void mymergesort(Item a[],int l,int r){
int m = (l+r)/2;
if(r<=l) return;
mymergesort(a,l,m);
/* mymergesort(a,m+1,r); */
merge(a,l,m,r);
}
void mymergesort(int *numbers, int low, int high)
{
//If only 1 element exit process
if (high-low < 1){
if (shmdt(numbers) == -1) perror("shmdt error");
exit(0);
}
pid_t left, right;
int middle = (low+high)/2;
//Create child process for left half
if ((left = fork()) < 0){
perror("fork error");
} else if (left == 0) {
mymergesort(numbers, low, middle);
if (shmdt(numbers) == -1) perror("shmdt error");
exit(0);
} else {
//Create child process for right half
if ((right = fork()) < 0){
perror("fork error");
} else if (right == 0) {
mymergesort(numbers, middle+1, high);
if (shmdt(numbers) == -1) perror("shmdt error");
exit(0);
}
//Wait for children to finish
if (waitpid(right, NULL, 0) != right){
perror("waitpid error");
}
if (waitpid(left, NULL, 0) != left){
perror("waitpid error");
}
}
//Merge halves
combine(numbers, low, middle, high);
}
static void mymergesort( int first, int last, Segment **seg )
{
int middle;
static TLS int i, j, k, p;
static TLS int allo = 0;
static TLS Segment **work = NULL;
if( seg == NULL )
{
free( work ); work = NULL;
return;
}
if( last > allo )
{
allo = last;
if( work ) free( work );
work = (Segment **)calloc( allo / 2 + 1, sizeof( Segment *) );
}
if( first < last )
{
middle = ( first + last ) / 2;
mymergesort( first, middle, seg );
mymergesort( middle+1, last, seg );
p = 0;
for( i=first; i<=middle; i++ ) work[p++] = seg[i];
i = middle + 1; j = 0; k = first;
while( i <= last && j < p )
{
if( work[j]->center <= seg[i]->center )
seg[k++] = work[j++];
else
seg[k++] = seg[i++];
}
while( j < p ) seg[k++] = work[j++];
}
}
void fillcell(celW **W, int i1, int j1, int r, double *rs, double tol) {
/*
fillcell makes the new recursive polynomial W[i1][j1] from
W[i1 - 1][j1 - 1] and W[i1][j1 - 1]. j1 is the total number of
rank scores assigned so far to either of the two groups,
i1 is the number of rank scores assigned to the smallest sample.
*/
long tijd;
celW temp2;
int j, j2;
temp2.c = Calloc(W[i1 - 1][j1 - 1].length +
W[i1][j1 - 1].length, double);
temp2.x = Calloc(W[i1 - 1][j1 - 1].length +
W[i1][j1 - 1].length, double);
temp2.length = W[i1 - 1][j1 - 1].length;
for (j = 0; j < temp2.length; j++) {
temp2.c[j] = W[i1 - 1][j1 - 1].c[j];
temp2.x[j] = W[i1 - 1][j1 - 1].x[j];
}
if (i1 == j1) {
mult(&temp2, r, rs);
} else {
mult(&temp2, r, rs);
tijd = temp2.length;
plus(W, &temp2, i1, j1, tol);
mymergesort(temp2, tijd);
}
W[i1][j1].length = temp2.length;
for (j2 = 0; j2 < temp2.length; j2++) {
W[i1][j1].c[j2] = temp2.c[j2];
W[i1][j1].x[j2] = temp2.x[j2];
}
Free(temp2.c);
Free(temp2.x);
}
int main(int argc, char *argv[])
{
printf("\n");
