be/src/storage/segment/segment_writer.cpp

Source
// 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 "storage/segment/segment_writer.h"

#include <assert.h>
#include <gen_cpp/segment_v2.pb.h>
#include <parallel_hashmap/phmap.h>

#include <algorithm>

// IWYU pragma: no_include <opentelemetry/common/threadlocal.h>
#include <crc32c/crc32c.h>

#include "cloud/config.h"
#include "common/cast_set.h"
#include "common/compiler_util.h" // IWYU pragma: keep
#include "common/config.h"
#include "common/logging.h" // LOG
#include "common/status.h"
#include "core/block/block.h"
#include "core/block/column_with_type_and_name.h"
#include "core/column/column_nullable.h"
#include "core/data_type/primitive_type.h"
#include "core/field.h"
#include "core/types.h"
#include "core/value/vdatetime_value.h"
#include "exec/common/variant_util.h"
#include "io/cache/block_file_cache.h"
#include "io/cache/block_file_cache_factory.h"
#include "io/fs/file_system.h"
#include "io/fs/file_writer.h"
#include "io/fs/local_file_system.h"
#include "runtime/exec_env.h"
#include "runtime/memory/mem_tracker.h"
#include "service/point_query_executor.h"
#include "storage/data_dir.h"
#include "storage/index/index_file_writer.h"
#include "storage/index/index_writer.h"
#include "storage/index/inverted/inverted_index_fs_directory.h"
#include "storage/index/primary_key_index.h"
#include "storage/index/short_key_index.h"
#include "storage/iterator/olap_data_convertor.h"
#include "storage/key_coder.h"
#include "storage/olap_common.h"
#include "storage/olap_define.h"
#include "storage/partial_update_info.h"
#include "storage/rowset/rowset_writer_context.h" // RowsetWriterContext
#include "storage/rowset/segment_creator.h"
#include "storage/segment/column_writer.h" // ColumnWriter
#include "storage/segment/external_col_meta_util.h"
#include "storage/segment/page_io.h"
#include "storage/segment/page_pointer.h"
#include "storage/segment/segment_loader.h"
#include "storage/segment/variant/variant_ext_meta_writer.h"
#include "storage/segment/variant_stats_calculator.h"
#include "storage/storage_engine.h"
#include "storage/tablet/tablet_schema.h"
#include "storage/utils.h"
#include "util/coding.h"
#include "util/faststring.h"
#include "util/jsonb/serialize.h"
#include "util/simd/bits.h"
namespace doris {
namespace segment_v2 {

using namespace ErrorCode;
using namespace KeyConsts;

const char* k_segment_magic = "D0R1";
const uint32_t k_segment_magic_length = 4;

inline std::string segment_mem_tracker_name(uint32_t segment_id) {
    return "SegmentWriter:Segment-" + std::to_string(segment_id);
}

SegmentWriter::SegmentWriter(io::FileWriter* file_writer, uint32_t segment_id,
                             TabletSchemaSPtr tablet_schema, BaseTabletSPtr tablet,
                             DataDir* data_dir, const SegmentWriterOptions& opts,
                             IndexFileWriter* index_file_writer)
        : _segment_id(segment_id),
          _tablet_schema(std::move(tablet_schema)),
          _tablet(std::move(tablet)),
          _data_dir(data_dir),
          _opts(opts),
          _file_writer(file_writer),
          _index_file_writer(index_file_writer),
          _mem_tracker(std::make_unique<MemTracker>(segment_mem_tracker_name(segment_id))),
          _mow_context(std::move(opts.mow_ctx)) {
    CHECK_NOTNULL(file_writer);
    _num_sort_key_columns = _tablet_schema->num_key_columns();
    _num_short_key_columns = _tablet_schema->num_short_key_columns();
    if (!_is_mow_with_cluster_key()) {
        DCHECK(_num_sort_key_columns >= _num_short_key_columns)
                << ", table_id=" << _tablet_schema->table_id()
                << ", num_key_columns=" << _num_sort_key_columns
                << ", num_short_key_columns=" << _num_short_key_columns
                << ", cluster_key_columns=" << _tablet_schema->cluster_key_uids().size();
    }
    for (size_t cid = 0; cid < _num_sort_key_columns; ++cid) {
        const auto& column = _tablet_schema->column(cid);
        _key_coders.push_back(get_key_coder(column.type()));
        _key_index_size.push_back(cast_set<uint16_t>(column.index_length()));
    }
    if (_is_mow()) {
        // encode the sequence id into the primary key index
        if (_tablet_schema->has_sequence_col()) {
            const auto& column = _tablet_schema->column(_tablet_schema->sequence_col_idx());
            _seq_coder = get_key_coder(column.type());
        }
        // encode the rowid into the primary key index
        if (_is_mow_with_cluster_key()) {
            _rowid_coder = get_key_coder(FieldType::OLAP_FIELD_TYPE_UNSIGNED_INT);
            // primary keys
            _primary_key_coders.swap(_key_coders);
            // cluster keys
            _key_coders.clear();
            _key_index_size.clear();
            _num_sort_key_columns = _tablet_schema->cluster_key_uids().size();
            for (auto cid : _tablet_schema->cluster_key_uids()) {
                const auto& column = _tablet_schema->column_by_uid(cid);
                _key_coders.push_back(get_key_coder(column.type()));
                _key_index_size.push_back(cast_set<uint16_t>(column.index_length()));
            }
        }
    }
}

SegmentWriter::~SegmentWriter() {
    _mem_tracker->release(_mem_tracker->consumption());
}

void SegmentWriter::init_column_meta(ColumnMetaPB* meta, uint32_t column_id,
                                     const TabletColumn& column, TabletSchemaSPtr tablet_schema) {
    meta->set_column_id(column_id);
    meta->set_type(int(column.type()));
    meta->set_length(column.length());
    meta->set_encoding(DEFAULT_ENCODING);
    meta->set_compression(_opts.compression_type);
    meta->set_is_nullable(column.is_nullable());
    meta->set_default_value(column.default_value());
    meta->set_precision(column.precision());
    meta->set_frac(column.frac());
    if (column.has_path_info()) {
        column.path_info_ptr()->to_protobuf(meta->mutable_column_path_info(),
                                            column.parent_unique_id());
    }
    meta->set_unique_id(column.unique_id());
    for (uint32_t i = 0; i < column.get_subtype_count(); ++i) {
        init_column_meta(meta->add_children_columns(), column_id, column.get_sub_column(i),
                         tablet_schema);
    }
    meta->set_result_is_nullable(column.get_result_is_nullable());
    meta->set_function_name(column.get_aggregation_name());
    meta->set_be_exec_version(column.get_be_exec_version());
    if (column.is_variant_type()) {
        meta->set_variant_max_subcolumns_count(column.variant_max_subcolumns_count());
        meta->set_variant_enable_doc_mode(column.variant_enable_doc_mode());
    }
}

