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source: thirdparty/SZ/sz/src/Huffman.c @ 9ee2ce3

Revision 9ee2ce3, 21.6 KB checked in by Hal Finkel <hfinkel@…>, 6 years ago (diff)
importing new SZ files
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1	/**
2	* @file Huffman.c
3	* @author Sheng Di
4	* @date Aug., 2016
5	* @brief Customized Huffman Encoding, Compression and Decompression functions
6	* (C) 2016 by Mathematics and Computer Science (MCS), Argonne National Laboratory.
7	* See COPYRIGHT in top-level directory.
8	*/
9
10	#include <stdio.h>
11	#include <stdlib.h>
12	#include <string.h>
13	#include "Huffman.h"
14	#include "sz.h"
15
16
17	HuffmanTree* createHuffmanTree(int stateNum)
18	{
19	HuffmanTree huffmanTree = (HuffmanTree)malloc(sizeof(HuffmanTree));
20	memset(huffmanTree, 0, sizeof(HuffmanTree));
21	huffmanTree->stateNum = stateNum;
22	huffmanTree->allNodes = 2*stateNum;
23
24	huffmanTree->pool = (struct node_t)malloc(huffmanTree->allNodes2*sizeof(struct node_t));
25	huffmanTree->qqq = (node)malloc(huffmanTree->allNodes2*sizeof(node));
26	huffmanTree->code = (unsigned long*)malloc(huffmanTree->stateNumsizeof(unsigned long*));
27	huffmanTree->cout = (unsigned char )malloc(huffmanTree->stateNumsizeof(unsigned char));
28
29	memset(huffmanTree->pool, 0, huffmanTree->allNodes2sizeof(struct node_t));
30	memset(huffmanTree->qqq, 0, huffmanTree->allNodes2sizeof(node));
31	memset(huffmanTree->code, 0, huffmanTree->stateNumsizeof(unsigned long));
32	memset(huffmanTree->cout, 0, huffmanTree->stateNum*sizeof(unsigned char));
33	huffmanTree->qq = huffmanTree->qqq - 1;
34	huffmanTree->n_nodes = 0;
35	huffmanTree->n_inode = 0;
36	huffmanTree->qend = 1;
37
38	return huffmanTree;
39	}
40
41	HuffmanTree* createDefaultHuffmanTree()
42	{
43	int maxRangeRadius = 32768;
44	int stateNum = maxRangeRadius << 1; //*2
45
46	return createHuffmanTree(stateNum);
47	}
48
49	node new_node(HuffmanTree* huffmanTree, size_t freq, unsigned int c, node a, node b)
50	{
51	node n = huffmanTree->pool + huffmanTree->n_nodes++;
52	if (freq)
53	{
54	n->c = c;
55	n->freq = freq;
56	n->t = 1;
57	}
58	else {
59	n->left = a;
60	n->right = b;
61	n->freq = a->freq + b->freq;
62	n->t = 0;
63	//n->c = 0;
64	}
65	return n;
66	}
67
68	node new_node2(HuffmanTree *huffmanTree, unsigned int c, unsigned char t)
69	{
70	huffmanTree->pool[huffmanTree->n_nodes].c = c;
71	huffmanTree->pool[huffmanTree->n_nodes].t = t;
72	return huffmanTree->pool + huffmanTree->n_nodes++;
73	}
74
75	/* priority queue */
76	void qinsert(HuffmanTree *huffmanTree, node n)
77	{
78	int j, i = huffmanTree->qend++;
79	while ((j = (i>>1))) //j=i/2
80	{
81	if (huffmanTree->qq[j]->freq <= n->freq) break;
82	huffmanTree->qq[i] = huffmanTree->qq[j], i = j;
83	}
84	huffmanTree->qq[i] = n;
85	}
86
87	node qremove(HuffmanTree* huffmanTree)
88	{
89	int i, l;
90	node n = huffmanTree->qq[i = 1];
91
92	if (huffmanTree->qend < 2) return 0;
93	huffmanTree->qend --;
94	while ((l = (i<<1)) < huffmanTree->qend) //l=(i*2)
95	{
96	if (l + 1 < huffmanTree->qend && huffmanTree->qq[l + 1]->freq < huffmanTree->qq[l]->freq) l++;
97	huffmanTree->qq[i] = huffmanTree->qq[l], i = l;
98	}
99	huffmanTree->qq[i] = huffmanTree->qq[huffmanTree->qend];
100	return n;
101	}
102
103	/* walk the tree and put 0s and 1s */
104	/**
105	* @out1 should be set to 0.
