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Current File : //compat/linux/proc/self/root/usr/sbin/dtruss |
#!/bin/sh # # dtruss - print process system call time details. # Written using DTrace (Solaris 10 3/05). # # $Id: dtruss 9 2007-08-07 10:21:07Z brendan $ # # USAGE: dtruss [-acdeflhoLs] [-t syscall] { -p PID | -n name | command } # # -p PID # examine this PID # -n name # examine this process name # -t syscall # examine this syscall only # -a # print all details # -c # print system call counts # -d # print relative timestamps (us) # -e # print elapsed times (us) # -f # follow children as they are forked # -l # force printing of pid/lwpid per line # -o # print on cpu times (us) # -s # print stack backtraces # -L # don't print pid/lwpid per line # -b bufsize # dynamic variable buf size (default is "4m") # eg, # dtruss df -h # run and examine the "df -h" command # dtruss -p 1871 # examine PID 1871 # dtruss -n tar # examine all processes called "tar" # dtruss -f test.sh # run test.sh and follow children # # See the man page dtruss(1M) for further details. # # SEE ALSO: procsystime # DTraceToolkit # dapptrace # DTraceToolkit # truss # # COPYRIGHT: Copyright (c) 2005, 2006, 2007 Brendan Gregg. # # CDDL HEADER START # # The contents of this file are subject to the terms of the # Common Development and Distribution License, Version 1.0 only # (the "License"). You may not use this file except in compliance # with the License. # # You can obtain a copy of the license at Docs/cddl1.txt # or http://www.opensolaris.org/os/licensing. # See the License for the specific language governing permissions # and limitations under the License. # # CDDL HEADER END # # TODO: Track signals, more output formatting. # # 29-Apr-2005 Brendan Gregg Created this. # 09-May-2005 " " Fixed evaltime (thanks Adam L.) # 16-May-2005 " " Added -t syscall tracing. # 17-Jun-2005 " " Added -s stack backtraces. # 17-Jun-2005 " " Last update. # 29-Jun-2007 " " Used progenyof() (thanks Aaron Gutman). # 06-Aug-2007 " " Various updates. # ############################## # --- Process Arguments --- # ### Default variables opt_pid=0; opt_name=0; pid=0; pname="."; opt_elapsed=0; opt_cpu=0 opt_counts=0; opt_relative=0; opt_printid=0; opt_follow=0; opt_command=0 command=""; opt_buf=0; buf="4m"; opt_trace=0; trace="."; opt_stack=0 ### Process options while getopts ab:cdefhln:op:st:L name do case $name in b) opt_buf=1; buf=$OPTARG ;; p) opt_pid=1; pid=$OPTARG ;; n) opt_name=1; pname=$OPTARG ;; t) opt_trace=1; trace=$OPTARG ;; a) opt_counts=1; opt_relative=1; opt_elapsed=1; opt_follow=1 opt_printid=1; opt_cpu=1 ;; c) opt_counts=1 ;; d) opt_relative=1 ;; e) opt_elapsed=1 ;; f) opt_follow=1 ;; l) opt_printid=1 ;; o) opt_cpu=1 ;; L) opt_printid=-1 ;; s) opt_stack=-1 ;; h|?) cat <<-END >&2 USAGE: dtruss [-acdefholLs] [-t syscall] { -p PID | -n name | command } -p PID # examine this PID -n name # examine this process name -t syscall # examine this syscall only -a # print all details -c # print syscall counts -d # print relative times (us) -e # print elapsed times (us) -f # follow children (-p or cmd only) -l # force printing pid/lwpid -o # print on cpu times -s # print stack backtraces -L # don't print pid/lwpid -b bufsize # dynamic variable buf size eg, dtruss df -h # run and examine "df -h" dtruss -p 1871 # examine PID 1871 dtruss -n tar # examine all processes called "tar" dtruss -f test.sh # run test.sh and follow children END exit 1 esac done shift `expr $OPTIND - 1` ### Option logic if [ $opt_pid -eq 0 -a $opt_name -eq 0 ]; then opt_command=1 if [ "$*" = "" ]; then $0 -h exit fi command="$*" # yes, I meant $*! fi if [ $opt_follow -eq 1 -o $opt_name -eq 1 ]; then if [ $opt_printid -ne -1 ]; then opt_printid=1 else opt_printid=0 fi fi if [ $opt_follow -eq 1 -a $opt_name -eq 1 ]; then echo "ERROR: -f option cannot be used with -n (use -p or cmd instead)." exit 1 fi ### Option translation if [ "$trace" = "exec" ]; then trace="exece"; fi if [ "$trace" = "time" ]; then trace="gtime"; fi if [ "$trace" = "exit" ]; then trace="rexit"; fi ################################# # --- Main