• 线索化二叉树实例


    1.#include <stdio.h>
    #include <stdlib.h>
    #include "BTree.h"
    #include "SeqList.h"

    /* 线索二叉树 */

    struct Node
    {
        BTreeNode header;
        char v;
    };

    void printf_data(BTreeNode* node)
    {
        if( node != NULL )
        {
            printf("%c", ((struct Node*)node)->v);
        }
    }
    //线索二叉树1
    void thread_via_left(BTreeNode* root, BTreeNode** pp)
    {
        if( (root != NULL) && (pp != NULL) )
        {
            if( *pp != NULL )
            {
                (*pp)->left = root;
                *pp = NULL;
            }
            
            if( root->left == NULL )
            {
                *pp = root;
            }
            //前序遍历
            thread_via_left(root->left, pp);
            thread_via_left(root->right, pp);
        }
    }
    //线索化 二叉树2
    void thread_via_list(BTreeNode* root, SeqList* list)
    {
        if( (root != NULL) && (list != NULL) )
        {
            SeqList_Insert(list, (SeqListNode*)root, SeqList_Length(list));
            
            thread_via_list(root->left, list);
            thread_via_list(root->right, list);
        }
    }

    int main(int argc, char *argv[])
    {
        BTree* tree = BTree_Create();
        //遍历
        BTreeNode* current = NULL;
        BTreeNode* p = NULL;
        SeqList* list = NULL;
        int i = 0;
        
        struct Node n1 = {{NULL, NULL}, 'A'};
        struct Node n2 = {{NULL, NULL}, 'B'};
        struct Node n3 = {{NULL, NULL}, 'C'};
        struct Node n4 = {{NULL, NULL}, 'D'};
        struct Node n5 = {{NULL, NULL}, 'E'};
        struct Node n6 = {{NULL, NULL}, 'F'};
        
        BTree_Insert(tree, (BTreeNode*)&n1, 0, 0, 0);
        BTree_Insert(tree, (BTreeNode*)&n2, 0x00, 1, 0);
        BTree_Insert(tree, (BTreeNode*)&n3, 0x01, 1, 0);
        BTree_Insert(tree, (BTreeNode*)&n4, 0x00, 2, 0);
        BTree_Insert(tree, (BTreeNode*)&n5, 0x02, 2, 0);
        BTree_Insert(tree, (BTreeNode*)&n6, 0x02, 3, 0);
        
        printf("Full Tree: ");
        
        BTree_Display(tree, printf_data, 4, '-');
        
        printf("Thread via List: ");
        
        list = SeqList_Create(BTree_Count(tree));
        
        thread_via_list(BTree_Root(tree), list);
        
        for(i=0; i<SeqList_Length(list); i++)
        {
            printf("%c, ", ((struct Node*)SeqList_Get(list, i))->v);
        }
        
        printf(" ");
        
        printf("Thread via Left: ");
        current = BTree_Root(tree);
        
        thread_via_left(current, &p);
        //开始遍历
        while( current != NULL )
        {
            printf("%c, ", ((struct Node*)current)->v);
            
            current = current->left;
        }
        
        printf(" ");
        
        BTree_Destroy(tree);
        
        return 0;
    }

    2.#include <stdio.h>
    #include <malloc.h>
    #include "SeqList.h"

    typedef unsigned int TSeqListNode;

    typedef struct _tag_SeqList
    {
        int capacity;
        int length;
        TSeqListNode* node;
    } TSeqList;

    SeqList* SeqList_Create(int capacity) // O(1)
    {
        TSeqList* ret = NULL;
        
        if( capacity >= 0 )
        {
            ret = (TSeqList*)malloc(sizeof(TSeqList) + sizeof(TSeqListNode) * capacity);
        }
        
        if( ret != NULL )
        {
            ret->capacity = capacity;
            ret->length = 0;
            ret->node = (TSeqListNode*)(ret + 1);
        }
        
        return ret;
    }

    void SeqList_Destroy(SeqList* list) // O(1)
    {
        free(list);
    }

    void SeqList_Clear(SeqList* list) // O(1)
    {
        TSeqList* sList = (TSeqList*)list;
        
        if( sList != NULL )
        {
            sList->length = 0;
        }
    }

    int SeqList_Length(SeqList* list) // O(1)
    {
        TSeqList* sList = (TSeqList*)list;
        int ret = -1;
        
        if( sList != NULL )
        {
            ret = sList->length;
        }
        
        return ret;
    }

    int SeqList_Capacity(SeqList* list) // O(1)
    {
        TSeqList* sList = (TSeqList*)list;
        int ret = -1;
        
        if( sList != NULL )
        {
            ret = sList->capacity;
        }
        
        return ret;
    }

    int SeqList_Insert(SeqList* list, SeqListNode* node, int pos) // O(n)
    {
        TSeqList* sList = (TSeqList*)list;
        int ret = (sList != NULL);
        int i = 0;
        
        ret = ret && (sList->length + 1 <= sList->capacity);
        ret = ret && (0 <= pos);
        
