Coverage Report

Created: 2026-07-08 04:47

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/root/doris/be/src/util/counts.h
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// Licensed to the Apache Software Foundation (ASF) under one
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// or more contributor license agreements.  See the NOTICE file
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// distributed with this work for additional information
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// regarding copyright ownership.  The ASF licenses this file
5
// to you under the Apache License, Version 2.0 (the
6
// "License"); you may not use this file except in compliance
7
// with the License.  You may obtain a copy of the License at
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//
9
//   http://www.apache.org/licenses/LICENSE-2.0
10
//
11
// Unless required by applicable law or agreed to in writing,
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// software distributed under the License is distributed on an
13
// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
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// KIND, either express or implied.  See the License for the
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// specific language governing permissions and limitations
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// under the License.
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18
#pragma once
19
20
#include <pdqsort.h>
21
22
#include <algorithm>
23
#include <cmath>
24
#include <queue>
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26
#include "vec/common/pod_array.h"
27
#include "vec/common/string_buffer.hpp"
28
#include "vec/io/io_helper.h"
29
30
namespace doris {
31
32
template <typename Ty>
33
class Counts {
34
public:
35
3.58k
    Counts() = default;
_ZN5doris6CountsIaEC2Ev
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35
45
    Counts() = default;
_ZN5doris6CountsIsEC2Ev
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35
215
    Counts() = default;
_ZN5doris6CountsIiEC2Ev
Line
Count
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35
2.20k
    Counts() = default;
_ZN5doris6CountsIlEC2Ev
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35
831
    Counts() = default;
_ZN5doris6CountsInEC2Ev
Line
Count
Source
35
41
    Counts() = default;
_ZN5doris6CountsIfEC2Ev
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Count
Source
35
11
    Counts() = default;
_ZN5doris6CountsIdEC2Ev
Line
Count
Source
35
242
    Counts() = default;
36
37
1.27k
    void merge(Counts* other) {
38
1.27k
        if (other != nullptr && !other->_nums.empty()) {
39
1.27k
            _sorted_nums_vec.emplace_back(std::move(other->_nums));
40
1.27k
        }
41
1.27k
    }
_ZN5doris6CountsIaE5mergeEPS1_
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37
4
    void merge(Counts* other) {
38
4
        if (other != nullptr && !other->_nums.empty()) {
39
4
            _sorted_nums_vec.emplace_back(std::move(other->_nums));
40
4
        }
41
4
    }
_ZN5doris6CountsIsE5mergeEPS1_
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37
16
    void merge(Counts* other) {
38
16
        if (other != nullptr && !other->_nums.empty()) {
39
16
            _sorted_nums_vec.emplace_back(std::move(other->_nums));
40
16
        }
41
16
    }
_ZN5doris6CountsIiE5mergeEPS1_
Line
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Source
37
821
    void merge(Counts* other) {
38
821
        if (other != nullptr && !other->_nums.empty()) {
39
821
            _sorted_nums_vec.emplace_back(std::move(other->_nums));
40
821
        }
41
821
    }
_ZN5doris6CountsIlE5mergeEPS1_
Line
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37
348
    void merge(Counts* other) {
38
348
        if (other != nullptr && !other->_nums.empty()) {
39
348
            _sorted_nums_vec.emplace_back(std::move(other->_nums));
40
348
        }
41
348
    }
_ZN5doris6CountsInE5mergeEPS1_
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37
4
    void merge(Counts* other) {
38
4
        if (other != nullptr && !other->_nums.empty()) {
39
4
            _sorted_nums_vec.emplace_back(std::move(other->_nums));
40
4
        }
41
4
    }
_ZN5doris6CountsIfE5mergeEPS1_
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37
4
    void merge(Counts* other) {
38
4
        if (other != nullptr && !other->_nums.empty()) {
39
4
            _sorted_nums_vec.emplace_back(std::move(other->_nums));
40
4
        }
41
4
    }
_ZN5doris6CountsIdE5mergeEPS1_
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37
78
    void merge(Counts* other) {
38
78
        if (other != nullptr && !other->_nums.empty()) {
39
78
            _sorted_nums_vec.emplace_back(std::move(other->_nums));
40
78
        }
41
78
    }
42
43
    void increment(Ty key, uint32_t i) {
44
        auto old_size = _nums.size();
45
        _nums.resize(_nums.size() + i);
46
        for (uint32_t j = 0; j < i; ++j) {
47
            _nums[old_size + j] = key;
48
        }
49
    }
50
51
2.92k
    void increment(Ty key) { _nums.push_back(key); }
_ZN5doris6CountsIaE9incrementEa
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51
73
    void increment(Ty key) { _nums.push_back(key); }
_ZN5doris6CountsIsE9incrementEs
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Count
Source
51
552
    void increment(Ty key) { _nums.push_back(key); }
_ZN5doris6CountsIiE9incrementEi
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Source
51
1.59k
    void increment(Ty key) { _nums.push_back(key); }
_ZN5doris6CountsIlE9incrementEl
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51
401
    void increment(Ty key) { _nums.push_back(key); }
_ZN5doris6CountsInE9incrementEn
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51
45
    void increment(Ty key) { _nums.push_back(key); }
_ZN5doris6CountsIfE9incrementEf
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51
9
    void increment(Ty key) { _nums.push_back(key); }
_ZN5doris6CountsIdE9incrementEd
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51
259
    void increment(Ty key) { _nums.push_back(key); }
52
53
5
    void increment_batch(const vectorized::PaddedPODArray<Ty>& keys) {
54
5
        _nums.insert(keys.begin(), keys.end());
55
5
    }
Unexecuted instantiation: _ZN5doris6CountsIaE15increment_batchERKNS_10vectorized8PODArrayIaLm4096ENS_9AllocatorILb0ELb0ELb0ENS_22DefaultMemoryAllocatorELb1EEELm16ELm15EEE
Unexecuted instantiation: _ZN5doris6CountsIsE15increment_batchERKNS_10vectorized8PODArrayIsLm4096ENS_9AllocatorILb0ELb0ELb0ENS_22DefaultMemoryAllocatorELb1EEELm16ELm15EEE
