contrib/libs/apache/arrow_next/cpp/src/arrow/json/chunked_builder.cc


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// Licensed to the Apache Software Foundation (ASF) under one
// or more contributor license agreements.  See the NOTICE file
// distributed with this work for additional information
// regarding copyright ownership.  The ASF licenses this file
// to you under the Apache License, Version 2.0 (the
// "License"); you may not use this file except in compliance
// with the License.  You may obtain a copy of the License at
//
//   http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing,
// software distributed under the License is distributed on an
// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
// KIND, either express or implied.  See the License for the
// specific language governing permissions and limitations
// under the License.

#include "contrib/libs/apache/arrow_next/cpp/src/arrow/json/chunked_builder.h"

#include <mutex>
#include <string>
#include <unordered_map>
#include <utility>
#include <vector>

#include "contrib/libs/apache/arrow_next/cpp/src/arrow/array.h"
#include "contrib/libs/apache/arrow_next/cpp/src/arrow/buffer.h"
#include "contrib/libs/apache/arrow_next/cpp/src/arrow/json/converter.h"
#include "contrib/libs/apache/arrow_next/cpp/src/arrow/table.h"
#include "contrib/libs/apache/arrow_next/cpp/src/arrow/util/checked_cast.h"
#include "contrib/libs/apache/arrow_next/cpp/src/arrow/util/logging.h"
#include "contrib/libs/apache/arrow_next/cpp/src/arrow/util/task_group.h"

namespace arrow20 {

using internal::checked_cast;
using internal::TaskGroup;

namespace json {
namespace {

Status MakeChunkedArrayBuilder(const std::shared_ptr<TaskGroup>& task_group,
                               MemoryPool* pool, const PromotionGraph* promotion_graph,
                               const std::shared_ptr<DataType>& type,
                               bool allow_promotion,
                               std::shared_ptr<ChunkedArrayBuilder>* out);

class NonNestedChunkedArrayBuilder : public ChunkedArrayBuilder {
 public:
  NonNestedChunkedArrayBuilder(const std::shared_ptr<TaskGroup>& task_group,
                               std::shared_ptr<Converter> converter)
      : ChunkedArrayBuilder(task_group), converter_(std::move(converter)) {}

  Status Finish(std::shared_ptr<ChunkedArray>* out) override {
    RETURN_NOT_OK(task_group_->Finish());
    *out = std::make_shared<ChunkedArray>(std::move(chunks_), converter_->out_type());
    chunks_.clear();
    return Status::OK();
  }

  Status ReplaceTaskGroup(const std::shared_ptr<TaskGroup>& task_group) override {
    RETURN_NOT_OK(task_group_->Finish());
    task_group_ = task_group;
    return Status::OK();
  }

 protected:
  ArrayVector chunks_;
  std::mutex mutex_;
  std::shared_ptr<Converter> converter_;
};

class TypedChunkedArrayBuilder
    : public NonNestedChunkedArrayBuilder,
      public std::enable_shared_from_this<TypedChunkedArrayBuilder> {
 public:
  using NonNestedChunkedArrayBuilder::NonNestedChunkedArrayBuilder;

  void Insert(int64_t block_index, const std::shared_ptr<Field>&,
              const std::shared_ptr<Array>& unconverted) override {
    std::unique_lock<std::mutex> lock(mutex_);
    if (chunks_.size() <= static_cast<size_t>(block_index)) {
      chunks_.resize(static_cast<size_t>(block_index) + 1, nullptr);
    }
    lock.unlock();

    auto self = shared_from_this();

    task_group_->Append([self, block_index, unconverted] {
      std::shared_ptr<Array> converted;
      RETURN_NOT_OK(self->converter_->Convert(unconverted, &converted));
      std::unique_lock<std::mutex> lock(self->mutex_);
      self->chunks_[block_index] = std::move(converted);
      return Status::OK();
    });
  }
};

class InferringChunkedArrayBuilder
    : public NonNestedChunkedArrayBuilder,
      public std::enable_shared_from_this<InferringChunkedArrayBuilder> {
 public:
  InferringChunkedArrayBuilder(const std::shared_ptr<TaskGroup>& task_group,
                               const PromotionGraph* promotion_graph,
                               std::shared_ptr<Converter> converter)
      : NonNestedChunkedArrayBuilder(task_group, std::move(converter)),
        promotion_graph_(promotion_graph) {}

