index.data<uint8_t>(), p_fmat_device, nbins, row_stride, offsets);
    } else if (curent_bin_size == BinTypeSize::kUint16BinsTypeSize) {
      SetIndexData(qu, index.data<uint16_t>(), p_fmat_device, nbins, row_stride, offsets);
    } else {
      CHECK_EQ(curent_bin_size, BinTypeSize::kUint32BinsTypeSize);
      SetIndexData(qu, index.data<uint32_t>(), p_fmat_device, nbins, row_stride, offsets);
    }
  /* For sparse DMatrix we have to store index of feature for each bin
     in index field to chose right offset. So offset is nullptr and index is not reduced */
  } else {
    SetIndexData(qu, index.data<uint32_t>(), p_fmat_device, nbins, row_stride, offsets);
  }
 }
 }  // namespace common
 }  // namespace sycl
 }  // namespace xgboost
--- a/plugin/sycl/data/gradient_index.h
+++ b/plugin/sycl/data/gradient_index.h
@ -0,0 +1,216 @@
 /*!
 * Copyright 2017-2024 by Contributors
 * \file gradient_index.h
 */
 #ifndef PLUGIN_SYCL_DATA_GRADIENT_INDEX_H_
 #define PLUGIN_SYCL_DATA_GRADIENT_INDEX_H_
 #include <vector>
 #include "../data.h"
 #include "../../src/common/hist_util.h"
 #include <CL/sycl.hpp>
 namespace xgboost {
 namespace sycl {
 namespace common {
 /*!
 * \brief SYCL implementation of HistogramCuts stored in USM buffers to provide access from device kernels
 */
 class HistogramCuts {
 protected:
  using BinIdx = uint32_t;
 public:
  HistogramCuts() {}
  explicit HistogramCuts(::sycl::queue qu) {}
  ~HistogramCuts() {
  }
  void Init(::sycl::queue qu, xgboost::common::HistogramCuts const& cuts) {
    qu_ = qu;
    cut_values_.Init(&qu_, cuts.cut_values_.HostVector());
    cut_ptrs_.Init(&qu_, cuts.cut_ptrs_.HostVector());
    min_vals_.Init(&qu_, cuts.min_vals_.HostVector());
  }
  // Getters for USM buffers to pass pointers into device kernels
  const USMVector<uint32_t>& Ptrs()      const { return cut_ptrs_;   }
  const USMVector<float>&    Values()    const { return cut_values_; }
  const USMVector<float>&    MinValues() const { return min_vals_;   }
 private:
  USMVector<bst_float> cut_values_;
  USMVector<uint32_t> cut_ptrs_;
  USMVector<float> min_vals_;
  ::sycl::queue qu_;
 };
 using BinTypeSize = ::xgboost::common::BinTypeSize;
 /*!
 * \brief Index data and offsets stored in USM buffers to provide access from device kernels
 */
 struct Index {
  Index() {
    SetBinTypeSize(binTypeSize_);
  }
  Index(const Index& i) = delete;
  Index& operator=(Index i) = delete;
  Index(Index&& i) = delete;
  Index& operator=(Index&& i) = delete;
  uint32_t operator[](size_t i) const {
    if (!offset_.Empty()) {
      return func_(data_.DataConst(), i) + offset_[i%p_];
    } else {
      return func_(data_.DataConst(), i);
    }
  }
  void SetBinTypeSize(BinTypeSize binTypeSize) {
    binTypeSize_ = binTypeSize;
    switch (binTypeSize) {
      case BinTypeSize::kUint8BinsTypeSize:
        func_ = &GetValueFromUint8;
        break;
      case BinTypeSize::kUint16BinsTypeSize:
        func_ = &GetValueFromUint16;
        break;
      case BinTypeSize::kUint32BinsTypeSize:
        func_ = &GetValueFromUint32;
        break;
      default:
        CHECK(binTypeSize == BinTypeSize::kUint8BinsTypeSize  ||
              binTypeSize == BinTypeSize::kUint16BinsTypeSize ||
              binTypeSize == BinTypeSize::kUint32BinsTypeSize);
    }
  }
  BinTypeSize GetBinTypeSize() const {