Unexecuted instantiation: _ZN5doris6CountsIiE15increment_batchERKNS_10vectorized8PODArrayIiLm4096ENS_9AllocatorILb0ELb0ELb0ENS_22DefaultMemoryAllocatorELb1EEELm16ELm15EEE
_ZN5doris6CountsIlE15increment_batchERKNS_10vectorized8PODArrayIlLm4096ENS_9AllocatorILb0ELb0ELb0ENS_22DefaultMemoryAllocatorELb1EEELm16ELm15EEE
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53
5
    void increment_batch(const vectorized::PaddedPODArray<Ty>& keys) {
54
5
        _nums.insert(keys.begin(), keys.end());
55
5
    }
Unexecuted instantiation: _ZN5doris6CountsInE15increment_batchERKNS_10vectorized8PODArrayInLm4096ENS_9AllocatorILb0ELb0ELb0ENS_22DefaultMemoryAllocatorELb1EEELm16ELm15EEE
Unexecuted instantiation: _ZN5doris6CountsIfE15increment_batchERKNS_10vectorized8PODArrayIfLm4096ENS_9AllocatorILb0ELb0ELb0ENS_22DefaultMemoryAllocatorELb1EEELm16ELm15EEE
Unexecuted instantiation: _ZN5doris6CountsIdE15increment_batchERKNS_10vectorized8PODArrayIdLm4096ENS_9AllocatorILb0ELb0ELb0ENS_22DefaultMemoryAllocatorELb1EEELm16ELm15EEE
56
57
1.64k
    void serialize(vectorized::BufferWritable& buf) {
58
1.64k
        if (!_nums.empty()) {
59
1.35k
            pdqsort(_nums.begin(), _nums.end());
60
1.35k
            size_t size = _nums.size();
61
1.35k
            buf.write_binary(size);
62
1.35k
            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);
63
1.35k
        } else {
64
            // convert _sorted_nums_vec to _nums and do seiralize again
65
288
            _convert_sorted_num_vec_to_nums();
66
288
            serialize(buf);
67
288
        }
68
1.64k
    }
_ZN5doris6CountsIaE9serializeERNS_10vectorized14BufferWritableE
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57
4
    void serialize(vectorized::BufferWritable& buf) {
58
4
        if (!_nums.empty()) {
59
4
            pdqsort(_nums.begin(), _nums.end());
60
4
            size_t size = _nums.size();
61
4
            buf.write_binary(size);
62
4
            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);
63
4
        } else {
64
            // convert _sorted_nums_vec to _nums and do seiralize again
65
0
            _convert_sorted_num_vec_to_nums();
66
0
            serialize(buf);
67
0
        }
68
4
    }
_ZN5doris6CountsIsE9serializeERNS_10vectorized14BufferWritableE
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57
16
    void serialize(vectorized::BufferWritable& buf) {
58
16
        if (!_nums.empty()) {
59
16
            pdqsort(_nums.begin(), _nums.end());
60
16
            size_t size = _nums.size();
61
16
            buf.write_binary(size);
62
16
            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);
63
16
        } else {
64
            // convert _sorted_nums_vec to _nums and do seiralize again
65
0
            _convert_sorted_num_vec_to_nums();
66
0
            serialize(buf);
67
0
        }
68
16
    }
_ZN5doris6CountsIiE9serializeERNS_10vectorized14BufferWritableE
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Source
57
1.05k
    void serialize(vectorized::BufferWritable& buf) {
58
1.05k
        if (!_nums.empty()) {
59
899
            pdqsort(_nums.begin(), _nums.end());
60
899
            size_t size = _nums.size();
61
899
            buf.write_binary(size);
62
899
            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);
63
899
        } else {
64
            // convert _sorted_nums_vec to _nums and do seiralize again
65
156
            _convert_sorted_num_vec_to_nums();
66
156
            serialize(buf);
67
156
        }
68
1.05k
    }
_ZN5doris6CountsIlE9serializeERNS_10vectorized14BufferWritableE
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57
480
    void serialize(vectorized::BufferWritable& buf) {
58
480
        if (!_nums.empty()) {
59
348
            pdqsort(_nums.begin(), _nums.end());
60
348
            size_t size = _nums.size();
61
348
            buf.write_binary(size);
62
348
            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);
63
348
        } else {
64
            // convert _sorted_nums_vec to _nums and do seiralize again
65
132
            _convert_sorted_num_vec_to_nums();
66
132
            serialize(buf);
67
132
        }
68
480
    }
_ZN5doris6CountsInE9serializeERNS_10vectorized14BufferWritableE
Line
Count
Source
57
4
    void serialize(vectorized::BufferWritable& buf) {
58
4
        if (!_nums.empty()) {
59
4
            pdqsort(_nums.begin(), _nums.end());
60
4
            size_t size = _nums.size();
61
4
            buf.write_binary(size);
62
4
            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);
63
4
        } else {
64
            // convert _sorted_nums_vec to _nums and do seiralize again
65
0
            _convert_sorted_num_vec_to_nums();
66
0
            serialize(buf);
67
0
        }
68
4
    }
_ZN5doris6CountsIfE9serializeERNS_10vectorized14BufferWritableE
Line
Count
Source
57
4
    void serialize(vectorized::BufferWritable& buf) {
58
4
        if (!_nums.empty()) {
59
4
            pdqsort(_nums.begin(), _nums.end());
60
4
            size_t size = _nums.size();
61
4
            buf.write_binary(size);
62
4
            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);
63
4
        } else {
64
            // convert _sorted_nums_vec to _nums and do seiralize again
65
0
            _convert_sorted_num_vec_to_nums();
66
0
            serialize(buf);
67
0
        }
68
4
    }
_ZN5doris6CountsIdE9serializeERNS_10vectorized14BufferWritableE
Line
Count
Source
57
78
    void serialize(vectorized::BufferWritable& buf) {
58
78
        if (!_nums.empty()) {
59
78
            pdqsort(_nums.begin(), _nums.end());
60
78
            size_t size = _nums.size();
61
78
            buf.write_binary(size);
62
78
            buf.write(reinterpret_cast<const char*>(_nums.data()), sizeof(Ty) * size);
63
78
        } else {
64
            // convert _sorted_nums_vec to _nums and do seiralize again
65
0
            _convert_sorted_num_vec_to_nums();
66
0
            serialize(buf);
67
0
        }
68
78
    }
69
70
1.27k
    void unserialize(vectorized::BufferReadable& buf) {
71
1.27k
        size_t size;
72
1.27k
        buf.read_binary(size);
73
1.27k
        _nums.resize(size);
74
1.27k
        auto buff = buf.read(sizeof(Ty) * size);
75
1.27k
        memcpy(_nums.data(), buff.data, buff.size);
76
1.27k
    }
_ZN5doris6CountsIaE11unserializeERNS_10vectorized14BufferReadableE
Line
Count
Source
70
4
    void unserialize(vectorized::BufferReadable& buf) {
71
4
        size_t size;
72
4
        buf.read_binary(size);
73
4
        _nums.resize(size);
74
4
        auto buff = buf.read(sizeof(Ty) * size);
75
4
        memcpy(_nums.data(), buff.data, buff.size);
76
4
    }
_ZN5doris6CountsIsE11unserializeERNS_10vectorized14BufferReadableE
Line
Count
Source
70
16
    void unserialize(vectorized::BufferReadable& buf) {