  void Insert(int64_t block_index, const std::shared_ptr<Field>& unconverted_field,
              const std::shared_ptr<Array>& unconverted) override {
    std::unique_lock<std::mutex> lock(mutex_);
    if (chunks_.size() <= static_cast<size_t>(block_index)) {
      chunks_.resize(static_cast<size_t>(block_index) + 1, nullptr);
      unconverted_.resize(chunks_.size(), nullptr);
      unconverted_fields_.resize(chunks_.size(), nullptr);
    }
    unconverted_[block_index] = unconverted;
    unconverted_fields_[block_index] = unconverted_field;
    lock.unlock();
    ScheduleConvertChunk(block_index);
  }

  void ScheduleConvertChunk(int64_t block_index) {
    auto self = shared_from_this();
    task_group_->Append([self, block_index] {
      return self->TryConvertChunk(static_cast<size_t>(block_index));
    });
  }

  Status TryConvertChunk(size_t block_index) {
    std::unique_lock<std::mutex> lock(mutex_);
    auto converter = converter_;
    auto unconverted = unconverted_[block_index];
    auto unconverted_field = unconverted_fields_[block_index];
    std::shared_ptr<Array> converted;

    lock.unlock();
    Status st = converter->Convert(unconverted, &converted);
    lock.lock();

    if (converter != converter_) {
      // another task promoted converter; reconvert
      lock.unlock();
      ScheduleConvertChunk(block_index);
      return Status::OK();
    }

    if (st.ok()) {
      // conversion succeeded
      chunks_[block_index] = std::move(converted);
      return Status::OK();
    }

    auto promoted_type =
        promotion_graph_->Promote(converter_->out_type(), unconverted_field);
    if (promoted_type == nullptr) {
      // converter failed, no promotion available
      return st;
    }
    RETURN_NOT_OK(MakeConverter(promoted_type, converter_->pool(), &converter_));

    size_t nchunks = chunks_.size();
    for (size_t i = 0; i < nchunks; ++i) {
      if (i != block_index && chunks_[i]) {
        // We're assuming the chunk was converted using the wrong type
        // (which should be true unless the executor reorders tasks)
        chunks_[i].reset();
        lock.unlock();
        ScheduleConvertChunk(i);
        lock.lock();
      }
    }
    lock.unlock();
    ScheduleConvertChunk(block_index);
    return Status::OK();
  }

  Status Finish(std::shared_ptr<ChunkedArray>* out) override {
    RETURN_NOT_OK(NonNestedChunkedArrayBuilder::Finish(out));
    unconverted_.clear();
    return Status::OK();
  }

 private:
  ArrayVector unconverted_;
  std::vector<std::shared_ptr<Field>> unconverted_fields_;
  const PromotionGraph* promotion_graph_;
};

class ChunkedListArrayBuilder : public ChunkedArrayBuilder {
 public:
  ChunkedListArrayBuilder(const std::shared_ptr<TaskGroup>& task_group, MemoryPool* pool,
                          std::shared_ptr<ChunkedArrayBuilder> value_builder,
                          const std::shared_ptr<Field>& value_field)
      : ChunkedArrayBuilder(task_group),
        pool_(pool),
        value_builder_(std::move(value_builder)),
        value_field_(value_field) {}

  Status ReplaceTaskGroup(const std::shared_ptr<TaskGroup>& task_group) override {
    RETURN_NOT_OK(task_group_->Finish());
    RETURN_NOT_OK(value_builder_->ReplaceTaskGroup(task_group));
    task_group_ = task_group;
    return Status::OK();
  }

  void Insert(int64_t block_index, const std::shared_ptr<Field>&,
              const std::shared_ptr<Array>& unconverted) override {
    std::unique_lock<std::mutex> lock(mutex_);

    if (null_bitmap_chunks_.size() <= static_cast<size_t>(block_index)) {
      null_bitmap_chunks_.resize(static_cast<size_t>(block_index) + 1, nullptr);
      offset_chunks_.resize(null_bitmap_chunks_.size(), nullptr);
    }

    if (unconverted->type_id() == Type::NA) {
      auto st = InsertNull(block_index, unconverted->length());
      if (!st.ok()) {
        task_group_->Append([st] { return st; });
      }
      return;
    }

