#include "mltaln.h" #include "miyata.h" #include "miyata5.h" #include "DNA.h" #include "JTT.c" #include "blosum.c" #define DEBUG 0 #define TEST 0 #define NORMALIZE1 1 static int shishagonyuu( double in ) { int out; if ( in > 0.0 ) out = ( (int)( in + 0.5 ) ); else if( in == 0.0 ) out = ( 0 ); else if( in < 0.0 ) out = ( (int)( in - 0.5 ) ); else out = 0; return( out ); } static void calcfreq_nuc( int nseq, char **seq, double *datafreq ) { int i, j, l; int aan; double total; for( i=0; i<4; i++ ) datafreq[i] = 0.0; total = 0.0; for( i=0; i= 0 && aan < 4 ) { datafreq[aan] += 1.0; total += 1.0; } } } for( i=0; i<4; i++ ) if( datafreq[i] < 0.0001 ) datafreq[i] = 0.0001; total = 0.0; for( i=0; i<4; i++ ) total += datafreq[i]; // fprintf( stderr, "total = %f\n", total ); for( i=0; i<4; i++ ) datafreq[i] /= (double)total; #if 0 fprintf( stderr, "\ndatafreq = " ); for( i=0; i<4; i++ ) fprintf( stderr, "%10.5f ", datafreq[i] ); fprintf( stderr, "\n" ); exit( 1 ); #endif } static void calcfreq( int nseq, char **seq, double *datafreq ) { int i, j, l; int aan; double total; for( i=0; i<20; i++ ) datafreq[i] = 0.0; total = 0.0; for( i=0; i= 0 && aan < 20 ) { datafreq[aan] += 1.0; total += 1.0; } } } for( i=0; i<20; i++ ) if( datafreq[i] < 0.0001 ) datafreq[i] = 0.0001; fprintf( stderr, "datafreq = \n" ); for( i=0; i<20; i++ ) fprintf( stderr, "%f\n", datafreq[i] ); total = 0.0; for( i=0; i<20; i++ ) total += datafreq[i]; fprintf( stderr, "total = %f\n", total ); for( i=0; i<20; i++ ) datafreq[i] /= (double)total; } void constants( int nseq, char **seq ) { int i, j, x; // double tmp; if( dorp == 'd' ) /* DNA */ { int k, m; double average; double **pamx = AllocateDoubleMtx( 11,11 ); double **pam1 = AllocateDoubleMtx( 4, 4 ); double *freq = AllocateDoubleVec( 4 ); scoremtx = -1; if( RNAppenalty == NOTSPECIFIED ) RNAppenalty = DEFAULTRNAGOP_N; if( RNAppenalty_ex == NOTSPECIFIED ) RNAppenalty_ex = DEFAULTRNAGEP_N; if( ppenalty == NOTSPECIFIED ) ppenalty = DEFAULTGOP_N; if( ppenalty_OP == NOTSPECIFIED ) ppenalty_OP = DEFAULTGOP_N; if( ppenalty_ex == NOTSPECIFIED ) ppenalty_ex = DEFAULTGEP_N; if( ppenalty_EX == NOTSPECIFIED ) ppenalty_EX = DEFAULTGEP_N; if( poffset == NOTSPECIFIED ) poffset = DEFAULTOFS_N; if( RNApthr == NOTSPECIFIED ) RNApthr = DEFAULTRNATHR_N; if( pamN == NOTSPECIFIED ) pamN = DEFAULTPAMN; if( kimuraR == NOTSPECIFIED ) kimuraR = 2; RNApenalty = (int)( 3 * 600.0 / 1000.0 * RNAppenalty + 0.5 ); RNApenalty_ex = (int)( 3 * 600.0 / 1000.0 * RNAppenalty_ex + 0.5 ); // fprintf( stderr, "DEFAULTRNAGOP_N = %d\n", DEFAULTRNAGOP_N ); // fprintf( stderr, "RNAppenalty = %d\n", RNAppenalty ); // fprintf( stderr, "RNApenalty = %d\n", RNApenalty ); RNAthr = (int)( 3 * 600.0 / 1000.0 * RNApthr + 0.5 ); penalty = (int)( 3 * 600.0 / 1000.0 * ppenalty + 0.5); penalty_OP = (int)( 3 * 600.0 / 1000.0 * ppenalty_OP + 0.5); penalty_ex = (int)( 3 * 600.0 / 1000.0 * ppenalty_ex + 0.5); penalty_EX = (int)( 3 * 600.0 / 1000.0 * ppenalty_EX + 0.5); offset = (int)( 3 * 600.0 / 1000.0 * poffset + 0.5); offsetFFT = (int)( 3 * 600.0 / 1000.0 * (-0) + 0.5); offsetLN = (int)( 3 * 600.0 / 1000.0 * 100 + 0.5); penaltyLN = (int)( 3 * 600.0 / 1000.0 * -2000 + 0.5); penalty_exLN = (int)( 3 * 600.0 / 1000.0 * -100 + 