1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
|
#!/usr/bin/env perl
use warnings; #sed replacement for -w perl parameter
# In general, doing
# run.pl some.log a b c is like running the command a b c in
# the bash shell, and putting the standard error and output into some.log.
# To run parallel jobs (backgrounded on the host machine), you can do (e.g.)
# run.pl JOB=1:4 some.JOB.log a b c JOB is like running the command a b c JOB
# and putting it in some.JOB.log, for each one. [Note: JOB can be any identifier].
# If any of the jobs fails, this script will fail.
# A typical example is:
# run.pl some.log my-prog "--opt=foo bar" foo \| other-prog baz
# and run.pl will run something like:
# ( my-prog '--opt=foo bar' foo | other-prog baz ) >& some.log
#
# Basically it takes the command-line arguments, quotes them
# as necessary to preserve spaces, and evaluates them with bash.
# In addition it puts the command line at the top of the log, and
# the start and end times of the command at the beginning and end.
# The reason why this is useful is so that we can create a different
# version of this program that uses a queueing system instead.
# use Data::Dumper;
@ARGV < 2 && die "usage: run.pl log-file command-line arguments...";
$max_jobs_run = -1;
$jobstart = 1;
$jobend = 1;
$ignored_opts = ""; # These will be ignored.
# First parse an option like JOB=1:4, and any
# options that would normally be given to
# queue.pl, which we will just discard.
if (@ARGV > 0) {
while (@ARGV >= 2 && $ARGV[0] =~ m:^-:) { # parse any options
# that would normally go to qsub, but which will be ignored here.
$switch = shift @ARGV;
if ($switch eq "-V") {
$ignored_opts .= "-V ";
} elsif ($switch eq "--max-jobs-run" || $switch eq "-tc") {
# we do support the option --max-jobs-run n, and its GridEngine form -tc n.
$max_jobs_run = shift @ARGV;
if (! ($max_jobs_run > 0)) {
die "run.pl: invalid option --max-jobs-run $max_jobs_run";
}
} else {
$option = shift @ARGV;
if ($switch eq "-sync" && $option =~ m/^[yY]/) {
$ignored_opts .= "-sync "; # Note: in the
# corresponding code in queue.pl it says instead, just "$sync = 1;".
}
$ignored_opts .= "$switch $option ";
if ($switch eq "-pe") { # e.g. -pe smp 5
$option2 = shift @ARGV;
$ignored_opts .= "$option2 ";
}
}
}
if ($ARGV[0] =~ m/^([\w_][\w\d_]*)+=(\d+):(\d+)$/) { # e.g. JOB=1:10
$jobname = $1;
$jobstart = $2;
$jobend = $3;
shift;
if ($jobstart > $jobend) {
die "run.pl: invalid job range $ARGV[0]";
}
if ($jobstart <= 0) {
die "run.pl: invalid job range $ARGV[0], start must be strictly positive (this is required for GridEngine compatibility).";
}
} elsif ($ARGV[0] =~ m/^([\w_][\w\d_]*)+=(\d+)$/) { # e.g. JOB=1.
$jobname = $1;
$jobstart = $2;
$jobend = $2;
shift;
} elsif ($ARGV[0] =~ m/.+\=.*\:.*$/) {
print STDERR "run.pl: Warning: suspicious first argument to run.pl: $ARGV[0]\n";
}
}
# Users found this message confusing so we are removing it.
# if ($ignored_opts ne "") {
# print STDERR "run.pl: Warning: ignoring options \"$ignored_opts\"\n";
# }
if ($max_jobs_run == -1) { # If --max-jobs-run option not set,
# then work out the number of processors if possible,
# and set it based on that.
$max_jobs_run = 0;
if (open(P, "</proc/cpuinfo")) { # Linux
while (<P>) { if (m/^processor/) { $max_jobs_run++; } }
if ($max_jobs_run == 0) {
print STDERR "run.pl: Warning: failed to detect any processors from /proc/cpuinfo\n";
$max_jobs_run = 10; # reasonable default.
}
close(P);
} elsif (open(P, "sysctl -a |")) { # BSD/Darwin
while (<P>) {
if (m/hw\.ncpu\s*[:=]\s*(\d+)/) { # hw.ncpu = 4, or hw.ncpu: 4
$max_jobs_run = $1;
last;
}
}
close(P);
if ($max_jobs_run == 0) {
print STDERR "run.pl: Warning: failed to detect any processors from sysctl -a\n";
$max_jobs_run = 10; # reasonable default.
