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StreamSampler.h
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StreamSampler.h
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// Copyright 2015 Lior Kogan ([email protected])
//
// Licensed 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 <random>
#include <vector>
#include <algorithm> // min_element
#include <stdexcept> // invalid_argument
// ==========================================================================
namespace StreamSampler {
// A stream is a sequence of data elements made available over time.
// The number of elements in the stream is usually large and unknown a priori.
// A stream sampler extracts a sample set with a given size from a stream.
// Each possible sample set (of the given size) has an equal probability of being extracted.
// A stream sampler is an online algorithm: The size of the input is unknown, and only one pass over the stream is possible.
using namespace std;
// ==========================================================================
// RandomSeed
// ==========================================================================
template <typename RNE> // Random Number Engine
static typename RNE::result_type RandomSeed()
{
random_device rd;
if (is_same<typename RNE::result_type, uint32_t>::value) // if RNE::result_type is uint32_t: return 32-bit seed
return rd();
if (is_same<typename RNE::result_type, uint64_t>::value) // if RNE::result_type is uint64_t: return 64-bit seed
return (static_cast<uint64_t>(rd()) << 32) | rd();
throw invalid_argument("please modify StreamSampler::RandomSeed() according to the RNE used");
}
// ==========================================================================
// CStreamSampler
// ==========================================================================
// Abstract base class for stream samplers
template <typename ElementType, typename RNE = mt19937_64> // Random Number Engine
class CStreamSampler
{
public:
CStreamSampler(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] Random Number Engine seed
// return the number of future stream elements the caller should skip before calling AddElement again
virtual uint64_t AddElement(const ElementType& Element) = 0;
// return the number of future stream elements the caller should skip before calling AddElement again
// if an element is sampled into more then one set, it will be moved first and then copied
// caller should call AddElement(move(s)) or simply AddElement(s) if Sample is a temporary object
virtual uint64_t AddElement( ElementType&& Element) = 0;
// get the SampleSets and reset it (implemented using move semantics)
vector<vector<ElementType>> GetSampleSets();
virtual void Reset();
protected:
bool m_bValid ; // invalidated when calling GetSampleSets(). validated on construction, and on AddElement() if invalid
const size_t m_nSampleSets; // number of independent sample sets
const size_t m_nSetSize ; // size of each sample set
vector<vector<ElementType>> m_vSampleSets; // for each sample set: vector of samples (reservoir)
uint64_t m_nElements ; // number of stream elements seen so far
vector<RNE> m_vRndGen ; // for each sample set: random number engine. see note in constructor's impl.
};
// ==========================================================================
// CStreamSamplerWOR_R0
// ==========================================================================
// Basic stream sampler without replacement (WOR)
// Based on "The Art of Computer Programming" [Knuth] Vol.2, 3.4.2 Algorithm R (Reservoir Sampling) attributed to Waterman, modified according to Ex.10
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR_R0 : public CStreamSampler<ElementType, RNE>
{
public:
CStreamSamplerWOR_R0(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ) // [i] RNE seed
: CStreamSampler<ElementType, RNE>(nSampleSets, nSetSize, nSeed) {}
// always return 0 (no skip)
uint64_t AddElement(const ElementType& Element) override;
uint64_t AddElement( ElementType&& Element) override;
};
// ==========================================================================
// CStreamSamplerWOR
// ==========================================================================
// Abstract base class for more advanced stream samplers without replacement (WOR)
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR : public CStreamSampler<ElementType, RNE>
{
public:
CStreamSamplerWOR(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] RNE seed
// return the number of future stream elements the caller should skip before calling AddElement again
uint64_t AddElement(const ElementType& Element) override;
uint64_t AddElement( ElementType&& Element) override;
void Reset() override;
protected:
vector<uint64_t> m_vnSkip ; // for each sample set: number of next elements to skip
vector<size_t > m_vnNextIdx; // for each sample set: next index to fill in reservoir
uint64_t m_nNextSkip; // next stream skip size = min(m_vnSkip)
// draw number of next elements to skip and next index to replace
virtual void DrawNext(size_t nSampleSetIdx) = 0; // [i] idx of sample set
};
// ==========================================================================
// Algorithms:
//