0.5); sprintf( modelname, "%s%d (%d), %6.3f (%6.3f), %6.3f (%6.3f)", rnakozo?"RNA":"DNA", pamN, kimuraR, -(double)ppenalty*0.001, -(double)ppenalty*0.003, -(double)poffset*0.001, -(double)poffset*0.003 ); if( kimuraR == 9999 ) { for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] = (double)locn_disn[i][j]; #if NORMALIZE1 average = 0.0; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) average += pamx[i][j]; average /= 16.0; if( disp ) fprintf( stderr, "average = %f\n", average ); for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] -= average; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] *= 600.0 / average; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] -= offset; #endif } else { double f = 0.99; double s = (double)kimuraR / ( 2 + kimuraR ) * 0.01; double v = (double)1 / ( 2 + kimuraR ) * 0.01; pam1[0][0] = f; pam1[0][1] = s; pam1[0][2] = v; pam1[0][3] = v; pam1[1][0] = s; pam1[1][1] = f; pam1[1][2] = v; pam1[1][3] = v; pam1[2][0] = v; pam1[2][1] = v; pam1[2][2] = f; pam1[2][3] = s; pam1[3][0] = v; pam1[3][1] = v; pam1[3][2] = s; pam1[3][3] = f; fprintf( stderr, "generating %dPAM scoring matrix for nucleotides ... ", pamN ); if( disp ) { fprintf( stderr, " TPM \n" ); for( i=0; i<4; i++ ) { for( j=0; j<4; j++ ) fprintf( stderr, "%+#6.10f", pam1[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); } MtxuntDouble( pamx, 4 ); for( x=0; x < pamN; x++ ) MtxmltDouble( pamx, pam1, 4 ); for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] /= 1.0 / 4.0; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) { if( pamx[i][j] == 0.0 ) { fprintf( stderr, "WARNING: pamx[i][j] = 0.0 ?\n" ); pamx[i][j] = 0.00001; /* by J. Thompson */ } pamx[i][j] = log10( pamx[i][j] ) * 1000.0; } if( disp ) { fprintf( stderr, " after log\n" ); for( i=0; i<4; i++ ) { for( j=0; j<4; j++ ) fprintf( stderr, "%+#6.10f", pamx[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); } // ????? for( i=0; i<26; i++ ) amino[i] = locaminon[i]; for( i=0; i<0x80; i++ ) amino_n[i] = -1; for( i=0; i<26; i++ ) amino_n[(int)amino[i]] = i; if( fmodel == 1 ) calcfreq_nuc( nseq, seq, freq ); else { freq[0] = 0.25; freq[1] = 0.25; freq[2] = 0.25; freq[3] = 0.25; } // fprintf( stderr, "a, freq[0] = %f\n", freq[0] ); // fprintf( stderr, "g, freq[1] = %f\n", freq[1] ); // fprintf( stderr, "c, freq[2] = %f\n", freq[2] ); // fprintf( stderr, "t, freq[3] = %f\n", freq[3] ); average = 0.0; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) average += pamx[i][j] * freq[i] * freq[j]; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] -= average; average = 0.0; for( i=0; i<4; i++ ) average += pamx[i][i] * 1.0 / 4.0; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] *= 600.0 / average; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] -= offset; /* extending gap cost */ for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) pamx[i][j] = shishagonyuu( pamx[i][j] ); if( disp ) { fprintf( stderr, " after shishagonyuu\n" ); for( i=0; i<4; i++ ) { for( j=0; j<4; j++ ) fprintf( stderr, "%+#6.10f", pamx[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); } fprintf( stderr, "done\n" ); } for( i=0; i<5; i++ ) { pamx[4][i] = pamx[3][i]; pamx[i][4] = pamx[i][3]; } for( i=5; i<10; i++ ) for( j=5; j<10; j++ ) { pamx[i][j] = pamx[i-5][j-5]; } if( disp ) { fprintf( stderr, " before dis\n" ); for( i=0; i<4; i++ ) { for( j=0; j<4; j++ ) fprintf( stderr, "%+#6.10f", pamx[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); } if( disp ) { fprintf( stderr, " score matrix \n" ); for( i=0; i<4; i++ ) { for( j=0; j<4; j++ ) fprintf( stderr, "%+#6.10f", pamx[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); } for( i=0; i<26; i++ ) amino[i] = locaminon[i]; for( i=0; i<26; i++ ) amino_grp[(int)amino[i]] = locgrpn[i]; for( i=0; i<26; i++ ) for( j=0; j<26; j++ ) n_dis[i][j] = 0; for( i=0; i<10; i++ ) for( j=0; j<10; j++ ) n_dis[i][j] = shishagonyuu( pamx[i][j] ); if( disp ) { fprintf( stderr, " score matrix \n" ); for( i=0; i<26; i++ ) { for( j=0; j<26; j++ ) fprintf( stderr, "%+6d", n_dis[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); } // RIBOSUM #if 1 average = 0.0; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) average += ribosum4[i][j] * freq[i] * freq[j]; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) ribosum4[i][j] -= average; average = 0.0; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) for( k=0; k<4; k++ ) for( m=0; m<4; m++ ) { // if( i%4==0&&j%4==3 || i%4==3&&j%4==0 || i%4==1&&j%4==2 || i%4==2&&j%4==1 || i%4==1&&j%4==3 || i%4==3&&j%4==1 ) // if( k%4==0&&m%4==3 || k%4==3&&m%4==0 || k%4==1&&m%4==2 || k%4==2&&m%4==1 || k%4==1&&m%4==3 || k%4==3&&m%4==1 ) average += ribosum16[i*4+j][k*4+m] * freq[i] * freq[j] * freq[k] * freq[m]; } for( i=0; i<16; i++ ) for( j=0; j<16; j++ ) ribosum16[i][j] -= average; average = 0.0; for( i=0; i<4; i++ ) average += ribosum4[i][i] * freq[i]; for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) ribosum4[i][j] *= 600.0 / average; average = 0.0; average += ribosum16[0*4+3][0*4+3] * freq[0] * freq[3]; // AU average += ribosum16[3*4+0][3*4+0] * freq[3] * freq[0]; // UA average += ribosum16[1*4+2][1*4+2] * freq[1] * freq[2]; // CG average += ribosum16[2*4+1][2*4+1] * freq[2] * freq[1]; // GC average += ribosum16[1*4+3][1*4+3] * freq[1] * freq[3]; // GU average += ribosum16[3*4+1][3*4+1] * freq[3] * freq[1]; // UG for( i=0; i<16; i++ ) for( j=0; j<16; j++ ) ribosum16[i][j] *= 600.0 / average; #if 1 for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) ribosum4[i][j] -= offset; /* extending gap cost ?????*/ for( i=0; i<16; i++ ) for( j=0; j<16; j++ ) ribosum16[i][j] -= offset; /* extending gap cost ?????*/ #endif for( i=0; i<4; i++ ) for( j=0; j<4; j++ ) ribosum4[i][j] = shishagonyuu( ribosum4[i][j] ); for( i=0; i<16; i++ ) for( j=0; j<16; j++ ) ribosum16[i][j] = shishagonyuu( ribosum16[i][j] ); if( disp ) { fprintf( stderr, "ribosum after shishagonyuu\n" ); for( i=0; i<4; i++ ) { for( j=0; j<4; j++ ) fprintf( stderr, "%+#6.10f", ribosum4[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); fprintf( stderr, "ribosum16 after shishagonyuu\n" ); for( i=0; i<16; i++ ) { for( j=0; j<16; j++ ) fprintf( stderr, "%+#7.0f", ribosum16[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); } fprintf( stderr, "done\n" ); #if 1 for( i=0; i<37; i++ ) for( j=0; j<37; j++ ) ribosumdis[i][j] = 0.0; //iru for( m=0; m<9; m++ ) for( i=0; i<4; i++ ) // loop for( k=0; k<9; k++ ) for( j=0; j<4; j++ ) ribosumdis[m*4+i][k*4+j] = ribosum4[i][j]; // loop-loop // for( k=0; k<9; k++ ) for( j=0; j<4; j++ ) ribosumdis[m*4+i][k*4+j] = n_dis[i][j]; // loop-loop for( i=0; i<16; i++ ) for( j=0; j<16; j++ ) ribosumdis[i+4][j+4] = ribosum16[i][j]; // stem5-stem5 for( i=0; i<16; i++ ) for( j=0; j<16; j++ ) ribosumdis[i+20][j+20] = ribosum16[i][j]; // stem5-stem5 #else // do not use ribosum for( i=0; i<37; i++ ) for( j=0; j<37; j++ ) ribosumdis[i][j] = 0.0; //iru for( m=0; m<9; m++ ) for( i=0; i<4; i++ ) // loop for( k=0; k<9; k++ ) for( j=0; j<4; j++ ) ribosumdis[m*4+i][k*4+j] = n_dis[i][j]; // loop-loop #endif if( disp ) { fprintf( stderr, "ribosumdis\n" ); for( i=0; i<37; i++ ) { for( j=0; j<37; j++ ) fprintf( stderr, "%+5d", ribosumdis[i][j] ); fprintf( stderr, "\n" ); } fprintf( stderr, "\n" ); } fprintf( stderr, "done\n" ); #endif FreeDoubleMtx( pam1 ); FreeDoubleMtx( pamx ); free( freq ); } else if( dorp == 'p' && scoremtx == 1 ) /* Blosum */ { double *freq; double *freq1; double *datafreq; double average; // double tmp; double **n_distmp; n_distmp = AllocateDoubleMtx( 20, 20 ); datafreq = AllocateDoubleVec( 20 ); freq = AllocateDoubleVec( 20 ); if( ppenalty == NOTSPECIFIED ) ppenalty = DEFAULTGOP_B; if( ppenalty_OP == NOTSPECIFIED ) ppenalty_OP = DEFAULTGOP_B; if( ppenalty_ex == NOTSPECIFIED ) ppenalty_ex = DEFAULTGEP_B; if( ppenalty_EX == NOTSPECIFIED ) ppenalty_EX = DEFAULTGEP_B; if( poffset == NOTSPECIFIED ) poffset = DEFAULTOFS_B; if( pamN == NOTSPECIFIED ) pamN = 0; if( kimuraR == NOTSPECIFIED ) kimuraR = 1; penalty = (int)( 600.0 / 1000.0 * ppenalty + 0.5 ); penalty_OP = (int)( 600.0 / 1000.0 * ppenalty_OP + 0.5 ); penalty_ex = (int)( 600.0 / 1000.0 * ppenalty_ex + 0.5 ); penalty_EX = (int)( 600.0 / 1000.0 * ppenalty_EX + 0.5 ); offset = (int)( 600.0 / 1000.0 * poffset + 0.5 ); offsetFFT = (int)( 600.0 / 1000.0 * (-0) + 0.5); offsetLN = (int)( 600.0 / 1000.0 * 100 + 0.5); penaltyLN = (int)( 600.0 / 1000.0 * -2000 + 0.5); penalty_exLN = (int)( 600.0 / 1000.0 * -100 + 0.5); BLOSUMmtx( nblosum, n_distmp, freq, amino, amino_grp ); if( nblosum == -1 ) sprintf( modelname, "User-defined, %6.3f, %+6.3f, %+6.3f", -(double)ppenalty/1000, -(double)poffset/1000, -(double)ppenalty_ex/1000 ); else sprintf( modelname, "BLOSUM%d, %6.3f, %+6.3f, %+6.3f", nblosum, -(double)ppenalty/1000, -(double)poffset/1000, -(double)ppenalty_ex/1000 ); #if 0 for( i=0; i<26; i++ ) amino[i] = locaminod[i]; for( i=0; i<26; i++ ) amino_grp[(int)amino[i]] = locgrpd[i]; for( i=0; i<0x80; i++ ) amino_n[i] = 0; for( i=0; i<26; i++ ) amino_n[(int)amino[i]] = i; #endif for( i=0; i<0x80; i++ )amino_n[i] = -1; for( i=0; i<26; i++) amino_n[(int)amino[i]] = i; if( fmodel == 1 ) { calcfreq( nseq, seq, datafreq ); freq1 = datafreq; } else freq1 = freq; #if TEST fprintf( stderr, "raw scoreing matrix : \n" ); for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { fprintf( stdout, "%6.2f", n_distmp[i][j] ); } fprintf( stdout, "\n" ); } #endif if( fmodel == -1 ) average = 0.0; else { for( i=0; i<20; i++ ) #if TEST fprintf( stdout, "freq[%c] = %f, datafreq[%c] = %f, freq1[] = %f\n", amino[i], freq[i], amino[i], datafreq[i], freq1[i] ); #endif average = 0.0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) average += n_distmp[i][j] * freq1[i] * freq1[j]; } #if