        if( ret )
        {
            if( pos >= sList->length )
            {
                pos = sList->length;
            }
            
            for(i=sList->length; i>pos; i--)
            {
                sList->node[i] = sList->node[i-1];
            }
            
            sList->node[i] = (TSeqListNode)node;
            
            sList->length++;
        }
        
        return ret;
    }

    SeqListNode* SeqList_Get(SeqList* list, int pos) // O(1)
    {
        TSeqList* sList = (TSeqList*)list;
        SeqListNode* ret = NULL;
        
        if( (sList != NULL) && (0 <= pos) && (pos <= sList->length) )
        {
            ret = (SeqListNode*)(sList->node[pos]);
        }
        
        return ret;
    }

    SeqListNode* SeqList_Delete(SeqList* list, int pos) // O(n)
    {
        TSeqList* sList = (TSeqList*)list;
        SeqListNode* ret = SeqList_Get(list, pos);
        int i = 0;
        
        if( ret != NULL )
        {
            for(i=pos+1; i<sList->length; i++)
            {
                sList->node[i-1] = sList->node[i];
            }
            
            sList->length--;
        }
        
        return ret;
    }

    3.#ifndef _SEQLIST_H_
    #define _SEQLIST_H_

    typedef void SeqList;
    typedef void SeqListNode;

    SeqList* SeqList_Create(int capacity);

    void SeqList_Destroy(SeqList* list);

    void SeqList_Clear(SeqList* list);

    int SeqList_Length(SeqList* list);

    int SeqList_Capacity(SeqList* list);

    int SeqList_Insert(SeqList* list, SeqListNode* node, int pos);

    SeqListNode* SeqList_Get(SeqList* list, int pos);

    SeqListNode* SeqList_Delete(SeqList* list, int pos);

    #endif

    4.#include <stdio.h>
    #include <malloc.h>
    #include "BTree.h"

    typedef struct _tag_BTree TBTree;
    struct _tag_BTree
    {
        int count;
        BTreeNode* root;
    };

    static void recursive_display(BTreeNode* node, BTree_Printf* pFunc, int format, int gap, char div) // O(n)
    {
        int i = 0;
        
        if( (node != NULL) && (pFunc != NULL) )
        {
            for(i=0; i<format; i++)
            {
                printf("%c", div);
            }
            
            pFunc(node);
            
            printf(" ");
            
            if( (node->left != NULL) || (node->right != NULL) )
            {
                recursive_display(node->left, pFunc, format + gap, gap, div);
                recursive_display(node->right, pFunc, format + gap, gap, div);
            }
        }
        else
        {
            for(i=0; i<format; i++)
            {
                printf("%c", div);
            }
            printf(" ");
        }
    }

    static int recursive_count(BTreeNode* root) // O(n)
    {
        int ret = 0;
        
        if( root != NULL )
        {
            ret = recursive_count(root->left) + 1 + recursive_count(root->right);
        }
        
        return ret;
    }

    static int recursive_height(BTreeNode* root) // O(n)
    {
        int ret = 0;
        
        if( root != NULL )
        {
            int lh = recursive_height(root->left);
            int rh = recursive_height(root->right);
            
            ret = ((lh > rh) ? lh : rh) + 1;
        }
        
        return ret;
    }

    static int recursive_degree(BTreeNode* root) // O(n)
    {
        int ret = 0;
        
        if( root != NULL )
        {
            if( root->left != NULL )
            {
                ret++;
            }
            
            if( root->right != NULL )
            {
                ret++;
            }
            
            if( ret == 1 )
            {
                int ld = recursive_degree(root->left);
                int rd = recursive_degree(root->right);
                
                if( ret < ld )
                {
                    ret = ld;
                }
                
                if( ret < rd )
                {
                    ret = rd;
                }
            }
        }
        
        return ret;
    }

    BTree* BTree_Create() // O(1)
    {
        TBTree* ret = (TBTree*)malloc(sizeof(TBTree));
        
        if( ret != NULL )
        {
            ret->count = 0;
            ret->root = NULL;
        }
        
        return ret;
    }

    void BTree_Destroy(BTree* tree) // O(1)
    {
        free(tree);
    }

    void BTree_Clear(BTree* tree) // O(1)
    {
        TBTree* btree = (TBTree*)tree;
        
        if( btree != NULL )
        {
            btree->count = 0;
            btree->root = NULL;
        }
    }

    int BTree_Insert(BTree* tree, BTreeNode* node, BTPos pos, int count, int flag) // O(n)
    {
        TBTree* btree = (TBTree*)tree;
        int ret = (btree != NULL) && (node != NULL) && ((flag == BT_LEFT) || (flag == BT_RIGHT));
        int bit = 0;
        
        if( ret )
        {
            BTreeNode* parent = NULL;
            BTreeNode* current = btree->root;
            
            node->left = NULL;
            node->right = NULL;
            
