// 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.

#pragma once

#include <pdqsort.h>

#include <algorithm>

#include <cmath>

#include <queue>

#include "udf/udf.h"

#include "vec/common/pod_array.h"

#include "vec/common/string_buffer.hpp"

#include "vec/io/io_helper.h"

namespace doris {

class OldCounts {

public:

    OldCounts() = default;

    inline void merge(const OldCounts* other) {

        if (other == nullptr || other->_counts.empty()) {

            return;

        }

        for (auto& cell : other->_counts) {

            increment(cell.first, cell.second);

        }

    }

    void increment(int64_t key, uint32_t i) {

        auto item = _counts.find(key);

        if (item != _counts.end()) {

            item->second += i;

        } else {

            _counts.emplace(std::make_pair(key, i));

        }

    }

    uint32_t serialized_size() const {

        return sizeof(uint32_t) + sizeof(int64_t) * _counts.size() +

               sizeof(uint32_t) * _counts.size();

    }

    void serialize(uint8_t* writer) const {

        uint32_t size = _counts.size();

        memcpy(writer, &size, sizeof(uint32_t));

        writer += sizeof(uint32_t);

        for (auto& cell : _counts) {

            memcpy(writer, &cell.first, sizeof(int64_t));

            writer += sizeof(int64_t);

            memcpy(writer, &cell.second, sizeof(uint32_t));

            writer += sizeof(uint32_t);

        }

    }

    void unserialize(const uint8_t* type_reader) {

        uint32_t size;

        memcpy(&size, type_reader, sizeof(uint32_t));

        type_reader += sizeof(uint32_t);

        for (uint32_t i = 0; i < size; ++i) {

            int64_t key;

            uint32_t count;

            memcpy(&key, type_reader, sizeof(int64_t));

            type_reader += sizeof(int64_t);

            memcpy(&count, type_reader, sizeof(uint32_t));

            type_reader += sizeof(uint32_t);

            _counts.emplace(std::make_pair(key, count));

        }

    }

    double get_percentile(std::vector<std::pair<int64_t, uint32_t>>& counts,

                          double position) const {

        long lower = long(std::floor(position));

        long higher = long(std::ceil(position));

        auto iter = counts.begin();

        for (; iter != counts.end() && iter->second < lower + 1; ++iter)

            ;

        int64_t lower_key = iter->first;

        if (higher == lower) {

            return lower_key;

        }

        if (iter->second < higher + 1) {

            iter++;

        }

        int64_t higher_key = iter->first;

        if (lower_key == higher_key) {

            return lower_key;

        }

        return (higher - position) * lower_key + (position - lower) * higher_key;

    }

    double terminate(double quantile) const {

        if (_counts.empty()) {

            // Although set null here, but the value is 0.0 and the call method just

            // get val in aggregate_function_percentile_approx.h

            return 0.0;

        }

        std::vector<std::pair<int64_t, uint32_t>> elems(_counts.begin(), _counts.end());

        sort(elems.begin(), elems.end(),

             [](const std::pair<int64_t, uint32_t> l, const std::pair<int64_t, uint32_t> r) {

                 return l.first < r.first;

             });

        long total = 0;

        for (auto& cell : elems) {

            total += cell.second;

            cell.second = total;

        }

        long max_position = total - 1;

        double position = max_position * quantile;

        return get_percentile(elems, position);

    }

private:

    std::unordered_map<int64_t, uint32_t> _counts;

};

template <typename Ty>

class Counts {

public:

    Counts() = default;

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    Counts() = default;

Unexecuted instantiation: _ZN5doris6CountsIhEC2Ev

Unexecuted instantiation: _ZN5doris6CountsIaEC2Ev

Unexecuted instantiation: _ZN5doris6CountsIsEC2Ev

Unexecuted instantiation: _ZN5doris6CountsIiEC2Ev

Unexecuted instantiation: _ZN5doris6CountsInEC2Ev

Unexecuted instantiation: _ZN5doris6CountsIfEC2Ev

Unexecuted instantiation: _ZN5doris6CountsIdEC2Ev

    void merge(Counts* other) {

        if (other != nullptr && !other->_nums.empty()) {

            _sorted_nums_vec.emplace_back(std::move(other->_nums));

        }

    }

_ZN5doris6CountsIlE5mergeEPS1_

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146

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    void merge(Counts* other) {