106	* @out2 should be 0 as well.
107	* @index: the index of the byte
108	* */
109	void build_code(HuffmanTree *huffmanTree, node n, int len, unsigned long out1, unsigned long out2)
110	{
111	if (n->t) {
112	huffmanTree->code[n->c] = (unsigned long)malloc(2sizeof(unsigned long));
113	if(len<=64)
114	{
115	(huffmanTree->code[n->c])[0] = out1 << (64 - len);
116	(huffmanTree->code[n->c])[1] = out2;
117	}
118	else
119	{
120	(huffmanTree->code[n->c])[0] = out1;
121	(huffmanTree->code[n->c])[1] = out2 << (128 - len);
122	}
123	huffmanTree->cout[n->c] = (unsigned char)len;
124	return;
125	}
126	int index = len >> 6; //=len/64
127	if(index == 0)
128	{
129	out1 = out1 << 1;
130	out1 = out1 \| 0;
131	build_code(huffmanTree, n->left, len + 1, out1, 0);
132	out1 = out1 \| 1;
133	build_code(huffmanTree, n->right, len + 1, out1, 0);
134	}
135	else
136	{
137	if(len%64!=0)
138	out2 = out2 << 1;
139	out2 = out2 \| 0;
140	build_code(huffmanTree, n->left, len + 1, out1, out2);
141	out2 = out2 \| 1;
142	build_code(huffmanTree, n->right, len + 1, out1, out2);
143	}
144	}
145
146	void init(HuffmanTree* huffmanTree, int *s, size_t length)
147	{
148	size_t i, index;
149	size_t freq = (size_t )malloc(huffmanTree->allNodes*sizeof(size_t));
150	memset(freq, 0, huffmanTree->allNodes*sizeof(size_t));
151	for(i = 0;i < length;i++)
152	{
153	//index = 0;
154	//index = (index \| s[i])<<8;
155	//index = index \| s[i+1];
156	index = s[i];
157	freq[index]++;
158	}
159
160	for (i = 0; i < huffmanTree->allNodes; i++)
161	if (freq[i])
162	qinsert(huffmanTree, new_node(huffmanTree, freq[i], i, 0, 0));
163
164	while (huffmanTree->qend > 2)
165	qinsert(huffmanTree, new_node(huffmanTree, 0, 0, qremove(huffmanTree), qremove(huffmanTree)));
166
167	build_code(huffmanTree, huffmanTree->qq[1], 0, 0, 0);
168	free(freq);
169	}
170
171	void encode(HuffmanTree huffmanTree, int s, size_t length, unsigned char out, size_t outSize)
172	{
173	size_t i = 0;
174	unsigned char bitSize = 0, byteSize, byteSizep;
175	int state;
176	unsigned char *p = out;
177	int lackBits = 0;
178	//long totalBitSize = 0, maxBitSize = 0, bitSize21 = 0, bitSize32 = 0;
179	for (i = 0;i<length;i++)
180	{
181	//state = 0;
182	//state = (state \| s[i])<<8;
183	//state = state \| s[i+1];
184
185	state = s[i];
186	bitSize = huffmanTree->cout[state];
187
188	//printf("%d %d : %d %u\n",i, state, bitSize, (code[state])[0] >> (64-cout[state]));
189	//debug: compute the average bitSize and the count that is over 32...