int i; //For loops
if (argc != 2){
printf ("Usage: %s filename\n", argv[0]);
exit(1);
}
FILE *file;
int *number;
int num;
int count = 0;
int *shmptr;
int shmid;
// Create array to hold input numbers
size_t size = (size_t)(10*sizeof(signed int));
number = (int*)malloc(size);
//Read file
file = fopen(argv[1], "r");
if (!file) {
perror("Error opening file\n");
free(number);
exit(2);
}
if (fscanf (file, "%d ", &num) == EOF) {
perror("Error reading file");
free(number);
exit(3);
}
number[0] = num;
while (!feof(file)){
if (fscanf (file, "%d ", &num) == EOF){
perror("Error reading file");
free(number);
exit(4);
}
count++;
if (count%10 == 0){
size+=(size_t)(10*sizeof(signed int));
number = (int*)realloc(number,size);
if(number == NULL){
perror("Out of Memory\n");
free(number);
exit(5);
}
}
number[count] = num;
}
fclose(file);
printf("Sorting file: %s\n%d elements read\n\n", argv[1], ++count);
//Create shared memory
if ((shmid = shmget(IPC_PRIVATE, (size_t)count*sizeof(signed int), IPC_CREAT|0666)) < 0){
perror("shmget error");
}
if ((shmptr = shmat(shmid, NULL, 0)) == (void *)-1){
perror("shmat error");
}
if (shmctl(shmid, IPC_RMID, 0) < 0) perror("shmctl error");
//Copy input to shared memory
memcpy((void *)shmptr, (void *)number, (size_t)count*sizeof(signed int));
printf("Input Numbers: \n");
for (i = 0; i < count; i++){
printf("%d ", shmptr[i]);
}
printf("\n\n");
//Run mergesort
mymergesort(shmptr, 0, count-1);
printf("Sorted Numbers: \n");
for (i = 0; i < count; i++){
printf("%d ", shmptr[i]);
}
printf("\n\n");
//Clean up memory
free(number);
if (shmdt(shmptr) == -1) perror("shmdt error");
shmptr = NULL;
return 0;
}
float Falign_localhom( char **seq1, char **seq2,
double *eff1, double *eff2,
int clus1, int clus2,
int alloclen,
LocalHom ***localhom, float *totalimpmatch,
int *gapmap1, int *gapmap2,
int *chudanpt, int chudanref, int *chudanres )
{
// tditeration.c deha alloclen ha huhen nanode
// prevalloclen ha iranai.
int i, j, k, l, m, maxk;
int nlen, nlen2, nlen4;
static TLS int crossscoresize = 0;
static TLS char **tmpseq1 = NULL;
static TLS char **tmpseq2 = NULL;
static TLS char **tmpptr1 = NULL;
static TLS char **tmpptr2 = NULL;
static TLS char **tmpres1 = NULL;
static TLS char **tmpres2 = NULL;
static TLS char **result1 = NULL;
static TLS char **result2 = NULL;
#if RND
static TLS char **rndseq1 = NULL;
static TLS char **rndseq2 = NULL;
#endif
static TLS Fukusosuu **seqVector1 = NULL;
static TLS Fukusosuu **seqVector2 = NULL;
static TLS Fukusosuu **naiseki = NULL;
static TLS Fukusosuu *naisekiNoWa = NULL;
static TLS double *soukan = NULL;
static TLS double **crossscore = NULL;
int nlentmp;
static TLS int *kouho = NULL;
static TLS Segment *segment = NULL;