// R : Based on "The Art of Computer Programming" [Knuth] Vol.2, 3.4.2 Algorithm R (Reservoir Sampling) attributed to Waterman, modified according to Ex.10
// Implemented such that AddElement calculates the number of future stream elements to skip
// X,Y,Z: Based on "Random Sampling with a Reservoir" [Jeferey Scott Vitter, 1985]
// K,L,M: Based on "Reservoir-Sampling Algorithms of Time Complexity O(n(1+log(N)-log(n)))" [Kim-Hung Li, 1994]
// ==========================================================================
// Algorithm R
// ==========================================================================
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR_R : public CStreamSamplerWOR<ElementType, RNE>
{
public:
CStreamSamplerWOR_R(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] RNE seed
private:
void DrawNext(size_t nSS) override; // [i] idx of sample set
};
// ==========================================================================
// Algorithm X
// ==========================================================================
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR_X : public CStreamSamplerWOR<ElementType, RNE>
{
public:
CStreamSamplerWOR_X(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] RNE seed
private:
void DrawNext(size_t nSS) override; // [i] idx of sample set
};
// ==========================================================================
// Algorithm Y
// ==========================================================================
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR_Y : public CStreamSamplerWOR<ElementType, RNE>
{
public:
CStreamSamplerWOR_Y(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] RNE seed
private:
void DrawNext(size_t nSS) override; // [i] idx of sample set
};
// ==========================================================================
// Algorithm Z
// ==========================================================================
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR_Z : public CStreamSamplerWOR<ElementType, RNE>
{
public:
CStreamSamplerWOR_Z(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] RNE seed
void Reset() override;
private:
vector<double> m_vfW;
void DrawNext(size_t nSS) override; // [i] idx of sample set
};
// ==========================================================================
// Algorithm K
// ==========================================================================
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR_K : public CStreamSamplerWOR<ElementType, RNE>
{
public:
CStreamSamplerWOR_K(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] RNE seed
void Reset() override;
private:
const double m_fHs;
vector<double> m_vfW;
void DrawNext(size_t nSS) override; // [i] idx of sample set
};
// ==========================================================================
// Algorithm L
// ==========================================================================
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR_L : public CStreamSamplerWOR<ElementType, RNE>
{
public:
CStreamSamplerWOR_L(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] RNE seed
void Reset() override;
private:
vector<double> m_vfW;
void DrawNext(size_t nSS) override; // [i] idx of sample set
};
// ==========================================================================
// Algorithm M
// ==========================================================================
template <typename ElementType, typename RNE = mt19937_64>
class CStreamSamplerWOR_M : public CStreamSamplerWOR<ElementType, RNE>
{
public:
CStreamSamplerWOR_M(size_t nSampleSets , // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed = RandomSeed<RNE>() ); // [i] RNE seed
void Reset() override;
private:
const uint64_t nR ;
vector<bool > m_vbStep2 ;
vector<double > m_vfU, m_vfW, m_vfQ;
vector<uint64_t> m_vnT, m_vnCount ;
void DrawNext(size_t nSS) override; // [i] idx of sample set
};
// **************************************************************************
// implementation
// **************************************************************************
// ==========================================================================
// CStreamSampler
// ==========================================================================
template <typename ElementType, typename RNE>
CStreamSampler<ElementType, RNE>::CStreamSampler(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] type of seed: as type of 1st class template parameter of mt19937_64
: m_bValid(true),
m_nSampleSets(nSampleSets), m_nSetSize(nSetSize),
m_vSampleSets(nSampleSets, vector<ElementType>(nSetSize)),
m_nElements(0)
{
if (0 == nSampleSets) throw invalid_argument("Stream Sampler: 0 sample sets");
if (0 == nSetSize ) throw invalid_argument("Stream Sampler: sample size 0");
// Note: why using many RNEs?
// When using many sample sets, it is important to use an arbitrary k-dimensional equidistribution RNE
// (where every possible k-tuple of RNs will occur, and they will all occur the same number of times)
// Mersenne Twister 19337 is 623-dimensionally 32-bit / 312-dimensionally 64-bit equidistributed
// (see "Mersenne Twister: A 623-Dimensionally Equidistributed Uniform Pseudo-Random Number Generator" [Matsumoto, Nishimura 1998])
// If there are more than 312 sample sets, using the same RNE for all of them may result in biased samples.