190	/*if(bitSize>=21)
191	bitSize21++;
192	if(bitSize>=32)
193	bitSize32++;
194	if(maxBitSize<bitSize)
195	maxBitSize = bitSize;
196	totalBitSize+=bitSize;*/
197
198	if(lackBits==0)
199	{
200	byteSize = bitSize%8==0 ? bitSize/8 : bitSize/8+1; //it's equal to the number of bytes involved (for *outSize)
201	byteSizep = bitSize/8; //it's used to move the pointer p for next data
202	if(byteSize<=8)
203	{
204	longToBytes_bigEndian(p, (huffmanTree->code[state])[0]);
205	p += byteSizep;
206	}
207	else //byteSize>8
208	{
209	longToBytes_bigEndian(p, (huffmanTree->code[state])[0]);
210	p += 8;
211	longToBytes_bigEndian(p, (huffmanTree->code[state])[1]);
212	p += (byteSizep - 8);
213	}
214	*outSize += byteSize;
215	lackBits = bitSize%8==0 ? 0 : 8 - bitSize%8;
216	}
217	else
218	{
219	p = (p) \| (unsigned char)((huffmanTree->code[state])[0] >> (64 - lackBits));
220	if(lackBits < bitSize)
221	{
222	p++;
223	//(*outSize)++;
224	long newCode = (huffmanTree->code[state])[0] << lackBits;
225	longToBytes_bigEndian(p, newCode);
226
227	if(bitSize<=64)
228	{
229	bitSize -= lackBits;
230	byteSize = bitSize%8==0 ? bitSize/8 : bitSize/8+1;
231	byteSizep = bitSize/8;
232	p += byteSizep;
233	(*outSize)+=byteSize;
234	lackBits = bitSize%8==0 ? 0 : 8 - bitSize%8;
235	}
236	else //bitSize > 64
237	{
238	byteSizep = 7; //must be 7 bytes, because lackBits!=0
239	p+=byteSizep;
240	(*outSize)+=byteSize;
241
242	bitSize -= 64;
243	if(lackBits < bitSize)
244	{
245	p = (p) \| (unsigned char)((huffmanTree->code[state])[0] >> (64 - lackBits));
246	p++;
247	//(*outSize)++;
248	newCode = (huffmanTree->code[state])[1] << lackBits;
249	longToBytes_bigEndian(p, newCode);
250	bitSize -= lackBits;
251	byteSize = bitSize%8==0 ? bitSize/8 : bitSize/8+1;
252	byteSizep = bitSize/8;
253	p += byteSizep;
254	(*outSize)+=byteSize;
255	lackBits = bitSize%8==0 ? 0 : 8 - bitSize%8;
256	}
257	else //lackBits >= bitSize
258	{
259	p = (p) \| (unsigned char)((huffmanTree->code[state])[0] >> (64 - bitSize));
260	lackBits -= bitSize;
261	}
262	}
263	}
264	else //lackBits >= bitSize
265	{
266	lackBits -= bitSize;
267	if(lackBits==0)
268	p++;
269	}
270	}
271	}
272	// for(i=0;i<stateNum;i++)
273	// if(code[i]!=NULL) free(code[i]);
274	/*printf("max bitsize = %d\n", maxBitSize);
275	printf("bitSize21 ratio = %f\n", ((float)bitSize21)/length);
276	printf("bitSize32 ratio = %f\n", ((float)bitSize32)/length);
277	printf("avg bit size = %f\n", ((float)totalBitSize)/length);*/
278	}
279
280	void decode(unsigned char s, size_t targetLength, node t, int out)
281	{
282	size_t i = 0, byteIndex = 0, count = 0;
283	int r;
284	node n = t;
285
286	if(n->t) //root->t==1 means that all state values are the same (constant)
287	{
288	for(count=0;count<targetLength;count++)
289	out[count] = n->c;
290	return;
291	}
292
293	for(i=0;count<targetLength;i++)
294	{
295
296	byteIndex = i>>3; //i/8
297	r = i%8;
298	if(((s[byteIndex] >> (7-r)) & 0x01) == 0)
299	n = n->left;
300	else
301	n = n->right;
302