147

2

        if (other != nullptr && !other->_nums.empty()) {

148

2

            _sorted_nums_vec.emplace_back(std::move(other->_nums));

149

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        }

150

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    }

Unexecuted instantiation: _ZN5doris6CountsIhE5mergeEPS1_

Unexecuted instantiation: _ZN5doris6CountsIaE5mergeEPS1_

Unexecuted instantiation: _ZN5doris6CountsIsE5mergeEPS1_

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Unexecuted instantiation: _ZN5doris6CountsIdE5mergeEPS1_

    void increment(Ty key, uint32_t i) {

        auto old_size = _nums.size();

        _nums.resize(_nums.size() + i);

        for (uint32_t j = 0; j < i; ++j) {

            _nums[old_size + j] = key;

        }

    }

    void increment(Ty key) { _nums.push_back(key); }

Unexecuted instantiation: _ZN5doris6CountsIhE9incrementEh

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Unexecuted instantiation: _ZN5doris6CountsIiE9incrementEi

Unexecuted instantiation: _ZN5doris6CountsIlE9incrementEl

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Unexecuted instantiation: _ZN5doris6CountsIfE9incrementEf

Unexecuted instantiation: _ZN5doris6CountsIdE9incrementEd

    void increment_batch(const vectorized::PaddedPODArray<Ty>& keys) {

        _nums.insert(keys.begin(), keys.end());

    }

Unexecuted instantiation: _ZN5doris6CountsIhE15increment_batchERKNS_10vectorized8PODArrayIhLm4096E9AllocatorILb0ELb0ELb0E22DefaultMemoryAllocatorELm16ELm15EEE

Unexecuted instantiation: _ZN5doris6CountsIaE15increment_batchERKNS_10vectorized8PODArrayIaLm4096E9AllocatorILb0ELb0ELb0E22DefaultMemoryAllocatorELm16ELm15EEE

Unexecuted instantiation: _ZN5doris6CountsIsE15increment_batchERKNS_10vectorized8PODArrayIsLm4096E9AllocatorILb0ELb0ELb0E22DefaultMemoryAllocatorELm16ELm15EEE

Unexecuted instantiation: _ZN5doris6CountsIiE15increment_batchERKNS_10vectorized8PODArrayIiLm4096E9AllocatorILb0ELb0ELb0E22DefaultMemoryAllocatorELm16ELm15EEE

Unexecuted instantiation: _ZN5doris6CountsIlE15increment_batchERKNS_10vectorized8PODArrayIlLm4096E9AllocatorILb0ELb0ELb0E22DefaultMemoryAllocatorELm16ELm15EEE

Unexecuted instantiation: _ZN5doris6CountsInE15increment_batchERKNS_10vectorized8PODArrayInLm4096E9AllocatorILb0ELb0ELb0E22DefaultMemoryAllocatorELm16ELm15EEE

Unexecuted instantiation: _ZN5doris6CountsIfE15increment_batchERKNS_10vectorized8PODArrayIfLm4096E9AllocatorILb0ELb0ELb0E22DefaultMemoryAllocatorELm16ELm15EEE

Unexecuted instantiation: _ZN5doris6CountsIdE15increment_batchERKNS_10vectorized8PODArrayIdLm4096E9AllocatorILb0ELb0ELb0E22DefaultMemoryAllocatorELm16ELm15EEE

    void serialize(vectorized::BufferWritable& buf) {

        if (!_nums.empty()) {

            pdqsort(_nums.begin(), _nums.end());

            size_t size = _nums.size();

            write_binary(size, buf);

            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);

        } else {

            // convert _sorted_nums_vec to _nums and do seiralize again

            _convert_sorted_num_vec_to_nums();

            serialize(buf);

        }

    }

_ZN5doris6CountsIlE9serializeERNS_10vectorized14BufferWritableE

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166

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    void serialize(vectorized::BufferWritable& buf) {

167

2

        if (!_nums.empty()) {

168

2

            pdqsort(_nums.begin(), _nums.end());

169

2

            size_t size = _nums.size();

170

2

            write_binary(size, buf);

171

2

            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);

172

2

        } else {

173

            // convert _sorted_nums_vec to _nums and do seiralize again

174

0

            _convert_sorted_num_vec_to_nums();

175

0

            serialize(buf);

176

0

        }

177

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    }

Unexecuted instantiation: _ZN5doris6CountsIhE9serializeERNS_10vectorized14BufferWritableE