Status SegmentWriter::init() {
    std::vector<uint32_t> column_ids;
    auto column_cnt = cast_set<int>(_tablet_schema->num_columns());
    for (uint32_t i = 0; i < column_cnt; ++i) {
        column_ids.emplace_back(i);
    }
    return init(column_ids, true);
}

Status SegmentWriter::_create_column_writer(uint32_t cid, const TabletColumn& column,
                                            const TabletSchemaSPtr& schema) {
    ColumnWriterOptions opts;
    opts.meta = _footer.add_columns();

    init_column_meta(opts.meta, cid, column, schema);

    // now we create zone map for key columns in AGG_KEYS or all column in UNIQUE_KEYS or DUP_KEYS
    // except for columns whose type don't support zone map.
    opts.need_zone_map = column.is_key() || schema->keys_type() != KeysType::AGG_KEYS;
    opts.need_bloom_filter = column.is_bf_column();
    if (opts.need_bloom_filter) {
        opts.bf_options.fpp = schema->has_bf_fpp() ? schema->bloom_filter_fpp() : 0.05;
    }
    auto* tablet_index = schema->get_ngram_bf_index(column.unique_id());
    if (tablet_index) {
        opts.need_bloom_filter = true;
        opts.is_ngram_bf_index = true;
        //narrow convert from int32_t to uint8_t and uint16_t which is dangerous
        auto gram_size = tablet_index->get_gram_size();
        auto gram_bf_size = tablet_index->get_gram_bf_size();
        if (gram_size > 256 || gram_size < 1) {
            return Status::NotSupported("Do not support ngram bloom filter for ngram_size: ",
                                        gram_size);
        }
        if (gram_bf_size > 65535 || gram_bf_size < 64) {
            return Status::NotSupported("Do not support ngram bloom filter for bf_size: ",
                                        gram_bf_size);
        }
        opts.gram_size = cast_set<uint8_t>(gram_size);
        opts.gram_bf_size = cast_set<uint16_t>(gram_bf_size);
    }

    bool skip_inverted_index = false;
    if (_opts.rowset_ctx != nullptr) {
        // skip write inverted index for index compaction column
        skip_inverted_index =
                _opts.rowset_ctx->columns_to_do_index_compaction.count(column.unique_id()) > 0;
    }
    // skip write inverted index on load if skip_write_index_on_load is true
    if (_opts.write_type == DataWriteType::TYPE_DIRECT && schema->skip_write_index_on_load()) {
        skip_inverted_index = true;
    }
    // indexes for this column
    if (!skip_inverted_index) {
        auto inverted_indexs = schema->inverted_indexs(column);
        if (!inverted_indexs.empty()) {
            opts.inverted_indexes = inverted_indexs;
            opts.need_inverted_index = true;
            DCHECK(_index_file_writer != nullptr);
        }
    }
    // indexes for this column
    if (const auto& index = schema->ann_index(column); index != nullptr) {
        opts.ann_index = index;
        opts.need_ann_index = true;
        DCHECK(_index_file_writer != nullptr);
    }

    opts.index_file_writer = _index_file_writer;

#define DISABLE_INDEX_IF_FIELD_TYPE(TYPE)                     \
    if (column.type() == FieldType::OLAP_FIELD_TYPE_##TYPE) { \
        opts.need_zone_map = false;                           \
        opts.need_bloom_filter = false;                       \
    }

    DISABLE_INDEX_IF_FIELD_TYPE(STRUCT)
    DISABLE_INDEX_IF_FIELD_TYPE(ARRAY)
    DISABLE_INDEX_IF_FIELD_TYPE(JSONB)
    DISABLE_INDEX_IF_FIELD_TYPE(AGG_STATE)
    DISABLE_INDEX_IF_FIELD_TYPE(MAP)
    DISABLE_INDEX_IF_FIELD_TYPE(BITMAP)
    DISABLE_INDEX_IF_FIELD_TYPE(HLL)
    DISABLE_INDEX_IF_FIELD_TYPE(QUANTILE_STATE)
    DISABLE_INDEX_IF_FIELD_TYPE(VARIANT)

#undef DISABLE_INDEX_IF_FIELD_TYPE

    int64_t storage_page_size = _tablet_schema->storage_page_size();
    // storage_page_size must be between 4KB and 10MB.
    if (storage_page_size >= 4096 && storage_page_size <= 10485760) {
        opts.data_page_size = storage_page_size;
    }
    opts.dict_page_size = _tablet_schema->storage_dict_page_size();
    DBUG_EXECUTE_IF("VerticalSegmentWriter._create_column_writer.storage_page_size", {
        auto table_id = DebugPoints::instance()->get_debug_param_or_default<int64_t>(
                "VerticalSegmentWriter._create_column_writer.storage_page_size", "table_id",
                INT_MIN);
        auto target_data_page_size = DebugPoints::instance()->get_debug_param_or_default<int64_t>(
                "VerticalSegmentWriter._create_column_writer.storage_page_size",
                "storage_page_size", INT_MIN);
        if (table_id == INT_MIN || target_data_page_size == INT_MIN) {
            return Status::Error<ErrorCode::INTERNAL_ERROR>(
                    "Debug point parameters missing: either 'table_id' or 'storage_page_size' not "
                    "set.");
        }
        if (table_id == _tablet_schema->table_id() &&
            opts.data_page_size != target_data_page_size) {
            return Status::Error<ErrorCode::INTERNAL_ERROR>(
                    "Mismatch in 'storage_page_size': expected size does not match the current "
                    "data page size. "
                    "Expected: " +
                    std::to_string(target_data_page_size) +
                    ", Actual: " + std::to_string(opts.data_page_size) + ".");
        }
    })
    if (column.is_row_store_column()) {
        // smaller page size for row store column
        auto page_size = _tablet_schema->row_store_page_size();
        opts.data_page_size =
                (page_size > 0) ? page_size : segment_v2::ROW_STORE_PAGE_SIZE_DEFAULT_VALUE;
    }

    opts.rowset_ctx = _opts.rowset_ctx;
    opts.file_writer = _file_writer;
    opts.compression_type = _opts.compression_type;
    opts.footer = &_footer;
    if (_opts.rowset_ctx != nullptr) {
        opts.input_rs_readers = _opts.rowset_ctx->input_rs_readers;
    }
    opts.encoding_preference = {.integer_type_default_use_plain_encoding =
                                        _tablet_schema->integer_type_default_use_plain_encoding(),
                                .binary_plain_encoding_default_impl =
                                        _tablet_schema->binary_plain_encoding_default_impl()};

    std::unique_ptr<ColumnWriter> writer;
    RETURN_IF_ERROR(ColumnWriter::create(opts, &column, _file_writer, &writer));
    RETURN_IF_ERROR(writer->init());
    _column_writers.push_back(std::move(writer));