303	if (n->t) {
304	//putchar(n->c);
305	out[count] = n->c;
306	n = t;
307	count++;
308	}
309	}
310	// putchar('\n');
311	if (t != n) printf("garbage input\n");
312	return;
313	}
314
315	void pad_tree_uchar(HuffmanTree* huffmanTree, unsigned char* L, unsigned char* R, unsigned int* C, unsigned char* t, unsigned int i, node root)
316	{
317	C[i] = root->c;
318	t[i] = root->t;
319	node lroot = root->left;
320	if(lroot!=0)
321	{
322	huffmanTree->n_inode++;
323	L[i] = huffmanTree->n_inode;
324	pad_tree_uchar(huffmanTree, L,R,C,t, huffmanTree->n_inode, lroot);
325	}
326	node rroot = root->right;
327	if(rroot!=0)
328	{
329	huffmanTree->n_inode++;
330	R[i] = huffmanTree->n_inode;
331	pad_tree_uchar(huffmanTree, L,R,C,t, huffmanTree->n_inode, rroot);
332	}
333	}
334
335	void pad_tree_ushort(HuffmanTree* huffmanTree, unsigned short* L, unsigned short* R, unsigned int* C, unsigned char* t, unsigned int i, node root)
336	{
337	C[i] = root->c;
338	t[i] = root->t;
339	node lroot = root->left;
340	if(lroot!=0)
341	{
342	huffmanTree->n_inode++;
343	L[i] = huffmanTree->n_inode;
344	pad_tree_ushort(huffmanTree,L,R,C,t,huffmanTree->n_inode, lroot);
345	}
346	node rroot = root->right;
347	if(rroot!=0)
348	{
349	huffmanTree->n_inode++;
350	R[i] = huffmanTree->n_inode;
351	pad_tree_ushort(huffmanTree,L,R,C,t,huffmanTree->n_inode, rroot);
352	}
353	}
354
355	void pad_tree_uint(HuffmanTree* huffmanTree, unsigned int* L, unsigned int* R, unsigned int* C, unsigned char* t, unsigned int i, node root)
356	{
357	C[i] = root->c;
358	t[i] = root->t;
359	node lroot = root->left;
360	if(lroot!=0)
361	{
362	huffmanTree->n_inode++;
363	L[i] = huffmanTree->n_inode;
364	pad_tree_uint(huffmanTree,L,R,C,t,huffmanTree->n_inode, lroot);
365	}
366	node rroot = root->right;
367	if(rroot!=0)
368	{
369	huffmanTree->n_inode++;
370	R[i] = huffmanTree->n_inode;
371	pad_tree_uint(huffmanTree,L,R,C,t,huffmanTree->n_inode, rroot);
372	}
373	}
374
375	unsigned int convert_HuffTree_to_bytes_anyStates(HuffmanTree* huffmanTree, int nodeCount, unsigned char** out)
376	{
377	//printf("nodeCount=%d\n", nodeCount);
378	if(nodeCount<=256)
379	{
380	unsigned char* L = (unsigned char)malloc(nodeCountsizeof(unsigned char));
381	memset(L, 0, nodeCount*sizeof(unsigned char));
382	unsigned char* R = (unsigned char)malloc(nodeCountsizeof(unsigned char));
383	memset(R, 0, nodeCount*sizeof(unsigned char));
384	unsigned int* C = (unsigned int)malloc(nodeCountsizeof(unsigned int));
385	memset(C, 0, nodeCount*sizeof(unsigned int));
386	unsigned char* t = (unsigned char)malloc(nodeCountsizeof(unsigned char));
387	memset(t, 0, nodeCount*sizeof(unsigned char));
388
389	pad_tree_uchar(huffmanTree,L,R,C,t,0,huffmanTree->qq[1]);
390
391	unsigned int totalSize = 1+3nodeCountsizeof(unsigned char)+nodeCount*sizeof(unsigned int);
392	out = (unsigned char)malloc(totalSize*sizeof(unsigned char));
393	(*out)[0] = (unsigned char)sysEndianType;
394	memcpy(out+1, L, nodeCountsizeof(unsigned char));