71
16
        size_t size;
72
16
        buf.read_binary(size);
73
16
        _nums.resize(size);
74
16
        auto buff = buf.read(sizeof(Ty) * size);
75
16
        memcpy(_nums.data(), buff.data, buff.size);
76
16
    }
_ZN5doris6CountsIiE11unserializeERNS_10vectorized14BufferReadableE
Line
Count
Source
70
821
    void unserialize(vectorized::BufferReadable& buf) {
71
821
        size_t size;
72
821
        buf.read_binary(size);
73
821
        _nums.resize(size);
74
821
        auto buff = buf.read(sizeof(Ty) * size);
75
821
        memcpy(_nums.data(), buff.data, buff.size);
76
821
    }
_ZN5doris6CountsIlE11unserializeERNS_10vectorized14BufferReadableE
Line
Count
Source
70
348
    void unserialize(vectorized::BufferReadable& buf) {
71
348
        size_t size;
72
348
        buf.read_binary(size);
73
348
        _nums.resize(size);
74
348
        auto buff = buf.read(sizeof(Ty) * size);
75
348
        memcpy(_nums.data(), buff.data, buff.size);
76
348
    }
_ZN5doris6CountsInE11unserializeERNS_10vectorized14BufferReadableE
Line
Count
Source
70
4
    void unserialize(vectorized::BufferReadable& buf) {
71
4
        size_t size;
72
4
        buf.read_binary(size);
73
4
        _nums.resize(size);
74
4
        auto buff = buf.read(sizeof(Ty) * size);
75
4
        memcpy(_nums.data(), buff.data, buff.size);
76
4
    }
_ZN5doris6CountsIfE11unserializeERNS_10vectorized14BufferReadableE
Line
Count
Source
70
4
    void unserialize(vectorized::BufferReadable& buf) {
71
4
        size_t size;
72
4
        buf.read_binary(size);
73
4
        _nums.resize(size);
74
4
        auto buff = buf.read(sizeof(Ty) * size);
75
4
        memcpy(_nums.data(), buff.data, buff.size);
76
4
    }
_ZN5doris6CountsIdE11unserializeERNS_10vectorized14BufferReadableE
Line
Count
Source
70
78
    void unserialize(vectorized::BufferReadable& buf) {
71
78
        size_t size;
72
78
        buf.read_binary(size);
73
78
        _nums.resize(size);
74
78
        auto buff = buf.read(sizeof(Ty) * size);
75
78
        memcpy(_nums.data(), buff.data, buff.size);
76
78
    }
77
78
1.14k
    double terminate(double quantile) {
79
1.14k
        if (_sorted_nums_vec.size() <= 1) {
80
1.00k
            if (_sorted_nums_vec.size() == 1) {
81
351
                _nums = std::move(_sorted_nums_vec[0]);
82
351
            }
83
84
1.00k
            if (_nums.empty()) {
85
                // Although set null here, but the value is 0.0 and the call method just
86
                // get val in aggregate_function_percentile_approx.h
87
0
                return 0.0;
88
0
            }
89
90
1.00k
            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {
91
180
                pdqsort(_nums.begin(), _nums.end());
92
180
            }
93
94
1.00k
            if (quantile == 1 || _nums.size() == 1) {
95
476
                return _nums.back();
96
476
            }
97
98
528
            double u = (_nums.size() - 1) * quantile;
99
528
            auto index = static_cast<uint32_t>(u);
100
528
            return _nums[index] +
101
528
                   (u - static_cast<double>(index)) * (static_cast<double>(_nums[index + 1]) -
102
528
                                                       static_cast<double>(_nums[index]));
103
1.00k
        } else {
104
140
            DCHECK(_nums.empty());
105
140
            size_t rows = 0;
106
338
            for (const auto& i : _sorted_nums_vec) {
107
338
                rows += i.size();
108
338
            }
109
140
            const bool reverse = quantile > 0.5 && rows > 2;
110
140
            double u = (rows - 1) * quantile;
111
140
            auto index = static_cast<uint32_t>(u);
112
            // if reverse, the step of target should start 0 like not reverse
113
            // so here rows need to minus index + 2
114
            // eg: rows = 10, index = 5
115
            // if not reverse, so the first number loc is 5, the second number loc is 6
116
            // if reverse, so the second number is 3, the first number is 4
117
            // 5 + 4 = 3 + 6 = 9 = rows - 1.
118
            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2
119
140
            size_t target = reverse ? rows - index - 2 : index;
120
140
            if (quantile == 1) {
121
0
                target = 0;
122
0
            }
123
140
            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);
124
140
            if (quantile == 1) {
125
0
                return second_number;
126
0
            }
127
140
            return first_number +
128
140
                   (u - static_cast<double>(index)) *
129
140
                           (static_cast<double>(second_number) - static_cast<double>(first_number));
130
140
        }
131
1.14k
    }
_ZN5doris6CountsIaE9terminateEd
Line
Count
Source
78
61
    double terminate(double quantile) {
79
61
        if (_sorted_nums_vec.size() <= 1) {
80
60
            if (_sorted_nums_vec.size() == 1) {
81
2
                _nums = std::move(_sorted_nums_vec[0]);
82
2
            }
83
84
60
            if (_nums.empty()) {
85
                // Although set null here, but the value is 0.0 and the call method just
86
                // get val in aggregate_function_percentile_approx.h
87
0
                return 0.0;
88
0
            }
89
90
60
            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {
91
24
                pdqsort(_nums.begin(), _nums.end());
92
24
            }
93
94
60
            if (quantile == 1 || _nums.size() == 1) {
95
34
                return _nums.back();
96
34
            }
97
98
26
            double u = (_nums.size() - 1) * quantile;
99
26
            auto index = static_cast<uint32_t>(u);
100
26
            return _nums[index] +
101
26
                   (u - static_cast<double>(index)) * (static_cast<double>(_nums[index + 1]) -
102
26
                                                       static_cast<double>(_nums[index]));
103
60
        } else {
104
1
            DCHECK(_nums.empty());
105
1
            size_t rows = 0;
106
2
            for (const auto& i : _sorted_nums_vec) {
107
2
                rows += i.size();
108
2
            }
109
1
            const bool reverse = quantile > 0.5 && rows > 2;
110
1
            double u = (rows - 1) * quantile;
111
1
            auto index = static_cast<uint32_t>(u);
112
            // if reverse, the step of target should start 0 like not reverse
113
            // so here rows need to minus index + 2
114
            // eg: rows = 10, index = 5
115
            // if not reverse, so the first number loc is 5, the second number loc is 6
116
            // if reverse, so the second number is 3, the first number is 4
117
            // 5 + 4 = 3 + 6 = 9 = rows - 1.
