RunSafely.sh - llvm-test-suite - Git at Google

 #!/bin/sh
 #
 # Program:  RunSafely.sh
 #
 # Synopsis: This script simply runs another program.  If the program works
 #           correctly, this script has no effect, otherwise it will do things
 #           like print a stack trace of a core dump.  It always returns
 #           "successful" so that tests will continue to be run.
 #
 #           This script funnels stdout and stderr from the program into the
 #           fourth argument specified, and outputs a <outfile>.time file which
 #           contains a timing of the program and the program's exit code.
 #
 #           The <exitok> parameter specifies how the program's exit status
 #           is interpreted.  If the <exitok> parameter is non-zero, any
 #           non-zero exit status from the program is considered to indicate
 #           a test failure.  If the <exitok> parameter is zero, only exit
 #           statuses that indicates that the program could not be executed
 #           normally or that the program was terminated as a signal are
 #           considered to indicate a test failure.
 #
 #           If optional parameters -r <remote host> -l <remote user> are
 #           specified, it execute the program remotely using rsh.
 #
 # Syntax:
 #
 #   RunSafely.sh [-r <rhost>] [-l <ruser>] [-rc <client>] [-rp <port>]
 #                <timeout> <exitok> <infile> <outfile> <program> <args...>
 #
 #   where:
 #     <rhost>   is the remote host to execute the program
 #     <ruser>   is the username on the remote host
 #     <client>  is the remote client used to execute the program
 #     <port>    is the port used by the remote client
 #     <timeout> is the maximum number of seconds to let the <program> run
 #     <exitok>  is 1 if the program must exit with 0 return code
 #     <infile>  is a file from which standard input is directed
 #     <outfile> is a file to which standard output and error are directed
 #     <program> is the path to the program to run
 #     <args...> are the arguments to pass to the program.
 #
 if [ $# -lt 4 ]; then
   echo "./RunSafely.sh <timeout> <exitok> <infile> <outfile> <program> <args...>"
   exit 1
 fi

 # Save a copy of the original arguments in a string before we
 # clobber them with the shift command.
 ORIG_ARGS="$*"

 DIR=${0%%`basename $0`}

 RHOST=
 RUSER=`id -un`
 RCLIENT=rsh
 RPORT=
 if [ $1 = "-r" ]; then
   RHOST=$2
   shift 2
 fi
 if [ $1 = "-l" ]; then
   RUSER=$2
   shift 2
 fi
 if [ $1 = "-rc" ]; then
   RCLIENT=$2
   shift 2
 fi
 if [ $1 = "-rp" ]; then
   RPORT="-p $2"
   shift 2
 fi

 ULIMIT=$1
 EXITOK=$2
 INFILE=$3
 OUTFILE=$4
 PROGRAM=$5
 shift 5
 SYSTEM=`uname -s`

 PROG=${PROGRAM}
 if [ `basename ${PROGRAM}` = "lli" ]; then
   PROG=`basename ${PROGRAM}`
 fi

 ULIMITCMD=""
 case $SYSTEM in
   CYGWIN*)
     ;;
   Darwin*)
     # Disable core file emission, the script doesn't find it anyway because it
     # is put into /cores.
     ULIMITCMD="$ULIMITCMD ulimit -c 0;"
     ULIMITCMD="$ULIMITCMD ulimit -t $ULIMIT;"
     # To prevent infinite loops which fill up the disk, specify a limit on size
     # of files being output by the tests. 10 MB should be enough for anybody. ;)
     ULIMITCMD="$ULIMITCMD ulimit -f 10485760;"
     ;;
   *)
     ULIMITCMD="$ULIMITCMD ulimit -t $ULIMIT;"
     ULIMITCMD="$ULIMITCMD ulimit -c unlimited;"
     # To prevent infinite loops which fill up the disk, specify a limit on size
     # of files being output by the tests. 10 MB should be enough for anybody. ;)
     ULIMITCMD="$ULIMITCMD ulimit -f 10485760;"

     # virtual memory: 250 MB should be enough for anybody. ;)
     ULIMITCMD="$ULIMITCMD ulimit -v 250000;"
 esac
 rm -f core core.*

