#include #include #include #include #include #include "clustalw.h" #include "xmenu.h" static void build_profile(int prf_length,int first_seq,int last_seq,sint matrix[NUMRES][NUMRES], sint *weight,sint **profile); static void calc_colscores(Boolean update_seqs,Boolean update_scores); static void calc_panel_segment_exceptions(PaneL p); static void calc_weights(PaneL p); static void remove_short_segments(PaneL p); extern Boolean aln_mode; extern Boolean profile1_empty,profile2_empty; extern int score_cutoff; /* cutoff for residue exceptions */ extern int score_hwin; /* half window for summing alignment column scores */ extern int score_scale; extern int segment_dnascale; extern int length_cutoff; /* cutoffs for segment exceptions */ extern Boolean residue_exceptions; extern Boolean segment_exceptions; extern int score_matnum; extern char score_mtrxname[]; extern int segment_matnum; extern char segment_mtrxname[]; extern int score_dnamatnum; extern char score_dnamtrxname[]; extern int segment_dnamatnum; extern char segment_dnamtrxname[]; extern IteM segment_item; extern double **tmat; extern short score_matrix[]; extern short score_aa_xref[]; extern short segment_matrix[]; extern short segment_aa_xref[]; extern short score_dnamatrix[]; extern short score_dna_xref[]; extern short segment_dnamatrix[]; extern short segment_dna_xref[]; extern WindoW mainw; extern FonT datafont; extern short idmat[]; extern short def_dna_xref[],def_aa_xref[]; extern short swgapdnamt[],clustalvdnamt[]; /* used for alignment scores */ extern short gon80mt[],gon120mt[],gon250mt[],gon350mt[]; extern Boolean dnaflag; extern sint max_aa; extern sint *seqlen_array; extern char **seq_array; extern sint gap_pos1, gap_pos2; extern sint *output_index; extern spanel seq_panel; /* data for multiple alignment area */ extern spanel prf_panel[]; /* data for profile alignment areas */ extern PrompT residue_cutofftext; extern PrompT length_cutofftext; extern PrompT scorescaletext; extern PrompT segmentdnascaletext; extern PrompT scoremattext; extern PrompT segmentmattext; extern PrompT scorednamattext; extern PrompT segmentdnamattext; extern PopuP show_seg_toggle; extern GrouP score_matrix_list,seg_matrix_list; extern GrouP score_dnamatrix_list,seg_dnamatrix_list; static Char filename[FILENAMELEN]; /* used in temporary file selection window */ void draw_colscores(PaneL p) { RecT block,r; int i, b, x, y; panel_data data; UseWindow(mainw); Select(p); SelectFont(datafont); GetPanelExtra(p, &data); if(data.nseqs == 0) return; if(data.colscore == NULL) return; if(data.vcols<=0) return; ObjectRect (p, &r); InsetRect(&r,1,1); block.bottom=r.bottom; block.top=block.bottom-SCOREHEIGHT-1; block.left=r.left; block.right=r.right; data_colors(); EraseRect(&block); Gray(); r.left=block.left+data.charwidth; r.bottom=b=block.bottom; for(i=data.firstvcol;i=0 && seq_array[s+1][p+1]=0 && seq_array[s+1][p+1]0) mean/=n; for(s=data.firstseq,i=0; s=0 && seq_array[s+1][p+1] 0.5) { q3=sorteddist[(int)t+1]; q1=sorteddist[n-(int)t-1]; } else { q3=sorteddist[(int)t]; q1=sorteddist[n-(int)t]; } if (n<4)ul=sorteddist[0]; else ul=q3+(q3-q1)*((float)score_cutoff/2.0); } /* fprintf(fd,"\nMedian %.1f Q1 %.1f Q3 %.1f UL %.1f\n",median,q1,q3,ul); fprintf(fd,"\nExceptions: "); for(s=0;sul) fprintf(fd,"%d ",s+1); */ for(s=data.firstseq;sul && p=0 && seq_array[s+1][p+1]=l) return; swap(scores,f,(f+l)/2); last=f; for(i=f+1;i<=l;i++) { if(scores[i]>scores[f]) swap(scores,++last,i); } swap(scores,f,last); sort_scores(scores,f,last-1); sort_scores(scores,last+1,l); } void swap(float *scores,int s1, int s2) { float temp; temp=scores[s1]; scores[s1]=scores[s2]; scores[s2]=temp; } void set_scorescale(BaR bar, GraphiC p, Nlm_Int2 newval, Nlm_Int2 oldval) { char str[FILENAMELEN]; panel_data data; score_scale = newval+1; calc_colscores(FALSE,TRUE); sprintf(str,"Score Plot Scale: %2d",score_scale); SetTitle(scorescaletext,str); } void set_scorecutoff(BaR bar, GraphiC p, Nlm_Int2 newval, Nlm_Int2 oldval) { char