118
            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2
119
1
            size_t target = reverse ? rows - index - 2 : index;
120
1
            if (quantile == 1) {
121
0
                target = 0;
122
0
            }
123
1
            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);
124
1
            if (quantile == 1) {
125
0
                return second_number;
126
0
            }
127
1
            return first_number +
128
1
                   (u - static_cast<double>(index)) *
129
1
                           (static_cast<double>(second_number) - static_cast<double>(first_number));
130
1
        }
131
61
    }
_ZN5doris6CountsIsE9terminateEd
Line
Count
Source
78
300
    double terminate(double quantile) {
79
300
        if (_sorted_nums_vec.size() <= 1) {
80
296
            if (_sorted_nums_vec.size() == 1) {
81
2
                _nums = std::move(_sorted_nums_vec[0]);
82
2
            }
83
84
296
            if (_nums.empty()) {
85
                // Although set null here, but the value is 0.0 and the call method just
86
                // get val in aggregate_function_percentile_approx.h
87
0
                return 0.0;
88
0
            }
89
90
296
            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {
91
144
                pdqsort(_nums.begin(), _nums.end());
92
144
            }
93
94
296
            if (quantile == 1 || _nums.size() == 1) {
95
87
                return _nums.back();
96
87
            }
97
98
209
            double u = (_nums.size() - 1) * quantile;
99
209
            auto index = static_cast<uint32_t>(u);
100
209
            return _nums[index] +
101
209
                   (u - static_cast<double>(index)) * (static_cast<double>(_nums[index + 1]) -
102
209
                                                       static_cast<double>(_nums[index]));
103
296
        } else {
104
4
            DCHECK(_nums.empty());
105
4
            size_t rows = 0;
106
14
            for (const auto& i : _sorted_nums_vec) {
107
14
                rows += i.size();
108
14
            }
109
4
            const bool reverse = quantile > 0.5 && rows > 2;
110
4
            double u = (rows - 1) * quantile;
111
4
            auto index = static_cast<uint32_t>(u);
112
            // if reverse, the step of target should start 0 like not reverse
113
            // so here rows need to minus index + 2
114
            // eg: rows = 10, index = 5
115
            // if not reverse, so the first number loc is 5, the second number loc is 6
116
            // if reverse, so the second number is 3, the first number is 4
117
            // 5 + 4 = 3 + 6 = 9 = rows - 1.
118
            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2
119
4
            size_t target = reverse ? rows - index - 2 : index;
120
4
            if (quantile == 1) {
121
0
                target = 0;
122
0
            }
123
4
            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);
124
4
            if (quantile == 1) {
125
0
                return second_number;
126
0
            }
127
4
            return first_number +
128
4
                   (u - static_cast<double>(index)) *
129
4
                           (static_cast<double>(second_number) - static_cast<double>(first_number));
130
4
        }
131
300
    }
_ZN5doris6CountsIiE9terminateEd
Line
Count
Source
78
483
    double terminate(double quantile) {
79
483
        if (_sorted_nums_vec.size() <= 1) {
80
396
            if (_sorted_nums_vec.size() == 1) {
81
278
                _nums = std::move(_sorted_nums_vec[0]);
82
278
            }
83
84
396
            if (_nums.empty()) {
85
                // Although set null here, but the value is 0.0 and the call method just
86
                // get val in aggregate_function_percentile_approx.h
87
0
                return 0.0;
88
0
            }
89
90
396
            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {
91
11
                pdqsort(_nums.begin(), _nums.end());
92
11
            }
93
94
396
            if (quantile == 1 || _nums.size() == 1) {
95
242
                return _nums.back();
96
242
            }
97
98
154
            double u = (_nums.size() - 1) * quantile;
99
154
            auto index = static_cast<uint32_t>(u);
100
154
            return _nums[index] +
101
154
                   (u - static_cast<double>(index)) * (static_cast<double>(_nums[index + 1]) -
102
154
                                                       static_cast<double>(_nums[index]));
103
396
        } else {
104
87
            DCHECK(_nums.empty());
105
87
            size_t rows = 0;
106
204
            for (const auto& i : _sorted_nums_vec) {
107
204
                rows += i.size();
108
204
            }
109
87
            const bool reverse = quantile > 0.5 && rows > 2;
110
87
            double u = (rows - 1) * quantile;
111
87
            auto index = static_cast<uint32_t>(u);
112
            // if reverse, the step of target should start 0 like not reverse
113
            // so here rows need to minus index + 2
114
            // eg: rows = 10, index = 5
115
            // if not reverse, so the first number loc is 5, the second number loc is 6
116
            // if reverse, so the second number is 3, the first number is 4
117
            // 5 + 4 = 3 + 6 = 9 = rows - 1.
118
            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2
119
87
            size_t target = reverse ? rows - index - 2 : index;
120
87
            if (quantile == 1) {
121
0
                target = 0;
122
0
            }
123
87
            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);
124
87
            if (quantile == 1) {
125
0
                return second_number;
126
0
            }
127
87
            return first_number +
128
87
                   (u - static_cast<double>(index)) *
129
87
                           (static_cast<double>(second_number) - static_cast<double>(first_number));
130
87
        }
131
483
    }
_ZN5doris6CountsIlE9terminateEd
Line
Count
Source
78
128
    double terminate(double quantile) {
79
128
        if (_sorted_nums_vec.size() <= 1) {
80
107
            if (_sorted_nums_vec.size() == 1) {
81
37
                _nums = std::move(_sorted_nums_vec[0]);
82
37
            }
83
84
107
            if (_nums.empty()) {
85
                // Although set null here, but the value is 0.0 and the call method just
86
                // get val in aggregate_function_percentile_approx.h
87
0
                return 0.0;
88
0
            }
89
90
107
            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {
91
1
                pdqsort(_nums.begin(), _nums.end());
92
1
            }
93
94
107
            if (quantile == 1 || _nums.size() == 1) {
95
59
                return _nums.back();
96
59
            }
97
98
48
            double u = (_nums.size() - 1) * quantile;
99
48
            auto index = static_cast<uint32_t>(u);
100
48
            return _nums[index] +
101
48
                   (u - static_cast<double>(index)) * (static_cast<double>(_nums[index + 1]) -
102
48
                                                       static_cast<double>(_nums[index]));
103
107
        } else {
104
21
            DCHECK(_nums.empty());
105
21
            size_t rows = 0;
106
64
            for (const auto& i : _sorted_nums_vec) {
107
64
                rows += i.size();
108
64
            }
109
21
            const bool reverse = quantile > 0.5 && rows > 2;
110
21
            double u = (rows - 1) * quantile;
111
21
            auto index = static_cast<uint32_t>(u);
112
            // if reverse, the step of target should start 0 like not reverse
113
            // so here rows need to minus index + 2
114
            // eg: rows = 10, index = 5
115
            // if not reverse, so the first number loc is 5, the second number loc is 6
116
            // if reverse, so the second number is 3, the first number is 4
117
            // 5 + 4 = 3 + 6 = 9 = rows - 1.
