runtime/platform/priority_queue.h - sdk.git - Git at Google

 // Copyright (c) 2020, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef RUNTIME_PLATFORM_PRIORITY_QUEUE_H_
 #define RUNTIME_PLATFORM_PRIORITY_QUEUE_H_

 #include "platform/assert.h"
 #include "platform/globals.h"
 #include "platform/hashmap.h"
 #include "platform/utils.h"

 namespace dart {

 // A min-priority queue with deletion support.
 //
 // The [PriorityQueue] allows insertion of entries with a priority [P] and a
 // value [V]. The minimum element can be queried in O(1) time.
 // Insertion/Deletion operations have O(N) time.
 //
 // In addition to the normal insert/minimum/remove-minimum operations this
 // priority queue allows deletion-by-value. We have therefore an invariant
 // is that the value must be unique amongst all entries.
 template <typename P, typename V>
 class PriorityQueue {
  public:
   static const intptr_t kMinimumSize = 16;

   struct Entry {
     P priority;
     V value;
   };

   PriorityQueue() : hashmap_(&MatchFun, kMinimumSize) {
     min_heap_size_ = kMinimumSize;
     min_heap_ =
         reinterpret_cast<Entry*>(malloc(sizeof(Entry) * min_heap_size_));
     if (min_heap_ == nullptr) FATAL("Cannot allocate memory.");
     size_ = 0;
   }

   ~PriorityQueue() { free(min_heap_); }

   // Whether the queue is empty.
   bool IsEmpty() const { return size_ == 0; }

   // Inserts a new entry with [priority] and [value], requires there to be no
   // existing entry with given [value].
   void Insert(const P& priority, const V& value) {
     ASSERT(!ContainsValue(value));

     if (size_ == min_heap_size_) {
       Resize(min_heap_size_ << 1);
     }

     Set(size_, {priority, value});
     BubbleUp(size_);

     size_++;
   }

   // Returns a reference to the minimum entry.
   //
   // The caller can access it's priority and value in read-only mode only.
   const Entry& Minimum() const {
     ASSERT(!IsEmpty());
     return min_heap_[0];
   }

   // Removes the minimum entry.
   void RemoveMinimum() {
     ASSERT(!IsEmpty());
     RemoveAt(0);
   }

   // Removes an existing entry with the given [value].
   //
   // Returns true if such an entry was removed.
   bool RemoveByValue(const V& value) {
     auto entry = FindMapEntry(value);
     if (entry != nullptr) {
       const intptr_t offset = ValueOfMapEntry(entry);
       RemoveAt(offset);

       ASSERT(hashmap_.size() == size_);
       return true;
     }
     return false;
   }

   // Whether the priority queue contains an entry with the given [value].
   bool ContainsValue(const V& value) { return FindMapEntry(value) != nullptr; }

   // Changes the priority of an existing entry with given [value] or adds a
   // new entry.
   bool InsertOrChangePriority(const P& priority, const V& value) {
     auto map_entry = FindMapEntry(value);
     if (map_entry == nullptr) {
       Insert(priority, value);
       return true;
     }

     const intptr_t offset = ValueOfMapEntry(map_entry);
     ASSERT(offset < size_);

     Entry& entry = min_heap_[offset];
     entry.priority = priority;
     if (offset == 0) {
       BubbleDown(offset);
     } else {
       intptr_t parent = (offset - 1) / 2;
       intptr_t diff = entry.priority - min_heap_[parent].priority;
       if (diff < 0) {
         BubbleUp(offset);
       } else if (diff > 0) {
         BubbleDown(offset);
       }
     }
     return false;
   }

 #ifdef TESTING
   intptr_t min_heap_size() { return min_heap_size_; }
 #endif  // TESTING

  private:
   // Utility functions dealing with the SimpleHashMap interface.
   static bool MatchFun(void* key1, void* key2) { return key1 == key2; }