static TLS Segment *segment1 = NULL;
static TLS Segment *segment2 = NULL;
static TLS Segment **sortedseg1 = NULL;
static TLS Segment **sortedseg2 = NULL;
static TLS int *cut1 = NULL;
static TLS int *cut2 = NULL;
static TLS char *sgap1, *egap1, *sgap2, *egap2;
static TLS int localalloclen = 0;
int lag;
int tmpint;
int count, count0;
int len1, len2;
int totallen;
float totalscore;
float impmatch;
extern Fukusosuu *AllocateFukusosuuVec();
extern Fukusosuu **AllocateFukusosuuMtx();
if( seq1 == NULL )
{
if( result1 )
{
// fprintf( stderr, "Freeing localarrays in Falign\n" );
localalloclen = 0;
mymergesort( 0, 0, NULL );
alignableReagion( 0, 0, NULL, NULL, NULL, NULL, NULL );
fft( 0, NULL, 1 );
A__align( NULL, NULL, NULL, NULL, 0, 0, 0, NULL, NULL, NULL, NULL, NULL, NULL, NULL, 0, NULL, 0, 0 );
G__align11( NULL, NULL, 0, 0, 0 );
partA__align( NULL, NULL, NULL, NULL, 0, 0, 0, NULL, NULL, 0, 0, 0, 0, NULL, NULL, NULL, NULL, NULL, NULL, NULL, 0, NULL );
blockAlign2( NULL, NULL, NULL, NULL, NULL, NULL );
if( crossscore ) FreeDoubleMtx( crossscore );
FreeCharMtx( result1 );
FreeCharMtx( result2 );
FreeCharMtx( tmpres1 );
FreeCharMtx( tmpres2 );
FreeCharMtx( tmpseq1 );
FreeCharMtx( tmpseq2 );
free( sgap1 );
free( egap1 );
free( sgap2 );
free( egap2 );
free( kouho );
free( cut1 );
free( cut2 );
free( tmpptr1 );
free( tmpptr2 );
free( segment );
free( segment1 );
free( segment2 );
free( sortedseg1 );
free( sortedseg2 );
if( !kobetsubunkatsu )
{
FreeFukusosuuMtx ( seqVector1 );
FreeFukusosuuMtx ( seqVector2 );
FreeFukusosuuVec( naisekiNoWa );
FreeFukusosuuMtx( naiseki );
FreeDoubleVec( soukan );
}
}
else
{
// fprintf( stderr, "Did not allocate localarrays in Falign\n" );
}
return( 0.0 );
}
len1 = strlen( seq1[0] );
len2 = strlen( seq2[0] );
nlentmp = MAX( len1, len2 );
nlen = 1;
while( nlentmp >= nlen ) nlen <<= 1;
#if 0
fprintf( stderr, "### nlen = %d\n", nlen );
#endif
nlen2 = nlen/2; nlen4 = nlen2 / 2;
#if DEBUG
fprintf( stderr, "len1 = %d, len2 = %d\n", len1, len2 );
fprintf( stderr, "nlentmp = %d, nlen = %d\n", nlentmp, nlen );
#endif
if( !localalloclen )
{
sgap1 = AllocateCharVec( njob );
egap1 = AllocateCharVec( njob );
sgap2 = AllocateCharVec( njob );
egap2 = AllocateCharVec( njob );
kouho = AllocateIntVec( NKOUHO );
cut1 = AllocateIntVec( MAXSEG );
cut2 = AllocateIntVec( MAXSEG );
tmpptr1 = AllocateCharMtx( njob, 0 );
tmpptr2 = AllocateCharMtx( njob, 0 );
result1 = AllocateCharMtx( njob, alloclen );
result2 = AllocateCharMtx( njob, alloclen );
tmpres1 = AllocateCharMtx( njob, alloclen );
tmpres2 = AllocateCharMtx( njob, alloclen );
// crossscore = AllocateDoubleMtx( MAXSEG, MAXSEG );
segment = (Segment *)calloc( MAXSEG, sizeof( Segment ) );
segment1 = (Segment *)calloc( MAXSEG, sizeof( Segment ) );