TEST fprintf( stdout, "####### average2 = %f\n", average ); #endif for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) n_distmp[i][j] -= average; #if TEST fprintf( stdout, "average2 = %f\n", average ); fprintf( stdout, "after average substruction : \n" ); for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { fprintf( stdout, "%6.2f", n_distmp[i][j] ); } fprintf( stdout, "\n" ); } #endif average = 0.0; for( i=0; i<20; i++ ) average += n_distmp[i][i] * freq1[i]; #if TEST fprintf( stdout, "####### average1 = %f\n", average ); #endif for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) n_distmp[i][j] *= 600.0 / average; #if TEST fprintf( stdout, "after average division : \n" ); for( i=0; i<20; i++ ) { for( j=0; j<=i; j++ ) { fprintf( stdout, "%7.1f", n_distmp[i][j] ); } fprintf( stdout, "\n" ); } #endif for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) n_distmp[i][j] -= offset; #if TEST fprintf( stdout, "after offset substruction (offset = %d): \n", offset ); for( i=0; i<20; i++ ) { for( j=0; j<=i; j++ ) { fprintf( stdout, "%7.1f", n_distmp[i][j] ); } fprintf( stdout, "\n" ); } #endif #if 0 /* 注意 !!!!!!!!!! */ penalty -= offset; #endif for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) n_distmp[i][j] = shishagonyuu( n_distmp[i][j] ); if( disp ) { fprintf( stdout, " scoring matrix \n" ); for( i=0; i<20; i++ ) { fprintf( stdout, "%c ", amino[i] ); for( j=0; j<20; j++ ) fprintf( stdout, "%5.0f", n_distmp[i][j] ); fprintf( stdout, "\n" ); } fprintf( stdout, " " ); for( i=0; i<20; i++ ) fprintf( stdout, " %c", amino[i] ); average = 0.0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) average += n_distmp[i][j] * freq1[i] * freq1[j]; fprintf( stdout, "average = %f\n", average ); average = 0.0; for( i=0; i<20; i++ ) average += n_distmp[i][i] * freq1[i]; fprintf( stdout, "itch average = %f\n", average ); fprintf( stderr, "parameters: %d, %d, %d\n", penalty, penalty_ex, offset ); exit( 1 ); } for( i=0; i<26; i++ ) for( j=0; j<26; j++ ) n_dis[i][j] = 0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) n_dis[i][j] = (int)n_distmp[i][j]; FreeDoubleMtx( n_distmp ); FreeDoubleVec( datafreq ); FreeDoubleVec( freq ); fprintf( stderr, "done.\n" ); } else if( dorp == 'p' && scoremtx == 2 ) /* Miyata-Yasunaga */ { fprintf( stderr, "Not supported\n" ); exit( 1 ); for( i=0; i<26; i++ ) for( j=0; j<26; j++ ) n_dis[i][j] = locn_dism[i][j]; for( i=0; i<26; i++ ) if( i != 24 ) n_dis[i][24] = n_dis[24][i] = exgpm; n_dis[24][24] = 0; if( ppenalty == NOTSPECIFIED ) ppenalty = locpenaltym; if( poffset == NOTSPECIFIED ) poffset = -20; if( pamN == NOTSPECIFIED ) pamN = 0; if( kimuraR == NOTSPECIFIED ) kimuraR = 1; penalty = ppenalty; offset = poffset; sprintf( modelname, "Miyata-Yasunaga, %6.3f, %6.3f", -(double)ppenalty/1000, -(double)poffset/1000 ); for( i=0; i<26; i++ ) amino[i] = locaminom[i]; for( i=0; i<26; i++ ) amino_grp[(int)amino[i]] = locgrpm[i]; #if DEBUG fprintf( stdout, "scoreing matrix : \n" ); for( i=0; i<26; i++ ) { for( j=0; j<26; j++ ) { fprintf( stdout, "%#5d", n_dis[i][j] ); } fprintf( stdout, "\n" ); } #endif } else /* JTT */ { double **rsr; double **pam1; double **pamx; double *freq; double *freq1; double *mutab; double *datafreq; double average; double