// Therefore we prefer to use a different RNE (different seed) for each sample set.
m_vRndGen.resize(nSampleSets);
for (auto& RndGen : m_vRndGen)
RndGen.seed(nSeed++);
}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
void CStreamSampler<ElementType, RNE>::Reset()
{
if (m_vSampleSets.empty())
m_vSampleSets.assign(m_nSampleSets, vector<ElementType>(m_nSetSize));
m_nElements = 0;
m_bValid = true;
}
// --------------------------------------------------------------------------
// get the SampleSets and reset it (implemented using move semantics)
template <typename ElementType, typename RNE>
vector<vector<ElementType>> CStreamSampler<ElementType, RNE>::GetSampleSets()
{
m_bValid = false;
return move(m_vSampleSets);
}
// ==========================================================================
// CStreamSamplerWOR_R0
// ==========================================================================
template <typename ElementType, typename RNE>
uint64_t CStreamSamplerWOR_R0<ElementType, RNE>::AddElement(const ElementType& Element)
{
if (!this->m_bValid)
this->Reset();
if (this->m_nElements < this->m_nSetSize) // first m_nSetSize elements
for (auto& vSampleSet : this->m_vSampleSets)
vSampleSet[static_cast<size_t>(this->m_nElements)] = Element; // copy element into each SampleSet
else
for (size_t nSS = 0; nSS < this->m_nSampleSets; ++nSS) // for each sample set
{
auto r = uniform_int_distribution<uint64_t>(0, this->m_nElements)(this->m_vRndGen[nSS]); // inclusive range
if (r < this->m_nSetSize)
this->m_vSampleSets[nSS][static_cast<size_t>(r)] = Element; // copy element
}
++this->m_nElements;
return 0;
}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
uint64_t CStreamSamplerWOR_R0<ElementType, RNE>::AddElement(ElementType&& Element)
{
if (!this->m_bValid)
this->Reset();
if (this->m_nElements < this->m_nSetSize) // first m_nSetSize elements
{
for (size_t nSS = 1; nSS < this->m_nSampleSets; ++nSS) // copy element into each SampleSet except the 1st
this->m_vSampleSets[nSS][static_cast<size_t>(this->m_nElements)] = Element;
this->m_vSampleSets[0][static_cast<size_t>(this->m_nElements)] = move(Element); // move element into 1st SampleSet
}
else
{
ElementType* pS = nullptr;
for (size_t nSS = 0; nSS < this->m_nSampleSets; ++nSS) // for each sample set
{
auto r = uniform_int_distribution<uint64_t>(0, this->m_nElements)(this->m_vRndGen[nSS]); // inclusive range
if (r < this->m_nSetSize)
{
if (pS)
this->m_vSampleSets[nSS][static_cast<size_t>(r)] = *pS; // copy element
else
{
pS = &this->m_vSampleSets[nSS][static_cast<size_t>(r)];
*pS = move(Element); // move element
}
}
}
}
++this->m_nElements;
return 0;
}
// ==========================================================================
// CStreamSamplerWOR
// ==========================================================================
template <typename ElementType, typename RNE>
CStreamSamplerWOR<ElementType, RNE>::CStreamSamplerWOR(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] random seed
: CStreamSampler<ElementType, RNE>(nSampleSets, nSetSize, nSeed),
m_vnSkip(nSampleSets), m_vnNextIdx(nSampleSets, -1), m_nNextSkip(0)
{}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
void CStreamSamplerWOR<ElementType, RNE>::Reset()
{
CStreamSampler<ElementType, RNE>::Reset();
m_nNextSkip = 0;
m_vnSkip .assign(this->m_nSampleSets, 0);
m_vnNextIdx .assign(this->m_nSampleSets, -1);
}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
uint64_t CStreamSamplerWOR<ElementType, RNE>::AddElement(const ElementType& Element)
{
if (!this->m_bValid)
Reset();
if (this->m_nElements < this->m_nSetSize) // first m_nSetSize elements: fill reservoir
for (auto& vSampleSet : this->m_vSampleSets)
vSampleSet[static_cast<size_t>(this->m_nElements)] = Element; // copy element into each SampleSet
if (++this->m_nElements >= this->m_nSetSize) // after initial fill of reservoir
{
this->m_nElements += m_nNextSkip; // update according to number of elements skipped
for (size_t nSS = 0; nSS < this->m_nSampleSets; ++nSS) // for each sample set
if (m_vnSkip[nSS] -= m_nNextSkip) // decrease by number of elements skipped. still >0 ?
