Provided by: atop_2.10.0-3_amd64 bug

NAME

       atop - Advanced System & Process Monitor

SYNOPSIS

       Live measurement in bar graph mode:

         atop -B[H] [interval [samples]]

       Live measurement in text mode:

           atop   [-g|-m|-d|-n|-u|-p|-s|-c|-v|-o|-y|-Y]   [-C|-M|-D|-N|-A]   [-fFG1xR]  [interval
       [samples]]

       Live generation of parsable output (white-space separated or JSON):

         atop [-Plabel[,label]... [-Z]] [-Jlabel[,label]...] [interval [samples]]

       Write raw log files:

         atop -w rawfile [-a] [-S] [interval [samples]]

       Analyze raw log files in bar graph mode:

         atop -B[H]r [rawfile|yyy...] [-b [YYYYMMDD]hhmm[ss]] [-e [YYYYMMDD]hhmm[ss]]

       Analyze raw log files in text mode:

           atop   -r   [rawfile|yyy...]   [-b   [YYYYMMDD]hhmm[ss]]    [-e    [YYYYMMDD]hhmm[ss]]
       [-g|-m|-d|-n|-u|-p|-s|-c|-v|-o|-y|-Y] [-C|-M|-D|-N|-A] [-fFG1xR]

       Generate parsable output from raw log files (white-space separated or JSON):

            atop    -r   [rawfile|yyy...]   [-b   [YYYYMMDD]hhmm[ss]]   [-e   [YYYYMMDD]hhmm[ss]]
       [-Plabel[,label]... [-Z]] [-Jlabel[,label]...]

DESCRIPTION

       The program atop is an interactive monitor to view the load  on  a  Linux  system.   Every
       interval  seconds  (default:  10  seconds)  information  is  gathered  about  the resource
       occupation on system level of the most critical hardware  resources  (from  a  performance
       point  of  view), i.e. CPUs, memory, disks and network interfaces. Besides, information is
       gathered about the processes (or threads) that are responsible for the utilization of  the
       CPUs,  memory  and  disks.  Network load per process is shown only when the netatop kernel
       module or the netatop-bpf BPF module has been installed.

BAR GRAPH MODE

       When running atop you can choose to view the system load in bar  graph  mode  or  in  text
       mode.   In  bar  graph  mode  the  resource utilization of CPUs, memory, disks and network
       interfaces is shown via (character-based) bar graphs, but only on system level.  When  you
       want  to  view  more  detailed  information  on  system level or when you want to view the
       resource consumption on process or thread level, you can switch to text mode  by  pressing
       the  'B'  key.  Alternatively, you can use the 'B' key (again) to switch from text mode to
       bar graph mode.
       By default, atop starts in text mode unless the -B flag is used or  unless  'B'  has  been
       configured  as  a  default flag in the .atoprc file (for further information about default
       flags, refer to the atoprc man page).

       In bar graph mode the terminal will be subdivided into four character-based windows,  i.e.
       one window for each hardware resource:

       Processors
            The  first bar shows the average busy percentage of all CPUs with the bar label 'Avg'
            (might be abbreviated to 'Av' or even just 'A').  The subsequent bars show  the  busy
            percentages of single CPUs.
            When  there  is not enough horizontal space to show all CPUs, only the most busy CPUs
            per sample will be shown after the width of each bar has been reduced to a minimum.

            By default, the categories of CPU consumption are shown by different  colors  in  the
            bars,  marked  with  a  character  'S' (system mode), 'U' (user mode), 'I' (interrupt
            handling), 's' (steal) and 'G' (guest, i.e. consumed by virtual machines).
            The top of the bar might consist  of  an  unmarked  color  representing  a  'neutral'
            category. Suppose that the scale unit is 5% per line and the total busy percentage is
            54% consisting of two categories of 27%.  The two categories will be rounded  to  25%
            (5  lines  of 5% each) but the total busy percentage will be rounded to 55% (11 lines
            of 5%).  Then the top line will represent a 'neutral' category.
            By pressing the 'H' key or by starting atop with the '-H'  flag,  no  categories  are
            shown.

            A red line is drawn in the bar graph as critical threshold.  By default this value is
            90% and can be modified by the 'cpucritperc' option in the  configuration  file  (see
            separate  atoprc man page). When this value is set to zero, no threshold line will be
            drawn.

       Memory and swap space
            Memory is  presented  as  a  column  in  which  the  specific  categories  of  memory
            consumption   are   shown.   These   categories   are  (code,  data  and   stack  of)
            processes/kernel, slab caches (i.e.  dynamically  allocated  kernel  memory),  shared
            memory, tmpfs, static huge pages, page cache and free memory.
            Swap  space  (if  present)  is  also  presented  as  a column in which the categories
            processes/tmpfs, shared memory and free space are shown.

            At the right side memory-related event counters are shown.
            The bottom three counters are colored green when there is no memory  pressure.   When
            considerable  activity  is noticed such counter might be colored orange and with high
            activity red.
            When memory pressure starts, usually memory page scanning will  be  activated  first.
            When pressure increases, memory pages of processes might be swapped out to swap space
            (if present).
            The 'oomkills' counter (Out Of Memory killing)  is  most  serious:  it  reflects  the
            number  of processes that are killed due to lack of memory (and swap). Therefore this
            counter shows the absolute number (not per second) of processes being  killed  during
            the last interval and will immediately be colored red when it is 1 or more.  Besides,
            after atop has noticed OOM killing the 'oomkills' counter remains orange for the next
            15 minutes, just in case that you have missed the OOM killing event itself.
            When  there  is  enough vertical space in the memory window, event counters are shown
            about the number of memory pages being swapped in, the number of memory  pages  paged
            out to block devices and the number of memory pages paged in from block devices.

            Memory  and  swap  space  consumption  will  preferably be shown in a character-based
            window that vertically uses the entire screen for optimal granularity. However,  when
            there  are  a  lot  of  disks  and/or  network  interfaces  the memory and swap space
            consumption will be shown in a character-based window that only uses the  upper  half
            of the screen.

       Disks
            For each disk the busy percentage is shown as a bar.
            When there is not enough horizontal space to show all disks, only the most busy disks
            per sample will be shown.

            By default, categories of disk consumption are shown by different colors in the bars,
            marked with a character 'R' (read) and 'W' (write).
            The  top  of  the  bar  might  consist  of an unmarked color representing a 'neutral'
            category. Suppose that the scale unit is 5% per line and the total busy percentage is
            54%  consisting  of two categories of 27%.  The two categories will be rounded to 25%
            (5 lines of 5% each) but the total busy percentage will be rounded to 55%  (11  lines
            of 5%).  Then the top line will represent a 'neutral' category.
            By  pressing  the  'H'  key or by starting atop with the '-H' flag, no categories are
            shown.

            A red line is drawn in the bar graph as critical threshold.  By default this value is
            90%  and  can  be modified by the 'dskcritperc' option in the configuration file (see
            separate atoprc man page). When this value is set to zero, no threshold line will  be
            drawn.

       Interfaces
            For  each  non-virtual network interface a double bar graph is shown with a dedicated
            scale that reflects the traffic rate. One of the bars shows the transmit rate  ('TX')
            and  the  other  bar  the  receive  rate  ('RX').   The traffic scale of each network
            interface remains at its highest level.  All interface scales can be reset during the
            measurement by pressing the 'L' key.

            Most  often  the  real  speed (maximum bandwidth) of network interfaces is not known,
            e.g. in case of the network interfaces of virtual  machines.   Therefore  it  is  not
            possible  to  show  the interface utilization as a percentage. However, when the real
            speed of an interface is known it will be shown underneath the concerning bar graph.

            When there is not enough horizontal space to show all network  interfaces,  only  the
            most busy interfaces per sample will be shown.

       Usually  the  bar  graphs  will  not  be  sorted  on  busy percentage when there is enough
       horizontal space. However, after switching from text mode to bar graph mode the bar graphs
       might have been sorted because this was needed for the presentation in text mode. The next
       interval in bar graph mode shows the bars  unsorted  again  unless  the  window  width  is
       unsufficient for all bars.

       The  remaining  part  of  this  manual page mainly describes the information shown in text
       mode.  When certain descriptions also apply  to  bar  graph  mode  it  will  be  mentioned
       explicitly.

TEXT MODE IN GENERAL

       The  initial  screen  in  text  mode shows if atop runs with restricted view (unprivileged
       user) or unrestricted view (privileged user).  In case of restricted view  atop  does  not
       have  the  privileges  (no  root  identity nor the necessary capabilities) to retrieve all
       counter values on system level and on process level.

       With every interval information is shown about the resource  occupation  on  system  level
       (CPU,  memory,  disks and network layers), followed by a list of processes which have been
       active during the last interval.  Notice that all processes that were unchanged during the
       last  interval  are  not  shown,  unless the key 'a' has been pressed or unless sorting on
       memory occupation is done (then inactive processes are relevant as well).  If the list  of
       active  processes  does  not entirely fit on the screen, only the top of the list is shown
       (sorted in order of activity).
       The intervals are repeated till the number of samples (specified as command  argument)  is
       reached, or till the key 'q' is pressed in interactive mode.

       When  atop  is  started,  it  checks whether the standard output channel is connected to a
       screen, or to a file/pipe. In the first case it produces screen  control  codes  (via  the
       ncurses  library)  and  behaves  interactively;  in  the second case it produces flat text
       output.

       In interactive mode, the output of atop scales dynamically to the  current  dimensions  of
       the screen/window.
       If the window is resized horizontally, columns will be added or removed automatically. For
       this purpose, every column has a particular weight. The columns with the  highest  weights
       that fit within the current width will be shown.
       If  the  window  is  resized vertically, lines of the process/thread list will be added or
       removed automatically.

       In interactive mode the output of atop can be  controlled  by  pressing  particular  keys.
       However  it is also possible to specify such key as flag on the command line. In that case
       atop switches to the indicated mode  on  beforehand.  This  mode  can  be  modified  again
       interactively.  Specifying  such  key  as flag is especially useful when running atop with
       output to a pipe or file (non-interactively).  These flags are the same as the  keys  that
       can be pressed in interactive mode (see section INTERACTIVE COMMANDS).
       Additional  flags are available to support storage of atop-data in raw format (see section
       RAW DATA STORAGE).

PROCESS ACCOUNTING

       With every interval, atop reads the kernel administration to obtain information about  all
       running  processes.   However,  it  is  likely  that  processes have terminated during the
       interval.  These processes might have  consumed  system  resources  during  this  interval
       before they terminated.  Therefore, atop tries to read the process accounting records that
       contain the accounting information of terminated processes and report these processes too.
       Only  when  the process accounting mechanism in the kernel is activated, the kernel writes
       such process accounting record to a file for every process that terminates.

       There are various ways for atop to get access to the process accounting records (tried  in
       this order):

       1.  When  the  environment  variable ATOPACCT is set, it specifies the name of the process
           accounting file.  In that case, process accounting for  this  file  should  have  been
           activated  on  beforehand.   Before opening this file for reading, atop drops its root
           privileges (if any).
           When this  environment  variable  is  present  but  its  contents  is  empty,  process
           accounting will not be used at all.

       2.  This is the preferred way of handling process accounting records!
           When the atopacctd daemon is active, it has activated the process accounting mechanism
           in the kernel and transfers to original accounting records to shadow files.   In  that
           case, atop drops its root privileges and opens the current shadow file for reading.
           This way is preferred, because the atopacctd daemon maintains full control of the size
           of the original process accounting file written by the kernel  and  the  shadow  files
           read by the atop process(es).

