/usr/bin/altree-convert is in altree 1.3.1-5.
This file is owned by root:root, with mode 0o755.
The actual contents of the file can be viewed below.
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# This program trasforms output files from different haplotype reconstructions programs (Phase, FAMHAP, ...) into input files for phylogeny reconstruction programs (PAUP or Phylip)
use strict;
use diagnostics;
use warnings;
use Getopt::Long; # qw(:config permute);
use Pod::Usage;
#use Getopt::Std;
our($opt_h, $opt_r, $opt_i, $opt_j, $opt_o, $opt_t, $opt_p, $opt_c, $opt_q, $opt_s);
our $VERSION;
$VERSION = sprintf "0.%03d", q$Revision: 290 $ =~ /(\d+)/g;
##### FONCTIONS ANNEXES GLOBALES POUR TOUS LES INPUTS ####
sub print_hash_ind
{
my($hash_ind)=shift;
my($clef);
print "AFFICHAGE\n";
foreach $clef (keys %{$hash_ind}) {
print $clef ," ", $hash_ind->{$clef}->{"statut"}, " ", $hash_ind->{$clef}->{"haplo1"}, " ", $hash_ind->{$clef}->{"haplo2"}, "\n";
}
}
#Verification that
# - the hash contains 2 haplo per individual
# - the statut is defined
sub VerifyHashInd
{
my($hash_ind)=shift;
my($nb_loci)=shift;
my($ind);
foreach $ind (keys %{$hash_ind}) {
if ((!exists $hash_ind->{$ind}->{"statut"}) && (!$opt_j)) {
die "Statut are not available in the input file: You should either provide a second input file (option -j ) or add it in the input file of phase and use the -c-1 option of phase";
} elsif ((!exists $hash_ind->{$ind}->{"haplo1"})
|| (!exists $hash_ind->{$ind}->{"haplo2"})) {
die "Undefined haplotypes for individual $ind\n";
} elsif ((length($hash_ind->{$ind}->{"haplo1"}) != $nb_loci)
|| (length($hash_ind->{$ind}->{"haplo2"}) != $nb_loci)) {
my($long)=length($hash_ind->{$ind}->{"haplo1"});
die "$nb_loci, $long, Bad haplotype sequence length for individual: $ind\n";
}
}
}
############################
##### READ PHASE OUTPUT #####
#Read information in the phase outfile (option -c)
#The info are stored in a hash{num_ind}->{"info"}
# (info=statut[if available], haplo1, haplo2)
sub ReadPhase
{
my($file)=shift;
# Do we have to read statut in INPUT1 or not (use INPUT2)?
my($read_statut)=shift;
my($mark)=0;
my(%hash_ind);
my($passe_par_la)=0; #indicates if a section is read in the input file
my($ligne, $nb_loci);
my($file_has_statut)=0; #=1 when we are sure that info about statut are in the file
open(INPUT1, '<', $file) || die "Unable to open '$file': $!\n";
while ($ligne=<INPUT1>) {
chomp($ligne);
if ($ligne =~ /^BEGIN (OUTFILE_LIST|BESTPAIRS1|INPUT_SUMMARY)$/) {
if ($mark != 0) {
die "Nested sections ! \n";
}
if ($1 eq "OUTFILE_LIST") {
$mark=2;
} elsif ($1 eq "INPUT_SUMMARY") {
$mark=3;
} else {
$mark=1;
}
if ($passe_par_la & (1<<($mark-1)) ) {
die "Double section 'BEGIN $1' !\n";
}
$passe_par_la |= (1<<($mark-1));
