dense_nbits_bin.hpp

#ifndef LIGHTGBM_IO_DENSE_NBITS_BIN_HPP_
#define LIGHTGBM_IO_DENSE_NBITS_BIN_HPP_

#include <LightGBM/bin.h>

#include <vector>
#include <cstring>
#include <cstdint>

namespace LightGBM {

class Dense4bitsBin;

class Dense4bitsBinIterator: public BinIterator {
public:
  explicit Dense4bitsBinIterator(const Dense4bitsBin* bin_data, uint32_t min_bin, uint32_t max_bin, uint32_t default_bin)
    : bin_data_(bin_data), min_bin_(static_cast<uint8_t>(min_bin)),
    max_bin_(static_cast<uint8_t>(max_bin)),
    default_bin_(static_cast<uint8_t>(default_bin)) {
    if (default_bin_ == 0) {
      bias_ = 1;
    } else {
      bias_ = 0;
    }
  }
  inline uint32_t Get(data_size_t idx) override;
  inline void Reset(data_size_t) override { }
private:
  const Dense4bitsBin* bin_data_;
  uint8_t min_bin_;
  uint8_t max_bin_;
  uint8_t default_bin_;
  uint8_t bias_;
};

class Dense4bitsBin: public Bin {
public:
  friend Dense4bitsBinIterator;
  Dense4bitsBin(data_size_t num_data)
    : num_data_(num_data) {
    int len = (num_data_ + 1) / 2;
    data_ = std::vector<uint8_t>(len, static_cast<uint8_t>(0));
  }

  ~Dense4bitsBin() {

  }

  void Push(int, data_size_t idx, uint32_t value) override {
    if (buf_.empty()) {
#pragma omp critical
      {
        if (buf_.empty()) {
          int len = (num_data_ + 1) / 2;
          buf_ = std::vector<uint8_t>(len, static_cast<uint8_t>(0));
        }
      }
    }
    const int i1 = idx >> 1;
    const int i2 = (idx & 1) << 2;
    const uint8_t val = static_cast<uint8_t>(value) << i2;
    if (i2 == 0) {
      data_[i1] = val;
    } else {
      buf_[i1] = val;
    }
  }

  void ReSize(data_size_t num_data) override {
    if (num_data_ != num_data) {
      num_data_ = num_data;
      int len = (num_data_ + 1) / 2;
      data_.resize(len);
    }
  }

  BinIterator* GetIterator(uint32_t min_bin, uint32_t max_bin, uint32_t default_bin) const override;

  void ConstructHistogram(const data_size_t* data_indices, data_size_t num_data,
                          const score_t* ordered_gradients, const score_t* ordered_hessians,
                          HistogramBinEntry* out) const override {
    if (data_indices != nullptr) {  // if use part of data

      const data_size_t rest = num_data & 0x3;
      data_size_t i = 0;
      for (; i < num_data - rest; i += 4) {

        data_size_t idx = data_indices[i];
        const auto bin0 = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;

        idx = data_indices[i + 1];
        const auto bin1 = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;

        idx = data_indices[i + 2];
        const auto bin2 = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;

        idx = data_indices[i + 3];
        const auto bin3 = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;


        out[bin0].sum_gradients += ordered_gradients[i];
        out[bin1].sum_gradients += ordered_gradients[i + 1];
        out[bin2].sum_gradients += ordered_gradients[i + 2];
        out[bin3].sum_gradients += ordered_gradients[i + 3];

        out[bin0].sum_hessians += ordered_hessians[i];
        out[bin1].sum_hessians += ordered_hessians[i + 1];
        out[bin2].sum_hessians += ordered_hessians[i + 2];
        out[bin3].sum_hessians += ordered_hessians[i + 3];

        ++out[bin0].cnt;
        ++out[bin1].cnt;
        ++out[bin2].cnt;
        ++out[bin3].cnt;

      }

      for (; i < num_data; ++i) {
        const data_size_t idx = data_indices[i];
        const auto bin = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;
        out[bin].sum_gradients += ordered_gradients[i];
        out[bin].sum_hessians += ordered_hessians[i];
        ++out[bin].cnt;
      }

