Provided by: nvidia-utils-550-server_550.90.12-0ubuntu2_amd64 bug

NAME

       nvidia-smi - NVIDIA System Management Interface program

SYNOPSIS

       nvidia-smi [OPTION1 [ARG1]] [OPTION2 [ARG2]] ...

DESCRIPTION

       nvidia-smi  (also  NVSMI)  provides  monitoring  and  management  capabilities for each of
       NVIDIA's Tesla, Quadro, GRID and  GeForce  devices  from  Fermi  and  higher  architecture
       families.  GeForce Titan series devices are supported for most functions with very limited
       information provided for the remainder of the Geforce brand.  NVSMI is  a  cross  platform
       tool  that  supports  all standard NVIDIA driver-supported Linux distros, as well as 64bit
       versions of Windows starting with  Windows  Server  2008  R2.   Metrics  can  be  consumed
       directly  by  users  via stdout, or provided by file via CSV and XML formats for scripting
       purposes.

       Note that much of the functionality of NVSMI is provided by the  underlying  NVML  C-based
       library.   See  the  NVIDIA  developer website link below for more information about NVML.
       NVML-based python bindings are also available.

       The output of NVSMI is not guaranteed to be backwards compatible. However, both  NVML  and
       the  Python bindings are backwards compatible, and should be the first choice when writing
       any tools that must be maintained across NVIDIA driver releases.

       NVML SDK: http://developer.nvidia.com/nvidia-management-library-nvml/

       Python bindings: http://pypi.python.org/pypi/nvidia-ml-py/

OPTIONS

   GENERAL OPTIONS
   -h, --help
       Print usage information and exit.

   --version
       Print version information and exit.

   LIST OPTIONS
   -L, --list-gpus
       List each of the NVIDIA GPUs in the system, along with their UUIDs.

   -B, --list-excluded-gpus
       List each of the excluded NVIDIA GPUs in the system, along with their UUIDs.

   SUMMARY OPTIONS
   Show a summary of GPUs connected to the system.
   [any one of]
   -i, --id=ID
       Target a specific GPU.

   -f FILE, --filename=FILE
       Log to the specified file, rather than to stdout.

   -l SEC, --loop=SEC
       Probe until Ctrl+C at specified second interval.

   QUERY OPTIONS
   -q, --query
       Display GPU or Unit info.  Displayed info includes all data listed in the (GPU ATTRIBUTES)
       or  (UNIT  ATTRIBUTES)  sections of this document.  Some devices and/or environments don't
       support all possible information.  Any unsupported data is indicated by  a  "N/A"  in  the
       output.   By default information for all available GPUs or Units is displayed.  Use the -i
       option to restrict the output to a single GPU or Unit.

   [plus optionally]
   -u, --unit
       Display Unit data instead of GPU data.  Unit data is only  available  for  NVIDIA  S-class
       Tesla enclosures.

   -i, --id=ID
       Display  data  for a single specified GPU or Unit.  The specified id may be the GPU/Unit's
       0-based index in the natural enumeration returned by the driver, the  GPU's  board  serial
       number,  the  GPU's  UUID, or the GPU's PCI bus ID (as domain:bus:device.function in hex).
       It is recommended that users desiring consistency use either UUID or  PCI  bus  ID,  since
       device  enumeration  ordering is not guaranteed to be consistent between reboots and board
       serial number might be shared between multiple GPUs on the same board.

   -f FILE, --filename=FILE
       Redirect query output to the specified file in place of the default stdout.  The specified
       file will be overwritten.

   -x, --xml-format
       Produce XML output in place of the default human-readable format.  Both GPU and Unit query
       outputs conform to corresponding DTDs.  These are available via the --dtd flag.

   --dtd
       Use with -x.  Embed the DTD in the XML output.

   --debug=FILE
       Produces an encrypted debug log for use in submission of bugs back to NVIDIA.

   -d TYPE, --display=TYPE
       Display only selected information: MEMORY, UTILIZATION, ECC,  TEMPERATURE,  POWER,  CLOCK,
       COMPUTE,  PIDS, PERFORMANCE, SUPPORTED_CLOCKS, PAGE_RETIREMENT, ACCOUNTING, ENCODER_STATS,
       SUPPORTED_GPU_TARGET_TEMP,     VOLTAGE,     FBC_STATS,     ROW_REMAPPER,     RESET_STATUS,
       GSP_FIRMWARE_VERSION.  Flags can be combined with comma e.g.  "MEMORY,ECC".  Sampling data
       with max, min and avg is also returned for POWER, UTILIZATION  and  CLOCK  display  types.
       Doesn't work with -u/--unit or -x/--xml-format flags.

   -l SEC, --loop=SEC
       Continuously  report query data at the specified interval, rather than the default of just
       once.  The application will sleep in-between queries.  Note that on Linux ECC error or XID
       error  events  will  print  out  during the sleep period if the -x flag was not specified.
       Pressing Ctrl+C at any time will abort the loop, which will  otherwise  run  indefinitely.
       If no argument is specified for the -l form a default interval of 5 seconds is used.

   -lms ms, --loop-ms=ms
       Same as -l,--loop but in milliseconds.

   SELECTIVE QUERY OPTIONS
       Allows the caller to pass an explicit list of properties to query.

   [one of]
   --query-gpu=
       Information  about  GPU.  Pass comma separated list of properties you want to query.  e.g.
       --query-gpu=pci.bus_id,persistence_mode.  Call --help-query-gpu for more info.

   --query-supported-clocks=
       List of supported clocks.  Call --help-query-supported-clocks for more info.

   --query-compute-apps=
       List of currently active compute processes.  Call --help-query-compute-apps for more info.

   --query-accounted-apps=
       List of accounted compute processes.   Call  --help-query-accounted-apps  for  more  info.
       This query is not supported on vGPU host.

   --query-retired-pages=
       List  of  GPU device memory pages that have been retired.  Call --help-query-retired-pages
       for more info.

   --query-remapped-rows=
       Information about remapped rows.  Call --help-query-remapped-rows for more info.

   [mandatory]
   --format=
       Comma separated list of format options:

       •      csv - comma separated values (MANDATORY)

       •      noheader - skip first line with column headers

       •      nounits - don't print units for numerical values

   [plus any of]
   -i, --id=ID
       Display data for a single specified GPU.  The specified id may be the GPU's 0-based  index
       in  the  natural  enumeration  returned  by the driver, the GPU's board serial number, the
       GPU's UUID, or the GPU's PCI  bus  ID  (as  domain:bus:device.function  in  hex).   It  is
       recommended  that  users  desiring consistency use either UUID or PCI bus ID, since device
       enumeration ordering is not guaranteed to be consistent between reboots and  board  serial
       number might be shared between multiple GPUs on the same board.

   -f FILE, --filename=FILE
       Redirect query output to the specified file in place of the default stdout.  The specified
       file will be overwritten.

   -l SEC, --loop=SEC
       Continuously report query data at the specified interval, rather than the default of  just
       once.  The application will sleep in-between queries.  Note that on Linux ECC error or XID
       error events will print out during the sleep period if the  -x  flag  was  not  specified.
       Pressing  Ctrl+C  at  any time will abort the loop, which will otherwise run indefinitely.
       If no argument is specified for the -l form a default interval of 5 seconds is used.

   -lms ms, --loop-ms=ms
       Same as -l,--loop but in milliseconds.

   DEVICE MODIFICATION OPTIONS
   [any one of]
   -pm, --persistence-mode=MODE
       Set the persistence mode for the target GPUs.  See the  (GPU  ATTRIBUTES)  section  for  a
       description of persistence mode.  Requires root.  Will impact all GPUs unless a single GPU
       is specified using the -i argument.  The effect of this operation is immediate.   However,
       it  does  not  persist across reboots.  After each reboot persistence mode will default to
       "Disabled".  Available on Linux only.

   -e, --ecc-config=CONFIG
       Set the ECC mode for the target GPUs.  See the (GPU ATTRIBUTES) section for a  description
       of  ECC mode.  Requires root.  Will impact all GPUs unless a single GPU is specified using
       the -i argument.  This setting takes effect after the next reboot and is persistent.

   -p, --reset-ecc-errors=TYPE
       Reset the ECC error counters for the target GPUs.  See the (GPU ATTRIBUTES) section for  a
       description   of   ECC  error  counter  types.   Available  arguments  are  0|VOLATILE  or
       1|AGGREGATE.  Requires root.  Will impact all GPUs unless a single GPU is specified  using
       the -i argument.  The effect of this operation is immediate.

   -c, --compute-mode=MODE
       Set  the  compute  mode  for  the  target  GPUs.   See  the (GPU ATTRIBUTES) section for a
       description of compute mode.  Requires root.  Will impact all GPUs unless a single GPU  is
       specified  using the -i argument.  The effect of this operation is immediate.  However, it
       does not persist across reboots.  After each reboot compute mode will reset to "DEFAULT".

   -dm TYPE, --driver-model=TYPE
   -fdm TYPE, --force-driver-model=TYPE
       Enable or disable TCC driver model.  For Windows only.  Requires administrator privileges.
       -dm  will  fail  if a display is attached, but -fdm will force the driver model to change.
       Will impact all GPUs unless a single GPU is specified using the -i argument.  A reboot  is
       required  for  the change to take place.  See Driver Model for more information on Windows
       driver models.

        --gom=MODE
       Set GPU Operation Mode: 0/ALL_ON, 1/COMPUTE, 2/LOW_DP Supported on GK110  M-class  and  X-
       class  Tesla  products  from the Kepler family.  Not supported on Quadro and Tesla C-class
       products.  LOW_DP and ALL_ON are the  only  modes  supported  on  GeForce  Titan  devices.
       Requires administrator privileges.  See GPU Operation Mode for more information about GOM.
       GOM changes take effect after reboot.  The reboot requirement  might  be  removed  in  the
       future.  Compute only GOMs don't support WDDM (Windows Display Driver Model)

   -r, --gpu-reset
       Trigger  a  reset  of  one  or  more  GPUs.   Can  be used to clear GPU HW and SW state in
       situations that would otherwise require a machine reboot.  Typically useful  if  a  double
       bit ECC error has occurred.  Optional -i switch can be used to target one or more specific
       devices.  Without this option, all GPUs are reset.  Requires root.   There  can't  be  any
       applications  using  these  devices  (e.g.  CUDA  application, graphics application like X
       server, monitoring application like other instance of nvidia-smi).  There  also  can't  be
       any compute applications running on any other GPU in the system if individual GPU reset is
       not feasible.

       Starting with the  NVIDIA  Ampere  architecture,  GPUs  with  NVLink  connections  can  be
       individually  reset.  On Ampere NVSwitch systems, Fabric Manager is required to facilitate
       reset. On Hopper  and  later  NVSwitch  systems,  the  dependency  on  Fabric  Manager  to
       facilitate reset is removed.

       If  Fabric  Manager  is  not  running,  or  if any of the GPUs being reset are based on an
       architecture preceding the NVIDIA Ampere architecture, any GPUs with NVLink connections to
       a  GPU  being  reset  must  also be reset in the same command.  This can be done either by
       omitting the -i switch, or using the -i switch to specify the GPUs to be reset.  If the -i
       option does not specify a complete set of NVLink GPUs to reset, this command will issue an
       error identifying the additional GPUs that must be included in the reset command.

       GPU reset is not guaranteed to work in all cases. It is  not  recommended  for  production
       environments  at  this  time.   In some situations there may be HW components on the board
       that fail to revert back to an initial state following the reset request.   This  is  more
       likely  to  be seen on Fermi-generation products vs. Kepler, and more likely to be seen if
       the reset is being performed on a hung GPU.

       Following a reset, it is recommended that the health of each reset GPU be verified  before
       further  use.   If  any  GPU is not healthy a complete reset should be instigated by power
       cycling the node.

       GPU reset operation will not be supported on MIG enabled vGPU guests.