next;
}
if ($ligne =~ /^END (OUTFILE_LIST|BESTPAIRS1|INPUT_SUMMARY)$/) {
if ($mark == 0) {
die "Section $1 ends before start ! \n";
}
$mark=0;
next;
}
if ($mark==1) {
my ($ligne2, $ligne3, $statut, $ind);
if ($ligne !~ /^([01])\s+([0-9A-Za-z\#_-]+)$/) {
print STDERR "Skipping strange line : $ligne\n";
} else {
$statut=$1;
$ind=$2;
my $i;
for ($i=1; $i<=2; $i++) {
$ligne2=<INPUT1>;
chomp($ligne2);
$ligne2 =~ tr/()[] //d; # faire aussi un s/(-1)/?/;
$ligne2 =~ s/-1/?/g;
$hash_ind{$ind}->{"haplo".$i}=$ligne2;
}
if ($read_statut) {
$hash_ind{$ind}->{"statut"}=$statut;
}
}
}
if ($mark==2) {
if ($ligne =~ / : p-value for testing cases vs controls$/) {
$file_has_statut=1;
}
}
if ($mark==3){
if ($ligne =~ /^Number of Loci: ([0-9]+)$/) {
$nb_loci=$1;
}
}
}
close(INPUT1);
if ($passe_par_la != 7) {
print "PASSE PAR LA=$passe_par_la \n";
die "The program has either read too many sections or not enough!\n";
}
if ($file_has_statut == 0 && $read_statut == 1) {
die "Statut are not available in the input file: You should either provide a second input file (option -j ) or add it in the input file of phase and use the -c-1 option of phase"
}
if (%hash_ind) { #not empty
return \%hash_ind, $nb_loci;
} else {
die "Error in reading Input 1: info have not been stored correctly in the hash. Check your input file?\n";
}
}
#To add statut info in the hash when it's not available in INPUT1
sub ReadStatut
{
my ($file)=shift;
my ($hash_ind)=shift;
my(@tableau, $ligne);
open(INPUT2, '<', $file) || die "Unable to open '$file': $!\n";
while ($ligne=<INPUT2>) {
chomp($ligne);
@tableau=split(/\s+/, $ligne);
if (!exists($hash_ind->{$tableau[0]})) {
die "This individual doesn't exist in $opt_i: $tableau[0] !\n";
}
$hash_ind->{$tableau[0]}->{"statut"}=$tableau[1];
}
close(INPUT2);
my($ind);
foreach $ind (keys %{$hash_ind}) {
if (!exists($hash_ind->{$tableau[0]}->{"statut"})) {
die "No statut was found for individual $ind !\n";
}
}
}
##########################################
#### READ FAMHAP OUTPUT ##################
#Read information in the FAMHAP outfile ( outfile=file1)
#The info are stored in a hash{haploID}=haplotype_sequence
sub ReadFAMHAPOutfile
{
my($file1)=shift;
my($ligne, , $ligne2, @tableau, %hashHaploID);
my($haplo, $HaploID);
my($nb_loci, $nb_haplo);
open(FAMHAPOUT, '<', $file1) || die "Unable to open '$file1': $!\n";
while ($ligne=<FAMHAPOUT>) {
chomp($ligne);
if ($ligne =~ /^Selected loci:/) {
chomp($ligne);
@tableau=split(/\s+/, $ligne);
$nb_loci=$#tableau-1;
}
if ($ligne =~ /HaploiD: ([0-9]+)/) {
$HaploID=$1;
@tableau=split(/\s+/, $ligne);
$haplo="";
my($i);
if (not defined $nb_loci) {
die "Problem in the input file: nb_loci could not be read: $nb_loci\n";
} else {
for ($i=0; $i<$nb_loci; $i++) {
$haplo.=$tableau[$i];
