利用Trie树对字符串集合进行排序并计算特征值

该算法用于将一组乱序的字符串反序列化到一个Trie树中，这个过程即可视为对字符串进行了一次排序。

还可以通过调用 GetFeatureString 将该 Trie 树重新序列化。

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#ifndef bool
#    define bool char
#endif

#ifndef true
#    define true 1
#endif

#ifndef false
#    define false 0
#endif

#define NEXTSIZE 256

struct TrieTreeNode
{
    struct TrieTreeNode *Next[NEXTSIZE];
    bool Accepted;
};

struct TrieTreeRoot
{
    int NodeCount;
    struct TrieTreeNode *Tree;
};

struct TrieTreeRoot *BuildTrieTree();
void InsertItem(struct TrieTreeRoot *TrieTreeRoot, char *Item);
unsigned char *GetFeatureString(struct TrieTreeRoot *TrieTreeRoot, int *StringLength);

/*
 * 构建 Trie 树并初始化
 * 返回一个新的 Trie 根节点
 */
struct TrieTreeRoot *BuildTrieTree()
{
    struct TrieTreeRoot *Root = (struct TrieTreeRoot *)malloc(sizeof(struct TrieTreeRoot));
    Root->NodeCount = 1;
    Root->Tree = (struct TrieTreeNode *)malloc(sizeof(struct TrieTreeNode));
    memset(Root->Tree, '\0', sizeof(struct TrieTreeNode));
    return Root;
}

/*
 * 插入新的字符串
 * Root : struct TrieTreeRoot* 要操作的 Trie 树根节点
 * Item : char* 要插入的字符串
 */
void InsertItem(struct TrieTreeRoot *Root, char *Item)
{
    struct TrieTreeNode *Ptr = Root->Tree;
    int index = 0;
    unsigned char Charactor;

    while ((Charactor = Item[index]) != '\0')
    {
        if (Ptr->Next[Charactor] == NULL)
        {
            Ptr->Next[Charactor] = (struct TrieTreeNode *)malloc(sizeof(struct TrieTreeNode));
            memset(Ptr->Next[Charactor], '\0', sizeof(struct TrieTreeNode));
            Root->NodeCount++;
        }
        Ptr = Ptr->Next[Charactor];
        index++;
    }

    Ptr->Accepted = true;
}

/*
 * 递归序列化 Trie 树
 * Node : struct TrieTreeNode* 当前操作的 Trie 节点
 * WritePtr : unsigned char* 特征串写入指针
 */
unsigned char *DoFeature(struct TrieTreeNode *Node, unsigned char *WritePtr)
{
    int i, count = 0;
    unsigned char *ErgodicPtr;

    *WritePtr = (unsigned char)Node->Accepted;    // 写入节点是否接受
    WritePtr++;

    ErgodicPtr = WritePtr;                // 记录集合起始地址

    for (i = 0; i < NEXTSIZE; i++)        // 将该组记录写入特征串
    {
        if (Node->Next[i] != NULL)
        {
            *WritePtr = (char)i;
            WritePtr++;
            count++;
        }
    }

    *WritePtr = '\0';                    // 写入组分隔符
    WritePtr++;

    for (i = 0; i < count; i++)            // 递归调用处理所有边
    {
        WritePtr = DoFeature(Node->Next[ErgodicPtr[i]], WritePtr);
    }

    return WritePtr;
}

/*
 * 取得 Trie 的特征串，即序列化 Trie 树
 * Root : struct TrieTreeRoot* 要操作的 Trie 树根节点
 * StringLength : int* 长度指针（为了返回二进制串而设置）
 */
unsigned char *GetFeatureString(struct TrieTreeRoot *Root, int *StringLength)
{
    struct TrieTreeNode *Ptr = Root->Tree;
    // 假设最坏情况下，每个节点只有一条边，那么存储该节点就需要三个单元（Accepted、边、分隔符）
    // 但实际上真正用到的只有 3N-1 个字节
    unsigned char *FeatureString = (unsigned char *)malloc(Root->NodeCount * 3);
    unsigned char *WritePtr = FeatureString;

    WritePtr = DoFeature(Ptr, WritePtr);

    *StringLength = WritePtr - FeatureString;
    return FeatureString;
}

void Test_1()
{
    struct TrieTreeRoot *t = BuildTrieTree();
    InsertItem(t, "P(\376P)\377");
    InsertItem(t, "P(\376)\377");
    InsertItem(t, "P(\376P)(");
    InsertItem(t, "P(\376)(");
    InsertItem(t, "P\376(P))");
    InsertItem(t, "P\376())");
    int l = 0, i;
    unsigned char *s = GetFeatureString(t, &l);
    printf("Feature: Size=%d, NodeCount=%d\n", l, t->NodeCount);
    for (i = 0; i < l; i++)
    {
        printf("%X ", s[i]);
    }
    printf("\n");
}

void Test_2()
{
    struct TrieTreeRoot *t = BuildTrieTree();
    InsertItem(t, "P(\376)(");
    InsertItem(t, "P(\376P)\377");
    InsertItem(t, "P(\376P)(");
    InsertItem(t, "P(\376(\377");
    InsertItem(t, "P(\376P)\377");
    InsertItem(t, "P\376())");
    InsertItem(t, "P(\376)\377");
    InsertItem(t, "P\376(P))");
    int l = 0, i;
    unsigned char *s = GetFeatureString(t, &l);
    printf("Feature: Size=%d, NodeCount=%d\n", l, t->NodeCount);
    for (i = 0; i < l; i++)
    {
        printf("%X ", s[i]);
    }
    printf("\n");
}

int main(int argc, char **argv)
{
    Test_1();
    Test_2();
    return 0;
}

仍有两个地方可以进行优化：

1、将 next 数组改为指针，有效减少叶子节点占用的空间；

2、如果插入的字符串是固定的，那么可以通过第一遍扫描该组字符串，构建一个大小为256的字典，通过代码 next[dic[charactor]] 进行访问，可有效减少边的数量。