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running_stat.h
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running_stat.h
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// Copyright 2010-2018 Google LLC
// 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.
#ifndef OR_TOOLS_UTIL_RUNNING_STAT_H_
#define OR_TOOLS_UTIL_RUNNING_STAT_H_
#include <deque>
#include "ortools/base/logging.h"
#include "ortools/base/macros.h"
namespace operations_research {
// Simple class to compute the average over a fixed size window of an integer
// stream.
class RunningAverage {
public:
// Initialize the class with the maximum window size.
// It must be positive (this is CHECKed).
explicit RunningAverage(int window_size = 1);
// Resets the class to the exact same state as if it was just constructed with
// the given window size.
void Reset(int window_size);
// Adds the next integer of the stream.
void Add(int value);
// Returns the average of all the values added so far or zero if no values
// where added.
double GlobalAverage() const;
// Returns the average of the values in the current window or zero if the
// current window is empty.
double WindowAverage() const;
// Returns true iff the current window size is equal to the one specified in
// the constructor.
bool IsWindowFull() const;
// Clears the current window.
void ClearWindow();
private:
int window_size_;
int num_adds_;
double global_sum_;
double local_sum_;
std::deque<int> values_;
DISALLOW_COPY_AND_ASSIGN(RunningAverage);
};
// Simple class to compute efficiently the maximum over a fixed size window
// of a numeric stream. This works in constant average amortized time.
template <class Number = double>
class RunningMax {
public:
// Takes the size of the running window. The size must be positive.
explicit RunningMax(int window_size);
// Processes a new element from the stream.
void Add(Number value);
// Returns the current maximum element in the window.
// An element must have been added before calling this function.
Number GetCurrentMax();
private:
const int window_size_;
// Values in the current window.
std::vector<Number> values_;
// Index of the last added element in the window.
int last_index_;
// Index of the current maximum element.
int max_index_;
DISALLOW_COPY_AND_ASSIGN(RunningMax);
};
// ################## Implementations below #####################
inline RunningAverage::RunningAverage(int window_size)
: window_size_(window_size),
num_adds_(0),
global_sum_(0.0),
local_sum_(0.0) {
CHECK_GT(window_size_, 0);
}
inline void RunningAverage::Reset(int window_size) {
window_size_ = window_size;
num_adds_ = 0;
global_sum_ = 0.0;
ClearWindow();
}
inline void RunningAverage::Add(int value) {
++num_adds_;
global_sum_ += value;
local_sum_ += value;
values_.push_back(value);
if (values_.size() > window_size_) {
local_sum_ -= values_.front();
values_.pop_front();
}
}
inline double RunningAverage::GlobalAverage() const {
return num_adds_ == 0 ? 0.0 : global_sum_ / static_cast<double>(num_adds_);
}
inline double RunningAverage::WindowAverage() const {
return values_.empty() ? 0.0
: local_sum_ / static_cast<double>(values_.size());
}
inline void RunningAverage::ClearWindow() {
local_sum_ = 0.0;
values_.clear();
}
inline bool RunningAverage::IsWindowFull() const {
return values_.size() == window_size_;
}
template <class Number>
RunningMax<Number>::RunningMax(int window_size)
: window_size_(window_size), values_(), last_index_(0), max_index_(0) {
DCHECK_GT(window_size, 0);
}
template <class Number>
void RunningMax<Number>::Add(Number value) {
if (values_.size() < window_size_) {
// Starting phase until values_ reaches its final size.
// Note that last_index_ stays at 0 during this phase.
if (values_.empty() || value >= GetCurrentMax()) {
max_index_ = values_.size();
}
values_.push_back(value);
return;
}
// We are in the steady state.
DCHECK_EQ(values_.size(), window_size_);
// Note the use of >= instead of > to get the O(1) behavior in presence of
// many identical values.
if (value >= GetCurrentMax()) {
max_index_ = last_index_;
values_[last_index_] = value;
} else {
values_[last_index_] = value;
if (last_index_ == max_index_) {
// We need to recompute the max.
// Note that this happens only if value was strictly lower than
// GetCurrentMax() in the last window_size_ updates.
max_index_ = 0;
Number max_value = values_[max_index_];
for (int i = 1; i < values_.size(); ++i) {
if (values_[i] > max_value) {
max_value = values_[i];
max_index_ = i;
}
}
}
}
if (++last_index_ == window_size_) {
last_index_ = 0;
}
}
template <class Number>
Number RunningMax<Number>::GetCurrentMax() {
DCHECK(!values_.empty());
return values_[max_index_];
}
} // namespace operations_research
#endif // OR_TOOLS_UTIL_RUNNING_STAT_H_