395	memcpy((out)+1+nodeCountsizeof(unsigned char),R,nodeCount*sizeof(unsigned char));
396	memcpy((out)+1+2nodeCountsizeof(unsigned char),C,nodeCountsizeof(unsigned int));
397	memcpy((out)+1+2nodeCountsizeof(unsigned char)+nodeCountsizeof(unsigned int), t, nodeCount*sizeof(unsigned char));
398	free(L);
399	free(R);
400	free(C);
401	free(t);
402	return totalSize;
403
404	}
405	else if(nodeCount<=65536)
406	{
407	unsigned short* L = (unsigned short)malloc(nodeCountsizeof(unsigned short));
408	memset(L, 0, nodeCount*sizeof(unsigned short));
409	unsigned short* R = (unsigned short)malloc(nodeCountsizeof(unsigned short));
410	memset(R, 0, nodeCount*sizeof(unsigned short));
411	unsigned int* C = (unsigned int)malloc(nodeCountsizeof(unsigned int));
412	memset(C, 0, nodeCount*sizeof(unsigned int));
413	unsigned char* t = (unsigned char)malloc(nodeCountsizeof(unsigned char));
414	memset(t, 0, nodeCount*sizeof(unsigned char));
415	pad_tree_ushort(huffmanTree,L,R,C,t,0,huffmanTree->qq[1]);
416	unsigned int totalSize = 1+2nodeCountsizeof(unsigned short)+nodeCountsizeof(unsigned char) + nodeCountsizeof(unsigned int);
417	out = (unsigned char)malloc(totalSize);
418	(*out)[0] = (unsigned char)sysEndianType;
419	memcpy(out+1, L, nodeCountsizeof(unsigned short));
420	memcpy((out)+1+nodeCountsizeof(unsigned short),R,nodeCount*sizeof(unsigned short));
421	memcpy((out)+1+2nodeCountsizeof(unsigned short),C,nodeCountsizeof(unsigned int));
422	memcpy((out)+1+2nodeCountsizeof(unsigned short)+nodeCountsizeof(unsigned int),t,nodeCount*sizeof(unsigned char));
423	free(L);
424	free(R);
425	free(C);
426	free(t);
427	return totalSize;
428	}
429	else //nodeCount>65536
430	{
431	unsigned int* L = (unsigned int)malloc(nodeCountsizeof(unsigned int));
432	memset(L, 0, nodeCount*sizeof(unsigned int));
433	unsigned int* R = (unsigned int)malloc(nodeCountsizeof(unsigned int));
434	memset(R, 0, nodeCount*sizeof(unsigned int));
435	unsigned int* C = (unsigned int)malloc(nodeCountsizeof(unsigned int));
436	memset(C, 0, nodeCount*sizeof(unsigned int));
437	unsigned char* t = (unsigned char)malloc(nodeCountsizeof(unsigned char));
438	memset(t, 0, nodeCount*sizeof(unsigned char));
439	pad_tree_uint(huffmanTree, L,R,C,t,0,huffmanTree->qq[1]);
440
441	//debug
442	//node root = new_node2(0,0);
443	//unpad_tree_uint(L,R,C,t,0,root);
444
445	unsigned int totalSize = 1+3nodeCountsizeof(unsigned int)+nodeCount*sizeof(unsigned char);
446	out = (unsigned char)malloc(totalSize);
447	(*out)[0] = (unsigned char)sysEndianType;
448	memcpy(out+1, L, nodeCountsizeof(unsigned int));
449	memcpy((out)+1+nodeCountsizeof(unsigned int),R,nodeCount*sizeof(unsigned int));
450	memcpy((out)+1+2nodeCountsizeof(unsigned int),C,nodeCountsizeof(unsigned int));
451	memcpy((out)+1+3nodeCountsizeof(unsigned int),t,nodeCountsizeof(unsigned char));
452	free(L);
453	free(R);
454	free(C);
455	free(t);
456	return totalSize;
457	}
458	}
459