    return binTypeSize_;
  }
  template<typename T>
  T* data() {
    return reinterpret_cast<T*>(data_.Data());
  }
  template<typename T>
  const T* data() const {
    return reinterpret_cast<const T*>(data_.DataConst());
  }
  uint32_t* Offset() {
    return offset_.Data();
  }
  const uint32_t* Offset() const {
    return offset_.DataConst();
  }
  size_t Size() const {
    return data_.Size() / (binTypeSize_);
  }
  void Resize(const size_t nBytesData) {
    data_.Resize(&qu_, nBytesData);
  }
  void ResizeOffset(const size_t nDisps) {
    offset_.Resize(&qu_, nDisps);
    p_ = nDisps;
  }
  uint8_t* begin() const {
    return data_.Begin();
  }
  uint8_t* end() const {
    return data_.End();
  }
  void setQueue(::sycl::queue qu) {
    qu_ = qu;
  }
 private:
  static uint32_t GetValueFromUint8(const uint8_t* t, size_t i) {
    return reinterpret_cast<const uint8_t*>(t)[i];
  }
  static uint32_t GetValueFromUint16(const uint8_t* t, size_t i) {
    return reinterpret_cast<const uint16_t*>(t)[i];
  }
  static uint32_t GetValueFromUint32(const uint8_t* t, size_t i) {
    return reinterpret_cast<const uint32_t*>(t)[i];
  }
  using Func = uint32_t (*)(const uint8_t*, size_t);
  USMVector<uint8_t, MemoryType::on_device> data_;
  // size of this field is equal to number of features
  USMVector<uint32_t, MemoryType::on_device> offset_;
  BinTypeSize binTypeSize_ {BinTypeSize::kUint8BinsTypeSize};
  size_t p_ {1};
  Func func_;
  ::sycl::queue qu_;
 };
 /*!
 * \brief Preprocessed global index matrix, in CSR format, stored in USM buffers
 *
 *  Transform floating values to integer index in histogram
 */
 struct GHistIndexMatrix {
  /*! \brief row pointer to rows by element position */
  /*! \brief The index data */
  Index index;
  /*! \brief hit count of each index */
  std::vector<size_t> hit_count;
  /*! \brief buffers for calculations */
  USMVector<size_t, MemoryType::on_device> hit_count_buff;
  USMVector<uint8_t, MemoryType::on_device> sort_buff;
  /*! \brief The corresponding cuts */
  xgboost::common::HistogramCuts cut;
  HistogramCuts cut_device;
  DMatrix* p_fmat;
  size_t max_num_bins;
  size_t nbins;
  size_t nfeatures;
  size_t row_stride;
  // Create a global histogram matrix based on a given DMatrix device wrapper
  void Init(::sycl::queue qu, Context const * ctx,
            const sycl::DeviceMatrix& p_fmat_device, int max_num_bins);
  template <typename BinIdxType>
  void SetIndexData(::sycl::queue qu, BinIdxType* index_data,
                    const sycl::DeviceMatrix &dmat_device,
                    size_t nbins, size_t row_stride, uint32_t* offsets);
  void ResizeIndex(size_t n_index, bool isDense);
  inline void GetFeatureCounts(size_t* counts) const {
    auto nfeature = cut_device.Ptrs().Size() - 1;
    for (unsigned fid = 0; fid < nfeature; ++fid) {
      auto ibegin = cut_device.Ptrs()[fid];
      auto iend = cut_device.Ptrs()[fid + 1];
      for (auto i = ibegin; i < iend; ++i) {
        *(counts + fid) += hit_count[i];
      }
    }
  }
  inline bool IsDense() const {
    return isDense_;
  }
 private:
  bool isDense_;
 };
 }  // namespace common
 }  // namespace sycl
 }  // namespace xgboost
 #endif  // PLUGIN_SYCL_DATA_GRADIENT_INDEX_H_
--- a/tests/cpp/plugin/sycl_helpers.h
+++ b/tests/cpp/plugin/sycl_helpers.h
@ -0,0 +1,30 @@
 /*!