    _olap_data_convertor->add_column_data_convertor(column);
    return Status::OK();
}

Status SegmentWriter::init(const std::vector<uint32_t>& col_ids, bool has_key) {
    DCHECK(_column_writers.empty());
    DCHECK(_column_ids.empty());
    _has_key = has_key;
    _column_writers.reserve(_tablet_schema->columns().size());
    _column_ids.insert(_column_ids.end(), col_ids.begin(), col_ids.end());
    _olap_data_convertor = std::make_unique<OlapBlockDataConvertor>();
    if (_opts.compression_type == UNKNOWN_COMPRESSION) {
        _opts.compression_type = _tablet_schema->compression_type();
    }

    // Vertical compaction calls init() multiple times against the same writer; the footer accumulates entries
    // across calls, so this init()'s slice of footer columns starts at the current size.
    const int variant_stats_footer_offset = _footer.columns_size();
    RETURN_IF_ERROR(_create_writers(_tablet_schema, col_ids));

    // Initialize variant statistics calculator
    _variant_stats_calculator = std::make_unique<VariantStatsCaculator>(
            &_footer, _tablet_schema, col_ids, variant_stats_footer_offset);

    // we don't need the short key index for unique key merge on write table.
    if (_has_key) {
        if (_is_mow()) {
            size_t seq_col_length = 0;
            if (_tablet_schema->has_sequence_col()) {
                seq_col_length =
                        _tablet_schema->column(_tablet_schema->sequence_col_idx()).length() + 1;
            }
            size_t rowid_length = 0;
            if (_is_mow_with_cluster_key()) {
                rowid_length = PrimaryKeyIndexReader::ROW_ID_LENGTH;
                _short_key_index_builder.reset(
                        new ShortKeyIndexBuilder(_segment_id, _opts.num_rows_per_block));
            }
            _primary_key_index_builder.reset(
                    new PrimaryKeyIndexBuilder(_file_writer, seq_col_length, rowid_length));
            RETURN_IF_ERROR(_primary_key_index_builder->init());
        } else {
            _short_key_index_builder.reset(
                    new ShortKeyIndexBuilder(_segment_id, _opts.num_rows_per_block));
        }
    }
    return Status::OK();
}

Status SegmentWriter::_create_writers(const TabletSchemaSPtr& tablet_schema,
                                      const std::vector<uint32_t>& col_ids) {
    _olap_data_convertor->reserve(col_ids.size());
    for (auto& cid : col_ids) {
        RETURN_IF_ERROR(_create_column_writer(cid, tablet_schema->column(cid), tablet_schema));
    }
    return Status::OK();
}

void SegmentWriter::_maybe_invalid_row_cache(const std::string& key) {
    // Just invalid row cache for simplicity, since the rowset is not visible at present.
    // If we update/insert cache, if load failed rowset will not be visible but cached data
    // will be visible, and lead to inconsistency.
    if (!config::disable_storage_row_cache && _tablet_schema->has_row_store_for_all_columns() &&
        _opts.write_type == DataWriteType::TYPE_DIRECT) {
        // invalidate cache
        RowCache::instance()->erase({_opts.rowset_ctx->tablet_id, key});
    }
}

void SegmentWriter::_serialize_block_to_row_column(const Block& block) {
    if (block.rows() == 0) {
        return;
    }
    MonotonicStopWatch watch;
    watch.start();
    int row_column_id = 0;
    for (int i = 0; i < _tablet_schema->num_columns(); ++i) {
        if (_tablet_schema->column(i).is_row_store_column()) {
            auto* row_store_column = static_cast<ColumnString*>(
                    block.get_by_position(i).column->assume_mutable_ref().assume_mutable().get());
            row_store_column->clear();
            DataTypeSerDeSPtrs serdes = create_data_type_serdes(block.get_data_types());
            JsonbSerializeUtil::block_to_jsonb(*_tablet_schema, block, *row_store_column,
                                               cast_set<int>(_tablet_schema->num_columns()), serdes,
                                               {_tablet_schema->row_columns_uids().begin(),
                                                _tablet_schema->row_columns_uids().end()});
            break;
        }
    }

    VLOG_DEBUG << "serialize , num_rows:" << block.rows() << ", row_column_id:" << row_column_id
               << ", total_byte_size:" << block.allocated_bytes() << ", serialize_cost(us)"
               << watch.elapsed_time() / 1000;
}

Status SegmentWriter::probe_key_for_mow(
        std::string key, std::size_t segment_pos, bool have_input_seq_column, bool have_delete_sign,
        const std::vector<RowsetSharedPtr>& specified_rowsets,
        std::vector<std::unique_ptr<SegmentCacheHandle>>& segment_caches,
        bool& has_default_or_nullable, std::vector<bool>& use_default_or_null_flag,
        const std::function<void(const RowLocation& loc)>& found_cb,
        const std::function<Status()>& not_found_cb, PartialUpdateStats& stats) {
    RowLocation loc;
    // save rowset shared ptr so this rowset wouldn't delete
    RowsetSharedPtr rowset;
    auto st = _tablet->lookup_row_key(
            key, _tablet_schema.get(), have_input_seq_column, specified_rowsets, &loc,
            cast_set<uint32_t>(_mow_context->max_version), segment_caches, &rowset);
    if (st.is<KEY_NOT_FOUND>()) {
        if (!have_delete_sign) {
            RETURN_IF_ERROR(not_found_cb());
        }
        ++stats.num_rows_new_added;
        has_default_or_nullable = true;
        use_default_or_null_flag.emplace_back(true);
        return Status::OK();
    }
    if (!st.ok() && !st.is<KEY_ALREADY_EXISTS>()) {
        LOG(WARNING) << "failed to lookup row key, error: " << st;
        return st;
    }

    // 1. if the delete sign is marked, it means that the value columns of the row will not
    //    be read. So we don't need to read the missing values from the previous rows.
    // 2. the one exception is when there are sequence columns in the table, we need to read
    //    the sequence columns, otherwise it may cause the merge-on-read based compaction
    //    policy to produce incorrect results
    // TODO(bobhan1): only read seq col rather than all columns in this situation for
    // partial update and flexible partial update

    // TODO(bobhan1): handle sequence column here
    if (st.is<KEY_ALREADY_EXISTS>() || (have_delete_sign && !_tablet_schema->has_sequence_col())) {
        has_default_or_nullable = true;
        use_default_or_null_flag.emplace_back(true);
    } else {
        // partial update should not contain invisible columns
        use_default_or_null_flag.emplace_back(false);
        _rsid_to_rowset.emplace(rowset->rowset_id(), rowset);
        found_cb(loc);
    }

    if (st.is<KEY_ALREADY_EXISTS>()) {
        // although we need to mark delete current row, we still need to read missing columns
        // for this row, we need to ensure that each column is aligned
        _mow_context->delete_bitmap->add(
                {_opts.rowset_ctx->rowset_id, _segment_id, DeleteBitmap::TEMP_VERSION_COMMON},
                cast_set<uint32_t>(segment_pos));
        ++stats.num_rows_deleted;
    } else {
        _mow_context->delete_bitmap->add(
                {loc.rowset_id, loc.segment_id, DeleteBitmap::TEMP_VERSION_COMMON}, loc.row_id);
        ++stats.num_rows_updated;
    }
    return Status::OK();
}

