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source: branches/help/GDE/CLUSTAL/myers.c

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Last change on this file was 13845, checked in by westram, 10 years ago
remove executable flag
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1	#include <stdio.h>
2	#include <string.h>
3	#include <stdlib.h>
4	#include "clustalv.h"
5
6	/*
7	* Prototypes
8	*/
9
10	extern Boolean read_tree(int ,double ,int ,int ,int *);
11	extern void *ckalloc(size_t);
12
13	void init_myers(void);
14	void myers(int);
15
16	static void group_gap(int,int,char *);
17	static void add_ggaps(void);
18	static void add(int);
19	static int calc_weight(int,int,int,int);
20	static void fill_pam(void);
21	static int diff(int,int,int,int,int,int);
22	static void do_align(int,int *);
23	static int *alist;
24	static int naa1,naa2,**naas;
25
26	/*
27	* Global variables
28	*/
29
30	extern int nseqs, next, profile1_nseqs; /* DES */
31	extern int *seqlen_array;
32	extern char **seq_array;
33	extern int pamo[];
34	extern Boolean dnaflag,percent;
35	extern int xover,big_pam;
36	extern int nblocks;
37	extern FILE clustal_outfile,tree;
38	extern char treename[],seqname[],mtrxnam[],**names;
39	extern char *matptr,idmat[],pam100mt[],pam250mt[];
40	extern int ktup,wind_gap,window;
41	extern int signif;
42
43
44	int gap_open, gap_extend;
45	int dna_gap_open, dna_gap_extend;
46	int prot_gap_open, prot_gap_extend;
47
48	Boolean is_weight;
49
50	extern int zza,zzb,zzc,zzd; /* allocated in show_pair.c */
51	static int *group;
52	static int print_ptr,last_print,pos1,pos2;
53	extern int * displ; /* allocated in show_pair.c */
54	static int pam[21][21];
55	int weights[21][21];
56	static int fst_list,snd_list;
57
58	#define gap(x) ((x) <= 0 ? 0 : gap_open + gap_extend * (x))
59
60	void init_myers()
61	{
62	register int i;
63
64	group = (int )ckalloc( (MAXN+1) sizeof (int));
65
66	alist = (int )ckalloc( (MAXN+1) sizeof (int));
67	fst_list = (int )ckalloc( (MAXN+1) sizeof (int));
68	snd_list = (int )ckalloc( (MAXN+1) sizeof (int));
69
70	naa1 = (int *)ckalloc(21 sizeof (int *) );
71	for(i=0;i<21;i++)
72	naa1[i]=(int )ckalloc( (MAXLEN+1)sizeof (int));
73	naa2 = (int *)ckalloc(21 sizeof (int *) );
74	for(i=0;i<21;i++)
75	naa2[i]=(int )ckalloc( (MAXLEN+1)sizeof (int));
76	naas = (int *)ckalloc(21 sizeof (int *) );
77	for(i=0;i<21;i++)
78	naas[i]=(int )ckalloc( (MAXLEN+1)sizeof (int));
79
80	dna_gap_open = 10; /* Default gap penalties for DNA */
81	dna_gap_extend = 10;
82
83	prot_gap_open = 10; /* Default gap penalties for protein */
84	prot_gap_extend = 10;
85
86	is_weight = TRUE;
87	}
88
89
90
91	static void group_gap(int len,int sclass,char *seq)
92	{
93	int i,j,k,xtra;
94
95	for(i=1;i<=nseqs;++i)
96	if(group[i] == sclass) {
97	xtra = len - seqlen_array[i];