   SimpleHashMap::Entry* FindMapEntry(const V& key, bool insert = false) {
     return hashmap_.Lookup(CastKey(key), HashKey(key), insert);
   }
   void RemoveMapEntry(const V& key) {
     ASSERT(FindMapEntry(key) != nullptr);
     hashmap_.Remove(CastKey(key), HashKey(key));
   }
   void SetMapEntry(const V& key, intptr_t value) {
     FindMapEntry(key, /*insert=*/true)->value = reinterpret_cast<void*>(value);
   }
   static uint32_t HashKey(const V& key) {
     return static_cast<uint32_t>(reinterpret_cast<intptr_t>(CastKey(key)));
   }
   static intptr_t ValueOfMapEntry(SimpleHashMap::Entry* entry) {
     return reinterpret_cast<intptr_t>(entry->value);
   }
   static void* CastKey(const V& key) {
     return reinterpret_cast<void*>((const_cast<V&>(key)));
   }

   void RemoveAt(intptr_t offset) {
     ASSERT(offset < size_);

     size_--;

     if (offset == size_) {
       RemoveMapEntry(min_heap_[offset].value);
     } else {
       Replace(offset, size_);
       BubbleDown(offset);
     }

     if (size_ <= (min_heap_size_ >> 2) &&
         kMinimumSize <= (min_heap_size_ >> 1)) {
       Resize(min_heap_size_ >> 1);
     }
   }

   void BubbleUp(intptr_t offset) {
     while (true) {
       if (offset == 0) return;

       intptr_t parent = (offset - 1) / 2;
       if (min_heap_[parent].priority > min_heap_[offset].priority) {
         Swap(parent, offset);
       }
       offset = parent;
     }
   }

   void BubbleDown(intptr_t offset) {
     while (true) {
       intptr_t left_child_index = 2 * offset + 1;
       bool has_left_child = left_child_index < size_;

       if (!has_left_child) return;

       intptr_t smallest_index = offset;

       if (min_heap_[left_child_index].priority < min_heap_[offset].priority) {
         smallest_index = left_child_index;
       }

       intptr_t right_child_index = left_child_index + 1;
       bool has_right_child = right_child_index < size_;
       if (has_right_child) {
         if (min_heap_[right_child_index].priority <
             min_heap_[smallest_index].priority) {
           smallest_index = right_child_index;
         }
       }

       if (offset == smallest_index) {
         return;
       }

       Swap(offset, smallest_index);
       offset = smallest_index;
     }
   }

   void Set(intptr_t offset1, const Entry& entry) {
     min_heap_[offset1] = entry;
     SetMapEntry(entry.value, offset1);
   }

   void Swap(intptr_t offset1, intptr_t offset2) {
     Entry temp = min_heap_[offset1];
     min_heap_[offset1] = min_heap_[offset2];
     min_heap_[offset2] = temp;

     SetMapEntry(min_heap_[offset1].value, offset1);
     SetMapEntry(min_heap_[offset2].value, offset2);
   }

   void Replace(intptr_t index, intptr_t with_other) {
     RemoveMapEntry(min_heap_[index].value);

     const Entry& entry = min_heap_[with_other];
     SetMapEntry(entry.value, index);
     min_heap_[index] = entry;
   }

   void Resize(intptr_t new_min_heap_size) {
     ASSERT(size_ < new_min_heap_size);
     ASSERT(new_min_heap_size != min_heap_size_);

     Entry* new_backing = reinterpret_cast<Entry*>(
         realloc(min_heap_, sizeof(Entry) * new_min_heap_size));

     if (new_backing == NULL) FATAL("Cannot allocate memory.");

     min_heap_ = new_backing;
     min_heap_size_ = new_min_heap_size;
   }

   // The array is representing a tree structure with guaranteed log(n) height.
   // It has the property that the value of node N is always equal or smaller
   // than the value of N's children. Furthermore it is a "dense" tree in the
   // sense that all rows/layers of the tree are fully occupied except the last
   // one. The way to represent such "dense" trees is via an array that allows
   // finding left/right children by <2*index+1><2*index+2> and the parent by
   // <(index-1)/2>.
   //
   // Insertion operations can be performed by adding one more entry at the end
   // (bottom right) and bubbling it up until the tree invariant is satisfied
   // again.
   //
   // Deletion operations can be performed by replacing the minimum element
   // (first entry) by the last entry (bottom right) and bubbling it down until
   // the tree invariant is satisified again.
   Entry* min_heap_;
   intptr_t min_heap_size_;
   intptr_t size_;
   SimpleHashMap hashmap_;
 };