segment2 = (Segment *)calloc( MAXSEG, sizeof( Segment ) );
sortedseg1 = (Segment **)calloc( MAXSEG, sizeof( Segment * ) );
sortedseg2 = (Segment **)calloc( MAXSEG, sizeof( Segment * ) );
if( !( segment && segment1 && segment2 && sortedseg1 && sortedseg2 ) )
ErrorExit( "Allocation error\n" );
if ( scoremtx == -1 ) n20or4or2 = 4;
else if( fftscore == 1 ) n20or4or2 = 2;
else n20or4or2 = 20;
}
if( localalloclen < nlen )
{
if( localalloclen )
{
#if 1
if( !kobetsubunkatsu )
{
FreeFukusosuuMtx ( seqVector1 );
FreeFukusosuuMtx ( seqVector2 );
FreeFukusosuuVec( naisekiNoWa );
FreeFukusosuuMtx( naiseki );
FreeDoubleVec( soukan );
}
FreeCharMtx( tmpseq1 );
FreeCharMtx( tmpseq2 );
#endif
#if RND
FreeCharMtx( rndseq1 );
FreeCharMtx( rndseq2 );
#endif
}
tmpseq1 = AllocateCharMtx( njob, nlen );
tmpseq2 = AllocateCharMtx( njob, nlen );
if( !kobetsubunkatsu )
{
naisekiNoWa = AllocateFukusosuuVec( nlen );
naiseki = AllocateFukusosuuMtx( n20or4or2, nlen );
seqVector1 = AllocateFukusosuuMtx( n20or4or2+1, nlen+1 );
seqVector2 = AllocateFukusosuuMtx( n20or4or2+1, nlen+1 );
soukan = AllocateDoubleVec( nlen+1 );
}
#if RND
rndseq1 = AllocateCharMtx( njob, nlen );
rndseq2 = AllocateCharMtx( njob, nlen );
for( i=0; i<njob; i++ )
{
generateRndSeq( rndseq1[i], nlen );
generateRndSeq( rndseq2[i], nlen );
}
#endif
localalloclen = nlen;
}
for( j=0; j<clus1; j++ ) strcpy( tmpseq1[j], seq1[j] );
for( j=0; j<clus2; j++ ) strcpy( tmpseq2[j], seq2[j] );
#if 0
fftfp = fopen( "input_of_Falign", "w" );
fprintf( fftfp, "nlen = %d\n", nlen );
fprintf( fftfp, "seq1: ( %d sequences ) \n", clus1 );
for( i=0; i<clus1; i++ )
fprintf( fftfp, "%s\n", seq1[i] );
fprintf( fftfp, "seq2: ( %d sequences ) \n", clus2 );
for( i=0; i<clus2; i++ )
fprintf( fftfp, "%s\n", seq2[i] );
fclose( fftfp );
system( "less input_of_Falign < /dev/tty > /dev/tty" );
#endif
if( !kobetsubunkatsu )
{
fprintf( stderr, "FFT ... " );
for( j=0; j<n20or4or2; j++ ) vec_init( seqVector1[j], nlen );
if( fftscore && scoremtx != -1 )
{
for( i=0; i<clus1; i++ )
{
seq_vec_2( seqVector1[0], polarity, eff1[i], tmpseq1[i] );
seq_vec_2( seqVector1[1], volume, eff1[i], tmpseq1[i] );
}
}
else
{
#if 0
for( i=0; i<clus1; i++ ) for( j=0; j<n20or4or2; j++ )
seq_vec( seqVector1[j], amino[j], eff1[i], tmpseq1[i] );
#else
for( i=0; i<clus1; i++ )
seq_vec_3( seqVector1, eff1[i], tmpseq1[i] );
#endif
}
#if RND
for( i=0; i<clus1; i++ )
{
vec_init2( seqVector1, rndseq1[i], eff1[i], len1, nlen );
}
#endif
#if 0
fftfp = fopen( "seqVec", "w" );
fprintf( fftfp, "before transform\n" );
for( k=0; k<n20or4or2; k++ )
{
fprintf( fftfp, "nlen=%d\n", nlen );
fprintf( fftfp, "%c\n", amino[k] );
for( l=0; l<nlen; l++ )
fprintf( fftfp, "%f %f\n", seqVector1[k][l].R, seqVector1[k][l].I );