# Je ne vérifie pas que les alleles font bien un seul
# caractère (une seuk chiffre ou une seule lettre...
}
}
#hash dont clef=HaploID, et valeur = la seq de l'haplotype
if ($HaploID ne "") {
$hashHaploID{$HaploID}=$haplo;
#DEBUG print "haplo=$haplo, hashHaploID=$HaploID hashHaploID{haplo}= $hashHaploID{$HaploID}\n";
} else {
die "Problem in the input file, HaploID could not be correctly read: $HaploID\n";
}
}
}
close(FAMHAPOUT);
return (\%hashHaploID, $nb_loci);
}
#Read information in the FAMHAP Hx_MOSTLIKELI (file2)
#uses the hashHaploID
sub ReadFAMHAPMostLikeli
{
my($file2)=shift;
my($hashHaploID)=shift;
my($ligne, $FT, $FID, $FNT, $MT, $MNT);
my(%hash_ind);
open(OUTHAPLO, '<', $file2) || die "Unable to open '$file2': $!\n";
my($index)=0;
while ($ligne=<OUTHAPLO>) {
chomp($ligne);
if ($ligne =~ /^\s*FID\s+PID\s+HAPLO1\s+HAPLO2\s+HAPLO3\s+HAPLO4\s+LIKELIHOOD_WEIGHT/) {
$index=1;
next;
}
if ($index==1) {
if ($ligne =~ /^\s*(\d+)\s+(.+)\s+(\d+)\s+(\d+)\s+(\d+)\s+(\d+)\s+(.+)/) {
$FID=$1;
$FT=$3;
$FNT=$4;
$MT=$5;
$MNT=$6;
# print "hashHaploID3= $hashHaploID->{$3}\n";
$hash_ind{$FID."0"}->{"haplo1"}=$hashHaploID->{$FNT};
$hash_ind{$FID."0"}->{"haplo2"}=$hashHaploID->{$MNT};
$hash_ind{$FID."0"}->{"statut"}=0;
$hash_ind{$FID."1"}->{"haplo1"}=$hashHaploID->{$FT};
$hash_ind{$FID."1"}->{"haplo2"}=$hashHaploID->{$MT};
$hash_ind{$FID."1"}->{"statut"}=1;
} elsif ($ligne =~ /^$/) {
next;
} else {
print "strange line $ligne\n";
}
}
}
close(OUTHAPLO);
return(\%hash_ind);
}
# call the different function involved in the reading of FAMHAP input file and storage of the infoin a hash{num_ind}->{"info"} (info=statut[if available], haplo1, haplo2)
sub ReadFAMHAP
{
my($file1)=shift;
my($file2)=shift;
my($hashHaploID, $hash_ind);
my($haplo);
my($nb_loci);
($hashHaploID, $nb_loci)=ReadFAMHAPOutfile($file1);
($hash_ind)= ReadFAMHAPMostLikeli($file2, $hashHaploID);
#print "nb_haplo= $nb_haplo, nb_loci=$nb_loci\n";
# foreach $haplo (keys %{$hashHaploID}) {
# print "haplo: $haplo hash=$hashHaploID->{$haplo}\n";
# }
# print_hash_ind($hash_ind);
return($hash_ind, $nb_loci);
}
##########################################
#### DATA TRANSFO ########################
sub TransfoData
{
my($hash_ind)=shift;
my($data_quali)=shift;
my($j)=1;
my($ind, %hash_haplo);
foreach $ind (keys %{$hash_ind}) {
if ($data_quali eq "quali") {
if (($hash_ind->{$ind}->{"statut"} != 0)
&& ($hash_ind->{$ind}->{"statut"} !=1)) {
die "Invalid disease statut for individual $ind: ",
$hash_ind->{$ind}->{"statut"}, "\n";
} else {
my($i);
for ($i=1; $i<=2; $i++) {
$hash_haplo{$hash_ind->{$ind}->{"haplo".$i}}->[$hash_ind->{$ind}->{"statut"}]++;
$hash_haplo{$hash_ind->{$ind}->{"haplo".$i}}->[0]+=0; # moche mais pour eviter les non défini dans affichage
$hash_haplo{$hash_ind->{$ind}->{"haplo".$i}}->[1]+=0;
if (!exists $hash_haplo{$hash_ind->{$ind}->{"haplo".$i}}->[2]) {
$hash_haplo{$hash_ind->{$ind}->{"haplo".$i}}->[2]=$j;
$j++;