--m_vnSkip[nSS]; // skip current element
else
{
if (m_vnNextIdx[nSS] != static_cast<size_t>(-1)) // not on the (m_nSetSize-1)'th element
this->m_vSampleSets[nSS][m_vnNextIdx[nSS]] = Element; // copy element
DrawNext(nSS); // draw number of next elements to skip and next index to replace
}
}
m_nNextSkip = *min_element(begin(m_vnSkip), end(m_vnSkip));
return m_nNextSkip;
}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
uint64_t CStreamSamplerWOR<ElementType, RNE>::AddElement(ElementType&& Element)
{
if (!this->m_bValid)
Reset();
if (this->m_nElements < this->m_nSetSize) // first m_nSetSize elements: fill reservoir
{
for (size_t nSS = 1; nSS < this->m_nSampleSets; ++nSS) // copy element into each SampleSet except the 1st
this->m_vSampleSets[nSS][static_cast<size_t>(this->m_nElements)] = Element;
this->m_vSampleSets[0][static_cast<size_t>(this->m_nElements)] = move(Element); // move element into 1st SampleSet
}
if (++this->m_nElements >= this->m_nSetSize) // after initial fill of reservoir
{
this->m_nElements += m_nNextSkip; // update according to number of elements skipped
ElementType* pS = nullptr;
for (size_t nSS = 0; nSS < this->m_nSampleSets; ++nSS) // for each sample set
if (m_vnSkip[nSS] -= m_nNextSkip) // decrease by number of elements skipped. still >0 ?
--m_vnSkip[nSS]; // skip current element
else
{
if (m_vnNextIdx[nSS] != static_cast<size_t>(-1)) // not on the (m_nSetSize-1)'th element
{
if (pS)
this->m_vSampleSets[nSS][m_vnNextIdx[nSS]] = *pS; // copy element
else
{
pS = &this->m_vSampleSets[nSS][m_vnNextIdx[nSS]];
*pS = move(Element); // move element
}
}
DrawNext(nSS); // draw number of next elements to skip and next index to replace
}
}
m_nNextSkip = *min_element(begin(m_vnSkip), end(m_vnSkip));
return m_nNextSkip;
}
// ==========================================================================
// Algorithm R
// ==========================================================================
template <typename ElementType, typename RNE>
CStreamSamplerWOR_R<ElementType, RNE>::CStreamSamplerWOR_R(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] random seed
: CStreamSamplerWOR<ElementType, RNE>(nSampleSets, nSetSize, nSeed)
{}
// --------------------------------------------------------------------------
// draw number of next elements to skip and next index to replace
template <typename ElementType, typename RNE>
inline void CStreamSamplerWOR_R<ElementType, RNE>::DrawNext(size_t nSS) // [i] idx of sample set
{
while (true)
{
uint64_t nNextIdx = uniform_int_distribution<uint64_t>(0, this->m_nElements + this->m_vnSkip[nSS])(this->m_vRndGen[nSS]); // inclusive range
if (nNextIdx < this->m_nSetSize)
{
this->m_vnNextIdx[nSS] = static_cast<size_t>(nNextIdx);
break;
}
++this->m_vnSkip[nSS];
}
}
// ==========================================================================
// Algorithm X
// ==========================================================================
template <typename ElementType, typename RNE>
CStreamSamplerWOR_X<ElementType, RNE>::CStreamSamplerWOR_X(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] random seed
: CStreamSamplerWOR<ElementType, RNE>(nSampleSets, nSetSize, nSeed)
{}
// --------------------------------------------------------------------------
// draw number of next elements to skip and next index to replace
template <typename ElementType, typename RNE>
inline void CStreamSamplerWOR_X<ElementType, RNE>::DrawNext(size_t nSS) // [i] idx of sample set
{
double fHs = static_cast<double>(this->m_nElements + 1 - this->m_nSetSize) / (this->m_nElements + 1);
double fV = uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]);