           The  atopacct  service  will  be  activated  before the atop service to enable atop to
           detect that process accounting is managed  by  the  atopacctd  daemon.  As  a  forking
           service,  atopacctd  takes  care that all directories and files are initialized before
           the parent process dies. The child process continues as the daemon process.

           For further information, refer to the atopacctd man page.

       3.  When the atopacctd daemon is not active,  atop  verifies  if  the  process  accounting
           mechanism  has  been  switched on via the separate psacct or acct package (the package
           name depends on the Linux distro). In that case,  one  of  the  files  /var/log/pacct,
           /var/account/pacct  or /var/log/account/pacct is in use as process accounting file and
           atop opens this file for reading.

       4.  As a last possibility, atop itself tries to activate the process accounting  mechanism
           (requires  root  privileges) using the file /var/cache/atop.d/atop.acct (to be written
           by the kernel, to be read by atop itself). Process accounting remains active  as  long
           as  at  least one atop process is alive.  Whenever the last atop process stops (either
           by pressing 'q' or by 'kill -15'), it deactivates  the  process  accounting  mechanism
           again.  Therefore you should never terminate atop by 'kill -9', because then it has no
           chance to stop process accounting.  As a result, the accounting file may consume a lot
           of disk space after a while.
           To  avoid that the process accounting file consumes too much disk space, atop verifies
           at the end of every sample if the size of the process accounting file exceeds 200  MiB
           and  if  this  atop process is the only one that is currently using the file.  In that
           case the file is truncated to a size of zero.

           Notice that root-privileges are required to switch on/off process  accounting  in  the
           kernel.  You  can  start  atop as a root user or specify setuid-root privileges to the
           executable file.  In the latter case, atop switches on process  accounting  and  drops
           the root-privileges again.
           If atop does not run with root-privileges, it does not show information about finished
           processes.  It indicates this situation with the message 'no  procacct'  in  the  top-
           right corner (instead of the counter that shows the number of exited processes).

       When during one interval a lot of processes have finished, atop might grow tremendously in
       memory when reading all process accounting records at the end of the  interval.  To  avoid
       such  excessive growth atop will never read more than 50 MiB with process information from
       the  process  accounting  file  per  interval  (approx.  54000  finished  processes).   In
       interactive mode a warning is given whenever processes have been skipped for this reason.

COLORS

       For  the  resource  consumption on system level, atop uses colors in text mode to indicate
       that a critical occupation percentage has been (almost) reached.   A  critical  occupation
       percentage  means  that  is likely that this load causes a noticeable negative performance
       influence for applications using this resource. The critical  percentage  depends  on  the
       type  of  resource: e.g. the performance influence of a disk with a busy percentage of 80%
       might be more noticeable for applications/users than a CPU with a busy percentage of 90%.
       Currently atop uses the following default values to calculate a  weighted  percentage  per
       resource:

        Processor
            A busy percentage of 90% or higher is considered 'critical' (also in bar graph mode).

        Disk
            A busy percentage of 90% or higher is considered 'critical'.

        Network
            A  busy  percentage  of  90%  or  higher  for  the load of an interface is considered
            'critical'.

        Memory
            An  occupation  percentage  of  90%  is  considered  'critical'.   Notice  that  this
            occupation  percentage is the accumulated memory consumption of the kernel (including
            slab) and all processes. The memory for the page cache ('cache'  and  'buff'  in  the
            MEM-line) and the reclaimable part of the slab ('slrec') is not implied!
            If  the  number  of pages swapped out ('swout' in the PAG-line) is larger than 10 per
            second, the memory resource is considered 'critical'.  A value  of  at  least  1  per
            second is considered 'almost critical'.
            If  the  committed  virtual memory exceeds the limit ('vmcom' and 'vmlim' in the SWP-
            line), the SWP-line is colored due to overcommitting the system.

        Swap
            An occupation percentage of 80% is considered 'critical' because swap space might  be
            completely  exhausted  in  the  near  future.   It is not critical from a performance
            point-of-view.

       These default values can be modified in the configuration file (see  separate  atoprc  man
       page).

       When  a  resource exceeds its critical occupation percentage, the concerning values in the
       screen line are colored red by default.
       When a resource exceeds (by default) 80% of its  critical  percentage  (so  it  is  almost
       critical),  the  concerning  values  in  the screen line are colored cyan by default. This
       'almost critical percentage' (one value for all resources) can be  also  modified  in  the
       configuration file (see separate atoprc man page).
       The  default  colors  red  and cyan can be modified in the configuration file as well (see
       separate atoprc man page).

       With the key 'x' (or flag -x), the use of colors can be suppressed in text mode.  The  use
       of colors is however mandatory in case of bar graph mode.

NETATOP OR NETATOP-BPF MODULE

       Per-process  and  per-thread network activity can be measured by the netatop kernel module
       or the netatop-bpf BPF module that can be separately installed.
       When atop gathers counters for a new interval, it verifies if the netatop  or  netatop-bpf
       module  is  currently  active. If so, atop obtains the relevant network counters from this
       module and shows the number of sent and received packets per process/thread in the generic
       screen. Besides, detailed counters can be requested by pressing the 'n' key.
       When  the  netatopd  daemon  is  running in combination with the netatop module, atop also
       reads the network counters of exited processes that are logged by this daemon  (comparable
       with process accounting).

       More  information  about the optional netatop kernel module and the netatopd daemon can be
       found in the concerning man-pages and on the website mentioned at the end of  this  manual
       page.

GPU STATISTICS GATHERING

       GPU  statistics  can  be  gathered  by atopgpud which is a separate data collection daemon
       process.  It gathers cumulative utilization counters of every Nvidia GPU in the system, as
       well as utilization counters of every process that uses a GPU.  When atop notices that the
       daemon is active, it reads these GPU utilization counters with every interval.

       The atopgpud daemon is written in Python, so a Python interpreter should be  installed  on
       the  target system.  For the gathering of the statistics, the pynvml module is used by the
       daemon. Be sure that this module is installed on the target system before  activating  the
       daemon, by running the command pip as root user:

         pip install nvidia-ml-py

       The  atopgpud  daemon  is  installed by default as part of the atop package, but it is not
       automatically enabled.  The daemon can be enabled and started now by running the following
       commands (as root):

         systemctl enable atopgpu
         systemctl start atopgpu

       Find a description about the utilization counters in the section OUTPUT DESCRIPTION.

INTERACTIVE COMMANDS

       When  running  atop  interactively (no output redirection), keys can be pressed to control
       the output. In general, lower case keys can be used to  show  other  information  for  the
       active  processes while certain upper case keys can be used to influence the sort order of
       the active process/thread list. Some of these keys can also be used  to  switch  from  bar
       graph mode to particular detailed process information in text mode.

       g    Show generic output (default).

            Per process the following fields are shown in case of a window-width of 80 positions:
            process-id, CPU consumption during the last interval in system  and  user  mode,  the
            virtual and resident memory growth of the process.
            The data transfer per process for read/write on disk can only be shown when atop runs
            with root privileges.
            When the optional module netatop or netatop-bpf is  loaded,  the  data  transfer  for
            send/receive of network packets is shown for each process.
            The last columns contain the state, the occupation percentage for the chosen resource
            (default: CPU) and the process name.

            When more than 80 positions are available, other information is added.

       m    Show memory related output.

            Per process the following fields are shown in case of a window width of 80 positions:
            process-id, minor and major memory faults, size of virtual shared text, total virtual
            process size, total resident process size, virtual and resident  growth  during  last
            interval, memory occupation percentage and process name.

            When more than 80 positions are available, other information is added.

            For  memory consumption, always all processes are shown (also the processes that were
            not active during the interval).

       d    Show disk-related output.

            When atop runs with root privileges, the  following  fields  are  shown:  process-id,
            amount  of  data  read from disk, amount of data written to disk, amount of data that
            was written but has been withdrawn again (WCANCL),  disk  occupation  percentage  and
            process name.

       n    Show network related output.

            Per process the following fields are shown in case of a window width of 80 positions:
            process-id, thread-id, total bandwidth for received packets, total bandwidth for sent
            packets,  number of received TCP packets with the average size per packet (in bytes),
            number of sent TCP packets with the average size per packet  (in  bytes),  number  of
            received  UDP packets with the average size per packet (in bytes), number of sent UDP
            packets with  the  average  size  per  packet  (in  bytes),  the  network  occupation
            percentage and process name.
            This information can only be shown when the optional module netatop or netatop-bpf is
            installed.

            When more than 80 positions are available, other information is added.

       s    Show scheduling characteristics.

            Per process the following fields are shown in case of a window width of 80 positions:
            process-id,  number  of  threads  in  state 'running' (R), number of threads in state
            'interruptible sleeping' (S), number of threads in state  'uninterruptible  sleeping'
            (D),  number  of  threads in state 'idle' (I), scheduling policy (normal timesharing,
            realtime round-robin,  realtime  fifo),  nice  value,  priority,  realtime  priority,
            current processor, status, exit code, state, the occupation percentage for the chosen
            resource and the process name.

            When more than 80 positions are available, other information is added.

       v    Show various process characteristics.

            Per process the following fields are shown in case of a window width of 80 positions:
            process-id,  user  name and group, start date and time, status (e.g. exit code if the
            process has finished), state, the occupation percentage for the chosen  resource  and
            the process name.

            When more than 80 positions are available, other information is added.

       c    Show the command line of the process.

            Per process the following fields are shown: process-id, the occupation percentage for
            the chosen resource and the command line including arguments.

       X    Show cgroup v2 information.

            Per process the following fields are shown: process-id, 'cpu.weight'  of  the  cgroup
            the  process  belongs  to, 'cpu.max' value (recalculated as percentage) of the cgroup
            the process  belongs  to,  most  restrictive  'cpu.max'  value  found  in  the  upper
            directories,   'memory.max'  value  of  the  cgroup  the  process  belongs  to,  most
            restrictive 'memory.max' value found  in  the  upper  directories,  'memory.swap.max'
            value  of the cgroup the process belongs to, most restrictive 'memory.swap.max' value
            found in  the  upper  directories,  the  command  name,  and  the  cgroup  path  name
            (horizontally scrollable).

       e    Show GPU utilization.

            Per process at least the following fields are shown: process-id, range of GPU numbers
            on which the process currently runs, GPU busy percentage on  all  GPUs,  memory  busy
            percentage (i.e. read and write accesses on memory) on all GPUs, memory occupation at
            the moment of the sample, average  memory  occupation  during  the  sample,  and  GPU
            percentage.

            When  the  atopgpud daemon does not run with root privileges, the GPU busy percentage
            and the memory busy percentage are not available on process level.  In that case, the
            GPU percentage on process level reflects the GPU memory occupation instead of the GPU
            busy percentage (which is preferred).

       o    Show the user-defined line of the process.

            In the  configuration  file  the  keyword  ownprocline  can  be  specified  with  the
            description of a user-defined output-line.
            Refer to the man-page of atoprc for a detailed description.

       y    Show the individual threads within a process (toggle).

            Single-threaded processes are still shown as one line.
            For  multi-threaded processes, one line represents the process while additional lines
            show the activity per individual thread (in a  different  color).  Depending  on  the
            option  'a'  (all  or  active toggle), all threads are shown or only the threads that
            were active during the last interval.  Depending on the option  'Y'  (sort  threads),
            the threads per process will be sorted on the chosen sort criterium or not.
            Whether this key is active or not can be seen in the header line.

       Y    Sort the threads per process when combined with option 'y' (toggle).

       u    Show the process activity accumulated per user.