    } else {  // use full data
      const data_size_t rest = num_data & 0x3;
      data_size_t i = 0;
      for (; i < num_data - rest; i += 4) {
        int j = i >> 1;
        const auto bin0 = (data_[j]) & 0xf;
        const auto bin1 = (data_[j] >> 4) & 0xf;
        ++j;
        const auto bin2 = (data_[j]) & 0xf;
        const auto bin3 = (data_[j] >> 4) & 0xf;

        out[bin0].sum_gradients += ordered_gradients[i];
        out[bin1].sum_gradients += ordered_gradients[i + 1];
        out[bin2].sum_gradients += ordered_gradients[i + 2];
        out[bin3].sum_gradients += ordered_gradients[i + 3];

        out[bin0].sum_hessians += ordered_hessians[i];
        out[bin1].sum_hessians += ordered_hessians[i + 1];
        out[bin2].sum_hessians += ordered_hessians[i + 2];
        out[bin3].sum_hessians += ordered_hessians[i + 3];

        ++out[bin0].cnt;
        ++out[bin1].cnt;
        ++out[bin2].cnt;
        ++out[bin3].cnt;
      }
      for (; i < num_data; ++i) {
        const auto bin = (data_[i >> 1] >> ((i & 1) << 2)) & 0xf;
        out[bin].sum_gradients += ordered_gradients[i];
        out[bin].sum_hessians += ordered_hessians[i];
        ++out[bin].cnt;
      }
    }
  }

  void ConstructHistogram(const data_size_t* data_indices, data_size_t num_data,
                          const score_t* ordered_gradients,
                          HistogramBinEntry* out) const override {
    if (data_indices != nullptr) {  // if use part of data

      const data_size_t rest = num_data & 0x3;
      data_size_t i = 0;
      for (; i < num_data - rest; i += 4) {

        data_size_t idx = data_indices[i];
        const auto bin0 = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;

        idx = data_indices[i + 1];
        const auto bin1 = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;

        idx = data_indices[i + 2];
        const auto bin2 = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;

        idx = data_indices[i + 3];
        const auto bin3 = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;


        out[bin0].sum_gradients += ordered_gradients[i];
        out[bin1].sum_gradients += ordered_gradients[i + 1];
        out[bin2].sum_gradients += ordered_gradients[i + 2];
        out[bin3].sum_gradients += ordered_gradients[i + 3];

        ++out[bin0].cnt;
        ++out[bin1].cnt;
        ++out[bin2].cnt;
        ++out[bin3].cnt;

      }

      for (; i < num_data; ++i) {
        const data_size_t idx = data_indices[i];
        const auto bin = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;
        out[bin].sum_gradients += ordered_gradients[i];
        ++out[bin].cnt;
      }

    } else {  // use full data
      const data_size_t rest = num_data & 0x3;
      data_size_t i = 0;
      for (; i < num_data - rest; i += 4) {
        int j = i >> 1;
        const auto bin0 = (data_[j]) & 0xf;
        const auto bin1 = (data_[j] >> 4) & 0xf;
        ++j;
        const auto bin2 = (data_[j]) & 0xf;
        const auto bin3 = (data_[j] >> 4) & 0xf;

        out[bin0].sum_gradients += ordered_gradients[i];
        out[bin1].sum_gradients += ordered_gradients[i + 1];
        out[bin2].sum_gradients += ordered_gradients[i + 2];
        out[bin3].sum_gradients += ordered_gradients[i + 3];

        ++out[bin0].cnt;
        ++out[bin1].cnt;
        ++out[bin2].cnt;
        ++out[bin3].cnt;
      }
      for (; i < num_data; ++i) {
        const auto bin = (data_[i >> 1] >> ((i & 1) << 2)) & 0xf;
        out[bin].sum_gradients += ordered_gradients[i];
        ++out[bin].cnt;
      }
    }
  }