Status SegmentWriter::partial_update_preconditions_check(size_t row_pos) {
    if (!_is_mow()) {
        auto msg = fmt::format(
                "Can only do partial update on merge-on-write unique table, but found: "
                "keys_type={}, _opts.enable_unique_key_merge_on_write={}, tablet_id={}",
                _tablet_schema->keys_type(), _opts.enable_unique_key_merge_on_write,
                _tablet->tablet_id());
        DCHECK(false) << msg;
        return Status::InternalError<false>(msg);
    }
    if (_opts.rowset_ctx->partial_update_info == nullptr) {
        auto msg =
                fmt::format("partial_update_info should not be nullptr, please check, tablet_id={}",
                            _tablet->tablet_id());
        DCHECK(false) << msg;
        return Status::InternalError<false>(msg);
    }
    if (!_opts.rowset_ctx->partial_update_info->is_fixed_partial_update()) {
        auto msg = fmt::format(
                "in fixed partial update code, but update_mode={}, please check, tablet_id={}",
                _opts.rowset_ctx->partial_update_info->update_mode(), _tablet->tablet_id());
        DCHECK(false) << msg;
        return Status::InternalError<false>(msg);
    }
    if (row_pos != 0) {
        auto msg = fmt::format("row_pos should be 0, but found {}, tablet_id={}", row_pos,
                               _tablet->tablet_id());
        DCHECK(false) << msg;
        return Status::InternalError<false>(msg);
    }
    return Status::OK();
}

// for partial update, we should do following steps to fill content of block:
// 1. set block data to data convertor, and get all key_column's converted slice
// 2. get pk of input block, and read missing columns
//       2.1 first find key location{rowset_id, segment_id, row_id}
//       2.2 build read plan to read by batch
//       2.3 fill block
// 3. set columns to data convertor and then write all columns
Status SegmentWriter::append_block_with_partial_content(const Block* block, size_t row_pos,
                                                        size_t num_rows) {
    if (block->columns() < _tablet_schema->num_key_columns() ||
        block->columns() >= _tablet_schema->num_columns()) {
        return Status::InvalidArgument(
                fmt::format("illegal partial update block columns: {}, num key columns: {}, total "
                            "schema columns: {}",
                            block->columns(), _tablet_schema->num_key_columns(),
                            _tablet_schema->num_columns()));
    }
    RETURN_IF_ERROR(partial_update_preconditions_check(row_pos));

    // find missing column cids
    const auto& missing_cids = _opts.rowset_ctx->partial_update_info->missing_cids;
    const auto& including_cids = _opts.rowset_ctx->partial_update_info->update_cids;

    // create full block and fill with input columns
    auto full_block = _tablet_schema->create_block();
    size_t input_id = 0;
    for (auto i : including_cids) {
        full_block.replace_by_position(i, block->get_by_position(input_id++).column);
    }

    if (_opts.rowset_ctx->write_type != DataWriteType::TYPE_COMPACTION &&
        _tablet_schema->num_variant_columns() > 0) {
        RETURN_IF_ERROR(variant_util::parse_and_materialize_variant_columns(
                full_block, *_tablet_schema, including_cids));
    }
    RETURN_IF_ERROR(_olap_data_convertor->set_source_content_with_specifid_columns(
            &full_block, row_pos, num_rows, including_cids));

    bool have_input_seq_column = false;
    // write including columns
    std::vector<IOlapColumnDataAccessor*> key_columns;
    IOlapColumnDataAccessor* seq_column = nullptr;
    size_t segment_start_pos = 0;
    for (auto cid : including_cids) {
        // here we get segment column row num before append data.
        segment_start_pos = _column_writers[cid]->get_next_rowid();
        // olap data convertor alway start from id = 0
        auto converted_result = _olap_data_convertor->convert_column_data(cid);
        if (!converted_result.first.ok()) {
            return converted_result.first;
        }
        if (cid < _num_sort_key_columns) {
            key_columns.push_back(converted_result.second);
        } else if (_tablet_schema->has_sequence_col() &&
                   cid == _tablet_schema->sequence_col_idx()) {
            seq_column = converted_result.second;
            have_input_seq_column = true;
        }
        RETURN_IF_ERROR(_column_writers[cid]->append(converted_result.second->get_nullmap(),
                                                     converted_result.second->get_data(),
                                                     num_rows));
    }

    bool has_default_or_nullable = false;
    std::vector<bool> use_default_or_null_flag;
    use_default_or_null_flag.reserve(num_rows);
    const auto* delete_signs =
            BaseTablet::get_delete_sign_column_data(full_block, row_pos + num_rows);

    const std::vector<RowsetSharedPtr>& specified_rowsets = _mow_context->rowset_ptrs;
    std::vector<std::unique_ptr<SegmentCacheHandle>> segment_caches(specified_rowsets.size());

    FixedReadPlan read_plan;

    // locate rows in base data
    PartialUpdateStats stats;

    for (size_t block_pos = row_pos; block_pos < row_pos + num_rows; block_pos++) {
        // block   segment
        //   2   ->   0
        //   3   ->   1
        //   4   ->   2
        //   5   ->   3
        // here row_pos = 2, num_rows = 4.
        size_t delta_pos = block_pos - row_pos;
        size_t segment_pos = segment_start_pos + delta_pos;
        std::string key = _full_encode_keys(key_columns, delta_pos);
        _maybe_invalid_row_cache(key);
        if (have_input_seq_column) {
            _encode_seq_column(seq_column, delta_pos, &key);
        }
        // If the table have sequence column, and the include-cids don't contain the sequence
        // column, we need to update the primary key index builder at the end of this method.
        // At that time, we have a valid sequence column to encode the key with seq col.
        if (!_tablet_schema->has_sequence_col() || have_input_seq_column) {
            RETURN_IF_ERROR(_primary_key_index_builder->add_item(key));
        }