tmp; double delta; rsr = AllocateDoubleMtx( 20, 20 ); pam1 = AllocateDoubleMtx( 20, 20 ); pamx = AllocateDoubleMtx( 20, 20 ); freq = AllocateDoubleVec( 20 ); mutab = AllocateDoubleVec( 20 ); datafreq = AllocateDoubleVec( 20 ); if( ppenalty == NOTSPECIFIED ) ppenalty = DEFAULTGOP_J; if( ppenalty_OP == NOTSPECIFIED ) ppenalty_OP = DEFAULTGOP_J; if( ppenalty_ex == NOTSPECIFIED ) ppenalty_ex = DEFAULTGEP_J; if( ppenalty_EX == NOTSPECIFIED ) ppenalty_EX = DEFAULTGEP_J; if( poffset == NOTSPECIFIED ) poffset = DEFAULTOFS_J; if( pamN == NOTSPECIFIED ) pamN = DEFAULTPAMN; if( kimuraR == NOTSPECIFIED ) kimuraR = 1; penalty = (int)( 600.0 / 1000.0 * ppenalty + 0.5 ); penalty_OP = (int)( 600.0 / 1000.0 * ppenalty_OP + 0.5 ); penalty_ex = (int)( 600.0 / 1000.0 * ppenalty_ex + 0.5 ); penalty_EX = (int)( 600.0 / 1000.0 * ppenalty_EX + 0.5 ); offset = (int)( 600.0 / 1000.0 * poffset + 0.5 ); offsetFFT = (int)( 600.0 / 1000.0 * (-0) + 0.5 ); offsetLN = (int)( 600.0 / 1000.0 * 100 + 0.5); penaltyLN = (int)( 600.0 / 1000.0 * -2000 + 0.5); penalty_exLN = (int)( 600.0 / 1000.0 * -100 + 0.5); sprintf( modelname, "%s %dPAM, %6.3f, %6.3f", (TMorJTT==TM)?"Transmembrane":"JTT", pamN, -(double)ppenalty/1000, -(double)poffset/1000 ); JTTmtx( rsr, freq, amino, amino_grp, (int)(TMorJTT==TM) ); #if TEST fprintf( stdout, "rsr = \n" ); for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { fprintf( stdout, "%9.2f ", rsr[i][j] ); } fprintf( stdout, "\n" ); } #endif for( i=0; i<0x80; i++ ) amino_n[i] = -1; for( i=0; i<26; i++ ) amino_n[(int)amino[i]] = i; if( fmodel == 1 ) { calcfreq( nseq, seq, datafreq ); freq1 = datafreq; } else freq1 = freq; fprintf( stderr, "generating %dPAM %s scoring matrix for amino acids ... ", pamN, (TMorJTT==TM)?"Transmembrane":"JTT" ); tmp = 0.0; for( i=0; i<20; i++ ) { mutab[i] = 0.0; for( j=0; j<20; j++ ) mutab[i] += rsr[i][j] * freq[j]; tmp += mutab[i] * freq[i]; } #if TEST fprintf( stdout, "mutability = \n" ); for( i=0; i<20; i++ ) fprintf( stdout, "%5.3f\n", mutab[i] ); fprintf( stdout, "tmp = %f\n", tmp ); #endif delta = 0.01 / tmp; for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { if( i != j ) pam1[i][j] = delta * rsr[i][j] * freq[i]; else pam1[i][j] = 1.0 - delta * mutab[i]; } } if( disp ) { fprintf( stdout, "pam1 = \n" ); for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { fprintf( stdout, "%9.6f ", pam1[i][j] ); } fprintf( stdout, "\n" ); } } MtxuntDouble( pamx, 20 ); for( x=0; x < pamN; x++ ) MtxmltDouble( pamx, pam1, 20 ); for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) pamx[i][j] /= freq[j]; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) { if( pamx[i][j] == 0.0 ) { fprintf( stderr, "WARNING: pamx[%d][%d] = 0.0?\n", i, j ); pamx[i][j] = 0.00001; /* by J. Thompson */ } pamx[i][j] = log10( pamx[i][j] ) * 1000.0; } #if TEST fprintf( stdout, "raw scoring matrix : \n" ); for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { fprintf( stdout, "%5.0f", pamx[i][j] ); } fprintf( stdout, "\n" ); } average = tmp = 0.0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) { average += pamx[i][j] * freq1[i] * freq1[j]; tmp += freq1[i] * freq1[j]; } average /= tmp; fprintf( stdout, "Zenbu average = %f, tmp = %f \n", average, tmp ); average = tmp = 