118
            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2
119
21
            size_t target = reverse ? rows - index - 2 : index;
120
21
            if (quantile == 1) {
121
0
                target = 0;
122
0
            }
123
21
            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);
124
21
            if (quantile == 1) {
125
0
                return second_number;
126
0
            }
127
21
            return first_number +
128
21
                   (u - static_cast<double>(index)) *
129
21
                           (static_cast<double>(second_number) - static_cast<double>(first_number));
130
21
        }
131
128
    }
_ZN5doris6CountsInE9terminateEd
Line
Count
Source
78
33
    double terminate(double quantile) {
79
33
        if (_sorted_nums_vec.size() <= 1) {
80
32
            if (_sorted_nums_vec.size() == 1) {
81
2
                _nums = std::move(_sorted_nums_vec[0]);
82
2
            }
83
84
32
            if (_nums.empty()) {
85
                // Although set null here, but the value is 0.0 and the call method just
86
                // get val in aggregate_function_percentile_approx.h
87
0
                return 0.0;
88
0
            }
89
90
32
            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {
91
0
                pdqsort(_nums.begin(), _nums.end());
92
0
            }
93
94
32
            if (quantile == 1 || _nums.size() == 1) {
95
24
                return _nums.back();
96
24
            }
97
98
8
            double u = (_nums.size() - 1) * quantile;
99
8
            auto index = static_cast<uint32_t>(u);
100
8
            return _nums[index] +
101
8
                   (u - static_cast<double>(index)) * (static_cast<double>(_nums[index + 1]) -
102
8
                                                       static_cast<double>(_nums[index]));
103
32
        } else {
104
1
            DCHECK(_nums.empty());
105
1
            size_t rows = 0;
106
2
            for (const auto& i : _sorted_nums_vec) {
107
2
                rows += i.size();
108
2
            }
109
1
            const bool reverse = quantile > 0.5 && rows > 2;
110
1
            double u = (rows - 1) * quantile;
111
1
            auto index = static_cast<uint32_t>(u);
112
            // if reverse, the step of target should start 0 like not reverse
113
            // so here rows need to minus index + 2
114
            // eg: rows = 10, index = 5
115
            // if not reverse, so the first number loc is 5, the second number loc is 6
116
            // if reverse, so the second number is 3, the first number is 4
117
            // 5 + 4 = 3 + 6 = 9 = rows - 1.
118
            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2
119
1
            size_t target = reverse ? rows - index - 2 : index;
120
1
            if (quantile == 1) {
121
0
                target = 0;
122
0
            }
123
1
            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);
124
1
            if (quantile == 1) {
125
0
                return second_number;
126
0
            }
127
1
            return first_number +
128
1
                   (u - static_cast<double>(index)) *
129
1
                           (static_cast<double>(second_number) - static_cast<double>(first_number));
130
1
        }
131
33
    }
_ZN5doris6CountsIfE9terminateEd
Line
Count
Source
78
3
    double terminate(double quantile) {
79
3
        if (_sorted_nums_vec.size() <= 1) {
80
2
            if (_sorted_nums_vec.size() == 1) {
81
2
                _nums = std::move(_sorted_nums_vec[0]);
82
2
            }
83
84
2
            if (_nums.empty()) {
85
                // Although set null here, but the value is 0.0 and the call method just
86
                // get val in aggregate_function_percentile_approx.h
87
0
                return 0.0;
88
0
            }
89
90
2
            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {
91
0
                pdqsort(_nums.begin(), _nums.end());
92
0
            }
93
94
2
            if (quantile == 1 || _nums.size() == 1) {
95
0
                return _nums.back();
96
0
            }
97
98
2
            double u = (_nums.size() - 1) * quantile;
99
2
            auto index = static_cast<uint32_t>(u);
100
2
            return _nums[index] +
101
2
                   (u - static_cast<double>(index)) * (static_cast<double>(_nums[index + 1]) -
102
2
                                                       static_cast<double>(_nums[index]));
103
2
        } else {
104
1
            DCHECK(_nums.empty());
105
1
            size_t rows = 0;
106
2
            for (const auto& i : _sorted_nums_vec) {
107
2
                rows += i.size();
108
2
            }
109
1
            const bool reverse = quantile > 0.5 && rows > 2;
110
1
            double u = (rows - 1) * quantile;
111
1
            auto index = static_cast<uint32_t>(u);
112
            // if reverse, the step of target should start 0 like not reverse
113
            // so here rows need to minus index + 2
114
            // eg: rows = 10, index = 5
115
            // if not reverse, so the first number loc is 5, the second number loc is 6
116
            // if reverse, so the second number is 3, the first number is 4
117
            // 5 + 4 = 3 + 6 = 9 = rows - 1.
118
            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2
119
1
            size_t target = reverse ? rows - index - 2 : index;
120
1
            if (quantile == 1) {
121
0
                target = 0;
122
0
            }
123
1
            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);
124
1
            if (quantile == 1) {
125
0
                return second_number;
126
0
            }
127
1
            return first_number +
128
1
                   (u - static_cast<double>(index)) *
129
1
                           (static_cast<double>(second_number) - static_cast<double>(first_number));
130
1
        }
131
3
    }
_ZN5doris6CountsIdE9terminateEd
Line
Count
Source
78
136
    double terminate(double quantile) {
79
136
        if (_sorted_nums_vec.size() <= 1) {
80
111
            if (_sorted_nums_vec.size() == 1) {
81
28
                _nums = std::move(_sorted_nums_vec[0]);
82
28
            }
83
84
111
            if (_nums.empty()) {
85
                // Although set null here, but the value is 0.0 and the call method just
86
                // get val in aggregate_function_percentile_approx.h
87
0
                return 0.0;
88
0
            }
89
90
111
            if (UNLIKELY(!std::is_sorted(_nums.begin(), _nums.end()))) {
91
0
                pdqsort(_nums.begin(), _nums.end());
92
0
            }
93
94
111
            if (quantile == 1 || _nums.size() == 1) {
95
30
                return _nums.back();
96
30
            }
97
98
81
            double u = (_nums.size() - 1) * quantile;
99
81
            auto index = static_cast<uint32_t>(u);
100
81
            return _nums[index] +
101
81
                   (u - static_cast<double>(index)) * (static_cast<double>(_nums[index + 1]) -
102
81
                                                       static_cast<double>(_nums[index]));
103
111
        } else {
104
25
            DCHECK(_nums.empty());
105
25
            size_t rows = 0;
106
50
            for (const auto& i : _sorted_nums_vec) {
107
50
                rows += i.size();
108
50
            }
109
25
            const bool reverse = quantile > 0.5 && rows > 2;
110
25
            double u = (rows - 1) * quantile;
111
25
            auto index = static_cast<uint32_t>(u);
112
            // if reverse, the step of target should start 0 like not reverse
113
            // so here rows need to minus index + 2
114
            // eg: rows = 10, index = 5
115
            // if not reverse, so the first number loc is 5, the second number loc is 6
116
            // if reverse, so the second number is 3, the first number is 4
117
            // 5 + 4 = 3 + 6 = 9 = rows - 1.