}
}
}
} else {
# In this case, $hash_haplo is a hash with $haplo as keys and a
# ref on a tab containing the quantitative values as values.
for (my $i=1; $i<=2; $i++) {
push (@{$hash_haplo{$hash_ind->{$ind}->{"haplo".$i}}->{"valeurs"}}, $hash_ind->{$ind}->{"statut"});
if (!exists $hash_haplo{$hash_ind->{$ind}->{"haplo".$i}}->{"name"}) {
$hash_haplo{$hash_ind->{$ind}->{"haplo".$i}}->{"name"}=$j;
$j++;
}
}
}
}
my($nb_haplo);
$nb_haplo=keys %hash_haplo;
# print "Nb_haplo= $nb_haplo\n";
return \%hash_haplo, $nb_haplo;
}
###########################################
#### BUILDING OF DIFFERENT OUTPUT FILE ####
#Affiche juste les haplo. Surtout pour debug
sub AfficheHashHaplo
{
my($hash_haplo)=shift;
my($haplo);
foreach $haplo (keys %{$hash_haplo}) {
printf "H%.3i_c%.3i_m%.3i\t%s\n", $hash_haplo->{$haplo}->[2],$hash_haplo->{$haplo}->[0], $hash_haplo->{$haplo}->[1], $haplo;
# print "hash_haplo->{$haplo}->[1]", $hash_haplo->{$haplo}->[1], "\n";
}
}
# Prepare a file (correspond.txt) in which the number of cases and the number of controls are specified for each haplotype.
sub MakeCorrespondanceFile
{
my($hash_haplo)=shift;
my($file_corres)=shift;
my $data_quali = shift;
my $seuil = shift;
my($haplo);
open (CORRESP, '>', $file_corres) || die "Unable to open correspond.txt: $!\n";
my $hash_haplo_sorted; # ref on tab containing the haplotypes sorted on the number of individuals carrying them
if ($data_quali eq "quali") {
$hash_haplo_sorted = SortNbhaploQuali($hash_haplo, $seuil);
} else {
$hash_haplo_sorted = SortNbhaploQuanti($hash_haplo, $seuil);
}
# foreach $haplo (keys %{$hash_haplo}) {
foreach $haplo (@{$hash_haplo_sorted}) { #new version with sorted sequences
if ($data_quali eq "quali") {
printf CORRESP "H%.3i\tm%.3i\tc%.3i\n", $hash_haplo->{$haplo}->[2],$hash_haplo->{$haplo}->[1], $hash_haplo->{$haplo}->[0];
} else {
printf CORRESP "H%.3i\t", $hash_haplo->{$haplo}->{"name"};
foreach my $valeurs (@{$hash_haplo->{$haplo}->{"valeurs"}}) {
print CORRESP "$valeurs\t";
}
print CORRESP "\n";
}
}
close(CORRESP);
}
# Select and sort the haplotypes that will appear in the paup file and in the correspondance file. Does not work with phylip yet
sub SortNbhaploQuali
{
my $hash_haplo = shift;
my $seuil = shift;
my @hash_haplo_sorted = sort {
$hash_haplo->{$a}->[0]+$hash_haplo->{$a}->[1] <=>
$hash_haplo->{$b}->[0]+$hash_haplo->{$b}->[1]
} (grep {
$hash_haplo->{$_}->[0]+$hash_haplo->{$_}->[1]>$seuil
} (keys %{$hash_haplo}));
return \@hash_haplo_sorted;
}
sub SortNbhaploQuanti
{
my $hash_haplo = shift;
my $seuil =shift;
my @hash_haplo_sorted = sort {
$#$hash_haplo->{$a}->{"valeurs"} <=>
$#$hash_haplo->{$b}->{"valeurs"}
} (grep {
$hash_haplo->{$_}->[0]+$hash_haplo->{$_}->[1]>$seuil
} (keys %{$hash_haplo}));
return \@hash_haplo_sorted;
}
# Read the opt_t and define the character to add to the ancestral sequence ($anc) and to the other haplotypes ($der). Also define the "format symbol for paup.