        // mark key with delete sign as deleted.
        bool have_delete_sign = (delete_signs != nullptr && delete_signs[block_pos] != 0);

        auto not_found_cb = [&]() {
            return _opts.rowset_ctx->partial_update_info->handle_new_key(
                    *_tablet_schema, [&]() -> std::string {
                        return block->dump_one_line(block_pos,
                                                    cast_set<int>(_num_sort_key_columns));
                    });
        };
        auto update_read_plan = [&](const RowLocation& loc) {
            read_plan.prepare_to_read(loc, segment_pos);
        };
        RETURN_IF_ERROR(probe_key_for_mow(std::move(key), segment_pos, have_input_seq_column,
                                          have_delete_sign, specified_rowsets, segment_caches,
                                          has_default_or_nullable, use_default_or_null_flag,
                                          update_read_plan, not_found_cb, stats));
    }
    CHECK_EQ(use_default_or_null_flag.size(), num_rows);

    if (config::enable_merge_on_write_correctness_check) {
        _tablet->add_sentinel_mark_to_delete_bitmap(_mow_context->delete_bitmap.get(),
                                                    *_mow_context->rowset_ids);
    }

    // read to fill full block
    RETURN_IF_ERROR(read_plan.fill_missing_columns(
            _opts.rowset_ctx, _rsid_to_rowset, *_tablet_schema, full_block,
            use_default_or_null_flag, has_default_or_nullable,
            cast_set<uint32_t>(segment_start_pos), block));

    if (_tablet_schema->num_variant_columns() > 0) {
        RETURN_IF_ERROR(variant_util::parse_and_materialize_variant_columns(
                full_block, *_tablet_schema, missing_cids));
    }

    // convert block to row store format
    _serialize_block_to_row_column(full_block);

    // convert missing columns and send to column writer
    RETURN_IF_ERROR(_olap_data_convertor->set_source_content_with_specifid_columns(
            &full_block, row_pos, num_rows, missing_cids));
    for (auto cid : missing_cids) {
        auto converted_result = _olap_data_convertor->convert_column_data(cid);
        if (!converted_result.first.ok()) {
            return converted_result.first;
        }
        if (_tablet_schema->has_sequence_col() && !have_input_seq_column &&
            cid == _tablet_schema->sequence_col_idx()) {
            DCHECK_EQ(seq_column, nullptr);
            seq_column = converted_result.second;
        }
        RETURN_IF_ERROR(_column_writers[cid]->append(converted_result.second->get_nullmap(),
                                                     converted_result.second->get_data(),
                                                     num_rows));
    }
    _num_rows_updated += stats.num_rows_updated;
    _num_rows_deleted += stats.num_rows_deleted;
    _num_rows_new_added += stats.num_rows_new_added;
    _num_rows_filtered += stats.num_rows_filtered;
    if (_tablet_schema->has_sequence_col() && !have_input_seq_column) {
        DCHECK_NE(seq_column, nullptr);
        if (_num_rows_written != row_pos ||
            _primary_key_index_builder->num_rows() != _num_rows_written) {
            return Status::InternalError(
                    "Correctness check failed, _num_rows_written: {}, row_pos: {}, primary key "
                    "index builder num rows: {}",
                    _num_rows_written, row_pos, _primary_key_index_builder->num_rows());
        }
        RETURN_IF_ERROR(
                _generate_primary_key_index(_key_coders, key_columns, seq_column, num_rows, false));
    }

    _num_rows_written += num_rows;
    DCHECK_EQ(_primary_key_index_builder->num_rows(), _num_rows_written)
            << "primary key index builder num rows(" << _primary_key_index_builder->num_rows()
            << ") not equal to segment writer's num rows written(" << _num_rows_written << ")";
    _olap_data_convertor->clear_source_content();

    return Status::OK();
}

Status SegmentWriter::append_block(const Block* block, size_t row_pos, size_t num_rows) {
    if (_opts.rowset_ctx->partial_update_info &&
        _opts.rowset_ctx->partial_update_info->is_partial_update() &&
        _opts.write_type == DataWriteType::TYPE_DIRECT &&
        !_opts.rowset_ctx->is_transient_rowset_writer) {
        if (_opts.rowset_ctx->partial_update_info->is_fixed_partial_update()) {
            RETURN_IF_ERROR(append_block_with_partial_content(block, row_pos, num_rows));
        } else {
            return Status::NotSupported<false>(
                    "SegmentWriter doesn't support flexible partial update, please set "
                    "enable_vertical_segment_writer=true in be.conf on all BEs to use "
                    "VerticalSegmentWriter.");
        }
        return Status::OK();
    }
    if (block->columns() < _column_writers.size()) {
        return Status::InternalError(
                "block->columns() < _column_writers.size(), block->columns()=" +
                std::to_string(block->columns()) +
                ", _column_writers.size()=" + std::to_string(_column_writers.size()) +
                ", _tablet_schema->dump_structure()=" + _tablet_schema->dump_structure());
    }
    CHECK(block->columns() >= _column_writers.size())
            << ", block->columns()=" << block->columns()
            << ", _column_writers.size()=" << _column_writers.size()
            << ", _tablet_schema->dump_structure()=" << _tablet_schema->dump_structure();
    // Row column should be filled here when it's a directly write from memtable
    // or it's schema change write(since column data type maybe changed, so we should reubild)
    if (_opts.write_type == DataWriteType::TYPE_DIRECT ||
        _opts.write_type == DataWriteType::TYPE_SCHEMA_CHANGE) {
        _serialize_block_to_row_column(*block);
    }

    if (_opts.rowset_ctx->write_type != DataWriteType::TYPE_COMPACTION &&
        _tablet_schema->num_variant_columns() > 0) {
        RETURN_IF_ERROR(variant_util::parse_and_materialize_variant_columns(
                const_cast<Block&>(*block), *_tablet_schema, _column_ids));
    }

    _olap_data_convertor->set_source_content(block, row_pos, num_rows);

    // find all row pos for short key indexes
    std::vector<size_t> short_key_pos;
    if (_has_key) {
        // We build a short key index every `_opts.num_rows_per_block` rows. Specifically, we
        // build a short key index using 1st rows for first block and `_short_key_row_pos - _row_count`
        // for next blocks.
        // Ensure we build a short key index using 1st rows only for the first block (ISSUE-9766).
        if (UNLIKELY(_short_key_row_pos == 0 && _num_rows_written == 0)) {
            short_key_pos.push_back(0);
        }
        while (_short_key_row_pos + _opts.num_rows_per_block < _num_rows_written + num_rows) {
            _short_key_row_pos += _opts.num_rows_per_block;
            short_key_pos.push_back(_short_key_row_pos - _num_rows_written);
        }
    }