       Visit http://developer.nvidia.com/gpu-deployment-kit to download the GDK.

   -vm, --virt-mode=MODE
       Switch GPU Virtualization  Mode.  Sets  GPU  virtualization  mode  to  3/VGPU  or  4/VSGA.
       Virtualization mode of a GPU can only be set when it is running on a hypervisor.

   -lgc, --lock-gpu-clocks=MIN_GPU_CLOCK,MAX_GPU_CLOCK
       Specifies <minGpuClock,maxGpuClock> clocks as a pair (e.g. 1500,1500) that defines closest
       desired locked GPU clock speed in MHz.  Input can also use be  a  singular  desired  clock
       value  (e.g.  <GpuClockValue>).   Optionally,  --mode can be supplied to specify the clock
       locking modes.  Supported on Volta+.  Requires root

       --mode=0 (Default)
                      This mode is the default  clock  locking  mode  and  provides  the  highest
                      possible frequency accuracies supported by the hardware.

       --mode=1       The  clock  locking  algorithm  leverages close loop controllers to achieve
                      frequency accuracies with improved perf  per  watt  for  certain  class  of
                      applications.  Due  to  convergence  latency of close loop controllers, the
                      frequency accuracies may be slightly lower than default mode 0.

   -lmc, --lock-memory-clocks=MIN_MEMORY_CLOCK,MAX_MEMORY_CLOCK
       Specifies <minMemClock,maxMemClock> clocks as a pair (e.g.  5100,5100)  that  defines  the
       range  of  desired  locked Memory clock speed in MHz. Input can also be a singular desired
       clock value (e.g. <MemClockValue>).

   -rgc, --reset-gpu-clocks
       Resets the GPU clocks to the default value.  Supported on Volta+.  Requires root.

   -rmc, --reset-memory-clocks
       Resets the memory clocks to the default value.  Supported on Volta+.  Requires root.

   -ac, --applications-clocks=MEM_CLOCK,GRAPHICS_CLOCK
       Specifies maximum <memory,graphics> clocks as a pair (e.g. 2000,800)  that  defines  GPU's
       speed  while  running  applications on a GPU.  Supported on Maxwell-based GeForce and from
       the Kepler+ family in Tesla/Quadro/Titan devices.  Requires root.

   -rac, --reset-applications-clocks
       Resets the applications clocks to the default value.  Supported on  Maxwell-based  GeForce
       and from the Kepler+ family in Tesla/Quadro/Titan devices.  Requires root.

   -lmcd, --lock-memory-clocks-deferred
       Specifies  the  memory  clock  that  defines  the closest desired Memory Clock in MHz. The
       memory clock takes effect the next time the GPU is initialized. This can be guaranteed  by
       unloading and reloading the kernel module.  Requires root.

   -rmcd, --reset-memory-clocks-deferred
       Resets the memory clock to default value. Driver unload and reload is required for this to
       take effect. This can be done by unloading and  reloading  the  kernel  module.   Requires
       root.

   -pl, --power-limit=POWER_LIMIT
       Specifies  maximum  power limit in watts.  Accepts integer and floating point numbers.  it
       takes an optional argument  --scope.   Only  on  supported  devices  from  Kepler  family.
       Requires  administrator  privileges.  Value needs to be between Min and Max Power Limit as
       reported by nvidia-smi.

   -sc, --scope=0/GPU, 1/TOTAL_MODULE
       Specifies the scope of the power limit.  Following  are  the  options:  0/GPU:  This  only
       changes  power  limits  for  the  GPU  1/Module:  This  changes  the  power for the module
       containing multiple components. E.g. GPU and CPU.

   -cc, --cuda-clocks=MODE
       Overrides or restores default CUDA clocks Available  arguments  are  0|RESTORE_DEFAULT  or
       1|OVERRIDE.

   -am, --accounting-mode=MODE
       Enables  or  disables  GPU Accounting.  With GPU Accounting one can keep track of usage of
       resources throughout lifespan of a single process.  Only on supported devices from  Kepler
       family.   Requires  administrator  privileges.   Available  arguments  are  0|DISABLED  or
       1|ENABLED.

   -caa, --clear-accounted-apps
       Clears all processes accounted so far.  Only on  supported  devices  from  Kepler  family.
       Requires administrator privileges.

        --auto-boost-default=MODE
       Set  the  default  auto boost policy to 0/DISABLED or 1/ENABLED, enforcing the change only
       after the last boost client has exited.  Only on certain Tesla devices  from  the  Kepler+
       family and Maxwell-based GeForce devices.  Requires root.

        --auto-boost-permission=MODE
       Allow   non-admin/root   control   over   auto   boost   mode.   Available  arguments  are
       0|UNRESTRICTED, 1|RESTRICTED.  Only on certain Tesla devices from the Kepler+  family  and
       Maxwell-based GeForce devices.  Requires root.

   -mig, --multi-instance-gpu=MODE
       Enables  or  disables  Multi  Instance  GPU  mode.  Only supported on devices based on the
       NVIDIA Ampere  architecture.   Requires  root.   Available  arguments  are  0|DISABLED  or
       1|ENABLED.

   -gtt, --gpu-target-temp=MODE
       Set  GPU  Target  Temperature  for  a  GPU  in  degree  celsius.   Requires  administrator
       privileges.  Target temperature should be within limits supported by  GPU.   These  limits
       can be retrieved by using query option with SUPPORTED_GPU_TARGET_TEMP.

   [plus optionally]
   -i, --id=ID
       Modify  a  single  specified GPU.  The specified id may be the GPU/Unit's 0-based index in
       the natural enumeration returned by the driver, the GPU's board serial number,  the  GPU's
       UUID,  or  the GPU's PCI bus ID (as domain:bus:device.function in hex).  It is recommended
       that users desiring consistency use either UUID or PCI bus ID,  since  device  enumeration
       ordering  is not guaranteed to be consistent between reboots and board serial number might
       be shared between multiple GPUs on the same board.

   -eom, --error-on-warning
       Return a non-zero error for warnings.

   UNIT MODIFICATION OPTIONS
   -t, --toggle-led=STATE
       Set the LED indicator state on the front and back of the unit to the specified color.  See
       the  (UNIT  ATTRIBUTES)  section  for a description of the LED states.  Allowed colors are
       0|GREEN and 1|AMBER.  Requires root.

   [plus optionally]
   -i, --id=ID
       Modify a single specified Unit.  The specified id is  the  Unit's  0-based  index  in  the
       natural enumeration returned by the driver.

   SHOW DTD OPTIONS
   --dtd
       Display Device or Unit DTD.

   [plus optionally]
   -f FILE, --filename=FILE
       Redirect query output to the specified file in place of the default stdout.  The specified
       file will be overwritten.

   -u, --unit
       Display Unit DTD instead of device DTD.

   topo
       Display topology information  about  the  system.   Use  "nvidia-smi  topo  -h"  for  more
       information.   Linux  only.   Shows  all GPUs NVML is able to detect but CPU and NUMA node
       affinity information will only be shown for  GPUs  with  Kepler  or  newer  architectures.
       Note: GPU enumeration is the same as NVML.

   drain
       Display  and  modify  the  GPU  drain states.  A drain state is one in which the GPU is no
       longer accepting new clients, and is used while preparing  to  power  down  the  GPU.  Use
       "nvidia-smi drain -h" for more information. Linux only.

   nvlink
       Display nvlink information.  Use "nvidia-smi nvlink -h" for more information.

   clocks
       Query and control clocking behavior. Use "nvidia-smi clocks --help" for more information.

   vgpu
       Display information on GRID virtual GPUs. Use "nvidia-smi vgpu -h" for more information.

   mig
       Provides controls for MIG management.

   boost-slider
       Provides controls for boost sliders management.

   power-hint
       Provides queries for power hint.

   conf-compute
       Provides control and queries for confidential compute.

RETURN VALUE

       Return  code reflects whether the operation succeeded or failed and what was the reason of
       failure.

       •      Return code 0 - Success

       •      Return code 2 - A supplied argument or flag is invalid

       •      Return code 3 - The requested operation is not available on target device

       •      Return code 4 - The current user does not have permission to access this device  or
              perform this operation

       •      Return code 6 - A query to find an object was unsuccessful

       •      Return code 8 - A device's external power cables are not properly attached

       •      Return code 9 - NVIDIA driver is not loaded

       •      Return code 10 - NVIDIA Kernel detected an interrupt issue with a GPU

       •      Return code 12 - NVML Shared Library couldn't be found or loaded

       •      Return code 13 - Local version of NVML doesn't implement this function

       •      Return code 14 - infoROM is corrupted

       •      Return  code  15  -  The  GPU  has  fallen  off  the  bus  or  has otherwise become
              inaccessible

       •      Return code 255 - Other error or internal driver error occurred

GPU ATTRIBUTES

       The following list describes all possible data returned by the  -q  device  query  option.
       Unless otherwise noted all numerical results are base 10 and unitless.

   Timestamp
       The  current  system timestamp at the time nvidia-smi was invoked.  Format is "Day-of-week
       Month Day HH:MM:SS Year".

   Driver Version
       The version of the installed NVIDIA display driver.  This is an alphanumeric string.

   Attached GPUs
       The number of NVIDIA GPUs in the system.

   Product Name
       The official product name of the GPU.  This is an alphanumeric string.  For all products.

   Display Mode
       A flag that indicates whether a physical display (e.g. monitor) is currently connected  to
       any  of  the  GPU's  connectors.   "Enabled"  indicates  an  attached display.  "Disabled"
       indicates otherwise.

   Display Active
       A flag that indicates whether a display is  initialized  on  the  GPU's  (e.g.  memory  is
       allocated  on  the  device  for  display).   Display can be active even when no monitor is
       physically  attached.   "Enabled"  indicates  an  active  display.   "Disabled"  indicates
       otherwise.

   Persistence Mode
       A  flag  that  indicates whether persistence mode is enabled for the GPU.  Value is either
       "Enabled" or "Disabled".  When persistence mode  is  enabled  the  NVIDIA  driver  remains
       loaded  even when no active clients, such as X11 or nvidia-smi, exist.  This minimizes the
       driver load latency associated with running dependent apps, such as  CUDA  programs.   For
       all CUDA-capable products.  Linux only.

   Accounting Mode
       A  flag that indicates whether accounting mode is enabled for the GPU Value is either When
       accounting is enabled statistics are calculated for each compute process  running  on  the
       GPU.   Statistics  can be queried during the lifetime or after termination of the process.
       The execution time of process is reported as 0 while the process is in running  state  and
       updated   to   actual   execution   time   after   the   process   has   terminated.   See
       --help-query-accounted-apps for more info.

   Accounting Mode Buffer Size
       Returns the size of the circular buffer that holds list of processes that can  be  queried
       for accounting stats.  This is the maximum number of processes that accounting information
       will be stored for before information about  oldest  processes  will  get  overwritten  by
       information about new processes.

   Driver Model
       On Windows, the TCC and WDDM driver models are supported.  The driver model can be changed
       with the  (-dm)  or  (-fdm)  flags.   The  TCC  driver  model  is  optimized  for  compute
       applications.   I.E.  kernel launch times will be quicker with TCC.  The WDDM driver model
       is designed for graphics applications and is not  recommended  for  compute  applications.
       Linux does not support multiple driver models, and will always have the value of "N/A".

       Current        The driver model currently in use.  Always "N/A" on Linux.

       Pending        The  driver  model  that  will be used on the next reboot.  Always "N/A" on
                      Linux.

   Serial Number
       This number matches the serial number physically printed on each board.  It is a  globally
       unique immutable alphanumeric value.

   GPU UUID
       This  value  is the globally unique immutable alphanumeric identifier of the GPU.  It does
       not correspond to any physical label on the board.

   Minor Number
       The minor number for the device is such that the Nvidia device node file for each GPU will
       have the form /dev/nvidia[minor number].  Available only on Linux platform.