118
            // the rows must GE 2 beacuse `_sorted_nums_vec` size GE 2
119
25
            size_t target = reverse ? rows - index - 2 : index;
120
25
            if (quantile == 1) {
121
0
                target = 0;
122
0
            }
123
25
            auto [first_number, second_number] = _merge_sort_and_get_numbers(target, reverse);
124
25
            if (quantile == 1) {
125
0
                return second_number;
126
0
            }
127
25
            return first_number +
128
25
                   (u - static_cast<double>(index)) *
129
25
                           (static_cast<double>(second_number) - static_cast<double>(first_number));
130
25
        }
131
136
    }
132
133
private:
134
    struct Node {
135
        Ty value;
136
        int array_index;
137
        int64_t element_index;
138
139
1.17k
        auto operator<=>(const Node& other) const { return value <=> other.value; }
_ZNK5doris6CountsIaE4NodessERKS2_
Line
Count
Source
139
2
        auto operator<=>(const Node& other) const { return value <=> other.value; }
_ZNK5doris6CountsIsE4NodessERKS2_
Line
Count
Source
139
70
        auto operator<=>(const Node& other) const { return value <=> other.value; }
_ZNK5doris6CountsIiE4NodessERKS2_
Line
Count
Source
139
648
        auto operator<=>(const Node& other) const { return value <=> other.value; }
_ZNK5doris6CountsIlE4NodessERKS2_
Line
Count
Source
139
409
        auto operator<=>(const Node& other) const { return value <=> other.value; }
_ZNK5doris6CountsInE4NodessERKS2_
Line
Count
Source
139
2
        auto operator<=>(const Node& other) const { return value <=> other.value; }
_ZNK5doris6CountsIfE4NodessERKS2_
Line
Count
Source
139
2
        auto operator<=>(const Node& other) const { return value <=> other.value; }
_ZNK5doris6CountsIdE4NodessERKS2_
Line
Count
Source
139
39
        auto operator<=>(const Node& other) const { return value <=> other.value; }
140
    };
141
142
288
    void _convert_sorted_num_vec_to_nums() {
143
288
        size_t rows = 0;
144
586
        for (const auto& i : _sorted_nums_vec) {
145
586
            rows += i.size();
146
586
        }
147
288
        _nums.resize(rows);
148
288
        size_t count = 0;
149
150
288
        std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
151
874
        for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
152
586
            if (!_sorted_nums_vec[i].empty()) {
153
586
                min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
154
586
            }
155
586
        }
156
157
1.02k
        while (!min_heap.empty()) {
158
737
            Node node = min_heap.top();
159
737
            min_heap.pop();
160
737
            _nums[count++] = node.value;
161
737
            if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
162
151
                node.value = _sorted_nums_vec[node.array_index][node.element_index];
163
151
                min_heap.push(node);
164
151
            }
165
737
        }
166
288
        _sorted_nums_vec.clear();
167
288
    }
Unexecuted instantiation: _ZN5doris6CountsIaE31_convert_sorted_num_vec_to_numsEv
Unexecuted instantiation: _ZN5doris6CountsIsE31_convert_sorted_num_vec_to_numsEv
_ZN5doris6CountsIiE31_convert_sorted_num_vec_to_numsEv
Line
Count
Source
142
156
    void _convert_sorted_num_vec_to_nums() {
143
156
        size_t rows = 0;
144
339
        for (const auto& i : _sorted_nums_vec) {
145
339
            rows += i.size();
146
339
        }
147
156
        _nums.resize(rows);
148
156
        size_t count = 0;
149
150
156
        std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
151
495
        for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
152
339
            if (!_sorted_nums_vec[i].empty()) {
153
339
                min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
154
339
            }
155
339
        }
156
157
531
        while (!min_heap.empty()) {
158
375
            Node node = min_heap.top();
159
375
            min_heap.pop();
160
375
            _nums[count++] = node.value;
161
375
            if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
162
36
                node.value = _sorted_nums_vec[node.array_index][node.element_index];
163
36
                min_heap.push(node);
164
36
            }
165
375
        }
166
156
        _sorted_nums_vec.clear();
167
156
    }
_ZN5doris6CountsIlE31_convert_sorted_num_vec_to_numsEv
Line
Count
Source
142
132
    void _convert_sorted_num_vec_to_nums() {
143
132
        size_t rows = 0;
144
247
        for (const auto& i : _sorted_nums_vec) {
145
247
            rows += i.size();
146
247
        }
147
132
        _nums.resize(rows);
148
132
        size_t count = 0;
149
150
132
        std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
151
379
        for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
152
247
            if (!_sorted_nums_vec[i].empty()) {
153
247
                min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
154
247
            }
155
247
        }
156
157
494
        while (!min_heap.empty()) {
158
362
            Node node = min_heap.top();
159
362
            min_heap.pop();
160
362
            _nums[count++] = node.value;
161
362
            if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
162
115
                node.value = _sorted_nums_vec[node.array_index][node.element_index];
163
115
                min_heap.push(node);
164
115
            }
165
362
        }
166
132
        _sorted_nums_vec.clear();
167
132
    }
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
168
169
140
    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {
170
140
        Ty first_number = 0, second_number = 0;
171
140
        size_t count = 0;
172
140
        if (reverse) {
173
23
            std::priority_queue<Node> max_heap;
174
96
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
175
73
                if (!_sorted_nums_vec[i].empty()) {
176
73
                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,
177
73
                                     _sorted_nums_vec[i].size() - 1);
178
73
                }
179
73
            }
180
181
102
            while (!max_heap.empty()) {
182
102
                Node node = max_heap.top();
183
102
                max_heap.pop();
184
102
                if (count == target) {
185
23
                    second_number = node.value;
186
79
                } else if (count == target + 1) {
187
23
                    first_number = node.value;
188
23
                    break;
189
23
                }
190
79
                ++count;
191
79
                if (--node.element_index >= 0) {
192
73
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
193
73
                    max_heap.push(node);
194
73
                }
195
79
            }
196
197
117
        } else {
198
117
            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
199
382
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
200
265
                if (!_sorted_nums_vec[i].empty()) {
201
265
                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
202
265
                }
203
265
            }
204
205
334
            while (!min_heap.empty()) {
206
334
                Node node = min_heap.top();
207
334
                min_heap.pop();
208
334
                if (count == target) {
209
117
                    first_number = node.value;
210
217
                } else if (count == target + 1) {
211
117
                    second_number = node.value;
212
117
                    break;
213
117
                }
214
217
                ++count;
215
217
                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
216
136
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
217
136
                    min_heap.push(node);
218
136
                }
219
217
            }
220
117
        }
221
222
140
        return {first_number, second_number};
223
140
    }
_ZN5doris6CountsIaE27_merge_sort_and_get_numbersElb
Line
Count
Source
169
1
    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {
170
1
        Ty first_number = 0, second_number = 0;
171
1
        size_t count = 0;
172
1
        if (reverse) {
173
0
            std::priority_queue<Node> max_heap;
174
0