Unexecuted instantiation: _ZN5doris6CountsIaE9serializeERNS_10vectorized14BufferWritableE

Unexecuted instantiation: _ZN5doris6CountsIsE9serializeERNS_10vectorized14BufferWritableE

Unexecuted instantiation: _ZN5doris6CountsIiE9serializeERNS_10vectorized14BufferWritableE

Unexecuted instantiation: _ZN5doris6CountsInE9serializeERNS_10vectorized14BufferWritableE

Unexecuted instantiation: _ZN5doris6CountsIfE9serializeERNS_10vectorized14BufferWritableE

Unexecuted instantiation: _ZN5doris6CountsIdE9serializeERNS_10vectorized14BufferWritableE

    void unserialize(vectorized::BufferReadable& buf) {

        size_t size;

        read_binary(size, buf);

        _nums.resize(size);

        auto buff = buf.read(sizeof(Ty) * size);

        memcpy(_nums.data(), buff.data, buff.size);

    }

_ZN5doris6CountsIlE11unserializeERNS_10vectorized14BufferReadableE

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    void unserialize(vectorized::BufferReadable& buf) {

180

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        size_t size;

181

2

        read_binary(size, buf);

182

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        _nums.resize(size);

183

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        auto buff = buf.read(sizeof(Ty) * size);

184

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        memcpy(_nums.data(), buff.data, buff.size);

185

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    }

Unexecuted instantiation: _ZN5doris6CountsIhE11unserializeERNS_10vectorized14BufferReadableE

Unexecuted instantiation: _ZN5doris6CountsIaE11unserializeERNS_10vectorized14BufferReadableE

Unexecuted instantiation: _ZN5doris6CountsIsE11unserializeERNS_10vectorized14BufferReadableE

Unexecuted instantiation: _ZN5doris6CountsIiE11unserializeERNS_10vectorized14BufferReadableE

Unexecuted instantiation: _ZN5doris6CountsInE11unserializeERNS_10vectorized14BufferReadableE

Unexecuted instantiation: _ZN5doris6CountsIfE11unserializeERNS_10vectorized14BufferReadableE

Unexecuted instantiation: _ZN5doris6CountsIdE11unserializeERNS_10vectorized14BufferReadableE

    double terminate(double quantile) {

        if (_sorted_nums_vec.size() <= 1) {

            if (_sorted_nums_vec.size() == 1) {

                _nums = std::move(_sorted_nums_vec[0]);

            }

            if (_nums.empty()) {

                // Although set null here, but the value is 0.0 and the call method just

                // get val in aggregate_function_percentile_approx.h

                return 0.0;

            }

            if (quantile == 1 || _nums.size() == 1) {

                return _nums.back();

            }

            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {

                pdqsort(_nums.begin(), _nums.end());

            }

            double u = (_nums.size() - 1) * quantile;

            auto index = static_cast<uint32_t>(u);

            return _nums[index] +

                   (u - static_cast<double>(index)) * (_nums[index + 1] - _nums[index]);

        } else {

            DCHECK(_nums.empty());

            size_t rows = 0;

            for (const auto& i : _sorted_nums_vec) {

                rows += i.size();

            }

            const bool reverse = quantile > 0.5 && rows > 2;

            double u = (rows - 1) * quantile;

            auto index = static_cast<uint32_t>(u);

            // if reverse, the step of target should start 0 like not reverse

            // so here rows need to minus index + 2

            // eg: rows = 10, index = 5

            // if not reverse, so the first number loc is 5, the second number loc is 6

            // if reverse, so the second number is 3, the first number is 4

            // 5 + 4 = 3 + 6 = 9 = rows - 1.

            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2

            size_t target = reverse ? rows - index - 2 : index;

            if (quantile == 1) {

                target = 0;

            }

            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);

            if (quantile == 1) {

                return second_number;

            }

            return first_number + (u - static_cast<double>(index)) * (second_number - first_number);

        }

    }

_ZN5doris6CountsIlE9terminateEd

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187

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    double terminate(double quantile) {

188

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        if (_sorted_nums_vec.size() <= 1) {

189

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            if (_sorted_nums_vec.size() == 1) {

190

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                _nums = std::move(_sorted_nums_vec[0]);

191

0

            }

192

193

2

            if (_nums.empty()) {

194

                // Although set null here, but the value is 0.0 and the call method just

195

                // get val in aggregate_function_percentile_approx.h

196

0

                return 0.0;