 }  // namespace dart

 #endif  // RUNTIME_PLATFORM_PRIORITY_QUEUE_H_
	// Copyright (c) 2020, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef RUNTIME_PLATFORM_PRIORITY_QUEUE_H_
	#define RUNTIME_PLATFORM_PRIORITY_QUEUE_H_

	#include "platform/assert.h"
	#include "platform/globals.h"
	#include "platform/hashmap.h"
	#include "platform/utils.h"

	namespace dart {

	// A min-priority queue with deletion support.
	//
	// The [PriorityQueue] allows insertion of entries with a priority [P] and a
	// value [V]. The minimum element can be queried in O(1) time.
	// Insertion/Deletion operations have O(N) time.
	//
	// In addition to the normal insert/minimum/remove-minimum operations this
	// priority queue allows deletion-by-value. We have therefore an invariant
	// is that the value must be unique amongst all entries.
	template <typename P, typename V>
	class PriorityQueue {
	public:
	static const intptr_t kMinimumSize = 16;

	struct Entry {
	P priority;
	V value;
	};

	PriorityQueue() : hashmap_(&MatchFun, kMinimumSize) {
	min_heap_size_ = kMinimumSize;
	min_heap_ =
	reinterpret_cast<Entry>(malloc(sizeof(Entry) min_heap_size_));
	if (min_heap_ == nullptr) FATAL("Cannot allocate memory.");
	size_ = 0;
	}

	~PriorityQueue() { free(min_heap_); }

	// Whether the queue is empty.
	bool IsEmpty() const { return size_ == 0; }

	// Inserts a new entry with [priority] and [value], requires there to be no
	// existing entry with given [value].
	void Insert(const P& priority, const V& value) {
	ASSERT(!ContainsValue(value));

	if (size_ == min_heap_size_) {
	Resize(min_heap_size_ << 1);
	}

	Set(size_, {priority, value});
	BubbleUp(size_);

	size_++;
	}

	// Returns a reference to the minimum entry.
	//
	// The caller can access it's priority and value in read-only mode only.
	const Entry& Minimum() const {
	ASSERT(!IsEmpty());
	return min_heap_[0];
	}

	// Removes the minimum entry.
	void RemoveMinimum() {
	ASSERT(!IsEmpty());
	RemoveAt(0);
	}

	// Removes an existing entry with the given [value].
	//
	// Returns true if such an entry was removed.
	bool RemoveByValue(const V& value) {
	auto entry = FindMapEntry(value);
	if (entry != nullptr) {
	const intptr_t offset = ValueOfMapEntry(entry);
	RemoveAt(offset);

	ASSERT(hashmap_.size() == size_);
	return true;
	}
	return false;
	}

	// Whether the priority queue contains an entry with the given [value].
	bool ContainsValue(const V& value) { return FindMapEntry(value) != nullptr; }

	// Changes the priority of an existing entry with given [value] or adds a
	// new entry.
	bool InsertOrChangePriority(const P& priority, const V& value) {
	auto map_entry = FindMapEntry(value);
	if (map_entry == nullptr) {
	Insert(priority, value);
	return true;
	}

	const intptr_t offset = ValueOfMapEntry(map_entry);
	ASSERT(offset < size_);

	Entry& entry = min_heap_[offset];
	entry.priority = priority;
	if (offset == 0) {
	BubbleDown(offset);
	} else {
	intptr_t parent = (offset - 1) / 2;
	intptr_t diff = entry.priority - min_heap_[parent].priority;
	if (diff < 0) {
	BubbleUp(offset);
	} else if (diff > 0) {
	BubbleDown(offset);
	}
	}
	return false;
	}

	#ifdef TESTING
	intptr_t min_heap_size() { return min_heap_size_; }
	#endif // TESTING

	private:
	// Utility functions dealing with the SimpleHashMap interface.
	static bool MatchFun(void* key1, void* key2) { return key1 == key2; }