            Per  user  the  following  fields are shown: number of processes active or terminated
            during last interval (or in total if combined  with  command  'a'),  accumulated  CPU
            consumption  during  last  interval  in system and user mode, the current virtual and
            resident memory space consumed by active processes (or all processes of the  user  if
            combined with command 'a').
            When  atop  runs  with  root privileges, the accumulated read and write throughput on
            disk is shown.  When the optional module netatop or netatop-bpf has  been  installed,
            the accumulated number of received and sent network packets is shown.
            The  last  columns  contain  the  accumulated  occupation  percentage  for the chosen
            resource (default: CPU) and the user name.

       p    Show the process activity accumulated per program (i.e. process name).

            Per program the following fields are shown: number of processes active or  terminated
            during  last  interval  (or  in  total if combined with command 'a'), accumulated CPU
            consumption during last interval in system and user mode,  the  current  virtual  and
            resident  memory  space consumed by active processes (or all processes of the user if
            combined with command 'a').
            When atop runs with root privileges, the accumulated read  and  write  throughput  on
            disk  is  shown.  When the optional module netatop or netatop-bpf has been installed,
            the accumulated number of received and sent network packets is shown.
            The last columns  contain  the  accumulated  occupation  percentage  for  the  chosen
            resource (default: CPU) and the program name.

       j    Show the process activity accumulated per container/pod.

            Per  container (e.g. Docker/Podman) or pod (e.g. Kubernetes) the following fields are
            shown: number of processes active or terminated during last interval (or in total  if
            combined  with  command  'a'),  accumulated  CPU  consumption during last interval in
            system and user mode, the current virtual  and  resident  memory  space  consumed  by
            active processes (or all processes of the user if combined with command 'a').
            When  atop  runs  with  root privileges, the accumulated read and write throughput on
            disk is shown.  When the optional module netatop or netatop-bpf has  been  installed,
            the accumulated number of received and sent network packets is shown.
            The  last  columns  contain  the  accumulated  occupation  percentage  for the chosen
            resource (default: CPU) and the container/pod name (CID/POD).

       C    Sort the current list in the order of CPU consumption  (default).   The  one-but-last
            column changes to 'CPU'.

       E    Sort the current list in the order of GPU utilization (preferred, but only applicable
            when the atopgpud daemon runs under root privileges)  or  the  order  of  GPU  memory
            occupation).  The one-but-last column changes to 'GPU'.

       M    Sort  the current list in the order of resident memory consumption.  The one-but-last
            column changes to 'MEM'. In case of sorting on memory, the full process list will  be
            shown (not only the active processes).

       D    Sort  the current list in the order of disk accesses issued.  The one-but-last column
            changes to 'DSK'.

       N    Sort the current list in the order of network bandwidth (received  and  transmitted).
            The one-but-last column changes to 'NET'.

       A    Sort  the  current  list  automatically in the order of the most busy system resource
            during this interval.  The one-but-last column shows either 'ACPU', 'AMEM', 'ADSK' or
            'ANET' (the preceding 'A' indicates automatic sorting-order).  The most busy resource
            is determined by comparing the weighted busy-percentages of the system resources,  as
            described earlier in the section COLORS.
            This option remains valid until another sorting-order is explicitly selected again.
            A sorting order for disk is only possible when atop runs with root privileges.
            A  sorting  order  for  network  is only possible when the optional module netatop or
            netatop-bpf is loaded.

       Miscellaneous interactive commands:

       ?    Request for help information (also the key 'h' can be pressed).

       V    Request for version information (version number and date).

       R    Gather and calculate the proportional set size of processes (toggle).   Gathering  of
            all  values  that  are  needed  to  calculate  the PSIZE of a process is a very time-
            consuming task, so this key should only be active when analyzing the resident  memory
            consumption of processes.

       W    Get  the  WCHAN  per  thread (toggle).  Gathering of the WCHAN string per thread is a
            relatively time-consuming task, so this key should only be made active when analyzing
            the reason for threads to be in sleep state.

       x    Suppress colors to highlight critical resources (toggle).
            Whether this key is active or not can be seen in the header line.

       z    The pause key can be used to freeze the current situation in order to investigate the
            output on the screen. While atop is paused, the keys described above can  be  pressed
            to  show  other  information about the current list of processes.  Whenever the pause
            key is pressed again, atop will continue with a next sample.
            The pause key can be used in text mode and bar graph mode.

       i    Modify the interval timer (default: 10  seconds).  If  an  interval  timer  of  0  is
            entered,  the  interval  timer is switched off. In that case a new sample can only be
            triggered manually by pressing the key 't'.
            The interval can be modified in text mode and bar graph mode.

       t    Trigger a new sample manually. This key can be pressed if the current  sample  should
            be  finished  before  the  timer has exceeded, or if no timer is set at all (interval
            timer defined as 0). In the latter case atop can be used as a  stopwatch  to  measure
            the  load  being  caused  by a particular application transaction, without knowing on
            beforehand how many seconds this transaction will last.
            This key can be used in text mode and bar graph mode.

            When viewing the contents of a raw file this key can be used to show the next  sample
            from the file. This key can also be used when viewing raw data via a pipe.

       T    When  viewing  the  contents  of a raw file this key can be used to show the previous
            sample from the file, however not when reading raw data from a pipe.
            This key can be used in text mode and bar graph mode.

       b    When viewing the contents of a raw file, this key can be used to branch to a  certain
            timestamp  within  the file either forward or backward.  When viewing raw data from a
            pipe only forward branches are possible.
            This key can be used in text mode and bar graph mode.

       r    Reset all counters to zero to see the system and process activity since boot again.
            This key can be used in text mode and bar graph mode.

            When viewing the contents of a raw file, this key  can  be  used  to  rewind  to  the
            beginning of the file again (except when reading raw data from a pipe).

       U    Specify  a  search  string for specific user names as a regular expression.  From now
            on, only (active) processes will be shown from  a  user  which  matches  the  regular
            expression.   The  system  statistics  are  still  system  wide.  If the Enter-key is
            pressed without specifying a name, (active) processes of  all  users  will  be  shown
            again.
            Whether this key is active or not can be seen in the header line.

       I    Specify  a  list  with  one or more PIDs to be selected.  From now on, only processes
            will be shown with a PID which matches one of the given list.  The system  statistics
            are  still  system  wide.   If the Enter-key is pressed without specifying a PID, all
            (active) processes will be shown again.
            Whether this key is active or not can be seen in the header line.

       P    Specify a search string for specific process names as a regular expression.  From now
            on,  only  processes  will be shown with a name which matches the regular expression.
            The system statistics are still system wide.  If the  Enter-key  is  pressed  without
            specifying a name, all (active) processes will be shown again.
            Whether this key is active or not can be seen in the header line.

       /    Specify  a specific command line search string as a regular expression.  From now on,
            only processes  will  be  shown  with  a  command  line  which  matches  the  regular
            expression.   The  system  statistics  are  still  system  wide.  If the Enter-key is
            pressed without specifying a string, all (active) processes will be shown again.
            Whether this key is active or not can be seen in the header line.

       J    Specify a container id (e.g. Docker or Podman)  or  pod  name  (e.g.  Kubernetes)  of
            maximum  15  characters.  In  case  the  name  is  longer, the last 15 characters are
            expected.  From now on, only processes will  be  shown  that  run  in  that  specific
            container  or pod.  The system statistics are still system wide.  If the Enter-key is
            pressed without specifying a container id or pod name, all (active) processes will be
            shown again.
            Whether this key is active or not can be seen in the header line.

       Q    Specify a comma-separated list of process/thread state characters.  From now on, only
            processes/threads will be shown that are in those specific states.   Accepted  states
            are:  R  (running),  S  (sleeping), D (disk sleep), I (idle), T (stopped), t (tracing
            stop), X (dead), Z (zombie) and P (parked).  The system statistics are  still  system
            wide.   If  the  Enter-key  is  pressed  without  specifying  a  state,  all (active)
            processes/threads will be shown again.
            Whether this key is active or not can be seen in the header line.

       S    Specify search strings for specific logical volume names,  specific  disk  names  and
            specific  network  interface  names.  All search strings are interpreted as a regular
            expressions.  From now on, only those system  resources  are  shown  that  match  the
            concerning  regular  expression.   If  the  Enter-key is pressed without specifying a
            search string, all (active) system resources of that type will be shown again.
            Whether this key is active or not can be seen in the header line.

       a    The 'all/active' key can be used to  toggle  between  only  showing/accumulating  the
            processes that were active during the last interval (default) or showing/accumulating
            all processes.
            Whether this key is active or not can be seen in the header line.

       G    By default, atop shows/accumulates the processes that are  alive  and  the  processes
            that   are   exited   during   the   last   interval.   With   this   key   (toggle),
            showing/accumulating the processes that are exited can be suppressed.
            Whether this key is active or not can be seen in the header line.

       f    Show a fixed (maximum) number of header lines  for  system  resources  (toggle).   By
            default  only  the  lines  are  shown  about  system resources (CPUs, paging, logical
            volumes, disks, network interfaces) that really have  been  active  during  the  last
            interval.   With  this  key you can force atop to show lines of inactive resources as
            well.
            Whether this key is active or not can be seen in the header line.

       F    Suppress sorting of system resources (toggle).  By default  system  resources  (CPUs,
            logical volumes, disks, network interfaces) are sorted on utilization.
            Whether this key is active or not can be seen in the header line.

       1    Show  relevant  counters as an average per second (in the format '..../s') instead of
            as a total during the interval (toggle).
            Whether this key is active or not can be seen in the header line.

       l    Limit the number of system level lines for the counters per-cpu, the active disks and
            the  network  interfaces.   By default lines are shown of all CPUs, disks and network
            interfaces which have been active during the last interval.  Limiting these lines can
            be  useful  on systems with huge number CPUs, disks or interfaces in order to be able
            to run atop on a screen/window with e.g. only 24 lines.
            For  all  mentioned  resources  the  maximum  number  of  lines  can   be   specified
            interactively.  When  using the flag -l the maximum number of per-cpu lines is set to
            0, the maximum number of disk lines to 5 and the maximum number of interface lines to
            3.  These values can be modified again in interactive mode.

       k    Send a signal to an active process (a.k.a. kill a process).

       q    Quit the program.
            This key can be used in text mode and bar graph mode.

       PgDn Show the next page of the process/thread list.
            With the arrow-down key the list can be scrolled downwards with single lines.

       ^F   Show the next page of the process/thread list (forward).
            With the arrow-down key the list can be scrolled downwards with single lines.

       PgUp Show the previous page of the process/thread list.
            With the arrow-up key the list can be scrolled upwards with single lines.

       ^B   Show the previous page of the process/thread list (backward).
            With the arrow-up key the list can be scrolled upwards with single lines.

       ^L   Redraw the screen.

RAW DATA STORAGE

       In  order  to  store  system  and process level statistics for long-term analysis (e.g. to
       check the system load and the active processes running yesterday  between  3:00  and  4:00
       PM), atop can store the system and process level statistics in compressed binary format in
       a raw file with the flag -w followed by the filename.  If this file already exists and  is
       recognized  as  a raw data file, atop will append new samples to the file (starting with a
       sample which reflects the activity since boot). If the file does not  exist,  it  will  be
       created.
       All information about system, processes and thread activity is stored in the raw file.
       The interval (default: 10 seconds) and number of samples (default: infinite) can be passed
       as last arguments. Instead of the number of samples, the flag -S can be used  to  indicate
       that atop should finish anyhow before midnight.