0.0; for( i=0; i<20; i++ ) for( j=i; j<20; j++ ) { average += pamx[i][j] * freq1[i] * freq1[j]; tmp += freq1[i] * freq1[j]; } average /= tmp; fprintf( stdout, "Zenbu average2 = %f, tmp = %f \n", average, tmp ); average = tmp = 0.0; for( i=0; i<20; i++ ) { average += pamx[i][i] * freq1[i]; tmp += freq1[i]; } average /= tmp; fprintf( stdout, "Itch average = %f, tmp = %f \n", average, tmp ); #endif #if NORMALIZE1 if( fmodel == -1 ) average = 0.0; else { #if TEST for( i=0; i<20; i++ ) fprintf( stdout, "freq[%c] = %f, datafreq[%c] = %f, freq1[] = %f\n", amino[i], freq[i], amino[i], datafreq[i], freq1[i] ); #endif average = 0.0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) average += pamx[i][j] * freq1[i] * freq1[j]; } #if TEST fprintf( stdout, "####### average2 = %f\n", average ); #endif for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) pamx[i][j] -= average; #if TEST fprintf( stdout, "average2 = %f\n", average ); fprintf( stdout, "after average substruction : \n" ); for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { fprintf( stdout, "%5.0f", pamx[i][j] ); } fprintf( stdout, "\n" ); } #endif average = 0.0; for( i=0; i<20; i++ ) average += pamx[i][i] * freq1[i]; #if TEST fprintf( stdout, "####### average1 = %f\n", average ); #endif for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) pamx[i][j] *= 600.0 / average; #if TEST fprintf( stdout, "after average division : \n" ); for( i=0; i<20; i++ ) { for( j=0; j<=i; j++ ) { fprintf( stdout, "%5.0f", pamx[i][j] ); } fprintf( stdout, "\n" ); } #endif for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) pamx[i][j] -= offset; #if TEST fprintf( stdout, "after offset substruction (offset = %d): \n", offset ); for( i=0; i<20; i++ ) { for( j=0; j<=i; j++ ) { fprintf( stdout, "%5.0f", pamx[i][j] ); } fprintf( stdout, "\n" ); } #endif #if 0 /* 注意 !!!!!!!!!! */ penalty -= offset; #endif for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) pamx[i][j] = shishagonyuu( pamx[i][j] ); #else average = 0.0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) average += pamx[i][j]; average /= 400.0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) { pamx[i][j] -= average; pamx[i][j] = shishagonyuu( pamx[i][j] ); } #endif if( disp ) { fprintf( stdout, " scoring matrix \n" ); for( i=0; i<20; i++ ) { fprintf( stdout, "%c ", amino[i] ); for( j=0; j<20; j++ ) fprintf( stdout, "%5.0f", pamx[i][j] ); fprintf( stdout, "\n" ); } fprintf( stdout, " " ); for( i=0; i<20; i++ ) fprintf( stdout, " %c", amino[i] ); average = 0.0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) average += pamx[i][j] * freq1[i] * freq1[j]; fprintf( stdout, "average = %f\n", average ); average = 0.0; for( i=0; i<20; i++ ) average += pamx[i][i] * freq1[i]; fprintf( stdout, "itch average = %f\n", average ); fprintf( stderr, "parameters: %d, %d, %d\n", penalty, penalty_ex, offset ); exit( 1 ); } for( i=0; i<26; i++ ) for( j=0; j<26; j++ ) n_dis[i][j] = 0; for( i=0; i<20; i++ ) for( j=0; j<20; j++ ) n_dis[i][j] = (int)pamx[i][j]; fprintf( stderr, "done.