}
fclose( fftfp );
system( "less seqVec < /dev/tty > /dev/tty" );
#endif
for( j=0; j<n20or4or2; j++ ) vec_init( seqVector2[j], nlen );
if( fftscore && scoremtx != -1 )
{
for( i=0; i<clus2; i++ )
{
seq_vec_2( seqVector2[0], polarity, eff2[i], tmpseq2[i] );
seq_vec_2( seqVector2[1], volume, eff2[i], tmpseq2[i] );
}
}
else
{
#if 0
for( i=0; i<clus2; i++ ) for( j=0; j<n20or4or2; j++ )
seq_vec( seqVector2[j], amino[j], eff2[i], tmpseq2[i] );
#else
for( i=0; i<clus2; i++ )
seq_vec_3( seqVector2, eff2[i], tmpseq2[i] );
#endif
}
#if RND
for( i=0; i<clus2; i++ )
{
vec_init2( seqVector2, rndseq2[i], eff2[i], len2, nlen );
}
#endif
#if 0
fftfp = fopen( "seqVec2", "w" );
fprintf( fftfp, "before fft\n" );
for( k=0; k<n20or4or2; k++ )
{
fprintf( fftfp, "%c\n", amino[k] );
for( l=0; l<nlen; l++ )
fprintf( fftfp, "%f %f\n", seqVector2[k][l].R, seqVector2[k][l].I );
}
fclose( fftfp );
system( "less seqVec2 < /dev/tty > /dev/tty" );
#endif
for( j=0; j<n20or4or2; j++ )
{
fft( nlen, seqVector2[j], (j==0) );
fft( nlen, seqVector1[j], 0 );
}
#if 0
fftfp = fopen( "seqVec2", "w" );
fprintf( fftfp, "#after fft\n" );
for( k=0; k<n20or4or2; k++ )
{
fprintf( fftfp, "#%c\n", amino[k] );
for( l=0; l<nlen; l++ )
fprintf( fftfp, "%f %f\n", seqVector2[k][l].R, seqVector2[k][l].I );
}
fclose( fftfp );
system( "less seqVec2 < /dev/tty > /dev/tty" );
#endif
for( k=0; k<n20or4or2; k++ )
{
for( l=0; l<nlen; l++ )
calcNaiseki( naiseki[k]+l, seqVector1[k]+l, seqVector2[k]+l );
}
for( l=0; l<nlen; l++ )
{
naisekiNoWa[l].R = 0.0;
naisekiNoWa[l].I = 0.0;
for( k=0; k<n20or4or2; k++ )
{
naisekiNoWa[l].R += naiseki[k][l].R;
naisekiNoWa[l].I += naiseki[k][l].I;
}
}
#if 0
fftfp = fopen( "naisekiNoWa", "w" );
fprintf( fftfp, "#Before fft\n" );
for( l=0; l<nlen; l++ )
fprintf( fftfp, "%d %f %f\n", l, naisekiNoWa[l].R, naisekiNoWa[l].I );
fclose( fftfp );
system( "less naisekiNoWa < /dev/tty > /dev/tty " );
#endif
fft( -nlen, naisekiNoWa, 0 );
for( m=0; m<=nlen2; m++ )
soukan[m] = naisekiNoWa[nlen2-m].R;
for( m=nlen2+1; m<nlen; m++ )
soukan[m] = naisekiNoWa[nlen+nlen2-m].R;
#if 0
fftfp = fopen( "naisekiNoWa", "w" );
fprintf( fftfp, "#After fft\n" );
for( l=0; l<nlen; l++ )
fprintf( fftfp, "%d %f\n", l, naisekiNoWa[l].R );
fclose( fftfp );
fftfp = fopen( "list.plot", "w" );
fprintf( fftfp, "plot 'naisekiNoWa'\npause -1" );
fclose( fftfp );
system( "/usr/bin/gnuplot list.plot &" );
#endif
#if 0
fprintf( stderr, "frt write start\n" );
fftfp = fopen( "frt", "w" );
for( l=0; l<nlen; l++ )
fprintf( fftfp, "%d %f\n", l-nlen2, soukan[l] );
fclose( fftfp );
system( "less frt < /dev/tty > /dev/tty" );
#if 0
fftfp = fopen( "list.plot", "w" );
fprintf( fftfp, "plot 'frt'\n pause +1" );
fclose( fftfp );
system( "/usr/bin/gnuplot list.plot" );