460	void unpad_tree_uchar(HuffmanTree* huffmanTree, unsigned char* L, unsigned char* R, unsigned int* C, unsigned char *t, unsigned int i, node root)
461	{
462	//root->c = C[i];
463	if(root->t==0)
464	{
465	unsigned char l, r;
466	l = L[i];
467	if(l!=0)
468	{
469	node lroot = new_node2(huffmanTree,C[l],t[l]);
470	root->left = lroot;
471	unpad_tree_uchar(huffmanTree,L,R,C,t,l,lroot);
472	}
473	r = R[i];
474	if(r!=0)
475	{
476	node rroot = new_node2(huffmanTree,C[r],t[r]);
477	root->right = rroot;
478	unpad_tree_uchar(huffmanTree,L,R,C,t,r,rroot);
479	}
480	}
481	}
482
483	void unpad_tree_ushort(HuffmanTree* huffmanTree, unsigned short* L, unsigned short* R, unsigned int* C, unsigned char* t, unsigned int i, node root)
484	{
485	//root->c = C[i];
486	if(root->t==0)
487	{
488	unsigned short l, r;
489	l = L[i];
490	if(l!=0)
491	{
492	node lroot = new_node2(huffmanTree,C[l],t[l]);
493	root->left = lroot;
494	unpad_tree_ushort(huffmanTree,L,R,C,t,l,lroot);
495	}
496	r = R[i];
497	if(r!=0)
498	{
499	node rroot = new_node2(huffmanTree,C[r],t[r]);
500	root->right = rroot;
501	unpad_tree_ushort(huffmanTree,L,R,C,t,r,rroot);
502	}
503	}
504	}
505
506	void unpad_tree_uint(HuffmanTree* huffmanTree, unsigned int* L, unsigned int* R, unsigned int* C, unsigned char* t, unsigned int i, node root)
507	{
508	//root->c = C[i];
509	if(root->t==0)
510	{
511	unsigned int l, r;
512	l = L[i];
513	if(l!=0)
514	{
515	node lroot = new_node2(huffmanTree,C[l],t[l]);
516	root->left = lroot;
517	unpad_tree_uint(huffmanTree,L,R,C,t,l,lroot);
518	}
519	r = R[i];
520	if(r!=0)
521	{
522	node rroot = new_node2(huffmanTree,C[r],t[r]);
523	root->right = rroot;
524	unpad_tree_uint(huffmanTree,L,R,C,t,r,rroot);
525	}
526	}
527	}
528
529	node reconstruct_HuffTree_from_bytes_anyStates(HuffmanTree huffmanTree, unsigned char bytes, int nodeCount)
530	{
531	//printf("nodeCount=%d\n", nodeCount);
532	if(nodeCount<=256)
533	{
534	unsigned char* L = (unsigned char)malloc(nodeCountsizeof(unsigned char));
535	memset(L, 0, nodeCount*sizeof(unsigned char));
536	unsigned char* R = (unsigned char)malloc(nodeCountsizeof(unsigned char));
537	memset(R, 0, nodeCount*sizeof(unsigned char));
538	unsigned int* C = (unsigned int)malloc(nodeCountsizeof(unsigned int));
539	memset(C, 0, nodeCount*sizeof(unsigned int));
540	unsigned char* t = (unsigned char)malloc(nodeCountsizeof(unsigned char));
541	memset(t, 0, nodeCount*sizeof(unsigned char));
542	unsigned char cmpSysEndianType = bytes[0];
543	if(cmpSysEndianType!=(unsigned char)sysEndianType)
544	{
545	unsigned char* p = (unsigned char)(bytes+1+2nodeCount*sizeof(unsigned char));
546	size_t i = 0, size = nodeCount*sizeof(unsigned int);
547	while(1)
548	{
549	symTransform_4bytes(p);
550	i+=sizeof(unsigned int);
551	if(i<size)
552	p+=sizeof(unsigned int);
553	else
554	break;
555	}
556	}
557	memcpy(L, bytes+1, nodeCount*sizeof(unsigned char));
558	memcpy(R, bytes+1+nodeCountsizeof(unsigned char), nodeCountsizeof(unsigned char));
559	memcpy(C, bytes+1+2nodeCountsizeof(unsigned char), nodeCount*sizeof(unsigned int));
