src/intervalmap.h - platform/external/perf_data_converter - Git at Google

 /*
  * Copyright (c) 2016, Google Inc.
  * All rights reserved.
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef PERFTOOLS_INTERVALMAP_H_
 #define PERFTOOLS_INTERVALMAP_H_

 #include <cstdlib>
 #include <iostream>
 #include <iterator>
 #include <map>
 #include <sstream>

 #include "int_compat.h"

 namespace perftools {

 template <class V>
 class IntervalMap {
  public:
   IntervalMap();

   // Set [start, limit) to value. If this interval overlaps one currently in the
   // map, the overlapping section will be overwritten by the new interval.
   void Set(uint64 start, uint64 limit, const V& value);

   // Finds the value associated with the interval containing key. Returns false
   // if no interval contains key.
   bool Lookup(uint64 key, V* value) const;

   // Find the interval containing key, or the next interval containing
   // something greater than key. Returns false if one is not found, otherwise
   // it sets start, limit, and value to the corresponding values from the
   // interval.
   bool FindNext(uint64 key, uint64* start, uint64* limit, V* value) const;

   // Remove all entries from the map.
   void Clear();

   // Clears everything in the interval map from [clear_start,
   // clear_limit). This may cut off sections or entire intervals in
   // the map. This will invalidate iterators to intervals which have a
   // start value residing in [clear_start, clear_limit).
   void ClearInterval(uint64 clear_start, uint64 clear_limit);

   uint64 Size() const;

  private:
   struct Value {
     uint64 limit;
     V value;
   };

   using MapIter = typename std::map<uint64, Value>::iterator;
   using ConstMapIter = typename std::map<uint64, Value>::const_iterator;

   // For an interval to be valid, start must be strictly less than limit.
   void AssertValidInterval(uint64 start, uint64 limit) const;

   // Returns an iterator pointing to the interval containing the given key, or
   // end() if one was not found.
   ConstMapIter GetContainingInterval(uint64 point) const {
     auto bound = interval_start_.upper_bound(point);
     if (!Decrement(&bound)) {
       return interval_start_.end();
     }
     if (bound->second.limit <= point) {
       return interval_start_.end();
     }
     return bound;
   }

   MapIter GetContainingInterval(uint64 point) {
     auto bound = interval_start_.upper_bound(point);
     if (!Decrement(&bound)) {
       return interval_start_.end();
     }
     if (bound->second.limit <= point) {
       return interval_start_.end();
     }
     return bound;
   }

   // Decrements the provided iterator to interval_start_, or returns false if
   // iter == begin().
   bool Decrement(ConstMapIter* iter) const;
   bool Decrement(MapIter* iter);

   // Removes everything in the interval map from [remove_start,
   // remove_limit). This may cut off sections or entire intervals in
   // the map. This will invalidate iterators to intervals which have a
   // start value residing in [remove_start, remove_limit).
   void RemoveInterval(uint64 remove_start, uint64 remove_limit);

   void Insert(uint64 start, uint64 limit, const V& value);

   // Split an interval into two intervals, [iter.start, point) and
   // [point, iter.limit). If point is not within (iter.start, point) or iter is
   // end(), it is a noop.
   void SplitInterval(MapIter iter, uint64 point);

   // Map from the start of the interval to the limit of the interval and the
   // corresponding value.
   std::map<uint64, Value> interval_start_;
 };

 template <class V>
 IntervalMap<V>::IntervalMap() {}

 template <class V>
 void IntervalMap<V>::Set(uint64 start, uint64 limit, const V& value) {
   AssertValidInterval(start, limit);
   RemoveInterval(start, limit);
   Insert(start, limit, value);
 }

 template <class V>
 bool IntervalMap<V>::Lookup(uint64 key, V* value) const {
   const auto contain = GetContainingInterval(key);
   if (contain == interval_start_.end()) {
     return false;
   }
   *value = contain->second.value;
   return true;
 }

 template <class V>
 bool IntervalMap<V>::FindNext(uint64 key, uint64* start, uint64* limit,
                               V* value) const {
   auto iter = interval_start_.upper_bound(key);
   if (iter == interval_start_.end()) {
     return false;
   }
   *start = iter->first;
   *limit = iter->second.limit;
   *value = iter->second.value;
   return true;
 }

 template <class V>
 void IntervalMap<V>::Clear() {
   interval_start_.clear();
 }

 template <class V>
 void IntervalMap<V>::ClearInterval(uint64 clear_start, uint64 clear_limit) {
   AssertValidInterval(clear_start, clear_limit);
   RemoveInterval(clear_start, clear_limit);
 }