#endif
#endif
getKouho( kouho, NKOUHO, soukan, nlen );
#if 0
for( i=0; i<NKOUHO; i++ )
{
fprintf( stderr, "kouho[%d] = %d\n", i, kouho[i] );
}
#endif
}
#if KEIKA
fprintf( stderr, "Searching anchors ... " );
#endif
count = 0;
#define CAND 0
#if CAND
fftfp = fopen( "cand", "w" );
fclose( fftfp );
#endif
if( kobetsubunkatsu )
{
maxk = 1;
kouho[0] = 0;
}
else
{
maxk = NKOUHO;
}
for( k=0; k<maxk; k++ )
{
lag = kouho[k];
zurasu2( lag, clus1, clus2, seq1, seq2, tmpptr1, tmpptr2 );
#if CAND
fftfp = fopen( "cand", "a" );
fprintf( fftfp, "Candidate No.%d lag = %d\n", k+1, lag );
fprintf( fftfp, "%s\n", tmpptr1[0] );
fprintf( fftfp, "%s\n", tmpptr2[0] );
fclose( fftfp );
#endif
tmpint = alignableReagion( clus1, clus2, tmpptr1, tmpptr2, eff1, eff2, segment+count );
if( count+tmpint > MAXSEG -3 ) ErrorExit( "TOO MANY SEGMENTS.\n" );
while( tmpint-- > 0 )
{
if( lag > 0 )
{
segment1[count].start = segment[count].start ;
segment1[count].end = segment[count].end ;
segment1[count].center = segment[count].center;
segment1[count].score = segment[count].score;
segment2[count].start = segment[count].start + lag;
segment2[count].end = segment[count].end + lag;
segment2[count].center = segment[count].center + lag;
segment2[count].score = segment[count].score ;
}
else
{
segment1[count].start = segment[count].start - lag;
segment1[count].end = segment[count].end - lag;
segment1[count].center = segment[count].center - lag;
segment1[count].score = segment[count].score ;
segment2[count].start = segment[count].start ;
segment2[count].end = segment[count].end ;
segment2[count].center = segment[count].center;
segment2[count].score = segment[count].score ;
}
#if 0
fftfp = fopen( "cand", "a" );
fprintf( fftfp, "Goukaku=%dko\n", tmpint );
fprintf( fftfp, "in 1 %d\n", segment1[count].center );
fprintf( fftfp, "in 2 %d\n", segment2[count].center );
fclose( fftfp );
#endif
segment1[count].pair = &segment2[count];
segment2[count].pair = &segment1[count];
count++;
#if 0
fprintf( stderr, "count=%d\n", count );
#endif
}
}
#if 1
if( !kobetsubunkatsu )
fprintf( stderr, "%d segments found\n", count );
#endif
if( !count && fftNoAnchStop )
ErrorExit( "Cannot detect anchor!" );
#if 0
fftfp = fopen( "fft", "a" );
fprintf( fftfp, "RESULT before sort:\n" );
for( l=0; l<count; l++ )
{
fprintf( fftfp, "cut[%d]=%d, ", l, segment1[l].center );
fprintf( fftfp, "%d score = %f\n", segment2[l].center, segment1[l].score );
}
fclose( fftfp );
#endif
#if KEIKA
fprintf( stderr, "Aligning anchors ... " );
#endif
for( i=0; i<count; i++ )
{
sortedseg1[i] = &segment1[i];
sortedseg2[i] = &segment2[i];
}
#if 0
tmpsort( count, sortedseg1 );
tmpsort( count, sortedseg2 );
qsort( sortedseg1, count, sizeof( Segment * ), segcmp );