98	if(xtra>0)
99	for(j=1;j<=xtra;++j)
100	seq_array[i][seqlen_array[i]+j] = -1;
101	for(j=1;j<=len;++j)
102	if(seq[j] == '-') {
103	for(k=len;k>=j+1;--k)
104	seq_array[i][k] = seq_array[i][k-1];
105	seq_array[i][j] = -1;
106	}
107	seqlen_array[i] = len;
108	}
109	}
110
111
112	static void add_ggaps()
113	{
114	int i,j,k,pos,to_do,len;
115	char str1[MAXLEN+1],str2[MAXLEN+1];
116
117	pos=1;
118	to_do=print_ptr-1;
119
120	for(i=1;i<=to_do;++i) {
121	if(displ[i]==0) {
122	str1[pos]=str2[pos]='*';
123	++pos;
124	}
125	else {
126	if((k=displ[i])>0) {
127	for(j=0;j<=k-1;++j) {
128	str2[pos+j]='*';
129	str1[pos+j]='-';
130	}
131	pos += k;
132	}
133	else {
134	k = (displ[i]<0) ? displ[i] * -1 : displ[i];
135	for(j=0;j<=k-1;++j) {
136	str1[pos+j]='*';
137	str2[pos+j]='-';
138	}
139	pos += k;
140	}
141	}
142	}
143
144	len = --pos;
145	group_gap(len,1,str1);
146	group_gap(len,2,str2);
147	}
148
149
150	static void add(int v)
151	{
152
153	if(last_print<0) {
154	displ[print_ptr-1] = v;
155	displ[print_ptr++] = last_print;
156	}
157	else
158	last_print = displ[print_ptr++] = v;
159	}
160
161
162	static int calc_weight(int iat,int jat,int v1,int v2)
163	{
164	int sum,i,j,lookn,ret;
165	int ipos,jpos;
166
167	sum=lookn=0;
168	ipos = v1 + iat -1;
169	jpos = v2 + jat -1;
170
171	ret=0;
172	if(pos1>=pos2) {
173	for(i=1;i<=pos2;++i) {
174	j=seq_array[alist[i]][jpos];
175	if(j>0) {
176	sum += naas[j][ipos];
177	++lookn;
178	}
179	}
180	}
181	else {
182	for(i=1;i<=pos1;++i) {
183	j=seq_array[alist[i]][ipos];
184	if(j>0) {
185	sum += naas[j][jpos];
186	++lookn;
187	}
188	}
189	}
190
191	if(sum > 0 ) ret = sum / lookn;
192	return ret;
193	}
194
195
196	static void fill_pam()
197	{
198	register int i,j,pos;
199
200	pos=0;
201
202	for(i=0;i<20;++i)
203	for(j=0;j<=i;++j)
204	pam[i][j]=pamo[pos++];
205
206	for(i=0;i<20;++i)
207	for(j=0;j<=i;++j)
208	pam[j][i]=pam[i][j];
209
210	if(dnaflag) {
211	xover=4;
212	big_pam=8;
213	for(i=0;i<5;++i)
214	for(j=0;j<5;++j) {
215	if(i==j)
216	weights[i][j]=0;
217	else
218	weights[j][i]=10;
219	}
220	if(is_weight) {
221	weights[1][3]=4;
222	weights[3][1]=4;
223	weights[2][4]=4;
224	weights[4][2]=4;
225	}
226	}
227	else {
228	/*
229	fprintf(stdout,"\nxover = %d; big_pam = %d\n",xover,big_pam);
230	*/
231	for(i=1;i<21;++i)
232	for(j=1;j<21;++j) {
233	weights[i][j] = big_pam - pam[i-1][j-1];
234	/*
235	fprintf(stdout,"\n%2d vs %2d: %5d",i,j,weights[i][j]);
236	*/
237	}
238	for(i=0;i<21;++i) {
239	weights[0][i] = xover;
240	weights[i][0] = xover;
241	}
242	}
243	}
244
245	static int diff(int v1,int v2,int v3,int v4,int st,int en)
246	{
247	int ctrc,ctri,ctrj,i,j,k,l,m,n,p,q,flag;
248
249	q = gap_open + gap_extend;
250
251	if(v4<=0) {
252	if(v3>0) {
253	if(last_print<0)
254	last_print = displ[print_ptr-1] -= v3;
255	else
256	last_print = displ[print_ptr++] = -(v3);