       A  raw file can be read and visualized again with the flag -r followed by the filename. If
       no filename is specified, the file /var/log/atop/atop_YYYYMMDD is opened for input  (where
       YYYYMMDD  are  digits  representing  the current date).  If a filename is specified in the
       format YYYYMMDD (representing any valid date),  the  file  /var/log/atop/atop_YYYYMMDD  is
       opened.  If a filename with the symbolic name y is specified, yesterday's daily logfile is
       opened (this can be repeated so 'yyyy' indicates the logfile of four days  ago).   If  the
       filename - is used, stdin will be read.
       The  samples  from  the  file can be viewed interactively by using the key 't' to show the
       next sample, the key 'T' to show  the  previous  sample,  the  key  'b'  to  branch  to  a
       particular  time or the key 'r' to rewind to the begin of the file. These keys can be used
       in text mode as well as in bar graph mode.
       When output is redirected to a file or pipe, atop prints all samples in plain  ASCII.  The
       default  line  length  is  80  characters  in  that  case. With the flag -L followed by an
       alternate line length, more (or less) columns will be shown.
       With the flag -b (begin time) and/or -e (end time) followed by a time argument of the form
       [YYYYMMDD]hhmm[ss], a certain time period within the raw file can be selected.

       Every  day  at midnight atop is restarted by the atop-rotate.timer and atop-rotate.service
       unit files, to write compressed binary data to the file  /var/log/atop/atop_YYYYMMDD  with
       an interval of 10 minutes by default.
       Furthermore all raw files are removed that are older than 28 days (by default).
       The  mentioned  default  values  can be overruled in the file /etc/default/atop that might
       contain other values for LOGOPTS (by default without any flag), LOGINTERVAL  (in  seconds,
       by  default 600), LOGGENERATIONS (in days, by default 28), and LOGPATH (directory in which
       logfiles are stored).

       Unfortunately, it is not always possible to keep the format of the raw files compatible in
       newer  versions  of  atop  especially  when  many  new  counters  have  to  be maintained.
       Therefore, the program atopconvert is installed to convert a raw file created by an  older
       version  of  atop  to  a raw file that can be read by a newer version of atop (see the man
       page of atopconvert for more details).

OUTPUT DESCRIPTION

       The first sample shows the system level activity since  boot  (the  elapsed  time  in  the
       header shows the time since boot).

       In  text  mode,  atop  first  shows  the  lines related to system level activity for every
       sample.  If a particular system resource has not been used during the interval, the entire
       line  related to this resource is suppressed. So the number of system level lines may vary
       for each sample.
       After that a list is shown of processes which have been active during the  last  interval.
       This  list  is  sorted on CPU consumption by default, but this order can be changed by the
       keys which are previously described.

       If values have to be shown by atop which do not fit in the column width, another format is
       used.  If  e.g. a CPU consumption of 233216 milliseconds should be shown in a column width
       of 4 positions, it is shown as '233s' (in seconds).  For  large  memory  figures,  another
       unit  is  chosen if the value does not fit (Mb instead of Kb, Gb instead of Mb, Tb instead
       of Gb, etcetera).  For other values, a kind of exponent notation is used (value  123456789
       shown in a column of 5 positions gives 123e6).

OUTPUT DESCRIPTION - SYSTEM LEVEL

       The system level information in text mode consists of the following output lines:

       PRC  Process and thread level totals.
            This  line  contains  the  total CPU time consumed in system mode ('sys') and in user
            mode ('user'), the total number of processes present at this  moment  ('#proc'),  the
            total  number  of  threads  present  at  this  moment  in  state 'running' ('#trun'),
            'sleeping interruptible' ('#tslpi'), 'sleeping uninterruptible' ('#tslpu') and 'idle'
            ('#tidle'),  the  number  of zombie processes ('#zombie'), the number of clone system
            calls ('clones'), and  the  number  of  processes  that  ended  during  the  interval
            ('#exit')  when  process  accounting  is used. Instead of '#exit' the last column may
            indicate that process accounting could not be activated ('no procacct').
            If the screen-width does not allow all of these counters, only a relevant  subset  is
            shown.

       CPU  CPU utilization.
            At least one line is shown for the total occupation of all CPUs together.
            In case of a multi-processor system, an additional line is shown for every individual
            processor (with 'cpu' in lower case), sorted on activity. Inactive CPUs will  not  be
            shown by default.  The lines showing the per-cpu occupation contain the CPU number in
            the field combined with the wait percentage.

            Every line contains the percentage of CPU time spent in kernel  mode  by  all  active
            processes  ('sys'), the percentage of CPU time consumed in user mode ('user') for all
            active processes (including processes running with a nice value  larger  than  zero),
            the  percentage  of  CPU time spent for interrupt handling ('irq') including softirq,
            the percentage of unused CPU time while  no  processes  were  waiting  for  disk  I/O
            ('idle'),  and  the  percentage  of  unused  CPU  time while at least one process was
            waiting for disk I/O ('wait').
            In case of per-cpu occupation, the CPU number and the wait percentage ('w') for  that
            CPU.  The number of lines showing the per-cpu occupation can be limited.

            For virtual machines, the steal-percentage ('steal') shows the percentage of CPU time
            stolen by other virtual machines running on the same hardware.
            For physical machines hosting one or more  virtual  machines,  the  guest  percentage
            ('guest')  shows the percentage of CPU time used by the virtual machines. Notice that
            this percentage overlaps the user percentage!

            When PMC performance monitoring counters are supported by the CPU and the kernel (and
            atop  runs with root privileges), the number of instructions per CPU cycle ('ipc') is
            shown.  The first sample always shows the value 'initial', because the  counters  are
            just activated at the moment that atop is started.
            When  the CPU busy percentage is high and the IPC is less than 1.0, it is likely that
            the CPU is frequently waiting for memory access during instruction execution  (larger
            CPU  caches  or faster memory might be helpful to improve performance).  When the CPU
            busy percentage is high and the IPC is greater than 1.0, it is likely that the CPU is
            instruction-bound (more/faster cores might be helpful to improve performance).
            Furthermore,  per  CPU  the effective number of cycles ('cycl') is shown.  This value
            can reach the current CPU frequency if such CPU is 100% busy.  When an  idle  CPU  is
            halted,  the  number of effective cycles can be (considerably) lower than the current
            frequency.
            Notice that the average instructions per cycle and number of cycles is shown  in  the
            CPU line for all CPUs.
            Beware  that  reading  the cycle counter in virtual machines (guests) might introduce
            performance delays. Therefore this metric is by default disabled in virtual machines.
            However,  with  the  keyword  'perfevents'  in  the  atoprc  file  this metric can be
            explicitly set to 'enable' or 'disable' (see separate man-page of atoprc).
            See also: http://www.brendangregg.com/blog/2017-05-09/cpu-utilization-is-wrong.html

            In case of frequency scaling, all previously mentioned CPU percentages  are  relative
            to  the  used  scaling  of the CPU during the interval.  If a CPU has been active for
            e.g. 50% in user mode during the interval while the frequency scaling of that CPU was
            40%, only 20% of the full capacity of the CPU has been used in user mode.
            In  case  that  the  kernel module 'cpufreq_stats' is active (after issuing 'modprobe
            cpufreq_stats'), the average frequency ('avgf') and the  average  scaling  percentage
            ('avgscal')  is  shown.  Otherwise  the  current  frequency  ('curf') and the current
            scaling percentage ('curscal') is shown at the  moment  that  the  sample  is  taken.
            Notice  that  average  values for frequency and scaling are shown in the CPU line for
            every CPU.
            Frequency scaling statistics are only gathered for systems with maximum 8 CPUs, since
            gathering of these values per CPU is very time consuming.

            If  the  screen-width does not allow all of these counters, only a relevant subset is
            shown.

       CPL  CPU load information.
            This line contains the load average figures reflecting the number of threads that are
            available  to  run  on a CPU (i.e. part of the runqueue) or that are waiting for disk
            I/O. These figures are averaged over 1 ('avg1'), 5 ('avg5') and 15 ('avg15') minutes.
            Furthermore the number of context switches ('csw'), the number of serviced interrupts
            ('intr') and the number of available CPUs are shown.

            If  the  screen-width does not allow all of these counters, only a relevant subset is
            shown.

       GPU  GPU utilization (Nvidia).
            Read the section GPU STATISTICS GATHERING in this document to find the details  about
            the activation of the atopgpud daemon.

            In  the  first  column  of  every line, the bus-id (last nine characters) and the GPU
            number are shown.  The subsequent columns show the percentage of  time  that  one  or
            more  kernels  were  executing  on  the  GPU ('gpubusy'), the percentage of time that
            global (device)  memory  was  being  read  or  written  ('membusy'),  the  occupation
            percentage  of memory ('memocc'), the total memory ('total'), the memory being in use
            at the moment of the sample ('used'), the average memory  being  in  use  during  the
            sample  time ('usavg'), the number of processes being active on the GPU at the moment
            of the sample ('#proc'), and the type of GPU.

            If the screen-width does not allow all of these counters, only a relevant  subset  is
            shown.
            The number of lines showing the GPUs can be limited.

       MEM  Memory occupation (two lines).
            These lines contain the total amount of physical memory ('tot'), the amount of memory
            which is currently free ('free'), the amount of memory  that  is  available  for  new
            workloads without pushing the system into swap ('avail'), the amount of memory in use
            as page cache including the total resident shared memory  ('cache'),  the  amount  of
            memory  within the page cache that has to be flushed to disk ('dirty'), the amount of
            memory used for filesystem meta data ('buff'), the amount of memory  being  used  for
            kernel mallocs ('slab'), the amount of slab memory that is reclaimable ('slrec'), the
            resident size of SYSV shared memory including tmpfs but excluding static  huge  pages
            ('shmem'),  the  resident  size  of  SYSV  shared  memory including static huge pages
            ('shrss'), the amount of SYSV shared memory that is currently swapped ('shswp'),  the
            amount of memory that is currently used for page tables ('pgtab'), the number of NUMA
            nodes in this system ('numnode'), the amount of memory that is currently  claimed  by
            vmware's  balloon driver ('vmbal'), the amount of memory that is currently claimed by
            the ARC  (cache)  of  ZFSonlinux  ('zfarc'),  the  amount  of  memory  for  anonymous
            transparent huge pages ('anthp'), the amount of memory that is claimed for huge pages
            ('hptot'), the amount of huge page memory that is really in use ('hpuse'), the amount
            of  memory  that  is  used for TCP sockets ('tcps'), and the amount of memory that is
            used for UDP sockets ('udps').

            If the screen-width does not allow all of these counters, only a relevant  subset  is
            shown.

       SWP  Swap occupation and overcommit info.
            This line contains the total amount of swap space on disk ('tot'), the amount of free
            swap space ('free'), the size of the swap cache ('swcac'),  the  size  of  compressed
            storage used for zswap ('zswap'), the real (decompressed) size of the pages stored in
            zswap ('zstor'), the total size of the memory used for KSM  ('ksuse',  i.e.  shared),
            and the total size of the memory saved (deduped) by KSM ('kssav', i.e. sharing).
            Furthermore the committed virtual memory space ('vmcom') and the maximum limit of the
            committed space ('vmlim', which is by default swap size plus 50% of memory  size)  is
            shown.   The  committed  space  is  the reserved virtual space for all allocations of
            private memory space for processes. The kernel only verifies  whether  the  committed
            space   exceeds   the   limit   if   strict   overcommit   handling   is   configured
            (vm.overcommit_memory is 2).

       LLC  Last-Level Cache of CPU info.
            This line contains the total memory bandwidth of LLC ('tot'), the  bandwidth  of  the
            local NUMA node ('loc'), and the percentage of LLC in use ('LLCXX YY%').