str[FILENAMELEN]; int temp; panel_data data; temp=newval+1; score_cutoff = temp; calc_colscores(residue_exceptions,FALSE); sprintf(str,"Residue Exception Cutoff: %2d",score_cutoff); SetTitle(residue_cutofftext,str); } void calc_segment_exceptions(IteM i) { WatchCursor(); segment_exceptions=TRUE; calc_seg_exceptions(); show_segment_exceptions(); SetValue(show_seg_toggle,1); SetStatus(segment_item,segment_exceptions); ArrowCursor(); } void set_lengthcutoff(BaR bar, GraphiC p, Nlm_Int2 newval, Nlm_Int2 oldval) { char str[100]; int temp; temp=newval+1; length_cutoff = temp; sprintf(str,"Minimum Length of Segments: %2d",length_cutoff); if(aln_mode==MULTIPLEM) { remove_short_segments(seq_panel.seqs); } else { remove_short_segments(prf_panel[0].seqs); remove_short_segments(prf_panel[1].seqs); } if(segment_exceptions) show_segment_exceptions(); SetTitle(length_cutofftext,str); } void set_score_user_matrix(ButtoN but) { if(get_user_matrixname(score_mtrxname,score_matrix,score_aa_xref,6,&score_matnum,scoremattext)) { calc_colscores(residue_exceptions,TRUE); SetValue(score_matrix_list,score_matnum); } } void set_score_matrix(GrouP g) { int tmp; tmp = GetValue(g); if(tmp>0 && tmp<6) { score_matnum=tmp; } else { if (score_mtrxname[0]=='\0') { get_user_matrixname(score_mtrxname,score_matrix,score_aa_xref,6,&score_matnum,scoremattext); } else score_matnum=6; } calc_colscores(residue_exceptions,TRUE); SetValue(score_matrix_list,score_matnum); } void set_segment_user_matrix(ButtoN but) { if(get_user_matrixname(segment_mtrxname,segment_matrix,segment_aa_xref,5,&segment_matnum,segmentmattext)) { calc_seg_exceptions(); if(segment_exceptions) show_segment_exceptions(); SetValue(seg_matrix_list,segment_matnum); } } void set_segment_matrix(GrouP g) { int tmp; tmp = GetValue(g); if(tmp>0 && tmp<5) { segment_matnum=tmp; } else { if (segment_mtrxname[0]=='\0') { get_user_matrixname(segment_mtrxname,segment_matrix,segment_aa_xref,5,&segment_matnum,segmentmattext); } else segment_matnum=5; } calc_seg_exceptions(); if(segment_exceptions) show_segment_exceptions(); SetValue(seg_matrix_list,segment_matnum); } void set_score_user_dnamatrix(ButtoN but) { if(get_user_matrixname(score_dnamtrxname,score_dnamatrix,score_dna_xref,3,&score_dnamatnum,scorednamattext)) { calc_colscores(residue_exceptions,TRUE); SetValue(score_dnamatrix_list,score_dnamatnum); } } void set_score_dnamatrix(GrouP g) { int tmp; tmp = GetValue(g); if(tmp>0 && tmp<3) { score_dnamatnum=tmp; } else { if (score_dnamtrxname[0]=='\0') { get_user_matrixname(score_dnamtrxname,score_dnamatrix,score_dna_xref,3,&score_dnamatnum,scorednamattext); } else score_dnamatnum=3; } calc_colscores(residue_exceptions,TRUE); SetValue(score_dnamatrix_list,score_dnamatnum); } void set_segment_user_dnamatrix(ButtoN but) { if(get_user_matrixname(segment_dnamtrxname,segment_dnamatrix,segment_dna_xref,3,&segment_dnamatnum,segmentdnamattext)) calc_seg_exceptions(); if(segment_exceptions) show_segment_exceptions(); SetValue(seg_dnamatrix_list,segment_dnamatnum); } void set_segment_dnamatrix(GrouP g) { int tmp; tmp = GetValue(g); if(tmp>0 && tmp<3) { segment_dnamatnum=tmp; } else { if (segment_dnamtrxname[0]=='\0') { get_user_matrixname(segment_dnamtrxname,segment_dnamatrix,segment_dna_xref,3,&segment_dnamatnum,segmentdnamattext); } else segment_dnamatnum=3; } calc_seg_exceptions(); if(segment_exceptions) show_segment_exceptions(); SetValue(seg_dnamatrix_list,segment_dnamatnum); } static void calc_colscores(Boolean update_seqs,Boolean update_scores) { panel_data data; if(aln_mode==MULTIPLEM) { GetPanelExtra(seq_panel.seqs,&data); make_colscores(data); SetPanelExtra(seq_panel.seqs,&data); if(update_seqs) draw_seqs(seq_panel.seqs); if(update_scores) draw_colscores(seq_panel.seqs); } else { GetPanelExtra(prf_panel[0].seqs,&data); make_colscores(data); SetPanelExtra(prf_panel[0].seqs,&data); if(update_seqs) draw_seqs(prf_panel[0].seqs); if(update_scores) draw_colscores(prf_panel[0].seqs); GetPanelExtra(prf_panel[1].seqs,&data); make_colscores(data); SetPanelExtra(prf_panel[1].seqs,&data); if(update_seqs) draw_seqs(prf_panel[1].seqs); if(update_scores) draw_colscores(prf_panel[1].seqs); } } void