 #
 # Run the command, timing its execution.
 # The standard output and standard error of $PROGRAM should go in $OUTFILE,
 # and the standard error of time should go in $OUTFILE.time. Note that the
 # return code of the program is appended to the $OUTFILE on an "Exit Val ="
 # line.
 #
 # To get the time program and the specified program different output filenames,
 # we tell time to launch a shell which in turn executes $PROGRAM with the
 # necessary I/O redirection.
 #
 PWD=`pwd`
 COMMAND="$PROGRAM $*"
 if [ "$SYSTEM" = "Darwin" ]; then
   COMMAND="${DIR}TimedExec.sh $ULIMIT $PWD $COMMAND"
 fi

 if [ "x$RHOST" = x ] ; then
   ( sh -c "$ULIMITCMD time -p sh -c '$COMMAND >$OUTFILE 2>&1 < $INFILE; echo exit \$?'" ) 2>&1 \
     | awk -- '\
 BEGIN     { cpu = 0.0; }
 /^user/   { cpu += $2; print; }
 /^sys/    { cpu += $2; print; }
 !/^user/ && !/^sys/  { print; }
 END       { printf("program %f\n", cpu); }' > $OUTFILE.time
 else
   rm -f "$PWD/${PROG}.command"
   rm -f "$PWD/${PROG}.remote"
   rm -f "$PWD/${PROG}.remote.time"
   echo "$ULIMITCMD cd $PWD; (time -p ($COMMAND > $PWD/${OUTFILE}.remote 2>&1 < $INFILE;); echo exit $?) > $PWD/${OUTFILE}.remote.time 2>&1" > "$PWD/${PROG}.command"
   chmod +x "$PWD/${PROG}.command"

   ( $RCLIENT -l $RUSER $RHOST $RPORT "ls $PWD/${PROG}.command" ) > /dev/null 2>&1
   ( $RCLIENT -l $RUSER $RHOST $RPORT "$PWD/${PROG}.command" )
   cat $PWD/${OUTFILE}.remote.time | awk -- '\
 BEGIN     { cpu = 0.0; }
 /^user/   { cpu += $2; print; }
 /^sys/    { cpu += $2; print; }
 !/^user/ && !/^sys/  { print; }
 END       { printf("program %f\n", cpu); }' > $OUTFILE.time
 sleep 1
 cp -f $PWD/${OUTFILE}.remote ${OUTFILE}
 rm -f $PWD/${OUTFILE}.remote
 rm -f $PWD/${OUTFILE}.remote.time
 fi

 exitval=`grep '^exit ' $OUTFILE.time | sed -e 's/^exit //'`
 fail=yes
 if [ -z "$exitval" ] ; then
   exitval=99
   echo "TEST $PROGRAM FAILED: CAN'T GET EXIT CODE!"
 elif test "$exitval" -eq 126 ; then
   echo "TEST $PROGRAM FAILED: command not executable (exit status 126)!"
 elif test "$exitval" -eq 127 ; then
   echo "TEST $PROGRAM FAILED: command not found (exit status 127)!"
 elif test "$exitval" -eq 128 ; then
   # Exit status 128 doesn't have a standard meaning, but it's unlikely
   # to be expected program behavior.
   echo "TEST $PROGRAM FAILED: exit status 128!"
 elif test "$exitval" -gt 128 ; then
   echo "TEST $PROGRAM FAILED: process terminated by signal (exit status $exitval)!"
 elif [ "$EXITOK" -ne 0 -a "$exitval" -ne 0 ] ; then
   echo "TEST $PROGRAM FAILED: EXIT != 0"
 else
   fail=no
 fi
 echo "exit $exitval" >> $OUTFILE

 # If we detected a failure, print the name of the test executable to the
 # output file. This will cause it to compare as different with other runs
 # of the same test even if they fail in the same way, because they'll have
 # different command names.
 if [ "${fail}" != "no" ]; then
   echo "RunSafely.sh detected a failure with these command-line arguments: " \
        "$ORIG_ARGS" >> $OUTFILE
 fi

 if ls | egrep "^core" > /dev/null
 then
     # If we are on a sun4u machine (UltraSparc), then the code we're generating
     # is 64 bit code.  In that case, use gdb-64 instead of gdb.
     myarch=`uname -m`
     if [ "$myarch" = "sun4u" ]
     then
 	GDB="gdb-64"
     else
 	GDB=gdb
     fi