   VBIOS Version
       The BIOS of the GPU board.

   MultiGPU Board
       Whether or not this GPU is part of a multiGPU board.

   Board ID
       The  unique  board  ID assigned by the driver.  If two or more GPUs have the same board ID
       and the above "MultiGPU" field is true then the GPUs are on the same board.

   Inforom Version
       Version numbers for each object in the GPU board's inforom  storage.   The  inforom  is  a
       small,  persistent store of configuration and state data for the GPU.  All inforom version
       fields are numerical.  It can be useful to know these version  numbers  because  some  GPU
       features are only available with inforoms of a certain version or higher.

       If  any  of the fields below return Unknown Error additional Inforom verification check is
       performed and appropriate warning message is displayed.

       Image Version  Global version of the infoROM image.  Image version just like VBIOS version
                      uniquely describes the exact version of the infoROM flashed on the board in
                      contrast to infoROM object version which is only an indicator of  supported
                      features.

       OEM Object     Version for the OEM configuration data.

       ECC Object     Version for the ECC recording data.

       Power Object   Version for the power management data.

   Inforom BBX Object Flush
       Information about flushing of the blackbox data to the inforom storage.

       Latest Timestamp
                      The timestamp of the latest flush of the BBX Object during the current run.

       Latest Duration
                      The duration of the latest flush of the BBX Object during the current run.

   GPU Operation Mode
       GOM  allows  one  to  reduce  power  usage  and  optimize  GPU throughput by disabling GPU
       features.

       Each GOM is designed to meet specific user needs.

       In "All On" mode everything is enabled and running at full speed.

       The "Compute" mode is designed for running only compute tasks. Graphics operations are not
       allowed.

       The  "Low  Double Precision" mode is designed for running graphics applications that don't
       require high bandwidth double precision.

       GOM can be changed with the (--gom) flag.

       Supported on GK110 M-class and  X-class  Tesla  products  from  the  Kepler  family.   Not
       supported on Quadro and Tesla C-class products.  Low Double Precision and All On modes are
       the only modes available for supported GeForce Titan products.

       Current        The GOM currently in use.

       Pending        The GOM that will be used on the next reboot.

   PCI
       Basic PCI info for the device.  Some of this information may  change  whenever  cards  are
       added/removed/moved in a system.  For all products.

       Bus            PCI bus number, in hex

       Device         PCI device number, in hex

       Domain         PCI domain number, in hex

       Base Classcode PCI Base classcode, in hex

       Sub Classcode  PCI Sub classcode, in hex

       Device Id      PCI vendor device id, in hex

       Sub System Id  PCI Sub System id, in hex

       Bus Id         PCI bus id as "domain:bus:device.function", in hex

   GPU Link information
       The PCIe link generation and bus width

       Current        The  current  link generation and width.  These may be reduced when the GPU
                      is not in use.

       Maximum        The maximum link generation and width possible with  this  GPU  and  system
                      configuration.   For  example, if the GPU supports a higher PCIe generation
                      than the system supports then this reports the system PCIe generation.

   Bridge Chip
       Information related to Bridge Chip on the device. The bridge chip firmware is only present
       on certain boards and may display "N/A" for some newer multiGPUs boards.

       Type           The type of bridge chip. Reported as N/A if doesn't exist.

       Firmware Version
                      The firmware version of the bridge chip. Reported as N/A if doesn't exist.

   Replays Since Reset
       The number of PCIe replays since reset.

   Replay Number Rollovers
       The  number  of  PCIe replay number rollovers since reset. A replay number rollover occurs
       after 4 consecutive replays and results in retraining the link.

   Tx Throughput
       The GPU-centric transmission throughput across the PCIe bus in MB/s over  the  past  20ms.
       Only supported on Maxwell architectures and newer.

   Rx Throughput
       The  GPU-centric  receive throughput across the PCIe bus in MB/s over the past 20ms.  Only
       supported on Maxwell architectures and newer.

   Atomic Caps
       The PCIe atomic capablities of outbound/inbound operation  between  GPU  memory  and  Host
       memory (no peer to peer).

   Fan Speed
       The fan speed value is the percent of the product's maximum noise tolerance fan speed that
       the device's fan is currently intended to run at.  This value may exceed 100%  in  certain
       cases.   Note:  The  reported  speed  is the intended fan speed.  If the fan is physically
       blocked and unable to spin, this output will not match the actual fan speed.   Many  parts
       do  not  report  fan  speeds  because  they  rely  on  cooling via fans in the surrounding
       enclosure.  For all discrete products with dedicated fans.

   Performance State
       The current performance state for the GPU.  States range from P0 (maximum performance)  to
       P12 (minimum performance).

   Clocks Event Reasons
       Retrieves information about factors that are reducing the frequency of clocks.

       If all event reasons are returned as "Not Active" it means that clocks are running as high
       as possible.

       Idle           Nothing is running on the GPU and the clocks are dropping  to  Idle  state.
                      This limiter may be removed in a later release.

       Application Clocks Setting
                      GPU clocks are limited by applications clocks setting.  E.g. can be changed
                      using nvidia-smi --applications-clocks=

       SW Power Cap   SW Power Scaling algorithm is reducing the clocks  below  requested  clocks
                      because  the  GPU is consuming too much power.  E.g. SW power cap limit can
                      be changed with nvidia-smi --power-limit=

       HW Slowdown    HW Slowdown (reducing the core clocks by a factor of 2 or more) is engaged.
                      HW Thermal Slowdown and HW Power Brake will be displayed on Pascal+.

                      This is an indicator of:
                      * Temperature being too high (HW Thermal Slowdown)
                      *  External  Power  Brake  Assertion is triggered (e.g. by the system power
                      supply) (HW Power Brake Slowdown)
                      * Power draw is too high and Fast Trigger protection is reducing the clocks

       SW Thermal Slowdown
                      SW Thermal capping algorithm is  reducing  clocks  below  requested  clocks
                      because GPU temperature is higher than Max Operating Temp

   Sparse Operation Mode
       A  flag  that  indicates  whether  sparse operation mode is enabled for the GPU.  Value is
       either "Enabled" or "Disabled". Reported as "N/A" if not supported.

   FB Memory Usage
       On-board frame buffer memory information.  Reported total memory is affected by ECC state.
       If  ECC  is enabled the total available memory is decreased by several percent, due to the
       requisite parity bits.  The driver may also reserve a small amount of memory for  internal
       use,  even  without  active  work  on  the GPU.  On systems where GPUs are NUMA nodes, the
       accuracy of FB memory utilization provided by nvidia-smi depends on the memory  accounting
       of  the  operating  system.   This is because FB memory is managed by the operating system
       instead of the NVIDIA GPU driver.  Typically, pages  allocated  from  FB  memory  are  not
       released even after the process terminates to enhance performance.  In scenarios where the
       operating system is under memory pressure, it may resort to  utilizing  FB  memory.   Such
       actions  can  result  in  discrepancies  in  the  accuracy  of  memory reporting.  For all
       products.

       Total          Total size of FB memory.

       Reserved       Reserved size of FB memory.

       Used           Used size of FB memory.

       Free           Available size of FB memory.

   BAR1 Memory Usage
       BAR1 is used to map the FB (device memory) so that it can be directly accessed by the  CPU
       or by 3rd party devices (peer-to-peer on the PCIe bus).

       Total          Total size of BAR1 memory.

       Used           Used size of BAR1 memory.

       Free           Available size of BAR1 memory.

   Compute Mode
       The  compute  mode  flag indicates whether individual or multiple compute applications may
       run on the GPU.

       "Default" means multiple contexts are allowed per device.

       "Exclusive Process" means only one context is allowed per  device,  usable  from  multiple
       threads at a time.

       "Prohibited" means no contexts are allowed per device (no compute apps).

       "EXCLUSIVE_PROCESS"  was  added  in  CUDA  4.0.   Prior  CUDA  releases supported only one
       exclusive mode, which is equivalent to "EXCLUSIVE_THREAD" in CUDA 4.0 and beyond.

       For all CUDA-capable products.

   Utilization
       Utilization rates report how busy each GPU is over time, and can be used to determine  how
       much  an application is using the GPUs in the system.  Note: On MIG-enabled GPUs, querying
       the utilization of  encoder,  decoder,  jpeg,  ofa,  gpu,  and  memory  is  not  currently
       supported.

       Note:  During  driver  initialization  when ECC is enabled one can see high GPU and Memory
       Utilization readings.  This is caused by ECC Memory Scrubbing mechanism that is  performed
       during driver initialization.

       GPU            Percent  of  time  over  the  past  sample  period during which one or more
                      kernels was executing on the GPU.  The  sample  period  may  be  between  1
                      second and 1/6 second depending on the product.

       Memory         Percent  of  time  over the past sample period during which global (device)
                      memory was being read or written.  The  sample  period  may  be  between  1
                      second and 1/6 second depending on the product.

       Encoder        Percent  of  time  over the past sample period during which the GPU's video
                      encoder was being used.  The sampling rate is variable and can be  obtained
                      directly via the nvmlDeviceGetEncoderUtilization() API

       Decoder        Percent  of  time  over the past sample period during which the GPU's video
                      decoder was being used.  The sampling rate is variable and can be  obtained
                      directly via the nvmlDeviceGetDecoderUtilization() API

       JPEG           Percent  of  time  over  the past sample period during which the GPU's JPEG
                      decoder was being used.  The sampling rate is variable and can be  obtained
                      directly via the nvmlDeviceGetJpgUtilization() API

       OFA            Percent  of  time  over  the  past sample period during which the GPU's OFA
                      (Optical Flow Accelerator) was being used.  The sampling rate  is  variable
                      and can be obtained directly via the nvmlDeviceGetOfaUtilization() API

   Ecc Mode
       A  flag  that  indicates  whether  ECC  support  is  enabled.   May be either "Enabled" or
       "Disabled".  Changes to ECC mode require a reboot.  Requires Inforom  ECC  object  version
       1.0 or higher.

       Current        The ECC mode that the GPU is currently operating under.

       Pending        The ECC mode that the GPU will operate under after the next reboot.

   ECC Errors
       NVIDIA GPUs can provide error counts for various types of ECC errors.  Some ECC errors are
       either single or double bit, where single bit errors are corrected and double  bit  errors
       are  uncorrectable.   Texture memory errors may be correctable via resend or uncorrectable
       if the resend fails.  These errors are  available  across  two  timescales  (volatile  and
       aggregate).  Single bit ECC errors are automatically corrected by the HW and do not result
       in data corruption.  Double bit errors are detected but not corrected.  Please see the ECC
       documents  on  the  web  for  information  on compute application behavior when double bit
       errors occur.  Volatile error counters track the number of errors detected since the  last
       driver  load.   Aggregate  error  counts  persist  indefinitely and thus act as a lifetime
       counter.

       A note about volatile counts: On Windows this is once per boot.  On Linux this can be more
       frequent.   On  Linux  the  driver  unloads  when  no  active  clients  exist.   Hence, if
       persistence mode is enabled or there is always a driver client  active  (e.g.  X11),  then
       Linux  also sees per-boot behavior.  If not, volatile counts are reset each time a compute
       app is run.

       Tesla and Quadro products from the Fermi and Kepler family can  display  total  ECC  error
       counts, as well as a breakdown of errors based on location on the chip.  The locations are
       described below.  Location-based data for aggregate  error  counts  requires  Inforom  ECC
       object version 2.0.  All other ECC counts require ECC object version 1.0.

       Device Memory  Errors detected in global device memory.

       Register File  Errors detected in register file memory.

       L1 Cache       Errors detected in the L1 cache.

       L2 Cache       Errors detected in the L2 cache.

       Texture Memory Parity errors detected in texture memory.

       Total          Total  errors  detected  across entire chip. Sum of Device Memory, Register
                      File, L1 Cache, L2 Cache and Texture Memory.