            Note  that this feature depends on the 'resctrl' pseudo filesystem.  Be sure that the
            kernel is built with the relevant config and take care that the pseudo-filesystem  is
            mounted:

              mount -t resctrl resctrl -o mba_MBps /sys/fs/resctrl (on Intel)
              mount -t resctrl resctrl -o cdp      /sys/fs/resctrl (on AMD)

       NUM  Memory utilization per NUMA node (not shown for single NUMA node).
            This  line shows the total amount of physical memory of this node ('tot'), the amount
            of free memory ('free'), the amount of memory for cached file data ('file'), modified
            cached file data ('dirty'), recently used memory ('activ'), less recently used memory
            ('inact'), memory being used for kernel mallocs ('slab'), the amount of  slab  memory
            that  is  reclaimable  ('slrec'), shared memory including tmpfs ('shmem'), total huge
            pages ('hptot'), used huge pages('hpuse'), and the fragmentation percentage ('frag').

       NUC  CPU utilization per NUMA node (not shown for single NUMA node).
            This line shows the utilization percentages of all CPUs related to  this  NUMA  node,
            categorized  for   system  mode  ('sys'),  user  mode  ('user'),  user mode for niced
            processes ('niced'), idle mode ('idle'), wait mode ('w' preceded by the node number),
            irq  mode  ('irq'),  softirq  mode  ('sirq'),  steal  mode  ('steal'), and guest mode
            ('guest') overlapping user mode.

       PAG  Paging frequency.
            This line contains the number of scanned pages ('scan') due to  the  fact  that  free
            memory drops below a particular threshold, the number of reclaimed pages('steal') due
            to the fact that free memory drops below a particular  threshold,  the  number  times
            that  the kernel tries to reclaim pages due to an urgent need ('stall'),the number of
            process stalls to run memory compaction  to  allocate  huge  pages  ('compact'),  the
            number  of  NUMA  pages  migrated  ('numamig'),  and the total number of memory pages
            migrated successfully e.g. between NUMA  nodes  or  for  compaction  ('migrate')  are
            shown.
            Also  the  number  of  memory  pages the system read from block devices ('pgin'), the
            number of memory pages the system wrote to block devices  ('pgout'),  the  number  of
            memory  pages swapped in from zswap ('zswin'), the number of memory pages swapped out
            to zswap ('zswout'), the number of memory pages  the  system  read  from  swap  space
            ('swin'),  the  number  of memory pages the system wrote to swap space ('swout'), and
            the number of out-of-memory kills ('oomkill').

       PSI  Pressure Stall Information.
            This line contains percentages about resource pressure related  to  CPU,  memory  and
            I/O.  Certain  percentages  refer  to 'some' meaning that some processes/threads were
            delayed due to resource overload. Other percentages refer to 'full' meaning a loss of
            overall throughput due to resource overload.
            The  values  'cpusome', 'memsome', 'memfull', 'iosome' and 'iofull' show the pressure
            percentage during the entire interval.
            The values 'cs' (cpu some), 'ms' (memory some), 'mf' (memory full), 'is'  (I/O  some)
            and  'if'  (I/O  full)  each  show  three  percentages separated by slashes: pressure
            percentage over the last 10, 60 and 300 seconds.

       LVM/MDD/DSK
            Logical volume/multiple device/disk utilization.
            Per active unit one line is produced, sorted on unit activity.  Such line  shows  the
            name  (e.g.  VolGroup00-lvtmp  for  a  logical  volume  or  sda for a hard disk), the
            percentage of elapsed time during which  I/O  requests  were  issued  to  the  device
            ('busy')  (note  that  for devices serving requests in parallel, such as RAID arrays,
            SSD and NVMe, this number does not reflect their performance limits), the  number  of
            read  requests  issued  ('read'),  the number of write requests issued ('write'), the
            number of discard requests issued ('discrd') if  supported  by  kernel  version,  the
            number  of KiBytes per read ('KiB/r'), the number of KiBytes per write ('KiB/w'), the
            number of KiBytes per discard ('KiB/d') if supported by kernel version, the number of
            MiBytes  per  second throughput for reads ('MBr/s'), the number of MiBytes per second
            throughput for writes ('MBw/s'),  requests  issued  to  the  device  driver  but  not
            completed  ('inflt'),  the  average  queue  depth  while busy ('avq') and the average
            number of milliseconds needed by a  request  ('avio')  for  seek,  latency  and  data
            transfer.
            If  the  screen-width does not allow all of these counters, only a relevant subset is
            shown.

            The number of lines showing the units can be limited per class (LVM, MDD or DSK) with
            the 'l' key or statically (see separate man-page of atoprc).  By specifying the value
            0 for a particular class, no lines will be shown any more for that class.

       NFM  Network Filesystem (NFS) mount at the client side.
            For each NFS-mounted filesystem, a line is shown that  contains  the  mounted  server
            directory,  the name of the server ('srv'), the total number of bytes physically read
            from the server ('read') and the total number of  bytes  physically  written  to  the
            server ('write').  Data transfer is subdivided in the number of bytes read via normal
            read() system calls ('nread'), the number of bytes written via normal  read()  system
            calls  ('nwrit'),  the  number  of bytes read via direct I/O ('dread'), the number of
            bytes written via direct I/O ('dwrit'), the number of bytes read  via  memory  mapped
            I/O  pages  ('mread'),  and  the  number of bytes written via memory mapped I/O pages
            ('mwrit').

       NFC  Network Filesystem (NFS) client side counters.
            This line contains the number of RPC calls issues by  local  processes  ('rpc'),  the
            number  of  read RPC calls ('read') and write RPC calls ('rpwrite') issued to the NFS
            server, the number of RPC calls being retransmitted ('retxmit')  and  the  number  of
            authorization refreshes ('autref').

       NFS  Network Filesystem (NFS) server side counters.
            This  line  contains  the  number of RPC calls received from NFS clients ('rpc'), the
            number of read RPC calls received ('cread'), the number of write RPC  calls  received
            ('cwrit'),  the  number  of  Megabytes/second  returned  to  read requests by clients
            ('MBcr/s'), the number of  Megabytes/second  passed  in  write  requests  by  clients
            ('MBcw/s'),  the number of network requests handled via TCP ('nettcp'), the number of
            network requests  handled  via  UDP  ('netudp'),  the  number  of  reply  cache  hits
            ('rchits'),  the  number  of reply cache misses ('rcmiss') and the number of uncached
            requests ('rcnoca').  Furthermore  some  error  counters  indicating  the  number  of
            requests  with  a  bad  format  ('badfmt')  or  a bad authorization ('badaut'), and a
            counter indicating the number of bad clients ('badcln').

       NET  Network utilization (TCP/IP).
            One line is shown for activity of the transport layer (TCP and UDP), one line for the
            IP layer and one line per active interface.
            For  the  transport  layer,  counters are shown concerning the number of received TCP
            segments including those received in error ('tcpi'), the number  of  transmitted  TCP
            segments  excluding <<<<<<< HEAD those containing only retransmitted octets ('tcpo'),
            the  number  of  UDP  datagrams  received  ('udpi'),  the  number  of  UDP  datagrams
            transmitted ('udpo'), the number of active TCP opens ('tcpao'), the number of passive
            TCP opens ('tcppo'), the number of TCP output retransmissions ('tcprs'),  the  number
            of  TCP input errors ('tcpie'), the number of TCP output resets ('tcpor'), the number
            of UDP no ports ('udpnp'), the number of UDP input errors ('udpie'), and  the  number
            of TCP incorrect checksums ('csumie').
            If  the  screen-width does not allow all of these counters, only a relevant subset is
            shown.
            These counters are related to IPv4 and IPv6 combined.

            For the IP layer, counters are shown concerning the number of IP  datagrams  received
            from  interfaces,  including  those  received  in  error  ('ipi'),  the  number of IP
            datagrams that local higher-layer protocols offered  for  transmission  ('ipo'),  the
            number  of  received IP datagrams which were forwarded to other interfaces ('ipfrw'),
            the number of IP datagrams which  were  delivered  to  local  higher-layer  protocols
            ('deliv'),  the  number  of  received  ICMP  datagrams  ('icmpi'),  and the number of
            transmitted ICMP datagrams ('icmpo').
            If the screen-width does not allow all of these counters, only a relevant  subset  is
            shown.
            These counters are related to IPv4 and IPv6 combined.

            For  every  active  network  interface  one  line  is  shown, sorted on the interface
            activity.  Such line shows the name of the interface and its busy percentage  in  the
            first  column.   The  busy  percentage for half duplex is determined by comparing the
            interface speed with the number of bits transmitted and received per second; for full
            duplex  the interface speed is compared with the highest of either the transmitted or
            the received bits.  When the interface speed can not  be  determined  (e.g.  for  the
            loopback interface), '---' is shown instead of the percentage.
            Furthermore  the  number  of  received  packets  ('pcki'),  the number of transmitted
            packets ('pcko'), the line speed of the interface ('sp'),  the  effective  amount  of
            bits  received per second ('si'), the effective amount of bits transmitted per second
            ('so'), the number of collisions ('coll'), the number of received  multicast  packets
            ('mlti'),  the  number  of  errors  while  receiving a packet ('erri'), the number of
            errors while transmitting a packet ('erro'), the number of received  packets  dropped
            ('drpi'), and the number of transmitted packets dropped ('drpo').
            If  the  screen-width does not allow all of these counters, only a relevant subset is
            shown.
            The number of lines showing the network interfaces can be limited.

       IFB  Infiniband utilization.
            For every active Infiniband port one line is shown, sorted on  activity.   Such  line
            shows  the  name  of  the port and its busy percentage in the first column.  The busy
            percentage is determined by taking the highest  of  either  the  transmitted  or  the
            received  bits during the interval, multiplying that value by the number of lanes and
            comparing it against the maximum port speed.
            Furthermore the number of received packets divided by the number of  lanes  ('pcki'),
            the  number  of  transmitted  packets  divided  by  the number of lanes ('pcko'), the
            maximum line speed ('sp'), the effective amount of bits received per  second  ('si'),
            the  effective  amount of bits transmitted per second ('so'), and the number of lanes
            ('lanes').
            If the screen-width does not allow all of these counters, only a relevant  subset  is
            shown.
            The number of lines showing the Infiniband ports can be limited.

OUTPUT DESCRIPTION - PROCESS LEVEL

       Following  the  system  level  information, a list of processes is shown in text mode from
       which the resource utilization has changed during the last interval. These processes might
       have  used  CPU  time or might have issued disk or network requests.  However a process is
       also shown if part of it has been paged out due to  lack  of  memory  (while  the  process
       itself was in sleep state).

       Per  process  the  following fields may be shown (in alphabetical order), depending on the
       current output mode as described in the section INTERACTIVE COMMANDS and depending on  the
       current width of your window:

       AVGRSZ   The average size of one read-action on disk.

       AVGWSZ   The average size of one write-action on disk.

       BANDWI   Total  bandwidth for received TCP and UDP packets consumed by this process (bits-
                per-second).  This value can be compared with the value 'si' on  interface  level
                (used bandwidth per interface).
                This  information will only be shown when the optional module netatop or netatop-
                bpf is loaded.

       BANDWO   Total bandwidth for sent TCP and UDP packets consumed by this process  (bits-per-
                second).  This value can be compared with the value 'so' on interface level (used
                bandwidth per interface).
                This information will only be shown when the optional module netatop or  netatop-
                bpf is loaded.

       BDELAY   Aggregated block I/O delay, i.e. time waiting for disk I/O.

       CGROUP   Path  name  of  the  cgroup (version 2) to which this process belongs.  This path
                name is relative to the cgroup root directory, which is usually '/sys/fs/cgroup'.