Program, DTrace --- # ### Define D Script dtrace=' #pragma D option quiet #pragma D option switchrate=10 /* * Command line arguments */ inline int OPT_command = '$opt_command'; inline int OPT_follow = '$opt_follow'; inline int OPT_printid = '$opt_printid'; inline int OPT_relative = '$opt_relative'; inline int OPT_elapsed = '$opt_elapsed'; inline int OPT_cpu = '$opt_cpu'; inline int OPT_counts = '$opt_counts'; inline int OPT_pid = '$opt_pid'; inline int OPT_name = '$opt_name'; inline int OPT_trace = '$opt_trace'; inline int OPT_stack = '$opt_stack'; inline string NAME = "'$pname'"; inline string TRACE = "'$trace'"; dtrace:::BEGIN { /* print header */ OPT_printid ? printf("%-9s ", "PID/LWP") : 1; OPT_relative ? printf("%8s ", "RELATIVE") : 1; OPT_elapsed ? printf("%7s ", "ELAPSD") : 1; OPT_cpu ? printf("%6s ", "CPU") : 1; printf("SYSCALL(args) \t\t = return\n"); } /* * Save syscall entry info */ syscall:::entry /((OPT_command || OPT_pid) && pid == $target) || (OPT_name && execname == NAME) || (OPT_follow && progenyof($target))/ { /* set start details */ self->start = timestamp; self->vstart = vtimestamp; self->arg0 = arg0; self->arg1 = arg1; self->arg2 = arg2; /* count occurances */ OPT_counts == 1 ? @Counts[probefunc] = count() : 1; } /* * Follow children */ syscall::fork*:return /(OPT_follow && progenyof($target)) && (!OPT_trace || (TRACE == probefunc))/ { /* print output */ self->code = errno == 0 ? "" : "Err#"; OPT_printid ? printf("%6d/%d: ", pid, tid) : 1; OPT_relative ? printf("%8d: ", vtimestamp/1000) : 1; OPT_elapsed ? printf("%7d: ", 0) : 1; OPT_cpu ? printf("%6d ", 0) : 1; printf("%s(0x%X, 0x%X, 0x%X)\t\t = %d %s%d\n", probefunc, self->arg0, self->arg1, self->arg2, (int)arg0, self->code, (int)errno); } /* * Check for syscall tracing */ syscall:::entry /OPT_trace && probefunc != TRACE/ { /* drop info */ self->start = 0; self->vstart = 0; self->arg0 = 0; self->arg1 = 0; self->arg2 = 0; } /* * Print return data */ /* * The following code is written in an intentionally repetative way. * The first versions had no code redundancies, but performed badly during * benchmarking. The priority here is speed, not cleverness. I know there * are many obvious shortcuts to this code, I have tried them. This style has * shown in benchmarks to be the fastest (fewest probes fired, fewest actions). */ /* print 3 args, return as hex */ syscall::sigprocmask:return /self->start/ { /* calculate elapsed time */ this->elapsed = timestamp - self->start; self->start = 0; this->cpu = vtimestamp - self->vstart; self->vstart = 0; self->code = errno == 0 ? "" : "Err#"; /* print optional fields */ OPT_printid ? printf("%6d/%d: ", pid, tid) : 1; OPT_relative ? printf("%8d ", vtimestamp/1000) : 1; OPT_elapsed ? printf("%7d ", this->elapsed/1000) : 1; OPT_cpu ? printf("%6d ", this->cpu/1000) : 1; /* print main data */ printf("%s(0x%X, 0x%X, 0x%X)\t\t = 0x%X %s%d\n", probefunc, (int)self->arg0, self->arg1, self->arg2, (int)arg0, self->code, (int)errno); OPT_stack ? ustack() : 1; OPT_stack ? trace("\n") : 1; self->arg0 = 0; self->arg1 = 0; self->arg2 = 0; } /* print 3 args, arg0 as a string */ syscall::access*:return, syscall::stat*:return, syscall::lstat*:return, syscall::readlink*:return, syscall::open*:return /self->start/ { /* calculate elapsed time */ this->elapsed = timestamp - self->start; self->start = 0; this->cpu = vtimestamp - self->vstart; self->vstart = 0; self->code = errno == 0 ? "" : "Err#"; /* print optional fields */ OPT_printid ? printf("%6d/%d: ", pid, tid) : 1; OPT_relative ? printf("%8d ", vtimestamp/1000) : 1; OPT_elapsed ? printf("%7d ", this->elapsed/1000) : 1; OPT_cpu ? printf("%6d ", this->cpu/1000) : 1; /* print main data */ printf("%s(\"%S\", 0x%X, 0x%X)\t\t = %d %s%d\n", probefunc, copyinstr(self->arg0), self->arg1, self->arg2, (int)arg0, self->code, (int)errno); OPT_stack ? ustack() : 1; OPT_stack ? trace("\n") : 1; self->arg0 = 0; self->arg1 = 0; self->arg2 = 0; } /* print 3 args, arg1 as a string */ syscall::write:return, syscall::pwrite:return, syscall::*read*:return /self->start/ { /* calculate elapsed time */ this->elapsed = timestamp - self->start; self->start = 0; this->cpu = vtimestamp - self->vstart; self->vstart = 0; self->code = errno == 0 ? "" : "Err#"; /* print optional fields */ OPT_printid ? printf("%6d/%d: ", pid, tid) : 1; OPT_relative ? printf("%8d ", vtimestamp/1000) : 1; OPT_elapsed ? printf("%7d ", this->elapsed/1000) : 1; OPT_cpu ? printf("%6d ", this->cpu/1000) : 1; /* print main data */ printf("%s(0x%X, \"%S\", 0x%X)\t\t = %d %s%d\n", probefunc, self->arg0, stringof(copyin(self->arg1, self->arg2)), self->arg2, (int)arg0, self->code, (int)errno); OPT_stack ? ustack() : 1; OPT_stack ? trace("\n") : 1; self->arg0 = 0; self->arg1 = 0; self->arg2 = 0; } /* print 0 arg output */ syscall::*fork*:return /self->start/ { /* calculate elapsed time */ this->elapsed = timestamp - self->start; self->start = 0; this->cpu = vtimestamp - self->vstart; self->vstart = 0; self->code = errno == 0 ? "" : "Err#"; /* print optional fields */ OPT_printid ? printf("%6d/%d: ", pid, tid) : 1; OPT_relative ? printf("%8d ", vtimestamp/1000) : 1; OPT_elapsed ? printf("%7d ", this->elapsed/1000) : 1; OPT_cpu ? printf("%6d ", this->cpu/1000) : 1; /* print main data */ printf("%s()\t\t = %d %s%d\n", probefunc, (int)arg0, self->code, (int)errno); OPT_stack ? ustack() : 1; OPT_stack ? trace("\n") : 1; self->arg0 = 0; self->arg1 = 0; self->arg2 = 0; } /* print 1 arg output */ syscall::close:return /self->start/ { /* calculate elapsed time */ this->elapsed = timestamp - self->start; self->start = 0; this->cpu = vtimestamp - self->vstart; self->vstart = 0; self->code = errno == 0 ? "" : "Err#"; /* print optional fields */ OPT_printid ? printf("%6d/%d: ", pid, tid) : 1; OPT_relative ? printf("%8d ", vtimestamp/1000) : 1; OPT_elapsed ? printf("%7d ", this->elapsed/1000) : 1; OPT_cpu ? printf("%6d ", this->cpu/1000) : 1; /* print main data */ printf("%s(0x%X)\t\t = %d %s%d\n", probefunc, self->arg0, (int)arg0, self->code, (int)errno); OPT_stack ? ustack() : 1; OPT_stack ? trace("\n") : 1; self->arg0 = 0; self->arg1 = 0; self->arg2 = 0; } /* print 2 arg output */ syscall::utimes:return, syscall::munmap:return /self->start/ { /* calculate elapsed time */ this->elapsed = timestamp - self->start; self->start = 0; this->cpu = vtimestamp - self->vstart; self->vstart = 0; self->code = errno == 0 ? "" : "Err#"; /* print optional fields */ OPT_printid ? printf("%6d/%d: ", pid, tid) : 1; OPT_relative ? printf("%8d ", vtimestamp/1000) : 1; OPT_elapsed ? printf("%7d ", this->elapsed/1000) : 1; OPT_cpu ? printf("%6d ", this->cpu/1000) : 1; /* print main data */ printf("%s(0x%X, 0x%X)\t\t = %d %s%d\n", probefunc, self->arg0, self->arg1, (int)arg0, self->code, (int)errno); OPT_stack ? ustack() : 1; OPT_stack ? trace("\n") : 1; self->arg0 = 0; self->arg1 = 0; self->arg2 = 0; } /* print 3 arg output - default */ syscall:::return /self->start/ { /* calculate elapsed time */ this->elapsed = timestamp - self->start; self->start = 0; this->cpu = vtimestamp - self->vstart; self->vstart = 0; self->code = errno == 0 ? "" : "Err#"; /* print optional fields */ OPT_printid ? printf("%6d/%d: ", pid, tid) : 1; OPT_relative ? printf("%8d ", vtimestamp/1000) : 1; OPT_elapsed ? printf("%7d ", this->elapsed/1000) : 1; OPT_cpu ? printf("%6d ", this->cpu/1000) : 1; /* print main data */ printf("%s(0x%X, 0x%X, 0x%X)\t\t = %d %s%d\n", probefunc, self->arg0, self->arg1, self->arg2, (int)arg0, self->code, (int)errno); OPT_stack ? ustack() : 1; OPT_stack ? trace("\n") : 1; self->arg0 = 0; self->arg1 = 0; self->arg2 = 0; } /* program exited */ proc:::exit /(OPT_command || OPT_pid) && pid == $target/ { exit(0); } /* print counts */ dtrace:::END { OPT_counts == 1 ? printf("\n%-32s %16s\n", "CALL", "COUNT") : 1; OPT_counts == 1 ? printa("%-32s %@16d\n", @Counts) : 1; } ' ### Run DTrace if [ $opt_command -eq 1 ]; then /usr/sbin/dtrace -x dynvarsize=$buf -x evaltime=exec -n "$dtrace" \ -c "$command" >&2 elif [ $opt_pid -eq 1 ]; then /usr/sbin/dtrace -x dynvarsize=$buf -n "$dtrace" -p "$pid" >&2 else /usr/sbin/dtrace -x dynvarsize=$buf -n "$dtrace" >&2 fi