   Page Retirement
       NVIDIA GPUs can retire pages of GPU device memory when they become unreliable.   This  can
       happen when multiple single bit ECC errors occur for the same page, or on a double bit ECC
       error.  When a page is retired, the NVIDIA driver will hide it such  that  no  driver,  or
       application memory allocations can access it.

       Double  Bit  ECC  The  number  of  GPU device memory pages that have been retired due to a
       double bit ECC error.

       Single Bit ECC The number of GPU device  memory  pages  that  have  been  retired  due  to
       multiple single bit ECC errors.

       Pending  Checks  if  any GPU device memory pages are pending blacklist on the next reboot.
       Pages that are retired but not yet blacklisted can  still  be  allocated,  and  may  cause
       further reliability issues.

   Row Remapper
       NVIDIA  GPUs  can  remap  rows of GPU device memory when they become unreliable.  This can
       happen when a single uncorrectable ECC error or multiple correctable ECC errors  occur  on
       the  same  row.   When a row is remapped, the NVIDIA driver will remap the faulty row to a
       reserved row.  All future accesses to the row will access the reserved row instead of  the
       faulty row.

       Correctable  Error  The  number  of  rows  that  have been remapped due to correctable ECC
       errors.

       Uncorrectable Error The number of rows that have been remapped due  to  uncorrectable  ECC
       errors.

       Pending Indicates whether or not a row is pending remapping. The GPU must be reset for the
       remapping to go into effect.

       Remapping Failure Occurred Indicates whether or not a row  remapping  has  failed  in  the
       past.

       Bank  Remap  Availability  Histogram  Each memory bank has a fixed number of reserved rows
       that can be used for row remapping.  The histogram will classify the remap availability of
       each  bank into Maximum, High, Partial, Low and None.  Maximum availability means that all
       reserved rows are available for remapping while None  means  that  no  reserved  rows  are
       available.

   Temperature
       Readings  from  temperature sensors on the board.  All readings are in degrees C.  Not all
       products support all reading types.  In particular, products in module form  factors  that
       rely  on  case  fans  or passive cooling do not usually provide temperature readings.  See
       below for restrictions.

       T.Limit: The T.Limit sensor measures the current margin in degree Celsius to  the  maximum
       operating temperature. As such it is not an absolute temperature reading rather a relative
       measurement.

       Not all products support T.Limit sensor readings.

       When supported, nvidia-smi reports the current T.Limit temperature as a signed value  that
       counts down. A T.Limit temperature of 0 C or lower indicates that the GPU may optimize its
       clock based on  thermal  conditions.  Further,  when  the  T.Limit  sensor  is  supported,
       available temperature thresholds are also reported relative to T.Limit (see below) instead
       of absolute measurements.

       GPU            Core GPU temperature.  For all discrete and S-class products.

       T.Limit Temp   Current  margin  in  degrees  Celsius  from  the  maximum   GPU   operating
                      temperature.

       Shutdown Temp  The temperature at which a GPU will shutdown.

       Shutdown T.Limit Temp
                      The  T.Limit temperature below which a GPU may shutdown. Since shutdown can
                      only triggered by the maximum  GPU  temperature  it  is  possible  for  the
                      current T.Limit to be more negative than this threshold.

       Slowdown Temp  The  temperature  at  which  a  GPU  HW will begin optimizing clocks due to
                      thermal conditions, in order to cool.

       Slowdown T.Limit Temp
                      The T.Limit temperature below which a GPU HW may optimize  its  clocks  for
                      thermal  conditions.  Since this clock adjustment can only triggered by the
                      maximum GPU temperature it is possible for the current T.Limit to  be  more
                      negative than this threshold.

       Max Operating Temp
                      The  temperature  at  which  GPU  SW  will  optimize  its clock for thermal
                      conditions.

       Max Operating T.Limit Temp
                      The T.Limit temperature below which GPU SW  will  optimize  its  clock  for
                      thermal conditions.

   Power Readings
       Power  readings  help to shed light on the current power usage of the GPU, and the factors
       that affect that usage.  When power management is enabled the GPU limits power draw  under
       load  to  fit  within  a predefined power envelope by manipulating the current performance
       state.  See below for limits of availability.  Please note that  power  readings  are  not
       applicable for Pascal and higher GPUs with BA sensor boards.

       Power State    Power  State  is  deprecated  and  has been renamed to Performance State in
                      2.285.  To maintain XML compatibility, in XML format Performance  State  is
                      listed in both places.

       Power Management
                      A  flag  that  indicates  whether  power  management  is  enabled.   Either
                      "Supported" or "N/A".  Requires Inforom PWR object version 3.0 or higher or
                      Kepler device.

       Power Draw     The  last  measured  power  draw  for  the  entire  board,  in watts.  Only
                      available if power management is supported.  On Ampere  (except  GA100)  or
                      newer  devices,  returns  average power draw over 1 sec. On GA100 and older
                      devices, returns instantaneous power draw.  Please  note  that  for  boards
                      without  INA sensors, this refers to the power draw for the GPU and not for
                      the entire board.

       Power Limit    The software power limit, in watts.  Set by software  such  as  nvidia-smi.
                      Only  available  if  power  management  is supported.  Requires Inforom PWR
                      object version 3.0 or higher or Kepler device.   On  Kepler  devices  Power
                      Limit can be adjusted using -pl,--power-limit= switches.

       Enforced Power Limit
                      The  power  management  algorithm's  power  ceiling, in watts.  Total board
                      power draw is manipulated by the power management algorithm  such  that  it
                      stays  under  this value.  This limit is the minimum of various limits such
                      as the software limit listed above.  Only available if power management  is
                      supported.   Requires a Kepler device.  Please note that for boards without
                      INA sensors, it is the GPU power draw that is being manipulated.

       Default Power Limit
                      The default power management algorithm's power ceiling,  in  watts.   Power
                      Limit will be set back to Default Power Limit after driver unload.  Only on
                      supported devices from Kepler family.

       Min Power Limit
                      The minimum value in watts that  power  limit  can  be  set  to.   Only  on
                      supported devices from Kepler family.

       Max Power Limit
                      The  maximum  value  in  watts  that  power  limit  can be set to.  Only on
                      supported devices from Kepler family.

   Clocks
       Current frequency at which parts of the GPU are running.  All readings are in MHz.

       Graphics       Current frequency of graphics (shader) clock.

       SM             Current frequency of SM (Streaming Multiprocessor) clock.

       Memory         Current frequency of memory clock.

       Video          Current frequency of video (encoder + decoder) clocks.

   Applications Clocks
       User specified frequency at which applications will be running at.  Can  be  changed  with
       [-ac | --applications-clocks] switches.

       Graphics       User specified frequency of graphics (shader) clock.

       Memory         User specified frequency of memory clock.

   Default Applications Clocks
       Default  frequency  at  which  applications will be running at.  Application clocks can be
       changed with [-ac | --applications-clocks] switches.  Application clocks  can  be  set  to
       default using [-rac | --reset-applications-clocks] switches.

       Graphics       Default frequency of applications graphics (shader) clock.

       Memory         Default frequency of applications memory clock.

   Max Clocks
       Maximum frequency at which parts of the GPU are design to run.  All readings are in MHz.

       On  GPUs  from Fermi family current P0 clocks (reported in Clocks section) can differ from
       max clocks by few MHz.

       Graphics       Maximum frequency of graphics (shader) clock.

       SM             Maximum frequency of SM (Streaming Multiprocessor) clock.

       Memory         Maximum frequency of memory clock.

       Video          Maximum frequency of video (encoder + decoder) clock.

   Clock Policy
       User-specified settings for automated clocking changes such as auto boost.

       Auto Boost     Indicates whether auto boost mode is currently enabled for this GPU (On) or
                      disabled  for  this  GPU (Off). Shows (N/A) if boost is not supported. Auto
                      boost allows dynamic GPU clocking based on power, thermal and  utilization.
                      When  auto  boost  is  disabled  the GPU will attempt to maintain clocks at
                      precisely the Current Application Clocks settings (whenever a CUDA  context
                      is  active). With auto boost enabled the GPU will still attempt to maintain
                      this floor, but will opportunistically boost to higher clocks  when  power,
                      thermal  and utilization headroom allow. This setting persists for the life
                      of the CUDA context  for  which  it  was  requested.  Apps  can  request  a
                      particular  mode  either  via an NVML call (see NVML SDK) or by setting the
                      CUDA environment variable CUDA_AUTO_BOOST.

       Auto Boost Default
                      Indicates the default setting for auto boost mode, either enabled  (On)  or
                      disabled (Off). Shows (N/A) if boost is not supported. Apps will run in the
                      default mode if they have not explicitly requested a particular mode. Note:
                      Auto  Boost settings can only be modified if "Persistence Mode" is enabled,
                      which is NOT by default.

   Supported clocks
       List of possible memory and graphics clocks combinations that the GPU can operate on  (not
       taking  into account HW brake reduced clocks).  These are the only clock combinations that
       can be passed to --applications-clocks flag.  Supported Clocks are listed only when -q  -d
       SUPPORTED_CLOCKS switches are provided or in XML format.

   Voltage
       Current voltage reported by the GPU. All units are in mV.

       Graphics       Current voltage of the graphics unit.

   Processes
       List  of processes having Compute or Graphics Context on the device. Compute processes are
       reported on all the fully supported products. Reporting for Graphics processes is  limited
       to the supported products starting with Kepler architecture.

       Each Entry is of format "<GPU Index> <PID> <Type> <Process Name> <GPU Memory Usage>"

       GPU Index      Represents NVML Index of the device.

       PID            Represents  Process  ID  corresponding  to  the  active Compute or Graphics
                      context.

       Type           Displayed as "C" for Compute Process, "G" for Graphics Process,  and  "C+G"
                      for the process having both Compute and Graphics contexts.

       Process Name   Represents process name for the Compute or Graphics process.

       GPU Memory Usage
                      Amount  of  memory  used  on  the  device by the context.  Not available on
                      Windows when running in WDDM mode  because  Windows  KMD  manages  all  the
                      memory not NVIDIA driver.

   Device Monitoring
       The  "nvidia-smi dmon" command-line is used to monitor one or more GPUs (up to 16 devices)
       plugged into the system. This tool allows the user to see one line of monitoring data  per
       monitoring  cycle.  The  output  is in concise format and easy to interpret in interactive
       mode. The output data per line is limited by the terminal size. It is supported on  Tesla,
       GRID,  Quadro  and  limited  GeForce products for Kepler or newer GPUs under bare metal 64
       bits Linux. By default, the monitoring data includes Power Usage, Temperature, SM  clocks,
       Memory  clocks  and  Utilization values for SM, Memory, Encoder, Decoder, JPEG and OFA. It
       can also be configured to report other metrics such as frame  buffer  memory  usage,  bar1
       memory  usage, power/thermal violations and aggregate single/double bit ecc errors. If any
       of the metric is not supported on the device or any other error in fetching the metric  is
       reported  as  "-" in the output data. The user can also configure monitoring frequency and
       the number of monitoring iterations for each run. There is also an option to include  date
       and time at each line. All the supported options are exclusive and can be used together in
       any order.  Note: On MIG-enabled GPUs, querying the utilization of encoder, decoder, jpeg,
       ofa, gpu, and memory is not currently supported.

       Usage:

       1) Default with no arguments

       nvidia-smi dmon

       Monitors  default  metrics  for  up  to  16  supported  devices  under natural enumeration
       (starting with GPU index 0) at a frequency of 1 sec. Runs until terminated with ^C.

       2) Select one or more devices

       nvidia-smi dmon -i <device1,device2, .. , deviceN>

       Reports default metrics for the devices selected by comma separated device list. The  tool
       picks  up  to  16 supported devices from the list under natural enumeration (starting with
       GPU index 0).