       CID/POD  Container id (e.g. Docker or Podman) or pod name (e.g. Kubernetes)  referring  to
                the  container/pod  in  which  the process/thread is running.  When a pod name is
                longer than 15 characters, only the last 15 characters are shown.

                If a process has been started and finished during the last  interval,  a  '?'  is
                shown  because  the  container id or pod name is not part of the standard process
                accounting record.

                This column will only be shown when atop runs with superuser privileges and  when
                at least one containerized process is detected.

       CMD      The  name  of  the  process.   This name can be surrounded by "less/greater than"
                signs ('<name>') which means that  the  process  has  finished  during  the  last
                interval.  A  single  accounting  record  is  written  for  the entire process on
                termination of the last thread in the process. When the main  thread  exits,  the
                process name is changed to the thread name.
                Behind the abbreviation 'CMD' in the header line, the current page number and the
                total number of pages of the process/thread list are shown.

       COMMAND-LINE
                The full command line of the process (including arguments). If the length of  the
                command  line exceeds the length of the screen line, the arrow keys -> and <- can
                be used for horizontal scroll.

                The '-z <regex>' command line option can be used to prepend matching  environment
                variables to the displayed command line. POSIX Extended Regular Expression syntax
                are used (see regex(3)).  When  a  matching  environment  variable  is  too  long
                (exceeding  the  buffer  that  should  contain  the  command  line),  it  will be
                truncated.
                Behind the verb 'COMMAND-LINE' in the header line, the current  page  number  and
                the total number of pages of the process/thread list are shown.

       CPU      The  occupation  percentage of this process related to the available capacity for
                this resource on system level.

       CPUMAX   The 'cpu.max' value of the cgroup (version 2)  to  which  this  process  belongs,
                calculated as percentage of one CPU.

       CPUMAXR  The  most  restrictive  (i.e.  effective)  'cpu.max'  value  defined by the upper
                directories of the cgroup (version 2) to which this process  belongs,  calculated
                as percentage of one CPU.

       CPUNR    The  identification  of  the  CPU the (main) thread is running on or has recently
                been running on.

       CPUWGT   The 'cpu.weight' value of the cgroup (version 2) to which this process belongs.

       CTID     Container ID (OpenVZ).  If a process has been started  and  finished  during  the
                last  interval,  a  '?'  is  shown  because  the  container ID is not part of the
                standard process accounting record.

       DSK      The occupation percentage of this process related  to  the  total  load  that  is
                produced  by  all processes (i.e. total disk accesses by all processes during the
                last interval).
                This information is shown when per process "storage accounting" is active in  the
                kernel.

       EGID     Effective group-id under which this process executes.

       ENDATE   Date  that  the  process has been finished. If the process is still running, this
                field shows 'active'.

       ENTIME   Time that the process has been finished. If the process is  still  running,  this
                field shows 'active'.

       ENVID    Virtual environment identified (OpenVZ only).

       EUID     Effective user-id under which this process executes.

       EXC      The  exit  code  of a terminated process (second position of column 'ST' is E) or
                the fatal signal number (second position of column 'ST' is S or C).

       FSGID    Filesystem group-id under which this process executes.

       FSUID    Filesystem user-id under which this process executes.

       GPU      When the atopgpud daemon does not run with root privileges,  the  GPU  percentage
                reflects the GPU memory occupation percentage (memory of all GPUs is 100%).
                When  the  atopgpud daemon runs with root privileges, the GPU percentage reflects
                the GPU busy percentage.

       GPUBUSY  Busy percentage on all GPUs (one GPU is 100%).
                When the atopgpud daemon does not run with root privileges,  this  value  is  not
                available.

       GPUNUMS  Comma-separated  list  of  GPUs used by the process during the interval. When the
                comma-separated list exceeds the width of the  column,  a  hexadecimal  value  is
                shown.

       LOCKSZ   The  virtual  amount  of memory being locked (i.e. non-swappable) by this process
                (or user).

       MAJFLT   The number of page faults issued  by  this  process  that  have  been  solved  by
                creating/loading the requested memory page.

       MEM      The  occupation  percentage of this process related to the available capacity for
                this resource on system level.

       MEMAVG   Average memory occupation during the interval on all used GPUs.

       MEMBUSY  Busy percentage of memory on all GPUs (one GPU is 100%), i.e.   the  time  needed
                for read and write accesses on memory.
                When  the  atopgpud  daemon  does not run with root privileges, this value is not
                available.

       MEMMAX   The 'memory.max' value of the cgroup (version 2) to which this process belongs.

       MEMNOW   Memory occupation at the moment of the sample on all used GPUs.

       MMMAXR   The most restrictive (i.e. effective) 'memory.max' value  defined  by  the  upper
                directories of the cgroup (version 2) to which this process belongs.

       MINFLT   The  number  of  page  faults  issued  by  this  process that have been solved by
                reclaiming the requested memory page from the free list of pages.

       NET      The occupation percentage of this process related  to  the  total  load  that  is
                produced  by  all  processes  (i.e.  consumed  network bandwidth of all processes
                during the last interval).
                This information will only be shown when the optional module netatop or  netatop-
                bpf is loaded.

       NICE     The  more  or less static priority that can be given to a process on a scale from
                -20 (high priority) to +19 (low priority).

       NIVCSW   Number of times the process/thread was context-switched  involuntarily,  in  case
                that the time slice expired.

       NPROCS   The  number  of  active  and  terminated  processes  accumulated for this user or
                program.

       NVCSW    Number of times that the process/thread was context-switched voluntarily in  case
                of a blocking system call, e.g. to wait for an I/O operation to complete.

       PID      Process-id.  If a process has been started and finished during the last interval,
                a '?' is shown because the  process-id  is  not  part  of  the  standard  process
                accounting record.

       POLI     The  policies  'norm'  (normal,  which is SCHED_OTHER), 'btch' (batch) and 'idle'
                refer to timesharing processes.  The policies 'fifo' (SCHED_FIFO) and 'rr' (round
                robin, which is SCHED_RR) refer to realtime processes.

       PPID     Parent  process-id.   If  a process has been started and finished during the last
                interval, value 0 is shown because the parent  process-id  is  not  part  of  the
                standard process accounting record.

       PRI      The  process' priority ranges from 0 (highest priority) to 139 (lowest priority).
                Priority 0 to 99 are used for realtime processes (fixed priority  independent  of
                their  behavior)  and  priority  100  to  139 for timesharing processes (variable
                priority depending on their recent CPU consumption and the nice value).

       PSIZE    The proportional memory size of this process (or user).
                Every process shares resident memory with other processes. E.g. when a particular
                program  is  started several times, the code pages (text) are only loaded once in
                memory and shared by all incarnations. Also  the  code  of  shared  libraries  is
                shared  by  all processes using that shared library, as well as shared memory and
                memory-mapped files.  For the PSIZE calculation of a process, the resident memory
                of  a  process  that  is  shared with other processes is divided by the number of
                sharers.  This means, that every process is accounted for a proportional part  of
                that memory. Accumulating the PSIZE values of all processes in the system gives a
                reliable impression of the total resident memory consumed by all processes.
                Since gathering of all values that are needed to calculate the PSIZE  is  a  very
                time-consuming task, the 'R' key (or '-R' flag) should be active. Gathering these
                values also requires  superuser  privileges  (otherwise  '?K'  is  shown  in  the
                output).
                If  a  process has finished during the last interval, no value is shown since the
                proportional memory size is not part of the standard process accounting record.

       RDDSK    The read data transfer issued physically on disk (so reading from the disk  cache
                is not accounted for).
                Unfortunately,  the  kernel aggregates the data transfer of a process to the data
                transfer of its parent process when terminating, so you might see  transfers  for
                (parent) processes like cron, bash or init, that are not really issued by them.

       RDELAY   Runqueue delay, i.e. time spent waiting on a runqueue.

       RGID     The real group-id under which the process executes.

       RGROW    The  amount  of  resident  memory  that  the  process  has  grown during the last
                interval. A resident growth can be caused by touching memory pages which were not
                physically  created/loaded  before (load-on-demand).  Note that a resident growth
                can also be negative e.g. when part of the process is paged out due  to  lack  of
                memory  or  when  the  process frees dynamically allocated memory.  For a process
                which started during the last interval, the resident growth  reflects  the  total
                resident size of the process at that moment.
                If  a  process  has  finished  during  the last interval, no value is shown since
                resident memory occupation is not part of the standard process accounting record.

       RNET     The number of TCP- and UDP packets received by this  process.   This  information
                will only be shown when the optional module netatop or netatop-bpf is installed.
                If  a  process  has  finished  during  the last interval, no value is shown since
                network counters are not part of the standard process accounting record.

       RSIZE    The total resident memory usage consumed by this process (or user).  Notice  that
                the RSIZE of a process includes all resident memory used by that process, even if
                certain memory parts are shared with other processes (see also the explanation of
                PSIZE).
                If  a  process  has  finished  during  the last interval, no value is shown since
                resident memory occupation is not part of the standard process accounting record.

       RTPR     Realtime priority according the POSIX standard.  Value can be 0 for a timesharing
                process  (policy  'norm',  'btch'  or  'idle')  or ranges from 1 (lowest) till 99
                (highest) for a realtime process (policy 'rr' or 'fifo').

       RUID     The real user-id under which the process executes.

       S        The current state of the (main) thread: 'R' for running (currently processing  or
                in  the  runqueue),  'S' for sleeping interruptible (wait for an event to occur),
                'D' for sleeping non-interruptible, 'Z' for zombie (waiting  to  be  synchronized
                with  its  parent  process),  'T'  for  stopped  (suspended  or  traced), 'W' for
                swapping, and 'E' (exit) for  processes  which  have  finished  during  the  last
                interval.

       SGID     The saved group-id of the process.

       SNET     The  number of TCP and UDP packets transmitted by this process.  This information
                will only be shown when the optional module netatop or netatop-bpf is installed.

       ST       The status of a process.
                The first position indicates if the process has  been  started  during  the  last
                interval (the value N means 'new process').

                The  second  position  indicates if the process has been finished during the last
                interval.
                The value E means 'exit' on  the  process'  own  initiative;  the  exit  code  is
                displayed in the column 'EXC'.
                The value S means that the process has been terminated unvoluntarily by a signal;
                the signal number is displayed in the in the column 'EXC'.
                The value C means that the process has been terminated unvoluntarily by a signal,
                producing a core dump in its current directory; the signal number is displayed in
                the column 'EXC'.

       STDATE   The start date of the process.

       STTIME   The start time of the process.

       SUID     The saved user-id of the process.

       SWPMAX   The 'memory.swap.max' value of the cgroup  (version  2)  to  which  this  process
                belongs.

       SWAPSZ   The swap space consumed by this process (or user).

       SWMAXR   The  most  restrictive  (i.e.  effective)  'memory.swap.max' value defined by the
                upper directories of the cgroup (version 2) to which this process belongs.

       SYSCPU   CPU time consumption of this process in system mode (kernel mode), usually due to
                system call handling.

       TCPRASZ  The  average  size of a received TCP buffer in bytes.  This information will only
                be shown when the optional module netatop or netatop-bpf is installed.

       TCPRCV   The number of TCP packets received for this process.  This information will  only
                be shown when the optional module netatop or netatop-bpf is installed.

       TCPSASZ  The  average  size  of  a transmitted TCP buffer in bytes.  This information will
                only be shown when the optional module netatop or netatop-bpf is installed.

       TCPSND   The number of TCP packets transmitted for this process.   This  information  will
                only be shown when the optional module netatop or netatop-bpf is installed.

       THR      Total  number  of threads within this process.  All related threads are contained
                in a thread group, represented by atop as one line or as a separate line when the
                'y' key (or -y flag) is active.