            while( (count > 0) && (current != NULL) )
            {
                bit = pos & 1;
                pos = pos >> 1;
                
                parent = current;
                
                if( bit == BT_LEFT )
                {
                    current = current->left;
                }
                else if( bit == BT_RIGHT )
                {
                    current = current->right;
                }
                
                count--;
            }
            
            if( flag == BT_LEFT )
            {
                node->left = current;
            }
            else if( flag == BT_RIGHT )
            {
                node->right = current;
            }
            
            if( parent != NULL )
            {
                if( bit == BT_LEFT )
                {
                    parent->left = node;
                }
                else if( bit == BT_RIGHT )
                {
                    parent->right = node;
                }
            }
            else
            {
                btree->root = node;
            }
            
            btree->count++;
        }
        
        return ret;
    }

    BTreeNode* BTree_Delete(BTree* tree, BTPos pos, int count) // O(n)
    {
        TBTree* btree = (TBTree*)tree;
        BTreeNode* ret = NULL;
        int bit = 0;
        
        if( btree != NULL )
        {
            BTreeNode* parent = NULL;
            BTreeNode* current = btree->root;
            
            while( (count > 0) && (current != NULL) )
            {
                bit = pos & 1;
                pos = pos >> 1;
                
                parent = current;
                
                if( bit == BT_LEFT )
                {
                    current = current->left;
                }
                else if( bit == BT_RIGHT )
                {
                    current = current->right;
                }
                
                count--;
            }
            
            if( parent != NULL )
            {
                if( bit == BT_LEFT )
                {
                    parent->left = NULL;
                }
                else if( bit == BT_RIGHT )
                {
                    parent->right = NULL;
                }
            }
            else
            {
                btree->root = NULL;
            }
            
            ret = current;
            
            btree->count = btree->count - recursive_count(ret);
        }
        
        return ret;
    }

    BTreeNode* BTree_Get(BTree* tree, BTPos pos, int count) // O(n)
    {
        TBTree* btree = (TBTree*)tree;
        BTreeNode* ret = NULL;
        int bit = 0;
        
        if( btree != NULL )
        {
            BTreeNode* current = btree->root;
            
            while( (count > 0) && (current != NULL) )
            {
                bit = pos & 1;
                pos = pos >> 1;
                
                if( bit == BT_LEFT )
                {
                    current = current->left;
                }
                else if( bit == BT_RIGHT )
                {
                    current = current->right;
                }
                
                count--;
            }
            
            ret = current;
        }
        
        return ret;
    }

    BTreeNode* BTree_Root(BTree* tree) // O(1)
    {
        TBTree* btree = (TBTree*)tree;
        BTreeNode* ret = NULL;
        
        if( btree != NULL )
        {
            ret = btree->root;
        }
        
        return ret;
    }

    int BTree_Height(BTree* tree) // O(n)
    {
        TBTree* btree = (TBTree*)tree;
        int ret = 0;
        
        if( btree != NULL )
        {
            ret = recursive_height(btree->root);
        }
        
        return ret;
    }

    int BTree_Count(BTree* tree) // O(1)
    {
        TBTree* btree = (TBTree*)tree;
        int ret = 0;
        
        if( btree != NULL )
        {
            ret = btree->count;
        }
        
        return ret;
    }

    int BTree_Degree(BTree* tree) // O(n)
    {
        TBTree* btree = (TBTree*)tree;
        int ret = 0;
        
        if( btree != NULL )
        {
            ret = recursive_degree(btree->root);
        }
        
        return ret;
    }

    void BTree_Display(BTree* tree, BTree_Printf* pFunc, int gap, char div) // O(n)
    {
        TBTree* btree = (TBTree*)tree;
        
        if( btree != NULL )
        {
            recursive_display(btree->root, pFunc, 0, gap, div);
        }
    }

    5.#ifndef _BTREE_H_
    #define _BTREE_H_

    #define BT_LEFT 0
    #define BT_RIGHT 1

    typedef void BTree;
    typedef unsigned long long BTPos;

    typedef struct _tag_BTreeNode BTreeNode;
    struct _tag_BTreeNode
    {
        BTreeNode* left;
        BTreeNode* right;
    };

    typedef void (BTree_Printf)(BTreeNode*);

    BTree* BTree_Create();

    void BTree_Destroy(BTree* tree);

    void BTree_Clear(BTree* tree);

    int BTree_Insert(BTree* tree, BTreeNode* node, BTPos pos, int count, int flag);

    BTreeNode* BTree_Delete(BTree* tree, BTPos pos, int count);

    BTreeNode* BTree_Get(BTree* tree, BTPos pos, int count);

    BTreeNode* BTree_Root(BTree* tree);

    int BTree_Height(BTree* tree);

    int BTree_Count(BTree* tree);

    int BTree_Degree(BTree* tree);

    void BTree_Display(BTree* tree, BTree_Printf* pFunc, int gap, char div);

    #endif

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  • 原文地址:https://www.cnblogs.com/wxb20/p/6156161.html
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