197

0

            }

198

2

            if (quantile == 1 || _nums.size() == 1) {

199

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                return _nums.back();

200

0

            }

201

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            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {

202

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                pdqsort(_nums.begin(), _nums.end());

203

1

            }

204

205

2

            double u = (_nums.size() - 1) * quantile;

206

2

            auto index = static_cast<uint32_t>(u);

207

2

            return _nums[index] +

208

2

                   (u - static_cast<double>(index)) * (_nums[index + 1] - _nums[index]);

209

2

        } else {

210

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            DCHECK(_nums.empty());

211

1

            size_t rows = 0;

212

2

            for (const auto& i : _sorted_nums_vec) {

213

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                rows += i.size();

214

2

            }

215

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            const bool reverse = quantile > 0.5 && rows > 2;

216

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            double u = (rows - 1) * quantile;

217

1

            auto index = static_cast<uint32_t>(u);

218

            // if reverse, the step of target should start 0 like not reverse

219

            // so here rows need to minus index + 2

220

            // eg: rows = 10, index = 5

221

            // if not reverse, so the first number loc is 5, the second number loc is 6

222

            // if reverse, so the second number is 3, the first number is 4

223

            // 5 + 4 = 3 + 6 = 9 = rows - 1.

224

            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2

225

1

            size_t target = reverse ? rows - index - 2 : index;

226

1

            if (quantile == 1) {

227

0

                target = 0;

228

0

            }

229

1

            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);

230

1

            if (quantile == 1) {

231

0

                return second_number;

232

0

            }

233

1

            return first_number + (u - static_cast<double>(index)) * (second_number - first_number);

234

1

        }

235

3

    }

Unexecuted instantiation: _ZN5doris6CountsIhE9terminateEd

Unexecuted instantiation: _ZN5doris6CountsIaE9terminateEd

Unexecuted instantiation: _ZN5doris6CountsIsE9terminateEd

Unexecuted instantiation: _ZN5doris6CountsIiE9terminateEd

Unexecuted instantiation: _ZN5doris6CountsInE9terminateEd

Unexecuted instantiation: _ZN5doris6CountsIfE9terminateEd

Unexecuted instantiation: _ZN5doris6CountsIdE9terminateEd

private:

    struct Node {

        Ty value;

        int array_index;

        int64_t element_index;

        auto operator<=>(const Node& other) const { return value <=> other.value; }

_ZNK5doris6CountsIlE4NodessERKS2_

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        auto operator<=>(const Node& other) const { return value <=> other.value; }

Unexecuted instantiation: _ZNK5doris6CountsIhE4NodessERKS2_

Unexecuted instantiation: _ZNK5doris6CountsIaE4NodessERKS2_

Unexecuted instantiation: _ZNK5doris6CountsIsE4NodessERKS2_

Unexecuted instantiation: _ZNK5doris6CountsIiE4NodessERKS2_

Unexecuted instantiation: _ZNK5doris6CountsInE4NodessERKS2_

Unexecuted instantiation: _ZNK5doris6CountsIfE4NodessERKS2_

Unexecuted instantiation: _ZNK5doris6CountsIdE4NodessERKS2_

    };

    void _convert_sorted_num_vec_to_nums() {

        size_t rows = 0;

        for (const auto& i : _sorted_nums_vec) {

            rows += i.size();

        }

        _nums.resize(rows);

        size_t count = 0;

        std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;

        for (int i = 0; i < _sorted_nums_vec.size(); ++i) {

            if (!_sorted_nums_vec[i].empty()) {

                min_heap.emplace(_sorted_nums_vec[i][0], i, 0);

            }

        }

        while (!min_heap.empty()) {

            Node node = min_heap.top();

            min_heap.pop();

            _nums[count++] = node.value;

            if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {

                node.value = _sorted_nums_vec[node.array_index][node.element_index];

                min_heap.push(node);

            }

        }

        _sorted_nums_vec.clear();