                On  Linux  2.4  systems  it  is  hardly possible to determine which threads (i.e.
                processes) are related to the same thread group.  Every thread is represented  by
                atop as a separate line.

       TID      Thread-id.   All  threads  within  a  process  run  with  the same PID but with a
                different TID. This value is  shown  for  individual  threads  in  multi-threaded
                processes (when using the key 'y').

       TIDLE    Number  of  threads  within  this  process that are in the state 'idle' (I), i.e.
                uninterruptible sleeping threads that do not count for the load average.

       TRUN     Number of threads within this process that are in the state 'running' (R).

       TSLPI    Number of threads within this  process  that  are  in  the  state  'interruptible
                sleeping' (S).

       TSLPU    Number  of  threads  within  this  process that are in the state 'uninterruptible
                sleeping' (D).

       UDPRASZ  The average size of a received UDP packet in bytes.  This information  will  only
                be shown when the optional module netatop or netatop-bpf is installed.

       UDPRCV   The  number  of UDP packets received by this process.  This information will only
                be shown when the optional module netatop or netatop-bpf is installed.

       UDPSASZ  The average size of a transmitted UDP packets in bytes.   This  information  will
                only be shown when the optional module netatop or netatop-bpf is installed.

       UDPSND   The  number  of  UDP  packets transmitted by this process.  This information will
                only be shown when the optional module netatop or netatop-bpf is installed.

       USRCPU   CPU time consumption of this process in user mode,  due  to  processing  the  own
                program text.

       VDATA    The  virtual memory size of the private data used by this process (including heap
                and shared library data).

       VGROW    The amount of virtual memory that the process has grown during the last interval.
                A  virtual  growth can be caused by e.g. issuing a malloc() or attaching a shared
                memory segment. Note that a virtual growth can also be negative by e.g. issuing a
                free()  or detaching a shared memory segment.  For a process which started during
                the last interval, the virtual growth reflects the  total  virtual  size  of  the
                process at that moment.
                If  a  process  has  finished  during  the last interval, no value is shown since
                virtual memory occupation is not part of the standard process accounting record.

       VPID     Virtual process-id (within an OpenVZ container).  If a process has  been  started
                and  finished  during  the  last  interval,  a  '?'  is shown because the virtual
                process-id is not part of the standard process accounting record.

       VSIZE    The total virtual memory usage consumed by this process (or user).
                If a process has finished during the last  interval,  no  value  is  shown  since
                virtual memory occupation is not part of the standard process accounting record.

       VSLIBS   The virtual memory size of the (shared) text of all shared libraries used by this
                process.

       VSTACK   The virtual memory size of the (private) stack used by this process

       VSTEXT   The virtual memory size of the (shared) text of the executable program.

       WCHAN    Wait channel of thread in sleep state, i.e. the name of the  kernel  function  in
                which the thread has been put asleep.
                Since  determining  the  name string of the kernel function is a relatively time-
                consuming task, the 'W' key (or '-W' flag) should be active.

       WRDSK    The write data transfer issued physically on disk (so writing to the  disk  cache
                is  not  accounted  for).  This counter is maintained for the application process
                that writes its data  to  the  cache  (assuming  that  this  data  is  physically
                transferred  to  disk  later on). Notice that disk I/O needed for swapping is not
                taken into account.
                Unfortunately, the kernel aggregates the data transfer of a process to  the  data
                transfer  of  its parent process when terminating, so you might see transfers for
                (parent) processes like cron, bash or init, that are not really issued by them.

       WCANCL   The write data transfer previously accounted for this process or another  process
                that  has  been  cancelled.  Suppose that a process writes new data to a file and
                that data is removed again before the cache buffers have been  flushed  to  disk.
                Then the original process shows the written data as WRDSK, while the process that
                removes/truncates the file shows the unflushed removed data as WCANCL.

PARSABLE OUTPUT

       With the flag -P followed by a list of one  or  more  labels  (comma-separated),  parsable
       output  is  produced  for  each sample.  The labels that can be specified for system-level
       statistics correspond to the labels (first verb of each line) that can  be  found  in  the
       interactive  output: "CPU", "cpu", "CPL", "GPU", "MEM", "SWP", "PAG", "PSI", "LVM", "MDD",
       "DSK", "NFM", "NFC", "NFS", "NET", "IFB", "LLC", "NUM" and "NUC".
       For process-level statistics special labels are available: "PRG" (general),  "PRC"  (CPU),
       "PRE"  (GPU),  "PRM"  (memory),  "PRD"  (disk, only if "storage accounting" is active) and
       "PRN" (network, only if the optional module netatop or netatop-bpf is installed).
       With the label "ALL", all system and process level statistics are shown.

       The command and command line in the parsable output might contain spaces and are therefore
       by  default  surrounded  by parenthesis. However, since a space is often used as separator
       between the fields by parsing tools, with  the  additional  flag  -Z  it  is  possible  to
       exchange the spaces in the command (line) by underscores and omit the parenthesis.

       For  every  interval  all  requested  lines  are  shown  whereafter atop shows a line just
       containing the label "SEP" as a separator  before  the  lines  for  the  next  sample  are
       generated.
       When  a sample contains the values since boot, atop shows a line just containing the label
       "RESET" before the lines for this sample are generated.

       The first part of each output-line consists of the following six fields: label  (the  name
       of the label), host (the name of this machine), epoch (the time of this interval as number
       of seconds since 1-1-1970), date (date of this interval in format YYYY/MM/DD), time  (time
       of  this  interval  in  format HH:MM:SS), and interval (number of seconds elapsed for this
       interval).

       The subsequent fields of each output-line depend on the label:

       CPU      Subsequent fields: total number of  clock-ticks  per  second  for  this  machine,
                number  of  processors,  consumption  for  all CPUs in system mode (clock-ticks),
                consumption for all CPUs in user mode (clock-ticks), consumption for all CPUs  in
                user  mode  for  niced  processes (clock-ticks), consumption for all CPUs in idle
                mode  (clock-ticks),  consumption  for  all  CPUs  in  wait  mode  (clock-ticks),
                consumption  for  all CPUs in irq mode (clock-ticks), consumption for all CPUs in
                softirq mode (clock-ticks), consumption for all CPUs in steal mode (clock-ticks),
                consumption  for  all  CPUs  in  guest  mode (clock-ticks) overlapping user mode,
                frequency of all CPUs, frequency percentage of all CPUs, instructions executed by
                all CPUs and cycles for all CPUs.

       cpu      Subsequent  fields:  total  number  of  clock-ticks  per second for this machine,
                processor-number,  consumption  for  this  CPU  in  system  mode   (clock-ticks),
                consumption  for this CPU in user mode (clock-ticks), consumption for this CPU in
                user mode for niced processes (clock-ticks), consumption for  this  CPU  in  idle
                mode  (clock-ticks),  consumption  for  this  CPU  in  wait  mode  (clock-ticks),
                consumption for this CPU in irq mode (clock-ticks), consumption for this  CPU  in
                softirq mode (clock-ticks), consumption for this CPU in steal mode (clock-ticks),
                consumption for this CPU in  guest  mode  (clock-ticks)  overlapping  user  mode,
                frequency of this CPU, frequency percentage of this CPU, instructions executed by
                this CPU and cycles for this CPU.

       CPL      Subsequent fields: number of processors,  load  average  for  last  minute,  load
                average  for  last five minutes, load average for last fifteen minutes, number of
                context-switches, and number of device interrupts.

       GPU      Subsequent fields: GPU number, bus-id  string,  type  of  GPU  string,  GPU  busy
                percentage  during  last  second  (-1  if  not available), memory busy percentage
                during last second (-1 if not available), total memory size  (KiB),  used  memory
                (KiB)  at  this  moment,  number of samples taken during interval, cumulative GPU
                busy percentage during the interval (to be divided by the number of  samples  for
                the  average  busy  percentage,  -1  if  not  available),  cumulative memory busy
                percentage during the interval (to be divided by the number of  samples  for  the
                average  busy  percentage, -1 if not available), and cumulative memory occupation
                during the interval (to be divided by the  number  of  samples  for  the  average
                occupation).

       MEM      Subsequent fields: page size for this machine (in bytes), size of physical memory
                (pages), size of free memory (pages), size of page cache (pages), size of  buffer
                cache  (pages),  size  of slab (pages), dirty pages in cache (pages), reclaimable
                part of slab (pages), total size of vmware's balloon pages (pages), total size of
                shared  memory  (pages),  size of resident shared memory (pages), size of swapped
                shared memory (pages), smaller huge page size (in bytes), total size  of  smaller
                huge  pages  (huge  pages), size of free smaller huge pages (huge pages), size of
                ARC (cache) of ZFSonlinux (pages), size of sharing pages for KSM (pages), size of
                shared  pages  for KSM (pages), size of memory used for TCP sockets (pages), size
                of memory used for UDP sockets (pages), size of pagetables (pages),  larger  huge
                page  size (in bytes), total size of larger huge pages (huge pages), size of free
                larger huge pages  (huge  pages),  size  of  available  memory  (pages)  for  new
                workloads  without  swapping,  and  size  of  anonymous  transparent  huge  pages
                ('normal' pages).

       SWP      Subsequent fields: page size for this machine (in bytes), size of  swap  (pages),
                size  of  free  swap (pages), size of swap cache (pages), size of committed space
                (pages), limit for committed space (pages), size of the swap cache  (pages),  the
                real  (decompressed)  size  of the pages stored in zswap (pages), and the size of
                compressed storage used for zswap (pages).

       LLC      Subsequent fields: LLC id, percentage of LLC in use, total  memory  bandwidth  of
                this  LLC  (in  bytes),  and  memory bandwidth on local NUMA node of this LLC (in
                bytes).

       PAG      Subsequent fields: page size for this machine (in bytes), number of  page  scans,
                number  of  allocstalls,  0  (future use), number of swapins, number of swapouts,
                number of oomkills (-1 when counter not present), number of process stalls to run
                memory compaction, number of pages successfully migrated in total, number of NUMA
                pages migrated, number of pages read from block devices, number of pages  written
                to block devices, number of swapins from zswap, and number of swapouts to zswap.

       PSI      Subsequent  fields:  PSI  statistics  present  on  this system (n or y), CPU some
                avg10, CPU some avg60, CPU some avg300, CPU some accumulated microseconds  during
                interval,  memory  some avg10, memory some avg60, memory some avg300, memory some
                accumulated microseconds during interval, memory full avg10, memory  full  avg60,
                memory  full  avg300,  memory  full accumulated microseconds during interval, I/O
                some avg10, I/O some avg60, I/O some avg300, I/O  some  accumulated  microseconds
                during  interval,  I/O  full avg10, I/O full avg60, I/O full avg300, and I/O full
                accumulated microseconds during interval.

       LVM/MDD/DSK
                For every logical volume/multiple device/hard disk one line is shown.
                Subsequent fields: name, number of milliseconds spent for I/O,  number  of  reads
                issued,  number of sectors transferred for reads, number of writes issued, number
                of  sectors  transferred  for  write,  number  of  discards  issued  (-1  if  not
                supported),  number  of  sectors  transferred  for  discards,  number of requests
                currently in flight (not yet completed), and the average queue  depth  while  the
                disk was busy.

       NFM      Subsequent  fields:  mounted  NFS  filesystem,  total number of bytes read, total
                number of bytes written, number of bytes read by normal system calls,  number  of
                bytes  written by normal system calls, number of bytes read by direct I/O, number
                of bytes written by direct I/O, number of pages read by  memory-mapped  I/O,  and
                number of pages written by memory-mapped I/O.

