Provided by: perf-tools-unstable_0.0.1~20150130+git85414b0-1_all bug

NAME

       iosnoop - trace block I/O events as they occur. Uses Linux ftrace.

SYNOPSIS

       iosnoop [-hQst] [-d device] [-i iotype] [-p pid] [-n name] [duration]

DESCRIPTION

       iosnoop  prints  block  device I/O events as they happen, with useful details such as PID,
       device, I/O type, block number, I/O size, and latency.

       This traces disk I/O at the block device interface, using the block: tracepoints. This can
       help  characterize  the  I/O  requested  for  the  storage  devices  and  their  resulting
       performance. I/O completions can also be studied event-by-event  for  debugging  disk  and
       controller I/O scheduling issues.

       NOTE:  Use  of a duration buffers I/O, which reduces overheads, but this also introduces a
       limit to the number of I/O that will be captured. See the duration section in OPTIONS.

       Since this uses ftrace, only the root user can use this tool.

REQUIREMENTS

       FTRACE  CONFIG,  and  the  tracepoints  block:block_rq_insert,  block:block_rq_issue,  and
       block:block_rq_complete,  which you may already have enabled and available on recent Linux
       kernels. And awk.

OPTIONS

       -d device
              Only show I/O issued by this device. (eg, "202,1"). This matches the DEV column  in
              the iosnoop output, and is filtered in-kernel.

       -i iotype
              Only  show  I/O  issued that matches this I/O type. This matches the TYPE column in
              the iosnoop output, and wildcards ("*") can be used at the beginning or end (only).
              Eg, "*R*" matches all reads. This is filtered in-kernel.

       -p PID Only  show  I/O  issued  by  this PID. This filters in-kernel. Note that I/O may be
              issued indirectly; for example, as the result of a memory allocation, causing dirty
              buffers (maybe from another PID) to be written to storage.

              With  the  -Q  option,  the  identified  PID  is  more accurate, however, LATms now
              includes queueing time (see the -Q option).

       -n name
              Only show I/O issued by processes with  this  name.  Partial  strings  and  regular
              expressions  are  allowed.  This  is  a  post-filter, so all I/O is traced and then
              filtered in user space. As with PID, this includes indirectly issued  I/O,  and  -Q
              can be used to improve accuracy (see the -Q option).

       -h     Print usage message.

       -Q     Use  block  I/O  queue  insertion  as the start tracepoint (block:block_rq_insert),
              instead of  block  I/O  issue  (block:block_rq_issue).  This  makes  the  following
              changes: COMM and PID are more likely to identify the origin process, as are -p PID
              and -n name; STARTs shows queue insert; and LATms shows  I/O  time  including  time
              spent on the block I/O queue.

       -s     Include a column for the start time (issue time) of the I/O, in seconds.  If the -Q
              option is used, this is the time the I/O is inserted on the block I/O queue.

       -t     Include a column for the completion time of the I/O, in seconds.

       duration
              Set the duration of tracing, in seconds. Trace output will be buffered and  printed
              at the end. This also reduces overheads by buffering in-kernel, instead of printing
              events as they occur.

              The     ftrace     buffer     has     a      fixed      size      per-CPU      (see
              /sys/kernel/debug/tracing/buffer_size_kb).  If  you  think  events are missing, try
              increasing that size (the bufsize_kb setting in iosnoop). With the default  setting
              (4 Mbytes), I'd expect this to happen around 50k I/O.

EXAMPLES

       Default output, print I/O activity as it occurs:
              # iosnoop

       Buffer for 5 seconds (lower overhead) and write to a file:
              # iosnoop 5 > outfile

       Trace based on block I/O queue insertion, showing queueing time:
              # iosnoop -Q

       Trace reads only:
              # iosnoop -i '*R*'

       Trace I/O issued to device 202,1 only:
              # iosnoop -d 202,1

       Include I/O start and completion timestamps:
              # iosnoop -ts

       Include I/O queueing and completion timestamps:
              # iosnop -Qts

       Trace I/O issued when PID 181 was on-CPU only:
              # iosnoop -p 181

       Trace I/O queued when PID 181 was on-CPU (more accurate), and include queue time:
              # iosnoop -Qp 181

FIELDS

       COMM   Process  name  (command)  for  the  PID that was on-CPU when the I/O was issued, or
              inserted if -Q is used. See PID. This column is truncated to 12 characters.

       PID    Process ID which was on-CPU when the I/O was issued, or inserted  if  -Q  is  used.
              This  will  usually  be  the  process directly requesting I/O, however, it may also
              include indirect I/O. For example, a memory allocation by  this  PID  which  causes
              dirty memory from another PID to be flushed to disk.

       TYPE   Type  of  I/O.  R=read,  W=write,  M=metadata,  S=sync, A=readahead, F=flush or FUA
              (force unit access), D=discard, E=secure, N=null (not RWFD).

       DEV    Storage device ID.

       BLOCK  Disk block for the operation (location, relative to this device).

       BYTES  Size of the I/O, in bytes.

       LATms  Latency (time) for the I/O, in milliseconds.

OVERHEAD

       By default, iosnoop works without buffering, printing I/O  events  as  they  happen  (uses
       trace_pipe),  context  switching  and  consuming  CPU  to do so. This has a limit of about
       10,000 IOPS (depending on your platform), at which point iosnoop will be consuming 1  CPU.
       The  duration  mode  uses  buffering,  and can handle much higher IOPS rates, however, the
       buffer has a limit of about 50,000 I/O, after which events will be dropped. You  can  tune
       this  with bufsize_kb, which is per-CPU. Also note that the "-n" option is currently post-
       filtered, so all events are traced.

       The overhead may be acceptable  in  many  situations.  If  it  isn't,  this  tool  can  be
       reimplemented in C, or using a different tracer (eg, perf_events, SystemTap, ktap.)

SOURCE

       This is from the perf-tools collection.

              https://github.com/brendangregg/perf-tools

       Also  look  under the examples directory for a text file containing example usage, output,
       and commentary for this tool.

OS

       Linux

STABILITY

       Unstable - in development.

AUTHOR

       Brendan Gregg

SEE ALSO

       iolatency(8), iostat(1)