while (fHs > fV) // increase skip till fHs <= fV
{
++this->m_vnSkip[nSS];
fHs *= static_cast<double>(this->m_nElements + 1 - this->m_nSetSize + this->m_vnSkip[nSS]) / (this->m_nElements + 1 + this->m_vnSkip[nSS]);
}
this->m_vnNextIdx[nSS] = uniform_int_distribution<size_t>(0, this->m_nSetSize - 1)(this->m_vRndGen[nSS]); // draw next index to replace
}
// ==========================================================================
// Algorithm Y
// ==========================================================================
template <typename ElementType, typename RNE>
CStreamSamplerWOR_Y<ElementType, RNE>::CStreamSamplerWOR_Y(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] random seed
: CStreamSamplerWOR<ElementType, RNE>(nSampleSets, nSetSize, nSeed)
{}
// --------------------------------------------------------------------------
// draw number of next elements to skip and next index to replace
template <typename ElementType, typename RNE>
inline void CStreamSamplerWOR_Y<ElementType, RNE>::DrawNext(size_t nSS) // [i] idx of sample set
{
double fHs = static_cast<double>(this->m_nElements + 1 - this->m_nSetSize) / (this->m_nElements + 1);
double fV = uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]);
while (fHs > fV) // increase skip till fHs <= fV
{
// naive
// double fHsPlus1 = fHs * (m_nElements + 1 - m_nSetSize + m_vnSkip[n] + 1) / (m_nElements + 1 + m_vnSkip[n] + 1); // H(s + 1)
// double fDeltaS = - (fHs - fV) / (fHsPlus1 - fHs); // Newton interpolation with discrete derivative
// optimized
const uint64_t nZ = this->m_nElements + 1 + this->m_vnSkip[nSS];
const double fDeltaS = (fHs - fV) * (nZ + 1) / (fHs * this->m_nSetSize);
const auto nS = static_cast<uint64_t>(ceil(fDeltaS));
// naive (no advantage over Algorithm X)
// for (uint64_t i = 1; i <= nS; ++i)
// fHs *= (double)(nZ - m_nSetSize + i) / (nZ + i);
// optimizated: when nS >= m_nSetSize we can cancel equal terms in the numerator and in the denominator
// so the loop size is always <= m_nSetSize
if (nS < this->m_nSetSize)
for (uint64_t i = 1; i <= nS; ++i)
fHs *= static_cast<double>(nZ - this->m_nSetSize + i) / (nZ + i);
else
for (uint64_t i = 0; i < this->m_nSetSize; ++i)
fHs *= static_cast<double>(nZ - i) / (nZ + nS - i);
this->m_vnSkip[nSS]+= nS;
}
this->m_vnNextIdx[nSS] = uniform_int_distribution<size_t>(0, this->m_nSetSize - 1)(this->m_vRndGen[nSS]); // draw next index to replace
}
// ==========================================================================
// Algorithm Z
// ==========================================================================
template <typename ElementType, typename RNE>
CStreamSamplerWOR_Z<ElementType, RNE>::CStreamSamplerWOR_Z(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] random seed
: CStreamSamplerWOR<ElementType, RNE>(nSampleSets, nSetSize, nSeed),
m_vfW(nSampleSets)
{
for (size_t nSS = 0; nSS < nSampleSets; ++nSS)
m_vfW[nSS] = pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), -1. / nSetSize); // initial W = exp(–log(random()) / nSetSize)
}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
void CStreamSamplerWOR_Z<ElementType, RNE>::Reset()
{
CStreamSamplerWOR<ElementType, RNE>::Reset();
for (size_t nSS = 0; nSS < this->m_nSampleSets; ++nSS)
m_vfW[nSS] = pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), -1. / this->m_nSetSize); // initial W = exp(–log(random()) / nSetSize)
}
// --------------------------------------------------------------------------
// draw number of next elements to skip and next index to replace
template <typename ElementType, typename RNE>
inline void CStreamSamplerWOR_Z<ElementType, RNE>::DrawNext(size_t nSS) // [i] idx of sample set
{