\n" ); FreeDoubleMtx( rsr ); FreeDoubleMtx( pam1 ); FreeDoubleMtx( pamx ); FreeDoubleVec( freq ); FreeDoubleVec( mutab ); FreeDoubleVec( datafreq ); } fprintf( stderr, "scoremtx = %d\n", scoremtx ); #if DEBUG fprintf( stderr, "scoremtx = %d\n", scoremtx ); fprintf( stderr, "amino[] = %s\n", amino ); #endif for( i=0; i<0x80; i++ )amino_n[i] = -1; for( i=0; i<26; i++) amino_n[(int)amino[i]] = i; for( i=0; i<0x80; i++ ) for( j=0; j<0x80; j++ ) amino_dis[i][j] = 0; for( i=0; i<0x80; i++ ) for( j=0; j<0x80; j++ ) amino_disLN[i][j] = 0; for( i=0; i<0x80; i++ ) for( j=0; j<0x80; j++ ) amino_dis_consweight_multi[i][j] = 0.0; for( i=0; i<26; i++) for( j=0; j<26; j++ ) { amino_dis[(int)amino[i]][(int)amino[j]] = n_dis[i][j]; n_dis_consweight_multi[i][j] = (float)n_dis[i][j] * consweight_multi; amino_dis_consweight_multi[(int)amino[i]][(int)amino[j]] = (double)n_dis[i][j] * consweight_multi; } if( dorp == 'd' ) /* DNA */ { for( i=0; i<5; i++) for( j=0; j<5; j++ ) amino_disLN[(int)amino[i]][(int)amino[j]] = n_dis[i][j] + offset - offsetLN; for( i=5; i<10; i++) for( j=5; j<10; j++ ) amino_disLN[(int)amino[i]][(int)amino[j]] = n_dis[i][j] + offset - offsetLN; for( i=0; i<5; i++) for( j=0; j<5; j++ ) n_disFFT[i][j] = n_dis[i][j] + offset - offsetFFT; for( i=5; i<10; i++) for( j=5; j<10; j++ ) n_disFFT[i][j] = n_dis[i][j] + offset - offsetFFT; } else // protein { for( i=0; i<20; i++) for( j=0; j<20; j++ ) amino_disLN[(int)amino[i]][(int)amino[j]] = n_dis[i][j] + offset - offsetLN; for( i=0; i<20; i++) for( j=0; j<20; j++ ) n_disFFT[i][j] = n_dis[i][j] + offset - offsetFFT; } #if 0 fprintf( stderr, "amino_dis (offset = %d): \n", offset ); for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { fprintf( stderr, "%5d", amino_dis[(int)amino[i]][(int)amino[j]] ); } fprintf( stderr, "\n" ); } fprintf( stderr, "amino_disLN (offsetLN = %d): \n", offsetLN ); for( i=0; i<20; i++ ) { for( j=0; j<20; j++ ) { fprintf( stderr, "%5d", amino_disLN[(int)amino[i]][(int)amino[j]] ); } fprintf( stderr, "\n" ); } fprintf( stderr, "n_dis (offset = %d): \n", offset ); for( i=0; i<26; i++ ) { for( j=0; j<26; j++ ) { fprintf( stderr, "%5d", n_dis[i][j] ); } fprintf( stderr, "\n" ); } fprintf( stderr, "n_disFFT (offsetFFT = %d): \n", offsetFFT ); for( i=0; i<26; i++ ) { for( j=0; j<26; j++ ) { fprintf( stderr, "%5d", n_disFFT[i][j] ); } fprintf( stderr, "\n" ); } exit( 1 ); #endif ppid = 0; if( fftThreshold == NOTSPECIFIED ) { fftThreshold = FFT_THRESHOLD; } if( fftWinSize == NOTSPECIFIED ) { if( dorp == 'd' ) fftWinSize = FFT_WINSIZE_D; else fftWinSize = FFT_WINSIZE_P; } if( fftscore ) { double av, sd; for( i=0; i<20; i++ ) polarity[i] = polarity_[i]; for( av=0.0, i=0; i<20; i++ ) av += polarity[i]; av /= 20.0; for( sd=0.0, i=0; i<20; i++ ) sd += ( polarity[i]-av ) * ( polarity[i]-av ); sd /= 20.0; sd = sqrt( sd ); for( i=0; i<20; i++ ) polarity[i] -= av; for( i=0; i<20; i++ ) polarity[i] /= sd; for( i=0; i<20; i++ ) volume[i] = volume_[i]; for( av=0.0, i=0; i<20; i++ ) av += volume[i]; av /= 20.0; for( sd=0.0, i=0; i<20; i++ ) sd += ( volume[i]-av ) * ( volume[i]-av ); sd /= 20.0; sd = sqrt( sd ); for( i=0; i<20; i++ ) volume[i] -= av; for( i=0; i<20; i++ ) volume[i] /= sd; #if 0 for( i=0; i<20; i++ ) fprintf( stdout, "amino=%c, pol = %f<-%f, vol = %f<-%f\n", amino[i], polarity[i], polarity_[i], volume[i], volume_[i] ); for( i=0; i<20; i++ ) fprintf( stdout, "%c %+5.3f %+5.3f\n", amino[i], volume[i], polarity[i] ); #endif } }