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
175
0
                if (!_sorted_nums_vec[i].empty()) {
176
0
                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,
177
0
                                     _sorted_nums_vec[i].size() - 1);
178
0
                }
179
0
            }
180
181
0
            while (!max_heap.empty()) {
182
0
                Node node = max_heap.top();
183
0
                max_heap.pop();
184
0
                if (count == target) {
185
0
                    second_number = node.value;
186
0
                } else if (count == target + 1) {
187
0
                    first_number = node.value;
188
0
                    break;
189
0
                }
190
0
                ++count;
191
0
                if (--node.element_index >= 0) {
192
0
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
193
0
                    max_heap.push(node);
194
0
                }
195
0
            }
196
197
1
        } else {
198
1
            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
199
3
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
200
2
                if (!_sorted_nums_vec[i].empty()) {
201
2
                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
202
2
                }
203
2
            }
204
205
3
            while (!min_heap.empty()) {
206
3
                Node node = min_heap.top();
207
3
                min_heap.pop();
208
3
                if (count == target) {
209
1
                    first_number = node.value;
210
2
                } else if (count == target + 1) {
211
1
                    second_number = node.value;
212
1
                    break;
213
1
                }
214
2
                ++count;
215
2
                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
216
1
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
217
1
                    min_heap.push(node);
218
1
                }
219
2
            }
220
1
        }
221
222
1
        return {first_number, second_number};
223
1
    }
_ZN5doris6CountsIsE27_merge_sort_and_get_numbersElb
Line
Count
Source
169
4
    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {
170
4
        Ty first_number = 0, second_number = 0;
171
4
        size_t count = 0;
172
4
        if (reverse) {
173
1
            std::priority_queue<Node> max_heap;
174
5
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
175
4
                if (!_sorted_nums_vec[i].empty()) {
176
4
                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,
177
4
                                     _sorted_nums_vec[i].size() - 1);
178
4
                }
179
4
            }
180
181
6
            while (!max_heap.empty()) {
182
6
                Node node = max_heap.top();
183
6
                max_heap.pop();
184
6
                if (count == target) {
185
1
                    second_number = node.value;
186
5
                } else if (count == target + 1) {
187
1
                    first_number = node.value;
188
1
                    break;
189
1
                }
190
5
                ++count;
191
5
                if (--node.element_index >= 0) {
192
3
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
193
3
                    max_heap.push(node);
194
3
                }
195
5
            }
196
197
3
        } else {
198
3
            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
199
13
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
200
10
                if (!_sorted_nums_vec[i].empty()) {
201
10
                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
202
10
                }
203
10
            }
204
205
16
            while (!min_heap.empty()) {
206
16
                Node node = min_heap.top();
207
16
                min_heap.pop();
208
16
                if (count == target) {
209
3
                    first_number = node.value;
210
13
                } else if (count == target + 1) {
211
3
                    second_number = node.value;
212
3
                    break;
213
3
                }
214
13
                ++count;
215
13
                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
216
12
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
217
12
                    min_heap.push(node);
218
12
                }
219
13
            }
220
3
        }
221
222
4
        return {first_number, second_number};
223
4
    }
_ZN5doris6CountsIiE27_merge_sort_and_get_numbersElb
Line
Count
Source
169
87
    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {
170
87
        Ty first_number = 0, second_number = 0;
171
87
        size_t count = 0;
172
87
        if (reverse) {
173
6
            std::priority_queue<Node> max_heap;
174
22
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
175
16
                if (!_sorted_nums_vec[i].empty()) {
176
16
                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,
177
16
                                     _sorted_nums_vec[i].size() - 1);
178
16
                }
179
16
            }
180
181
31
            while (!max_heap.empty()) {
182
31
                Node node = max_heap.top();
183
31
                max_heap.pop();
184
31
                if (count == target) {
185
6
                    second_number = node.value;
186
25
                } else if (count == target + 1) {
187
6
                    first_number = node.value;
188
6
                    break;
189
6
                }
190
25
                ++count;
191
25
                if (--node.element_index >= 0) {
192
25
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
193
25
                    max_heap.push(node);
194
25
                }
195
25
            }
196
197
81
        } else {
198
81
            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
199
269
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
200
188
                if (!_sorted_nums_vec[i].empty()) {
201
188
                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
202
188
                }
203
188
            }
204
205
231
            while (!min_heap.empty()) {
206
231
                Node node = min_heap.top();
207
231
                min_heap.pop();
208
231
                if (count == target) {
209
81
                    first_number = node.value;
210
150
                } else if (count == target + 1) {
211
81
                    second_number = node.value;
212
81
                    break;
213
81
                }
214
150
                ++count;
215
150
                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
216
94
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
217
94
                    min_heap.push(node);
218
94
                }
219
150
            }
220
81
        }
221
222
87
        return {first_number, second_number};
223
87
    }
_ZN5doris6CountsIlE27_merge_sort_and_get_numbersElb
Line
Count
Source
169
21
    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {
170
21
        Ty first_number = 0, second_number = 0;
171
21
        size_t count = 0;
172
21
        if (reverse) {
173
14
            std::priority_queue<Node> max_heap;
174
63
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
175
49
                if (!_sorted_nums_vec[i].empty()) {
176
49
                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,
177
49
                                     _sorted_nums_vec[i].size() - 1);
178
49
                }
179
49
            }
180
181
60
            while (!max_heap.empty()) {
182
60
                Node node = max_heap.top();
183
60
                max_heap.pop();
184
60
                if (count == target) {
185
14
                    second_number = node.value;
186
46
                } else if (count == target + 1) {
187
14
                    first_number = node.value;
188
14
                    break;
189
14
                }
190
46
                ++count;
191
46
                if (--node.element_index >= 0) {
192
42
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
193
42
                    max_heap.push(node);
194
42
                }
195
46
            }
196
197
14
        } else {
198
7
            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
199
22
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
200
15