sub ReadDataType
{
my($data_type)=shift;
# my ($der, $anc);
my($write_data_type);
if ($data_type eq "DNA") {
$write_data_type="ATGCU";
# $anc="G";
# $der="C";
} elsif ($data_type eq "NUM") {
$write_data_type="0123456789";
# $anc="1";
# $der="0";
} else {
die "Invalid data type specified in opt_t: $opt_t. You should use DNA or NUM\n";
}
return ($write_data_type);
# return ($anc, $der, $write_data_type);
}
#Build a PAUP OUTFILE
sub BuildPAUP
{
my($file)=shift;
my($hash_haplo)=shift;
my($nb_haplo)=shift;
my($nb_loci)=shift;
my($data_type)=shift;
my($file_corres)= shift;
my $data_quali=shift;
my $seuil = shift;
#my($der, $anc);
my($write_data_type);
MakeCorrespondanceFile($hash_haplo, $file_corres, $data_quali, $seuil);
#($anc, $der, $write_data_type)=ReadDataType($data_type);
($write_data_type)=ReadDataType($data_type);
my $hash_haplo_sorted;
if ($data_quali eq "quali") {
$hash_haplo_sorted = SortNbhaploQuali($hash_haplo, $seuil);
} else {
$hash_haplo_sorted = SortNbhaploQuanti($hash_haplo, $seuil);
}
open(OUTPAUP, '>', $file) || die "Unable to open '$file': $!\n";
print OUTPAUP "#Nexus\n";
print OUTPAUP "Begin data;\n";
print OUTPAUP "dimension ntax=",$#$hash_haplo_sorted+1," nchar=", $nb_loci,";\n";
print OUTPAUP "format symbols=\"$write_data_type\" missing=?;\n";
print OUTPAUP "matrix\n";
my($haplo);
# foreach $haplo (keys %{$hash_haplo}) {
# printf OUTPAUP "H%.3i_m%.3i_c%.3i\t%s%s\n", $hash_haplo->{$haplo}->[2],$hash_haplo->{$haplo}->[1], $hash_haplo->{$haplo}->[0], $haplo, $der; # a modifier si je fais un deuxième fichier de sortie...
foreach $haplo (@{$hash_haplo_sorted}) {
if ($data_quali eq "quali") {
printf OUTPAUP "H%.3i\t%s\n", $hash_haplo->{$haplo}->[2], $haplo;#, $der;
} else {
printf OUTPAUP "H%.3i\t%s\n", $hash_haplo->{$haplo}->{"name"}, $haplo;
}
}
print OUTPAUP "H000_ancetre [add ancestral haplotype]\n";#$anc\n";
print OUTPAUP ";\n";
print OUTPAUP "end;\n";
print OUTPAUP "begin assumptions;\n";
print OUTPAUP "ancstates *anc vector = [add ancestral haplotype];\n";
print OUTPAUP "end;\n";
print OUTPAUP "begin paup;\n";
print OUTPAUP "set nowarnreset autoclose maxtrees = [2000] increase=[no - Auto AutoInc = 100] monitor = no taxlabels = full\n";
print OUTPAUP "root=lundberg warnroot=no opt=[deltran - acctran] ancstates=anc;\n";
print OUTPAUP "hsearch;\n";
print OUTPAUP "savetrees [from=1 to=1] file=[test.tree] root=yes format=altnexus;\n";
print OUTPAUP "cleartrees nowarn=yes;\n";
print OUTPAUP "gettrees rooted=yes file=[test.tree];\n";
print OUTPAUP "log file = [test.res.log] replace=[yes - no];\n";
print OUTPAUP "describetrees [all] /plot=[cladogram - phylogram] brlens=yes rootmethod=lundberg apolist=yes;\n";
print OUTPAUP "log stop;\n";
print OUTPAUP "end;\n";
print OUTPAUP "quit;\n";
print OUTPAUP "[WARNING, this file is designed for bi-allelic data. If it is not the case, you may have to modify this input file, for example by specifying the ordered option in the typeset command in the assumption block]\n";
close(OUTPAUP);
}
#Build a PHYLIP OUTFILE
sub BuildPHYLIP
{
my ($file)=shift;
my($hash_haplo)=shift;
my($nb_haplo)=shift;
my($nb_loci)=shift;
my($data_type)=shift;
my($file_corres)=shift;
# my ($der, $anc);
my($write_data_type);