  virtual data_size_t Split(
    uint32_t min_bin, uint32_t max_bin, uint32_t default_bin,
    uint32_t threshold, data_size_t* data_indices, data_size_t num_data,
    data_size_t* lte_indices, data_size_t* gt_indices, BinType bin_type) const override {
    if (num_data <= 0) { return 0; }
    uint8_t th = static_cast<uint8_t>(threshold + min_bin);
    uint8_t minb = static_cast<uint8_t>(min_bin);
    uint8_t maxb = static_cast<uint8_t>(max_bin);
    if (default_bin == 0) {
      th -= 1;
    }
    data_size_t lte_count = 0;
    data_size_t gt_count = 0;
    data_size_t* default_indices = gt_indices;
    data_size_t* default_count = &gt_count;
    if (bin_type == BinType::NumericalBin) {
      if (default_bin <= threshold) {
        default_indices = lte_indices;
        default_count = &lte_count;
      }
      for (data_size_t i = 0; i < num_data; ++i) {
        const data_size_t idx = data_indices[i];
        const auto bin = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;
        if (bin > maxb || bin < minb) {
          default_indices[(*default_count)++] = idx;
        } else if (bin > th) {
          gt_indices[gt_count++] = idx;
        } else {
          lte_indices[lte_count++] = idx;
        }
      }
    } else {
      if (default_bin == threshold) {
        default_indices = lte_indices;
        default_count = &lte_count;
      }
      for (data_size_t i = 0; i < num_data; ++i) {
        const data_size_t idx = data_indices[i];
        const auto bin = (data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;
        if (bin > maxb || bin < minb) {
          default_indices[(*default_count)++] = idx;
        } else if (bin != th) {
          gt_indices[gt_count++] = idx;
        } else {
          lte_indices[lte_count++] = idx;
        }
      }
    }
    return lte_count;
  }
  data_size_t num_data() const override { return num_data_; }

  /*! \brief not ordered bin for dense feature */
  OrderedBin* CreateOrderedBin() const override { return nullptr; }

  void FinishLoad() override {
    if (buf_.empty()) { return; }
    int len = (num_data_ + 1) / 2;
    for (int i = 0; i < len; ++i) {
      data_[i] |= buf_[i];
    }
    buf_.clear();
  }

  void LoadFromMemory(const void* memory, const std::vector<data_size_t>& local_used_indices) override {
    const uint8_t* mem_data = reinterpret_cast<const uint8_t*>(memory);
    if (!local_used_indices.empty()) {
      const data_size_t rest = num_data_ & 1;
      for (int i = 0; i < num_data_ - rest; i += 2) {
        // get old bins
        data_size_t idx = local_used_indices[i];
        const auto bin1 = static_cast<uint8_t>((mem_data[idx >> 1] >> ((idx & 1) << 2)) & 0xf);
        idx = local_used_indices[i + 1];
        const auto bin2 = static_cast<uint8_t>((mem_data[idx >> 1] >> ((idx & 1) << 2)) & 0xf);
        // add
        const int i1 = i >> 1;
        data_[i1] = (bin1 | (bin2 << 4));
      }
      if (rest) {
        data_size_t idx = local_used_indices[num_data_ - 1];
        data_[num_data_ >> 1] = (mem_data[idx >> 1] >> ((idx & 1) << 2)) & 0xf;
      }
    } else {
      for (size_t i = 0; i < data_.size(); ++i) {
        data_[i] = mem_data[i];
      }
    }
  }

  void CopySubset(const Bin* full_bin, const data_size_t* used_indices, data_size_t num_used_indices) override {
    auto other_bin = reinterpret_cast<const Dense4bitsBin*>(full_bin);
    const data_size_t rest = num_used_indices & 1;
    for (int i = 0; i < num_used_indices - rest; i += 2) {
      data_size_t idx = used_indices[i];
      const auto bin1 = static_cast<uint8_t>((other_bin->data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf);
      idx = used_indices[i + 1];
      const auto bin2 = static_cast<uint8_t>((other_bin->data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf);
      const int i1 = i >> 1;
      data_[i1] = (bin1 | (bin2 << 4));
    }
    if (rest) {
      data_size_t idx = used_indices[num_used_indices - 1];
      data_[num_used_indices >> 1] = (other_bin->data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;
    }
  }

  void SaveBinaryToFile(FILE* file) const override {
    fwrite(data_.data(), sizeof(uint8_t), data_.size(), file);
  }

  size_t SizesInByte() const override {
    return sizeof(uint8_t) * data_.size();
  }

protected:
  data_size_t num_data_;
  std::vector<uint8_t> data_;
  std::vector<uint8_t> buf_;
};

uint32_t Dense4bitsBinIterator::Get(data_size_t idx) {
  const auto bin = (bin_data_->data_[idx >> 1] >> ((idx & 1) << 2)) & 0xf;
  if (bin >= min_bin_ && bin <= max_bin_) {
    return bin - min_bin_ + bias_;
  } else {
    return default_bin_;
  }
}

BinIterator* Dense4bitsBin::GetIterator(uint32_t min_bin, uint32_t max_bin, uint32_t default_bin) const {
  return new Dense4bitsBinIterator(this, min_bin, max_bin, default_bin);
}

}  // namespace LightGBM
#endif   // LIGHTGBM_IO_DENSE_NBITS_BIN_HPP_