257	}
258
259	return gap(v3);
260	}
261
262	if(v3<=1) {
263	if(v3<=0) {
264	add(v4);
265	return gap(v4);
266	}
267	if(st>en)
268	st=en;
269
270	/*************if(!v4)*****BUG******************************/
271
272	ctrc = (st+gap_extend) + gap(v4);
273	ctrj = 0;
274	for(j=1;j<=v4;++j) {
275	k = calc_weight(1,j,v1,v2) + gap(v4-j) + gap(j-1);
276	if(k<ctrc) {
277	ctrc = k;
278	ctrj = j;
279	}
280	}
281
282	if(!ctrj) {
283	add(v4);
284	if(last_print<0)
285	last_print = displ[print_ptr-1] -= 1;
286	else
287	last_print = displ[print_ptr++] = -1;
288	}
289	else {
290	if(ctrj>1)
291	add(ctrj-1);
292	displ[print_ptr++] = last_print = 0;
293	if(ctrj<v4)
294	add(v4-ctrj);
295	}
296	return ctrc;
297	}
298
299
300	ctri = v3 / 2;
301	zza[0] = 0;
302	p = gap_open;
303	for(j=1;j<=v4;++j) {
304	p += gap_extend;
305	zza[j] = p;
306	zzb[j] = p + gap_open;
307	}
308
309	p=st;
310	for(i=1;i<=ctri;++i) {
311	n=zza[0];
312	p += gap_extend;
313	k = p;
314	zza[0]=k;
315	l = p+gap_open;
316	for(j=1;j<=v4;++j) {
317	k += q;
318	l += gap_extend;
319	if(k<l)
320	l=k;
321	k = zza[j] + q;
322	m = zzb[j] + gap_extend;
323	if(k<m)
324	m=k;
325	k = n + calc_weight(i,j,v1,v2);
326	if(l<k)
327	k=l;
328	if(m<k)
329	k=m;
330	n=zza[j];
331	zza[j]=k;
332	zzb[j]=m;
333	}
334	}
335
336	zzb[0]=zza[0];
337	zzc[v4]=0;
338	p=gap_open;
339	for(j=v4-1;j>-1;--j) {
340	p += gap_extend;
341	zzc[j]=p;
342	zzd[j]=p+gap_open;
343	}
344	p=en;
345	for(i=v3-1;i>=ctri;--i) {
346	n=zzc[v4];
347	p += gap_extend;
348	k = p;
349	zzc[v4] = k;
350	l = p+gap_open;
351	for(j=v4-1;j>=0;--j) {
352	k += q;
353	l += gap_extend;
354	if(k<l)
355	l=k;
356	k = zzc[j] + q;
357	m = zzd[j] + gap_extend;
358	if(k<m)
359	m=k;
360	k = n + calc_weight(i+1,j+1,v1,v2);
361	if(l<k)
362	k=l;
363	if(m<k)
364	k=m;
365	n=zzc[j];
366	zzc[j]=k;
367	zzd[j]=m;
368	}
369	}
370
371	zzd[v4]=zzc[v4];
372	ctrc=zza[0]+zzc[0];
373	ctrj=0;
374	flag=1;
375	for(j=0;j<=v4;++j) {
376	k = zza[j] + zzc[j];
377	if(k<=ctrc)
378	if(k<ctrc \|\| ((zza[j]!=zzb[j]) && (zzc[j]==zzd[j]))) {
379	ctrc=k;
380	ctrj=j;
381	}
382	}
383
384	for(j=v4;j>=0;--j) {
385	k = zzb[j] + zzd[j] - gap_open;
386	if(k<ctrc) {
387	ctrc=k;
388	ctrj=j;
389	flag=2;
390	}
391	}
392
393	/* Conquer recursively around midpoint */
394
395	if(flag==1) { /* Type 1 gaps */
396	diff(v1,v2,ctri,ctrj,st,gap_open);
397	diff(v1+ctri,v2+ctrj,v3-ctri,v4-ctrj,gap_open,en);
398	}
399	else {
400	diff(v1,v2,ctri-1,ctrj,st,0);
401	if(last_print<0) /* Delete 2 */
402	last_print = displ[print_ptr-1] -= 2;
403	else
404	last_print = displ[print_ptr++] = -2;
405	diff(v1+ctri+1,v2+ctrj,v3-ctri-1,v4-ctrj,0,en);
406	}
407	return ctrc; /* Return the score of the best alignment */
408	}
409
410
411
412
413
414
415	static void do_align(int v1,int *score)
416	{
417	int ctrc,i,j,k,l1,l2,n;
418	int t_arr[21];
419