#### SI ON UTILISE PHYLIP? FAIRE UN TEST: on doit avoir du 0/1 ou du ATGCU... SInon, marche pas!
MakeCorrespondanceFile($hash_haplo, $file_corres);
# ($anc, $der, $write_data_type)=ReadDataType($data_type);
($write_data_type)=ReadDataType($data_type);
open(OUTPHYLIP, '>', $file) || die "Unable to open '$file': $!\n";
print OUTPHYLIP "\t", $nb_haplo+1, "\t", $nb_loci+1, "\n";
my($haplo);
foreach $haplo (keys %{$hash_haplo}) {#### SI ON UTILISE PHYLIP? FAIRE UN TEST: on doit avoir du 0/1 ou du ATGCU... SInon, marche pas!
printf OUTPHYLIP "H%.3i%s\t%s\n", $hash_haplo->{$haplo}->[2]," ", $haplo;#, $der;
}
# print OUTPHYLIP "H000_anc ", "\t", "[ancestral sequence]\n";#$anc\n";
close(OUTPHYLIP);
# print STDERR "Don't forget to prepare the ancestor file containing the ancestor sequence followed by the character $anc\n";
}
############################################
sub main
{
my($progname, $rec_program);
my %options= (
"first-input-file" => \$opt_i,
"second-input-file" => \$opt_j,
"output-file" => \$opt_o,
"case-control-output" => \$opt_c,
"data-type" => \$opt_t,
"phylo-prog" => \$opt_p,
"reconstruct-prog" => \$opt_r,
"data-quali" => \$opt_q,
"nbind-threshold" => \$opt_s,
);
#getopts('hr:i:j:o:t:p:');
GetOptions (\%options,
"version",
"short-help|h",
"help",
"man",
"first-input-file|i=s",
"second-input-file|j=s",
"output-file|o=s",
"case-control-output|c=s",
"data-type|t=s",
"phylo-prog|p=s",
"reconstruct-prog|r=s",
"data-quali|q=s",
"nbind-threshold|s=i",
) or pod2usage(2);
if (defined($options{"version"})) {
print $0, " version ", $VERSION, "\n";
print "(Perl version ", $], ")\n";
exit 0;
}
if (defined($options{"short-help"})) {
pod2usage(-exitstatus => 0, -verbose => 0);
}
if (defined($options{"help"})) {
pod2usage(-exitstatus => 0, -verbose => 1);
}
if (defined($options{"man"})) {
pod2usage(-exitstatus => 0, -verbose => 2);
}
# if ($opt_h) {
# ($progname = $0) =~ s|^.*/([^/]*)$|$1|;
# print STDERR "usage : $progname \n";
# print STDERR "\t-r Haplotype reconstruction program\n";
# print STDERR "\t-i Input file 1\n";
# print STDERR "\t[-j Input file 2]\n";
# print STDERR "\t-o Output file \n";
# print STDERR "\t-t Type of data: DNA (ATGCU) or NUM (0-9)\n";
# print STDERR "\t-p Phylogeny reconstruction program\n";
# print STDERR "\t-h: this help\n";
# exit (1);
# }
if ($opt_r){
$rec_program = $opt_r;
} else {
die "Name of the haplotype reconstruction program used missing: opt_r\n";
}
if (!$opt_i) { # Principal outfile of haplotypic reconstruction program
die "No input file\n";
}
if (!$opt_o) { # Output file for a phylogeny reconstruction program
die "No output file\n";
}
if (!$opt_c) { # Output file for a phylogeny reconstruction program
die "No case-control statut output file\n";
}
my($phylo_program);
if ($opt_p){
$phylo_program = $opt_p;
} else {
die "Name of the phylogeny reconstruction program used missing: opt_p\n";
}
if (!$opt_t){
die "Type of data: opt_t (DNA or NUM) not specified!\n"; #il faudra peut-etre vérifier que les données sont bien du bon type???