uint64_t& nS = this->m_vnSkip[nSS];
uint64_t nTerm = this->m_nElements - this->m_nSetSize + 1;
if (this->m_nElements <= 22ull * this->m_nSetSize) // execute algorithm X
{
double fHs = static_cast<double>(nTerm) / (this->m_nElements + 1);
double fV = uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]);
while (fHs > fV) // increase skip till fHs <= fV
{
++nS;
fHs *= static_cast<double>(nTerm+nS) / (this->m_nElements + 1 + nS);
}
}
else while (true)
{
double fU = uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]);
double fX = (m_vfW[nSS] - 1.) * this->m_nElements;
nS = static_cast<uint64_t>(floor(fX));
// test if u<=h(s)/cg(x)
double fRHS = (this->m_nElements + fX) / (nTerm+nS) * nTerm;
double fLHS = pow(fU * (this->m_nElements + 1.) / fRHS * (this->m_nElements + 1.) / nTerm, 1. / this->m_nSetSize);
fRHS /= this->m_nElements;
if (fLHS <= fRHS)
{
m_vfW[nSS] = fRHS / fLHS;
break;
}
// test if u<=f(s)/cg(x)
double fY = fU * (this->m_nElements + 1) / nTerm * (this->m_nElements + nS + 1) / (this->m_nElements + fX);
uint64_t nDenom = nTerm;
uint64_t nNumer = (this->m_nSetSize < nS) ? nTerm+nS : this->m_nElements + 1;
while (nNumer <= this->m_nElements + nS)
fY *= static_cast<double>(nNumer++) / nDenom++;
m_vfW[nSS] = pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), -1. / this->m_nSetSize); // generate W in advance
if (pow(fY, 1. / this->m_nSetSize) <= (this->m_nElements + fX) / this->m_nElements)
break;
}
this->m_vnNextIdx[nSS] = uniform_int_distribution<size_t>(0, this->m_nSetSize - 1)(this->m_vRndGen[nSS]); // draw next index to replace
}
// ==========================================================================
// Algorithm K
// ==========================================================================
template <typename ElementType, typename RNE>
CStreamSamplerWOR_K<ElementType, RNE>::CStreamSamplerWOR_K(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] random seed
: CStreamSamplerWOR<ElementType, RNE>(nSampleSets, nSetSize, nSeed),
m_fHs(static_cast<double>(nSetSize) / 2.), // a,b in Kim-Hung Li's paper
m_vfW(nSampleSets)
{
for (size_t nSS = 0; nSS < nSampleSets; ++nSS)
m_vfW[nSS] = pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), -1. / nSetSize); // initial W = exp(–log(random()) / nSetSize)
}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
void CStreamSamplerWOR_K<ElementType, RNE>::Reset()
{
CStreamSamplerWOR<ElementType, RNE>::Reset();
for (size_t nSS = 0; nSS < this->m_nSampleSets; ++nSS)
m_vfW[nSS] = pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), -1. / this->m_nSetSize); // initial W = exp(–log(random()) / nSetSize)
}
// --------------------------------------------------------------------------
// draw number of next elements to skip and next index to replace
template <typename ElementType, typename RNE>
inline void CStreamSamplerWOR_K<ElementType, RNE>::DrawNext(size_t nSS) // [i] idx of sample set
{
uint64_t& nS = this->m_vnSkip[nSS];
uint64_t nTerm = this->m_nElements - this->m_nSetSize + 1;
if (this->m_nElements <= 14ull * this->m_nSetSize) // execute algorithm X
{
double fHs = static_cast<double>(nTerm) / (this->m_nElements + 1);
double fV = uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]);
while (fHs > fV) // increase skip till fHs <= fV
{
++nS;
fHs *= static_cast<double>(nTerm + nS) / (this->m_nElements + 1 + nS);
}
}
else while (true)
{
double fU = uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]);
double fX = (m_vfW[nSS] - 1.) * (this->m_nElements - m_fHs);
nS = static_cast<uint64_t>(floor(fX));
// test if u<=h(s)/cg(x)
double fRHS = (this->m_nElements + fX - m_fHs) / (nTerm + nS) * nTerm / (this->m_nElements - m_fHs);