    // convert column data from engine format to storage layer format
    std::vector<IOlapColumnDataAccessor*> key_columns;
    IOlapColumnDataAccessor* seq_column = nullptr;
    for (size_t id = 0; id < _column_writers.size(); ++id) {
        // olap data convertor alway start from id = 0
        auto converted_result = _olap_data_convertor->convert_column_data(id);
        if (!converted_result.first.ok()) {
            return converted_result.first;
        }
        auto cid = _column_ids[id];
        if (_has_key && cid < _tablet_schema->num_key_columns()) {
            key_columns.push_back(converted_result.second);
        } else if (_has_key && _tablet_schema->has_sequence_col() &&
                   cid == _tablet_schema->sequence_col_idx()) {
            seq_column = converted_result.second;
        }
        RETURN_IF_ERROR(_column_writers[id]->append(converted_result.second->get_nullmap(),
                                                    converted_result.second->get_data(), num_rows));
    }
    if (_opts.write_type == DataWriteType::TYPE_COMPACTION) {
        RETURN_IF_ERROR(
                _variant_stats_calculator->calculate_variant_stats(block, row_pos, num_rows));
    }
    if (_has_key) {
        if (_is_mow_with_cluster_key()) {
            // for now we don't need to query short key index for CLUSTER BY feature,
            // but we still write the index for future usage.
            // 1. generate primary key index, the key_columns is primary_key_columns
            RETURN_IF_ERROR(_generate_primary_key_index(_primary_key_coders, key_columns,
                                                        seq_column, num_rows, true));
            // 2. generate short key index (use cluster key)
            key_columns.clear();
            for (const auto& cid : _tablet_schema->cluster_key_uids()) {
                // find cluster key index in tablet schema
                auto cluster_key_index = _tablet_schema->field_index(cid);
                if (cluster_key_index == -1) {
                    return Status::InternalError(
                            "could not find cluster key column with unique_id=" +
                            std::to_string(cid) + " in tablet schema");
                }
                bool found = false;
                for (auto i = 0; i < _column_ids.size(); ++i) {
                    if (_column_ids[i] == cluster_key_index) {
                        auto converted_result = _olap_data_convertor->convert_column_data(i);
                        if (!converted_result.first.ok()) {
                            return converted_result.first;
                        }
                        key_columns.push_back(converted_result.second);
                        found = true;
                        break;
                    }
                }
                if (!found) {
                    return Status::InternalError(
                            "could not found cluster key column with unique_id=" +
                            std::to_string(cid) +
                            ", tablet schema index=" + std::to_string(cluster_key_index));
                }
            }
            RETURN_IF_ERROR(_generate_short_key_index(key_columns, num_rows, short_key_pos));
        } else if (_is_mow()) {
            RETURN_IF_ERROR(_generate_primary_key_index(_key_coders, key_columns, seq_column,
                                                        num_rows, false));
        } else {
            RETURN_IF_ERROR(_generate_short_key_index(key_columns, num_rows, short_key_pos));
        }
    }

    _num_rows_written += num_rows;
    _olap_data_convertor->clear_source_content();
    return Status::OK();
}

int64_t SegmentWriter::max_row_to_add(size_t row_avg_size_in_bytes) {
    auto segment_size = estimate_segment_size();
    if (segment_size >= MAX_SEGMENT_SIZE || _num_rows_written >= _opts.max_rows_per_segment)
            [[unlikely]] {
        return 0;
    }
    int64_t size_rows = ((int64_t)MAX_SEGMENT_SIZE - (int64_t)segment_size) / row_avg_size_in_bytes;
    int64_t count_rows = (int64_t)_opts.max_rows_per_segment - _num_rows_written;

    return std::min(size_rows, count_rows);
}

std::string SegmentWriter::_full_encode_keys(
        const std::vector<IOlapColumnDataAccessor*>& key_columns, size_t pos, bool null_first) {
    assert(_key_index_size.size() == _num_sort_key_columns);
    assert(key_columns.size() == _num_sort_key_columns &&
           _key_coders.size() == _num_sort_key_columns);
    return _full_encode_keys(_key_coders, key_columns, pos, null_first);
}

std::string SegmentWriter::_full_encode_keys(
        const std::vector<const KeyCoder*>& key_coders,
        const std::vector<IOlapColumnDataAccessor*>& key_columns, size_t pos, bool null_first) {
    assert(key_columns.size() == key_coders.size());

    std::string encoded_keys;
    size_t cid = 0;
    for (const auto& column : key_columns) {
        auto field = column->get_data_at(pos);
        if (UNLIKELY(!field)) {
            if (null_first) {
                encoded_keys.push_back(KEY_NULL_FIRST_MARKER);
            } else {
                encoded_keys.push_back(KEY_NORMAL_MARKER);
            }
            ++cid;
            continue;
        }
        encoded_keys.push_back(KEY_NORMAL_MARKER);
        DCHECK(key_coders[cid] != nullptr);
        key_coders[cid]->full_encode_ascending(field, &encoded_keys);
        ++cid;
    }
    return encoded_keys;
}

void SegmentWriter::_encode_seq_column(const IOlapColumnDataAccessor* seq_column, size_t pos,
                                       std::string* encoded_keys) {
    auto field = seq_column->get_data_at(pos);
    // To facilitate the use of the primary key index, encode the seq column
    // to the minimum value of the corresponding length when the seq column
    // is null
    if (UNLIKELY(!field)) {
        encoded_keys->push_back(KEY_NULL_FIRST_MARKER);
        size_t seq_col_length = _tablet_schema->column(_tablet_schema->sequence_col_idx()).length();
        encoded_keys->append(seq_col_length, KEY_MINIMAL_MARKER);
        return;
    }
    encoded_keys->push_back(KEY_NORMAL_MARKER);
    _seq_coder->full_encode_ascending(field, encoded_keys);
}

void SegmentWriter::_encode_rowid(const uint32_t rowid, std::string* encoded_keys) {
    encoded_keys->push_back(KEY_NORMAL_MARKER);
    _rowid_coder->full_encode_ascending(&rowid, encoded_keys);
}

std::string SegmentWriter::_encode_keys(const std::vector<IOlapColumnDataAccessor*>& key_columns,
                                        size_t pos) {
    assert(key_columns.size() == _num_short_key_columns);

    std::string encoded_keys;
    size_t cid = 0;
    for (const auto& column : key_columns) {
        auto field = column->get_data_at(pos);
        if (UNLIKELY(!field)) {
            encoded_keys.push_back(KEY_NULL_FIRST_MARKER);
            ++cid;
            continue;
        }
        encoded_keys.push_back(KEY_NORMAL_MARKER);
        _key_coders[cid]->encode_ascending(field, _key_index_size[cid], &encoded_keys);
        ++cid;
    }
    return encoded_keys;
}

// TODO(lingbin): Currently this function does not include the size of various indexes,
// We should make this more precise.
// NOTE: This function will be called when any row of data is added, so we need to
// make this function efficient.
uint64_t SegmentWriter::estimate_segment_size() {
    // footer_size(4) + checksum(4) + segment_magic(4)
    uint64_t size = 12;
    for (auto& column_writer : _column_writers) {
        size += column_writer->estimate_buffer_size();
    }
    if (_is_mow_with_cluster_key()) {
        size += _primary_key_index_builder->size() + _short_key_index_builder->size();
    } else if (_is_mow()) {
        size += _primary_key_index_builder->size();
    } else {
        size += _short_key_index_builder->size();
    }