       3) Select metrics to be displayed

       nvidia-smi dmon -s <metric_group>

       <metric_group> can be one or more from the following:

           p - Power Usage (in Watts) and Gpu/Memory Temperature (in C) if supported

           u - Utilization (SM, Memory, Encoder, Decoder, JPEG and OFA Utilization in %)

           c - Proc and Mem Clocks (in MHz)

           v - Power Violations (in %) and Thermal Violations (as a boolean flag)

           m - Frame Buffer, Bar1 and Confidential Compute protected memory usage (in MB)

           e - ECC (Number of aggregated single bit, double  bit  ecc  errors)  and  PCIe  Replay
       errors

           t - PCIe Rx and Tx Throughput in MB/s (Maxwell and above)

       4) Configure monitoring iterations

       nvidia-smi dmon -c <number of samples>

       Displays data for specified number of samples and exit.

       5) Configure monitoring frequency

       nvidia-smi dmon -d <time in secs>

       Collects  and  displays  data at every specified monitoring interval until terminated with
       ^C.

       6) Display date

       nvidia-smi dmon -o D

       Prepends monitoring data with date in YYYYMMDD format.

       7) Display time

       nvidia-smi dmon -o T

       Prepends monitoring data with time in HH:MM:SS format.

       8) Select GPM metrics to be displayed

       nvidia-smi dmon --gpm-metrics <gpmMetric1, gpmMetric2, ... ,gpmMetricN>

       <gpmMetricX> Refer to the documentation for nvmlGpmMetricId_t in the NVML header file

       9) Select which level of GPM metrics to be displayed

       nvidia-smi dmon --gpm-options <gpmMode>

       <gpmMode> can be one of the following:

           d  - Display Device Level GPM metrics

           m  - Display MIG Level GPM metrics

           dm - Display Device and MIG Level GPM metrics

           md - Display Device and MIG Level GPM metrics, same as 'dm'

       10) Modify output format

       nvidia-smi dmon --format <formatSpecifier>

       <formatSpecifier> can be any comma separated combination of the following:

           csv - Format dmon output as CSV

           nounit - Remove unit line from dmon output

           noheader - Remove header line from dmon output

       11) Help Information

       nvidia-smi dmon -h

       Displays help information for using the command line.

   Daemon (EXPERIMENTAL)
       The "nvidia-smi daemon" starts a background process to monitor one or more GPUs plugged in
       to  the system. It monitors the requested GPUs every monitoring cycle and logs the file in
       compressed format at the user provided path or the default location at  /var/log/nvstats/.
       The  log  file  is  created  with  system's date appended to it and of the format nvstats-
       YYYYMMDD. The flush operation to the log file is done every  alternate  monitoring  cycle.
       Daemon  also  logs  it's own PID at /var/run/nvsmi.pid. By default, the monitoring data to
       persist includes Power Usage, Temperature, SM clocks, Memory clocks and Utilization values
       for SM, Memory, Encoder, Decoder, JPEG and OFA. The daemon tools can also be configured to
       record other metrics such as frame buffer memory usage, bar1 memory  usage,  power/thermal
       violations  and aggregate single/double bit ecc errors.The default monitoring cycle is set
       to 10 secs and can be configured via command-line. It is supported on Tesla, GRID,  Quadro
       and  GeForce  products for Kepler or newer GPUs under bare metal 64 bits Linux. The daemon
       requires root privileges to run, and  only supports  running  a  single  instance  on  the
       system.  All of the supported options are exclusive and can be used together in any order.
       Note: On MIG-enabled GPUs, querying the utilization of encoder, decoder, jpeg,  ofa,  gpu,
       and memory is not currently supported.  Usage:

       1) Default with no arguments

       nvidia-smi daemon

       Runs  in  the  background  to monitor default metrics for up to 16 supported devices under
       natural enumeration (starting with GPU index 0) at a frequency of 10 sec. The date stamped
       log file is created at /var/log/nvstats/.

       2) Select one or more devices

       nvidia-smi daemon -i <device1,device2, .. , deviceN>

       Runs  in  the  background  to  monitor  default  metrics for the devices selected by comma
       separated device list. The tool picks up to 16  supported  devices  from  the  list  under
       natural enumeration (starting with GPU index 0).

       3) Select metrics to be monitored

       nvidia-smi daemon -s <metric_group>

       <metric_group> can be one or more from the following:

           p - Power Usage (in Watts) and Gpu/Memory Temperature (in C) if supported

           u - Utilization (SM, Memory, Encoder, Decoder, JPEG and OFA Utilization in %)

           c - Proc and Mem Clocks (in MHz)

           v - Power Violations (in %) and Thermal Violations (as a boolean flag)

           m - Frame Buffer, Bar1 and Confidential Compute protected memory usage (in MB)

            e  -  ECC  (Number  of  aggregated single bit, double bit ecc errors) and PCIe Replay
       errors

           t - PCIe Rx and Tx Throughput in MB/s (Maxwell and above)

       4) Configure monitoring frequency

       nvidia-smi daemon -d <time in secs>

       Collects data at every specified monitoring interval until terminated.

       5) Configure log directory

       nvidia-smi daemon -p <path of directory>

       The log files are created at the specified directory.

       6) Configure log file name

       nvidia-smi daemon -j <string to append log file name>

       The command-line is used to append the log file name with the user provided string.

       7) Terminate the daemon

       nvidia-smi daemon -t

       This command-line uses the stored PID (at /var/run/nvsmi.pid) to terminate the daemon.  It
       makes the best effort to stop the daemon and offers no guarantees for it's termination. In
       case the daemon is not terminated, then the user can manually terminate  by  sending  kill
       signal  to  the daemon. Performing a GPU reset operation (via nvidia-smi) requires all GPU
       processes to be exited, including the daemon. Users who have the daemon open will  see  an
       error to the effect that the GPU is busy.

       8) Help Information

       nvidia-smi daemon -h

       Displays help information for using the command line.

   Replay Mode (EXPERIMENTAL)
       The  "nvidia-smi  replay"  command-line is used to extract/replay all or parts of log file
       generated by the daemon. By default, the tool tries to pull  the  metrics  such  as  Power
       Usage,  Temperature,  SM  clocks,  Memory  clocks  and  Utilization values for SM, Memory,
       Encoder, Decoder, JPEG and OFA. The replay tool can also fetch other metrics such as frame
       buffer   memory   usage,   bar1  memory  usage,  power/thermal  violations  and  aggregate
       single/double bit ecc errors. There is an option to select a set of metrics to replay,  If
       any  of  the requested metric is not maintained or logged as not-supported then it's shown
       as "-" in the output. The format of data produced by this mode is such that  the  user  is
       running  the  device monitoring utility interactively. The command line requires mandatory
       option "-f" to specify complete path of the log filename, all the other supported  options
       are  exclusive and can be used together in any order.  Note: On MIG-enabled GPUs, querying
       the utilization of  encoder,  decoder,  jpeg,  ofa,  gpu,  and  memory  is  not  currently
       supported.  Usage:

       1) Specify log file to be replayed

       nvidia-smi replay -f <log file name>

       Fetches  monitoring  data from the compressed log file and allows the user to see one line
       of monitoring data (default metrics with time-stamp) for each monitoring iteration  stored
       in the log file. A new line of monitoring data is replayed every other second irrespective
       of the actual monitoring frequency maintained at the time of collection. It  is  displayed
       till the end of file or until terminated by ^C.

       2) Filter metrics to be replayed

       nvidia-smi replay -f <path to log file> -s <metric_group>

       <metric_group> can be one or more from the following:

           p - Power Usage (in Watts) and Gpu/Memory Temperature (in C) if supported

           u - Utilization (SM, Memory, Encoder, Decoder, JPEG and OFA Utilization in %)

           c - Proc and Mem Clocks (in MHz)

           v - Power Violations (in %) and Thermal Violations (as a boolean flag)

           m - Frame Buffer, Bar1 and Confidential Compute protected memory usage (in MB)

            e  -  ECC  (Number  of  aggregated single bit, double bit ecc errors) and PCIe Replay
       errors

           t - PCIe Rx and Tx Throughput in MB/s (Maxwell and above)

       3) Limit replay to one or more devices

       nvidia-smi replay -f <log file> -i <device1,device2, .. , deviceN>

       Limits reporting of the metrics to the set of devices selected by comma  separated  device
       list. The tool skips any of the devices not maintained in the log file.

       4) Restrict the time frame between which data is reported

       nvidia-smi  replay  -f  <log  file>  -b  <start  time  in HH:MM:SS format> -e <end time in
       HH:MM:SS format>

       This option allows the data to be limited between the  specified  time  range.  Specifying
       time as 0 with -b or -e option implies start or end file respectively.

       5) Redirect replay information to a log file

       nvidia-smi replay -f <log file> -r <output file name>

       This  option  takes  log  file as an input and extracts the information related to default
       metrics in the specified output file.

       6) Help Information

       nvidia-smi replay -h

       Displays help information for using the command line.

   Process Monitoring
       The "nvidia-smi pmon" command-line is used  to  monitor  compute  and  graphics  processes
       running  on  one or more GPUs (up to 16 devices) plugged into the system. This tool allows
       the user to see the statistics for all the running  processes  on  each  device  at  every
       monitoring  cycle.  The  output  is in concise format and easy to interpret in interactive
       mode. The output data per line is limited by the terminal size. It is supported on  Tesla,
       GRID,  Quadro  and  limited  GeForce products for Kepler or newer GPUs under bare metal 64
       bits Linux. By default, the monitoring data for each process  includes  the  pid,  command
       name  and  average  utilization  values for SM, Memory, Encoder and Decoder since the last
       monitoring cycle. It can also be configured to report frame buffer memory usage  for  each
       process.  If there is no process running for the device, then all the metrics are reported
       as "-" for the device. If any of the metric is not supported on the device  or  any  other
       error in fetching the metric is also reported as "-" in the output data. The user can also
       configure monitoring frequency and the number of monitoring iterations for each run. There
       is  also  an  option  to include date and time at each line. All the supported options are
       exclusive and can be used together in any order.  Note: On MIG-enabled GPUs, querying  the
       utilization of encoder, decoder, jpeg, ofa, gpu, and memory is not currently supported.

       Usage:

       1) Default with no arguments

       nvidia-smi pmon

       Monitors  all  the  processes  running on each device for up to 16 supported devices under
       natural enumeration (starting with GPU index 0) at  a  frequency  of  1  sec.  Runs  until
       terminated with ^C.

       2) Select one or more devices

       nvidia-smi pmon -i <device1,device2, .. , deviceN>

       Reports  statistics  for  all  the  processes  running  on  the  devices selected by comma
       separated device list. The tool picks up to 16  supported  devices  from  the  list  under
       natural enumeration (starting with GPU index 0).

       3) Select metrics to be displayed

       nvidia-smi pmon -s <metric_group>

       <metric_group> can be one or more from the following:

           u  -  Utilization  (SM,  Memory,  Encoder,  Decoder, JPEG, and OFA Utilization for the
       process in %). Reports average utilization since last monitoring cycle.

           m - Frame Buffer and Confidential Compute protected  memory  usage  (in  MB).  Reports
       instantaneous value for memory usage.

       4) Configure monitoring iterations

       nvidia-smi pmon -c <number of samples>

       Displays data for specified number of samples and exit.

       5) Configure monitoring frequency

       nvidia-smi pmon -d <time in secs>

       Collects  and  displays  data at every specified monitoring interval until terminated with
       ^C. The monitoring frequency must be between 1 to 10 secs.

       6) Display date

       nvidia-smi pmon -o D

       Prepends monitoring data with date in YYYYMMDD format.

       7) Display time

       nvidia-smi pmon -o T

       Prepends monitoring data with time in HH:MM:SS format.

       8) Help Information

       nvidia-smi pmon -h

       Displays help information for using the command line.

   Topology (EXPERIMENTAL)
       List topology information about the system's GPUs, how they connect to each other as  well
       as qualified NICs capable of RDMA.