 template <class V>
 uint64 IntervalMap<V>::Size() const {
   return interval_start_.size();
 }

 template <class V>
 void IntervalMap<V>::RemoveInterval(uint64 remove_start, uint64 remove_limit) {
   if (remove_start >= remove_limit) {
     return;
   }
   // It starts by splitting intervals that will only be partly cleared into two,
   // where one of those will be fully cleared and the other will not be cleared.
   SplitInterval(GetContainingInterval(remove_limit), remove_limit);
   SplitInterval(GetContainingInterval(remove_start), remove_start);

   auto remove_interval_start = interval_start_.lower_bound(remove_start);
   auto remove_interval_end = interval_start_.lower_bound(remove_limit);
   // Note that if there are no intervals to be cleared, then
   // clear_interval_start == clear_interval_end and the erase will be a noop.
   interval_start_.erase(remove_interval_start, remove_interval_end);
 }

 template <class V>
 void IntervalMap<V>::SplitInterval(MapIter iter, uint64 point) {
   if (iter == interval_start_.end() || point <= iter->first ||
       point >= iter->second.limit) {
     return;
   }
   const auto larger_limit = iter->second.limit;
   iter->second.limit = point;
   Insert(point, larger_limit, iter->second.value);
 }

 template <class V>
 bool IntervalMap<V>::Decrement(ConstMapIter* iter) const {
   if ((*iter) == interval_start_.begin()) {
     return false;
   }
   --(*iter);
   return true;
 }

 template <class V>
 bool IntervalMap<V>::Decrement(MapIter* iter) {
   if ((*iter) == interval_start_.begin()) {
     return false;
   }
   --(*iter);
   return true;
 }

 template <class V>
 void IntervalMap<V>::Insert(uint64 start, uint64 limit, const V& value) {
   interval_start_.emplace(std::pair<uint64, Value>{start, {limit, value}});
 }

 template <class V>
 void IntervalMap<V>::AssertValidInterval(uint64 start, uint64 limit) const {
   if (start >= limit) {
     std::cerr << "Invalid interval. Start may not be >= limit." << std::endl
               << "Start: " << start << std::endl
               << "Limit: " << limit << std::endl;
     abort();
   }
 }

 }  // namespace perftools

 #endif  // PERFTOOLS_INTERVALMAP_H_
	/*
	* Copyright (c) 2016, Google Inc.
	* All rights reserved.
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef PERFTOOLS_INTERVALMAP_H_
	#define PERFTOOLS_INTERVALMAP_H_

	#include <cstdlib>
	#include <iostream>
	#include <iterator>
	#include <map>
	#include <sstream>

	#include "int_compat.h"

	namespace perftools {

	template <class V>
	class IntervalMap {
	public:
	IntervalMap();

	// Set [start, limit) to value. If this interval overlaps one currently in the
	// map, the overlapping section will be overwritten by the new interval.
	void Set(uint64 start, uint64 limit, const V& value);

	// Finds the value associated with the interval containing key. Returns false
	// if no interval contains key.
	bool Lookup(uint64 key, V* value) const;

	// Find the interval containing key, or the next interval containing
	// something greater than key. Returns false if one is not found, otherwise
	// it sets start, limit, and value to the corresponding values from the
	// interval.
	bool FindNext(uint64 key, uint64* start, uint64* limit, V* value) const;

	// Remove all entries from the map.
	void Clear();

	// Clears everything in the interval map from [clear_start,
	// clear_limit). This may cut off sections or entire intervals in
	// the map. This will invalidate iterators to intervals which have a
	// start value residing in [clear_start, clear_limit).
	void ClearInterval(uint64 clear_start, uint64 clear_limit);

	uint64 Size() const;

	private:
	struct Value {
	uint64 limit;
	V value;
	};

	using MapIter = typename std::map<uint64, Value>::iterator;
	using ConstMapIter = typename std::map<uint64, Value>::const_iterator;

	// For an interval to be valid, start must be strictly less than limit.
	void AssertValidInterval(uint64 start, uint64 limit) const;

	// Returns an iterator pointing to the interval containing the given key, or
	// end() if one was not found.
	ConstMapIter GetContainingInterval(uint64 point) const {
	auto bound = interval_start_.upper_bound(point);
	if (!Decrement(&bound)) {
	return interval_start_.end();
	}
	if (bound->second.limit <= point) {
	return interval_start_.end();
	}
	return bound;
	}