	SimpleHashMap::Entry* FindMapEntry(const V& key, bool insert = false) {
	return hashmap_.Lookup(CastKey(key), HashKey(key), insert);
	}
	void RemoveMapEntry(const V& key) {
	ASSERT(FindMapEntry(key) != nullptr);
	hashmap_.Remove(CastKey(key), HashKey(key));
	}
	void SetMapEntry(const V& key, intptr_t value) {
	FindMapEntry(key, /insert=/true)->value = reinterpret_cast<void*>(value);
	}
	static uint32_t HashKey(const V& key) {
	return static_cast<uint32_t>(reinterpret_cast<intptr_t>(CastKey(key)));
	}
	static intptr_t ValueOfMapEntry(SimpleHashMap::Entry* entry) {
	return reinterpret_cast<intptr_t>(entry->value);
	}
	static void* CastKey(const V& key) {
	return reinterpret_cast<void*>((const_cast<V&>(key)));
	}

	void RemoveAt(intptr_t offset) {
	ASSERT(offset < size_);

	size_--;

	if (offset == size_) {
	RemoveMapEntry(min_heap_[offset].value);
	} else {
	Replace(offset, size_);
	BubbleDown(offset);
	}

	if (size_ <= (min_heap_size_ >> 2) &&
	kMinimumSize <= (min_heap_size_ >> 1)) {
	Resize(min_heap_size_ >> 1);
	}
	}

	void BubbleUp(intptr_t offset) {
	while (true) {
	if (offset == 0) return;

	intptr_t parent = (offset - 1) / 2;
	if (min_heap_[parent].priority > min_heap_[offset].priority) {
	Swap(parent, offset);
	}
	offset = parent;
	}
	}

	void BubbleDown(intptr_t offset) {
	while (true) {
	intptr_t left_child_index = 2 * offset + 1;
	bool has_left_child = left_child_index < size_;

	if (!has_left_child) return;

	intptr_t smallest_index = offset;

	if (min_heap_[left_child_index].priority < min_heap_[offset].priority) {
	smallest_index = left_child_index;
	}

	intptr_t right_child_index = left_child_index + 1;
	bool has_right_child = right_child_index < size_;
	if (has_right_child) {
	if (min_heap_[right_child_index].priority <
	min_heap_[smallest_index].priority) {
	smallest_index = right_child_index;
	}
	}

	if (offset == smallest_index) {
	return;
	}

	Swap(offset, smallest_index);
	offset = smallest_index;
	}
	}

	void Set(intptr_t offset1, const Entry& entry) {
	min_heap_[offset1] = entry;
	SetMapEntry(entry.value, offset1);
	}

	void Swap(intptr_t offset1, intptr_t offset2) {
	Entry temp = min_heap_[offset1];
	min_heap_[offset1] = min_heap_[offset2];
	min_heap_[offset2] = temp;

	SetMapEntry(min_heap_[offset1].value, offset1);
	SetMapEntry(min_heap_[offset2].value, offset2);
	}

	void Replace(intptr_t index, intptr_t with_other) {
	RemoveMapEntry(min_heap_[index].value);

	const Entry& entry = min_heap_[with_other];
	SetMapEntry(entry.value, index);
	min_heap_[index] = entry;
	}

	void Resize(intptr_t new_min_heap_size) {
	ASSERT(size_ < new_min_heap_size);
	ASSERT(new_min_heap_size != min_heap_size_);

	Entry* new_backing = reinterpret_cast<Entry*>(
	realloc(min_heap_, sizeof(Entry) * new_min_heap_size));

	if (new_backing == NULL) FATAL("Cannot allocate memory.");

	min_heap_ = new_backing;
	min_heap_size_ = new_min_heap_size;
	}

	// The array is representing a tree structure with guaranteed log(n) height.
	// It has the property that the value of node N is always equal or smaller
	// than the value of N's children. Furthermore it is a "dense" tree in the
	// sense that all rows/layers of the tree are fully occupied except the last
	// one. The way to represent such "dense" trees is via an array that allows
	// finding left/right children by <2index+1><2index+2> and the parent by
	// <(index-1)/2>.
	//
	// Insertion operations can be performed by adding one more entry at the end
	// (bottom right) and bubbling it up until the tree invariant is satisfied
	// again.
	//
	// Deletion operations can be performed by replacing the minimum element
	// (first entry) by the last entry (bottom right) and bubbling it down until
	// the tree invariant is satisified again.
	Entry* min_heap_;
	intptr_t min_heap_size_;
	intptr_t size_;
	SimpleHashMap hashmap_;
	};

	} // namespace dart

	#endif // RUNTIME_PLATFORM_PRIORITY_QUEUE_H_