double fLHS = pow(fU * (this->m_nElements + 1.) / (nTerm - 1) / fRHS, 1. / this->m_nSetSize);
if (fLHS <= fRHS)
{
m_vfW[nSS] = fRHS / fLHS;
break;
}
// test if u<=f(s)/cg(x)
double fY = fU * (this->m_nElements - m_fHs) / (nTerm- 1 ) * (this->m_nElements + nS + 1) / (this->m_nElements - m_fHs + fX);
uint64_t nDenom = nTerm;
uint64_t nNumer = (this->m_nSetSize < nS) ? nTerm + nS : this->m_nElements + 1;
while (nNumer <= this->m_nElements + nS)
fY *= static_cast<double>(nNumer++) / nDenom++;
m_vfW[nSS] = pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), -1. / this->m_nSetSize); // generate W in advance
if (pow(fY, 1. / this->m_nSetSize) <= (this->m_nElements - m_fHs + fX) / (this->m_nElements - m_fHs))
break;
}
this->m_vnNextIdx[nSS] = uniform_int_distribution<size_t>(0, this->m_nSetSize - 1)(this->m_vRndGen[nSS]); // draw next index to replace
}
// ==========================================================================
// Algorithm L
// ==========================================================================
template <typename ElementType, typename RNE>
CStreamSamplerWOR_L<ElementType, RNE>::CStreamSamplerWOR_L(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] random seed
: CStreamSamplerWOR<ElementType, RNE>(nSampleSets, nSetSize, nSeed),
m_vfW(nSampleSets)
{
for (size_t nSS = 0; nSS < nSampleSets; ++nSS)
m_vfW[nSS] = pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), 1. / nSetSize); // initial W = exp(–log(random()) / nSetSize)
}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
void CStreamSamplerWOR_L<ElementType, RNE>::Reset()
{
CStreamSamplerWOR<ElementType, RNE>::Reset();
for (size_t nSS = 0; nSS < this->m_nSampleSets; ++nSS)
m_vfW[nSS] = pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), 1. / this->m_nSetSize); // initial W = exp(–log(random()) / nSetSize)
}
// --------------------------------------------------------------------------
// draw number of next elements to skip and next index to replace
template <typename ElementType, typename RNE>
inline void CStreamSamplerWOR_L<ElementType, RNE>::DrawNext(size_t nSS) // [i] idx of sample set
{
this->m_vnSkip [nSS] = static_cast<uint64_t>(floor(log(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS])) / log(1. - m_vfW[nSS])));
this->m_vnNextIdx[nSS] = uniform_int_distribution<size_t>(0, this->m_nSetSize - 1)(this->m_vRndGen[nSS]); // draw next index to replace
m_vfW [nSS] *= pow(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]), 1. / this->m_nSetSize); // generate W in advance
}
// ==========================================================================
// Algorithm M
// ==========================================================================
// produce a random floating-point value according to a beta distribution
// Based on "Generating Beta Variates with Nonintegral Shape Parameters" [R. C. H. Cheng, 1978] algorithm BB
// handles only cases where min(a0, b0) > 1
template <typename RNE>
inline double beta_distribution(RNE& engine, double a0, double b0)
{
double a = min(a0, b0);
double b = max(a0, b0);
double alpha = a + b;
double beta = sqrt((alpha - 2) / (2. * a * b - alpha));
double gamma = a + 1 / beta;
double w;
while (true)
{
double u1 = uniform_real_distribution<double>(0, 1)(engine);
double u2 = uniform_real_distribution<double>(0, 1)(engine);
double v = beta * log(u1 / (1. - u1));
w = a * exp(v);
double z = u1 * u1 * u2;
double r = gamma * v - 1.3862943611198906188344642429164; // const = log(4)
double s = a + r - w;
if (s + 2.6094379124341003746007593332262 >= 5. * z) // const = log(5) + 1
break;
double t = log(z);
if (s >= t)
break;
if (r + alpha * log(alpha / (b + w)) >= t)