qsort( sortedseg2, count, sizeof( Segment * ), segcmp );
#else
mymergesort( 0, count-1, sortedseg1 );
mymergesort( 0, count-1, sortedseg2 );
#endif
for( i=0; i<count; i++ ) sortedseg1[i]->number = i;
for( i=0; i<count; i++ ) sortedseg2[i]->number = i;
if( kobetsubunkatsu )
{
for( i=0; i<count; i++ )
{
cut1[i+1] = sortedseg1[i]->center;
cut2[i+1] = sortedseg2[i]->center;
}
cut1[0] = 0;
cut2[0] = 0;
cut1[count+1] = len1;
cut2[count+1] = len2;
count += 2;
}
else
{
if( crossscoresize < count+2 )
{
crossscoresize = count+2;
#if 1
fprintf( stderr, "######allocating crossscore, size = %d\n", crossscoresize );
#endif
if( crossscore ) FreeDoubleMtx( crossscore );
crossscore = AllocateDoubleMtx( crossscoresize, crossscoresize );
}
for( i=0; i<count+2; i++ ) for( j=0; j<count+2; j++ )
crossscore[i][j] = 0.0;
for( i=0; i<count; i++ )
{
crossscore[segment1[i].number+1][segment1[i].pair->number+1] = segment1[i].score;
cut1[i+1] = sortedseg1[i]->center;
cut2[i+1] = sortedseg2[i]->center;
}
#if DEBUG
fprintf( stderr, "AFTER SORT\n" );
for( i=0; i<count; i++ ) fprintf( stderr, "%d, %d\n", segment1[i].start, segment2[i].start );
#endif
crossscore[0][0] = 10000000.0;
cut1[0] = 0;
cut2[0] = 0;
crossscore[count+1][count+1] = 10000000.0;
cut1[count+1] = len1;
cut2[count+1] = len2;
count += 2;
count0 = count;
blockAlign2( cut1, cut2, sortedseg1, sortedseg2, crossscore, &count );
if( count0 > count )
{
#if 0
fprintf( stderr, "\7 REPEAT!? \n" );
#else
fprintf( stderr, "REPEAT!? \n" );
#endif
if( fftRepeatStop ) exit( 1 );
}
#if KEIKA
else fprintf( stderr, "done\n" );
#endif
}
#if 0
fftfp = fopen( "fft", "a" );
fprintf( fftfp, "RESULT after sort:\n" );
for( l=0; l<count; l++ )
{
fprintf( fftfp, "cut[%d]=%d, ", l, segment1[l].center );
fprintf( fftfp, "%d\n", segment2[l].center );
}
fclose( fftfp );
#endif
#if 0
fftfp = fopen( "fft", "a" );
fprintf( fftfp, "RESULT after sort:\n" );
for( l=0; l<count; l++ )
{
fprintf( fftfp, "cut : %d %d\n", cut1[l], cut2[l] );
}
fclose( fftfp );
#endif
#if KEIKA
fprintf( trap_g, "Devided to %d segments\n", count-1 );
fprintf( trap_g, "%d %d forg\n", MIN( clus1, clus2 ), count-1 );
#endif
totallen = 0;
for( j=0; j<clus1; j++ ) result1[j][0] = 0;
for( j=0; j<clus2; j++ ) result2[j][0] = 0;
totalscore = 0.0;
*totalimpmatch = 0.0;
for( i=0; i<count-1; i++ )
{
#if DEBUG
fprintf( stderr, "DP %03d / %03d %4d to ", i+1, count-1, totallen );
#else
#if KEIKA
fprintf( stderr, "DP %03d / %03d\r", i+1, count-1 );
#endif
#endif
if( cut1[i] )
{
getkyokaigap( sgap1, seq1, cut1[i]-1, clus1 );
getkyokaigap( sgap2, seq2, cut2[i]-1, clus2 );
}
else
{
for( j=0; j<clus1; j++ ) sgap1[j] = 'o';
for( j=0; j<clus2; j++ ) sgap2[j] = 'o';
}
if( cut1[i+1] != len1 )
{
getkyokaigap( egap1, seq1, cut1[i+1], clus1 );