}
} else {
# allow at most 32 jobs at once, on non-UNIX systems; change this code
# if you need to change this default.
$max_jobs_run = 32;
}
# The just-computed value of $max_jobs_run is just the number of processors
# (or our best guess); and if it happens that the number of jobs we need to
# run is just slightly above $max_jobs_run, it will make sense to increase
# $max_jobs_run to equal the number of jobs, so we don't have a small number
# of leftover jobs.
$num_jobs = $jobend - $jobstart + 1;
if ($num_jobs > $max_jobs_run && $num_jobs < 1.4 * $max_jobs_run) {
$max_jobs_run = $num_jobs;
}
}
$logfile = shift @ARGV;
if (defined $jobname && $logfile !~ m/$jobname/ &&
$jobend > $jobstart) {
print STDERR "run.pl: you are trying to run a parallel job but "
. "you are putting the output into just one log file ($logfile)\n";
exit(1);
}
$cmd = "";
foreach $x (@ARGV) {
if ($x =~ m/^\S+$/) { $cmd .= $x . " "; }
elsif ($x =~ m:\":) { $cmd .= "'$x' "; }
else { $cmd .= "\"$x\" "; }
}
#$Data::Dumper::Indent=0;
$ret = 0;
$numfail = 0;
%active_pids=();
use POSIX ":sys_wait_h";
for ($jobid = $jobstart; $jobid <= $jobend; $jobid++) {
if (scalar(keys %active_pids) >= $max_jobs_run) {
# Lets wait for a change in any child's status
# Then we have to work out which child finished
$r = waitpid(-1, 0);
$code = $?;
if ($r < 0 ) { die "run.pl: Error waiting for child process"; } # should never happen.
if ( defined $active_pids{$r} ) {
$jid=$active_pids{$r};
$fail[$jid]=$code;
if ($code !=0) { $numfail++;}
delete $active_pids{$r};
# print STDERR "Finished: $r/$jid " . Dumper(\%active_pids) . "\n";
} else {
die "run.pl: Cannot find the PID of the chold process that just finished.";
}
# In theory we could do a non-blocking waitpid over all jobs running just
# to find out if only one or more jobs finished during the previous waitpid()
# However, we just omit this and will reap the next one in the next pass
# through the for(;;) cycle
}
$childpid = fork();
if (!defined $childpid) { die "run.pl: Error forking in run.pl (writing to $logfile)"; }
if ($childpid == 0) { # We're in the child... this branch
# executes the job and returns (possibly with an error status).
if (defined $jobname) {
$cmd =~ s/$jobname/$jobid/g;
$logfile =~ s/$jobname/$jobid/g;
}
system("mkdir -p `dirname $logfile` 2>/dev/null");
open(F, ">$logfile") || die "run.pl: Error opening log file $logfile";
print F "# " . $cmd . "\n";
print F "# Started at " . `date`;
$starttime = `date +'%s'`;
print F "#\n";
close(F);
# Pipe into bash.. make sure we're not using any other shell.
open(B, "|bash") || die "run.pl: Error opening shell command";
print B "( " . $cmd . ") 2>>$logfile >> $logfile";
close(B); # If there was an error, exit status is in $?
$ret = $?;
$lowbits = $ret & 127;
$highbits = $ret >> 8;
if ($lowbits != 0) { $return_str = "code $highbits; signal $lowbits" }
else { $return_str = "code $highbits"; }
$endtime = `date +'%s'`;
open(F, ">>$logfile") || die "run.pl: Error opening log file $logfile (again)";
$enddate = `date`;
chop $enddate;
print F "# Accounting: time=" . ($endtime - $starttime) . " threads=1\n";
print F "# Ended ($return_str) at " . $enddate . ", elapsed time " . ($endtime-$starttime) . " seconds\n";
close(F);
exit($ret == 0 ? 0 : 1);
} else {
$pid[$jobid] = $childpid;
$active_pids{$childpid} = $jobid;
# print STDERR "Queued: " . Dumper(\%active_pids) . "\n";
}
}
# Now we have submitted all the jobs, lets wait until all the jobs finish
foreach $child (keys %active_pids) {
$jobid=$active_pids{$child};
$r = waitpid($pid[$jobid], 0);
$code = $?;
if ($r == -1) { die "run.pl: Error waiting for child process"; } # should never happen.
if ($r != 0) { $fail[$jobid]=$code; $numfail++ if $code!=0; } # Completed successfully
}
# Some sanity checks:
# The $fail array should not contain undefined codes
# The number of non-zeros in that array should be equal to $numfail
# We cannot do foreach() here, as the JOB ids do not necessarily start by zero
$failed_jids=0;
for ($jobid = $jobstart; $jobid <= $jobend; $jobid++) {
$job_return = $fail[$jobid];
if (not defined $job_return ) {
# print Dumper(\@fail);
die "run.pl: Sanity check failed: we have indication that some jobs are running " .
"even after we waited for all jobs to finish" ;
}
if ($job_return != 0 ){ $failed_jids++;}
}
if ($failed_jids != $numfail) {
die "run.pl: Sanity check failed: cannot find out how many jobs failed ($failed_jids x $numfail)."
}
if ($numfail > 0) { $ret = 1; }
if ($ret != 0) {
$njobs = $jobend - $jobstart + 1;
if ($njobs == 1) {
if (defined $jobname) {
$logfile =~ s/$jobname/$jobstart/; # only one numbered job, so replace name with
# that job.
}
print STDERR "run.pl: job failed, log is in $logfile\n";
if ($logfile =~ m/JOB/) {
print STDERR "run.pl: probably you forgot to put JOB=1:\$nj in your script.";
}
}
else {
$logfile =~ s/$jobname/*/g;
print STDERR "run.pl: $numfail / $njobs failed, log is in $logfile\n";
}
}
exit ($ret);
|