                if (!_sorted_nums_vec[i].empty()) {
201
15
                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
202
15
                }
203
15
            }
204
205
23
            while (!min_heap.empty()) {
206
23
                Node node = min_heap.top();
207
23
                min_heap.pop();
208
23
                if (count == target) {
209
7
                    first_number = node.value;
210
16
                } else if (count == target + 1) {
211
7
                    second_number = node.value;
212
7
                    break;
213
7
                }
214
16
                ++count;
215
16
                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
216
14
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
217
14
                    min_heap.push(node);
218
14
                }
219
16
            }
220
7
        }
221
222
21
        return {first_number, second_number};
223
21
    }
_ZN5doris6CountsInE27_merge_sort_and_get_numbersElb
Line
Count
Source
169
1
    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {
170
1
        Ty first_number = 0, second_number = 0;
171
1
        size_t count = 0;
172
1
        if (reverse) {
173
0
            std::priority_queue<Node> max_heap;
174
0
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
175
0
                if (!_sorted_nums_vec[i].empty()) {
176
0
                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,
177
0
                                     _sorted_nums_vec[i].size() - 1);
178
0
                }
179
0
            }
180
181
0
            while (!max_heap.empty()) {
182
0
                Node node = max_heap.top();
183
0
                max_heap.pop();
184
0
                if (count == target) {
185
0
                    second_number = node.value;
186
0
                } else if (count == target + 1) {
187
0
                    first_number = node.value;
188
0
                    break;
189
0
                }
190
0
                ++count;
191
0
                if (--node.element_index >= 0) {
192
0
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
193
0
                    max_heap.push(node);
194
0
                }
195
0
            }
196
197
1
        } else {
198
1
            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
199
3
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
200
2
                if (!_sorted_nums_vec[i].empty()) {
201
2
                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
202
2
                }
203
2
            }
204
205
3
            while (!min_heap.empty()) {
206
3
                Node node = min_heap.top();
207
3
                min_heap.pop();
208
3
                if (count == target) {
209
1
                    first_number = node.value;
210
2
                } else if (count == target + 1) {
211
1
                    second_number = node.value;
212
1
                    break;
213
1
                }
214
2
                ++count;
215
2
                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
216
1
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
217
1
                    min_heap.push(node);
218
1
                }
219
2
            }
220
1
        }
221
222
1
        return {first_number, second_number};
223
1
    }
_ZN5doris6CountsIfE27_merge_sort_and_get_numbersElb
Line
Count
Source
169
1
    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {
170
1
        Ty first_number = 0, second_number = 0;
171
1
        size_t count = 0;
172
1
        if (reverse) {
173
0
            std::priority_queue<Node> max_heap;
174
0
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
175
0
                if (!_sorted_nums_vec[i].empty()) {
176
0
                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,
177
0
                                     _sorted_nums_vec[i].size() - 1);
178
0
                }
179
0
            }
180
181
0
            while (!max_heap.empty()) {
182
0
                Node node = max_heap.top();
183
0
                max_heap.pop();
184
0
                if (count == target) {
185
0
                    second_number = node.value;
186
0
                } else if (count == target + 1) {
187
0
                    first_number = node.value;
188
0
                    break;
189
0
                }
190
0
                ++count;
191
0
                if (--node.element_index >= 0) {
192
0
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
193
0
                    max_heap.push(node);
194
0
                }
195
0
            }
196
197
1
        } else {
198
1
            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
199
3
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
200
2
                if (!_sorted_nums_vec[i].empty()) {
201
2
                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
202
2
                }
203
2
            }
204
205
3
            while (!min_heap.empty()) {
206
3
                Node node = min_heap.top();
207
3
                min_heap.pop();
208
3
                if (count == target) {
209
1
                    first_number = node.value;
210
2
                } else if (count == target + 1) {
211
1
                    second_number = node.value;
212
1
                    break;
213
1
                }
214
2
                ++count;
215
2
                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
216
1
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
217
1
                    min_heap.push(node);
218
1
                }
219
2
            }
220
1
        }
221
222
1
        return {first_number, second_number};
223
1
    }
_ZN5doris6CountsIdE27_merge_sort_and_get_numbersElb
Line
Count
Source
169
25
    std::pair<Ty, Ty> _merge_sort_and_get_numbers(int64_t target, bool reverse) {
170
25
        Ty first_number = 0, second_number = 0;
171
25
        size_t count = 0;
172
25
        if (reverse) {
173
2
            std::priority_queue<Node> max_heap;
174
6
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
175
4
                if (!_sorted_nums_vec[i].empty()) {
176
4
                    max_heap.emplace(_sorted_nums_vec[i][_sorted_nums_vec[i].size() - 1], i,
177
4
                                     _sorted_nums_vec[i].size() - 1);
178
4
                }
179
4
            }
180
181
5
            while (!max_heap.empty()) {
182
5
                Node node = max_heap.top();
183
5
                max_heap.pop();
184
5
                if (count == target) {
185
2
                    second_number = node.value;
186
3
                } else if (count == target + 1) {
187
2
                    first_number = node.value;
188
2
                    break;
189
2
                }
190
3
                ++count;
191
3
                if (--node.element_index >= 0) {
192
3
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
193
3
                    max_heap.push(node);
194
3
                }
195
3
            }
196
197
23
        } else {
198
23
            std::priority_queue<Node, std::vector<Node>, std::greater<Node>> min_heap;
199
69
            for (int i = 0; i < _sorted_nums_vec.size(); ++i) {
200
46
                if (!_sorted_nums_vec[i].empty()) {
201
46
                    min_heap.emplace(_sorted_nums_vec[i][0], i, 0);
202
46
                }
203
46
            }
204
205
55
            while (!min_heap.empty()) {
206
55
                Node node = min_heap.top();
207
55
                min_heap.pop();
208
55
                if (count == target) {
209
23
                    first_number = node.value;
210
32
                } else if (count == target + 1) {
211
23
                    second_number = node.value;
212
23
                    break;
213
23
                }
214
32
                ++count;
215
32
                if (++node.element_index < _sorted_nums_vec[node.array_index].size()) {
216
13
                    node.value = _sorted_nums_vec[node.array_index][node.element_index];
217
13
                    min_heap.push(node);
218
13
                }
219
32
            }
220
23
        }
221
222
25
        return {first_number, second_number};
223
25
    }
224
225
    vectorized::PODArray<Ty> _nums;
226
    std::vector<vectorized::PODArray<Ty>> _sorted_nums_vec;
227
};
228
229
} // namespace doris