       Displays a matrix of available GPUs with the following legend:

       Legend:

                        X    = Self
                        SYS  = Connection traversing PCIe as well as the SMP interconnect between
                      NUMA nodes (e.g., QPI/UPI)
                        NODE = Connection traversing PCIe as well  as  the  interconnect  between
                      PCIe Host Bridges within a NUMA node
                        PHB   =  Connection  traversing  PCIe  as  well  as  a  PCIe  Host Bridge
                      (typically the CPU)
                        PXB  = Connection traversing multiple PCIe switches  (without  traversing
                      the PCIe Host Bridge)
                        PIX  = Connection traversing a single PCIe switch
                        NV#  = Connection traversing a bonded set of # NVLinks

       Note: This command may also display bonded NICs which may not be RDMA capable.

   vGPU Management
       The  "nvidia-smi  vgpu"  command  reports  on  GRID  vGPUs executing on supported GPUs and
       hypervisors (refer to driver release notes for  supported  platforms).  Summary  reporting
       provides  basic  information  about  vGPUs  currently  executing on the system. Additional
       options provide detailed reporting of vGPU properties, per-vGPU reporting of  SM,  Memory,
       Encoder,  Decoder,  Jpeg,  and  OFA  utilization,  and  per-GPU reporting of supported and
       creatable  vGPUs.  Periodic  reports  can  be  automatically  generated  by  specifying  a
       configurable  loop  frequency  to  any  command.   Note: On MIG-enabled GPUs, querying the
       utilization of encoder, decoder, jpeg, ofa, gpu, and memory is not currently supported.

       Usage:

       1) Help Information

       nvidia-smi vgpu -h

       Displays help information for using the command line.

       2) Default with no arguments

       nvidia-smi vgpu

       Reports summary of all the vGPUs currently active on each device.

       3) Display detailed info on currently active vGPUs

       nvidia-smi vgpu -q

       Collects and displays information on currently active  vGPUs  on  each  device,  including
       driver version, utilization, and other information.

       4) Select one or more devices

       nvidia-smi vgpu -i <device1,device2, .. , deviceN>

       Reports  summary  for  all  the  vGPUs  currently active on the devices selected by comma-
       separated device list.

       5) Display supported vGPUs

       nvidia-smi vgpu -s

       Displays vGPU types supported on each device. Use  the  -v  /  --verbose  option  to  show
       detailed info on each vGPU type.

       6) Display creatable vGPUs

       nvidia-smi vgpu -c

       Displays  vGPU  types  creatable on each device. This varies dynamically, depending on the
       vGPUs already active on the device. Use the -v / --verbose option to show detailed info on
       each vGPU type.

       7) Report utilization for currently active vGPUs.

       nvidia-smi vgpu -u

       Reports  average utilization (SM, Memory, Encoder, Decoder, Jpeg, and OFA) for each active
       vGPU since last monitoring cycle. The default cycle time is 1 second, and the command runs
       until  terminated  with  ^C.  If a device has no active vGPUs, its metrics are reported as
       "-".

       8) Configure loop frequency

       nvidia-smi vgpu [-s -c -q -u] -l <time in secs>

       Collects and displays data at a specified loop interval until terminated with ^C. The loop
       frequency  must  be  between  1 and 10 secs. When no time is specified, the loop frequency
       defaults to 5 secs.

       9) Display GPU engine usage

       nvidia-smi vgpu -p

       Display GPU engine usage of currently active processes running in the vGPU VMs.

       10) Display migration capabitlities.

       nvidia-smi vgpu -m

       Display pGPU's migration/suspend/resume capability.

       11) Display the vGPU Software scheduler state.

       nvidia-smi vgpu -ss

       Display the information about vGPU Software scheduler state.

       12) Display the vGPU Software scheduler capabilities.

       nvidia-smi vgpu -sc

       Display the list of supported vGPU  scheduler  policies  returned  along  with  the  other
       capabilities  values,  if  the engine is Graphics type. For other engine types, it is BEST
       EFFORT policy and other capabilities will be  zero.  If  ARR  is  supported  and  enabled,
       scheduling frequency and averaging factor are applicable else timeSlice is applicable.

       13) Display the vGPU Software scheduler logs.

       nvidia-smi vgpu -sl

       Display the vGPU Software scheduler runlist logs.

       nvidia-smi --query-vgpu-scheduler-logs=[input parameters]

       Display the vGPU Software scheduler runlist logs in CSV format.

       14) Set the vGPU Software scheduler state.

       nvidia-smi vgpu --set-vgpu-scheduler-state [options]

       Set the vGPU Software scheduler policy and states.

       15) Display Nvidia Encoder session info.

       nvidia-smi vgpu -es

       Display the information about encoder sessions for currently running vGPUs.

       16) Display accounting statistics.

       nvidia-smi vgpu --query-accounted-apps=[input parameters]

       Display accounting stats for compute/graphics processes.

       To find list of properties which can be queried, run - 'nvidia-smi --help-query-accounted-
       apps'.

       17) Display Nvidia Frame Buffer Capture session info.

       nvidia-smi vgpu -fs

       Display the information about FBC sessions for currently running vGPUs.

       Note : Horizontal resolution, vertical resolution, average FPS and  average  latency  data
       for  a  FBC  session  may  be  zero  if there are no new frames captured since the session
       started.

       18) Set vGPU heterogeneous mode.

       nvidia-smi vgpu -shm

       Set vGPU heterogeneous mode of the device for timesliced vGPUs with different  framebuffer
       sizes.

   MIG Management
       The  privileged  "nvidia-smi  mig"  command-line  is  used  to manage MIG-enabled GPUs. It
       provides options to create, list and destroy GPU instances and compute instances.

       Usage:

       1) Display help menu

       nvidia-smi mig -h

       Displays help menu for using the command-line.

       2) Select one or more GPUs

       nvidia-smi mig -i <GPU IDs>

       nvidia-smi mig --id <GPU IDs>

       Selects one or more GPUs using the given comma-separated  GPU  indexes,  PCI  bus  IDs  or
       UUIDs. If not used, the given command-line option applies to all of the supported GPUs.

       3) Select one or more GPU instances

       nvidia-smi mig -gi <GPU instance IDs>

       nvidia-smi mig --gpu-instance-id <GPU instance IDs>

       Selects one or more GPU instances using the given comma-separated GPU instance IDs. If not
       used, the given command-line option applies to all of the GPU instances.

       4) Select one or more compute instances

       nvidia-smi mig -ci <compute instance IDs>

       nvidia-smi mig --compute-instance-id <compute instance IDs>

       Selects one or more compute instances using the  given  comma-separated  compute  instance
       IDs. If not used, the given command-line option applies to all of the compute instances.

       5) List GPU instance profiles

       nvidia-smi mig -lgip -i <GPU IDs>

       nvidia-smi mig --list-gpu-instance-profiles --id <GPU IDs>

       Lists  GPU  instance profiles, their availability and IDs. Profiles describe the supported
       types of GPU instances, including all of the GPU resources they exclusively control.

       6) List GPU instance possible placements

       nvidia-smi mig -lgipp -i <GPU IDs>

       nvidia-smi mig --list-gpu-instance-possible-placements --id <GPU IDs>

       Lists GPU instance possible placements. Possible placements describe the locations of  the
       supported types of GPU instances within the GPU.

       7) Create GPU instance

       nvidia-smi mig -cgi <GPU instance specifiers> -i <GPU IDs>

       nvidia-smi mig --create-gpu-instance <GPU instance specifiers> --id <GPU IDs>

       Creates  GPU  instances  for  the  given GPU instance specifiers. A GPU instance specifier
       comprises a GPU instance profile name or ID and an optional placement specifier consisting
       of a colon and a placement start index. The command fails if the GPU resources required to
       allocate the requested GPU instances are not available, or if the placement index  is  not
       valid for the given profile.

       8) Create a GPU instance along with the default compute instance

       nvidia-smi mig -cgi <GPU instance profile IDs or names> -i <GPU IDs> -C

       nvidia-smi  mig  --create-gpu-instance  <GPU instance profile IDs or names> --id <GPU IDs>
       --default-compute-instance

       9) List GPU instances

       nvidia-smi mig -lgi -i <GPU IDs>

       nvidia-smi mig --list-gpu-instances --id <GPU IDs>

       Lists GPU instances and their IDs.

       10) Destroy GPU instance

       nvidia-smi mig -dgi -gi <GPU instance IDs> -i <GPU IDs>

       nvidia-smi mig --destroy-gpu-instances --gpu-instance-id <GPU instance IDs> --id <GPU IDs>

       Destroys GPU instances. The command fails if the requested GPU instance is in  use  by  an
       application.

       11) List compute instance profiles

       nvidia-smi mig -lcip -gi <GPU instance IDs> -i <GPU IDs>

       nvidia-smi  mig --list-compute-instance-profiles --gpu-instance-id <GPU instance IDs> --id
       <GPU IDs>

       Lists compute instance  profiles,  their  availability  and  IDs.  Profiles  describe  the
       supported  types  of  compute  instances, including all of the GPU resources they share or
       exclusively control.

       12) List compute instance possible placements

       nvidia-smi mig -lcipp -gi <GPU instance IDs> -i <GPU IDs>

       nvidia-smi mig --list-compute-instance-possible-placements --gpu-instance-id <GPU instance
       IDs> --id <GPU IDs>

       Lists  compute instance possible placements. Possible placements describe the locations of
       the supported types of compute instances within the GPU instance.

       13) Create compute instance

       nvidia-smi mig -cci <compute instance profile IDs or names> -gi <GPU instance IDs> -i <GPU
       IDs>

       nvidia-smi  mig  --create-compute-instance  <compute instance profile IDs or names> --gpu-
       instance-id <GPU instance IDs> --id <GPU IDs>

       Creates compute instances for the given compute instance  spcifiers.  A  compute  instance
       specifier  comprises  a  compute  instance  profile  name  or ID and an optional placement
       specifier consisting of a colon and a placement start index. The command fails if the  GPU
       resources  required  to  allocate the requested compute instances are not available, or if
       the placement index is not valid for the given profile.

       14) List compute instances

       nvidia-smi mig -lci -gi <GPU instance IDs> -i <GPU IDs>

       nvidia-smi mig --list-compute-instances --gpu-instance-id <GPU  instance  IDs>  --id  <GPU
       IDs>

       Lists compute instances and their IDs.

       15) Destroy compute instance

       nvidia-smi mig -dci -ci <compute instance IDs> -gi <GPU instance IDs> -i <GPU IDs>

       nvidia-smi  mig  --destroy-compute-instance  --compute-instance-id  <compute instance IDs>
       --gpu-instance-id <GPU instance IDs> --id <GPU IDs>

       Destroys compute instances. The command fails if the requested compute instance is in  use
       by an application.

   Boost Slider
       The  privileged  "nvidia-smi  boost-slider" command-line is used to manage boost slider on
       GPUs. It provides options to list and control boost sliders.

       Usage:

       1) Display help menu

       nvidia-smi boost-slider -h

       Displays help menu for using the command-line.

       2) List one or more GPUs

       nvidia-smi boost-slider -i <GPU IDs>

       nvidia-smi boost-slider --id <GPU IDs>

       Selects one or more GPUs using the given comma-separated  GPU  indexes,  PCI  bus  IDs  or
       UUIDs. If not used, the given command-line option applies to all of the supported GPUs.

       3) List boost sliders

       nvidia-smi boost-slider -l

       nvidia-smi boost-slider --list

       List all boost sliders for the selected devices.

       4) Set video boost slider

       nvidia-smi boost-slider --vboost <value>

       Set the video boost slider for the selected devices.

   Power Hint
       The privileged "nvidia-smi power-hint" command-line is used to query power hint on GPUs.

       Usage:

       1) Display help menu

       nvidia-smi boost-slider -h

       Displays help menu for using the command-line.

