Binary search tree: remove node: Difference between revisions
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'''Invariant:''' | '''Invariant:''' | ||
# The [[Directed Tree#Immediate Predecessor and Successor|immediate predecessor]] of '''''K''''' is in the [[Directed Tree#Ranges of Search Tree Nodes|range]] of <math>p'</math>. | # The [[Directed Tree#Immediate Predecessor and Successor|immediate predecessor]] of '''''K''''' is in the [[Directed Tree#Ranges of Search Tree Nodes|range]] of <math>p'</math>. | ||
# It is <math>p'</math>.right | # It is <math>p'</math>.right <math>\neq</math> void. | ||
'''Variant:''' The pointer <math>p'</math> descends one level deeper, namely to <math>p</math>'.right. | '''Variant:''' The pointer <math>p'</math> descends one level deeper, namely to <math>p</math>'.right. | ||
'''Break condition:''' It is <math>p'</math>.right.right = void. | '''Break condition:''' It is <math>p'</math>.right.right = void. | ||
'''Remark:''' For example, the height of the subtree rooted at the node to which <math>p</math> points may be chosen as the induction parameter. For conciseness, the induction parameter is omitted in the following. | |||
== Induction Basis == | == Induction Basis == | ||
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'''Implementation:''' | '''Implementation:''' | ||
# If <math>p.left.right = void | # If <math>p</math>.left.right = void: | ||
## Set <math>p.key := p.left.key | ## Set <math>p</math>.key := p.left.key. | ||
## Set <math>p.left := p.left.left | ## Set <math>p</math>.left := p.left.left. | ||
## Terminate the algorithm. | ## Terminate the algorithm. | ||
#Otherwise, set <math>p' := p.left | #Otherwise, set <math>p'</math> := p.left. | ||
'''Proof:''' Obvious. | '''Proof:''' Obvious. | ||
== Induction Step == | == Induction Step == | ||
'''Abstract view:''' If <math>p' | '''Abstract view:''' If <math>p'</math>.right.key is the immediate predecessor of <math>K</math>, overwrite <math>K</math> by its immediate predecessor and terminate; otherwise, let <math>p'</math> descend one level deeper. | ||
'''Implementation:''' | '''Implementation:''' | ||
# If <math>p'.right.right = void | # If <math>p'</math>.right.right = void: | ||
## Set <math>p.key := p'.right.key | ## Set <math>p</math>.key := <math>p'</math>.right.key. | ||
## Set <math>p'.right := p'.right.left | ## Set <math>p'</math>.right := <math>p'</math>.right.left. | ||
# Terminate the algorithm. | ## Terminate the algorithm. | ||
# Set <math>p':=p'</math>.right. | |||
'''Correctness:''' | '''Correctness:''' Obvious. | ||
== Complexity == | == Complexity == |
Latest revision as of 13:39, 3 March 2017
General Information
Algorithmic problem: See the remark clause of Binary Search Tree; pointer [math]\displaystyle{ p }[/math] as defined there is the input.
Prerequisites: [math]\displaystyle{ p }[/math].left [math]\displaystyle{ \neq }[/math] void.
Type of algorithm: loop
Auxiliary data: A pointer [math]\displaystyle{ p' }[/math] of type "pointer to a binary search tree node of type [math]\displaystyle{ \mathcal{K} }[/math]."
Abstract View
Invariant:
- The immediate predecessor of K is in the range of [math]\displaystyle{ p' }[/math].
- It is [math]\displaystyle{ p' }[/math].right [math]\displaystyle{ \neq }[/math] void.
Variant: The pointer [math]\displaystyle{ p' }[/math] descends one level deeper, namely to [math]\displaystyle{ p }[/math]'.right.
Break condition: It is [math]\displaystyle{ p' }[/math].right.right = void.
Remark: For example, the height of the subtree rooted at the node to which [math]\displaystyle{ p }[/math] points may be chosen as the induction parameter. For conciseness, the induction parameter is omitted in the following.
Induction Basis
Abstract view: If [math]\displaystyle{ p.left }[/math] is the immediate predecessor of K, overwrite K by its immediate predecessor and terminate; otherwise, initialize [math]\displaystyle{ p' }[/math].
Implementation:
- If [math]\displaystyle{ p }[/math].left.right = void:
- Set [math]\displaystyle{ p }[/math].key := p.left.key.
- Set [math]\displaystyle{ p }[/math].left := p.left.left.
- Terminate the algorithm.
- Otherwise, set [math]\displaystyle{ p' }[/math] := p.left.
Proof: Obvious.
Induction Step
Abstract view: If [math]\displaystyle{ p' }[/math].right.key is the immediate predecessor of [math]\displaystyle{ K }[/math], overwrite [math]\displaystyle{ K }[/math] by its immediate predecessor and terminate; otherwise, let [math]\displaystyle{ p' }[/math] descend one level deeper.
Implementation:
- If [math]\displaystyle{ p' }[/math].right.right = void:
- Set [math]\displaystyle{ p }[/math].key := [math]\displaystyle{ p' }[/math].right.key.
- Set [math]\displaystyle{ p' }[/math].right := [math]\displaystyle{ p' }[/math].right.left.
- Terminate the algorithm.
- Set [math]\displaystyle{ p':=p' }[/math].right.
Correctness: Obvious.
Complexity
Statement: The complexity is in [math]\displaystyle{ \mathcal{O}(T\cdot h)\subseteq\mathcal{O}(T\cdot n) }[/math] in the worst case, where [math]\displaystyle{ n }[/math] is the length of the sequence, [math]\displaystyle{ h }[/math] the height of the tree, and [math]\displaystyle{ T }[/math] the complexity of the comparison.
Proof: Obvious.