    // update the mem_tracker of segment size
    _mem_tracker->consume(size - _mem_tracker->consumption());
    return size;
}

Status SegmentWriter::finalize_columns_data() {
    if (_has_key) {
        _row_count = _num_rows_written;
    } else {
        DCHECK(_row_count == _num_rows_written)
                << "_row_count != _num_rows_written:" << _row_count << " vs. " << _num_rows_written;
        if (_row_count != _num_rows_written) {
            std::stringstream ss;
            ss << "_row_count != _num_rows_written:" << _row_count << " vs. " << _num_rows_written;
            LOG(WARNING) << ss.str();
            return Status::InternalError(ss.str());
        }
    }
    _num_rows_written = 0;

    for (auto& column_writer : _column_writers) {
        RETURN_IF_ERROR(column_writer->finish());
    }
    RETURN_IF_ERROR(_write_data());

    return Status::OK();
}

Status SegmentWriter::finalize_columns_index(uint64_t* index_size) {
    uint64_t index_start = _file_writer->bytes_appended();
    RETURN_IF_ERROR(_write_ordinal_index());
    RETURN_IF_ERROR(_write_zone_map());
    RETURN_IF_ERROR(_write_inverted_index());
    RETURN_IF_ERROR(_write_ann_index());
    RETURN_IF_ERROR(_write_bloom_filter_index());

    *index_size = _file_writer->bytes_appended() - index_start;
    if (_has_key) {
        if (_is_mow_with_cluster_key()) {
            // 1. sort primary keys
            std::sort(_primary_keys.begin(), _primary_keys.end());
            // 2. write primary keys index
            std::string last_key;
            for (const auto& key : _primary_keys) {
                DCHECK(key.compare(last_key) > 0)
                        << "found duplicate key or key is not sorted! current key: " << key
                        << ", last key: " << last_key;
                RETURN_IF_ERROR(_primary_key_index_builder->add_item(key));
                last_key = key;
            }

            RETURN_IF_ERROR(_write_short_key_index());
            *index_size = _file_writer->bytes_appended() - index_start;
            RETURN_IF_ERROR(_write_primary_key_index());
            *index_size += _primary_key_index_builder->disk_size();
        } else if (_is_mow()) {
            RETURN_IF_ERROR(_write_primary_key_index());
            // IndexedColumnWriter write data pages mixed with segment data, we should use
            // the stat from primary key index builder.
            *index_size += _primary_key_index_builder->disk_size();
        } else {
            RETURN_IF_ERROR(_write_short_key_index());
            *index_size = _file_writer->bytes_appended() - index_start;
        }
    }
    // reset all column writers and data_conveter
    clear();

    return Status::OK();
}

Status SegmentWriter::finalize_footer(uint64_t* segment_file_size) {
    RETURN_IF_ERROR(_write_footer());
    // finish
    RETURN_IF_ERROR(_file_writer->close(true));
    *segment_file_size = _file_writer->bytes_appended();
    if (*segment_file_size == 0) {
        return Status::Corruption("Bad segment, file size = 0");
    }
    return Status::OK();
}

Status SegmentWriter::finalize(uint64_t* segment_file_size, uint64_t* index_size) {
    MonotonicStopWatch timer;
    timer.start();
    // check disk capacity
    if (_data_dir != nullptr && _data_dir->reach_capacity_limit((int64_t)estimate_segment_size())) {
        return Status::Error<DISK_REACH_CAPACITY_LIMIT>("disk {} exceed capacity limit, path: {}",
                                                        _data_dir->path_hash(), _data_dir->path());
    }
    // write data
    RETURN_IF_ERROR(finalize_columns_data());
    // Get the index start before finalize_footer since this function would write new data.
    uint64_t index_start = _file_writer->bytes_appended();
    // write index
    RETURN_IF_ERROR(finalize_columns_index(index_size));
    // write footer
    RETURN_IF_ERROR(finalize_footer(segment_file_size));

    if (timer.elapsed_time() > 5000000000l) {
        LOG(INFO) << "segment flush consumes a lot time_ns " << timer.elapsed_time()
                  << ", segmemt_size " << *segment_file_size;
    }
    // When the cache type is not ttl(expiration time == 0), the data should be split into normal cache queue
    // and index cache queue
    if (auto* cache_builder = _file_writer->cache_builder(); cache_builder != nullptr &&
                                                             cache_builder->_expiration_time == 0 &&
                                                             config::is_cloud_mode()) {
        auto size = *index_size + *segment_file_size;
        auto holder = cache_builder->allocate_cache_holder(index_start, size, _tablet->tablet_id());
        for (auto& segment : holder->file_blocks) {
            static_cast<void>(segment->change_cache_type(io::FileCacheType::INDEX));
        }
    }
    return Status::OK();
}

void SegmentWriter::clear() {
    for (auto& column_writer : _column_writers) {
        column_writer.reset();
    }
    _column_writers.clear();
    _column_ids.clear();
    _olap_data_convertor.reset();
}

// write column data to file one by one
Status SegmentWriter::_write_data() {
    for (auto& column_writer : _column_writers) {
        RETURN_IF_ERROR(column_writer->write_data());

        auto* column_meta = column_writer->get_column_meta();
        DCHECK(column_meta != nullptr);
        column_meta->set_compressed_data_bytes(
                (column_meta->has_compressed_data_bytes() ? column_meta->compressed_data_bytes()
                                                          : 0) +
                column_writer->get_total_compressed_data_pages_bytes());
        column_meta->set_uncompressed_data_bytes(
                (column_meta->has_uncompressed_data_bytes() ? column_meta->uncompressed_data_bytes()
                                                            : 0) +
                column_writer->get_total_uncompressed_data_pages_bytes());
        column_meta->set_raw_data_bytes(
                (column_meta->has_raw_data_bytes() ? column_meta->raw_data_bytes() : 0) +
                column_writer->get_raw_data_bytes());
    }
    return Status::OK();
}

// write ordinal index after data has been written
Status SegmentWriter::_write_ordinal_index() {
    for (auto& column_writer : _column_writers) {
        RETURN_IF_ERROR(column_writer->write_ordinal_index());
    }
    return Status::OK();
}

Status SegmentWriter::_write_zone_map() {
    for (auto& column_writer : _column_writers) {
        RETURN_IF_ERROR(column_writer->write_zone_map());
    }
    return Status::OK();
}

Status SegmentWriter::_write_inverted_index() {
    for (auto& column_writer : _column_writers) {
        RETURN_IF_ERROR(column_writer->write_inverted_index());
    }
    return Status::OK();
}

Status SegmentWriter::_write_ann_index() {
    for (auto& column_writer : _column_writers) {
        RETURN_IF_ERROR(column_writer->write_ann_index());
    }
    return Status::OK();
}

Status SegmentWriter::_write_bloom_filter_index() {
    for (auto& column_writer : _column_writers) {
        RETURN_IF_ERROR(column_writer->write_bloom_filter_index());
    }
    return Status::OK();
}

