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176 lines
5.5 KiB
C++
176 lines
5.5 KiB
C++
#pragma once
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#include <AggregateFunctions/IAggregateFunction.h>
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#include <Common/assert_cast.h>
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#include <DataTypes/DataTypesNumber.h>
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#include <Common/HashTable/HashMap.h>
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#include <AggregateFunctions/UniqVariadicHash.h>
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/** Aggregate function that calculates statistics on top of cross-tab:
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* - histogram of every argument and every pair of elements.
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* These statistics include:
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* - Cramer's V;
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* - Theil's U;
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* - contingency coefficient;
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* It can be interpreted as interdependency coefficient between arguments;
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* or non-parametric correlation coefficient.
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*/
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namespace DB
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{
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struct CrossTabData
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{
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/// Total count.
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UInt64 count = 0;
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/// Count of every value of the first and second argument (values are pre-hashed).
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/// Note: non-cryptographic 64bit hash is used, it means that the calculation is approximate.
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HashMapWithStackMemory<UInt64, UInt64, TrivialHash, 4> count_a;
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HashMapWithStackMemory<UInt64, UInt64, TrivialHash, 4> count_b;
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/// Count of every pair of values. We pack two hashes into UInt128.
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HashMapWithStackMemory<UInt128, UInt64, UInt128Hash, 4> count_ab;
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void add(UInt64 hash1, UInt64 hash2)
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{
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++count;
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++count_a[hash1];
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++count_b[hash2];
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UInt128 hash_pair{hash1, hash2};
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++count_ab[hash_pair];
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}
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void merge(const CrossTabData & other)
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{
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count += other.count;
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for (const auto & [key, value] : other.count_a)
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count_a[key] += value;
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for (const auto & [key, value] : other.count_b)
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count_b[key] += value;
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for (const auto & [key, value] : other.count_ab)
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count_ab[key] += value;
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}
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void serialize(WriteBuffer & buf) const
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{
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writeBinary(count, buf);
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count_a.write(buf);
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count_b.write(buf);
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count_ab.write(buf);
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}
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void deserialize(ReadBuffer & buf)
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{
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readBinary(count, buf);
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count_a.read(buf);
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count_b.read(buf);
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count_ab.read(buf);
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}
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/** See https://en.wikipedia.org/wiki/Cram%C3%A9r%27s_V
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*
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* φ² is χ² divided by the sample size (count).
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* χ² is the sum of squares of the normalized differences between the "expected" and "observed" statistics.
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* ("Expected" in the case when one of the hypotheses is true).
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* Something resembling the L2 distance.
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*
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* Note: statisticians use the name χ² for every statistic that has χ² distribution in many various contexts.
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*
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* Let's suppose that there is no association between the values a and b.
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* Then the frequency (e.g. probability) of (a, b) pair is equal to the multiplied frequencies of a and b:
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* count_ab / count = (count_a / count) * (count_b / count)
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* count_ab = count_a * count_b / count
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*
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* Let's calculate the difference between the values that are supposed to be equal if there is no association between a and b:
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* count_ab - count_a * count_b / count
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*
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* Let's sum the squares of the differences across all (a, b) pairs.
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* Then divide by the second term for normalization: (count_a * count_b / count)
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*
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* This will be the χ² statistics.
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* This statistics is used as a base for many other statistics.
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*/
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Float64 getPhiSquared() const
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{
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Float64 chi_squared = 0;
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for (const auto & [key, value_ab] : count_ab)
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{
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Float64 value_a = count_a.at(key.items[0]);
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Float64 value_b = count_b.at(key.items[1]);
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Float64 expected_value_ab = (value_a * value_b) / count;
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Float64 chi_squared_elem = value_ab - expected_value_ab;
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chi_squared_elem = chi_squared_elem * chi_squared_elem / expected_value_ab;
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chi_squared += chi_squared_elem;
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}
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return chi_squared / count;
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}
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};
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template <typename Data>
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class AggregateFunctionCrossTab : public IAggregateFunctionDataHelper<Data, AggregateFunctionCrossTab<Data>>
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{
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public:
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explicit AggregateFunctionCrossTab(const DataTypes & arguments)
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: IAggregateFunctionDataHelper<Data, AggregateFunctionCrossTab<Data>>({arguments}, {})
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{
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}
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String getName() const override
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{
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return Data::getName();
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}
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bool allocatesMemoryInArena() const override
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{
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return false;
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}
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DataTypePtr getReturnType() const override
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{
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return std::make_shared<DataTypeNumber<Float64>>();
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}
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void add(
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AggregateDataPtr __restrict place,
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const IColumn ** columns,
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size_t row_num,
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Arena *) const override
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{
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UInt64 hash1 = UniqVariadicHash<false, false>::apply(1, &columns[0], row_num);
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UInt64 hash2 = UniqVariadicHash<false, false>::apply(1, &columns[1], row_num);
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this->data(place).add(hash1, hash2);
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}
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void merge(AggregateDataPtr __restrict place, ConstAggregateDataPtr rhs, Arena *) const override
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{
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this->data(place).merge(this->data(rhs));
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}
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void serialize(ConstAggregateDataPtr __restrict place, WriteBuffer & buf, std::optional<size_t>) const override
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{
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this->data(place).serialize(buf);
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}
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void deserialize(AggregateDataPtr __restrict place, ReadBuffer & buf, std::optional<size_t>, Arena *) const override
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{
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this->data(place).deserialize(buf);
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}
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void insertResultInto(AggregateDataPtr __restrict place, IColumn & to, Arena *) const override
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{
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Float64 result = this->data(place).getResult();
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auto & column = static_cast<ColumnVector<Float64> &>(to);
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column.getData().push_back(result);
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}
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};
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}
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