    DCHECK_EQ(unconverted->type_id(), Type::LIST);
    const auto& list_array = checked_cast<const ListArray&>(*unconverted);

    null_bitmap_chunks_[block_index] = unconverted->null_bitmap();
    offset_chunks_[block_index] = list_array.value_offsets();

    value_builder_->Insert(block_index, list_array.list_type()->value_field(),
                           list_array.values());
  }

  Status Finish(std::shared_ptr<ChunkedArray>* out) override {
    RETURN_NOT_OK(task_group_->Finish());

    std::shared_ptr<ChunkedArray> value_array;
    RETURN_NOT_OK(value_builder_->Finish(&value_array));

    auto type = list(value_field_->WithType(value_array->type())->WithMetadata(nullptr));
    ArrayVector chunks(null_bitmap_chunks_.size());
    for (size_t i = 0; i < null_bitmap_chunks_.size(); ++i) {
      auto value_chunk = value_array->chunk(static_cast<int>(i));
      auto length = offset_chunks_[i]->size() / sizeof(int32_t) - 1;
      chunks[i] = std::make_shared<ListArray>(type, length, offset_chunks_[i],
                                              value_chunk, null_bitmap_chunks_[i]);
    }

    *out = std::make_shared<ChunkedArray>(std::move(chunks), type);
    return Status::OK();
  }

 private:
  // call from Insert() only, with mutex_ locked
  Status InsertNull(int64_t block_index, int64_t length) {
    value_builder_->Insert(block_index, value_field_, std::make_shared<NullArray>(0));

    ARROW_ASSIGN_OR_RAISE(null_bitmap_chunks_[block_index],
                          AllocateEmptyBitmap(length, pool_));

    int64_t offsets_length = (length + 1) * sizeof(int32_t);
    ARROW_ASSIGN_OR_RAISE(offset_chunks_[block_index],
                          AllocateBuffer(offsets_length, pool_));
    std::memset(offset_chunks_[block_index]->mutable_data(), 0, offsets_length);

    return Status::OK();
  }

  std::mutex mutex_;
  MemoryPool* pool_;
  std::shared_ptr<ChunkedArrayBuilder> value_builder_;
  BufferVector offset_chunks_, null_bitmap_chunks_;
  std::shared_ptr<Field> value_field_;
};

class ChunkedStructArrayBuilder : public ChunkedArrayBuilder {
 public:
  ChunkedStructArrayBuilder(
      const std::shared_ptr<TaskGroup>& task_group, MemoryPool* pool,
      const PromotionGraph* promotion_graph,
      std::vector<std::pair<std::string, std::shared_ptr<ChunkedArrayBuilder>>>
          name_builders)
      : ChunkedArrayBuilder(task_group), pool_(pool), promotion_graph_(promotion_graph) {
    for (auto&& name_builder : name_builders) {
      auto index = static_cast<int>(name_to_index_.size());
      name_to_index_.emplace(std::move(name_builder.first), index);
      child_builders_.emplace_back(std::move(name_builder.second));
    }
  }

  void Insert(int64_t block_index, const std::shared_ptr<Field>&,
              const std::shared_ptr<Array>& unconverted) override {
    std::unique_lock<std::mutex> lock(mutex_);

    if (null_bitmap_chunks_.size() <= static_cast<size_t>(block_index)) {
      null_bitmap_chunks_.resize(static_cast<size_t>(block_index) + 1, nullptr);
      chunk_lengths_.resize(null_bitmap_chunks_.size(), -1);
      child_absent_.resize(null_bitmap_chunks_.size(), std::vector<bool>(0));
    }
    null_bitmap_chunks_[block_index] = unconverted->null_bitmap();
    chunk_lengths_[block_index] = unconverted->length();

    if (unconverted->type_id() == Type::NA) {
      auto maybe_buffer = AllocateBitmap(unconverted->length(), pool_);
      if (maybe_buffer.ok()) {
        null_bitmap_chunks_[block_index] = *std::move(maybe_buffer);
        std::memset(null_bitmap_chunks_[block_index]->mutable_data(), 0,
                    null_bitmap_chunks_[block_index]->size());
      } else {
        Status st = maybe_buffer.status();
        task_group_->Append([st] { return st; });
      }