420	l1=l2=pos1=pos2=0;
421
422	for(i=1;i<=MAXLEN;++i) {
423	for(j=0;j<21;++j)
424	naa1[j][i]=naa2[j][i]=0;
425	for(j=1;j<21;++j)
426	naas[j][i]=0;
427	}
428
429	for(i=1;i<=nseqs;++i) {
430	if(group[i]==1) {
431	fst_list[++pos1]=i;
432	for(j=1;j<=seqlen_array[i];++j)
433	if(seq_array[i][j]>0) {
434	++naa1[seq_array[i][j]][j];
435	++naa1[0][j];
436	}
437	if(seqlen_array[i]>l1)
438	l1=seqlen_array[i];
439	}
440	else if(group[i]==2) {
441	snd_list[++pos2]=i;
442	for(j=1;j<=seqlen_array[i];++j)
443	if(seq_array[i][j]>0) {
444	++naa2[seq_array[i][j]][j];
445	++naa2[0][j];
446	}
447	if(seqlen_array[i]>l2) l2=seqlen_array[i];
448	}
449	}
450
451	if(pos1>=pos2) {
452	for(i=1;i<=pos2;++i)
453	alist[i]=snd_list[i];
454	for(n=1;n<=l1;++n) {
455	for(i=1;i<21;++i)
456	t_arr[i]=0;
457	for(i=1;i<21;++i)
458	if(naa1[i][n]>0)
459	for(j=1;j<21;++j)
460	t_arr[j] += (weights[i][j]*naa1[i][n]);
461	k = naa1[0][n];
462	if(k>0)
463	for(i=1;i<21;++i)
464	naas[i][n]=t_arr[i]/k;
465	}
466	}
467	else {
468	for(i=1;i<=pos1;++i)
469	alist[i]=fst_list[i];
470	for(n=1;n<=l2;++n) {
471	for(i=1;i<21;++i)
472	t_arr[i]=0;
473	for(i=1;i<21;++i)
474	if(naa2[i][n]>0)
475	for(j=1;j<21;++j)
476	t_arr[j] += (weights[i][j]*naa2[i][n]);
477	k = naa2[0][n];
478	if(k>0)
479	for(i=1;i<21;++i)
480	naas[i][n]=t_arr[i]/k;
481	}
482	}
483
484	score=diff(1,1,l1,l2,v1,v1); / Myers and Miller alignment now */
485	}
486
487
488	void myers(int align_type) /* align_type = 0 for full progressive alignment*/
489	/* align_type = 1 for a profile alignment */
490	{
491	/* static char *nbases = "XACGT";
492	static char seq1[MAXLEN+1]; */
493	char temp[MAXLINE];
494	int val,i,j,k,a,b,len,set;
495	int sets,chunks,ident,lv1,pos,copt,flag,entries,idummy,score,ptr;
496	double dummy;
497
498	nblocks=0;
499
500	fprintf(stdout,"\nStart of Multiple Alignment\n");
501
502	fill_pam();
503
504	if(align_type == 0) { /* a full progressive alignment */
505	sets=0;
506	tree=fopen(treename,"r");
507	while(fgets(temp,MAXLINE,tree)!=NULL) ++sets;
508	fseek(tree,0,0);
509	fprintf(stdout,"There are %d sets\n",sets);
510	}
511	else /* just one set (a profile alignment) */
512	sets = 1;
513
514	fprintf(stdout,"Aligning...\n");
515
516	for(set=1;set<=sets;++set) {
517	if(align_type == 0)
518	read_tree(&entries,&dummy,&idummy,&idummy,group);
519	else {
520	for(i=1; i<=profile1_nseqs; ++i)
521	group[i] = 1;
522	for(i=profile1_nseqs+1; i<=nseqs; ++i)
523	group[i] = 2;
524	entries = nseqs;
525	}
526	last_print=0;
527	print_ptr=1;
528	do_align(gap_open,&score);
529	fprintf(stdout,"Set %d: Entries:%d Score:%d\n",set,entries,score);
530	add_ggaps();
531	}
532	if(align_type == 0) fclose(tree);
533
534	/* make the rest (output stuff) into routine clustal_out in file amenu.c */
535
536	}
537
538

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