	MapIter GetContainingInterval(uint64 point) {
	auto bound = interval_start_.upper_bound(point);
	if (!Decrement(&bound)) {
	return interval_start_.end();
	}
	if (bound->second.limit <= point) {
	return interval_start_.end();
	}
	return bound;
	}

	// Decrements the provided iterator to interval_start_, or returns false if
	// iter == begin().
	bool Decrement(ConstMapIter* iter) const;
	bool Decrement(MapIter* iter);

	// Removes everything in the interval map from [remove_start,
	// remove_limit). This may cut off sections or entire intervals in
	// the map. This will invalidate iterators to intervals which have a
	// start value residing in [remove_start, remove_limit).
	void RemoveInterval(uint64 remove_start, uint64 remove_limit);

	void Insert(uint64 start, uint64 limit, const V& value);

	// Split an interval into two intervals, [iter.start, point) and
	// [point, iter.limit). If point is not within (iter.start, point) or iter is
	// end(), it is a noop.
	void SplitInterval(MapIter iter, uint64 point);

	// Map from the start of the interval to the limit of the interval and the
	// corresponding value.
	std::map<uint64, Value> interval_start_;
	};

	template <class V>
	IntervalMap<V>::IntervalMap() {}

	template <class V>
	void IntervalMap<V>::Set(uint64 start, uint64 limit, const V& value) {
	AssertValidInterval(start, limit);
	RemoveInterval(start, limit);
	Insert(start, limit, value);
	}

	template <class V>
	bool IntervalMap<V>::Lookup(uint64 key, V* value) const {
	const auto contain = GetContainingInterval(key);
	if (contain == interval_start_.end()) {
	return false;
	}
	*value = contain->second.value;
	return true;
	}

	template <class V>
	bool IntervalMap<V>::FindNext(uint64 key, uint64* start, uint64* limit,
	V* value) const {
	auto iter = interval_start_.upper_bound(key);
	if (iter == interval_start_.end()) {
	return false;
	}
	*start = iter->first;
	*limit = iter->second.limit;
	*value = iter->second.value;
	return true;
	}

	template <class V>
	void IntervalMap<V>::Clear() {
	interval_start_.clear();
	}

	template <class V>
	void IntervalMap<V>::ClearInterval(uint64 clear_start, uint64 clear_limit) {
	AssertValidInterval(clear_start, clear_limit);
	RemoveInterval(clear_start, clear_limit);
	}

	template <class V>
	uint64 IntervalMap<V>::Size() const {
	return interval_start_.size();
	}

	template <class V>
	void IntervalMap<V>::RemoveInterval(uint64 remove_start, uint64 remove_limit) {
	if (remove_start >= remove_limit) {
	return;
	}
	// It starts by splitting intervals that will only be partly cleared into two,
	// where one of those will be fully cleared and the other will not be cleared.
	SplitInterval(GetContainingInterval(remove_limit), remove_limit);
	SplitInterval(GetContainingInterval(remove_start), remove_start);

	auto remove_interval_start = interval_start_.lower_bound(remove_start);
	auto remove_interval_end = interval_start_.lower_bound(remove_limit);
	// Note that if there are no intervals to be cleared, then
	// clear_interval_start == clear_interval_end and the erase will be a noop.
	interval_start_.erase(remove_interval_start, remove_interval_end);
	}

	template <class V>
	void IntervalMap<V>::SplitInterval(MapIter iter, uint64 point) {
	if (iter == interval_start_.end() \|\| point <= iter->first \|\|
	point >= iter->second.limit) {
	return;
	}
	const auto larger_limit = iter->second.limit;
	iter->second.limit = point;
	Insert(point, larger_limit, iter->second.value);
	}

	template <class V>
	bool IntervalMap<V>::Decrement(ConstMapIter* iter) const {
	if ((*iter) == interval_start_.begin()) {
	return false;
	}
	--(*iter);
	return true;
	}

	template <class V>
	bool IntervalMap<V>::Decrement(MapIter* iter) {
	if ((*iter) == interval_start_.begin()) {
	return false;
	}
	--(*iter);
	return true;
	}

	template <class V>
	void IntervalMap<V>::Insert(uint64 start, uint64 limit, const V& value) {
	interval_start_.emplace(std::pair<uint64, Value>{start, {limit, value}});
	}

	template <class V>
	void IntervalMap<V>::AssertValidInterval(uint64 start, uint64 limit) const {
	if (start >= limit) {
	std::cerr << "Invalid interval. Start may not be >= limit." << std::endl
	<< "Start: " << start << std::endl
	<< "Limit: " << limit << std::endl;
	abort();
	}
	}

	} // namespace perftools

	#endif // PERFTOOLS_INTERVALMAP_H_