       NFC      Subsequent  fields:  number of transmitted RPCs, number of transmitted read RPCs,
                number of transmitted write RPCs, number of RPC retransmissions,  and  number  of
                authorization refreshes.

       NFS      Subsequent  fields:  number of handled RPCs, number of received read RPCs, number
                of received write RPCs, number of bytes read by clients, number of bytes  written
                by   clients,   number  of  RPCs  with  bad  format,  number  of  RPCs  with  bad
                authorization, number of RPCs from bad client, total number  of  handled  network
                requests,  number  of handled network requests via TCP, number of handled network
                requests via UDP, number of handled TCP connections,  number  of  hits  on  reply
                cache, number of misses on reply cache, and number of uncached requests.

       NET      First, one line is produced for the upper layers of the TCP/IP stack.
                Subsequent fields: the verb "upper", number of packets received by TCP, number of
                packets transmitted by TCP, number of packets received by UDP, number of  packets
                transmitted  by  UDP,  number  of  packets  received  by  IP,  number  of packets
                transmitted by IP, number of packets delivered to higher layers by IP, number  of
                packets  forwarded  by  IP, number of input errors (UDP), number of noport errors
                (UDP), number of active opens (TCP), number of passive  opens  (TCP),  number  of
                passive  opens  (TCP),  number  of  established connections at this moment (TCP),
                number of retransmitted segments (TCP), number of input errors (TCP),  number  of
                output resets (TCP), and number of checksum errors on received packets (TCP).

                Next, one line is shown for every interface.
                Subsequent  fields:  name  of  the  interface,  number of packets received by the
                interface,  number  of  bytes  received  by  the  interface,  number  of  packets
                transmitted  by  the  interface,  number  of  bytes transmitted by the interface,
                interface speed, and duplex mode (0=half, 1=full).

       IFB      Subsequent fields: name of the  InfiniBand  interface,  port  number,  number  of
                lanes,   maximum   rate  (Mbps),  number  of  bytes  received,  number  of  bytes
                transmitted, number of packets received, and number of packets transmitted.

       NUM      Subsequent fields: NUMA node number, page size for this machine (in  bytes),  the
                fragmentation  percentage  of this node, size of physical memory (pages), size of
                free memory  (pages),  recently  (active)  used  memory  (pages),  less  recently
                (inactive)  used memory (pages), size of cached file data (pages), dirty pages in
                cache (pages), slab memory being used for kernel  mallocs  (pages),  slab  memory
                that  is  reclaimable  (pages), shared memory including tmpfs (pages), total huge
                pages (huge pages), and free huge pages (huge pages).

       NUC      Subsequent fields:  NUMA  node  number,  number  of  processors  for  this  node,
                consumption for node CPUs in system mode (clock-ticks), consumption for node CPUs
                in user mode (clock-ticks), consumption for node CPUs  in  user  mode  for  niced
                processes  (clock-ticks),  consumption  for node CPUs in idle mode (clock-ticks),
                consumption for node CPUs in wait mode (clock-ticks), consumption for  node  CPUs
                in  irq  mode  (clock-ticks),  consumption  for node CPUs in softirq mode (clock-
                ticks), consumption for node CPUs in steal mode  (clock-ticks),  and  consumption
                for node CPUs in guest mode (clock-ticks) overlapping user mode.

       PRG      For every process one line is shown.
                Subsequent  fields:  PID  (unique  ID  of  task),  name  (between  parenthesis or
                underscores for spaces), state, real uid, real gid, TGID (group number of related
                tasks/threads),  total  number  of  threads,  exit code (in case of fatal signal:
                signal number + 256), start time (epoch), full command line (between  parenthesis
                or  underscores  for  spaces),  PPID,  number  of threads in state 'running' (R),
                number of threads in state 'interruptible sleeping' (S),  number  of  threads  in
                state  'uninterruptible  sleeping'  (D), effective uid, effective gid, saved uid,
                saved gid, filesystem uid, filesystem gid, elapsed  time  of  terminated  process
                (hertz),  is_process  (y/n),  OpenVZ   virtual  pid  (VPID),  OpenVZ container id
                (CTID), container/pod name (CID/POD), indication if the  task  is  newly  started
                during  this  interval  ('N'),  cgroup  v2  path  name  (between  parenthesis  or
                underscores for spaces), end time (epoch or 0 if still  active),  and  number  of
                threads in state 'idle' (I).

       PRC      For every process one line is shown.
                Subsequent  fields:  PID,  name  (between parenthesis or underscores for spaces),
                state, total number of clock-ticks per second for this  machine,  CPU-consumption
                in  user  mode  (clockticks),  CPU-consumption  in system mode (clockticks), nice
                value, priority, realtime priority, scheduling policy, current CPU (-1 for exited
                process), sleep average, TGID (group number of related tasks/threads), is_process
                (y/n), runqueue delay in nanoseconds for this thread or for all threads (in  case
                of  process), wait channel of this thread (between parenthesis or underscores for
                spaces),  block  I/O  delay  (clockticks),  cgroup  v2  'cpu.max'  calculated  as
                percentage  (-3  means  no  cgroup  v2  support,  -2 means undefined and -1 means
                maximum), cgroup v2 most restrictive 'cpu.max' in upper directories calculated as
                percentage  (-3  means  no  cgroup  v2  support,  -2 means undefined and -1 means
                maximum), number of voluntary context switches, and number of involuntary context
                switches.

       PRE      For every process one line is shown.
                Subsequent  fields:  PID,  name  (between parenthesis or underscores for spaces),
                process state, GPU state (A for active, E for exited, N for no GPU user),  number
                of  GPUs  used by this process, bitlist reflecting used GPUs, GPU busy percentage
                during interval, memory busy percentage during interval, memory occupation  (KiB)
                at  this moment cumulative memory occupation (KiB) during interval, and number of
                samples taken during interval.

       PRM      For every process one line is shown.
                Subsequent fields: PID, name (between parenthesis  or  underscores  for  spaces),
                state, page size for this machine (in bytes), virtual memory size (KiB), resident
                memory size (KiB), shared text memory size (KiB), virtual  memory  growth  (KiB),
                resident  memory  growth (KiB), number of minor page faults, number of major page
                faults, virtual library exec size (KiB), virtual data size (KiB),  virtual  stack
                size  (KiB), swap space used (KiB), TGID (group number of related tasks/threads),
                is_process (y/n), proportional set size (KiB) if  in  'R'  option  is  specified,
                virtually  locked  memory space (KiB), cgroup v2 'memory.max' in KiB (-3 means no
                cgroup v2 support, -2 means undefined and  -1  means  maximum),  cgroup  v2  most
                restrictive  'memory.max'  in  upper  directories  in  KiB (-3 means no cgroup v2
                support, -2 means undefined and -1 means maximum), cgroup v2 'memory.swap.max' in
                KiB (-3 means no cgroup v2 support, -2 means undefined and -1 means maximum), and
                cgroup v2 most restrictive 'memory.swap.max' in  upper  directories  in  KiB  (-3
                means no cgroup v2 support, -2 means undefined and -1 means maximum).

       PRD      For every process one line is shown.
                Subsequent  fields:  PID,  name  (between parenthesis or underscores for spaces),
                state, obsoleted kernel patch installed ('n'), standard io statistics  used  ('y'
                or  'n'),  number  of reads on disk, cumulative number of sectors read, number of
                writes on disk, cumulative number of sectors written, cancelled number of written
                sectors, TGID (group number of related tasks/threads), obsoleted value ('n'), and
                is_process (y/n).

       PRN      For every process one line is shown.
                Subsequent fields: PID, name (between parenthesis  or  underscores  for  spaces),
                state,  kernel  module  netatop  or netatop-bpf installed ('y' or 'n'), number of
                TCP-packets transmitted, cumulative size of TCP-packets  transmitted,  number  of
                TCP-packets  received,  cumulative  size  of TCP-packets received, number of UDP-
                packets transmitted, cumulative size of UDP-packets transmitted, number  of  UDP-
                packets  received,  cumulative  size  of  UDP-packets  transmitted, number of raw
                packets  transmitted  (obsolete,  always  0),  number  of  raw  packets  received
                (obsolete, always 0), TGID (group number of related tasks/threads) and is_process
                (y/n).
                If the kernel module is not active, the network I/O counters per process are  not
                relevant.

JSON OUTPUT

       With  the  flag -J followed by a list of one or more labels (comma-separated), JSON output
       is produced for each sample. The syntax and name of JSON labels are the same  as  for  the
       parsable output.

SIGNALS

       By  sending  the  SIGUSR1  signal to atop a new sample will be forced, even if the current
       timer interval has not exceeded yet. The behavior is similar to pressing the 't' key in an
       interactive session.

       By  sending the SIGUSR2 signal to atop a final sample will be forced after which atop will
       terminate.

EXAMPLES

       To monitor the current system load in text mode with an interval of (default) 10 seconds:

         atop

       To monitor the current system load as bar graphs with an interval of 5 seconds:

         atop -B 5

       Store information about the system and process activity in binary  compressed  form  to  a
       file with an interval of ten minutes during an hour:

         atop -w /tmp/atop.raw 600 6

       View the contents of this file interactively:

         atop -r /tmp/atop.raw

       View the processor and disk utilization of this file in parsable format:

         atop -PCPU,DSK -r /tmp/atop.raw

       View the contents of today's standard logfile interactively:

         atop -r

       View the contents of the standard logfile of the day before yesterday interactively:

         atop -r yy

       View  the  contents  of  the  standard  logfile  of  2023,  April 15 from 02:00 PM onwards
       interactively:

         atop -r 20230415 -b 1400

       Concatenate all raw log files of March 2023 and generate parsable  output  about  the  CPU
       utilization:

         atopcat /var/log/atop/atop_202303?? | atop -r - -PCPU

       To monitor the system load and write it to a file (in plain ASCII) with an interval of one
       minute during half an hour with active processes sorted on memory consumption:

         atop -M 60 30 > /log/atop.mem

FILES

       /run/pacct_shadow.d/
            Directory containing the process accounting shadow files that are used by  atop  when
            the atopacctd daemon is active.

       /var/cache/atop.d/atop.acct
            File in which the kernel writes the accounting records when atop itself has activated
            the process accounting mechanism.

       /etc/atoprc
            Configuration file containing system-wide default values.   For  further  information
            about the default values, refer to the atoprc man page).

       ~/.atoprc
            Configuration file containing personal default values.  For further information about
            the default values, refer to the atoprc man page).

       /etc/default/atop
            Configuration file to overrule the settings of atop that runs in  the  background  to
            create  the daily logfile.  This file is created when atop is installed.  The default
            settings are:

       LOGOPTS=""
               LOGINTERVAL=600
               LOGGENERATIONS=28

       /var/log/atop/atop_YYYYMMDD
            Raw file, where YYYYMMDD are digits representing the current date.  This name is used
            by atop running in the background as default name for the output file, and by atop as
            default name for the input file when using the -r flag.
            All binary system and process level data in this file has been stored  in  compressed
            format.

       /run/netatop.log
            File  that  contains the netpertask structs containing the network counters of exited
            processes. These structs are written by the netatopd daemon (which is related to  the
            netatop  module)  and  read  by  atop  after  reading the standard process accounting
            records.

SEE ALSO

       atopsar(1), atopconvert(1), atopcat(1), atophide(1), atoprc(5), atopacctd(8),  netatop(4),
       netatopd(8), atopgpud(8), logrotate(8)
       https://www.atoptool.nl

AUTHOR

       Gerlof Langeveld (gerlof.langeveld@atoptool.nl)
       JC van Winkel