 * Copyright 2022-2024 XGBoost contributors
 */
 #pragma once
 #include "../helpers.h"
 namespace xgboost::sycl {
 template<typename T, typename Container>
 void VerifySyclVector(const USMVector<T, MemoryType::shared>& sycl_vector,
                      const Container& host_vector) {
  ASSERT_EQ(sycl_vector.Size(), host_vector.size());
  size_t size = sycl_vector.Size();
  for (size_t i = 0; i < size; ++i) {
    ASSERT_EQ(sycl_vector[i], host_vector[i]);
  }
 }
 template<typename T, typename Container>
 void VerifySyclVector(const std::vector<T>& sycl_vector, const Container& host_vector) {
  ASSERT_EQ(sycl_vector.size(), host_vector.size());
  size_t size = sycl_vector.size();
  for (size_t i = 0; i < size; ++i) {
    ASSERT_EQ(sycl_vector[i], host_vector[i]);
  }
 }
 }  // namespace xgboost::sycl
--- a/tests/cpp/plugin/test_sycl_gradient_index.cc
+++ b/tests/cpp/plugin/test_sycl_gradient_index.cc
@ -0,0 +1,79 @@
 /**
 * Copyright 2021-2024 by XGBoost contributors
 */
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Wtautological-constant-compare"
 #pragma GCC diagnostic ignored "-W#pragma-messages"
 #include "../../../src/data/gradient_index.h"       // for GHistIndexMatrix
 #pragma GCC diagnostic pop
 #include "../../../plugin/sycl/data/gradient_index.h"
 #include "../../../plugin/sycl/device_manager.h"
 #include "sycl_helpers.h"
 #include "../helpers.h"
 namespace xgboost::sycl::data {
 TEST(SyclGradientIndex, HistogramCuts) {
  size_t max_bins = 8;
  Context ctx;
  ctx.UpdateAllowUnknown(Args{{"device", "sycl"}});
  DeviceManager device_manager;
  auto qu = device_manager.GetQueue(ctx.Device());
  auto p_fmat = RandomDataGenerator{512, 16, 0.5}.GenerateDMatrix(true);
  xgboost::common::HistogramCuts cut = 
    xgboost::common::SketchOnDMatrix(&ctx, p_fmat.get(), max_bins);
  common::HistogramCuts cut_sycl;
  cut_sycl.Init(qu, cut);
  VerifySyclVector(cut_sycl.Ptrs(), cut.cut_ptrs_.HostVector());
  VerifySyclVector(cut_sycl.Values(), cut.cut_values_.HostVector());
  VerifySyclVector(cut_sycl.MinValues(), cut.min_vals_.HostVector());
 }
 TEST(SyclGradientIndex, Init) {
  size_t n_rows = 128;
  size_t n_columns = 7;
  Context ctx;
  ctx.UpdateAllowUnknown(Args{{"device", "sycl"}});
  DeviceManager device_manager;
  auto qu = device_manager.GetQueue(ctx.Device());
  auto p_fmat = RandomDataGenerator{n_rows, n_columns, 0.3}.GenerateDMatrix();
  sycl::DeviceMatrix dmat(qu, p_fmat.get());
  int max_bins = 256;
  common::GHistIndexMatrix gmat_sycl;
  gmat_sycl.Init(qu, &ctx, dmat, max_bins);
  xgboost::GHistIndexMatrix gmat{&ctx, p_fmat.get(), max_bins, 0.3, false};
  {
    ASSERT_EQ(gmat_sycl.max_num_bins, max_bins);
    ASSERT_EQ(gmat_sycl.nfeatures, n_columns);
  }
  {
    VerifySyclVector(gmat_sycl.hit_count, gmat.hit_count);
  }
  {
    std::vector<size_t> feature_count_sycl(n_columns, 0);
    gmat_sycl.GetFeatureCounts(feature_count_sycl.data());
    std::vector<size_t> feature_count(n_columns, 0);
    gmat.GetFeatureCounts(feature_count.data());
    VerifySyclVector(feature_count_sycl, feature_count);
  }
 }
 }  // namespace xgboost::sycl::data