calc_seg_exceptions(void) { if(aln_mode==MULTIPLEM) { calc_panel_segment_exceptions(seq_panel.seqs); } else { calc_panel_segment_exceptions(prf_panel[0].seqs); calc_panel_segment_exceptions(prf_panel[1].seqs); } } void show_segment_exceptions(void) { if(aln_mode==MULTIPLEM) { draw_seqs(seq_panel.seqs); } else { draw_seqs(prf_panel[0].seqs); draw_seqs(prf_panel[1].seqs); } } static void remove_short_segments(PaneL p) { int i,j,k,start; panel_data data; GetPanelExtra(p,&data); if(data.nseqs<=0) return; /* Reset all the exceptions - a value of 1 indicates an exception that will be displayed. A value of -1 is used to remember exceptions that are temporarily hidden in the display */ for(i=0;i=2) { for (i=1;i<=data.nseqs;i++) { for (j=i+1;j<=data.nseqs;j++) { dscore = countid(i+data.firstseq,j+data.firstseq); tmat[i][j] = (100.0 - dscore)/100.0; tmat[j][i] = tmat[i][j]; } } if((tree = open_explicit_file(tree_name))==NULL) return; guide_tree(tree,data.firstseq+1,data.nseqs); status = read_tree(tree_name, data.firstseq, data.firstseq+data.nseqs); if (status == 0) return; } weight = (sint *) ckalloc( (data.firstseq+data.nseqs+1) * sizeof(sint) ); /* get the sequence weights */ calc_seq_weights(data.firstseq, data.firstseq+data.nseqs,weight); if(data.seqweight==NULL) data.seqweight=(sint *)ckalloc((data.nseqs+1) * sizeof(sint)); for(i=data.firstseq;i= 2) { clear_tree(NULL); remove(tree_name); } ckfree(weight); SetPanelExtra(p,&data); info("Done."); ArrowCursor(); } static void calc_panel_segment_exceptions(PaneL p) { int i,j; float sum,prev_sum; float gscale; sint **profile; sint *weight,sweight; sint *gaps; sint maxres; int max=0,offset; short *mat_xref, *matptr; sint matrix[NUMRES][NUMRES]; float *fsum; float *bsum; float *pscore; panel_data data; /* First, calculate sequence weights which will be used to build the profile */ calc_weights(p); GetPanelExtra(p,&data); if(data.nseqs<=0) return; WatchCursor(); info("Calculating profile scores..."); for(i=0;imax) max=matrix[i][j]; /* subtract max*scale/2 from each matrix value */ offset=(float)(max*segment_dnascale)/20.0; for(i=0;i<=max_aa;i++) for(j=0;j<=max_aa;j++) matrix[i][j]-=offset; } else { if (segment_matnum==1) { matptr = gon80mt; mat_xref = def_aa_xref; } else if (segment_matnum==2) { matptr = gon120mt; mat_xref = def_aa_xref; } else if (segment_matnum==3) { matptr = gon250mt; mat_xref = def_aa_xref; } else if (segment_matnum==4) { matptr = gon350mt; mat_xref = def_aa_xref; } else { matptr = segment_matrix; mat_xref = segment_aa_xref; } /* get a negative matrix */ maxres = get_matrix(matptr, mat_xref, matrix, TRUE, 100); } profile = (sint **) ckalloc( (data.ncols+2) * sizeof (sint *) ); for(i=0; i max_aa)) gaps[j-1]++; } weight = (sint *) ckalloc( (data.firstseq+data.nseqs+1) * sizeof(sint) ); for(i=data.firstseq;i=max_aa) { pscore[j-1]=0.0; sum=0.0; } else pscore[j-1]=(profile[j][seq_array[i][j]]- weight[i-1]*matrix[seq_array[i][j]][seq_array[i][j]])*gscale/sweight; sum+=pscore[j-1]; if(sum>0.0) sum=0.0; fsum[j-1]=sum; } /* trim off any positive scoring residues from the end of the segments */ prev_sum=0; for(j=seqlen_array[i]-1;j>=0;j--) { if(prev_sum>=0.0 && fsum[j]<0.0 && pscore[j]>=0.0) fsum[j]=0.0; prev_sum=fsum[j]; } /* Now, in a backward phase, do the same summing process. */ sum=0.0; for(j=seqlen_array[i];j>=1;j--) { if(seq_array[i][j]<0 || seq_array[i][j]>=max_aa) sum=0; else sum+=pscore[j-1]; if(sum>0.0) sum=0.0; bsum[j-1]=sum; } /* trim off any positive scoring residues from the start of the segments */ prev_sum=0; for(j=0;j=0.0 && bsum[j]<0.0 && pscore[j]>=0.0) bsum[j]=0.0; prev_sum=bsum[j]; } /*Mark residues as exceptions if they score negative in the forward AND backward directions. */ for(j=1;j<=seqlen_array[i];j++) if(fsum[j-1]<0.0 && bsum[j-1]<0.0) if(seq_array[i][j]>=0 && seq_array[i][j]