      // absent fields will be inserted at Finish
      return;
    }

    const auto& struct_array = checked_cast<const StructArray&>(*unconverted);
    if (promotion_graph_ == nullptr) {
      // If unexpected fields are ignored or result in an error then all parsers will emit
      // columns exclusively in the ordering specified in ParseOptions::explicit_schema,
      // so child_builders_ is immutable and no associative lookup is necessary.
      for (int i = 0; i < unconverted->num_fields(); ++i) {
        child_builders_[i]->Insert(block_index, unconverted->type()->field(i),
                                   struct_array.field(i));
      }
    } else {
      auto st = InsertChildren(block_index, struct_array);
      if (!st.ok()) {
        return task_group_->Append([st] { return st; });
      }
    }
  }

  Status Finish(std::shared_ptr<ChunkedArray>* out) override {
    RETURN_NOT_OK(task_group_->Finish());

    if (promotion_graph_ != nullptr) {
      // insert absent child chunks
      for (auto&& name_index : name_to_index_) {
        auto child_builder = child_builders_[name_index.second].get();

        RETURN_NOT_OK(child_builder->ReplaceTaskGroup(TaskGroup::MakeSerial()));

        for (size_t i = 0; i < chunk_lengths_.size(); ++i) {
          if (child_absent_[i].size() > static_cast<size_t>(name_index.second) &&
              !child_absent_[i][name_index.second]) {
            continue;
          }
          auto empty = std::make_shared<NullArray>(chunk_lengths_[i]);
          child_builder->Insert(i, promotion_graph_->Null(name_index.first), empty);
        }
      }
    }

    std::vector<std::shared_ptr<Field>> fields(name_to_index_.size());
    std::vector<std::shared_ptr<ChunkedArray>> child_arrays(name_to_index_.size());
    for (auto&& name_index : name_to_index_) {
      auto child_builder = child_builders_[name_index.second].get();

      std::shared_ptr<ChunkedArray> child_array;
      RETURN_NOT_OK(child_builder->Finish(&child_array));

      child_arrays[name_index.second] = child_array;
      fields[name_index.second] = field(name_index.first, child_array->type());
    }

    auto type = struct_(std::move(fields));
    ArrayVector chunks(null_bitmap_chunks_.size());
    for (size_t i = 0; i < null_bitmap_chunks_.size(); ++i) {
      ArrayVector child_chunks;
      for (const auto& child_array : child_arrays) {
        child_chunks.push_back(child_array->chunk(static_cast<int>(i)));
      }
      chunks[i] = std::make_shared<StructArray>(type, chunk_lengths_[i], child_chunks,
                                                null_bitmap_chunks_[i]);
    }

    *out = std::make_shared<ChunkedArray>(std::move(chunks), type);
    return Status::OK();
  }

  Status ReplaceTaskGroup(const std::shared_ptr<TaskGroup>& task_group) override {
    RETURN_NOT_OK(task_group_->Finish());
    for (auto&& child_builder : child_builders_) {
      RETURN_NOT_OK(child_builder->ReplaceTaskGroup(task_group));
    }
    task_group_ = task_group;
    return Status::OK();
  }

 private:
  // Insert children associatively by name; the unconverted block may have unexpected or
  // differently ordered fields
  // call from Insert() only, with mutex_ locked
  Status InsertChildren(int64_t block_index, const StructArray& unconverted) {
    const auto& fields = unconverted.type()->fields();

    for (int i = 0; i < unconverted.num_fields(); ++i) {
      auto it = name_to_index_.find(fields[i]->name());

      if (it == name_to_index_.end()) {
        // add a new field to this builder
        auto type = promotion_graph_->Infer(fields[i]);
        DCHECK_NE(type, nullptr)
            << "invalid unconverted_field encountered in conversion: "
            << fields[i]->name() << ":" << *fields[i]->type();

        auto new_index = static_cast<int>(name_to_index_.size());
        it = name_to_index_.emplace(fields[i]->name(), new_index).first;

