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splay.c
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#include "splay.h"
#include <stdlib.h>
#include "fatal.h"
struct SplayNode
{
ElementType Element;
SplayTree Left;
SplayTree Right;
};
typedef struct SplayNode *Position;
static Position NullNode = NULL; /* Needs initialization */
SplayTree
Initialize( void )
{
if( NullNode == NULL )
{
NullNode = malloc( sizeof( struct SplayNode ) );
if( NullNode == NULL )
FatalError( "Out of space!!!" );
NullNode->Left = NullNode->Right = NullNode;
}
return NullNode;
}
static SplayTree Splay( ElementType Item, Position X );
SplayTree
MakeEmpty( SplayTree T )
{
if( T != NullNode )
{
MakeEmpty( T->Left );
MakeEmpty( T->Right );
free( T );
}
return NullNode;
}
void
PrintTree( SplayTree T )
{
if( T != NullNode )
{
PrintTree( T->Left );
printf( "%d ", T->Element );
PrintTree( T->Right );
}
}
SplayTree
Find( ElementType X, SplayTree T )
{
return Splay( X, T );
}
SplayTree
FindMin( SplayTree T )
{
return Splay( NegInfinity, T );
}
SplayTree
FindMax( SplayTree T )
{
return Splay( Infinity, T );
}
/* This function can be called only if K2 has a left child */
/* Perform a rotate between a node (K2) and its left child */
/* Update heights, then return new root */
static Position
SingleRotateWithLeft( Position K2 )
{
Position K1;
K1 = K2->Left;
K2->Left = K1->Right;
K1->Right = K2;
return K1; /* New root */
}
/* This function can be called only if K1 has a right child */
/* Perform a rotate between a node (K1) and its right child */
/* Update heights, then return new root */
static Position
SingleRotateWithRight( Position K1 )
{
Position K2;
K2 = K1->Right;
K1->Right = K2->Left;
K2->Left = K1;
return K2; /* New root */
}
/* START: fig12_6.txt */
/* Top-down splay procedure, */
/* not requiring Item to be in tree */
SplayTree
Splay( ElementType Item, Position X )
{
static struct SplayNode Header;
Position LeftTreeMax, RightTreeMin;
Header.Left = Header.Right = NullNode;
LeftTreeMax = RightTreeMin = &Header;
NullNode->Element = Item;
while( Item != X->Element )
{
if( Item < X->Element )
{
if( Item < X->Left->Element )
X = SingleRotateWithLeft( X );
if( X->Left == NullNode )
break;
/* Link right */
RightTreeMin->Left = X;
RightTreeMin = X;
X = X->Left;
}
else
{
if( Item > X->Right->Element )
X = SingleRotateWithRight( X );
if( X->Right == NullNode )
break;
/* Link left */
LeftTreeMax->Right = X;
LeftTreeMax = X;
X = X->Right;
}
} /* while Item != X->Element */
/* Reassemble */
LeftTreeMax->Right = X->Left;
RightTreeMin->Left = X->Right;
X->Left = Header.Right;
X->Right = Header.Left;
return X;
}
/* END */
/* START: fig12_7.txt */
SplayTree
Insert( ElementType Item, SplayTree T )
{
static Position NewNode = NULL;
if( NewNode == NULL )
{
NewNode = malloc( sizeof( struct SplayNode ) );
if( NewNode == NULL )
FatalError( "Out of space!!!" );
}
NewNode->Element = Item;
if( T == NullNode )
{
NewNode->Left = NewNode->Right = NullNode;
T = NewNode;
}
else
{
T = Splay( Item, T );
if( Item < T->Element )
{
NewNode->Left = T->Left;
NewNode->Right = T;
T->Left = NullNode;
T = NewNode;
}
else
if( T->Element < Item )
{
NewNode->Right = T->Right;
NewNode->Left = T;
T->Right = NullNode;
T = NewNode;
}
else
return T; /* Already in the tree */
}
NewNode = NULL; /* So next insert will call malloc */
return T;
}
/* END */
/* START: fig12_8.txt */
SplayTree
Remove( ElementType Item, SplayTree T )
{
Position NewTree;
if( T != NullNode )
{
T = Splay( Item, T );
if( Item == T->Element )
{
/* Found it! */
if( T->Left == NullNode )
NewTree = T->Right;
else
{
NewTree = T->Left;
NewTree = Splay( Item, NewTree );
NewTree->Right = T->Right;
}
free( T );
T = NewTree;
}
}
return T;
}
/* END */
ElementType
Retrieve( SplayTree T )
{
return T->Element;
}