     corefile=`ls core* | head -n 1`
     echo "where 100" > StackTrace.$$
     $GDB -q -batch --command=StackTrace.$$ --core=$corefile $PROGRAM < /dev/null
     rm -f StackTrace.$$ $corefile
 fi
 # Always return "successful" so that tests will continue to be run.
 exit 0
	#!/bin/sh
	#
	# Program: RunSafely.sh
	#
	# Synopsis: This script simply runs another program. If the program works
	# correctly, this script has no effect, otherwise it will do things
	# like print a stack trace of a core dump. It always returns
	# "successful" so that tests will continue to be run.
	#
	# This script funnels stdout and stderr from the program into the
	# fourth argument specified, and outputs a <outfile>.time file which
	# contains a timing of the program and the program's exit code.
	#
	# The <exitok> parameter specifies how the program's exit status
	# is interpreted. If the <exitok> parameter is non-zero, any
	# non-zero exit status from the program is considered to indicate
	# a test failure. If the <exitok> parameter is zero, only exit
	# statuses that indicates that the program could not be executed
	# normally or that the program was terminated as a signal are
	# considered to indicate a test failure.
	#
	# If optional parameters -r <remote host> -l <remote user> are
	# specified, it execute the program remotely using rsh.
	#
	# Syntax:
	#
	# RunSafely.sh [-r <rhost>] [-l <ruser>] [-rc <client>] [-rp <port>]
	# <timeout> <exitok> <infile> <outfile> <program> <args...>
	#
	# where:
	# <rhost> is the remote host to execute the program
	# <ruser> is the username on the remote host
	# <client> is the remote client used to execute the program
	# <port> is the port used by the remote client
	# <timeout> is the maximum number of seconds to let the <program> run
	# <exitok> is 1 if the program must exit with 0 return code
	# <infile> is a file from which standard input is directed
	# <outfile> is a file to which standard output and error are directed
	# <program> is the path to the program to run
	# <args...> are the arguments to pass to the program.
	#
	if [ $# -lt 4 ]; then
	echo "./RunSafely.sh <timeout> <exitok> <infile> <outfile> <program> <args...>"
	exit 1
	fi

	# Save a copy of the original arguments in a string before we
	# clobber them with the shift command.
	ORIG_ARGS="$*"

	DIR=${0%%`basename $0`}

	RHOST=
	RUSER=`id -un`
	RCLIENT=rsh
	RPORT=
	if [ $1 = "-r" ]; then
	RHOST=$2
	shift 2
	fi
	if [ $1 = "-l" ]; then
	RUSER=$2
	shift 2
	fi
	if [ $1 = "-rc" ]; then
	RCLIENT=$2
	shift 2
	fi
	if [ $1 = "-rp" ]; then
	RPORT="-p $2"
	shift 2
	fi

	ULIMIT=$1
	EXITOK=$2
	INFILE=$3
	OUTFILE=$4
	PROGRAM=$5
	shift 5
	SYSTEM=`uname -s`

	PROG=${PROGRAM}
	if [ `basename ${PROGRAM}` = "lli" ]; then
	PROG=`basename ${PROGRAM}`
	fi

	ULIMITCMD=""
	case $SYSTEM in
	CYGWIN*)
	;;
	Darwin*)
	# Disable core file emission, the script doesn't find it anyway because it
	# is put into /cores.
	ULIMITCMD="$ULIMITCMD ulimit -c 0;"
	ULIMITCMD="$ULIMITCMD ulimit -t $ULIMIT;"
	# To prevent infinite loops which fill up the disk, specify a limit on size
	# of files being output by the tests. 10 MB should be enough for anybody. ;)
	ULIMITCMD="$ULIMITCMD ulimit -f 10485760;"
	;;
	*)
	ULIMITCMD="$ULIMITCMD ulimit -t $ULIMIT;"
	ULIMITCMD="$ULIMITCMD ulimit -c unlimited;"
	# To prevent infinite loops which fill up the disk, specify a limit on size
	# of files being output by the tests. 10 MB should be enough for anybody. ;)
	ULIMITCMD="$ULIMITCMD ulimit -f 10485760;"

	# virtual memory: 250 MB should be enough for anybody. ;)
	ULIMITCMD="$ULIMITCMD ulimit -v 250000;"
	esac
	rm -f core core.*