}
my $data_quali;
if (! $opt_q){
die "Data quality: opt_q, (qualitative or quantitative) not specified!\n";
}
if (not defined $opt_s){
die "Nb ind threshold: opt_s not specified!\n";
}
my($hash_ind, $hash_statut, $hash_haplo);
my($nb_haplo, $nb_loci);
if ($rec_program =~ /^[Pp][Hh][Aa][Ss][Ee]$/) {
($hash_ind, $nb_loci)=ReadPhase($opt_i, !$opt_j);
VerifyHashInd($hash_ind, $nb_loci);
if ($opt_j) {
ReadStatut($opt_j, $hash_ind);
}
} elsif ($rec_program =~ /^[Ff][Aa][Mm][Hh][Aa][Pp]$/) {
if (!$opt_j) {
die "No file H1_MOSTLIKELI or H0_MOSTLIKELI provided\n";
} else {
($hash_ind, $nb_loci)=ReadFAMHAP($opt_i, $opt_j);
VerifyHashInd($hash_ind, $nb_loci);
}
} else {
die "Unknown software. Check the -r option! \n";
}
if ($opt_q =~ /^[Qq][Uu][Aa][Ll][Ii][Tt][Aa][Tt][Ii][Vv][Ee]$/) {
$data_quali="quali";
} elsif ($opt_q =~ /^[Qq][Uu][Aa][Nn][Tt][Ii][Tt][Aa][Tt][Ii][Vv][Ee]$/) {
$data_quali="quanti";
} else {
die "Unknown data_qual. Check the -q option! \n";
}
#print_hash_ind($hash_ind);
($hash_haplo, $nb_haplo)=TransfoData($hash_ind, $data_quali);
# AfficheHashHaplo($hash_haplo); # pour verifier
if ($phylo_program =~ /^[Pp][Aa][Uu][Pp]$/) {
BuildPAUP($opt_o, $hash_haplo, $nb_haplo, $nb_loci, $opt_t, $opt_c, $data_quali, $opt_s)
} elsif ($phylo_program =~ /^[Pp][Hh][Yy][Ll][Ii][Pp]$/) {
BuildPHYLIP($opt_o, $hash_haplo, $nb_haplo, $nb_loci, $opt_t, $opt_c);
} else {
die "Unknown phylogeny software. Check the -p option! \n";
}
}
main;
__END__
=head1 NAME
altree-convert - Title...
=head1 SYNOPSIS
altree-convert [options]
Options:
--version program version
--short-help|h brief help message
--help help message with options descriptions
--man full documentation
--first-input-file|i input file 1
--second-input-file|j input file 2 (not mandatory)
--output-file|o output file
--case-control-output|c output containing the nb cases/controls
--data-type|t DNA|NUM
--phylo-prog|p PAUP|PHYLIP
--reconstruct-prog|r PHASE|FAMHAP
--data-quali|q Type of data: qualitative or quantitative
--nbind-threshold|s Minimum number of individuals ecquired to keep an haplotype
=head1 OPTIONS
=over 8
=item B<--version>
Print the program version and exits.
=item B<--short-help>
Print a brief help message and exits.
=item B<--help>
Print a help message with options descriptions and exits.
=item B<--man>
Prints the manual page and exits.
=item B<--first-input-file|i>
Input file 1 (output of the haplotype reconstruction program)
=item B<--second-input-file|j>
Input file 2 (second output of famhap or file containig the disease status)
=item B<--output-file|o>
Output file
=item B<--case-control-output|c>
Output file containing the number of cases and controls carrying each haplotype
=item B<--data-type|t> C<DNA>|C<SNP>
Type of data: DNA (ATGCU) or SNP (0-1)
=item B<--phylo-prog|p> C<phylip>|C<paup>
Phylogeny reconstruction program
=item B<reconstruct-prog|r> C<famhap|phase>
Haplotype reconstruction program
=item B<data-quali|q> C<qualitative|quantitative>
Type of data analyzed
=item B<nbind-threshold|s>
Minimal number of individuals carrying an haplotype recquired to keep it for further analysis. If you want to keep all haplotypes, you must affect 0 to this variable
=back
=head1 DESCRIPTION
B<This program> will read the given input file(s) and generate an input file for the phylogenetic reconstruction software paup or phylip/paml
=cut
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