break;
}
return (a == a0) ? w / (b + w) : b / (b + w);
}
// --------------------------------------------------------------------------
constexpr double fStreamSamplerWOR_M_Theta = 10.5; // see table 2 in Li's paper
constexpr double fStreamSamplerWOR_M_Tau = 2.07;
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
CStreamSamplerWOR_M<ElementType, RNE>::CStreamSamplerWOR_M(size_t nSampleSets, // [i] number of independent sample sets
size_t nSetSize , // [i] size of each sample set
typename RNE::result_type nSeed ) // [i] random seed
: CStreamSamplerWOR<ElementType, RNE>(nSampleSets, nSetSize, nSeed),
nR(static_cast<uint64_t>(floor(fStreamSamplerWOR_M_Tau * sqrt(nSetSize)))),
m_vbStep2(nSampleSets), m_vfU(nSampleSets), m_vfW(nSampleSets), m_vfQ(nSampleSets), m_vnT(nSampleSets), m_vnCount(nSampleSets)
{
double fH = 0; // sum(1 / u); u = nSetSize ... nSetSize+nR
for (uint64_t i = nSetSize; i <= nSetSize + nR; ++i)
fH += 1. / i;
auto nC = static_cast<uint64_t>(floor(fStreamSamplerWOR_M_Theta * (fStreamSamplerWOR_M_Tau * fStreamSamplerWOR_M_Tau / 2. + 1. + nR) / fH - nSetSize));
for (size_t nSS = 0; nSS < nSampleSets; ++nSS)
{
m_vfW [nSS] = beta_distribution(this->m_vRndGen[nSS], nSetSize + 0., nC + 1.);
m_vfU [nSS] = uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]);
m_vnCount[nSS] = nC;
}
}
// --------------------------------------------------------------------------
template <typename ElementType, typename RNE>
void CStreamSamplerWOR_M<ElementType, RNE>::Reset()
{
CStreamSamplerWOR<ElementType, RNE>::Reset();
m_vbStep2.assign(this->m_nSampleSets, false);
m_vfQ .assign(this->m_nSampleSets, 0. );
m_vnT .assign(this->m_nSampleSets, 0 );
double fH = 0; // sum(1 / u); u = nSetSize ... nSetSize+nR
for (uint64_t i = this->m_nSetSize; i <= this->m_nSetSize + nR; ++i)
fH += 1. / i;
auto nC = static_cast<uint64_t>(floor(fStreamSamplerWOR_M_Theta * (fStreamSamplerWOR_M_Tau * fStreamSamplerWOR_M_Tau / 2. + 1. + nR) / fH - this->m_nSetSize));
for (size_t nSS = 0; nSS < this->m_nSampleSets; ++nSS)
{
m_vfW [nSS] = beta_distribution(this->m_vRndGen[nSS], this->m_nSetSize + 0., nC + 1.);
m_vfU [nSS] = uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS]);
m_vnCount[nSS] = nC;
}
}
// --------------------------------------------------------------------------
// draw number of next elements to skip and next index to replace
template <typename ElementType, typename RNE>
inline void CStreamSamplerWOR_M<ElementType, RNE>::DrawNext(size_t nSS) // [i] idx of sample set
{
while (m_vnCount[nSS] > 0)
{
if (m_vbStep2[nSS])
this->m_vnSkip[nSS] += static_cast<uint64_t>(floor(log(uniform_real_distribution<double>(0, 1)(this->m_vRndGen[nSS])) / m_vfQ[nSS]));
--m_vnCount [nSS];
m_vfU [nSS] *= (1. + static_cast<double>(this->m_nSetSize) / ++m_vnT[nSS]);
if (1 <= m_vfU[nSS])
{
m_vfU [nSS] = uniform_real_distribution<double>(0, 1 )(this->m_vRndGen[nSS]);
this->m_vnNextIdx[nSS] = uniform_int_distribution<size_t >(0, this->m_nSetSize - 1)(this->m_vRndGen[nSS]); // draw next index to replace
return;
}
++this->m_vnSkip[nSS];
}
m_vbStep2 [nSS] = true;
m_vnCount [nSS] = nR;
m_vfQ [nSS] = log(1. - m_vfW[nSS]);
this->m_vnSkip [nSS] += static_cast<uint64_t>(floor(log(m_vfU[nSS]) / m_vfQ[nSS]));
m_vnT [nSS] = 0;
m_vfW [nSS] *= beta_distribution(this->m_vRndGen[nSS], this->m_nSetSize + 0., nR + 1.);
m_vfU [nSS] = uniform_real_distribution<double>(0, 1 )(this->m_vRndGen[nSS]);
this->m_vnNextIdx[nSS] = uniform_int_distribution <size_t>(0, this->m_nSetSize - 1)(this->m_vRndGen[nSS]); // draw next index to replace
}
// ==========================================================================
} // namespace StreamSampler