	#
	# Run the command, timing its execution.
	# The standard output and standard error of $PROGRAM should go in $OUTFILE,
	# and the standard error of time should go in $OUTFILE.time. Note that the
	# return code of the program is appended to the $OUTFILE on an "Exit Val ="
	# line.
	#
	# To get the time program and the specified program different output filenames,
	# we tell time to launch a shell which in turn executes $PROGRAM with the
	# necessary I/O redirection.
	#
	PWD=`pwd`
	COMMAND="$PROGRAM $*"
	if [ "$SYSTEM" = "Darwin" ]; then
	COMMAND="${DIR}TimedExec.sh $ULIMIT $PWD $COMMAND"
	fi

	if [ "x$RHOST" = x ] ; then
	( sh -c "$ULIMITCMD time -p sh -c '$COMMAND >$OUTFILE 2>&1 < $INFILE; echo exit \$?'" ) 2>&1 \
	\| awk -- '\
	BEGIN { cpu = 0.0; }
	/^user/ { cpu += $2; print; }
	/^sys/ { cpu += $2; print; }
	!/^user/ && !/^sys/ { print; }
	END { printf("program %f\n", cpu); }' > $OUTFILE.time
	else
	rm -f "$PWD/${PROG}.command"
	rm -f "$PWD/${PROG}.remote"
	rm -f "$PWD/${PROG}.remote.time"
	echo "$ULIMITCMD cd $PWD; (time -p ($COMMAND > $PWD/${OUTFILE}.remote 2>&1 < $INFILE;); echo exit $?) > $PWD/${OUTFILE}.remote.time 2>&1" > "$PWD/${PROG}.command"
	chmod +x "$PWD/${PROG}.command"

	( $RCLIENT -l $RUSER $RHOST $RPORT "ls $PWD/${PROG}.command" ) > /dev/null 2>&1
	( $RCLIENT -l $RUSER $RHOST $RPORT "$PWD/${PROG}.command" )
	cat $PWD/${OUTFILE}.remote.time \| awk -- '\
	BEGIN { cpu = 0.0; }
	/^user/ { cpu += $2; print; }
	/^sys/ { cpu += $2; print; }
	!/^user/ && !/^sys/ { print; }
	END { printf("program %f\n", cpu); }' > $OUTFILE.time
	sleep 1
	cp -f $PWD/${OUTFILE}.remote ${OUTFILE}
	rm -f $PWD/${OUTFILE}.remote
	rm -f $PWD/${OUTFILE}.remote.time
	fi

	exitval=`grep '^exit ' $OUTFILE.time \| sed -e 's/^exit //'`
	fail=yes
	if [ -z "$exitval" ] ; then
	exitval=99
	echo "TEST $PROGRAM FAILED: CAN'T GET EXIT CODE!"
	elif test "$exitval" -eq 126 ; then
	echo "TEST $PROGRAM FAILED: command not executable (exit status 126)!"
	elif test "$exitval" -eq 127 ; then
	echo "TEST $PROGRAM FAILED: command not found (exit status 127)!"
	elif test "$exitval" -eq 128 ; then
	# Exit status 128 doesn't have a standard meaning, but it's unlikely
	# to be expected program behavior.
	echo "TEST $PROGRAM FAILED: exit status 128!"
	elif test "$exitval" -gt 128 ; then
	echo "TEST $PROGRAM FAILED: process terminated by signal (exit status $exitval)!"
	elif [ "$EXITOK" -ne 0 -a "$exitval" -ne 0 ] ; then
	echo "TEST $PROGRAM FAILED: EXIT != 0"
	else
	fail=no
	fi
	echo "exit $exitval" >> $OUTFILE

	# If we detected a failure, print the name of the test executable to the
	# output file. This will cause it to compare as different with other runs
	# of the same test even if they fail in the same way, because they'll have
	# different command names.
	if [ "${fail}" != "no" ]; then
	echo "RunSafely.sh detected a failure with these command-line arguments: " \
	"$ORIG_ARGS" >> $OUTFILE
	fi

	if ls \| egrep "^core" > /dev/null
	then
	# If we are on a sun4u machine (UltraSparc), then the code we're generating
	# is 64 bit code. In that case, use gdb-64 instead of gdb.
	myarch=`uname -m`
	if [ "$myarch" = "sun4u" ]
	then
	GDB="gdb-64"
	else
	GDB=gdb
	fi

	corefile=`ls core* \| head -n 1`
	echo "where 100" > StackTrace.$$
	$GDB -q -batch --command=StackTrace.$$ --core=$corefile $PROGRAM < /dev/null
	rm -f StackTrace.$$ $corefile
	fi
	# Always return "successful" so that tests will continue to be run.
	exit 0