        std::shared_ptr<ChunkedArrayBuilder> child_builder;
        RETURN_NOT_OK(MakeChunkedArrayBuilder(task_group_, pool_, promotion_graph_, type,
                                              /*allow_promotion=*/true, &child_builder));
        child_builders_.emplace_back(std::move(child_builder));
      }

      auto unconverted_field = unconverted.type()->field(i);
      child_builders_[it->second]->Insert(block_index, unconverted_field,
                                          unconverted.field(i));

      child_absent_[block_index].resize(child_builders_.size(), true);
      child_absent_[block_index][it->second] = false;
    }

    return Status::OK();
  }

  std::mutex mutex_;
  MemoryPool* pool_;
  const PromotionGraph* promotion_graph_;
  std::unordered_map<std::string, int> name_to_index_;
  std::vector<std::shared_ptr<ChunkedArrayBuilder>> child_builders_;
  std::vector<std::vector<bool>> child_absent_;
  BufferVector null_bitmap_chunks_;
  std::vector<int64_t> chunk_lengths_;
};

Status MakeChunkedArrayBuilder(const std::shared_ptr<TaskGroup>& task_group,
                               MemoryPool* pool, const PromotionGraph* promotion_graph,
                               const std::shared_ptr<DataType>& type,
                               bool allow_promotion,
                               std::shared_ptr<ChunkedArrayBuilder>* out) {
  // If a promotion graph is provided, unexpected fields will be allowed - using the graph
  // recursively for itself and any child fields (via the `allow_promotion` parameter).
  // Fields provided in the schema will adhere to their corresponding type. However,
  // structs defined in the schema may obtain unexpected child fields, which will use the
  // promotion graph as well.
  //
  // If a promotion graph is not provided, unexpected fields are always ignored and
  // type inference never occurs.
  if (type->id() == Type::STRUCT) {
    std::vector<std::pair<std::string, std::shared_ptr<ChunkedArrayBuilder>>>
        child_builders;
    for (const auto& f : type->fields()) {
      std::shared_ptr<ChunkedArrayBuilder> child_builder;
      RETURN_NOT_OK(MakeChunkedArrayBuilder(task_group, pool, promotion_graph, f->type(),
                                            allow_promotion, &child_builder));
      child_builders.emplace_back(f->name(), std::move(child_builder));
    }
    *out = std::make_shared<ChunkedStructArrayBuilder>(task_group, pool, promotion_graph,
                                                       std::move(child_builders));
    return Status::OK();
  }
  if (type->id() == Type::LIST) {
    const auto& list_type = checked_cast<const ListType&>(*type);
    std::shared_ptr<ChunkedArrayBuilder> value_builder;
    RETURN_NOT_OK(MakeChunkedArrayBuilder(task_group, pool, promotion_graph,
                                          list_type.value_type(), allow_promotion,
                                          &value_builder));
    *out = std::make_shared<ChunkedListArrayBuilder>(
        task_group, pool, std::move(value_builder), list_type.value_field());
    return Status::OK();
  }

  // Construct the "leaf" builder
  std::shared_ptr<Converter> converter;
  RETURN_NOT_OK(MakeConverter(type, pool, &converter));
  if (allow_promotion && promotion_graph) {
    *out = std::make_shared<InferringChunkedArrayBuilder>(task_group, promotion_graph,
                                                          std::move(converter));
  } else {
    *out = std::make_shared<TypedChunkedArrayBuilder>(task_group, std::move(converter));
  }
  return Status::OK();
}

}  // namespace

// This overload is exposed to the user and will only be called once on instantiation to
// canonicalize any explicitly-defined fields. Such fields won't be subject to
// type inference/promotion
Status MakeChunkedArrayBuilder(const std::shared_ptr<TaskGroup>& task_group,
                               MemoryPool* pool, const PromotionGraph* promotion_graph,
                               const std::shared_ptr<DataType>& type,
                               std::shared_ptr<ChunkedArrayBuilder>* out) {
  return MakeChunkedArrayBuilder(task_group, pool, promotion_graph, type,
                                 /*allow_promotion=*/false, out);
}

}  // namespace json
}  // namespace arrow20