560	memcpy(t, bytes+1+2nodeCountsizeof(unsigned char)+nodeCountsizeof(unsigned int), nodeCountsizeof(unsigned char));
561	node root = new_node2(huffmanTree, C[0],t[0]);
562	unpad_tree_uchar(huffmanTree,L,R,C,t,0,root);
563	free(L);
564	free(R);
565	free(C);
566	free(t);
567	return root;
568	}
569	else if(nodeCount<=65536)
570	{
571	unsigned short* L = (unsigned short)malloc(nodeCountsizeof(unsigned short));
572	memset(L, 0, nodeCount*sizeof(unsigned short));
573	unsigned short* R = (unsigned short)malloc(nodeCountsizeof(unsigned short));
574	memset(R, 0, nodeCount*sizeof(unsigned short));
575	unsigned int* C = (unsigned int)malloc(nodeCountsizeof(unsigned int));
576	memset(C, 0, nodeCount*sizeof(unsigned int));
577	unsigned char* t = (unsigned char)malloc(nodeCountsizeof(unsigned char));
578	memset(t, 0, nodeCount*sizeof(unsigned char));
579
580	unsigned char cmpSysEndianType = bytes[0];
581	if(cmpSysEndianType!=(unsigned char)sysEndianType)
582	{
583	unsigned char* p = (unsigned char*)(bytes+1);
584	size_t i = 0, size = 3nodeCountsizeof(unsigned int);
585	while(1)
586	{
587	symTransform_4bytes(p);
588	i+=sizeof(unsigned int);
589	if(i<size)
590	p+=sizeof(unsigned int);
591	else
592	break;
593	}
594	}
595
596	memcpy(L, bytes+1, nodeCount*sizeof(unsigned short));
597	memcpy(R, bytes+1+nodeCountsizeof(unsigned short), nodeCountsizeof(unsigned short));
598	memcpy(C, bytes+1+2nodeCountsizeof(unsigned short), nodeCount*sizeof(unsigned int));
599
600	memcpy(t, bytes+1+2nodeCountsizeof(unsigned short)+nodeCountsizeof(unsigned int), nodeCountsizeof(unsigned char));
601
602	node root = new_node2(huffmanTree,0,0);
603	unpad_tree_ushort(huffmanTree,L,R,C,t,0,root);
604	free(L);
605	free(R);
606	free(C);
607	free(t);
608	return root;
609	}
610	else //nodeCount>65536
611	{
612	unsigned int* L = (unsigned int)malloc(nodeCountsizeof(unsigned int));
613	memset(L, 0, nodeCount*sizeof(unsigned int));
614	unsigned int* R = (unsigned int)malloc(nodeCountsizeof(unsigned int));
615	memset(R, 0, nodeCount*sizeof(unsigned int));
616	unsigned int* C = (unsigned int)malloc(nodeCountsizeof(unsigned int));
617	memset(C, 0, nodeCount*sizeof(unsigned int));
618	unsigned char* t = (unsigned char)malloc(nodeCountsizeof(unsigned char));
619	memset(t, 0, nodeCount*sizeof(unsigned char));
620	unsigned char cmpSysEndianType = bytes[0];
621	if(cmpSysEndianType!=(unsigned char)sysEndianType)
622	{
623	unsigned char* p = (unsigned char*)(bytes+1);
624	size_t i = 0, size = 3nodeCountsizeof(unsigned int);
625	while(1)
626	{
627	symTransform_4bytes(p);
628	i+=sizeof(unsigned int);
629	if(i<size)
630	p+=sizeof(unsigned int);
631	else
632	break;
633	}
634	}
635
636	memcpy(L, bytes+1, nodeCount*sizeof(unsigned int));
637	memcpy(R, bytes+1+nodeCountsizeof(unsigned int), nodeCountsizeof(unsigned int));
638	memcpy(C, bytes+1+2nodeCountsizeof(unsigned int), nodeCount*sizeof(unsigned int));
639