Status SegmentWriter::_write_short_key_index() {
    std::vector<Slice> body;
    PageFooterPB footer;
    RETURN_IF_ERROR(_short_key_index_builder->finalize(_row_count, &body, &footer));
    PagePointer pp;
    // short key index page is not compressed right now
    RETURN_IF_ERROR(PageIO::write_page(_file_writer, body, footer, &pp));
    pp.to_proto(_footer.mutable_short_key_index_page());
    return Status::OK();
}

Status SegmentWriter::_write_primary_key_index() {
    CHECK_EQ(_primary_key_index_builder->num_rows(), _row_count);
    return _primary_key_index_builder->finalize(_footer.mutable_primary_key_index_meta());
}

Status SegmentWriter::_write_footer() {
    _footer.set_num_rows(_row_count);
    // Decide whether to externalize ColumnMetaPB by tablet default, and stamp footer version
    if (_tablet_schema->is_external_segment_column_meta_used()) {
        _footer.set_version(SEGMENT_FOOTER_VERSION_V3_EXT_COL_META);
        VLOG_DEBUG << "use external column meta";
        // External ColumnMetaPB writing (optional)
        RETURN_IF_ERROR(ExternalColMetaUtil::write_external_column_meta(
                _file_writer, &_footer, _opts.compression_type,
                [this](const std::vector<Slice>& slices) { return _write_raw_data(slices); }));
    }

    // Footer := SegmentFooterPB, FooterPBSize(4), FooterPBChecksum(4), MagicNumber(4)
    std::string footer_buf;
    VLOG_DEBUG << "footer " << _footer.DebugString();
    if (!_footer.SerializeToString(&footer_buf)) {
        return Status::InternalError("failed to serialize segment footer");
    }

    faststring fixed_buf;
    // footer's size
    put_fixed32_le(&fixed_buf, cast_set<uint32_t>(footer_buf.size()));
    // footer's checksum
    uint32_t checksum = crc32c::Crc32c(footer_buf.data(), footer_buf.size());
    put_fixed32_le(&fixed_buf, checksum);
    // Append magic number. we don't write magic number in the header because
    // that will need an extra seek when reading
    fixed_buf.append(k_segment_magic, k_segment_magic_length);

    std::vector<Slice> slices {footer_buf, fixed_buf};
    return _write_raw_data(slices);
}

Status SegmentWriter::_write_raw_data(const std::vector<Slice>& slices) {
    RETURN_IF_ERROR(_file_writer->appendv(&slices[0], slices.size()));
    return Status::OK();
}

Slice SegmentWriter::min_encoded_key() {
    return (_primary_key_index_builder == nullptr) ? Slice(_min_key.data(), _min_key.size())
                                                   : _primary_key_index_builder->min_key();
}
Slice SegmentWriter::max_encoded_key() {
    return (_primary_key_index_builder == nullptr) ? Slice(_max_key.data(), _max_key.size())
                                                   : _primary_key_index_builder->max_key();
}

void SegmentWriter::set_min_max_key(const Slice& key) {
    if (UNLIKELY(_is_first_row)) {
        _min_key.append(key.get_data(), key.get_size());
        _is_first_row = false;
    }
    if (key.compare(_max_key) > 0) {
        _max_key.clear();
        _max_key.append(key.get_data(), key.get_size());
    }
}

void SegmentWriter::set_min_key(const Slice& key) {
    if (UNLIKELY(_is_first_row)) {
        _min_key.append(key.get_data(), key.get_size());
        _is_first_row = false;
    }
}

void SegmentWriter::set_max_key(const Slice& key) {
    _max_key.clear();
    _max_key.append(key.get_data(), key.get_size());
}

void SegmentWriter::set_mow_context(std::shared_ptr<MowContext> mow_context) {
    _mow_context = mow_context;
}

Status SegmentWriter::_generate_primary_key_index(
        const std::vector<const KeyCoder*>& primary_key_coders,
        const std::vector<IOlapColumnDataAccessor*>& primary_key_columns,
        IOlapColumnDataAccessor* seq_column, size_t num_rows, bool need_sort) {
    if (!need_sort) { // mow table without cluster key
        std::string last_key;
        for (size_t pos = 0; pos < num_rows; pos++) {
            // use _key_coders
            std::string key = _full_encode_keys(primary_key_columns, pos);
            _maybe_invalid_row_cache(key);
            if (_tablet_schema->has_sequence_col()) {
                _encode_seq_column(seq_column, pos, &key);
            }
            DCHECK(key.compare(last_key) > 0)
                    << "found duplicate key or key is not sorted! current key: " << key
                    << ", last key: " << last_key;
            RETURN_IF_ERROR(_primary_key_index_builder->add_item(key));
            last_key = std::move(key);
        }
    } else { // mow table with cluster key
        // generate primary keys in memory
        for (uint32_t pos = 0; pos < num_rows; pos++) {
            std::string key = _full_encode_keys(primary_key_coders, primary_key_columns, pos);
            _maybe_invalid_row_cache(key);
            if (_tablet_schema->has_sequence_col()) {
                _encode_seq_column(seq_column, pos, &key);
            }
            _encode_rowid(pos + _num_rows_written, &key);
            _primary_keys_size += key.size();
            _primary_keys.emplace_back(std::move(key));
        }
    }
    return Status::OK();
}

Status SegmentWriter::_generate_short_key_index(std::vector<IOlapColumnDataAccessor*>& key_columns,
                                                size_t num_rows,
                                                const std::vector<size_t>& short_key_pos) {
    // use _key_coders
    set_min_key(_full_encode_keys(key_columns, 0));
    set_max_key(_full_encode_keys(key_columns, num_rows - 1));
    DCHECK(Slice(_max_key.data(), _max_key.size())
                   .compare(Slice(_min_key.data(), _min_key.size())) >= 0)
            << "key is not sorted! min key: " << _min_key << ", max key: " << _max_key;

    key_columns.resize(_num_short_key_columns);
    std::string last_key;
    for (const auto pos : short_key_pos) {
        std::string key = _encode_keys(key_columns, pos);
        DCHECK(key.compare(last_key) >= 0)
                << "key is not sorted! current key: " << key << ", last key: " << last_key;
        RETURN_IF_ERROR(_short_key_index_builder->add_item(key));
        last_key = std::move(key);
    }
    return Status::OK();
}

inline bool SegmentWriter::_is_mow() {
    return _tablet_schema->keys_type() == UNIQUE_KEYS && _opts.enable_unique_key_merge_on_write;
}

inline bool SegmentWriter::_is_mow_with_cluster_key() {
    return _is_mow() && !_tablet_schema->cluster_key_uids().empty();
}

} // namespace segment_v2
} // namespace doris

Coverage Report

Created: 2026-05-14 23:40