    }

Unexecuted instantiation: _ZN5doris6CountsIlE31_convert_sorted_num_vec_to_numsEv

Unexecuted instantiation: _ZN5doris6CountsIhE31_convert_sorted_num_vec_to_numsEv

Unexecuted instantiation: _ZN5doris6CountsIaE31_convert_sorted_num_vec_to_numsEv

Unexecuted instantiation: _ZN5doris6CountsIsE31_convert_sorted_num_vec_to_numsEv

Unexecuted instantiation: _ZN5doris6CountsIiE31_convert_sorted_num_vec_to_numsEv

Unexecuted instantiation: _ZN5doris6CountsInE31_convert_sorted_num_vec_to_numsEv

Unexecuted instantiation: _ZN5doris6CountsIfE31_convert_sorted_num_vec_to_numsEv

Unexecuted instantiation: _ZN5doris6CountsIdE31_convert_sorted_num_vec_to_numsEv

    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {

        Ty first_number = 0, second_number = 0;

        size_t count = 0;

        if (reverse) {

            std::priority_queue<Node> max_heap;

            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {

                if (!_sorted_nums_vec[i].empty()) {

                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,

                                     _sorted_nums_vec[i].size() - 1);

                }

            }

            while (!max_heap.empty()) {

                Node node = max_heap.top();

                max_heap.pop();

                if (count == target) {

                    second_number = node.value;

                } else if (count == target + 1) {

                    first_number = node.value;

                    break;

                }

                ++count;

                if (--node.element_index >= 0) {

                    node.value = _sorted_nums_vec[node.array_index][node.element_index];

                    max_heap.push(node);

                }

            }

        } else {

            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;

            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {

                if (!_sorted_nums_vec[i].empty()) {

                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);

                }

            }

            while (!min_heap.empty()) {

                Node node = min_heap.top();

                min_heap.pop();

                if (count == target) {

                    first_number = node.value;

                } else if (count == target + 1) {

                    second_number = node.value;

                    break;

                }

                ++count;

                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {

                    node.value = _sorted_nums_vec[node.array_index][node.element_index];

                    min_heap.push(node);

                }

            }

        }

        return {first_number, second_number};

    }

_ZN5doris6CountsIlE27_merge_sort_and_get_numbersElb

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273

1

    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {

274

1

        Ty first_number = 0, second_number = 0;

275

1

        size_t count = 0;

276

1

        if (reverse) {

277

0

            std::priority_queue<Node> max_heap;

278

0

            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {

279

0

                if (!_sorted_nums_vec[i].empty()) {

280

0

                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,

281

0

                                     _sorted_nums_vec[i].size() - 1);

282

0

                }

283

0

            }

284

285

0

            while (!max_heap.empty()) {

286

0

                Node node = max_heap.top();

287

0

                max_heap.pop();

288

0

                if (count == target) {

289

0

                    second_number = node.value;

290

0

                } else if (count == target + 1) {

291

0

                    first_number = node.value;

292

0

                    break;

293

0

                }

294

0

                ++count;

295

0

                if (--node.element_index >= 0) {

296

0

                    node.value = _sorted_nums_vec[node.array_index][node.element_index];

297

0

                    max_heap.push(node);

298

0

                }

299

0

            }

300

301

1

        } else {

302

1

            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;

303

3

            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {

304

2

                if (!_sorted_nums_vec[i].empty()) {

305

2

                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);

306

2

                }

307

2

            }

308

309

7

            while (!min_heap.empty()) {

310

7

                Node node = min_heap.top();

311

7

                min_heap.pop();

312

7

                if (count == target) {

313

1

                    first_number = node.value;

314

6

                } else if (count == target + 1) {

315

1

                    second_number = node.value;

316

1

                    break;

317

1

                }

318

6

                ++count;

319

6

                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {

320

6

                    node.value = _sorted_nums_vec[node.array_index][node.element_index];

321

6

                    min_heap.push(node);

322

6

                }

323

6

            }

324

1

        }

325

326

1

        return {first_number, second_number};

327

1

    }

Unexecuted instantiation: _ZN5doris6CountsIhE27_merge_sort_and_get_numbersElb

Unexecuted instantiation: _ZN5doris6CountsIaE27_merge_sort_and_get_numbersElb

Unexecuted instantiation: _ZN5doris6CountsIsE27_merge_sort_and_get_numbersElb

Unexecuted instantiation: _ZN5doris6CountsIiE27_merge_sort_and_get_numbersElb

Unexecuted instantiation: _ZN5doris6CountsInE27_merge_sort_and_get_numbersElb

Unexecuted instantiation: _ZN5doris6CountsIfE27_merge_sort_and_get_numbersElb

Unexecuted instantiation: _ZN5doris6CountsIdE27_merge_sort_and_get_numbersElb

    vectorized::PODArray<Ty> _nums;

    std::vector<vectorized::PODArray<Ty>> _sorted_nums_vec;

};

} // namespace doris