Heap as array: Difference between revisions
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[[Category:Data Structures]] | |||
==General information== | ==General information== | ||
'''Abstract Data Structure:''' [[Bounded priority queue]] | '''Abstract Data Structure:''' [[Bounded priority queue]] | ||
'''Implementation Invariant:''' | '''Implementation Invariant:''' | ||
# For each object of "Heap as array", there is | # For each object of "Heap as array", there is | ||
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# There is an internal type '''heap item''' with two components: | # There is an internal type '''heap item''' with two components: | ||
## a component named <math>key</math> of type <math>\mathcal{K}</math> | ## a component named <math>key</math> of type <math>\mathcal{K}</math> | ||
## a component named <math>ID</math>, which is a [[natural numbers|natural number]] and ranges from <math>1,...,N_\text{max}</math>. | ## a component named <math>ID</math>, which is a [[Numbers#natural numbers|natural number]] and ranges from <math>1,...,N_\text{max}</math>. | ||
# There is an array <math>TheHeap</math> with index range <math>1,...,N_\text{max}</math> and component type heap item. The '''currently stored items''' are <math>TheHeap[1],...,TheHeap[N]</math>. | # There is an array <math>TheHeap</math> with index range <math>1,...,N_\text{max}</math> and component type heap item. The '''currently stored items''' are <math>TheHeap[1],...,TheHeap[N]</math>. | ||
# There is an [[Index handler|index handler]] <math>IH</math> with maximum size <math>N_\text{max}</math> and value type <math>\{1,\ldots,N_\text{max}\}</math>. For each used index <math>i\in\{1,...,N_\text{max}\}</math>, the associated value is the position of one of the <math>N</math> heap items in <math>TheHeap</math>. As long as this heap item is stored, <math>i</math> is permanently associated with this heap item (and can hence be used to locate and access this heap item at any time). The correspondence between the heap items and these numbers <math>i</math> is one-to-one. | |||
# There is an [[ | |||
# '''Heap property:''' For each <math>i\in\{2,...,N\}</math>, it is <math>TheHeap[i].key\ge TheHeap[\lfloor i/2 \rfloor ].key.</math>. | # '''Heap property:''' For each <math>i\in\{2,...,N\}</math>, it is <math>TheHeap[i].key\ge TheHeap[\lfloor i/2 \rfloor ].key.</math>. | ||
The heap property may be viewed as follows: Imagine a [[Directed Tree|binary tree]] of <math>N</math> nodes such that each height level except for the last one is full, and the last one is filled from left to right. The nodes have pairwise different indexes from <math>\{ 1,...,N \}</math>: | |||
# The root is indexed <math>1</math>. | |||
# For a node with <math>i</math>, the left child (if existing) has index <math>2*i</math>, and the right child (if existing) has index <math>2*i+1</math>. | |||
Now associate the node with index <math>i</math> with the key <math>TheHeap[i].key</math>. Then the heap property says that the key of a node is not larger than the keys of its children. In this case, we say that i fulfills the heap property. | |||
In particular, the minimum key is associated with the root. | |||
==Remark== | |||
The implementations of the methods [[Bounded priority queue|Bounded priority queue: number]] and [[Bounded priority queue|Bounded priority queue: find minimum]] are trivial and, hence, left out here. | |||
==References== |
Latest revision as of 23:12, 19 June 2015
General information
Abstract Data Structure: Bounded priority queue
Implementation Invariant:
- For each object of "Heap as array", there is
- a specific maximum number of items [math]\displaystyle{ N_\text{max}\in\mathbb{N} }[/math], which is constant throughout the object's lifetime.
- a current number of items [math]\displaystyle{ N\in\mathbb{N}_{0} }[/math], which is dynamically changing, but it is [math]\displaystyle{ N\le N_\text{max} }[/math] at any time.
- There is an internal type heap item with two components:
- a component named [math]\displaystyle{ key }[/math] of type [math]\displaystyle{ \mathcal{K} }[/math]
- a component named [math]\displaystyle{ ID }[/math], which is a natural number and ranges from [math]\displaystyle{ 1,...,N_\text{max} }[/math].
- There is an array [math]\displaystyle{ TheHeap }[/math] with index range [math]\displaystyle{ 1,...,N_\text{max} }[/math] and component type heap item. The currently stored items are [math]\displaystyle{ TheHeap[1],...,TheHeap[N] }[/math].
- There is an index handler [math]\displaystyle{ IH }[/math] with maximum size [math]\displaystyle{ N_\text{max} }[/math] and value type [math]\displaystyle{ \{1,\ldots,N_\text{max}\} }[/math]. For each used index [math]\displaystyle{ i\in\{1,...,N_\text{max}\} }[/math], the associated value is the position of one of the [math]\displaystyle{ N }[/math] heap items in [math]\displaystyle{ TheHeap }[/math]. As long as this heap item is stored, [math]\displaystyle{ i }[/math] is permanently associated with this heap item (and can hence be used to locate and access this heap item at any time). The correspondence between the heap items and these numbers [math]\displaystyle{ i }[/math] is one-to-one.
- Heap property: For each [math]\displaystyle{ i\in\{2,...,N\} }[/math], it is [math]\displaystyle{ TheHeap[i].key\ge TheHeap[\lfloor i/2 \rfloor ].key. }[/math].
The heap property may be viewed as follows: Imagine a binary tree of [math]\displaystyle{ N }[/math] nodes such that each height level except for the last one is full, and the last one is filled from left to right. The nodes have pairwise different indexes from [math]\displaystyle{ \{ 1,...,N \} }[/math]:
- The root is indexed [math]\displaystyle{ 1 }[/math].
- For a node with [math]\displaystyle{ i }[/math], the left child (if existing) has index [math]\displaystyle{ 2*i }[/math], and the right child (if existing) has index [math]\displaystyle{ 2*i+1 }[/math].
Now associate the node with index [math]\displaystyle{ i }[/math] with the key [math]\displaystyle{ TheHeap[i].key }[/math]. Then the heap property says that the key of a node is not larger than the keys of its children. In this case, we say that i fulfills the heap property.
In particular, the minimum key is associated with the root.
Remark
The implementations of the methods Bounded priority queue: number and Bounded priority queue: find minimum are trivial and, hence, left out here.