640	memcpy(t, bytes+1+3nodeCountsizeof(unsigned int), nodeCount*sizeof(unsigned char));
641
642	node root = new_node2(huffmanTree,0,0);
643	unpad_tree_uint(huffmanTree,L,R,C,t,0,root);
644	free(L);
645	free(R);
646	free(C);
647	free(t);
648	return root;
649	}
650	}
651
652	void encode_withTree(HuffmanTree* huffmanTree, int s, size_t length, unsigned char out, size_t outSize)
653	{
654	size_t i;
655	int nodeCount = 0;
656	unsigned char *treeBytes, buffer[4];
657
658	init(huffmanTree, s, length);
659	for (i = 0; i < huffmanTree->stateNum; i++)
660	if (huffmanTree->code[i]) nodeCount++;
661	nodeCount = nodeCount*2-1;
662	unsigned int treeByteSize = convert_HuffTree_to_bytes_anyStates(huffmanTree,nodeCount, &treeBytes);
663	//printf("treeByteSize=%d\n", treeByteSize);
664	out = (unsigned char)malloc(length*sizeof(int)+treeByteSize);
665	intToBytes_bigEndian(buffer, nodeCount);
666	memcpy(*out, buffer, 4);
667	intToBytes_bigEndian(buffer, huffmanTree->stateNum/2); //real number of intervals
668	memcpy(*out+4, buffer, 4);
669	memcpy(*out+8, treeBytes, treeByteSize);
670	free(treeBytes);
671	size_t enCodeSize = 0;
672	encode(huffmanTree, s, length, *out+8+treeByteSize, &enCodeSize);
673	*outSize = 8+treeByteSize+enCodeSize;
674
675	//unsigned short state[length];
676	//decode(*out+4+treeByteSize, enCodeSize, qqq[0], state);
677	//printf("dataSeriesLength=%d",length );
678	}
679
680	/**
681	* @par *out rememmber to allocate targetLength short_type data for it beforehand.
682	*
683	* */
684	void decode_withTree(HuffmanTree* huffmanTree, unsigned char s, size_t targetLength, int out)
685	{
686	size_t encodeStartIndex;
687	size_t nodeCount = bytesToInt_bigEndian(s);
688	node root = reconstruct_HuffTree_from_bytes_anyStates(huffmanTree,s+8, nodeCount);
689
690	//sdi: Debug
691	/* build_code(root, 0, 0, 0);
692	int i;
693	unsigned long code_1, code_2;
694	for (i = 0; i < stateNum; i++)
695	if (code[i])
696	{
697	printf("%d: %lu,%lu ; %u\n", i, (code[i])[0],(code[i])[1], cout[i]);
698	//code_1 = (code[i])[0];
699	}*/
700
701	if(nodeCount<=256)
702	encodeStartIndex = 1+3nodeCountsizeof(unsigned char)+nodeCount*sizeof(unsigned int);
703	else if(nodeCount<=65536)
704	encodeStartIndex = 1+2nodeCountsizeof(unsigned short)+nodeCountsizeof(unsigned char)+nodeCountsizeof(unsigned int);
705	else
706	encodeStartIndex = 1+3nodeCountsizeof(unsigned int)+nodeCount*sizeof(unsigned char);
707	decode(s+8+encodeStartIndex, targetLength, root, out);
708	}
709
710	void SZ_ReleaseHuffman(HuffmanTree* huffmanTree)
711	{
712	size_t i;
713	free(huffmanTree->pool);
714	huffmanTree->pool = NULL;
715	free(huffmanTree->qqq);
716	huffmanTree->qqq = NULL;
717	for(i=0;i<huffmanTree->stateNum;i++)
718	{
719	if(huffmanTree->code[i]!=NULL)
720	free(huffmanTree->code[i]);
721	}
722	free(huffmanTree->code);
723	huffmanTree->code = NULL;
724	free(huffmanTree->cout);
725	huffmanTree->cout = NULL;
726	free(huffmanTree);
727	huffmanTree = NULL;
728	}

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