       2) List one or more GPUs

       nvidia-smi boost-slider -i <GPU IDs>

       nvidia-smi boost-slider --id <GPU IDs>

       Selects  one  or  more  GPUs  using  the given comma-separated GPU indexes, PCI bus IDs or
       UUIDs. If not used, the given command-line option applies to all of the supported GPUs.

       3) List power hint info

       nvidia-smi boost-slider -l

       nvidia-smi boost-slider --list-info

       List all boost sliders for the selected devices.

       4) Query power hint

       nvidia-smi boost-slider -gc <value> -t <value> -p <profile ID>

       nvidia-smi boost-slider --graphics-clock <value> --temperature <value> --profile  <profile
       ID>

       Query power hint with graphics clock, temperature and profile id.

       5) Query power hint

       nvidia-smi boost-slider -gc <value> -mc <value> -t <value> -p <profile ID>

       nvidia-smi  boost-slider  --graphics-clock  <value>  --memory-clock  <value> --temperature
       <value> --profile <profile ID>

       Query power hint with graphics clock, memory clock, temperature and profile id.

   Confidential Compute
       The "nvidia-smi conf-compute" command-line is used  to  manage  confidential  compute.  It
       provides options to set and query confidential compute.

       Usage:

       1) Display help menu

       nvidia-smi conf-compute -h

       Displays help menu for using the command-line.

       2) List one or more GPUs

       nvidia-smi conf-compute -i <GPU IDs>

       nvidia-smi conf-compute --id <GPU IDs>

       Selects  one  or  more  GPUs  using  the given comma-separated GPU indexes, PCI bus IDs or
       UUIDs. If not used, the given command-line option applies to all of the supported GPUs.

       3) Query confidential compute CPU capability

       nvidia-smi conf-compute -gc

       nvidia-smi conf-compute --get-cpu-caps

       Get confidential compute CPU capability.

       4) Query confidential compute GPUs capability

       nvidia-smi conf-compute -gg

       nvidia-smi conf-compute --get-gpus-caps

       Get confidential compute GPUs capability.

       5) Query confidential compute devtools mode

       nvidia-smi conf-compute -d

       nvidia-smi conf-compute --get-devtools-mode

       Get confidential compute DevTools mode.

       6) Query confidential compute environment

       nvidia-smi conf-compute -e

       nvidia-smi conf-compute --get-environment

       Get confidential compute environment.

       7) Query confidential compute feature status

       nvidia-smi conf-compute -f

       nvidia-smi conf-compute --get-cc-feature

       Get confidential compute CC feature status.

       8) Query confidential compute GPU protected/unprotected memory sizes

       nvidia-smi conf-compute -gm

       nvidia-smi conf-compute --get-mem-size-info

       Get confidential compute GPU protected/unprotected memory sizes.

       9) Set confidential compute GPU unprotected memory size

       nvidia-smi conf-compute -sm <value>

       nvidia-smi conf-compute --set-unprotected-mem-size <value>

       Set confidential compute GPU unprotected memory size in KiB. Requires root.

       10) Set confidential compute GPUs ready state

       nvidia-smi conf-compute -srs <value>

       nvidia-smi conf-compute --set-gpus-ready-state <value>

       Set confidential compute GPUs ready state. The value must be 1 to set the ready state  and
       0 to unset it. Requires root.

       11) Query confidential compute GPUs ready state

       nvidia-smi conf-compute -grs

       nvidia-smi conf-compute --get-gpus-ready-state

       Get confidential compute GPUs ready state.

   GPU Performance Monitoring(GPM) Stream State
       The  "nvidia-smi  gpm"  command-line is used to manage GPU performance monitoring unit. It
       provides options to query and set the stream state.

       Usage:

       1) Display help menu

       nvidia-smi gpm -h

       Displays help menu for using the command-line.

       2) List one or more GPUs

       nvidia-smi gpm -i <GPU IDs>

       nvidia-smi gpm --id <GPU IDs>

       Selects one or more GPUs using the given comma-separated  GPU  indexes,  PCI  bus  IDs  or
       UUIDs. If not used, the given command-line option applies to all of the supported GPUs.

       3) Query GPU performance monitoring stream state

       nvidia-smi gpm -g

       nvidia-smi gpm --get-stream-state

       Get gpm stream state for the selected devices.

       4) Set GPU performance monitoring stream state

       nvidia-smi gpm -s <value>

       nvidia-smi gpm --set-stream-state <value>

       Set gpm stream state for the selected devices.

UNIT ATTRIBUTES

       The  following  list  describes all possible data returned by the -q -u unit query option.
       Unless otherwise noted all numerical results are base 10 and unitless.

   Timestamp
       The current system timestamp at the time nvidia-smi was invoked.  Format  is  "Day-of-week
       Month Day HH:MM:SS Year".

   Driver Version
       The     version    of    the    installed    NVIDIA    display    driver.     Format    is
       "Major-Number.Minor-Number".

   HIC Info
       Information about any Host Interface Cards (HIC) that are installed in the system.

       Firmware Version
                      The version of the firmware running on the HIC.

   Attached Units
       The number of attached Units in the system.

   Product Name
       The official product name of the unit.  This is an alphanumeric value.   For  all  S-class
       products.

   Product Id
       The  product  identifier  for  the  unit.   This  is  an  alphanumeric  value  of the form
       "part1-part2-part3".  For all S-class products.

   Product Serial
       The immutable globally unique identifier for the unit.  This  is  an  alphanumeric  value.
       For all S-class products.

   Firmware Version
       The  version  of the firmware running on the unit.  Format is "Major-Number.Minor-Number".
       For all S-class products.

   LED State
       The LED indicator is used to flag systems with potential problems.  An LED color of  AMBER
       indicates an issue.  For all S-class products.

       Color          The color of the LED indicator.  Either "GREEN" or "AMBER".

       Cause          The  reason  for  the  current  LED  color.  The cause may be listed as any
                      combination of "Unknown", "Set to AMBER by host  system",  "Thermal  sensor
                      failure", "Fan failure" and "Temperature exceeds critical limit".

   Temperature
       Temperature readings for important components of the Unit.  All readings are in degrees C.
       Not all readings may be available.  For all S-class products.

       Intake         Air temperature at the unit intake.

       Exhaust        Air temperature at the unit exhaust point.

       Board          Air temperature across the unit board.

   PSU
       Readings for the unit power supply.  For all S-class products.

       State          Operating state of the PSU.  The power supply  state  can  be  any  of  the
                      following:  "Normal",  "Abnormal", "High voltage", "Fan failure", "Heatsink
                      temperature",  "Current  limit",  "Voltage  below  UV   alarm   threshold",
                      "Low-voltage",  "I2C remote off command", "MOD_DISABLE input" or "Short pin
                      transition".

       Voltage        PSU voltage setting, in volts.

       Current        PSU current draw, in amps.

   Fan Info
       Fan readings for the unit.  A reading is provided for each fan,  of  which  there  can  be
       many.  For all S-class products.

       State          The state of the fan, either "NORMAL" or "FAILED".

       Speed          For a healthy fan, the fan's speed in RPM.

   Attached GPUs
       A  list  of PCI bus ids that correspond to each of the GPUs attached to the unit.  The bus
       ids have the form "domain:bus:device.function", in hex.  For all S-class products.

NOTES

       On Linux, NVIDIA device files may be modified by nvidia-smi if run as  root.   Please  see
       the relevant section of the driver README file.

       The  -a and -g arguments are now deprecated in favor of -q and -i, respectively.  However,
       the old arguments still work for this release.

EXAMPLES

   nvidia-smi -q
       Query attributes for all GPUs once, and display in plain text to stdout.

   nvidia-smi --format=csv,noheader --query-gpu=uuid,persistence_mode
       Query UUID and persistence mode of all GPUs in the system.

   nvidia-smi -q -d ECC,POWER -i 0 -l 10 -f out.log
       Query ECC errors  and  power  consumption  for  GPU  0  at  a  frequency  of  10  seconds,
       indefinitely, and record to the file out.log.

   "nvidia-smi -c 1 -i GPU-b2f5f1b745e3d23d-65a3a26d-097db358-7303e0b6-149642ff3d219f8587cde3a8"
       Set    the    compute    mode    to    "PROHIBITED"    for    GPU    with    UUID    "GPU-
       b2f5f1b745e3d23d-65a3a26d-097db358-7303e0b6-149642ff3d219f8587cde3a8".

   nvidia-smi -q -u -x --dtd
       Query attributes for all Units once, and display  in  XML  format  with  embedded  DTD  to
       stdout.

   nvidia-smi --dtd -u -f nvsmi_unit.dtd
       Write the Unit DTD to nvsmi_unit.dtd.

   nvidia-smi -q -d SUPPORTED_CLOCKS
       Display supported clocks of all GPUs.

   nvidia-smi -i 0 --applications-clocks 2500,745
       Set applications clocks to 2500 MHz memory, and 745 MHz graphics.

   nvidia-smi mig -cgi 19
       Create a MIG GPU instance on profile ID 19.

   nvidia-smi mig -cgi 19:2
       Create a MIG GPU instance on profile ID 19 at placement start index 2.

   nvidia-smi boost-slider -l
       List all boost sliders for all GPUs.

   nvidia-smi boost-slider --vboost 1
       Set vboost to value 1 for all GPUs.

   nvidia-smi power-hint -l
       List clock range, temperature range and supported profiles of power hint.

   nvidia-smi boost-slider -gc 1350 -t 60 -p 0
       Query power hint with graphics clock at 1350MHz, temperature at 60C and profile ID at 0.

   nvidia-smi boost-slider -gc 1350 -mc 1215 -t n5 -p 1
       Query  power  hint with graphics clock at 1350MHz, memory clock at 1215MHz, temperature at
       -5C and profile ID at 1.

CHANGE LOG

         === Known Issues ===

         * On systems where GPUs are NUMA nodes, the accuracy of FB memory  utilization  provided
       by nvidia-smi depends on the memory accounting of the operating system.

           This is because FB memory is managed by the operating system instead of the NVIDIA GPU
       driver.

           Typically, pages allocated from FB memory are not  released  even  after  the  process
       terminates to enhance performance. In scenarios where

           the  operating  system is under memory pressure, it may resort to utilizing FB memory.
       Such actions can result in discrepancies in the accuracy of memory reporting.

         * On Linux GPU Reset can't be triggered when there is pending GOM change.

         * On Linux GPU Reset may not successfully change pending ECC mode. A full reboot may  be
       required to enable the mode change.

         * On Linux platforms that configure NVIDIA GPUs as NUMA nodes, enabling persistence mode
       or resetting GPUs  may  print  "Warning:  persistence  mode  is  disabled  on  device"  if
       nvidia-persistenced  is  not running, or if nvidia-persistenced cannot access files in the
       NVIDIA driver's procfs directory  for  the  device  (/proc/driver/nvidia/gpus/<PCI  Config
       Address>/).  During  GPU  reset  and  driver  reload,  this  directory will be deleted and
       recreated, and outstanding references to the deleted directory, such as mounts or  shells,
       can prevent processes from accessing files in the new directory.

         *  === Changes between nvidia-smi v550 Update and v545 ===

         *  Add multiGpuMode dipsplay via nvidia-smi via "nvidia-smi conf-compute --get-multigpu-
       mode" or "nvidia-smi conf-compute -mgm"

         * Added a new cmdline option to print out version information: --version

         * Added ability to print out only the  GSP  firmware  version  with"nvidia-smi  -q  -d".
       Example commandline: nvidia-smi -q -d GSP_FIRMWARE_VERSION

         * Added support to query pci.baseClass and pci.subClass. See nvidia-smi --help-query-gpu
       for details.

         * Added PCI base and sub classcodes to "nvidia-smi -q" output.