getkyokaigap( egap2, seq2, cut2[i+1], clus2 );
}
else
{
for( j=0; j<clus1; j++ ) egap1[j] = 'o';
for( j=0; j<clus2; j++ ) egap2[j] = 'o';
}
for( j=0; j<clus1; j++ )
{
strncpy( tmpres1[j], seq1[j]+cut1[i], cut1[i+1]-cut1[i] );
tmpres1[j][cut1[i+1]-cut1[i]] = 0;
}
if( kobetsubunkatsu ) commongappick_record( clus1, tmpres1, gapmap1 );
for( j=0; j<clus2; j++ )
{
strncpy( tmpres2[j], seq2[j]+cut2[i], cut2[i+1]-cut2[i] );
tmpres2[j][cut2[i+1]-cut2[i]] = 0;
}
if( kobetsubunkatsu ) commongappick_record( clus2, tmpres2, gapmap2 );
#if 0
fprintf( stderr, "count = %d\n", count );
fprintf( stderr, "### reg1 = %d-%d\n", cut1[i], cut1[i+1]-1 );
fprintf( stderr, "### reg2 = %d-%d\n", cut2[i], cut2[i+1]-1 );
#endif
switch( alg )
{
case( 'a' ):
totalscore += Aalign( tmpres1, tmpres2, eff1, eff2, clus1, clus2, alloclen );
break;
case( 'Q' ):
totalscore += partQ__align( tmpres1, tmpres2, eff1, eff2, clus1, clus2, alloclen, localhom, &impmatch, cut1[i], cut1[i+1]-1, cut2[i], cut2[i+1]-1, gapmap1, gapmap2, sgap1, sgap2, egap1, egap2 );
*totalimpmatch += impmatch;
// fprintf( stderr, "*totalimpmatch in Falign_localhom = %f\n", *totalimpmatch );
break;
case( 'A' ):
totalscore += partA__align( tmpres1, tmpres2, eff1, eff2, clus1, clus2, alloclen, localhom, &impmatch, cut1[i], cut1[i+1]-1, cut2[i], cut2[i+1]-1, gapmap1, gapmap2, sgap1, sgap2, egap1, egap2, chudanpt, chudanref, chudanres );
*totalimpmatch += impmatch;
// fprintf( stderr, "*totalimpmatch in Falign_localhom = %f\n", *totalimpmatch );
break;
default:
fprintf( stderr, "alg = %c\n", alg );
ErrorExit( "ERROR IN SOURCE FILE Falign.c" );
break;
}
#ifdef enablemultithread
if( chudanres && *chudanres )
{
// fprintf( stderr, "\n\n## CHUUDAN!!! at Falign_localhom\n" );
return( -1.0 );
}
#endif
nlen = strlen( tmpres1[0] );
if( totallen + nlen > alloclen )
{
fprintf( stderr, "totallen=%d + nlen=%d > alloclen = %d\n", totallen, nlen, alloclen );
ErrorExit( "LENGTH OVER in Falign\n " );
}
for( j=0; j<clus1; j++ ) strcat( result1[j], tmpres1[j] );
for( j=0; j<clus2; j++ ) strcat( result2[j], tmpres2[j] );
totallen += nlen;
#if 0
fprintf( stderr, "%4d\r", totallen );
fprintf( stderr, "\n\n" );
for( j=0; j<clus1; j++ )
{
fprintf( stderr, "%s\n", tmpres1[j] );
}
fprintf( stderr, "-------\n" );
for( j=0; j<clus2; j++ )
{
fprintf( stderr, "%s\n", tmpres2[j] );
}
#endif
}
#if KEIKA
fprintf( stderr, "DP ... done \n" );
#endif
for( j=0; j<clus1; j++ ) strcpy( seq1[j], result1[j] );
for( j=0; j<clus2; j++ ) strcpy( seq2[j], result2[j] );
#if 0
for( j=0; j<clus1; j++ )
{
fprintf( stderr, "%s\n", result1[j] );
}
fprintf( stderr, "- - - - - - - - - - -\n" );
for( j=0; j<clus2; j++ )
{
fprintf( stderr, "%s\n", result2[j] );
}
#endif
return( totalscore );
}