         * Added new cmdline option "--format" to "nvidia-smi dmon" to  support  "csv",  "nounit"
       and "noheader" format specifiers

         * Added a new cmdline option "--gpm-options" to "nvidia-smi dmon" to support GPM metrics
       report in MIG mode

         * Added the NVJPG and NVOFA utilization report to "nvidia-smi pmon"

         * Added the NVJPG and NVOFA utilization report to "nvidia-smi -q -d utilization"

         * Added the NVJPG and NVOFA  utilization  report  to  "nvidia-smi  vgpu  -q"  to  report
       NVJPG/NVOFA utilization on active vgpus

         *  Added  the NVJPG and NVOFA utilization report to "nvidia-smi vgpu -u" to periodically
       report NVJPG/NVOFA utilization on active vgpus

         * Added the NVJPG and NVOFA utilization report to "nvidia-smi vgpu -p"  to  periodically
       report NVJPG/NVOFA utilization on running processs of active vgpus

         * Added a new cmdline option "-shm" to "nvidia-smi vgpu" to set vGPU heterogeneous mode

         * Added the reporting of vGPU heterogeneous mode in nvidia-smi -q

         *  Added  ability  to  call  "nvidia-smi  mig -lgip" and "nvidia-smi mig -lgipp" to work
       without requiring MIG being enabled

         * Added support to query confidential compute key rotation threshold info.

         * Added support to set confidential compute key rotation max attacker advantage.

         * Added a new cmdline option "--sparse-operation-mode" to "nvidia-smi clocks" to set the
       sparse operation mode

         * Added the reporting of sparse operation mode to "nvidia-smi -q -d PERFORMANCE"

         *  === Changes between nvidia-smi v535 Update and v545 ===

         *  Added  support  to  query  the  timestamp and duration of the latest flush of the BBX
       object to the inforom storage.

         * Added support for reporting out GPU Memory power usage.

         *  === Changes between nvidia-smi v535 Update and v530 ===

         * Updated the SRAM error status reported in the ECC query "nvidia-smi -q -d ECC"

         * Added support to query and report the GPU JPEG  and  OFA  (Optical  Flow  Accelerator)
       utilizations.

         * Removed deprecated "stats" command.

         * Added support to set the vGPU software scheduler state.

         * Renamed counter collection unit to gpu performance monitoring.

         * Added new C2C Mode reporting to device query.

         * Added back clock_throttle_reasons to --query-gpu to not break backwards compatibility

         * Added support to get confidential compute CPU capability and GPUs capability.

         * Added support to set confidential compute unprotected memory and GPU ready state.

         * Added support to get confidential compute memory info and GPU ready state.

         *  Added  support to display confidential compute devtools mode, environment and feature
       status.

         *  === Changes between nvidia-smi v525 Update and v530 ===

         * Added support to  query  power.draw.average  and  power.draw.instant.  See  nvidia-smi
       --help-query-gpu for details.

         * Added support to get the vGPU software scheduler state.

         * Added support to get the vGPU software scheduler logs.

         * Added support to get the vGPU software scheduler capabilities.

         * Renamed Clock Throttle Reasons to Clock Event Reasons.

         *  === Changes between nvidia-smi v520 Update and v525 ===

         * Added support to query and set counter collection unit stream state.

         *  === Changes between nvidia-smi v470 Update and v510 ===

         * Add new "Reserved" memory reporting to the FB memory output

         *  === Changes between nvidia-smi v465 Update and v470 ===

         * Added support to query power hint

         *  === Changes between nvidia-smi v460 Update and v465 ===

         * Removed support for -acp,--application-clock-permissions option

         *  === Changes between nvidia-smi v450 Update and v460 ===

         * Add option to specify placement when creating a MIG GPU instance.

         * Added support to query and control boost slider

         *  === Changes between nvidia-smi v445 Update and v450 ===

         *  Added --lock-memory-clock and --reset-memory-clock command to lock to closest min/max
       Memory clock provided and ability to reset Memory clock

         * Allow fan speeds greater than 100% to be reported

         * Added topo support to display NUMA node affinity for GPU devices

         * Added support to create MIG instances using profile names

         * Added support to create the default compute instance while creating a GPU instance

         * Added support to query and disable MIG mode on Windows

         * Removed support of GPU reset(-r) command on MIG enabled vGPU guests

         *  === Changes between nvidia-smi v418 Update and v445 ===

         * Added support for Multi Instance GPU (MIG)

         * Added support to individually reset NVLink-capable GPUs based  on  the  NVIDIA  Ampere
       architecture

         *  === Changes between nvidia-smi v361 Update and v418 ===

         *  Support  for Volta and Turing architectures, bug fixes, performance improvements, and
       new features

         *  === Changes between nvidia-smi v352 Update and v361 ===

         * Added nvlink support to expose the publicly available NVLINK NVML APIs

         * Added clocks sub-command with synchronized boost support

         * Updated nvidia-smi stats to report GPU temperature metric

         * Updated nvidia-smi dmon to support PCIe throughput

         * Updated nvidia-smi daemon/replay to support PCIe throughput

         * Updated nvidia-smi dmon, daemon and replay to support PCIe Replay Errors

         * Added GPU part numbers in nvidia-smi -q

         * Removed support for exclusive thread compute mode

         * Added Video (encoder/decode) clocks to the Clocks and Max Clocks display of nvidia-smi
       -q

         * Added memory temperature output to nvidia-smi dmon

         *  Added  --lock-gpu-clock  and --reset-gpu-clock command to lock to closest min/max GPU
       clock provided and reset clock

         * Added --cuda-clocks to override or restore default CUDA clocks

         === Changes between nvidia-smi v346 Update and v352 ===

         * Added topo support to display affinities per GPU

         * Added topo support to display neighboring GPUs for a given level

         * Added topo support to show pathway between two given GPUs

         * Added "nvidia-smi pmon" command-line for process monitoring in scrolling format

         * Added "--debug" option to produce an encrypted debug log for use in submission of bugs
       back to NVIDIA

         * Fixed reporting of Used/Free memory under Windows WDDM mode

         *  The accounting stats is updated to include both running and terminated processes. The
       execution time of running process is reported as 0 and updated to actual  value  when  the
       process is terminated.

         === Changes between nvidia-smi v340 Update and v346 ===

         * Added reporting of PCIe replay counters

         * Added support for reporting Graphics processes via nvidia-smi

         * Added reporting of PCIe utilization

         * Added dmon command-line for device monitoring in scrolling format

         *  Added  daemon  command-line  to  run  in  background  and monitor devices as a daemon
       process. Generates dated log files at /var/log/nvstats/

         * Added replay command-line to replay/extract the stat files  generated  by  the  daemon
       tool

         === Changes between nvidia-smi v331 Update and v340 ===

         * Added reporting of temperature threshold information.

         * Added reporting of brand information (e.g. Tesla, Quadro, etc.)

         * Added support for K40d and K80.

         *  Added  reporting of max, min and avg for samples (power, utilization, clock changes).
       Example commandline: nvidia-smi -q -d power,utilization, clock

         * Added nvidia-smi stats interface to collect statistics  such  as  power,  utilization,
       clock changes, xid events and perf capping counters with a notion of time attached to each
       sample. Example commandline: nvidia-smi stats

         * Added support for collectively reporting metrics on more than one GPU. Used with comma
       separated with "-i" option. Example: nvidia-smi -i 0,1,2

         * Added support for displaying the GPU encoder and decoder utilizations

         *  Added  nvidia-smi  topo  interface  to  display  the  GPUDirect  communication matrix
       (EXPERIMENTAL)

         * Added support for displayed the GPU board ID and whether or not it is a multiGPU board

         * Removed user-defined throttle reason from XML output

         === Changes between nvidia-smi v5.319 Update and v331 ===

         * Added reporting of minor number.

         * Added reporting BAR1 memory size.

         * Added reporting of bridge chip firmware.

         === Changes between nvidia-smi v4.319 Production and v4.319 Update ===

         * Added new --applications-clocks-permission switch to  change  permission  requirements
       for setting and resetting applications clocks.

         === Changes between nvidia-smi v4.304 and v4.319 Production ===

         *  Added  reporting  of Display Active state and updated documentation to clarify how it
       differs from Display Mode and Display Active state

         * For consistency on multi-GPU boards nvidia-smi -L  always  displays  UUID  instead  of
       serial number

         *  Added  machine  readable  selective reporting. See SELECTIVE QUERY OPTIONS section of
       nvidia-smi -h

         * Added queries for page retirement information.  See --help-query-retired-pages and  -d
       PAGE_RETIREMENT

         * Renamed Clock Throttle Reason User Defined Clocks to Applications Clocks Setting

         *  On error, return codes have distinct non zero values for each error class. See RETURN
       VALUE section

         * nvidia-smi -i can now query information from healthy GPU when there is a problem  with
       other GPU in the system

         * All messages that point to a problem with a GPU print pci bus id of a GPU at fault

         *  New  flag  --loop-ms for querying information at higher rates than once a second (can
       have negative impact on system performance)

         * Added  queries  for  accounting  procsses.   See  --help-query-accounted-apps  and  -d
       ACCOUNTING

         * Added the enforced power limit to the query output

         === Changes between nvidia-smi v4.304 RC and v4.304 Production ===

         * Added reporting of GPU Operation Mode (GOM)

         * Added new --gom switch to set GPU Operation Mode

         === Changes between nvidia-smi v3.295 and v4.304 RC ===

         * Reformatted non-verbose output due to user feedback.  Removed pending information from
       table.

         * Print out helpful message if initialization fails due to kernel module  not  receiving
       interrupts

         * Better error handling when NVML shared library is not present in the system

         * Added new --applications-clocks switch

         *  Added  new  filter to --display switch. Run with -d SUPPORTED_CLOCKS to list possible
       clocks on a GPU

         * When reporting free memory, calculate it from the rounded total  and  used  memory  so
       that values add up

         * Added reporting of power management limit constraints and default limit

         * Added new --power-limit switch

         * Added reporting of texture memory ECC errors

         * Added reporting of Clock Throttle Reasons

         === Changes between nvidia-smi v2.285 and v3.295 ===

         * Clearer error reporting for running commands (like changing compute mode)

         * When running commands on multiple GPUs at once N/A errors are treated as warnings.

         * nvidia-smi -i now also supports UUID

         * UUID format changed to match UUID standard and will report a different value.

         === Changes between nvidia-smi v2.0 and v2.285 ===

         * Report VBIOS version.

         * Added -d/--display flag to filter parts of data

         * Added reporting of PCI Sub System ID

         * Updated docs to indicate we support M2075 and C2075

         * Report HIC HWBC firmware version with -u switch

         * Report max(P0) clocks next to current clocks

         * Added --dtd flag to print the device or unit DTD

         * Added message when NVIDIA driver is not running

         *  Added  reporting  of  PCIe link generation (max and current), and link width (max and
       current).

         * Getting pending driver model works on non-admin

         * Added support for running nvidia-smi on Windows Guest accounts

         * Running nvidia-smi without -q command will output non verbose version of -q instead of
       help

         * Fixed parsing of -l/--loop= argument (default value, 0, to big value)

         * Changed format of pciBusId (to XXXX:XX:XX.X - this change was visible in 280)

         *  Parsing  of  busId  for  -i  command  is  less  restrictive.  You can pass 0:2:0.0 or
       0000:02:00 and other variations

         * Changed versioning scheme to also include "driver version"

         * XML format always conforms to DTD, even when error conditions occur

         * Added support for single and double bit ECC events and XID errors (enabled by  default
       with -l flag disabled for -x flag)

         * Added device reset -r --gpu-reset flags

         * Added listing of compute running processes

         *  Renamed  power  state  to  performance state. Deprecated support exists in XML output
       only.

         * Updated DTD version number to 2.0 to match the updated XML output

SEE ALSO

       On Linux, the driver README is installed as /usr/share/doc/NVIDIA_GLX-1.0/README.txt

AUTHOR

       NVIDIA Corporation

COPYRIGHT

       Copyright 2011-2024 NVIDIA Corporation.